JP2019034065A - Game machine - Google Patents

Abstract

To provide a game machine capable of appropriately coping with occurrence of power failure.SOLUTION: The number of game balls entering each ball entry part is stored in various counters provided in a normal counter area of a main-side RAM 65. A base value calculated by utilizing information stored in the various counters is stored in a calculation result storage area of the main-side RAM 65. A plurality of base values having different calculation timing can be stored in the calculation result storage area. The respective base values stored in the calculation result storage area are successively displayed on a notification display device. When operation power starts to be supplied to the main-side CPU 63, check display in which each display segment of the notification display device is turned on is performed. Monitoring of power failure is executed in a situation in which processing when supply of operation power is started is under execution.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a gaming machine.

  Pachinko machines and slot machines are known as gaming machines. For example, a pachinko gaming machine has a dish storage unit that stores game balls given to a player on the front side of the gaming machine, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish reservoir are discharged to the lower dish reservoir (see, for example, Patent Document 1).

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

JP 2009-261415 A

  Here, in the gaming machine such as the above-described example, it is necessary to appropriately cope with the occurrence of a power failure, and there is still room for improvement in this respect.

  The present invention has been made in view of the circumstances exemplified above, and an object thereof is to provide a gaming machine capable of appropriately dealing with the occurrence of a power failure.

In order to solve the above-mentioned problem, the invention according to claim 1 is configured to execute processing at the start of supply of operating power based on the start of supply of operating power.
A power failure monitoring means for enabling a power failure monitoring process to monitor the occurrence of a power failure in a situation where the process at the start of supplying the operating power is being performed;
It is characterized by having.

  According to the present invention, it is possible to appropriately cope with the occurrence of a power failure.

It is a perspective view which shows the pachinko machine in 1st Embodiment. It is a perspective view which decomposes | disassembles and shows the main structures of a pachinko machine. It is a front view which shows the structure of a game board. It is explanatory drawing for demonstrating the structure regarding discharge | emission of the game ball which flowed down the game area | region. It is a front view of a main controller. It is a block diagram which shows the electric constitution of a pachinko machine. It is explanatory drawing for demonstrating the content of the various counters used for a success or failure lottery. It is explanatory drawing for demonstrating the various tables memorize | stored in main side ROM. It is a flowchart which shows the main process performed by main side CPU. It is a flowchart which shows the setting value update process performed in main side CPU. It is a flowchart which shows the timer interruption process performed with the main side CPU. It is a flowchart which shows the special figure special electric power control process performed in main side CPU. It is a flowchart which shows the special figure fluctuation start process performed with the main side CPU. It is explanatory drawing for demonstrating the structure which makes the main side CPU input the detection result of a entrance detection sensor. It is a flowchart which shows the entrance detection process performed by main side CPU. It is a block diagram for demonstrating the electrical structure of the various apparatuses which communicate between a payout control apparatus and the said payout control apparatus. It is a flowchart which shows the timer interruption process performed with payout side CPU. It is a block diagram for demonstrating the electrical structure of IC for management. It is explanatory drawing for demonstrating the structure of the input port of management side I / F. It is explanatory drawing for demonstrating the structure of the memory for correspondence. It is explanatory drawing for demonstrating the structure of the memory for log | history. It is a flowchart which shows the process for recognition performed with the main side CPU. It is a flowchart which shows the management process performed with management side CPU. (A)-(d) It is a time chart which shows a mode that the information of the correspondence of the 1st-15th buffer and the kind of signal is stored in the memory for correspondence. It is a flowchart which shows the output process for management performed in main side CPU. It is a flowchart which shows the log | history setting process performed with management side CPU. (A)-(e) It is a time chart which shows a mode that log | history information is stored in the memory for log | history. It is a flowchart which shows the output process of the setting value update signal performed with the main side CPU. It is a flowchart which shows the process for the setting update recognition performed by management side CPU. It is a flowchart which shows the display output process performed in management side CPU. It is a flowchart which shows the process for a display performed with management side CPU. (A) It is a flowchart which shows the process for data output performed by main side CPU, (b) It is a flowchart which shows the process for external output performed by management side CPU. It is explanatory drawing for demonstrating the various tables memorize | stored in the main side ROM in 2nd Embodiment. It is explanatory drawing for demonstrating the structure of the memory for another storage in 3rd Embodiment. It is a flowchart which shows the process for the setting update recognition performed by management side CPU. It is a flowchart which shows the monitoring process of the repeated change performed by management side CPU. It is a flowchart which shows the monitoring process of the repeated change performed by the main side CPU in 4th Embodiment. It is a flowchart which shows the process for setting update recognition performed by the management side CPU in 5th Embodiment. It is explanatory drawing for demonstrating the structure of the memory for log | history in 6th Embodiment. It is a flowchart which shows the log | history setting process performed with management side CPU. It is a flowchart which shows the process for the setting update recognition performed by management side CPU. It is explanatory drawing for demonstrating the structure of the memory for log | history in 7th Embodiment. It is a flowchart which shows the process for the setting update recognition performed by management side CPU. It is explanatory drawing for demonstrating the structure of the memory for log | history in 8th Embodiment. It is a flowchart which shows the process for the setting update recognition performed by management side CPU. It is a flowchart which shows the log | history setting process performed with management side CPU. It is a flowchart which shows the display output process performed in management side CPU. It is explanatory drawing for demonstrating the structure of the input port of the management side I / F in 9th Embodiment. It is a flowchart which shows the process for recognition performed with the main side CPU. It is a flowchart which shows the management process performed with management side CPU. (A)-(h) It is a time chart which shows a mode that the information of the correspondence of 1st-12th buffer and the kind of signal is stored in the memory for correspondence. It is a block diagram for demonstrating the structure of the signal path | route which transmits the detection result of each entrance detection sensor in 10th Embodiment to main side CPU and management IC. It is a front view of the main controller in an 11th embodiment. It is a block diagram for demonstrating the electrical structure for performing various displays in the display apparatus for 1st-4th alerting | reporting based on control of MPU. It is a flowchart which shows the process for a display performed with management side CPU. It is a flowchart which shows the setting value update process performed in main side CPU. (A) It is explanatory drawing for demonstrating the display aspect of the display apparatus for 1st-4th alerting | reporting in case the management result of a game history is displayed, (b) When the setting state of a pachinko machine is changed It is explanatory drawing for demonstrating the display mode of the display apparatus for 1st-4th alerting | reporting. (A)-(h) It is a time chart which shows a mode that the display apparatus for 1st-4th notification will be in a display state. (A) It is explanatory drawing for demonstrating the structure of the 1st alerting | reporting display apparatus in 12th Embodiment, (b) It is explanatory drawing for demonstrating the structure of the 2nd alerting | reporting display apparatus. The first notification display device when displaying the management result of the game history on the first to fourth notification display devices and when displaying the changeable state in which the setting state of the pachinko machine can be changed It is explanatory drawing for demonstrating the display content of the display apparatus for 2nd alerting | reporting. It is a flowchart which shows the setting value update process performed in main side CPU. It is explanatory drawing for demonstrating the structure of the abnormality display area in 13th Embodiment. It is a flowchart which shows the abnormality setting process performed in main side CPU. It is a flowchart which shows the process for abnormality display performed by main side CPU. It is a flowchart which shows the output process for management performed by the main side CPU in 14th Embodiment. It is a flowchart which shows the main process performed with the main side CPU in another form. It is explanatory drawing for demonstrating the setting aspect of the program and data of a main side ROM in 15th Embodiment. It is explanatory drawing for demonstrating the setting aspect of each area in main side RAM. It is a flowchart which shows the timer interruption process performed with the main side CPU. It is a flowchart which shows the process for management performed by main side CPU. It is a flowchart which shows the management execution process performed with main side CPU. It is explanatory drawing for demonstrating the various areas of the work area for non-specific control used in order to manage a game log | history. It is a flowchart which shows the check process performed in main side CPU. It is a flowchart which shows the normal entrance management process performed with the main side CPU. It is a flowchart which shows the result calculation process performed in main side CPU. It is a flowchart which shows the process for a display performed with main side CPU. It is a flowchart which shows the process for management performed by the main side CPU in 16th Embodiment. It is a flowchart which shows the management execution process performed with the main side CPU in 17th Embodiment. It is a flowchart which shows the management execution process performed with the main side CPU in 18th Embodiment. It is a flowchart which shows the management execution process performed with the main side CPU in 19th Embodiment. It is a flowchart which shows the process for management performed by the main side CPU in 20th Embodiment. It is a flowchart which shows the management execution process performed with main side CPU. It is explanatory drawing for demonstrating the electrical structure in 21st Embodiment. It is a flowchart which shows the main process performed by the main side CPU in 22nd Embodiment. It is a flowchart which shows the setting value update process performed in main side CPU. It is a flowchart which shows the timer interruption process performed with the main side CPU. It is a flowchart which shows the process for a setting confirmation performed in main side CPU. It is a flowchart which shows the RAM monitoring process performed with the main side CPU. It is a flowchart which shows the main process performed with the main side CPU in another form. It is a flowchart which shows the setting value update process performed with the main side CPU in another form. It is a flowchart which shows the main process performed by the main side CPU in 23rd Embodiment. It is a flowchart which shows the RAM monitoring process performed with the main side CPU in 24th Embodiment. It is a flowchart which shows the RAM monitoring process performed with the main side CPU in 25th Embodiment. It is a flowchart which shows the management execution process performed with main side CPU. It is a flowchart which shows the another monitoring process performed with the main side CPU. It is a flowchart which shows the process for management performed by the main side CPU in 26th Embodiment. It is a flowchart which shows the process for management performed by the main side CPU in 27th Embodiment. It is a flowchart which shows the process for management performed by the main side CPU in 28th Embodiment. It is a flowchart which shows the process for management performed by the main side CPU in 29th Embodiment. It is a flowchart which shows the main process performed with the main side CPU in 30th Embodiment. It is a flowchart which shows the power failure information storage process performed with main side CPU. (A) It is a block diagram for demonstrating the structure of MPU, (b) It is a time chart which shows the mode of the output of the reset signal by a reset signal output part. It is a flowchart which shows the timer interruption process performed with the main side CPU. It is a flowchart which shows the setting monitoring process performed in main side CPU. It is a flowchart which shows the process for management performed by main side CPU. It is a flowchart which shows the management execution process performed with main side CPU. It is a flowchart which shows the another monitoring process performed with the main side CPU. It is a flowchart which shows the main process performed by the main side CPU in 31st Embodiment. It is a flowchart which shows the clear process at the time of abnormality performed by main side CPU. It is a flowchart which shows the clear process for non-specific control performed by the main side CPU. It is a flowchart which shows the power failure information storage process performed with the main side CPU in 32nd Embodiment. It is a flowchart which shows the checksum monitoring process performed with the main side CPU. It is a flowchart which shows the clear process for non-specific control performed by the main side CPU. It is a flowchart which shows the main process performed by the main side CPU in 33rd Embodiment. It is a flowchart which shows the process for a setting confirmation performed in main side CPU. It is a flowchart which shows the setting value update process performed in main side CPU. It is a flowchart which shows the 1st timer interruption process performed with the main side CPU. It is a flowchart which shows the setting monitoring process performed in main side CPU. It is a block diagram for demonstrating the structure for carrying out display control of the various display circuits in main side CPU. (A) It is explanatory drawing for demonstrating the various buffers provided in the work area for specific control, (b) It is explanatory drawing for demonstrating the various storage areas provided in the work area for non-specific control. is there. It is explanatory drawing for demonstrating the electrical structure of display IC. (A) to (g) The type data and display data are transmitted from the main CPU to the display IC, and the display data transmitted from the display IC is received by the first display circuit or the second display circuit. It is a time chart. It is a flowchart which shows the 2nd timer interruption process performed with the main side CPU. (A) It is explanatory drawing for demonstrating the display content of the display apparatus for the 1st-4th alerting | reporting in the condition where a setting value is updated, (b) The 1st-4th alerting | reporting in the condition where a setting value is confirmed It is explanatory drawing for demonstrating the display content of the display apparatus for computers. It is a flowchart which shows the setting value update process performed with the main side CPU in 34th Embodiment. FIG. 38 is an explanatory diagram for describing an electrical configuration of a calculation result storage area in a thirty-fifth embodiment. (A)-(d) It is explanatory drawing for demonstrating the display content of the display apparatus for 1st-4th information. (A)-(c) It is explanatory drawing for demonstrating the display content of the display apparatus for 1st-4th alerting | reporting. (A)-(e) It is a time chart which shows a mode that the base value of various areas is alert | reported with the display apparatus for 1st-4th alerting | reporting. It is a flowchart which shows the result calculation process performed in main side CPU. It is a flowchart which shows the process for a display performed with main side CPU. It is a flowchart which shows the main process performed by main side CPU. It is a flowchart which shows the 1st timer interruption process performed with the main side CPU. It is a flowchart which shows the 2nd timer interruption process performed with the main side CPU. It is a flowchart which shows the setting process in the normal time performed with the main side CPU. It is a flowchart which shows the process for a setting confirmation performed in main side CPU. It is a flowchart which shows the setting value update process performed in main side CPU. (A)-(f) It is a time chart for demonstrating the display content of the 1st-4th alerting | reporting display apparatus in case supply of the operating power to the main side CPU is started. It is a flowchart which shows the main process performed by the main side CPU in 36th Embodiment. It is a flowchart which shows the main process performed by the main side CPU in 37th Embodiment. It is a flowchart which shows the normal time setting process performed with the main side CPU in 38th Embodiment.

<First Embodiment>
Hereinafter, a first embodiment of a pachinko gaming machine (hereinafter referred to as “pachinko machine”), which is a type of gaming machine, will be described in detail with reference to the drawings. FIG. 1 is a perspective view of the pachinko machine 10, and FIG. 2 is an exploded perspective view showing the main configuration of the pachinko machine 10. As shown in FIG. In FIG. 2, the configuration in the game area PA of the pachinko machine 10 is omitted for convenience.

  As shown in FIG. 1, the pachinko machine 10 includes an outer frame 11 that forms an outer shell of the pachinko machine 10, and a gaming machine main body 12 that is rotatably attached to the outer frame 11. Have. The outer frame 11 is configured by connecting wooden plates to four sides and has a rectangular frame shape. The pachinko machine 10 is installed in the game hall by attaching and fixing the outer frame 11 to the island facility. In the pachinko machine 10, the outer frame 11 is not an essential configuration, and may be configured such that the outer frame 11 is provided in the island facility of the game hall.

  As shown in FIG. 2, the gaming machine main body 12 includes an inner frame 13, a front door frame 14 disposed in front of the inner frame 13, and a back pack unit 15 disposed behind the inner frame 13. ing. An inner frame 13 of the gaming machine body 12 is rotatably supported by the outer frame 11. Specifically, the inner frame 13 can be rotated forward with the left side as a rotation base end side and the right side as a rotation front end side in front view.

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

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

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

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

  Here, the structure of the game board 24 is demonstrated based on FIG. FIG. 3 is a front view of the game board 24.

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

  Incidentally, the game ball launching mechanism 27 includes a launch rail 27a that extends toward the guide rail, a ball feeding device 27b that supplies game balls stored in an upper plate 55a, which will be described later, onto the launch rail 27a, and the launch rail 27a. And a solenoid 27c which is an electric actuator for firing the game ball supplied to the guide rail. When the launch operation device (or operation handle) 28 provided on the front door frame 14 is rotated, the solenoid 27c is driven and controlled, and a game ball is launched.

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

  Even if a ball enters the through gate 35, the game ball is not paid out. On the other hand, when a ball enters the general winning port 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34, a predetermined number of game balls are paid out. Specifically, when the number of prize balls is one game ball entering the first operation port 33 or one game ball entering the second operation port 34 is generated. In the case where one prize ball is paid out and one game ball is thrown into the general prize opening 31, ten prize balls are paid out and the special prize winning device 32 is paid out. When one game ball enters, 15 prize balls are paid out.

  The number of prize balls may be arbitrary. For example, the second actuation port 34 may have a smaller number of prize balls than the first actuation port 33, and the second actuation port 34 may be configured as the first actuation port. The number of prize balls may be larger than 33.

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

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

  The first operating port 33 and the second operating port 34 are unitized as operating port devices and are installed in the game board 24. Both the first working port 33 and the second working port 34 are opened upward. Further, both the operation ports 33 and 34 are arranged in the vertical direction so that the first operation port 33 is located on the upper side. The second operating port 34 is provided with a general electric utility 34a as a guide piece composed of a pair of left and right movable pieces. In the closed state of the utility wire 34a, the game ball cannot win the second operating port 34, and the winning of the second operating port 34 becomes possible when the universal power 34a is opened.

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

  Based on the winning of the through gate 35, the common utility 34 a of the second operating port 34 is switched from the closed state to the open state. Specifically, an internal lottery is performed with a winning at the through gate 35 as a trigger, and a normal display of a general-purpose unit 38 provided at the lower right corner, which is a region where game balls do not pass in the game region PA, is displayed. In the part 38a, the change display of the pattern is performed. Then, when the result of the internal lottery is the electrification opening winning, the stop result corresponding to the result is displayed, and the fluctuation display of the general map display unit 38a is finished, the state shifts to the public power open state. In the public power open state, the general electric utility 34a is opened in a predetermined manner.

  The general map display unit 38a is configured by a segment display in which a plurality of display segments by LEDs are arranged in a predetermined manner. However, the display unit 38a is not limited to this, and is not limited to this. You may be comprised by other types of display apparatuses, such as a display apparatus, CRT, or a dot matrix display. In addition, as a pattern variably displayed on the normal map display unit 38a, a configuration in which a plurality of types of characters are variably displayed, a configuration in which a plurality of types of symbols are variably displayed, a configuration in which a plurality of types of characters are variably displayed or A configuration in which a plurality of colors are switched and displayed is conceivable.

  In the universal map unit 38, a universal map hold display section 38b is provided at a position adjacent to the universal map display section 38a. A maximum of four game balls won in the through gate 35 are reserved, and the number of the reserved balls is displayed by turning on the general-purpose display unit 38b.

  A lottery is performed with the winning of the first working port 33 or the second working port 34 as a trigger. The lottery result is clearly shown through display effects in the symbol display device 41 of the special figure unit 37 and the variable display unit 36.

  Specifically, the special figure unit 37 is provided with a special figure display unit 37a. The display area of the special figure display unit 37 a is narrower than the display surface 41 a of the symbol display device 41. In the special figure display part 37a, a winning change to the first working port 33 or a winning to the second working port 34 is used as a trigger, and a lottery is performed to display a variation display or a predetermined display. Then, a result corresponding to the lottery result is displayed. The special figure display unit 37a is constituted by a segment display in which a plurality of display segments by LEDs are arranged in a predetermined manner, but is not limited to this, and is not limited to this. You may be comprised by other types of display apparatuses, such as a display apparatus, CRT, or a dot matrix display. In addition, as a picture displayed on the special figure display unit 37a, a configuration in which a plurality of types of characters are displayed, a configuration in which a plurality of types of symbols are displayed, a configuration in which a plurality of types of characters are displayed, or a plurality of types of colors A configuration in which is displayed is considered.

  In the special figure unit 37, a special figure holding display part 37b is provided at a position adjacent to the special figure display part 37a. A maximum of four game balls won in the first operation port 33 or the second operation port 34 are reserved, and the reserved number is displayed by lighting the special figure reservation display portion 37b.

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

  In the symbol display device 41, when the special symbol display unit 37a performs a variable display or a predetermined display on the basis of the winning in the first operating port 33 or the winning in the second operating port 34, the symbol is displayed accordingly. A variable display or a predetermined display is performed. For example, on the display surface 41a of the symbol display device 41, three symbol rows of upper, middle, and lower rows are set as a plurality of display areas, and numbers “1” to “9” are attached to the symbol rows. The symbols are scrolled and displayed with the symbols arranged in ascending or descending order. In this scroll display, the scroll display in all the symbol sequences is started first, and the display is switched from the scroll display to the standby display in the order of the upper symbol sequence → the lower symbol sequence → the middle symbol sequence. The process ends with the symbols still displayed. Then, in the game times in which the game result is a jackpot result, a combination of predetermined symbols is stopped and displayed on the active line set in advance on the display surface 41a of the symbol display device 41. Specifically, the same odd symbol combination is stopped when the most advantageous jackpot result described later is displayed, and the same even symbol combination is stopped and displayed when the lower probability winning result described later is described. If the winning combination is not the same symbol combination, the combination of symbols that are not displayed in a stopped state is stopped.

  The symbol display device 41 performs not only a display effect triggered by winning a prize at the first operating port 33 or the second operating port 34, but also a display effect in the opening / closing execution mode that is shifted to after winning the winning combination. Is called. In addition, based on the winning in one of the operation ports 33 and 34, the display is started on the special symbol display unit 37a and the symbol display device 41, and until a predetermined result is displayed and ended, the game number is 1 Equivalent to times. Further, the variation display mode of the symbol in the symbol display device 41 is not limited to the above, and is arbitrary, such as the number of symbol columns, the direction of symbol variation display in the symbol column, the number of symbols in each symbol column, etc. Can be appropriately changed. Also, the pattern that is variably displayed on the symbol display device 41 is not limited to the above-described pattern, and for example, only numbers may be variably displayed as the pattern.

  When the big win is won in the winning lottery based on the winning to the first operating port 33 or the winning to the second operating port 34, the mode shifts to an opening / closing execution mode in which the special electric winning device 32 can be won. The special electric prize winning device 32 is provided with a large winning opening (not shown) leading to the back side of the game board 24 and an open / close door 32a for opening and closing the large winning opening. The open / close door 32a is arranged in either a closed state or an open state. Specifically, the open / close door 32a is normally in a closed state in which a game ball cannot be won, and is switched to an open state in which a game ball can win when winning the transition to the open / close execution mode in the internal lottery. It has become. Incidentally, the opening / closing execution mode is a mode that shifts when a hit result is obtained. Note that, in the closed state, winning may not be impossible, but it may be configured such that winning is less likely to occur than in the open state.

  FIG. 4 is an explanatory diagram for explaining a configuration relating to the discharge of the game ball that has flowed down the game area PA.

  As already described, the game balls that have entered the general winning opening 31, the special prize winning device 32, the first operating opening 33, the second operating opening 34, and the out opening 24a are discharged from the gaming area PA. In other words, the game ball that is launched from the game ball launching mechanism 27 and flows into the game area PA is any one of the general winning port 31, the special prize winning device 32, the first operating port 33, the second operating port 34, and the out port 24a. By entering the ball, the game area PA is discharged. A game ball that has entered any of the general winning port 31, the special prize winning device 32, the first operating port 33, the second operating port 34, and the out port 24a is guided to the back side of the game board 24.

  On the back side of the game board 24, discharge passage portions 42 to 48 are formed in correspondence with the general winning port 31, the special electricity winning device 32, the first operating port 33, the second operating port 34, and the out port 24a, respectively. . The game balls that have flowed into the discharge passage portions 42 to 48 flow down through the discharge passage portions 42 to 48 that have flowed in, and are led to the lower end portion of the game board 24 on the back side of the game board 24, and become a discharge ball collection portion (not shown). Collected. Then, the game balls collected by the discharge ball collection unit are discharged to the ball circulation device of the island facility where the pachinko machine 10 is installed in the game hall.

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

  Corresponding to the special electric prize winning device 32, a fourth discharge passage portion 45 exists. A special electric detection sensor 45 a is provided so that a detection range exists in the middle of the fourth discharge passage portion 45, and a game ball that has entered the special electric prize device 32 is in the middle of passing through the fourth discharge passage portion 45. It is detected by the special electricity detection sensor 45a. A fifth discharge passage portion 46 exists corresponding to the first working port 33. A first operation port detection sensor 46a is provided so that a detection range exists in the middle of the fifth discharge passage portion 46, and a game ball that has entered the first operation port 33 passes through the fifth discharge passage portion 46. In the middle of passing, it is detected by the first working port detection sensor 46a. A sixth discharge passage portion 47 exists corresponding to the second working port 34. A second operation port detection sensor 47a is provided so that a detection range exists in the middle of the sixth discharge passage portion 47, and a game ball that has entered the second operation port 34 passes through the sixth discharge passage portion 47. In the middle of passing, it is detected by the second working port detection sensor 47a. A seventh discharge passage portion 48 exists corresponding to the out port 24a. An out-port detection sensor 48 a is provided so that a detection range exists in the middle of the seventh discharge passage portion 48, and a game ball that has entered the out-port 24 a passes through the seventh discharge passage portion 48. It is detected by the outlet detection sensor 48a.

  In addition, the game ball which became a detection target by any one detection sensor 42a-48a among the various detection sensors 42a-48a does not become a detection target of the other detection sensors 42a-48a. A gate detection sensor 49a is also provided for the through gate 35, and a game ball passing through the through gate 35 in the middle of flowing down the game area PA is detected by the gate detection sensor 49a.

  As the various detection sensors 42a to 49a, electromagnetic induction type proximity sensors are used, but any sensor can be used as long as it can individually detect game balls. The various detection sensors 42 a to 49 a are electrically connected to a main control device 60 described later, and the detection results of the various detection sensors 42 a to 49 a are output to the main control device 60. Specifically, the various detection sensors 42a to 49a output a LOW level signal in a situation where a game ball is not detected, and an HI level signal in a situation where a game ball is detected. Note that the present invention is not limited to this, and the relationship between HI and LOW may be reversed.

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

  A display light emitting unit 53 is provided above the window unit 51. In addition, a pair of left and right speaker portions 54 that output sound effects according to the gaming state are provided. Further, below the window portion 51, an upper bulging portion 55 and a lower bulging portion 56 that bulge to the near side are arranged in parallel vertically. An upper plate 55a that opens upward is provided inside the upper bulge portion 55, and a lower plate 56a that also opens upward is provided inside the lower bulge portion 56. The upper plate 55a has a function of temporarily storing game balls paid out from a payout device described later and guiding them to the game ball launching mechanism 27 side while aligning them in a row. In addition, the lower tray 56a has a function of storing game balls that are surplus in the upper tray 55a.

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

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

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

  The board box 60a is formed by combining a plurality of case bodies 60c back and forth, and the plurality of case bodies 60c prevent the separation of the case bodies 60c and the traces when the case bodies 60c are separated. A coupling portion 60e is provided for leaving A plurality of coupling portions 60e are arranged in parallel on one side of the substantially rectangular parallelepiped substrate box 60a. As a result, even if the part of the coupling part 60e is broken and the case body 60c is separated in a state where the separation of the case body 60c is prevented using the part of the coupling part 60e, another coupling is performed thereafter. Separation of the case body 60c can be prevented again by setting the portion 60e in the coupled state. Further, when the case portion 60c is separated, the coupling portion 60e is destroyed and the trace remains, so that it is possible to grasp whether the case body 60c is illegally separated by visually confirming the coupling portion 60e. It becomes possible. In addition, a sealing seal 60f is attached to one side opposite to the side where the coupling portion 60e is arranged in the substrate box 60a so as to straddle the boundary between the case bodies 60c. When the seal seal 60f is peeled off, the adhesive layer remains on the case body 60c. Thereby, when the seal seal 60f is peeled off at the time of separation of the case body 60c, it becomes possible to leave the trace.

  In the main control device 60 configured as described above, the main control board 61 is owned by the manager of the game hall in order to generate an opportunity to change the setting state of the pachinko machine 10 in the range of “setting 1” to “setting 6”. A setting key insertion unit 68a that is turned on when the setting key is inserted; an update button 68b that is operated to sequentially change the setting state of the pachinko machine 10 after the ON operation is performed on the setting key insertion unit 68a; A reset button 68c that is operated to clear data in a later-described main RAM 65 provided in the MPU 62 of 60, and first to third notification display devices 69a to 69c for notifying the management result of the game history; , Is provided. The MPU 62 mounted on the main control board 61 is connected to a connection terminal of the external device in order to read the game history management result or information (program and data) stored in the main ROM 64 by the external device. A reading terminal 68d is provided. Note that the setting state of the pachinko machine 10 is not limited to six levels of “setting 1” to “setting 6”, and is arbitrary as long as it is a plurality of levels.

  These setting key insertion portion 68a, update button 68b, reset button 68c, reading terminal 68d (ie, MPU 62) and first to third notification display devices 69a to 69c are all provided on the element mounting surface of the main control board 61. ing. The element mounting surface of the main control board 61 faces the facing wall 60b of the board box 60a as described above, but the setting key insertion part 68a, the update button 68b, the reset button 68c, and the reading terminal 68d face each other. It is not covered with the wall part 60b. In other words, the opposing wall portion 60b has individual openings corresponding to the setting key insertion portion 68a, the update button 68b, the reset button 68c, and the reading terminal 68d. Thus, the setting key can be inserted into the setting key insertion portion 68a without opening the board box 60a, the update button 68b can be pressed, and the reset button 68c can be pressed. It is possible to connect a connection terminal of an external device to the reading terminal 68d.

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

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

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

  The reset button 68c is operated to clear the data in the main RAM 65 as described above. In order to generate the clearing of the data, supply of operating power to the pachinko machine 10 with the reset button 68c being pressed is performed. (That is, the supply of operating power to the MPU 62 of the main controller 60 needs to be started). The ON operation for the reset button 68c is valid only when the supply of operating power to the pachinko machine 10 is started (that is, when the supply of operating power to the MPU 62 of the main controller 60 is started). Therefore, even if the reset button 68c is pressed after the processing at the start of supply of operating power is completed in the MPU 62 of the main controller 60, the data in the main RAM 65 cannot be cleared.

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

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

  On the display surface of the first notification display device 69a, not only the numbers “0” to “9” but also various characters including alphabetic characters are displayed. On the other hand, the numbers “0” to “9” are displayed on the second notification display device 69b and the third notification display device 69c. The management results of the game history are notified using the first to third notification display devices 69a to 69c, and the details of the notification will be described later in detail. In the changeable state in which the setting state of the pachinko machine 10 can be changed, a value corresponding to the current setting value is displayed on the third notification display device 69c. Note that a value corresponding to the set value may be displayed on the first notification display device 69a, or may be displayed on the second notification display device 69b. In addition, the set value before the changeable state is displayed on one of the first to third notification display devices 69a to 69c, and the current set value is the first to third notification. It is good also as a structure displayed on the other one display apparatus for notification among the display apparatuses 69a-69c.

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

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

  The control device assembly unit 74 generates and outputs predetermined power required by the payout control device 77 having a function of controlling the payout device 76 and various control devices, and is accompanied by an operation of the launch operation device 28 by the player. And a power source / launch control device 78 for controlling the launch of the game ball. The payout control device 77 and the power supply / launch control device 78 are arranged so as to overlap each other so that the payout control device 77 is behind the pachinko machine 10.

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

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

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

  The main-side RAM 65 is a memory (that is, a volatile storage unit) that requires an external power supply for storage and holding such as SRAM and DRAM, and is used for both reading and writing. The main RAM 65 is capable of random access, and has a faster read time than the main ROM 64 when compared with the same data capacity. The main RAM 65 temporarily stores various data for the execution of the control program stored in the main ROM 64.

  The management IC 66 is a management device that manages a game history based on information supplied from the main CPU 63. Although details will be described later, the management IC 66 grasps the history of entering the game balls into the general winning opening 31, the special prize winning device 32, the first operating opening 33, the second operating opening 34, and the out opening 24a, The frequency of entering the general winning port 31, the special prize winning device 32, the first operating port 33, and the second operating port 34 is determined in accordance with the determined winning history. Further, the management IC 66 grasps the frequency of occurrence of an opening / closing execution mode and a high frequency support mode, which will be described later.

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

  Various sensors such as the ball entry detection sensors 42 a to 49 a are connected to the input side of the MPU 62. As described above, each of the winning detection sensors 42a to 49a includes the first winning opening detection sensor 42a, the second winning opening detection sensor 43a, the third winning opening detection sensor 44a, the special electric detection sensor 45a, and the first operation opening detection. A sensor 46a, a second working port detection sensor 47a, an out port detection sensor 48a, and a gate detection sensor 49a are included. Based on the detection results of these entrance detection sensors 42a to 49a, the main CPU 63 determines whether or not to enter each entrance. Further, the main CPU 63 executes various lotteries based on winning in the first operating port 33 and various lotteries based on winning in the second operating port 34.

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

  A power failure monitoring board 67, a payout control device 77, and a sound emission control device 81 are connected to the output side of the MPU 62. For example, a prize ball command is output to the payout control device 77 based on the fact that a game ball has entered a prize ball-corresponding entrance part corresponding to the payout of a game ball in the entrance part. The Various commands such as a change command, a type command, and an opening command are output to the sound emission control device 81.

  On the output side of the MPU 62, a special electric drive unit 32 b that opens and closes the open / close door 32 a of the special electric prize winning device 32, a general electric drive unit 34 b that opens and closes the electric utility item 34 a of the second operating port 34, A figure unit 37 and a universal figure unit 38 are connected. Incidentally, the special figure unit 37 is provided with a special figure display part 37 a and a special figure holding display part 37 b, all of which are connected to the output side of the MPU 62. Similarly, the universal map unit 38 is provided with a universal map display unit 38 a and a universal map hold display unit 38 b, all of which are connected to the output side of the MPU 62. The main control board 61 is provided with various driver circuits, and the MPU 62 performs drive control of various drive units and various display units through the driver circuits.

  In other words, in the open / close execution mode, the main CPU 63 performs drive control of the special electric drive unit 32b so that the special electric prize winning device 32 is opened and closed. In addition, when the power utility 34a is in the open state, the main CPU 63 performs drive control of the power drive 34b so that the power utility 34a is opened and closed. In each game round, the main CPU 63 executes display control of the special figure display unit 37a. In addition, when the lottery result indicating whether or not to open the general electric utility 34a is clearly indicated, the main CPU 63 performs display control of the normal display portion 38a. In addition, when a winning in the first working port 33 or the second working port 34 occurs, or when a variable display is started in the special figure display unit 37a, the main CPU 63 performs display control of the special figure holding display unit 37b. Is executed, and when the winning display to the through gate 35 occurs, or when the variable display is started in the general map display unit 38a, the display control of the general map hold display unit 38b is executed in the main CPU 63.

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

  However, the present invention is not limited to this, and the third notification display device 69c may be configured to be controlled by the management IC 66 and not controlled by the main CPU 63. In this case, when the current setting value is displayed on the third notification display device 69c when the setting state of the pachinko machine 10 is changed, the main CPU 63 issues a setting value display instruction to the management IC 66. Good.

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

  The power failure monitoring board 67 relays between the main control board 61 and the power source / launch control device 78 and monitors a DC stable voltage of 24 volts, which is the maximum voltage output from the power source / launch control device 78. The payout control device 77 performs payout control of prize balls and rental balls by the payout device 76 based on the prize ball command received from the main control device 60.

  The power / launch control device 78 is connected to, for example, a commercial power source (external power source) in a game hall or the like. And based on the external electric power supplied from the commercial power supply, necessary operating power is generated for each of the main control board 61, the payout control device 77, etc., and the generated operating power is supplied. Incidentally, the power supply / launch control device 78 is provided with a power supply unit for power interruption such as a backup capacitor. Power for storing and holding is supplied to the main side RAM 65 and the payout control device 77 of the control device 60. In addition, the power source / launch control device 78 is responsible for launch control of the game ball launch mechanism 27, and the game ball launch mechanism 27 is driven when predetermined launch conditions are met. In addition, the payout mechanism 73 is provided with a power switch as described above. When the power switch is turned on, supply of operating power to the pachinko machine 10 is started and the power switch is turned off. As a result, the supply of operating power to the pachinko machine 10 is stopped.

  The sound emission control device 81 controls the display control device 82 while driving and controlling the display light emitting portion 53 and the speaker portion 54 provided on the front door frame 14 based on various commands received from the main control device 60. It is. The display control device 82 executes display control of the symbol display device 41 based on the command received from the sound emission control device 81.

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

  The main CPU 63 uses various counter information during the game to perform jackpot occurrence lottery, setting of display of the special symbol display unit 37a, setting of symbol display of the symbol display device 41, setting of display of the general symbol display unit 38a, etc. Specifically, as shown in FIG. 7, the winning random number counter C1 used for the winning lottery, the big hit type counter C2 used for determining the big hit type, and the symbol display device 41 are changed. The reach random number counter C3 used for the reach generation lottery, the random number initial value counter CINI used for setting the initial value of the hit random number counter C1, the display duration in the special figure display unit 37a and the symbol display device 41 are determined. The fluctuation type counter CS is used. Further, the utility power release counter C4 used for the lottery to determine whether or not the utility power item 34a of the second working port 34 is set to the utility power release state is used. The counters C1 to C3, CINI, CS, and C4 are provided in various counter areas 65b of the main RAM 65.

  Each of the counters C1 to C3, CINI, CS, and C4 is a loop counter that adds 1 to the previous value every time it is updated and returns to “0” after reaching the maximum value. Each counter is updated at short intervals. Information corresponding to the winning random number counter C1, the big hitting type counter C2 and the reach random number counter C3 is provided as acquisition information storage means in the main RAM 65 when a winning to the first operating port 33 or the second operating port 34 occurs. Stored in the reserved storage area 65a.

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

  In this case, in the first reservation area RE1 to the fourth reservation area RE4, when a winning to the first operation port 33 or the second operation port 34 occurs continuously a plurality of times, the first reservation area RE1 → second Each numerical information is stored in time series in the order of the reserved area RE2 → the third reserved area RE3 → the fourth reserved area RE4. By providing the four holding areas RE1 to RE4 as described above, up to four game balls winning histories to the first operating port 33 or the second operating port 34 are stored and stored. .

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

  The execution area AE is an area for moving each numerical information stored in the first holding area RE1 of the holding area RE when starting the variable display of the special figure display section 37a, and starting one game round At this time, determination of success or failure is performed based on various numerical information stored in the execution area AE.

  Each of the counters will be described in detail.

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

  In the pachinko machine 10, a plurality of types of support modes are set so that the modes of support by the electric utility 34 a are different from each other. Specifically, in the support mode, when compared to the game area PA in a situation where the game ball is continuously being fired in the same manner, the utility object 34a of the second working port 34 is released per unit time. The high frequency support mode and the low frequency support mode are set so that the frequency of the state becomes relatively high and low.

  In the high frequency support mode and the low frequency support mode, the probability of winning the electric power open state in the electric power open lottery using the electric power utility opening counter C4 is the same (for example, both 4/5). In the high frequency support mode, the number of times that the power utility 34a is in the open state is set more frequently than in the low frequency support mode, and one open time is set longer. Has been. In this case, in the high frequency support mode, when the open state of the public electric power is selected and the open state of the general electric utility 34a is generated a plurality of times, from the end of one open state to the start of the next open state. The closing time is set shorter than one opening time. Furthermore, in the high frequency support mode, the minimum reserved time (i.e., the normal map) is required for the next open train lottery after the first open train lottery than in the low frequency support mode. The display duration time for the display unit 38a is set short.

  As described above, in the high frequency support mode, the probability of winning a prize to the second operating port 34 is higher than in the low frequency support mode. In other words, in the low frequency support mode, there is a higher probability of winning the first operating port 33 than in the second operating port 34, but in the high frequency support mode, the second operation is performed more than in the first operating port 33. The probability of winning a prize in the mouth 34 is increased. When a winning is made to the second operation port 34, a predetermined number of game balls are paid out. Therefore, in the high frequency support mode, the player plays a game while not reducing the number of possessed balls so much. It can be carried out.

  Note that the configuration for increasing the frequency at which the high frequency support mode is set to the normal power open state per unit time as compared to the low frequency support mode is not limited to the above, for example, in the general power open lottery It is good also as a structure which raises the probability that it will be elected in an open state of a public train. In addition, a reserved time (for example, executed in the general map display unit 38a based on a winning to the through gate 35) is secured after the next public train opening lottery is performed. In a configuration in which a plurality of types of variable display time) are prepared, the high frequency support mode is set so that a short securing time is easily selected or the average secure time is shorter than the low frequency support mode. Also good. Furthermore, increase the number of times of opening, lengthen the opening time, and shorten the reserved time that will be secured when the next public train opening lottery is performed after the first public train opening lottery is performed, the reserved time concerned The advantage of the high-frequency support mode over the low-frequency support mode may be increased by applying any one condition or any combination of conditions among shortening the average time and increasing the winning probability.

  Here, as described above, the pachinko machine 10 has the setting states of “setting 1” to “setting 6”, but the release frequency and the release mode of the general utility 34a in the low frequency support mode are any. Even if it is a set value, it is the same, and the open frequency and the open mode of the utility model 34a in the high frequency support mode are the same regardless of the set value. However, the present invention is not limited to this. At least one of the low frequency support mode and the high frequency support mode varies in accordance with the setting state of the pachinko machine 10 in at least one of the opening frequency and the opening mode of the utility appliance 34a. It is good also as a structure. For example, the higher the set value, the higher the frequency of opening of the power utility 34a in the low frequency support mode, and the second operation when the power utility 34a is opened once in the low frequency support mode. It is good also as a structure where the entrance probability of the game ball to the mouth 34 becomes high. In addition, the higher the set value, the higher the frequency of opening the power utility 34a in the high frequency support mode, and the second frequency when the power utility 34a is in the open state once in the high frequency support mode. It is good also as a structure where the entrance probability of the game ball to the operation port 34 becomes high.

  Next, the winning random number counter C1 will be described. For example, the winning random number counter C1 is incremented by 1 within a range of 0 to 599, and returns to “0” after reaching the maximum value. In particular, when the winning random number counter C1 makes one round, the value of the initial random number counter CINI at that time is read as the initial value of the winning random number counter C1. The random number initial value counter CINI is a loop counter similar to the winning random number counter C1 (value = 0 to 599). The winning random number counter C1 is periodically updated and stored in the holding storage area 65a of the main RAM 65 at the timing when the game ball wins the first operation port 33 or the second operation port 34.

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

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

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

  On the other hand, the high-accuracy determination table 64g is provided with only one type so as to be common in any setting state of “setting 1” to “setting 6”. The high-accuracy determination table 64g is set so that the winning probability of the jackpot result is higher than that of the low-accuracy determination tables 64a to 64f in any of the setting states “setting 1” to “setting 6”. Specifically, when the high-accuracy table 64g is referred to, a jackpot result is obtained at about 1/30. Thereby, regardless of the setting state of the pachinko machine 10, it becomes possible to make the high probability mode more advantageous than the low probability mode. In addition, even in the lowest setting state “Setting 1”, it becomes possible to increase the probability of a jackpot result compared to the low setting mode “Setting 6” which is the highest setting state by entering the high probability mode. It becomes. Further, in the high probability mode, it becomes possible to prevent the advantage or disadvantage of the setting state of the pachinko machine 10 from occurring, and the storage capacity for preliminarily storing the high-accuracy determination table 64g in the main ROM 64 is suppressed. It becomes possible.

  The jackpot type counter C2 is incremented one by one within the range of 0 to 29, and returns to “0” after reaching the maximum value. The jackpot type counter C2 is periodically updated and stored in the holding storage area 65a at the timing when the game ball wins the first operating port 33 or the second operating port 34.

  In the pachinko machine 10, a plurality of jackpot results are set. The plurality of jackpot results are as follows: (1) a mode of opening / closing control of the special prize winning device 32 in the opening / closing execution mode, (2) lottery mode in the winning lottery means after the opening / closing execution mode ends, (3) A plurality of jackpot results are set by making a difference in the three conditions of the support mode in the general electric utility 34a of the two operation ports 34.

  As an aspect of the opening / closing control of the special electricity winning device 32 in the opening / closing execution mode, the occurrence frequency of the winning to the special electricity winning device 32 from the start to the end of the opening / closing execution mode is relatively high. A frequency winning mode and a low frequency winning mode are set. Specifically, in any of the high-frequency winning mode and the low-frequency winning mode, the game is executed with a predetermined number of round games as an upper limit.

  A round game is a game that continues until either a predetermined upper limit duration has elapsed and a predetermined upper limit number of game balls have won the special electric prize device 32. That is. In addition, the number of round games in the opening / closing execution mode triggered by the jackpot result is the same for a fixed number of rounds regardless of the type of jackpot result triggered by the transition. Specifically, the upper limit number of round games is set to 15 rounds regardless of which jackpot result is obtained.

  Moreover, in this pachinko machine 10, a plurality of types of opening modes of the special electricity prize winning device 32 are set with different opening durations from when the special electricity prize winning device 32 is opened until it is closed. Specifically, a long time mode set to 29 seconds, which is a long open duration, and a short time mode set to 0.06 seconds, which is a short time shorter than the above long time, Is set.

  In the present pachinko machine 10, when the launch operation device 28 is operated by the player, the game ball launching mechanism 27 is driven so that one game ball is launched toward the game area PA every 0.6 seconds. Be controlled. In the round game, the upper limit number of end conditions is set to nine. Then, in the long time mode among the above open modes, the open duration time is set longer than the product of the game ball firing period and one round game. On the other hand, in the short-time mode, an opening continuation time is set that is shorter than the product of the game ball launch cycle and one round game, more specifically, shorter than the game ball launch cycle. Therefore, when the opening is performed once in the long-time mode, it is expected that the special electric prize winning device 32 will receive the maximum number of winnings in one round game. When the number of times is released, it is expected that no prize will be given to the special electric prize winning device 32 or that there will be about one even if a prize is generated.

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

  In addition, the number of opening / closing of the special electric prize device 32 in the high frequency winning mode and the low frequency winning mode, the number of round games, the opening duration for one opening, and the upper limit number in one round game are those in the high frequency winning mode. However, the value is not limited to the above value as long as the occurrence frequency of the winning to the special electricity winning device 32 is higher than the low-frequency winning mode until the opening / closing execution mode starts and ends. It is.

  The allocation destination of the jackpot result for the jackpot type counter C2 is stored in the main ROM 64 as a sorting table 64h as shown in FIG. And in the allocation table 64h, the low probability big hit result, the low winning high probability big hit result, and the most advantageous big hit result are set as the allocation destination of the big hit result when the big hit result is obtained.

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

  The low-winning high-probability jackpot result is a jackpot result in which the opening / closing execution mode becomes the low-frequency winning mode, and after the opening / closing execution mode ends, the success / failure lottery mode becomes the high probability mode and the support mode becomes the high-frequency support mode. is there. These high-probability mode and high-frequency support mode are continued until the lottery result in the success / failure lottery becomes a big hit state win and shifts to the big win state by that.

  The most advantageous jackpot result is a jackpot result in which the opening / closing execution mode becomes the high-frequency winning mode, and after the opening / closing execution mode ends, the winning / raising lottery mode becomes the high probability mode and the support mode becomes the high-frequency support mode. These high-probability mode and high-frequency support mode are continued until the lottery result in the success / failure lottery becomes a big hit state win and shifts to the big win state by that.

  Note that the normal game state in relation to each of the above-described game states refers to a state in which the success / failure lottery mode is the low probability mode and the support mode is the low frequency support mode, not the open / close execution mode. Moreover, it is good also as a structure in which the low prize-winning high probability hit result is not set as a game result. Further, in the opening / closing execution mode in the low winning and winning big hit result, the number of round games may be smaller than in the case of the low winning big hit result and the most advantageous big hit result.

  In the distribution table 64h, among the values of the jackpot type counter C2 of “0 to 29”, “0 to 9” corresponds to the low probability big hit result, and “10 to 14” is the low winning high probability big hit result. “15-29” corresponds to the most advantageous jackpot result.

  The distribution table 64h is provided with only one type so as to be common in any setting state of “setting 1” to “setting 6”. As a result, it is possible to prevent an advantage or disadvantage caused by the setting state of the pachinko machine 10 with respect to the distribution mode of the jackpot result, and a storage capacity for storing the distribution table 64h in the main ROM 64 in advance. Can be suppressed.

  In addition, it is good also as a structure from which the distribution aspect of a jackpot result differs according to the setting state of the pachinko machine 10. For example, a higher setting value may be configured to increase the probability of being distributed to the most advantageous big hit result, and a higher setting value may be configured to increase the probability of being distributed to the most advantageous big hit result or the low winning high probability winning result. In this case, the higher the set value, the higher the probability of entering the high probability mode after the jackpot result. Also, the higher the set value, the lower the probability that it will be assigned to the low winning high-accuracy result may be lowered. It is good also as a structure which can be distributed to a jackpot result. In this case, the higher the set value, the higher the probability that the opening / closing execution mode of the high-frequency winning mode will occur.

  Next, the reach random number counter C3 will be described. The reach random number counter C3 is, for example, incremented by 1 within a range of 0 to 238, and returns to “0” after reaching the maximum value. The pachinko machine 10 is set with an expected effect as a kind of display effect in the symbol display device 41. The expected effect includes a symbol display device 41 that can display a variation of symbols, and in a gaming machine in which a final stop result is an assignment corresponding result in a game round that results in a predetermined jackpot result, the symbol display device 41 This is a display state for making the player think that it is a variable display state that is likely to be the above-mentioned giving correspondence result at the stage before the stop result is derived and displayed after the symbol variable display is started. In addition, about the provision corresponding | compatible result, the combination of the symbol to which the same number was attached | subjected on one of the effective lines is stopped and displayed.

  In the expected effect, two types of reach display and a notice display for expecting the occurrence of reach display and the generation of the result of giving correspondence at a stage before the reach display occurs are set.

  In the reach display, a combination of reach symbols is displayed by displaying symbols for a part of a plurality of symbol sequences displayed on the display surface 41a of the symbol display device 41, and the remaining combinations in that state are displayed. A display state in which a variable display of symbols is displayed in the symbol row is included. In addition, in the state where the combination of reach symbols is displayed as described above, the variation of the symbols is displayed in the remaining symbol rows, and a predetermined character or the like is displayed as a moving image on the background screen, and the reach effect is performed. In addition, there are those that perform a reach effect by displaying a predetermined character or the like as a moving image on substantially the entire display surface 41a after reducing or not displaying a combination of reach symbols.

  The notice display includes a plurality of symbol strings in a situation where symbols are variably displayed in all symbol columns after the symbol variable display is started on the display surface 41a of the symbol display device 41. In the situation where the symbols are variably displayed in the symbol row, a mode in which the character is displayed separately from the symbols on the symbol row is included. Moreover, what makes a background screen the predetermined aspect different from the previous aspect, and what makes the symbol on a symbol row the predetermined aspect different from the previous aspect are also included. Such a notice display can occur in any game times when reach display is performed and when reach display is not performed, but the case where reach display is performed is higher than the case where reach display is not performed. It is set to occur with probability.

  The reach display is executed regardless of the value of the reach random number counter C3 in the game times in which the combination of the same symbols is finally stopped. In addition, the game times corresponding to the jackpot result in which the same symbol combination is not stopped and displayed are not executed regardless of the value of the reach random number counter C3. Further, in the game times corresponding to the losing result, it is executed when the reach random number counter C3 acquired at a predetermined timing with reference to the reach table stored in the main ROM 64 corresponds to the occurrence of reach display. .

  On the other hand, the determination as to whether or not to perform the notice display is performed not by the main controller 60 but by the sound emission controller 81. In this case, the sound emission control device 81 is more prone to generate a notice display in the game times corresponding to any of the jackpot results than the game times corresponding to the miss results, and displays a notice display with a low appearance rate. A lottery process for displaying a notice is executed so as to satisfy at least one of the conditions of being easily generated. Incidentally, the lottery result is reflected when the game display effect is executed on the symbol display device 41.

  Here, the probability that the reach display occurs in the game times that are the result of losing is the same in any of the setting states of “setting 1” to “setting 6”. Thereby, it becomes possible to prevent the advantage or disadvantage of the set state of the pachinko machine 10 from occurring with respect to the probability that the reach display is generated in the game times that are the result of losing. However, the present invention is not limited to this, and the higher the set value, the higher the probability that a reach display will occur in the game times that result in a miss.

  Next, the variation type counter CS will be described. For example, the variation type counter CS is incremented one by one within a range of 0 to 198, and returns to “0” after reaching the maximum value. The variation type counter CS is used when the main CPU 63 determines the display duration in the special symbol display section 37a and the symbol display duration in the symbol display device 41. The variation type counter CS is updated once every time a timer interrupt process (to be described later) is executed once, and is repeatedly updated within the remaining time until the next timer interrupt process is executed. Then, the buffer value of the variation type counter CS is acquired when the variation pattern is determined at the start of variation display in the special symbol display unit 37a and at the time of symbol variation start by the symbol display device 41.

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

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

  First, a power-on wait process is executed (step S101). In the power-on wait process, for example, the process waits without proceeding to the next process until a predetermined time for waiting (specifically, 1 second) elapses after the main process is activated. The operation start and initial setting of the symbol display device 41 are completed during the execution period of the power-on wait process. Thereafter, access to the main RAM 65 is permitted (step S102).

  Thereafter, it is determined whether or not the setting key insertion unit 68a is turned on (step S103). If the setting key insertion portion 68a has not been turned ON (step S103: NO), it is determined whether or not the reset button 68c has been pressed (step S104). When the reset button 68c is pressed (step S104: YES), each area of the main RAM 65 is “excluding the area where the setting value information indicating the setting state of the pachinko machine 10 is set in the main RAM 65. “0” is cleared, and initial setting is performed for the area where “0” is cleared (step S105). That is, when the supply of operating power to the pachinko machine 10 is started while pressing the reset button 68c without the setting key insertion unit 68a being turned on, the setting value information is the operation to the pachinko machine 10. The main RAM 65 is cleared while maintaining the state before the power supply is stopped, and initial setting is performed for the storage area where the clear processing is performed. As a result, it is possible to initialize other areas of the main RAM 65 without changing the set value. In step S105, the various registers of the main CPU 63 are also cleared after “0” is cleared.

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

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

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

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

  Thereafter, the process proceeds to the remaining process of steps S113 to S116. That is, the main CPU 63 is configured to periodically execute the timer interrupt process, but a remaining time occurs between one timer interrupt process and the next timer interrupt process. The remaining time varies depending on the processing completion time of each timer interrupt process, but the remaining processes in steps S113 to S116 are repeatedly executed using the irregular time. In this regard, it can be said that the remaining processes in steps S113 to S116 are non-periodic processes that are performed irregularly.

  In the remaining process, first, in step S113, an interrupt prohibition setting is performed to prohibit the generation of the timer interrupt process. In the subsequent step S114, a random number initial value updating process for updating the random number initial value counter CINI is executed, and in addition, a fluctuation counter updating process for updating the fluctuation type counter CS is executed in step S115. In these update processes, the current numerical information is read from the corresponding counter in the main RAM 65, the process of adding 1 to the read numerical information is executed, and then the process of overwriting the reading source counter is executed. In this case, each counter value is cleared to “0” when it exceeds the maximum value. Thereafter, in step S116, an interrupt permission setting for switching from a state in which the generation of the timer interrupt process is prohibited to a state in which it is permitted is performed. When the process of step S116 is executed, the process returns to step S113, and the processes of step S113 to step S116 are repeated.

  On the other hand, when the setting key insertion unit 68a is ON-operated (step S103: YES), the main RAM 65 also includes an area in which setting value information indicating the setting state of the pachinko machine 10 is set in the main RAM 65. All areas are cleared to “0” and initial setting is performed for the areas cleared to “0” (step S117). That is, when an operation for changing the setting state of the pachinko machine 10 is performed, all the areas of the main RAM 65 are cleared to “0” and cleared even if the reset button 68 c is not pressed. Initial setting is performed on the storage area where the processing is executed. Further, in step S117, various registers of the main CPU 63 are also cleared after “0” is cleared. Note that the present invention is not limited to this, and even if the operation for changing the setting state of the pachinko machine 10 is performed, if the reset button 68c is not pressed, the entire main RAM 65 A configuration may be adopted in which the clearing process is not performed but the clearing process is performed when an operation for changing the setting state of the pachinko machine 10 is performed and the reset button 68c is pressed.

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

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

  After that, a set value display start process is executed (step S202). In the setting value display start process, the third notification display device 69c is controlled to display the number “1” corresponding to “setting 1”. The manager of the game hall can grasp the current setting state of the pachinko machine 10 by checking the third notification display device 69c when changing the setting value.

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

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

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

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

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

  First, a power failure information storage process is executed (step S301). In the power failure information storage process, it is monitored whether or not a power failure signal corresponding to the occurrence of power interruption has been received from the power failure monitoring board 67. Become. In the power failure process, “1” is set to the power failure flag of the main RAM 65, and a checksum is calculated and the calculated checksum is stored.

  Thereafter, a lottery random number update process is executed (step S302). In the lottery random number update process, the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the universal utility release counter C4 are updated. Specifically, the current numerical information is sequentially read from the hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the general electric utility release counter C4, and a process of adding 1 to each of the read numerical information is executed. Later, a process of overwriting the reading source counter is executed. In this case, each counter value is cleared to “0” when it exceeds the maximum value. Thereafter, in step S303, random number initial value update processing is executed in the same manner as in step S114, and in step S304, variation counter update processing is executed in the same manner as in step S115.

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

  In step S307, port output processing is executed. In the port output process, when output information is set in the previous timer interrupt process, a process for performing output corresponding to the output information to the various drive units 32b and 34b is executed. For example, when the information for switching the special electric prize winning device 32 to the open state is set, the output of the drive signal to the special electric drive unit 32b is started, and when the information to be switched to the closed state is set. Stops the output of the drive signal. In addition, when the information for switching the general utility 34a of the second working port 34 to the open state is set, output of the drive signal to the general power drive unit 34b is started, and the closed state should be switched to. When the information is set, the output of the drive signal is stopped.

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

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

  Thereafter, a timer update process for updating the numerical information of a plurality of types of timer counters provided in the main RAM 65 is executed (step S310). In this case, the timer counter that is updated by subtracting the stored numerical information is handled in an integrated manner. However, both the updating of the subtracting timer counter and the updating of the adding timer counter are performed collectively. It is good also as a structure.

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

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

  Thereafter, the ordinary power control process is executed (step S314). In the ordinary map / electric power control process, when a winning to the through gate 35 is generated, a process for acquiring the retained information on the ordinary map side is executed and the retained information on the ordinary map side is stored. In addition, a release determination is performed on the hold information, and a process for performing an effect for a normal diagram is executed using the release determination as a trigger. Further, based on the result of the opening determination, a process for opening and closing the utility wire 34a of the second working port 34 is executed. In this case, if the support mode is the low frequency support mode, the corresponding process is executed, and if the support mode is the high frequency support mode, the corresponding process is executed. In the case of the opening / closing execution mode, even if the immediately preceding support mode is the high frequency support mode, the low frequency support mode is set.

  In subsequent step S315, based on the processing results of the immediately preceding steps S313 and S314, output information is set for reflecting the increase / decrease number of the hold information related to the special figure display unit 37a in the special figure hold display unit 37b. The output information for reflecting the increase / decrease number of the hold information related to the general map display unit 38a to the general map hold display unit 38b is set. In step S315, output information for updating the display content of the special figure display unit 37a is set based on the processing results of the immediately preceding steps S313 and S314, and the display content of the general map display unit 38a is set. Set the output information to be updated.

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

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

  First, hold information acquisition processing is executed (step S401). In the hold information acquisition process, it is determined whether or not a winning has occurred for the first operating port 33 or the second operating port 34. If a winning has occurred, the number of holds in the holding storage area 65a is the upper limit. It is determined whether or not the value is less than the value (“4” in the present embodiment). When the number of reserves is less than the upper limit value, 1 is added to the number of holds, and the numerical information of the hit random number counter C1, the big hit type counter C2, and the reach random number counter C3 updated in the previous step S302 is used for holding. Stored in the first reserved area among the empty reserved areas RE1 to RE4 of the area RE. In addition, when the winning to the 1st operation port 33 and the 2nd operation port 34 has generate | occur | produced simultaneously, within the range which performs the acquisition process of reservation information once, the process for acquiring the said reservation information is performed. Run multiple times. In addition, when a new acquisition of the hold information is performed, a corresponding acquisition time command is transmitted to the sound emission control device 81. When receiving the command, the sound emission control device 81 updates the display of the image indicating the number of the hold information on the symbol display device 41 to the display content corresponding to the increase of the hold information.

  Thereafter, the information of the special figure special electricity counter provided in the main side RAM 65 is read (step S402), and the special figure special electric address table provided in the main side ROM 64 is read (step S403). Then, a start address corresponding to the information of the special figure special electricity counter is obtained from the special figure special electricity address table (step S404), and jumps to the process indicated by the obtained start address among the processes of steps S406 to S412 (step S405). ). The special figure special power counter is a counter for the main CPU 63 to grasp which of the various processes in steps S406 to S412 should be executed, and the special figure special electric address table is the special figure special electric counter. Corresponding to the numerical information, the start address of the program for executing the processing of step S406 to step S412 is set.

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

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

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

  Thereafter, the success / failure determination process is executed with reference to the success / failure tables 64a to 64g read in step S503 (step S504). In the success / failure determination process, the information for determination of success / failure among the information stored in the execution area AE, that is, the numerical information related to the winning random number counter C1 is the jackpot numerical value information set in the determination tables 64a to 64g read in step S503. It is determined whether or not it matches.

  When the result of the success / failure determination process is a jackpot winning result (step S505: YES), the distribution determination process is executed (step S506). In the allocation determination process, information for allocation determination among the information stored in the execution area AE, that is, numerical information relating to the big hit type counter C2 is read. Then, with reference to the sorting table 64h provided in the main ROM 64, it is specified which jackpot result corresponds to the read numerical information related to the jackpot type counter C2. Specifically, which jackpot result corresponds to the low winning jackpot result, the low winning / high winning jackpot result, or the most advantageous jackpot result is specified.

  Thereafter, a stop result setting process for the jackpot result is executed (step S507). Specifically, information on the pattern mode to be finally stopped and displayed on the special figure display unit 37a in the game round related to the start of the change from the stop result table for the jackpot result stored in the main ROM 64 in advance. The specified information is written into the main RAM 65. In the stop result table for the jackpot result, information on the pattern mode to be stopped and displayed on the special figure display unit 37a is set differently for each type of the jackpot result.

  Thereafter, a flag setting process corresponding to the distribution determination result is executed (step S508). Specifically, the main-side RAM 65 is provided with a flag corresponding to each type of jackpot result. In step S508, among the flags corresponding to each type of jackpot result, the distribution determination process in step S506 is performed. “1” is set in the flag corresponding to the result.

  On the other hand, if it is determined in step S505 that the result is not a big win, a stop result setting process for a losing result is executed (step S509). Specifically, information on the pattern mode to be finally stopped and displayed on the special figure display unit 37a in the game round related to the start of the change is obtained from the stop result table for outliers stored in the main ROM 64 in advance. The specified information is written into the main RAM 65. The information on the pattern mode selected in this case is different from the information on the pattern mode selected in the case of the jackpot result.

  After executing one of the processes of step S508 and step S509, a process of grasping the duration of game times is executed (step S510). In such processing, numerical value information of the variation type counter CS is acquired. In addition, it is determined whether or not reach display occurs in the symbol display device 41 in the current game round. Specifically, it is determined that the reach display is generated when the game times related to the start of the current fluctuation is the low probability big hit result or the most advantageous big hit result. If the numerical information related to the reach random number counter C3 stored in the execution area AE is not the result of any jackpot, but is numerical information corresponding to the occurrence of reach, it is determined that reach display occurs.

  When it is determined that the reach display is generated, the game generation duration corresponding to the numerical value information of the current variation type counter CS is acquired with reference to the reach generation duration table stored in the main ROM 64. . On the other hand, if it is determined that the reach display does not occur, the continuation of the game times corresponding to the numerical information of the current variation type counter CS with reference to the reach non-occurrence duration table stored in the main ROM 64 Get the period. By the way, the duration of game times that can be acquired with reference to the reach non-occurrence duration table is different from the duration of game times that can be acquired with reference to the reach occurrence duration table.

  The duration of the game times when no reach occurs is set such that the duration of the game times is shortened as the number of pieces of holding information stored in the holding area RE increases. Also, in the situation where the support mode is the high-frequency support mode, a shorter duration of game times is selected compared to the case where the number of pending information is the same as in the situation where the support mode is the low-frequency support mode. A reach non-occurrence duration table is set. However, the present invention is not limited to this, and it may be configured such that the duration of the game times does not vary depending on the number of hold information and the support mode, and the above relationship may be reversed. Furthermore, the above-described configuration may be applied to the duration of game times when reach occurs. In addition, in the case of various jackpot results, a duration table may be set individually for each of the cases of outreach and non-reach outliers. In this case, distribution of the duration of game times according to each game result is performed.

  Thereafter, the information on the duration of the game times acquired in step S510 is set in a special figure special timer counter provided in the main RAM 65 (step S511). The update of the numerical information set in the special figure special electricity timer counter is executed in a timer update process (step S310). By the way, as the effects for the game times, the variation display of the symbols on the special symbol display unit 37a and the variation display of the symbols on the symbol display device 41 are carried out. In the state where the stop result is displayed (in the symbol display device 41, a state where a predetermined symbol combination is waited on the active line), the final stop is displayed for the final stop period (for example, 0.5 seconds). In this case, the duration of the game times acquired in step S510 is a total time for one game time.

  Thereafter, the variation command and the type command are transmitted to the sound emission control device 81 (step S512). The variation command includes information on the duration of game times. Here, as described above, the duration of game times acquired with reference to the reach non-occurrence duration table is different from the duration of game times acquired with reference to the reach occurrence duration table. Even if the change command does not include information on whether or not reach has occurred, the sound emission control device 81 can specify whether or not reach has occurred from information on the duration of game times. In this regard, it can be said that the change command includes information indicating whether or not reach has occurred. Note that the change command may include information that directly indicates whether or not reach has occurred. The type command includes game result information.

  When the sound emission control device 81 receives the change command and the type command from the main CPU 63, the display light emission unit 53, the speaker unit 54, and the symbol display device 41 execute effects for game times. In this case, the game round effect is performed in a manner corresponding to the contents of the change command and the type command. In addition, the symbol display device 41 displays a variation of the symbol as an effect for the game turn, and when the effect for the game turn ends, a combination of symbols corresponding to the result of the success / failure determination process and the distribution determination process is obtained. Stopped display.

  Thereafter, the display of the variation of the pattern in the special figure display unit 37a is started (step S513). Then, 1 is added to the special figure special electricity counter (step S514). In this case, since the numerical information of the special figure special power counter is “0” when the special figure variation start process is executed, the numerical information of the special figure special electric power counter is “1”. Thereafter, “1” is set to the eleventh output flag provided in the main RAM 65 (step S515). The eleventh output flag is a flag for the main CPU 63 to specify that the information output indicating that the game is started should be executed to the management IC 66.

  Returning to the description of the special figure special electric control process (FIG. 52), in step S407, the special figure fluctuation process is executed. In the special figure changing process, it is determined whether it is during the game time duration and before the final stop display. If it is before the final stop display, the display mode of the pattern in the special figure display unit 37a is regulated. The process for changing automatically is executed. When it is time to display the final stop, the numerical information of the special figure special counter is incremented by 1 so that the numerical information of the counter corresponds to the special figure changing process from the one corresponding to the special figure changing process. Update to stuff. In the present embodiment, the final stop command is not transmitted from the main CPU 63 to the sound emission control device 81.

  In step S408, a special figure finalizing process is executed. In the special figure determination process, the display form of the pattern in the special figure display unit 37a is set to a display form corresponding to the lottery result of the current game time. Further, in the special figure determination process, it is determined whether or not the final stop period has elapsed, and if the period has elapsed, it is determined whether or not the transition to the opening / closing execution mode occurs. When the transition to the opening / closing execution mode does not occur, the numerical information of the special figure special electricity counter is cleared to “0”. When the transition to the open / close execution mode occurs, the numerical information of the special figure special counter is incremented by 1, so that the numerical information of the counter is changed from the one corresponding to the special figure determination process to the special electric figure start process. Update.

  In step S409, a special electricity start process is executed. In the special electricity start process, if the process for starting the opening period in the current opening / closing execution mode has not been executed yet, the opening period setting process is executed. Also, an opening command is transmitted to the sound emission control device 81. The voice light emission control device 81 receives the opening command so that the display light emitting unit 53, the speaker unit 54, and the symbol display device 41 execute the opening effect. When the opening period has elapsed, a start process for starting the first round game is executed. In the start process, the special game winning device 32 is set to the open state and the end condition of the round game is set. In setting the end condition, an upper limit duration is set in the case where the special electric prize device 32 is kept open in the first round game of this time, and the special electric prize device 32 can be awarded in the first round game of this time. The upper limit number of game balls is set in a winning number counter provided in the main side RAM 65.

  In step S410, a special electricity release process is executed. In the special electric release opening process, it is determined whether or not a round game end condition is satisfied. If the end condition is satisfied, the special electricity prize winning device 32 is closed. If the round game ended this time is not the last round game, the numerical information of the special figure special electricity counter is incremented by 1 to change the numerical information of the counter from the one corresponding to the special electric release opening processing. If the round game ended this time is the last execution round game, the numerical information of the special figure special counter is added by 2 so that the numerical information of the counter corresponds to the special electric release open processing. Update to the one corresponding to the special electricity termination process.

  In step S411, a special electric power closing process is executed. In the special electricity closing process, it is determined whether or not the interval period between round games has elapsed. The interval period is set when the previous round game ends. When the interval period elapses, the special electric prize winning device 32 is set in an open state and a round game end condition is set. Then, by subtracting 1 from the numerical information of the special figure special electric counter, the numerical information of the counter is updated from the one corresponding to the special electric power closing process to the one corresponding to the special electric power closing process.

  In step S412, special electric power end processing is executed. In the special electric power end processing, when the processing for starting the ending period in the current opening / closing execution mode has not been executed yet, the ending period (for example, 5 seconds) is set and the ending command is transmitted to the sound emission control device 81. . The voice light emission control device 81 receives the ending command so that the display light emission unit 53, the speaker unit 54, and the symbol display device 41 execute the ending effect. When the ending period has elapsed, each of the success / failure lottery mode and the support mode after the end of the opening / closing execution mode is set to a mode corresponding to the jackpot result that triggered the opening / closing execution mode of this time.

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

  The main CPU 63 is provided with an input port 63a. The input port 63a is configured as an 8-bit parallel interface so that eight types of signals can be handled simultaneously. An area for storing “0” or “1” information according to the voltage of each signal is provided in a one-to-one correspondence with each terminal. That is, the area includes 0th bit D0 to 7th bit D7. Further, more than eight types of signals are input to the input port 63a. In order to limit the number of simultaneously input targets to eight types, a signal group to be input to the input port 63a depends on the driver IC. It is switched through switching control.

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

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

  FIG. 15 is a flowchart showing the entrance detection process executed in step S309 of the timer interrupt process (FIG. 11).

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

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

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

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

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

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

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

  When it is confirmed that the situation in which the information “0” is stored in the seventh bit D7 is switched to the situation in which the information “1” is stored, one game ball is detected by the gate detection sensor 49a. It is determined that it has been detected (step S624: YES). In this case, “1” is set to the gate winning flag provided in the main RAM 65 (step S625). The gate winning flag is a flag for the main CPU 63 to specify that one game ball has entered the through gate 35. In the ordinary power transmission control process (step S314) of the timer interruption process (FIG. 11), it is confirmed that “1” is set in the gate winning flag, so that the ordinary power stored in the general power reservation area 65c is stored. Processing for storing the current numerical information of the general utility release counter C4 in the general electric power reservation area 65c as general information holding information on condition that the number of reserved information on the side is less than the upper limit number of four Execute. It is confirmed that “1” is set in the gate winning flag in the ordinary power control process (step S314), and the gate winning flag is cleared to “0” when processing corresponding to the confirmation is executed.

  Since the timer interrupt process (FIG. 11) is started at a cycle of 4 milliseconds as already described, when one game ball is detected by one ball detection sensor 42a to 49a, The main CPU 63 specifies that one game ball is detected by the ball detection sensors 42a to 49a in a situation where the ball detection sensors 42a to 49a continue to detect the one game ball. It is done at. Therefore, it is sufficient to provide one each of the first to seventh output flags.

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

  The payout control device 77 includes an MPU 91. The MPU 91 incorporates a payout-side ROM 93, a payout-side RAM 94, an interrupt circuit, a timer circuit, a data input / output circuit, and the like in addition to a payout-side CPU 92 that is an arithmetic processing unit including a control unit and a calculation unit.

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

  The payout-side RAM 94 is a memory (that is, a volatile storage unit) that requires an external power supply for storage and holding such as SRAM and DRAM, and is used for both reading and writing. The payout side RAM 94 can be randomly accessed, and when compared with the same data capacity, the payout side RAM 94 requires a faster time for reading than the payout side ROM 93. The payout-side RAM 94 temporarily stores various data for execution of the control program stored in the payout-side ROM 93.

  The payout side CPU 92 can perform bidirectional communication with the main side CPU 63. When the payout side CPU 92 receives a prize ball command from the main side CPU 63, the payout side CPU 92 drives and controls the payout device 76 so that the number of game balls corresponding to the prize ball command is paid out. Further, the payout side CPU 92 monitors whether or not the game ball can be normally paid out, and if the payout side CPU 92 specifies that the game ball cannot be normally discharged, The payout device 76 is stopped even in a situation where the information on the number of unpaid prize balls is stored. Further, the payout side CPU 92 transmits a payout limit command indicating that the payout is not normally possible to the main CPU63. When the main CPU 63 receives the payout restriction command, the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 perform notification indicating that it is not possible to pay out the game balls normally. In this manner, a notification command is transmitted to the sound emission control device 81. As a state where it is not possible to normally pay out game balls, a full state where the lower plate 56a is filled with game balls, a state where no balls are refilled in the tank 75, a state where no balls are replenished, and a payout device 76 There are a payout abnormal state in which the machine does not operate normally, a main body open state in which the gaming machine main body 12 is opened from the outer frame 11, and a front door open state in which the front door frame 14 is opened from the inner frame 13. .

  A full tank detection sensor (not shown) is provided in the middle of the game ball passage leading from the payout device 76 to the lower tray 56a, and the detection result of the full tank detection sensor is input to the payout CPU 92. The payout side CPU 92 specifies that the game ball is fully filled when the game ball is continuously detected by the full tank detection sensor, and the state where the game ball is continuously detected by the full tank detection sensor is released. In this case, it is determined that the full tank state has been released.

  A ball non-detection sensor (not shown) is provided in the middle of the game ball passage leading from the tank 75 to the payout device 76, and the detection result of the ball non-detection sensor is input to the payout side CPU 92. The payout-side CPU 92 specifies that the game ball is not detected when the game ball is not continuously detected by the ball non-detection sensor, and when the game ball is not continuously detected by the ball detection sensor is released. Identifies that the ballless state has been released.

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

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

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

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

  First, a full tank process is executed (step S701). In the full tank process, as described above, it is determined whether or not the tank is full based on the detection result of the full tank detection sensor. And a command indicating that the tank is full is transmitted to the main CPU 63. When the full tank state is released, a process for enabling the game ball to be paid out is executed, and a command indicating that the full tank state has been released is transmitted to the main CPU 63.

  Thereafter, a ball useless process is executed (step S702). In the ball-free process, as described above, it is determined whether or not the ball is in the non-ball state based on the detection result of the ball-free detection sensor. At the same time, a command indicating that there is no ball is transmitted to the main CPU 63. In addition, when the no-ball state is released, a process for enabling the game ball to be paid out is executed, and a command indicating that the no-ball state is released is transmitted to the main CPU 63.

  Thereafter, a payout abnormality monitoring process is executed (step S703). In the payout abnormality monitoring process, as described above, it is determined whether or not the payout abnormality state is based on the detection result of the payout detection sensor, and if it is in the payout abnormal state, the process of stopping payout of the game ball is executed. At the same time, a command indicating a payout abnormality state is transmitted to the main CPU 63. In addition, when the payout abnormal state is canceled, a process for enabling payout of the game ball is executed, and a command indicating that the payout abnormal state has been canceled is transmitted to the main CPU 63.

  Thereafter, a front door opening monitoring process is executed (step S704). In the front door opening monitoring process, as described above, it is determined whether or not the front door frame 14 is in the open state based on the detection result of the front door opening sensor 95. When the front door frame 14 is in the open state, A process for stopping the payout of game balls is executed, and a front door opening command is transmitted to the main CPU 63. In addition, when the front door frame 14 is closed, a process for allowing the game ball to be paid out is executed, and a front door closing command is transmitted to the main CPU 63.

  Thereafter, the main body opening monitoring process is executed (step S705). In the main body opening monitoring process, as described above, it is determined whether or not the gaming machine main body 12 is in an open state based on the detection result of the main body opening sensor 96. If the gaming machine main body 12 is in the open state, Is executed, and a main body release command is transmitted to the main CPU 63. Further, when the gaming machine main body 12 is closed, a process for enabling the payout of the game ball is executed, and a main body closing command is transmitted to the main CPU 63.

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

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

  As shown in FIG. 2, the back pack unit 15 is provided with an external terminal plate 97. The external terminal plate 97 is provided with a large number of external terminals, which are some external terminals and a plurality of external terminals are electrically connected to the main CPU 63 and some external terminals. A plurality of external terminals are electrically connected to the payout side CPU 92. Since the main CPU 63 and the payout CPU 92 are electrically connected to the external terminal plate 97 as described above, the main CPU 63 and the payout CPU 92 send information to the hall computer HC as shown in FIG. It is possible to output.

  One external terminal of the external terminal plate 97 is electrically connected to the front door opening sensor 95, and one external terminal of the external terminal plate 97 is electrically connected to the main body opening sensor 96. In detail, the signal connection board 98 is provided in the middle of the signal path from the front door opening sensor 95 to the payout CPU 92 with regard to the configuration of this electrical connection. The signal relay board 98 is provided with a branch path SL2 branched from the signal path SL1 from the front door opening sensor 95 to the payout CPU 92. The branch path SL2 is connected to an external terminal for opening the front door in the external terminal plate 97. Therefore, an electrical signal corresponding to the detection result of the front door opening sensor 95 is input not only to the payout-side CPU 92 but also to an external terminal for opening the front door on the external terminal plate 97. Thus, a signal indicating whether or not the front door frame 14 is in an open state can be externally output to the hall computer HC without being controlled by the payout side CPU 92.

  In detail, the signal relay board 98 is provided with a branch path SL4 that branches from the signal path SL3 from the main body open sensor 96 to the payout CPU 92. The branch path SL4 is connected to an external terminal for opening the main body of the external terminal plate 97. Therefore, the electrical signal corresponding to the detection result in the main body opening sensor 96 is not only input to the payout side CPU 92 but also input to the external terminal for opening the main body on the external terminal plate 97. As a result, a signal indicating whether or not the gaming machine main body 12 is in an open state can be externally output to the hall computer HC without being controlled by the payout side CPU 92.

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

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

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

In the hall computer HC, in accordance with various information received from the pachinko machine 10 through the external terminal board 97, it is possible to grasp the execution mode of the game ball payout in the pachinko machine 10. For example,
-A payout rate that is the ratio of the number of game balls paid out until 100 game balls are discharged from the game area PA of the pachinko machine 10-A game play state that is not in the opening / closing execution mode and the high frequency support mode Ball ratio (hereinafter referred to as “B”)
-Number of games played in the opening / closing execution mode-Number of games played in the high frequency support mode-Number of game times executed until 100 game balls are discharged from the game area PA of the pachinko machine 10 "S")
B-S × “number of winning balls for winning in the first operating port 33 and the second operating port 34”
-Number of game balls that enter the first operating port 33 before 100 game balls are discharged from the game area PA of the pachinko machine 10 (hereinafter, this ratio is referred to as "S1")
The number of game balls that have entered the second operating port 34 before 100 game balls are discharged from the game area PA of the pachinko machine 10 (hereinafter, this ratio is referred to as “S2”).
B- (S1 × “the number of winning balls for winning in the first operating port 33” + S2 × “the number of winning balls for winning in the second operating port 34”)
The occurrence probability of the opening / closing execution mode per unit game time, the occurrence probability of the high frequency support mode per unit game time, and the like are calculated. Thereby, it becomes possible to manage the entrance mode of the game ball in the game area PA of the pachinko machine 10 in the hall computer HC. The number of prize balls is the number of game balls to be paid out when one game ball enters the corresponding entrance part.

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

  As described above, the MPU 62 of the main control device 60 includes the main CPU 63, the main ROM 64, the main RAM 65, and the management IC 66. In addition to the above, the MPU 62 includes the I / F 101 and the reading terminal 68d described above.

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

  The management IC 66 includes a management-side I / F 111, a management-side CPU 112, a management-side ROM 113, a management-side RAM 114, an RTC 115, a correspondence memory 116, a history memory 117, a calculation result memory 131, It has. Each of these devices is connected to be capable of bidirectional communication through an internal bus 66a provided in the management IC 66.

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

  The management side CPU 112 is an arithmetic processing device including a control unit and an arithmetic unit. The management ROM 113 is a memory (that is, non-volatile storage means) that does not require external power supply for storing and holding, such as a NOR flash memory and a NAND flash memory, and is used as a read-only memory. The management ROM 113 stores various control programs executed by the management CPU 112 and fixed value data. The management-side RAM 114 is a memory (that is, a volatile storage unit) that requires an external power supply for storing and holding, such as SRAM and DRAM, and is used for both reading and writing. The management-side RAM 114 can be accessed at random, and when compared with the same data capacity, the management-side RAM 114 requires a faster time for reading than the management-side ROM 113. The management-side RAM 114 temporarily stores various data for the execution of the control program stored in the management-side ROM 113.

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

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

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

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

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

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

  A first signal corresponding to the detection result of the first winning port detection sensor 42a is input to the first buffer 122a. In this case, the main CPU 63 outputs a first signal at the LOW level when no new game ball is detected by the first winning opening detection sensor 42a, and one game is output by the first winning opening detection sensor 42a. When a sphere is detected, a HI level first signal is output for a specific period. This specific period is a period sufficient for the management CPU 112 to specify that the HI level first signal is input to the first buffer 122a.

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

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

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

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

  A sixth signal corresponding to the detection result of the second working port detection sensor 47a is input to the sixth buffer 122f. In this case, the main CPU 63 outputs a sixth signal at the LOW level when no new game ball is detected by the second operation port detection sensor 47a, and one game is output by the second operation port detection sensor 47a. When a sphere is detected, a HI level sixth signal is output for a specific period. This specific period is a period sufficient for the management CPU 112 to specify that the HI level sixth signal is input to the sixth buffer 122f.

  A seventh signal corresponding to the detection result of the out port detection sensor 48a is input to the seventh buffer 122g. In this case, the main CPU 63 outputs a seventh signal at the LOW level when no new game ball is detected by the out port detection sensor 48a, and one game ball is detected by the out port detection sensor 48a. In this case, the seventh signal at the HI level is output over a specific period. This specific period is a period sufficient for the management side CPU 112 to specify that the HI level seventh signal is input to the seventh buffer 122g.

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

  A ninth signal corresponding to whether or not the high frequency support mode is in progress is input to the ninth buffer 122i. In this case, the main CPU 63 continuously outputs the ninth signal at the LOW level when the high frequency support mode is not set, and continuously outputs the ninth signal at the HI level when the high frequency support mode is set.

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

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

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

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

  The twelfth buffer 122l, the thirteenth buffer 122m, and the fourteenth buffer 122n can be input with signals from the main CPU 63, but the pachinko machine 10 is blank to which normal signals are not input. As described above, by providing a larger number of buffers 122a to 122p than the types of signals output from the main CPU 63 to the management IC 66 in the pachinko machine 10 as the input port 121 of the management I / F 111, It is possible to divert the management IC 66 to a different model from the pachinko machine 10. Thereby, the versatility of the management IC 66 can be enhanced. Incidentally, signal paths 118a to 118p are formed between the main CPU 63 and the first to sixteenth buffers 122a to 122p so as to correspond to the first to sixteenth buffers 122a to 122p on a one-to-one basis. However, the present invention is not limited to this, and the signal paths 118l to 118n may not be formed between the buffers 122l to 122n to be blanked.

  The setting value update signal input to the fifteenth buffer 122o and the output instruction signal input to the sixteenth buffer 122p are determined at the design stage of the management IC 66 and receive an instruction from the main CPU 63. The management CPU 112 can specify that the set value update signal is input to the fifteenth buffer 122o and that the output instruction signal is input to the sixteenth buffer 122p. On the other hand, what kind of signal is input to the first to fourteenth buffers 122a to 122n is not determined at the design stage of the management IC 66, and the type of these signals receives an instruction from the main CPU 63. This is specified by the management CPU 112. Although the details of the types of these signals in the management-side CPU 112 will be described later, when control is started in the main-side CPU 63 and the management-side CPU 112 with the start of the supply of operating power to the MPU 62, the management-side CPU 112 changes from the main-side CPU 63 to the management-side CPU 112. This is done by sending a type identification command to In this case, the information on the types of various signals provided by the type identification command is stored in the correspondence memory 116, and when the various types of signals are specified by the management CPU 112 in a situation where operating power is supplied. Information stored in the correspondence relationship memory 116 is referred to.

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

  In the first correspondence relationship area 123a, information indicating the general winning opening 31 is stored as information for the management CPU 112 to specify the type of signal input to the first buffer 122a. In addition, information indicating the number of game balls to be paid out when one game ball enters the general prize opening 31 is included in the first correspondence area 123a together with information indicating that the game is a general prize opening 31 (10 pieces). Stored. In the second correspondence area 123b, information indicating the general winning opening 31 is stored as information for specifying the type of signal input to the second buffer 122b by the management CPU 112. The second correspondence area 123b also includes information indicating the number of game balls to be paid out when one game ball enters the general prize opening 31 together with information indicating that the game is a general prize opening 31 (10 pieces). Stored. In the third correspondence area 123c, information indicating the general winning opening 31 is stored as information for the management CPU 112 to specify the type of signal input to the third buffer 122c. In addition, in the third correspondence area 123c, information indicating the number of game balls to be paid out when one game ball enters the general prize opening 31 is included along with information indicating that it is the general prize opening 31 (10 pieces). Stored.

  In the fourth correspondence area 123d, information indicating the special prize winning device 32 is stored as information for the management CPU 112 to specify the type of signal input to the fourth buffer 122d. The fourth correspondence area 123d also includes information indicating the number of game balls to be paid out when one game ball enters the special electricity prize device 32, as well as information indicating that the special electricity prize device 32 is present (15). Stored. In the fifth correspondence area 123e, information indicating the first working port 33 is stored as information for the management CPU 112 to specify the type of signal input to the fifth buffer 122e. In addition, information indicating the number of game balls to be paid out when one game ball enters the first operation port 33 together with information indicating the first operation port 33 in the fifth correspondence area 123e (one) ) Is also stored. In the sixth correspondence area 123f, information indicating the second working port 34 is stored as information for specifying the type of signal input to the sixth buffer 122f by the management CPU 112. In addition, in the sixth correspondence area 123f, information indicating the number of game balls to be paid out when one game ball enters the second operation port 34 together with information indicating the second operation port 34 (one piece). ) Is also stored. In the seventh correspondence area 123g, information indicating the out port 24a is stored as information for the management CPU 112 to specify the type of signal input to the seventh buffer 122g.

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

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

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

  In addition, every time a signal corresponding to storage of history information is output to the first to fourteenth buffers 122a to 122n, information for recognizing the signal type is not output, but the signal type is recognized in advance. Information for specifying the type of signal input to the first to fourteenth buffers 122a to 122n on the management side CPU 112 based on the output information is stored in the correspondence memory 116. This is a configuration. As a result, in comparison with the configuration in which information for recognizing the type of the signal is output each time the first to fourteenth buffers 122a to 122n output a signal corresponding to the storage of the history information, The amount of information output from the side CPU 63 to the management side CPU 112 can be suppressed.

  The output of information for specifying the type of signal input to the first to fourteenth buffers 122a to 122n by the management CPU 112 is performed when the supply of operating power is started. Thereby, in the situation where a game is started in the pachinko machine 10, it becomes possible for the management-side CPU 112 to specify the type of signal input to the first to fourteenth buffers 122a to 122n.

  Information setting that the set value update signal is input to the fifteenth buffer 122o and information setting that the output instruction signal is input to the sixteenth buffer 122p are performed at the design stage of the management IC 66. As a result, the 15th buffer 122o and the 16th buffer 122p are used for the set value update signal and the output instruction signal that are surely used not only for the pachinko machine 10 but also for other types of pachinko machines that use the management IC 66. Therefore, it is possible to omit the process for specifying the type of the signal input to. Therefore, it is possible to suppress the processing load of processing for specifying the type of such signal.

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

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

  Specifically, regarding the correspondence information stored in the history information storage area 125, the first to seventh buffers 122a to 122g receive signals corresponding to the detection results of the incoming ball detection sensors 42a to 48a as described above. Therefore, information corresponding to the types of the incoming detection sensors 42a to 48a is stored in the first to seventh correspondence areas 123a to 123g in the correspondence memory 116. More specifically, information corresponding to the type of the entrance portion corresponding to each of the entrance detection sensors 42a to 48a is stored in the first to seventh correspondence areas 123a to 123g. As already described in the pachinko machine 10, the first to third winning opening detection sensors 42 a to 44 a detect game balls that have entered the general winning opening 31. The first to third correspondence areas 123a to 123c corresponding to the detection sensors 42a to 44a each store information indicating that it is the general winning opening 31. The fourth correspondence area 123d stores information indicating that it is the special prize winning device 32, and the fifth correspondence area 123e stores information indicating that it is the first operation port 33. In the sixth correspondence area 123f, information indicating the second operation port 34 is stored, and in the seventh correspondence area 123g, information indicating the out port 24a is stored. When the buffer 122a to 122n that is the information storage trigger this time is any one of the first to seventh buffers 122a to 122g, the information on the type of the ball entry part corresponding to the buffers 122a to 122g is first to first. The information is read from any one of the seventh correspondence relationship areas 123a to 123g, and the read information on the type of the ball-entry part is stored as it is in the area for storing the correspondence information in the history information storage area 125.

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

  As described above, the main CPU 63 continuously outputs the eighth signal at the LOW level in the situation that is not in the opening / closing execution mode, and continuously outputs the eighth signal at the HI level in the situation in the opening / closing execution mode. The side CPU 112 specifies that the opening / closing execution mode has started when the eighth signal changes from the LOW level to the HI level, and specifies that the opening / closing execution mode has ended when the eighth signal changes from the HI level to the LOW level. It becomes possible. Then, in both cases where the eighth signal changes from the LOW level to the HI level and when the eighth signal changes from the HI level to the LOW level, the management CPU 112 is triggered to store the correspondence information in the history information storage area 125. Identifies That is, when the eighth signal changes from the LOW level to the HI level, the history information storage area 125 includes not only the information indicating the opening / closing execution mode read from the eighth correspondence area 123h but also the start information. Is stored in the area for storing the correspondence information. Further, when the eighth signal changes from the HI level to the LOW level, not only the information indicating that it is the opening / closing execution mode read from the eighth correspondence area 123h but also the end information together with the history information storage area 125 Is stored in the area for storing the correspondence information.

  As described above, the main CPU 63 continuously outputs the ninth signal at the LOW level in the situation that is not the high frequency support mode, and continuously outputs the ninth signal at the HI level in the situation that is the high frequency support mode. The management CPU 112 identifies that the high frequency support mode has started when the ninth signal changes from LOW level to HI level, and ends the high frequency support mode when the ninth signal changes from HI level to LOW level. It is possible to specify that Then, in both cases where the ninth signal changes from the LOW level to the HI level and when the ninth signal changes from the HI level to the LOW level, the management CPU 112 is triggered to store the correspondence information in the history information storage area 125. Identifies That is, when the ninth signal changes from the LOW level to the HI level, not only the information indicating the high-frequency support mode read from the ninth correspondence area 123i but also the start information together with the history information storage area It stores in the area for storing 125 correspondence information. When the ninth signal changes from the HI level to the LOW level, the history information storage area includes not only the information indicating the high frequency support mode read from the ninth correspondence area 123i but also the end information. It stores in the area for storing 125 correspondence information.

  As described above, the main CPU 63 continuously outputs the LOW level tenth signal when the front door frame 14 is in the closed state, and outputs the HI level tenth signal when the front door frame 14 is in the open state. In order to continuously output, the management side CPU 112 specifies that the front door frame 14 is opened when the tenth signal changes from the LOW level to the HI level, and when the tenth signal changes from the HI level to the LOW level. However, it is possible to specify that the front door frame 14 is closed. The management CPU 112 is triggered to store the corresponding information in the history information storage area 125 both when the tenth signal changes from the LOW level to the HI level and when the tenth signal changes from the HI level to the LOW level. Identifies That is, when the tenth signal changes from the LOW level to the HI level, the history information is stored together with not only the information indicating that it is the front door frame 14 read from the tenth correspondence area 123j but also the opening start information. The correspondence information of the area 125 is stored in the area for storing. Further, when the tenth signal changes from the HI level to the LOW level, history information is stored together with not only the information indicating that it is the front door frame 14 read from the tenth correspondence area 123j but also the opening end information. The correspondence information of the area 125 is stored in the area for storing.

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

  The history information storage area 125 can store all the history information generated during the ten consecutive business days when game balls are continuously fired in the pachinko machine 10 from opening to closing. It is provided for several minutes. For example, if history information is generated 60000 times a day, 600000 or more history information storage areas 125 are provided. As a result, all history information can be stored and retained in the history memory 117 for at least 10 days.

  The history memory 117 includes a pointer area 126 in addition to the history area 124. The pointer area 126 stores information for the management CPU 112 to specify pointer information that is currently written in the history memory 117. Specifically, at the shipping stage of the pachinko machine 10, information for designating pointer information of “0” as a write target is set in the pointer area 126. Each time one piece of history information is newly stored in the history information storage area 125, the information in the pointer area 126 is updated so that the value of the pointer information to be written is incremented by one. When the history information is stored in the history information storage area 125 corresponding to the last-order pointer information and the last-order pointer information is to be written, the pointer is set so that the pointer information “0” becomes the write-target. The information in the service area 126 is updated. As a result, when there is an opportunity to store history information exceeding the number of storable history information, new history information is overwritten in order from the history information storage area 125 in which old history information is stored. Become.

  When the history information is read from the history memory 117 by the external device, the history information storage area 125 is all cleared to “0” and the pointer information “0” is to be written. The information in the pointer area 126 is updated. As a result, it is possible to prevent history information that has been read once from being read again.

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

  First, “14” is set in the recognition output counter provided in the main RAM 65 (step S801). The recognition output counter is a remaining information output for causing the management side CPU 112 to recognize which type of signal the first to fourteenth buffers 122a to 122n of the input port 121 in the management side I / F 111 correspond to. Is a counter for the main CPU 63 to specify the required number of times. As described above, 14 of the first to fourteenth buffers 122a to 122n are to be recognized as signal types, so “14” is set in the recognition output counter.

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

  Thereafter, the type identification command corresponding to the current value of the recognition output counter of the main RAM 65 is read from the main ROM 64 (step S803). In this case, the first buffer 122a becomes the signal type setting target first, and then the n + 1 buffer becomes the signal type setting target next to the nth buffer, so as to correspond to the first to fourteenth buffers 122a to 122n. The signal type recognition setting is performed. Therefore, if the recognition output counter is “14” to “12”, the type identification command indicating the general winning opening 31 and the number of prize balls is read. If the recognition output counter is “11”, the special electric prize is received. The type identification command indicating the device 32 and the number of prize balls is read. If the output counter for recognition is “10”, the type identification command indicating the first operating port 33 and the number of prize balls is read. If the recognition output counter is “9”, it is the second operation port 34 and the type identification command indicating the number of prize balls is read. If the recognition output counter is “8”, it is determined that the output port 24a is. If the recognition output counter is “7”, the type identification command indicating the open / close execution mode is read, and the recognition output counter If “6”, the type identification command indicating the high-frequency support mode is read, and if the recognition output counter is “5”, the type identification command indicating the front door frame 14 is read, and the recognition output counter is read. If “4”, the type identification command indicating that the game is played is read, and if the recognition output counter is “3” to “1”, the type identification command indicating that it is blank is read.

  Thereafter, output processing of the read type identification command is executed (step S804). The type identification command has an 8-bit data capacity like the identification start command, and data of each bit is input to the first to eighth buffers 122a to 122h as the first to eighth signals, respectively. In the output process of the identification type command, the output state of the ninth signal is switched to the HI level at the timing when the output of the identification type command is started in order to make the management CPU 112 recognize that the new command has been transmitted. The output period of the identification type command and the period of maintaining the output state of the ninth signal at the HI level are set to a period sufficient for the management CPU 112 to recognize the output state of the identification type command and the ninth signal. Has been. By receiving the identification type command, the management-side CPU 112 corresponds to the identification type command in the corresponding relationship areas 123a to 123n corresponding to the buffer to be set this time among the first to fourteenth buffers 122a to 122n. Store information to be used.

  Thereafter, 1 is subtracted from the value of the recognition output counter in the main RAM 65 (step S805), and it is determined whether or not the value of the recognition output counter after the 1 subtraction is “0” (step S806). If the value of the recognition output counter is 1 or more (step S806: NO), a process for outputting a type identification command corresponding to the value of the recognition output counter after 1 subtraction is executed (steps S803 and S803). Step S804).

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

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

  First, it is determined whether an identification start command has been received from the main CPU 63 (step S901). When the identification start command has not been received (step S901: NO), after the setting update recognition process is executed (step S902), the process returns to step S901. In the process for recognizing the setting update, details will be described later, but when the main CPU 63 performs a new setting of the setting state of the pachinko machine 10, a corresponding process is executed.

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

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

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

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

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

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

  Thereafter, the output of the first type identification command using the first to eighth signals is started at the timing t4 as shown in FIG. At the timing t4, as shown in FIG. 24B, the output state of the ninth signal is changed from the LOW level to the HI level. Thereafter, at the timing t5 when the output of the type identification command is continued, the output state of the ninth signal is changed from the HI level to the LOW level as shown in FIG. The management side CPU 112 identifies that the command is transmitted from the main side CPU 63 by confirming that the output state of the ninth signal has been changed from the HI level to the LOW level. By confirming the information, the contents of the command received from the main CPU 63 are grasped. In this case, since the first type identification command has been received, the management CPU 112 executes the correspondence setting process as shown in FIG. In the correspondence setting process, information indicating the general winning opening 31 and information on the number of winning balls are stored in the first correspondence relationship area 123a of the correspondence memory 116. Thereafter, the output of the type identification command is stopped at the timing of t6 as shown in FIG.

  After that, at the timings t7 to t9, t10 to t12, t13 to t15, and t16 to t18, respectively, Correspondence setting processing corresponding to the type identification command output from the side CPU 63 is executed by the management side CPU 112. In this case, the correspondence setting process corresponding to the fourteenth type identification command is completed from the timing t16 to the timing t18.

  After that, at the timing of t19, as shown in FIG. 24A, the output of the identification end command using the first to eighth signals is started. In addition, at the timing of t19, as shown in FIG. 24B, the output state of the ninth signal is changed from the LOW level to the HI level. Thereafter, at the timing t20 when the output of the identification end command is continued, the output state of the ninth signal is changed from the HI level to the LOW level as shown in FIG. The management side CPU 112 identifies that the command is transmitted from the main side CPU 63 by confirming that the output state of the ninth signal has been changed from the HI level to the LOW level. By confirming the information, the contents of the command received from the main CPU 63 are grasped. In this case, since the identification end command has been received, the identification state of the management side CPU 112 ends at the timing of t20 as shown in FIG. Thereafter, the output of the identification end command is stopped at the timing of t21 as shown in FIG.

  In order to instruct the management CPU 112 to store the history information, the management CPU 112 recognizes whether the command is output using the ninth signal as described above. Even if the command is output using the first to eighth signals (that is, the first to eighth signal paths) used, it is clearly shown to the management CPU 112 that the command is being output. It can be recognized.

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

  First, “11” is set in the management target counter provided in the main RAM 65 (step S1001). The management target counter specifies in the main CPU 63 whether or not there is a management target that is not specified as to whether or not the signal output state to the management CPU 112 should be changed in the current management output process. At the same time, it is a counter for the main CPU 63 to specify which of the management targets the signal output state to the management CPU 112 should be changed. The management target to be specified by the main CPU 63 as to whether or not the signal output state to the management CPU 112 should be changed in one management output process is seven entrance detection sensors 42a to 48a, There are a total of 11 items: presence / absence of execution of the opening / closing execution mode, presence / absence of execution of the high-frequency support mode, presence / absence of opening / closing of the front door frame 14, and presence / absence of the start of game times. Therefore, first, “11” is set in the management target counter.

  Thereafter, it is determined whether or not the output state of the signal to the management CPU 112 for the management target corresponding to the current management target counter value is HI level (step S1002). If it is not the HI level (step S1002: NO), it is determined whether or not the value of the management target counter is 5 or more, so that the number of management targets corresponding to the value of the management target counter is seven entrance detection sensors 42a. To 48a is specified (step S1003).

  If an affirmative determination is made in step S1003, it is determined whether or not “1” is set in the output flag of the main RAM 65 corresponding to the value of the management target counter (step S1004). Specifically, if the value of the management target counter is “11” and corresponds to the first winning mouth detection sensor 42a, it is determined whether or not “1” is set in the first output flag. If the value of the management target counter is “10” and corresponds to the second prize opening detection sensor 43a, it is determined whether or not “1” is set in the second output flag, and the value of the management target counter is determined. Is “9” and corresponds to the third prize opening detection sensor 44a, it is determined whether or not “1” is set in the third output flag, and the value of the management target counter is “8”. In the case of corresponding to the special electric detection sensor 45a, it is determined whether or not “1” is set in the fourth output flag, the value of the management target counter is “7”, and the first working port detection sensor 46a. If it corresponds to “5”, the fifth output flag is set to “1”. It is determined whether or not it is set. If the value of the management target counter is “6” and corresponds to the second working port detection sensor 47a, whether or not “6” is set to the sixth output flag. If the value of the management target counter is “5” and corresponds to the out port 24a, it is determined whether or not “1” is set in the seventh output flag. Note that “1” is set to the first to seventh output flags in the ball entry detection process (FIG. 15) as already described.

  When “1” is set in the output flag corresponding to the value of the management target counter (step S1004: YES), the output state of the signal corresponding to the value of the management target counter among the first to seventh signals is set to the HI level. (Step S1005). Thereafter, the output flag corresponding to the value of the management target counter is cleared to “0” (step S1006).

  If a negative determination is made in step S1003, it is determined whether or not an opportunity to switch the output state of the signal corresponding to the value of the management target counter to the HI level has occurred (step S1007). Specifically, when the value of the management target counter is “4”, it is determined whether or not a transition to the opening / closing execution mode has occurred, and when the value of the management target counter is “3”, the value is high. It is determined whether or not the transition to the frequency support mode has occurred, and when the value of the management target counter is “2”, it is determined whether or not the front door frame 14 has been opened, and the management target counter When the value is “1”, it is determined whether or not the game turn is started by determining whether or not “1” is set in the eleventh output flag. If an affirmative determination is made in step S1007, the output state of the signal corresponding to the value of the management target counter is set to the HI level (step S1008). When the value of the management target counter is “1” and the process of step S1008 is executed, the eleventh output flag is cleared to “0”.

  If an affirmative determination is made in step S1002, it is determined whether or not an opportunity to switch the output state of the signal corresponding to the value of the management target counter to the LOW level has occurred (step S1009). Specifically, if the value of the management target counter is 5 or more or “1” and the current management target is any of the entrance detection sensors 42a to 48a or the start of game times, the first to seventh signals In addition, it is determined whether or not the HI output duration period (specifically, 10 milliseconds) has elapsed since the output state of the signal corresponding to the value of the management target counter among the eleventh signals is switched from the LOW level to the HI level. . This HI output continuation period is set to a period longer than the longest processing interval of the history setting process (step S908) of the management process (FIG. 23) in the management side CPU 112, and the output of the signal switched from the LOW level to the HI level. It is a period during which the state can be reliably specified by the management CPU 112. If the value of the management target counter is “4” and the current management target is the opening / closing execution mode, it is determined whether the opening / closing execution mode has ended, and the value of the management target counter is “3”. If the current management target is the high-frequency support mode, it is determined whether or not the high-frequency support mode has ended. The value of the management target counter is “2” and the current management target is the front door frame 14. In this case, it is determined whether or not the front door frame 14 is in a closed state. When an opportunity to switch the output state of the signal corresponding to the value of the management target counter to the LOW level has occurred (step S1009: YES), the output state of the signal corresponding to the value of the management target counter is set to the LOW level ( Step S1010).

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

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

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

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

  If an affirmative determination is made in step S1102, the RTC information that is year / month / day information and time information is read from the RTC 115 (step S1103). Then, the writing process to the history memory 117 is executed (step S1104). In the writing process, the pointer information of the history area 124 that is the current writing target is specified by referring to the pointer area 126 of the history memory 117 and corresponds to the pointer information that is the writing target. The RTC information read in step S1103 is written into the history information storage area 125 of the history area 124. Also, the correspondence information is read out from the correspondence areas 123a to 123n corresponding to the value of the current confirmation target counter, and the correspondence information is written into the history information storage area 125 corresponding to the pointer information that is the write target. In addition, when the correspondence information is any one of information indicating that it is an opening / closing execution mode, information indicating that it is a high-frequency support mode, and information indicating that it is the front door frame 14, the above In addition to the correspondence information, start information is written in the history information storage area 125 corresponding to the pointer information to be written. When the value of the confirmation target counter is “n”, the n-th corresponding relationship areas 123a to 123n are targets for reading the corresponding relationship information. For example, if the value of the check target counter is “11”, the eleventh corresponding relationship area 123k is a target for reading the corresponding relationship information, and if the value of the check target counter is “5”, the fifth corresponding relationship area 123e is the corresponding relationship. Information is to be read out.

  By executing the writing process as described above, the value of the check target counter is any of the out port 24a, the general winning port 31, the special electricity winning device 32, the first operating port 33, the second operating port 34, and the game times. Is stored in the history information storage area 125 corresponding to the pointer information to be written, the RTC information, the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, the second A combination of the operation relationship 34 and the correspondence information indicating that it is one of the game times is stored as history information. Further, when the value of the confirmation target counter is any of the opening / closing execution mode, the high frequency support mode, and the front door frame 14, the RTC information is stored in the history information storage area 125 corresponding to the pointer information to be written. And the combination of the correspondence information indicating that it is one of the opening / closing execution mode, the high-frequency support mode, and the front door frame 14 and the start information is stored as history information.

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

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

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

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

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

  At the timing t1, as shown in FIG. 27A, the output state of the signal input to any of the first to seventh and eleventh buffers 122a to 122g, 122k is switched from the LOW level to the HI level. Therefore, history information is written in the history memory 117 as shown in FIG. Thereafter, at the timing of t2, as shown in FIG. 27A, the signal switched to the HI level at the timing of t1 is switched to the LOW level. However, since the signal is a signal input to any of the first to seventh and eleventh buffers 122a to 122g, 122k, and the switching of the LOW level is not a history information storage target, the t2 As shown in FIG. 27E, the history information is not written at the timing.

  After that, as shown in FIG. 27 (a), at the timing of t3, the timing of t5, the timing of t6, the timing of t9, the timing of t10, the timing of t13, and the timing of t14, The output state of the signal input to any of the 11 buffers 122a to 122g, 122k is switched from the LOW level to the HI level. Accordingly, history information is written at each timing as shown in FIG.

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

  Also, history information is written in the history memory 117 in the order of time passage. Therefore, whether the history information indicating that a ball has entered any one of the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33 and the second operating port 34 is in the open / close execution mode. It becomes possible to distinguish whether or not. Since the history information includes RTC information, any of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 can be compared by comparing the RTC information. It is possible to distinguish whether or not the history information indicating that the ball has entered the open / close execution mode.

  As shown in FIG. 27C, the output state of the signal input to the ninth buffer 122i becomes the HI level from the timing t8 to the timing t11. The ninth buffer 122i corresponds to whether or not the high frequency support mode has occurred. Therefore, as shown in FIG. 27E, the timing at time t8 when the output state of the signal input to the ninth buffer 122i switches to the HI level, and the timing when the output state of the signal switches to the LOW level. The history information is written at each timing t11. In this case, the history information written at timing t8 includes start information, and the history information written at timing t11 includes end information. Accordingly, it is possible to grasp the execution period of the high frequency support mode by confirming the history information in the history memory 117.

  Also, history information is written in the history memory 117 in the order of time passage. Accordingly, the history information indicating that a ball has entered any one of the out port 24a, the general winning port 31, the special electric winning device 32, the first operating port 33, and the second operating port 34 is also in the high frequency support mode. It becomes possible to distinguish whether or not. Since the history information includes RTC information, any of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 can be compared by comparing the RTC information. It is possible to distinguish whether or not the history information indicating that the ball has entered the high frequency support mode.

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

  Also, history information is written in the history memory 117 in the order of time passage. Therefore, history information indicating that a ball has entered any one of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 is being opened. It becomes possible to distinguish whether it is a thing. Since the history information includes RTC information, any of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 can be compared by comparing the RTC information. It is possible to distinguish whether or not the history information indicating that the ball has entered the door is in the state where the front door frame 14 is being opened.

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

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

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

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

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

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

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

  As described above, in the output process of the set value update signal, a pulse signal by the set value update signal corresponding to the set value value of the pachinko machine 10 set at the start of the supply of the current operating power is output to the management IC 66. To do. The management-side CPU 112 executes the setting update recognition process, thereby grasping the number of pulse signals by the set value update signal, and grasping the set value of the pachinko machine 10 set this time based on the number.

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

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

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

  When a negative determination is made in step S1303, or when the process of step S1304 is executed, based on the input states of the first to eighth signals input to the first to eighth buffers 122a to 122h of the input port 121. Then, it is determined whether a set value identification end command has been received from the main CPU 63 (step S1305). If a negative determination is made in step S1305, the process returns to step S1303.

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

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

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

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

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

  First, it is determined whether it is a calculation timing (step S1401). If 51 seconds have elapsed since the supply of operating power to the management CPU 112 has started, or if 51 seconds have elapsed since the previous determination in step S1401, an affirmative determination is made in step S1401. When an affirmative determination is made in step S1401, the number of various incoming balls at normal times is calculated (step S1402). Specifically, first, by counting the number of history information storage areas 125 in which the corresponding relationship information indicating the outlets 24a in the history area 124 of the history memory 117 is stored, Calculate the number of balls entered. In addition, by counting the number of history information storage areas 125 in which the correspondence information indicating that it is the general winning opening 31 is stored in the history area 124 of the history memory 117, it is possible to enter the general winning opening 31. Calculate the number. In addition, by counting the number of history information storage areas 125 in which the correspondence information indicating that the special power prize winning device 32 is stored in the history area 124 of the history memory 117, it is possible to enter the special power prize winning device 32. Calculate the number. Further, by counting the number of history information storage areas 125 in which the correspondence information indicating the first operating port 33 is stored in the history area 124 of the history memory 117, Calculate the number of balls entered. In addition, by counting the number of history information storage areas 125 in which the correspondence information indicating the second operation port 34 is stored in the history area 124 of the history memory 117, Calculate the number of balls entered.

  Thereafter, in the history area 124 of the history memory 117, the history information storage area 125 in which correspondence information and start information indicating the front door frame 14 are stored, and the correspondence relationship indicating the front door frame 14 An outlet that occurs in a situation where the front door frame 14 is open by referring to the history information storage area 125 that exists in a period between the information and the history information storage area 125 in which the end information is stored 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, and the second operating opening 34 are calculated (step S1403). The history information storage area 125 in which the correspondence information and start information indicating the front door frame 14 in the history area 124 of the history memory 117 are stored, the correspondence information indicating the front door frame 14 and A period with the history information storage area 125 in which the end information is stored is calculated from the RTC information stored in the history information storage area 125. In addition, in the entire pointer information that is a serial number, the correspondence information indicating the front door frame 14 and the history information storage area 125 in which the start information is stored, and the correspondence indicating the front door frame 14 When there are a plurality of sections with the history information storage area 125 in which information and end information are stored, the number of balls entered for the total of the sections is calculated. Further, although there is a history information storage area 125 in which correspondence information indicating start door frame 14 and start information are stored, RTC information corresponding to a time later than the history information storage area 125 Is stored in the history information storage area 125 in which the front door frame 14 is stored, the correspondence information and the start information indicating the front door frame 14 are stored. The history information in the history information storage area 125 in which the RTC information corresponding to the time after the history information storage area 125 is stored is treated as if the front door frame 14 is in the open state.

Thereafter, various parameters are calculated using the calculation results of step S1402 and step S1403 (step S1404). Specifically, first, the number of entrances generated while the front door frame 14 is open calculated in step S1403 is subtracted from the number of entrances calculated in step S1402. And the following 1st-8th parameters are calculated using the number of each incoming balls after the subtraction. Note that the difference in the number of entered balls in the out mouth 24a calculated in step S1403 with respect to the number of entered balls in the out mouth 24a calculated in step S1402 is defined as the number of entered balls K1, and the entrance to the general winning opening 31 calculated in step S1402 is entered. The difference in the number of balls entered in the general winning opening 31 calculated in step S1403 with respect to the number of balls is defined as the number K2 of balls received, and the special prize winning device calculated in step S1403 with respect to the number of balls entered in the special prize winning device 32 calculated in step S1402. The difference in the number of incoming balls of 32 is defined as the number of incoming balls K3, and the difference in the number of incoming balls of the first working port 33 calculated in step S1403 with respect to the number of incoming balls of the first operating port 33 calculated in step S1402 is entered. The number K4 is the second number calculated in step S1403 with respect to the number of balls in the second operating port 34 calculated in step S1402. The difference between the ball entrance number of Doguchi 34 and ball entrance number K5.
First parameter: Total number of game balls to be paid out (K2 × “number of winning balls for winning in the general winning opening 31” + K3 × “number of winning balls for winning in the special electricity winning device 32” + K4 × “first operating port 33 The number of winning balls for winning a prize + K5 × “the number of winning balls for winning the second operating port 34”) / the ratio of the total number of game balls discharged from the work area PA (K1 + K2 + K3 + K4 + K5) D1 ”)
Second parameter: the ratio of the total number of game balls K2 entering the general winning opening 31 / the total number of game balls discharged from the game area PA (K1 + K2 + K3 + K4 + K5). Third parameter: game balls to the special prize winning device 32. The total number of balls K3 / the ratio of the total number of game balls discharged from the game area PA (K1 + K2 + K3 + K4 + K5). Fourth parameter: the total number K4 of game balls entering the first operating port 33 / discharge from the game area PA. Ratio of the total number of game balls played (K1 + K2 + K3 + K4 + K5) (hereinafter, this ratio is referred to as “D2”)
Fifth parameter: ratio of the total number of game balls entering the second operation port K5 / total number of game balls discharged from the game area PA (K1 + K2 + K3 + K4 + K5) (hereinafter, this ratio is referred to as “D3”)
Sixth parameter: D1- (D2 × “the number of winning balls for winning in the first operating port 33” + D3 × “the number of winning balls for winning in the second operating port 34”)
7th parameter: (K3 × “the number of winning balls for winning in the special electricity winning device 32” + K5 × “the number of winning balls for winning in the second operating port 34”) / total number of game balls to be paid out (K2 × “general The number of winning balls for winning at the winning opening 31 + K3 × “the number of winning balls for winning at the special electricity winning device 32” + K4 × “the number of winning balls for winning at the first operating port 33” + K5 × “the second operating port 34” Ratio / eighth parameter: K3 × “number of winning balls for winning to the special electric prize device 32” / total number of game balls to be paid out (K2 × “for winning to the general winning opening 31”) “Number of winning balls” + K3 × “Number of winning balls for winning in the special electric prize winning device 32” + K4 × “Number of winning balls for winning in the first operating port 33” + K5 × “Number of winning balls for winning in the second operating port 34” )) Step S1404 Which stores the first to eighth parameter is the operation result to the normal storage area for the time of the operation result memory 131. The first to eighth parameters stored in the normal time storage area are stored and held until the next step S1404 is executed. In other words, when the next step S1404 is executed and the first to eighth parameters are calculated, the newly calculated first to eighth parameters are stored in the normal storage area. The previous calculation results of the first to eighth parameters stored in the normal time storage area are overwritten.

  Thereafter, in the history area 124 of the history memory 117, the history information storage area 125 in which correspondence information and start information indicating the opening / closing execution mode are stored, correspondence information indicating the switching execution mode, and By referring to the history information storage area 125 existing in the period between the end information and the history information storage area 125, the out port 24a and the general winning port 31 generated in the state of the open / close execution mode are referred to. Then, the number of balls entered into each of the special electric prize winning device 32, the first operating port 33 and the second operating port 34 is calculated (step S1405). The history information storage area 125 in which the correspondence information and start information indicating the opening / closing execution mode are stored in the history area 124 of the history memory 117, and the correspondence information and end information indicating the opening / closing execution mode are stored. Is calculated from the RTC information stored in the history information storage area 125. In addition, in the entire pointer information that is a serial number, the history information storage area 125 in which correspondence information and start information indicating the opening / closing execution mode are stored, correspondence information indicating the opening / closing execution mode, and If there are a plurality of sections with the history information storage area 125 in which the end information is stored, the number of balls entered for the total of the sections is calculated. Further, although there is a history information storage area 125 in which correspondence information indicating start / close execution mode and start information are stored, RTC information corresponding to a time later than the history information storage area 125 is present. When correspondence information and end information indicating that it is in the opening / closing execution mode are not stored in the stored history information storage area 125, correspondence information and start information indicating that it is in the opening / closing execution mode are stored. Any history information in the history information storage area 125 in which RTC information corresponding to a time later than the history information storage area 125 is stored is handled in the open / close execution mode.

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

Thereafter, various parameters are calculated using the calculation results of steps S1405 and S1406 (step S1407). Specifically, first, the number of balls entered during the opening of the front door frame 14 calculated in step S1406 is subtracted from the number of balls entered in step S1405. Then, the following 11th to 18th parameters are calculated using the number of balls entered after the subtraction. Note that the difference in the number of entered balls in the out port 24a calculated in step S1406 with respect to the number of entered balls in the out port 24a calculated in step S1405 is set as the number of entered balls K11, and the entry of the general winning port 31 calculated in step S1405 is entered. The difference in the number of balls entered at the general winning opening 31 calculated in step S1406 with respect to the number of balls is defined as the number K12 of balls entered, and the special prize device calculated in step S1406 with respect to the number of balls entered in the special prize device 32 calculated in step S1405. The difference in the number of entering balls 32 is defined as the number of entering balls K13, and the difference in the number of entering balls in the first working port 33 calculated in step S1406 with respect to the number of entering balls in the first operating port 33 calculated in step S1405 is entered. The number K14 is calculated in step S1406 with respect to the number of balls entering the second operation port 34 calculated in step S1405. The difference between the ball entrance number of the second actuating port 34 and ball entrance number K15 was.
Eleventh parameter: Total number of game balls to be paid out (K12 × “number of winning balls for winning in the general winning opening 31” + K13 × “number of winning balls for winning in the special electric winning device 32” + K14 × “first operating port 33 The number of winning balls for winning a prize + K15 × “the number of winning balls for winning the second operating port 34”) / the ratio of the total number of gaming balls discharged from the gaming area PA (K11 + K12 + K13 + K14 + K15) D11 ”)
The twelfth parameter: the total number of game balls entered into the general winning opening 31 K12 / the ratio of the total number of game balls discharged from the game area PA (K11 + K12 + K13 + K14 + K15) The thirteenth parameter: game balls to the special prize winning device 32 The total number of balls K13 / the ratio of the total number of game balls (K11 + K12 + K13 + K14 + K15) discharged from the game area PA. Fourteenth parameter: the total number K14 of game balls entering the first operating port 33 / discharge from the game area PA. Ratio of the total number of game balls played (K11 + K12 + K13 + K14 + K15) (hereinafter, this ratio is referred to as “D12”)
Fifteenth parameter: ratio of total number of game balls K15 entering the second operating port 34 / total number of game balls discharged from the game area PA (K11 + K12 + K13 + K14 + K15) (hereinafter, this ratio is referred to as “D13”)
16th parameter: D11− (D12 × “the number of winning balls for winning in the first operating port 33” + D13 × “the number of winning balls for winning in the second operating port 34”)
17th parameter: (K13 × “the number of winning balls for winning in the special electricity winning device 32” + K15 × “the number of winning balls for winning in the second operating port 34”) / total payout of game balls (K12 × “general The number of winning balls for winning in the winning opening 31 "+ K13 ×" the number of winning balls for winning in the special electricity winning device 32 "+ K14 ×" the number of winning balls for winning in the first operating port 33 "+ K15 ×" the second operating port 34 ". Ratio / 18th parameter: K13 × “the number of winning balls for winning the special electric prize device 32” / total number of game balls to be paid out (K12 × “for winning to the general winning opening 31”) “Number of winning balls” + K13 × “Number of winning balls for winning in the special electric prize winning device 32” + K14 × “Number of winning balls for winning in the first operating port 33” + K15 × “Number of winning balls for winning in the second operating port 34” ") In step S1407, the 11th to 18th parameters, which are the calculation results, are stored in the storage area for the open / close execution mode in the calculation result memory 131. The 11th to 18th parameters stored in the opening / closing execution mode storage area are stored and held until the next step S1407 is executed. That is, when the next step S1407 is executed and the 11th to 18th parameters are calculated, the newly calculated 11th to 18th parameters are stored in the opening / closing execution mode storage area. The previous calculation results of the 11th to 18th parameters stored in the storage area for the open / close execution mode are overwritten.

  Thereafter, the history information storage area 125 in which the correspondence information indicating the high frequency support mode and the start information are stored in the history area 124 of the history memory 117 and the correspondence relationship indicating the high frequency support mode are stored. The out port 24a generated in the situation of the high frequency support mode by referring to the history information storage area 125 existing in the period between the information and the history information storage area 125 in which the end information is stored, The number of balls entered into each of the winning opening 31, the special prize winning device 32, the first operating opening 33 and the second operating opening 34 is calculated (step S1408). In the history area 117 of the history memory 117, the history information storage area 125 storing the correspondence information and start information indicating the high frequency support mode, the correspondence information indicating the high frequency support mode, and A period with the history information storage area 125 in which the end information is stored is calculated from the RTC information stored in the history information storage area 125. In addition, in the entire pointer information that is a serial number, the correspondence information indicating the high frequency support mode and the history information storage area 125 in which the start information is stored, and the correspondence indicating the high frequency support mode When there are a plurality of sections with the history information storage area 125 in which information and end information are stored, the number of balls entered for the total of the sections is calculated. In addition, although there is a history information storage area 125 in which correspondence information indicating the high frequency support mode and start information are stored, RTC information corresponding to a time later than the history information storage area 125 Is stored in the history information storage area 125, the correspondence information indicating the high frequency support mode and the end information are stored. The history information in the history information storage area 125 in which the RTC information corresponding to the time after the history information storage area 125 is stored is treated as being in the high frequency support mode.

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

Thereafter, various parameters are calculated using the calculation results of steps S1408 and S1409 (step S1410). Specifically, first, the number of balls entered during the opening of the front door frame 14 calculated in step S1409 is subtracted from the number of balls entered in step S1408. Then, the following 21st to 26th parameters are calculated using the number of incoming balls after the subtraction. Note that the difference in the number of entered balls in the out mouth 24a calculated in step S1409 with respect to the number of entered balls in the out mouth 24a calculated in step S1408 is defined as the number of entered balls K21, and the entry of the general winning opening 31 calculated in step S1408 is performed. The difference in the number of balls in the general winning opening 31 calculated in step S1409 with respect to the number of balls is set as the number K22 of balls, and the special prize apparatus calculated in step S1409 with respect to the number of balls in the special prize device 32 calculated in step S1408. The difference in the number of entering balls 32 is defined as the number of entering balls K23, and the difference in the number of entering balls in the first operating port 33 calculated in step S1409 with respect to the number of entering balls in the first operating port 33 calculated in step S1408 is entered. The number is K24 and is calculated in step S1409 with respect to the number of balls entering the second operation port 34 calculated in step S1408. The difference between the ball entrance number of the second actuating port 34 and ball entrance number K25 was.
21st parameter: total number of game balls to be paid out (K22 × “the number of winning balls for winning in the general winning opening 31” + K23 × “the number of winning balls for winning in the special electric winning device 32” + K24 × “first operating port 33” The number of winning balls for winning a prize + K25 × “the number of winning balls for winning the second operating port 34”) / the ratio of the total number of gaming balls discharged from the gaming area PA (K21 + K22 + K23 + K24 + K25) D11 ”)
22nd parameter: Total number of game balls entering the general winning opening 31 K22 / Ratio of total number of game balls discharged from the game area PA (K21 + K22 + K23 + K24 + K25) 23rd parameter: Game balls to the special prize winning device 32 Total number of entered balls K23 / Ratio of the total number of game balls discharged from the game area PA (K21 + K22 + K23 + K24 + K25). Twenty-fourth parameter: Total number of game balls entered into the first working port 33 K24 / discharged from the game area PA Ratio of the total number of game balls played (K21 + K22 + K23 + K24 + K25) (hereinafter, this ratio is referred to as “D22”)
25th parameter: ratio of the total number of game balls entering the second operation port K25 / total number of game balls discharged from the game area PA (K21 + K22 + K23 + K24 + K25) (hereinafter, this ratio is referred to as “D23”)
26th parameter: D21− (D22 × “the number of winning balls for winning in the first operating port 33” + D23 × “the number of winning balls for winning in the second operating port 34”)
In step S1410, the 21st to 26th parameters, which are the calculation results, are stored in the high frequency support mode storage area in the calculation result memory 131. The 21st to 26th parameters stored in the high frequency support mode storage area are stored and held until the next step S1410 is executed. That is, when the next step S1410 is executed and the 21st to 26th parameters are calculated, the newly calculated 21st to 26th parameters are stored in the high frequency support mode storage area. Thus, the previous calculation results of the 21st to 26th parameters stored in the storage area for high frequency support mode are overwritten.

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

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

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

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

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

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

  The display target counter is a counter for the management CPU 112 to specify the type of parameter that is the display target in the first to third notification display devices 69a to 69c. The first to eighth parameters, the eleventh to eighteenth parameters, the twenty-first to twenty-sixth parameters, the thirty-first parameter, the thirty-first to forty-second parameters, and display target counters “0” to “24”. There is a one-to-one correspondence with possible values. For example, when the value of the display target counter is “0”, the first parameter that is the first display target is the display target of the first to third notification display devices 69a to 69c, and the value of the display target counter is “24”. If so, the forty-second parameter that is the last display target is the display target of the first to third notification display devices 69a to 69c.

  When a negative determination is made in step S1504, or when the process of step S1505 is executed, the first notification display device 69a is displayed so that information corresponding to the type of parameter corresponding to the value of the display target counter is displayed. Control is performed (step S1506). In addition, the parameter corresponding to the value of the display target counter is read from the calculation result memory 131, the read parameter is multiplied by 100, and the number corresponding to the tenth digit is displayed on the second notification display device 69b. The number corresponding to the 1's place is displayed on the third notification display device 69c (step S1507). The contents displayed on the first to third notification display devices 69a to 69c in step S1506 and step S1507 are continued until the next update timing or until the supply of operating power to the management CPU 112 is stopped. The Thereafter, a value corresponding to 2 seconds is set in the update timing counter of the management side RAM 114 as a value corresponding to the next update timing (step S1508).

  When supply of operating power to the management CPU 112 is started by executing the display processing as described above, the management results of the game history are displayed on the first to third notification display devices 69a to 69c. Is done. The management result of the game history is displayed regardless of whether or not the game is continued, and the main body 60 is opened from the front of the pachinko machine 10 by opening the gaming machine main body 12 with respect to the outer frame 11. This is done regardless of whether it is visible. As described above, the display control of the first to third notification display devices 69a to 69c is executed regardless of the game situation and the state of the pachinko machine 10, and thereby the first to third notification display devices 69a. It becomes possible to simplify the processing configuration for display control of .about.69c.

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

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

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

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

  In the data output processing, first, it is determined whether or not a connection signal indicating that an external device is electrically connected to the reading terminal 68d is received from the reading terminal 68d (step S1601). If a negative determination is made in step S1601, the data output process is terminated as it is. In this case, in order to execute the data output process, it is necessary to restart the supply of operating power to the main CPU 63. Thus, in order to perform external output of history information and various parameters, supply of operating power to the main CPU 63 is started with an external device electrically connected to the reading terminal 68d. It is necessary to. Since the power switch for stopping and starting the operation power supply to the main CPU 63 is provided in the payout mechanism 73 mounted on the back surface of the back pack unit 15, these stop and start operations are performed. In order to do this, it is necessary to open the gaming machine main body 12 to the outer frame 11 to expose the back surface of the back pack unit 15. Under such circumstances, in order to externally output history information and various parameters, supply of operating power to the main CPU 63 is started with an external device electrically connected to the reading terminal 68d. By adopting a configuration that needs to be configured, it is possible to make it difficult to perform an operation for reading history information and various parameters by anyone other than the administrator of the game hall.

  If an affirmative determination is made in step S1601, it is determined whether or not a control information confirmation signal is received from the reading terminal 68d, so that the current connection of the external device to the reading terminal 68d is determined by the main ROM 64. It is determined whether or not the control information (program and data) is confirmed (step S1602). The external device is configured to allow both confirmation of control information and history information and various parameters, and if control information confirmation is selected by manual operation on the external device, the external device A control information confirmation signal is transmitted, and when history information and confirmation of various parameters are selected by a manual operation on the external apparatus, a history confirmation signal is transmitted from the external apparatus. However, the present invention is not limited to this, and an external device for confirming control information may be configured separately from an external device for confirming history. In this case, when an external device for confirming control information is electrically connected to the reading terminal 68d, a signal for confirming control information is transmitted from the external device, and an external for history confirmation is transmitted to the reading terminal 68d. When the device is electrically connected, a history confirmation signal is transmitted from the external device.

  When an affirmative determination is made in step S1602, output processing for control information confirmation is executed (step S1603). In the output process, a program and data are read from the main ROM 64 as control information, and the read control information is output to the reading terminal 68d. As a result, it becomes possible to read the control information in the external device electrically connected to the reading terminal 68d, and it is confirmed whether the control information is normal or normal. Can be performed.

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

  Specifically, as shown in the flowchart of FIG. 32B, the management CPU 112 has changed the output state of the output instruction signal input to the sixteenth buffer 122p of the input port 121 from the LOW level to the HI level. (Step S1701: YES), the history information stored in the history memory 117 and the various parameters stored in the calculation result memory 131 are read, and the read history information and various parameters are output to the reading terminal 68d. (Step S1702). As a result, the history information and various parameters can be read by the external device electrically connected to the reading terminal 68d, and the game history management result information can be analyzed. Further, when the history information is output to the reading terminal 68d, the management CPU 112 clears the history memory 117 to “0” (step S1703). The history information in the history memory 117 is deleted only when the history information is read by the external device.

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

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

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

  All the entrances that discharge the game balls from the game area PA are the targets for executing the history information storage process and the targets for management using the history information. Thereby, it becomes possible to manage the pitching frequency for an arbitrary history target pitching part using the history information. In addition, it is possible to manage the ratio of the number of game balls entering each history target entrance part with respect to the number of game balls discharged from the game area PA using history information.

  The history information includes RTC information, which is information corresponding to the timing at which a game ball has entered the history target entrance portion that triggered the storage of the history information. Thereby, by using the history information, it is possible to grasp in detail the entry history of the game balls into the history target entry portion.

  In the history memory 117, not only history information corresponding to the game ball entering the history target entry part, but also history information indicating whether or not the open / close execution mode is in effect, and the high frequency support mode History information indicating whether or not, and history information indicating whether or not the front door frame 14 is open. Thereby, it is possible to manage whether or not the game balls have entered the history target ball entering unit by distinguishing whether or not each of these situations is present.

  The history information stored in the history memory 117 can be output to an external device that is an external device of the pachinko machine 10. As a result, the history information is read by the external device, and it is possible to analyze the manner in which the game ball enters the history target entry portion using the read history information.

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

  It is specified whether the information to be output from the reading terminal 68d is a program or history information, and information on the side corresponding to the specified result is externally output through the reading terminal 68d. Accordingly, in the configuration in which the history information is output to the outside using the reading terminal 68d for outputting the program to the outside, the pachinko machine 10 determines whether the information to be externally output is the program or the history information. The specified information is output to the outside. Therefore, only necessary information can be read out even if the reading terminal 68d is also used.

  Based on the information received from the external device electrically connected to the reading terminal 68d, it is specified which information of the program and the history information is to be output from the reading terminal 68d. As a result, it is possible to prevent the configuration relating to selection of information to be externally output from becoming complicated.

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

  The main CPU 63 that executes processing for paying out the game ball based on the game ball entering any of the general winning port 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34. Separately, a management CPU 112 is provided, and the management CPU 112 executes processing for storing history information in the history memory 117. As a result, it is possible to manage the manner in which the game balls enter the respective history target entrance portions while preventing the processing load on the main CPU 63 from increasing extremely.

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

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

  Information corresponding to whether or not the main CPU 63 is in the opening / closing execution mode, information corresponding to whether or not the high-frequency support mode is in progress, information corresponding to whether or not the front door frame 14 is being opened, Information corresponding to the start of the game round is transmitted to each of the buffers 122h to 122k of the input port 121 of the management IC 66 by using a signal path corresponding to each of these situations. As a result, the types of information corresponding to these situations correspond to the buffers 122h to 122k (that is, the signal paths), and the configuration for distinguishing the types of information by the management CPU 112 is simplified. It becomes possible.

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

  When supply of operating power to the main CPU 63 is started, correspondence information is transmitted from the main CPU 63 to the management IC 66. As a result, in a situation where a game ball can enter the history target entrance part, the correspondence between the information transmitted from the main CPU 63 and the history target entrance part can be specified by the management IC 66. It becomes possible to become.

  Correspondence information is transmitted from the main CPU 63 to the management IC 66 by using signal paths 118a to 118g for transmitting information indicating whether or not a game ball has entered the history target ball entry unit. Thereby, it becomes possible to simplify the structure regarding communication compared with the structure which provides the dedicated signal path | route for transmitting corresponding relationship information.

  The management IC 66 is provided with a correspondence memory 116, and correspondence information transmitted from the main CPU 63 to the management IC 66 is stored in the correspondence memory 116. As a result, information that enables the management target IC 66 to specify the history target entrance portion corresponding to the transmission target information is transmitted from the main CPU 63 each time detection result information of each of the entrance detection sensors 42a to 48a is transmitted. No need to provide. Therefore, it is possible to suppress the amount of information of the detection results of the respective entrance detection sensors 42a to 48a transmitted from the main CPU 63.

  When the output state of the output instruction signal output from the main CPU 63 to the management IC 66 is switched from the LOW level to the HI level, information is output from the management IC 66 to the reading terminal 68d. In this case, the fact that the signal path corresponding to the sixteenth buffer 122p corresponds to the output instruction signal can be specified by the management CPU 112 without receiving correspondence information from the main CPU 63. . As a result, it is possible to prevent the configuration related to transmission of correspondence information from becoming extremely complicated.

  The management IC 66 is provided with more buffers than the types of information that need to be transmitted from the main CPU 63 to the management IC 66 as buffers 122a to 122p capable of receiving information from the main CPU 63. It has been. Thereby, even if the number of types of the information increases or decreases according to the model of the pachinko machine 10, it is possible to cope without changing the configuration regarding the buffers 122a to 122p. Therefore, the versatility of the management IC 66 can be improved.

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

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

  Various parameters are calculated in a state where the history information corresponding to the situation where the front door frame 14 is open is excluded. Thereby, it becomes possible to derive various parameters in a normal situation where the front door frame 14 is in the closed state. Also, various parameters corresponding to each of the situation in the opening / closing execution mode and the situation in the high frequency support mode are calculated. Thereby, the manager of the game hall or the like can grasp the entrance mode of the game ball according to each situation.

  When the history information of the history memory 117 is output to an external device, the history memory 117 is initialized by executing the clear processing of the history memory 117. As a result, the history information that exceeds the storage capacity of the history memory 117 becomes an object to be stored in the history memory 117, and the history information that should originally be stored is erased by overwriting. Can be made difficult to occur.

  In a configuration in which when a game ball enters the first operation port 33 or the second operation port 34, an external output corresponding to the game ball is generated through the external terminal plate 97, history information is stored in the history memory 117. . Thus, by using information output externally through the external terminal plate 97, the number of game balls entering the first operation port 33 and the second operation port 34 and the frequency of entering the game ball can be easily grasped. By using the history information stored in the memory 117 for use, it is possible to accurately grasp the number and frequency of entering the game balls into the history target entry portion.

  The probability of a jackpot result in the low probability mode varies depending on the setting state of the pachinko machine 10 of “Setting 1” to “Setting 6”. Thereby, even if it is the single pachinko machine 10, it becomes possible to produce the situation which becomes advantageous or unfavorable about the probability of being a jackpot result in the low probability mode. Therefore, it is possible to improve the interest of the game.

  The probability of a jackpot result in the low probability mode varies depending on the setting state of the pachinko machine 10 of “Setting 1” to “Setting 6”, while the probability of a jackpot result in the high probability mode is set in the pachinko machine 10. Does not vary according to conditions. Thereby, it becomes possible to restrict the influence of the setting state of the pachinko machine 10 on the probability of the jackpot result to the situation in the low probability mode. In addition, since the high-accuracy determination table 64g referred to in the high-probability mode can be made common regardless of the setting state of the pachinko machine 10, the determination tables 64a to 64g are stored in advance in the main ROM 64. It is possible to suppress an increase in storage capacity for storing.

  The probability of a jackpot result in the low probability mode varies depending on the setting state of the pachinko machine 10 of “Setting 1” to “Setting 6”, while the sort mode of the type of jackpot result is the setting state of the pachinko machine 10. Does not fluctuate accordingly. Thereby, it becomes possible to restrict the influence of the setting state of the pachinko machine 10 to the situation in the low probability mode. Further, since the distribution table 64h referred to when distributing the types of jackpot results can be made common in any of the setting states of the pachinko machine 10, the distribution table 64h in the main ROM 64 can be used. Can be prevented from increasing in storage capacity.

  Even if a new setting state of the pachinko machine 10 is set, the history information stored in the history memory 117 is stored and held without being erased. As a result, even if a new setting state of the pachinko machine 10 is set, the history information up to that time can be continuously stored in the history memory 117, and the history memory can be stored for a long period of time. The management result of the game history can be specified using the history information accumulated in 117.

  Even if a new setting state of the pachinko machine 10 is set, the history information stored in the history memory 117 is stored and held without being erased, and the new setting state of the pachinko machine 10 is set. Is performed, the corresponding history information is stored in the history memory 117. Thereby, it becomes possible to distinguish the history information before the new setting of the setting state of the pachinko machine 10 is performed and the history information after the setting.

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

  When calculating various parameters at the calculation timing, the history information stored in the history memory 117 is used based on the history information corresponding to the new setting of the pachinko machine 10 setting. Thus, various parameters may be calculated. In this case, the management result of the game history at the timing after the new setting state of the pachinko machine 10 is performed can be derived as various parameters.

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

  In addition, although the opening for exposing the reading terminal 68d is provided in the board box 60a of the main controller 60, the opening 69 is not provided and the reading terminal 69d is opposed to the opposing wall 60b. It is good also as a structure covered with. In this case, in order to connect an external device to the reading terminal 68d, it is necessary to open the substrate box 60a.

<Second Embodiment>
In the present embodiment, the contents of the success / failure table corresponding to the set state of the pachinko machine 10 are different from those in the first embodiment. Hereinafter, a configuration different from that of the first embodiment will be described. The description of the same configuration as that of the first embodiment is basically omitted.

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

  As shown in FIG. 33, the main ROM 64 has a setting 1 area 161, a setting 2 area 162, a setting 3 area 163, a setting 4 area 164, a setting 5 area 165, and a setting 6 area. 166 are provided. In the setting 1 area 161, the low probability table 161 a for setting 1 that is referred to when the setting state of the pachinko machine 10 is “setting 1” and the winning / losing lottery mode is the low probability mode, and the pachinko machine 10 Is stored in a high-probability table 161b for setting 1 that is referred to when the setting state is “setting 1” and the winning-and-raising lottery mode is the high probability mode. The setting 2 area 162 includes a low probability table 162a for setting 2 that is referred to when the setting state of the pachinko machine 10 is “setting 2” and the winning / non-winning lottery mode is the low probability mode, and the pachinko machine 10 Is stored in a high probability determination table 162b for setting 2, which is referred to when the setting state of “Setting 2” is “high probability mode”. In the setting 3 area 163, a low probability table 163a for setting 3 that is referred to when the setting state of the pachinko machine 10 is “setting 3” and the winning / non-winning lottery mode is the low probability mode, and the pachinko machine 10 Is stored in a high-probability table 163b for setting 3, which is referred to when the setting state is “setting 3” and the winning-and-raising lottery mode is the high probability mode.

  In the setting 4 area 164, a low probability table 164a for setting 4 that is referred to when the setting state of the pachinko machine 10 is “setting 4” and the winning / non-winning lottery mode is the low probability mode, and the pachinko machine 10 Is stored in a high probability determination table 164b for setting 4, which is referred to when the setting state of “setting 4” is “high probability mode”. In the setting 5 area 165, the low probability table 165a for setting 5 that is referred to when the setting state of the pachinko machine 10 is “setting 5” and the winning / non-winning lottery mode is the low probability mode, and the pachinko machine 10 Is stored in the high-probability table 165b for setting 5, which is referred to when the setting state is “setting 5” and the winning / non-winning lottery mode is the high probability mode. In the setting 6 area 166, a low probability table 166a for setting 6 that is referred to when the setting state of the pachinko machine 10 is “setting 6” and the winning / non-winning lottery mode is the low probability mode, and the pachinko machine 10 Is stored in a high-probability table 166b for setting 6 that is referred to when the setting state is “setting 6” and the winning / non-winning lottery mode is the high probability mode.

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

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

  That is, in the first embodiment, the winning probability of the jackpot result in the low probability mode becomes higher as the setting state of the pachinko machine 10 is higher, while the winning probability of the jackpot result in the high probability mode is “Setting 1”. In the present embodiment, both of the winning probability of the jackpot result in the low probability mode and the winning probability of the jackpot result in the high probability mode are the same. The setting state of the machine 10 is higher as the setting value is higher. This makes it possible to increase the player's advantage over the setting of a high setting value.

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

  On the other hand, as in the first embodiment, only one type of distribution table 64h is provided so as to be common in any setting state of “setting 1” to “setting 6”. As a result, it is possible to prevent an advantage or disadvantage caused by the setting state of the pachinko machine 10 with respect to the distribution mode of the jackpot result, and a storage capacity for storing the distribution table 64h in the main ROM 64 in advance. Can be suppressed.

  Note that the winning probability of the jackpot result in the low probability mode is higher when the setting state of the pachinko machine 10 is higher, while the winning probability of the jackpot result in the high probability mode is higher in the setting state of the pachinko machine 10. A configuration in which the set value is lower may be employed. In this case, in the low probability mode, a higher setting value of the pachinko machine 10 is advantageous to the player, and in the high probability mode, a lower setting value of the pachinko machine 10 is advantageous to the player. It becomes possible.

  The winning probability of the jackpot result in the high probability mode is higher when the setting state of the pachinko machine 10 is a higher setting value, while the winning probability of the jackpot result in the low probability mode is “Setting 1” to “Setting 6”. It is good also as a structure which is constant in the setting state of "." In this case, in the high probability mode, the higher the set value of the pachinko machine 10 is, the more advantageous for the player. In the low probability mode, it is possible to prevent the advantage or disadvantage caused by the set state of the pachinko machine 10 from occurring. Become.

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

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

  The separate storage memory 171 includes a first separate storage area 172, a second separate storage area 173, a third separate storage area 174, a fourth separate storage area 175, and a fifth separate storage area 176. In the first to fifth separate storage areas 172 to 176, information on the management result of the game history calculated when the setting state of the pachinko machine 10 is newly set, more specifically, the first embodiment described above. The various parameters (1st to 8th parameters, 11th to 18th parameters, 21st to 26th parameters, 31st parameter, 41st to 42nd parameters) described in the above are sequentially stored. In this case, when the setting state of the pachinko machine 10 is newly set, first, various parameters are stored in the first separate storage area 172, and thereafter each time the setting state of the pachinko machine 10 is newly set, the nth The areas to be stored are switched so that the storage areas 172 to 176 → the (n + 1) th separate storage areas 172 to 176. When various parameters are stored in the fifth separate storage area 176 and the setting state of the pachinko machine 10 is newly set, the various parameters are stored again in the first separate storage area 172. At this time, various parameters already stored in the first separate storage area 172 are deleted. As a result, various parameters until the new setting state of the pachinko machine 10 is executed five times are stored in the separate storage memory 171, and the oldest various parameters are erased for more than five times. It is memorized.

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

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

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

  Thereafter, it is determined whether or not the set value update signal input to the fifteenth buffer 122o of the input port 121 is switched from the LOW level to the HI level (step S1803). When an affirmative determination is made in step S1803, 1 is added to the value of the set value grasp counter in the management side RAM 114 (step S1804). As a result, the set value of the pachinko machine 10 specified by the management CPU 112 is increased by one step.

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

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

  Thereafter, various arithmetic processes are executed (step S1807). In various arithmetic processes, the processes in steps S1402 to S1412 of the display output process (FIG. 30) in the first embodiment are executed. Accordingly, various parameters (first to eighth parameters, first to eighteenth parameters, twenty-first to twenty-sixth parameters, thirty-first parameter, and thirty-first parameter) using the history information stored in the history memory 117 at that time. To 42nd parameter) is calculated.

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

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

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

  Thereafter, update processing of the target pointer is executed (step S1812). In the update process, the numerical information stored in the pointer area 126 of the history memory 117 is read and added by one. It is determined whether the pointer information after the addition of 1 exceeds the maximum value of the pointer information in the history area 124. If the maximum value is not exceeded, the pointer information after adding 1 is overwritten in the pointer area 126 as pointer information to be newly written. If the maximum value is exceeded, the pointer area 126 is cleared to “0” so that the pointer information to be written becomes the first pointer information.

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

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

  When an affirmative determination is made in step S1901, 1 is added to the value of the repeated change counter provided in the separate storage memory 171 (step S1902). Since the separate storage memory 171 is a memory that does not require external power supply for storing and holding, as described above, it is not necessary to supply external power for storing and holding the value of the repeated change counter.

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

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

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

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

  When a new setting state of the pachinko machine 10 is performed, the history information stored in the history memory 117 is deleted. As a result, it is possible to leave history information about the game executed after the new setting of the pachinko machine 10 is set in the history memory 117.

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

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

  By providing a plurality of separate storage areas 172 to 176 in the separate storage memory 171, it is possible to store various parameters corresponding to the setting timings of the setting states for a plurality of times. Thereby, it becomes possible to grasp the management result of the game history in a plurality of periods with reference to the timing when the new setting state is set. In addition, even when a new setting of the pachinko machine 10 is repeated in a situation where no game is played, various parameters calculated using history information of the situation where the game is actually played are The possibility of remaining in the separate storage memory 171 can be increased.

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

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

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

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

  In the case where the number of game times executed after the new setting of the setting state of the pachinko machine 10 is within the reference number, the event in which the new setting is performed continues beyond the notification reference value. However, the present invention is not limited to this, and the total discharge of game balls discharged from the game area PA after a new setting of the pachinko machine 10 is performed is not limited to this. In a situation where the number is within the reference number, when the event in which the new setting is performed continues beyond the notification reference value, the corresponding notification may be executed. In addition, after a new setting of the setting state of the pachinko machine 10 is performed, a predetermined entry part (for example, one of the out port 24a, the general winning port 31, the first operating port 33, the second operating port 34, or a predetermined In a situation where the total number of game balls discharged into the combination) is within the reference number, and the event where the new setting is made continues beyond the notification reference value, the corresponding notification may be executed. Good. In addition, an event that the new setting is performed in a situation where the total number of history information newly stored in the history memory 117 after the new setting state of the pachinko machine 10 is within the reference number is notified. A configuration may be adopted in which notification corresponding to the reference value is executed when the reference value is exceeded.

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

  In addition, when the number of game times executed after the new setting of the setting state of the pachinko machine 10 is within the reference number, the event in which the new setting is performed continues beyond the notification reference value However, the setting value has been changed in a situation where the number of game times executed after the new setting of the setting state of the pachinko machine 10 is within the reference number of times. When an event continues beyond the notification reference value, a corresponding notification may be executed.

  In addition, when the number of game times executed after the new setting of the setting state of the pachinko machine 10 is within the reference number, the event in which the new setting is performed continues beyond the notification reference value The corresponding notification is executed, but the new setting is triggered when the number of game times executed after the new setting state of the pachinko machine 10 is within the reference number of times. It is good also as a structure by which the alerting | reporting corresponding to it is performed when the event by which the various parameters made above continue exceeding the alerting | reporting reference value.

  In addition, when the number of game times executed after the new setting of the setting state of the pachinko machine 10 is within the reference number, the event in which the new setting is performed continues beyond the notification reference value However, in addition to or in place of it, the progress of the game may be limited for a predetermined period (for example, 1 hour).

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

  FIG. 37 is a flowchart showing the repeated change monitoring process executed by the main CPU 63. The repeated change monitoring process is executed when the set value update process (step S118) is executed in the main process (FIG. 9). That is, when the setting state of the pachinko machine 10 is newly set, the monitoring process for repeated change is executed. However, the present invention is not limited to this, and a configuration in which repeated change monitoring processing is executed when a set value is changed may be employed.

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

  When an affirmative determination is made in step S2001, the value of the repeat change counter provided in the main RAM 65 is incremented by 1 (step S2002). The repetitive change counter is excluded from the “0” clearing target even when the clear processing (step S105, step S117) of the main RAM 65 is executed.

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

  If an affirmative determination is made in step S2003, "1" is set to the repeated change flag provided in the main RAM 65 (step S2004). The repeated change flag is a flag for the main CPU 63 to specify that the repeated change notification should be notified. The repeated change flag is excluded from the “0” clearing target even when the clear processing (step S105, step S117) of the main RAM 65 is executed.

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

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

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

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

  The main CPU 63 may execute the repeated change monitoring process according to the present embodiment, and the management CPU 112 may execute the repeated change monitoring process according to the third embodiment. Thereby, it becomes possible to strictly monitor whether or not the new setting of the pachinko machine 10 is repeatedly performed in a short period.

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

  FIG. 38 is a flowchart showing a setting update recognition process in the present embodiment, which is executed by the management CPU 112.

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

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

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

  If an affirmative determination is made in step S2105, it is determined whether or not a predetermined number or more of predetermined history information exists in the history memory 117 (step S2106). Specifically, the setting of the pachinko machine 10 is performed by counting the number of history information storage areas 125 in which the correspondence information indicating the start of game times is stored in the history area 124 of the history memory 117. The number of game times executed since the state was set last time is grasped, and further, it is determined whether or not the grasped number of game times exceeds a reference number (specifically, 100 times). However, the present invention is not limited to this, and the number of history information storage areas 125 in which correspondence information indicating that game balls are discharged from the game area PA is stored is a reference number (specifically, 1000). It is good also as a structure which determines whether it is over in step S2106. Corresponding relationship information indicating that a game ball has entered a predetermined ball entering portion (for example, any of the out port 24a, the general winning port 31, the first operating port 33, the second operating port 34, or a predetermined combination). In step S2106, it may be determined whether or not the number of history information storage areas 125 storing the number exceeds a reference number (specifically, 1000). Further, it may be configured to determine whether or not the total reference number of history information stored in the history memory 117 (specifically, 1000) is exceeded in step S2106.

  In the case where the number of game times executed after the new setting of the setting state of the pachinko machine 10 is within the reference number, the event in which the new setting is performed continues beyond the notification reference value. However, the present invention is not limited to this, and the total discharge of game balls discharged from the game area PA after a new setting of the pachinko machine 10 is performed is not limited to this. In a situation where the number is within the reference number, when the event in which the new setting is performed continues beyond the notification reference value, the corresponding notification may be executed. In addition, after a new setting of the setting state of the pachinko machine 10 is performed, a predetermined entry part (for example, one of the out port 24a, the general winning port 31, the first operating port 33, the second operating port 34, or a predetermined In a situation where the total number of game balls discharged into the combination) is within the reference number, and the event where the new setting is made continues beyond the notification reference value, the corresponding notification may be executed. Good. In addition, an event that the new setting is performed in a situation where the total number of history information newly stored in the history memory 117 after the new setting state of the pachinko machine 10 is within the reference number is notified. A configuration may be adopted in which notification corresponding to the reference value is executed when the reference value is exceeded.

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

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

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

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

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

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

  Note that the process of step S2109 may be executed on condition that the processes of step S2107 and step S2108 have been executed. That is, the history information stored in the history memory 117 is erased on condition that a predetermined number or more of history information is stored in the history memory 117. Thereby, even if a new setting state of the pachinko machine 10 is repeatedly set in a short period, the history information in the history memory 117 can be prevented from being deleted.

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

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

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

  FIG. 40 is a flowchart showing history setting processing in the present embodiment, which is executed by the management CPU 112.

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

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

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

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

  If an affirmative determination is made in step S2204, the corresponding sum counter is added (step S2205). In the addition process, one of the counter values corresponding to the current value of the check target counter among the first to fourteenth counters 141a to 141n for summation in the summation area 141 of the history memory 117 is added. For example, if the value of the check target counter is “11”, the eleventh counter 141k for summation is an addition target, and if the value of the check target counter is “5”, the fifth counter 141e for summation is an addition target. If the value of the check target counter is “1”, the total first counter 141a is an addition target.

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

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

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

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

  When the history setting process is executed as described above, the number of game balls that enter the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34, and the opening and closing are executed. The number of occurrences of the mode, the number of occurrences of the high frequency support mode, and the number of occurrences of the game times are not stored as history information as in the first embodiment but are stored as number information. As a result, the storage capacity required in the history memory 117 can be reduced as compared with a configuration in which each history information is stored individually.

  As described above, since it is stored as the number information instead of the history information, it is not necessary to execute a process for deriving the number information from the history information when calculating various parameters. Thereby, it is possible to reduce the processing load for calculating various parameters.

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

  When the set value update signal input to the 15th buffer 122o of the input port 121 is switched from the LOW level to the HI level (step S2301: YES), the value of the set value grasping counter of the management side RAM 114 is set to “1”. Setting is performed (step S2302). The setting value grasping counter is a counter for specifying the setting value of the pachinko machine 10 by the management side CPU 112. For example, if the value of the setting value grasping counter is “1”, it means “setting 1”. If the value of the setting value grasping counter is “6”, it means “setting 6”.

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

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

  If an affirmative determination is made in step S 2305, the summation eleventh counter 141 k measuring the number of game times executed in the summation area 141 in the history memory 117 and the opening / closing execution in the summation area 141 in the history memory 117. Each of the eighth counter 141h for counting the number of occurrences of the mode and the ninth counter 141i for totaling the number of occurrences of the high frequency support mode in the summing area 141 in the history memory 117 “0” is cleared (steps S2306 to S2308). As a result, the number of game times, the number of times of opening / closing execution mode, and the number of times of high-frequency support mode are cleared to “0” when a new setting state of the pachinko machine 10 is set. Is done. Accordingly, the thirty-first parameter indicating the number of occurrences of the opening / closing execution mode per unit game time, the forty-first parameter indicating the number of occurrences of the high-frequency support mode per unit game time, and the high-frequency support mode for the number of occurrences of the opening / closing execution mode The calculation result of the forty-second parameter indicating the ratio of the number of occurrences corresponds to the game content after the new setting of the pachinko machine 10 is set. In the configuration in which the winning probability of the jackpot result is changed when the set value of the pachinko machine 10 is changed, the calculation results of the 31st parameter, the 41st parameter, and the 42nd parameter are the setting state of the pachinko machine 10 as described above. As a result, the calculation results of the 31st parameter, the 41st parameter, and the 42nd parameter are appropriate based on the current setting value. It is possible to determine whether or not.

  On the other hand, even if a new setting state of the pachinko machine 10 is performed, the history memory 117 has counters other than the total eighth counter 141h, the total ninth counter 141i, and the eleventh counter 141k. “0” is not cleared. Thereby, the management of the number or frequency of entering the game balls into each history target entrance part is performed based on the long-term game history without being affected by the new setting of the setting state of the pachinko machine 10. It becomes possible.

  According to the above configuration, the number of game balls that enter the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33 and the second operating port 34, the number of occurrences of the opening / closing execution mode, and the high frequency support The number of occurrences of the mode and the number of occurrences of the game times are not stored as history information as in the first embodiment, but are stored as number of times information. As a result, the storage capacity required in the history memory 117 can be reduced as compared with a configuration in which each history information is stored individually.

  Further, since the configuration is such that the number information is stored instead of the history information, it is not necessary to execute a process for deriving the number information from the history information when calculating various parameters. Thereby, it is possible to reduce the processing load for calculating various parameters.

  Information about the number of game times, the number of times of opening / closing execution mode, and the number of times of occurrence of high-frequency support mode is cleared to “0” when a new setting state of the pachinko machine 10 is set. Accordingly, the thirty-first parameter indicating the number of occurrences of the opening / closing execution mode per unit game time, the forty-first parameter indicating the number of occurrences of the high-frequency support mode per unit game time, and the high-frequency support mode for the number of occurrences of the opening / closing execution mode The calculation result of the forty-second parameter indicating the ratio of the number of occurrences corresponds to the game content after the new setting of the pachinko machine 10 is set. In the configuration in which the winning probability of the jackpot result is changed when the set value of the pachinko machine 10 is changed, the calculation results of the 31st parameter, the 41st parameter, and the 42nd parameter are the setting state of the pachinko machine 10 as described above. As a result, the calculation results of the 31st parameter, the 41st parameter, and the 42nd parameter are appropriate based on the current setting value. It is possible to determine whether or not.

  On the other hand, even if a new setting state of the pachinko machine 10 is performed, the history memory 117 has counters other than the total eighth counter 141h, the total ninth counter 141i, and the eleventh counter 141k. “0” is not cleared. Thereby, the management of the number or frequency of entering the game balls into each history target entrance part is performed based on the long-term game history without being affected by the new setting of the setting state of the pachinko machine 10. It becomes possible.

  The configuration of the history memory 117 as in the present embodiment may be applied to the first to fifth embodiments and the embodiments described after the present embodiment. For example, when applied to the first embodiment, even if a new setting state of the pachinko machine 10 is set, the information in the history memory 117 is maintained as it is. Further, when applied to the third embodiment, when a new setting state of the pachinko machine 10 is set, the entire history memory 117 is cleared to “0”.

  Moreover, it is good also as a structure by which the process of step S2306-step S2308 is performed in the process for a setting update recognition (FIG. 41) when the setting value of the pachinko machine 10 is changed. As a result, even if a new setting state of the pachinko machine 10 is set, if the setting value is not changed before and after that, information on the number of executions of the game times, information on the number of occurrences of the opening / closing execution mode, and high frequency support The information on the number of occurrences of the mode is not cleared to “0”, and when the set value of the pachinko machine 10 is changed, the information on the number of executions of the game times, the information on the number of occurrences of the opening / closing execution mode, and the high frequency support mode It is possible to clear the information on the number of occurrences of “0”.

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

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

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

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

  Each of the history memories 181 to 186 for the settings 1 to 6 is provided with a combination of the history area 124 and the pointer area 126 of the history memory 117 in the first embodiment. As a result, it is possible to store history information corresponding to each of the setting states of the pachinko machine 10 of “Setting 1” to “Setting 6”. In this case, when a new setting of the setting state of the pachinko machine 10 is performed, the history memories 181 to 186 corresponding to the setting value for which the new setting has been performed are stored as history information. The history information can be stored separately for each set value without deleting the history information when the setting state of the pachinko machine 10 is newly set. Further, since various parameters are calculated using the history information corresponding to the setting state of the pachinko machine 10 that is currently set, it is possible to appropriately derive various parameters corresponding to each setting value.

  In addition, in each of the history memories 181 to 186 for the settings 1 to 6, the total area 141, the first state area 142, the second state area 143, and the third state area 144 in the sixth embodiment. It is good also as a structure by which these combinations are set.

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

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

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

  When a negative determination is made in step S2403, or when the process of step S2404 is executed, based on the input states of the first to eighth signals input to the first to eighth buffers 122a to 122h of the input port 121. Then, it is determined whether a set value identification end command has been received from the main CPU 63 (step S2405). If a negative determination is made in step S2405, the process returns to step S2403.

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

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

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

  According to the above configuration, history memories 181 to 186 for settings 1 to 6 are provided as the history memory 117 so as to correspond to “setting 1” to “setting 6”, respectively. Thereby, it becomes possible to store the game history corresponding to each of the setting states of the pachinko machine 10 of “Setting 1” to “Setting 6”. In this case, when a new setting of the setting state of the pachinko machine 10 is performed, the history memories 181 to 186 corresponding to the setting value for which the new setting has been performed are stored as history information. The history information can be stored separately for each set value without deleting the history information when the setting state of the pachinko machine 10 is newly set. Further, since various parameters are calculated using the history information corresponding to the setting state of the pachinko machine 10 that is currently set, it is possible to appropriately derive various parameters corresponding to each setting value.

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

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

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

  As the history memory 117, a first history memory 191 and a second history memory 192 are provided. Each of the first history memory 191 and the second history memory 192 is provided with a combination of the history area 124 and the pointer area 126 of the history memory 117 in the first embodiment. In this case, a new setting of the setting state of the pachinko machine 10 is performed in a situation where history information is stored using one of the first history memory 191 and the second history memory 192. If the history information is stored, the history information in the one history memory 191 or 192 is not deleted until a predetermined number or more of history information is stored in the other history memory 191 or 192. The history information can be newly stored in both the history memories 191 and 192 until a predetermined number or more of history information is stored in the other history memory 191 and 192. Become.

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

  When the set value update signal input to the 15th buffer 122o of the input port 121 is switched from the LOW level to the HI level (step S2501: YES), the value of the set value grasping counter provided in the management side RAM 114 is set to “ 1 "(step S2502). The setting value grasping counter is a counter for specifying the setting value of the pachinko machine 10 by the management side CPU 112. For example, if the value of the setting value grasping counter is “1”, it means “setting 1”. If the value of the setting value grasping counter is “6”, it means “setting 6”.

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

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

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

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

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

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

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

  Thereafter, a history setting execution process is executed for the memory for history 191 and 192 to be stored (step S2603). Specifically, the process from step S1101 to step S1112 of the history setting process (FIG. 26) in the first embodiment is executed on one of the history memories 191 and 192 to be stored. As a result, history information is stored in one of the history memories 191 and 192 to be stored.

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

  When the process of step S2603 is executed, or when the process of step S2604 is executed, it is determined whether or not “1” is set in the setting change occurrence flag of the calculation result memory 131 (step S2605). If an affirmative determination is made in step S2605, it is determined whether or not a predetermined number or more of ball discharge histories exist in the non-memory target history memories 191 and 192 (step S2606). Specifically, when the value of the storage target flag in the calculation result memory 131 is “0”, the first history memory 191 is a storage target, so the game area PA is stored in the second history memory 192. It is determined whether or not the history information indicating that the game ball has been discharged from is stored a predetermined number (specifically, “1000”) or more. Further, when the value of the storage target flag in the calculation result memory 131 is “1”, the second history memory 192 is a storage target, and therefore, the game ball from the game area PA to the first history memory 191. It is determined whether or not the history information indicating that has been discharged is stored a predetermined number (specifically, “1000”) or more. In addition, it is not determined whether or not a predetermined number (specifically, “1000”) of history information indicating that game balls have been discharged from the game area PA is stored, but game times have been executed. It is good also as a structure which determines whether the log | history information which shows is stored more than predetermined number (specifically "100").

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

  After that, a clear process is executed on the first history memory 191 and the second history memory 192 that have been stored until then (step S2608). Specifically, if the value of the storage target flag is “0”, the second history memory 192 is cleared to “0”, and if the value of the storage target flag is “1”, the first history memory 191 is set to “ Clear “0”. Thereafter, the setting change occurrence flag in the calculation result memory 131 is cleared to “0” (step S2609).

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

  If it is the calculation timing (step S2701: YES), the storage side of the first history memory 191 and the second history memory 192 is grasped (step S2702). Specifically, if the value of the storage target flag in the calculation result memory 131 is “0”, the first history memory 191 is grasped as a storage target, and if the value of the storage target flag is “1”, the second The history memory 192 is grasped as a storage target. Thereafter, steps S1402 to S1412 of the display output process (FIG. 30) in the first embodiment are executed using the history information stored in the memory histories 191 and 192 to be stored grasped in step S2702. As a result, various parameters (first to eighth parameters, 11th to 18th parameters, 21st to 26th parameters, 31st parameter, 41st to 42nd parameters) are calculated, and the calculated various parameters are calculated. The result is stored in the result memory 131 (step S2703). In this case, history information is stored in both the first history memory 191 and the second history memory 192 because the setting change occurrence flag of the calculation result memory 131 is set to “1”. Even if there are, various parameters are calculated using one of the history memories 191 and 192 that are stored.

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

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

  On the other hand, according to the above configuration, even if a new setting state of the pachinko machine 10 is repeatedly performed in a short period so as not to appropriately calculate various parameters, The memories 191 and 192 are maintained without being changed. Thereby, even if new setting of the setting state of the pachinko machine 10 is repeatedly performed in a short period, it is possible to appropriately derive the management result of the game history so far.

  The history memory 117 is not limited to the configuration in which the two memories of the first history memory 191 and the second history memory 192 are provided, and the first history is stored in one memory. The first history area corresponding to the storage memory 191 and the second history area corresponding to the second history memory 192 may be set.

  Further, only one history memory 117 may be provided. In this case, a new setting of the pachinko machine 10 is performed when the total number of game balls discharged from the game area PA exceeds a predetermined number after the new setting of the pachinko machine 10 is set. It is also possible to adopt a configuration in which history information before the timing at which the information is released is erased, and history information after the timing at which the setting is made is stored and retained without being erased. Thereby, the history before the timing when the new setting state of the pachinko machine 10 is set at the timing when a predetermined number or more of history information is accumulated after the new setting of the setting state of the pachinko machine 10 is performed. Information can be erased. Further, the history information corresponding to the history information is stored in the history memory 117 at the timing when the setting state of the pachinko machine 10 is newly set, so that the new setting state is set in the history memory 117. It is possible to distinguish between history information before and after the timing at which is performed.

  In addition, the timing of erasing the history information is limited to a case where the total number of game balls discharged from the game area PA after the new setting of the setting state of the pachinko machine 10 is greater than or equal to a predetermined number. Alternatively, the number of game times executed after the new setting of the setting state of the pachinko machine 10 may be a predetermined number or more.

  Further, even when a new setting state of the pachinko machine 10 is set, if the setting value is not changed before and after that, the change of the history memory 191 and 192 as described above and the history information are changed. When the setting state of the pachinko machine 10 is newly set and the setting value is changed before and after the setting, the history memories 191 and 192 to be stored as described above are not erased. The change and the deletion of the history information may be performed.

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

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

  The first to seventh buffers 122a to 122g and the sixteenth buffer 122p receive the same types of signals as in the first embodiment. Specifically, the first buffer 122a receives a first signal corresponding to the detection result of the first winning opening detection sensor 42a, and the second buffer 122b receives the first signal corresponding to the detection result of the second winning opening detection sensor 43a. The second signal is input, the third signal corresponding to the detection result of the third prize opening detection sensor 44a is input to the third buffer 122c, and the fourth signal corresponding to the detection result of the special electricity detection sensor 45a is input to the fourth buffer 122d. The fifth buffer 122e receives a fifth signal corresponding to the detection result of the first working port detection sensor 46a, and the sixth buffer 122f corresponds to the detection result of the second working port detection sensor 47a. The sixth signal is input, the seventh buffer 122g is input with the seventh signal corresponding to the detection result of the out port detection sensor 48a, and the sixteenth buffer 122p is instructed to output. No. is input.

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

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

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

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

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

  In the present embodiment, when the management CPU 112 recognizes the type of signal input to the first buffer 122a to the tenth buffer 122j, the number of winning balls set for the pitching portion corresponding to the type of signal. The type identification signal is output the same number of times. The management CPU 112 stores information corresponding to the number of times of receiving the type identification signal for each of the first buffer 122a to the tenth buffer 122j in the first to tenth correspondence areas 123a to 123j of the correspondence memory 116. . In other words, the type of signal input to the first buffer 122a to the tenth buffer 122j is grasped as the number of winning balls set for the pitching part corresponding to the type of signal.

  In step S2803, when the value of the recognition output counter is “10”, “9”, or “8”, “10” corresponding to the number of prize balls in the general winning opening 31 is set in the output number counter. . When the value of the output counter for recognition is “7”, “15” corresponding to the number of prize balls of the special electricity prize winning device 32 is set in the output number counter. When the value of the recognition output counter is “6”, “1” corresponding to the number of prize balls in the first operation port 33 is set in the output number counter. When the value of the recognition output counter is “5”, “1” corresponding to the number of prize balls in the second operation port 34 is set in the output number counter. Further, when the value of the recognition output counter is “4”, since the game ball is not paid out even if the game ball enters the out port 24a although it corresponds to the out port 24a, the output counter Set “0” to. Further, when the value of the recognition output counter is any of “3” to “1”, there is no corresponding entrance portion and it is blank, so “0” is set in the output number counter.

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

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

  Thereafter, 1 is subtracted from the value of the output number counter of the main RAM 65 (step S2807), and it is determined whether or not the value of the output number counter after the 1 subtraction is “0” (step S2808). When the value of the output number counter is 1 or more (step S2808: NO), the process returns to step S2806.

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

  Thereafter, 1 is subtracted from the value of the recognition output counter in the main RAM 65 (step S2810), and it is determined whether or not the value of the recognition output counter after the 1 subtraction is “0” (step S2811). If the value of the recognition output counter is 1 or more (step S2811: NO), the process returns to step S2803 to execute processing for recognizing the type of signal corresponding to the value of the recognition output counter after 1 subtraction. To do.

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

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

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

  When reception of the identification start signal from the main CPU 63 is completed (step S2901: YES), the value of the setting target counter in the management RAM 114 is cleared to “0” (step S2903). Thereafter, on condition that the start trigger signal is received from the main CPU 63 (step S2904: YES), the process proceeds to step S2905. In step S2905, it is determined whether a type identification signal is received from the main CPU 63 or not. When the type identification signal is received (step S2905: YES), 1 is added to the value of the reception number counter provided in the management side RAM 114 (step S2906). The reception counter is a counter for the management CPU 112 to specify the number of times the type identification signal is received from the main CPU 63. The value of the reception number counter is cleared to “0” when an affirmative determination is made in step S2904.

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

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

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

  As the supply of operating power to the main CPU 63 and the management CPU 112 is started, as shown in FIG. 51A, FIG. 51D, and FIG. The output states of the open / close execution mode signal and the high frequency support mode signal are changed from the LOW level to the HI level. Thereby, the output of the identification start signal from the main CPU 63 to the management CPU 112 is started. Thereafter, at timing t2, the output state of the first signal, the opening / closing execution mode signal, and the high frequency support mode signal is changed from the HI level to the LOW bell. Thereby, the output of the identification start signal from the main CPU 63 to the management CPU 112 is stopped. At the timing of t2, the management-side CPU 112 makes an affirmative determination in step S2901 of the management process (FIG. 50) to enter the identification state as shown in FIG. 51 (f).

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

  Thereafter, the output state of the third signal is maintained at the HI level as shown in FIG. 51C from the timing t8 to the timing t10. As a result, a termination trigger signal is output to the management CPU 112. In this case, the correspondence setting process is executed by the management CPU 112 as shown in FIG. Since the value of the reception number counter is “1” at the timing when the corresponding relationship setting process is executed, “1” is set as the corresponding relationship information in the corresponding relationship areas 123 a to 123 j in the corresponding relationship memory 116. Is stored.

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

  Thereafter, the output state of the third signal is maintained at the HI level as shown in FIG. 51 (c) from the timing t25 to the timing t27. As a result, a termination trigger signal is output to the management CPU 112. In this case, the correspondence setting process is executed by the management CPU 112 as shown in FIG. Since the value of the reception number counter is “10” at the timing when the corresponding relationship setting process is executed, “10” is set as the corresponding relationship information in the corresponding relationship areas 123a to 123j in the corresponding relationship memory 116. Is stored.

  Thereafter, at the timing of t28, as shown in FIGS. 51 (c), 51 (d), and 51 (e), the output state of the third signal, the open / close execution mode signal, and the high frequency support mode signal is LOW. Change from level to HI level. Thereby, the output of the identification end signal from the main CPU 63 to the management CPU 112 is started. Thereafter, at timing t29, the output state of the third signal, the opening / closing execution mode signal, and the high frequency support mode signal is changed from the HI level to the LOW bell. Thereby, the output of the identification end signal from the main CPU 63 to the management CPU 112 is stopped. At the timing of t29, the management CPU 112 makes an affirmative determination in step S2910 of the management process (FIG. 50), so that the identification state is canceled as shown in FIG.

  In this embodiment, since the information on the number of prize balls is stored as the correspondence information, the history information stored in the history memory 117 includes a prize ball corresponding to the entry part that triggered the storage of the history information. Number information is included as correspondence information. In this configuration, when there are a plurality of types of pitched portions having the same number of winning balls, the pitched portions cannot be distinguished in the history information. Specifically, since the first working port 33 and the second working port 34 each have one winning ball, it is possible to distinguish the first working port 33 and the second working port 34 in the history information. Can not. Under such circumstances, the number of prize balls of the first working port 33 and the second working port 34 may be different. Thereby, even if it is the structure where history information like this embodiment is stored, it becomes possible to distinguish the 1st operation port 33 and the 2nd operation port 34 in history information.

  According to the present embodiment described in detail above, not only the set value update signal and the output instruction signal, but also information corresponding to whether or not the game round has been started, information corresponding to whether or not the opening / closing execution mode is in progress, Regarding the information corresponding to whether or not the high frequency support mode is being performed and the information corresponding to whether or not the front door frame 14 is being opened, the main CPU 63 indicates that the signal path corresponds to the information. Even if the corresponding relationship information is not received, the management CPU 112 can specify the correspondence information. In this case, only information corresponding to the detection results of the respective ball detection sensors 42a to 48a is information that requires the management CPU 112 to recognize the correspondence between the information and the signal paths 118a to 118j from the main CPU 63. Become. When the management side CPU 112 is made to recognize the correspondence information, the same number of pulse signals as the number of winning balls corresponding to each of the entrance detection sensors 42a to 48a are transmitted from the main CPU 63 to the management CPU 112 using the second signal. Is output. Thereby, it becomes possible to simplify the structure regarding transmission of correspondence information.

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

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

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

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

  With the above-described configuration, the detection results of the respective ball detection sensors 42a to 48a are input to the management IC 66 without any processing by the main CPU 63. As a result, the main CPU 63 executes processing for causing the management side CPU 112 to recognize the respective winning results of the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33 and the second operating port 34. Therefore, the processing load on the main CPU 63 can be reduced.

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

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

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

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

  Each of the first to fourth notification display devices 201 to 204 is a segment display in which seven LED display segments are arranged, but is not limited to this, and is a single multicolor light emitting type. It may be a light emitter, a liquid crystal display device, or an organic EL display. Each of the first to fourth notification display devices 201 to 204 is installed such that its display surface faces the direction in which the element mounting surface of the main control board 61 faces, and by the opposing wall portion 60b of the board box 60a. Covered. In this case, since the substrate box 60a is formed transparently, the display surfaces of the first to fourth notification display devices 201 to 204 accommodated in the substrate box 60a are visually observed from the outside of the substrate box 60a. It becomes possible. The main control device 60 is mounted on the back surface of the resin base 21 so that the opposing wall portion 60b facing the element mounting surface of the main control board 61 faces the rear of the pachinko machine 10 in the board box 60a. When the main body 12 is opened to the front of the pachinko machine 10 with respect to the outer frame 11 and the back surface of the resin base 21 is exposed to the front of the pachinko machine 10, the first to fourth notification display devices 201 are provided through the opposing wall portion 60b. The display surface of ~ 204 can be visually observed.

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

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

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

  In detail about the display contents of the third notification display device 203 and the fourth notification display device 204, the number corresponding to the tenth digit is the third notification value among the values obtained by multiplying the parameter to be notified by 100. A number displayed on the display device 203 and corresponding to the first digit is displayed on the fourth notification display device 204.

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

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

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

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

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

  However, the present invention is not limited to this configuration, and even if the supply of operating power to the pachinko machine 10 is stopped by supplying backup power to the first display IC 205, the display is performed on the first display IC 205. A configuration may be adopted in which data can be stored. In this case, when the supply of the operating power to the pachinko machine 10 is started, the display performed on the first notification display device 201 immediately before the supply of the operating power of the pachinko machine 10 is stopped The first notification display device 201 is started.

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

  However, the present invention is not limited to this configuration, and even if the supply of operating power to the pachinko machine 10 is stopped by supplying backup power to the second display IC 206, the display is performed on the second display IC 206. A configuration may be adopted in which data can be stored. In this case, when the supply of the operating power to the pachinko machine 10 is started, the display performed on the second notification display device 202 immediately before the supply of the operating power of the pachinko machine 10 is stopped The second notification display device 202 is started.

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

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

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

  However, the present invention is not limited to this configuration, and even if the supply of operating power to the pachinko machine 10 is stopped by supplying backup power to the fourth display IC 208, the display is performed on the fourth display IC 208. A configuration may be adopted in which data can be stored. In this case, when the supply of the operating power to the pachinko machine 10 is started, the display performed on the fourth notification display device 204 immediately before the supply of the operating power of the pachinko machine 10 is stopped The fourth notification display device 204 starts.

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

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

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

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

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

  If a negative determination is made in step S3004, or if the process of step S3005 is executed, display data corresponding to the type of parameter corresponding to the value of the display target counter is read from the management ROM 113 (step S3006). Then, display data setting processing corresponding to the first notification display device 201 is executed (step S3007), and display data setting processing corresponding to the second notification display device 202 is executed (step S3008). For example, if the value of the display target counter is “0” and the first parameter is a display target, display data for displaying “A” on the first notification display device 201 is displayed in the first display IC 205. In addition to outputting, display data for displaying “1” on the second notification display device 202 is output to the second display IC 206. For example, if the value of the display target counter is “24” and the forty-second parameter is a display target, display data for displaying “O” on the first notification display device 201 is displayed in the first display. While outputting to IC205, the display data for displaying "2" on the 2nd alerting display apparatus 202 are output to 2nd display IC206.

  Thereafter, the parameter corresponding to the value of the display target counter is read from the calculation result memory 131, and the display data corresponding to the 10th place and the display data corresponding to the 1st place are obtained by multiplying the read parameter by 100. Read from the management-side ROM 113 (step S3009). Then, display control is performed on the third notification display device 203 so that the number corresponding to the tenth digit of the result is displayed (step S3010), and the fourth corresponding to the number corresponding to the first digit is displayed. Display control of the notification display device 204 is performed (step S3011). For example, when the result obtained by multiplying by 100 is “53”, display data for displaying “5” on the third notification display device 203 is output to the third display IC 207 and also displayed on the fourth notification display device 204. Display data for displaying “3” is output to the fourth display IC 208.

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

  By executing the display process as described above, the management results of the game history are displayed on the first to fourth notification display devices 201 to 204. The management result of the game history is displayed regardless of whether or not the game is continued, and the main body 60 is opened from the front of the pachinko machine 10 by opening the gaming machine main body 12 with respect to the outer frame 11. This is done regardless of whether it is visible. As described above, the display control of the first to fourth notification display devices 201 to 204 is executed regardless of the game situation and the state of the pachinko machine 10, thereby the first to fourth notification display devices 201. It is possible to simplify the processing configuration for display control of .about.204.

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

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

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

  First, the extinguishing process of the first to third notification display devices 201 to 203 is executed (step S3101). Specifically, display data that is all “0” is output to the first to third display ICs 205 to 207. As a result, the display segments of the first to third notification display devices 201 to 203 are all turned off, and the first to third notification display devices 201 to 203 are not displayed. Immediately after the supply of operating power to the pachinko machine 10 is started, the display segments of the first to fourth notification display devices 201 to 204 are all turned off, and the first to fourth notification display devices 201 are displayed. ˜204 is a non-display state. Therefore, step S3101 is a process of maintaining the first to third notification display devices 201 to 203 in a non-display state, and if any of the first to third notification display devices 201 to 203 is temporarily affected, If it is in the display state, it is a process of making it non-display state.

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

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

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

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

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

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

  In the display start processing, a management result display start command is transmitted from the main CPU 63 to the management CPU 112. The management-side CPU 112 that has received the management result display start command executes processing for displaying the first parameter among the various parameters stored in the calculation result memory 131. The processing contents in this case are the same as steps S3006 to S3012 in the display processing (FIG. 55). Thereby, the display corresponding to the 1st parameter calculated just before the operating electric power of the pachinko machine 10 was stopped last time is performed on the display devices 201 to 204 for notification.

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

  When the management result of the game history is displayed, at least one display segment is in a light emitting state in each of the first to fourth notification display devices 201 to 204 as shown in FIG. That is, each of the first to fourth notification display devices 201 to 204 is in a display state. This is the same even when any of the first to eighth parameters, the first to eighteenth parameters, the twenty-first to twenty-sixth parameters, the thirty-first parameter, and the forty-first to forty-second parameters is a notification target. . Thereby, the manager of the game hall visually observes that all of the first to fourth notification display devices 201 to 204 are in the display state, so that in the first to fourth notification display devices 201 to 204, It is possible to grasp that the management result of the game history is displayed.

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

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

  When the supply of operating power to the pachinko machine 10 is started with the setting key insertion portion 68a being turned on, the setting state of the pachinko machine 10 is changed at the timing t1 as shown in FIG. Can be changed. At the timing t1, the setting display update timing is reached as shown in FIG. 58B, the fourth notification display device 204 is in the display state as shown in FIG. 58H, and the display state is continued. In this case, since “setting 1” is selected, “1” is displayed on the fourth notification display device 204. On the other hand, at the timing t1, as shown in FIGS. 58 (e) to 58 (g), the first to third notification display devices 201 to 203 are not displayed, that is, all display segments are turned off. Maintained.

  Thereafter, an operation for changing the set value is performed by operating the update button 68b at each of the timing t2, the timing t3, the timing t4, and the timing t5, and as shown in FIG. This is the update timing of the set value display. In this case, as shown in FIG. 58 (h), in the fourth notification display device 204, the display content is switched to a number corresponding to the set value after the change at each timing. The fourth notification display device 204 is maintained in the display state including the respective timings when. On the other hand, as shown in FIGS. 58 (e) to 58 (g), the first to third notification display devices 201 to 203 are in a non-display state, that is, for all display, at each of the update timings of the set value display. The segment is kept off.

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

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

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

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

  This corresponds to the period in which the game history management results are displayed on the first to fourth notification display devices 201 to 204 and the setting value changeable state on the first to fourth notification display devices 201 to 204. It is distinguished from the period during which the display is performed. Thereby, any display is performed in the first to fourth notification display devices 201 to 204 by grasping the situation in which the display is performed in the first to fourth notification display devices 201 to 204. It is possible to specify whether or not

  When the display corresponding to the changeable state of the setting value is performed, the first to fourth notification display devices 201 to 204 are configured so as to have a display mode different from the display mode when the management result of the game history is displayed. Display controlled. Thereby, by identifying the display mode of the first to fourth notification display devices 201 to 204, it is specified which display is being performed on the first to fourth notification display devices 201 to 204. It becomes possible.

  A plurality of notification display devices 201 to 204 are provided. This makes it possible to perform a wide variety of displays as displays corresponding to the game history management results. Further, since there are a plurality of notification display devices 201 to 204, the display mode is greatly increased when the management result of the game history is displayed and when the display corresponding to the setting value changeable state is performed. It is possible to make it different.

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

  When the display corresponding to the setting value changeable state is performed, the fourth notification display device 204 is in the display state, and the display content is the fourth notification display device 204 when the management result of the game history is displayed. This is the display content that can be displayed. In this way, by allowing the display contents on the fourth notification display device 204 to overlap, each of the case where the management result of the game history is displayed and the case where the display corresponding to the setting value changeable state is performed are performed. It becomes possible not to give restrictions to the display contents. In addition, even if the display contents in the fourth notification display device 204 can overlap, the first to third notification display devices are displayed when the display corresponding to the setting value changeable state is performed. Since 201 to 203 are in a non-display state, it is possible to specify which display is being performed on the first to fourth notification display devices 201 to 204.

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

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

  When the display corresponding to the setting value changeable state is performed, only one of the fourth notification display devices 204 is in the display state. Thereby, it becomes easy to grasp whether or not the display corresponding to the setting value changeable state is performed.

  In the configuration in which the first to fourth notification display devices 201 to 204 are arranged in the horizontal direction, the display corresponding to the setting value changeable state is performed using only the fourth notification display device 204 arranged at the right end. Done. Thereby, it becomes easy to grasp whether or not the display corresponding to the setting value changeable state is performed.

  When the management result of the game history is displayed, the display corresponding to the type of the management result of the game history to be displayed is performed using the first notification display device 201 and the second notification display device 202. Using the third notification display device 203 and the fourth notification display device 204, a display corresponding to the content of the management result of the game history is performed. Thereby, it becomes easy to grasp the management result of the game history. In this case, in the setting value changeable state, both the first notification display device 201 and the second notification display device 202 that display the type of management result of the game history are not displayed. Thereby, the non-display state of the first and second notification display devices 201 and 202 for displaying the type corresponds to the changeable state of the set value, and corresponds to the changeable state of the set value. It becomes easy to grasp that the display is performed.

  When the display corresponding to the changeable state of the set value is performed, not only the first notification display device 201 and the second notification display device 202 on which the type of the management result of the game history is displayed, but also the game The third notification display device 203 on which the contents of the history management results are displayed is also hidden. Thereby, it becomes easy to grasp that the display corresponding to the setting value changeable state is performed.

  Display data is output from the MPU 62 to the first to fourth display ICs 205 to 208, and the first to fourth display ICs 205 to 208 perform predetermined display on the first to fourth notification display devices 201 to 204 according to the display data. In the configuration, the display data is stored and held in the first to fourth display ICs 205 to 208. Thereby, for example, even when the execution of processing for advancing the game is stopped in the main CPU 63 due to occurrence of radio wave detection abnormality or vibration detection abnormality (when an affirmative determination is made in step S306), It becomes possible to maintain the display of the game history management results in the first to fourth notification display devices 201 to 204.

  Of the first to fourth notification display devices 201 to 204, the objects that are not displayed (all unlit) in the changeable state in which the setting state of the pachinko machine 10 can be changed are the first to fourth notification devices. It is good also as the 1st, 2nd information display apparatus 201,202, without being limited to the 3rd information display apparatus 201-203. In this case, the third notification display device 203 performs a predetermined display (for example, “5”) that is different from the content of the current setting value, and the fourth notification display device 204 displays the current setting value. The fourth notification display device 204 may perform a predetermined display (for example, a display of “5”) different from the content of the current set value, and the third notification. The display device 203 may be configured to display numbers corresponding to the current set values. In addition, the first notification display device 201 and the third notification display device 203 are in a non-display state (all-off state), and the second notification display device 202 and the fourth notification display device 204 are in a display state. The first notification display device 201 and the fourth notification display device 204 are in a non-display state (all off state), and the second notification display device 202 and the third notification display device 203 are in the display state. The second notification display device 202 and the third notification display device 203 are in a non-display state (all-off state), and the first notification display device 201 and the fourth notification display device 204 are displayed. The second notification display device 202 and the fourth notification display device 204 may be in a non-display state (all-off state), and the first notification display device 201 and the third notification display device 203 Is displayed It may be configured.

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

  In the changeable state in which the setting state of the pachinko machine 10 can be changed, only the first notification display device 201 may be in the display state, and only the second notification display device 202 is displayed. It may be configured to be in a state, or only the third notification display device 203 may be in a display state.

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

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

  As shown in FIG. 59A, the first notification display device 201 includes seven first to seventh display segments 201a to 201g. Each of the first to seventh display segments 201a to 201g is formed in a bar shape and has a light emitter such as an LED inside. The seven first to seventh display segments 201a to 201g are arranged so that the first notification display device 201 is a so-called seven-segment display.

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

  FIG. 60 shows a case where the management result of the game history is displayed on the first to fourth notification display devices 201 to 204 and a case where a changeable state in which the setting state of the pachinko machine 10 can be changed is displayed. It is explanatory drawing for demonstrating the display content of the display apparatus 201 for 1st notifications and the display apparatus 202 for 2nd notifications.

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

  In this case, each of the first to seventh display segments 201a to 201g of the first notification display device 201 is “A”, “E”, “H”, “L”, At least one of the “O” displays is a light emission target. That is, the display segments 201a to 201g that are not the light emission target even when any of “A”, “E”, “H”, “L”, and “O” is displayed on the first notification display device 201 are displayed. Does not exist.

  Similarly, for the second notification display device 202, the first to seventh display segments 202a to 202g of the second notification display device 202 are “1” to “8” in the second notification display device 202, respectively. Among these displays, at least one kind of display is a light emission target. That is, there is no display segment 202a to 202g that is not a light emission target even when any of “1” to “8” is displayed on the second notification display device 202.

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

  In the setting value changeable state, in the second notification display device 202, the third display segment 202c is in a light emitting state. As described above, the third display segment 202c can be in a light emitting state when the management result of the game history is displayed on the second notification display device 202. On the other hand, the display content of the second notification display device 202 in which only the third display segment 202c among the first to seventh display segments 202a to 202g is in the light emitting state exists when displaying the management result of the game history. Not done. As a result, a display mode that is not displayed when the management result of the game history is displayed while using the display segment 202c that can be in the light emitting state when the management result of the game history is displayed in the setting value changeable state. It can be displayed on the second notification display device 202. Therefore, the display corresponding to the changeable state of the set value can be performed on the second notification display device 202 while also using the display segments 202a to 202g used when displaying the management result of the game history. It becomes possible.

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

  First, set value display start processing in the first and second notification display devices 201 and 202 is executed (step S3201). Specifically, for the first notification display device 201, the second display segment 201b and the fifth display segment 201e are in a light emitting state, and the other display segments 201a, 201c, 201d, 201f, and 201g are in an unlit state. Is output to the first display IC 205. For the second notification display device 202, the display data is output to the second display IC 206 in which the third display segment 202 c is in the light emitting state and the other display segments 202 a, 202 b, 202 d to 202 g are in the unlit state. Thereby, the display for alert | reporting that it is a changeable state which can change the setting state of the pachinko machine 10 is started by the display apparatus 201 for 1st notifications and the display apparatus 202 for 2nd notifications.

  Then, the light-off process of the 3rd alerting | reporting display apparatus 203 is performed (step S3202). Specifically, display data that is all “0” is output to the third display IC 207. As a result, all the display segments of the third notification display device 203 are turned off, and the third notification display device 203 is not displayed.

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

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

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

  If the update button 68b has been pressed once (step S3206: YES), the value of the set value counter in the main RAM 65 is incremented by 1 (step S3207). When the value of the set value counter after adding 1 exceeds “6” (step S3208: YES), “1” is set to the set value counter (step S3209). As a result, each time the update button 68b is pressed, the setting value is updated to one level higher. When the update button 68b is pressed once in the state of “setting 6”, the setting value is set to “setting 1”. Will return.

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

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

  In the display start processing, a management result display start command is transmitted from the main CPU 63 to the management CPU 112. The management-side CPU 112 that has received the management result display start command executes processing for displaying the first parameter among the various parameters stored in the calculation result memory 131. The processing contents in this case are the same as steps S3006 to S3012 in the display processing (FIG. 55). Thereby, the display corresponding to the 1st parameter calculated just before the operating electric power of the pachinko machine 10 was stopped last time is performed on the display devices 201 to 204 for notification.

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

  The setting value can be changed by setting the display segments 201a to 201g and 202a to 202g of the first and second notification display devices 201 and 202 that can be in a light emitting state when the management result of the game history is displayed to the light emitting state. A display corresponding to the state is performed. Thereby, when diversifying the display of the management result of the game history, it is possible to minimize the restrictions on the contents of the display corresponding to the management result of the game history. On the other hand, for each of the first notification display device 201 and the second notification display device 202, the display segments 201a to 201g and 202a to be in a light emitting state when the display corresponding to the setting value changeable state is performed. The combination of 202g is a combination that does not exist when the management result of the game history is displayed. Thereby, the management result display of the game history is performed by grasping the combination of the display segments 201a to 201g and 202a to 202g that are in the light emitting state for each of the first notification display device 201 and the second notification display device 202. It is possible to grasp which of the displays corresponding to the changeable state of the set value is being performed.

  For each of the first notification display device 201 and the second notification display device 202, there are display segments 201a to 201g and 202a to 202g that are not in a light emitting state even if the display of the game history management results is performed in all patterns. Not done. As a result, it is possible to minimize the display contents of the management result of the game history as much as possible when diversifying the display corresponding to the management result of the game history.

  When the display corresponding to the setting value changeable state is performed, the third notification display device 203 that is not in the non-display state when the management result of the game history is displayed is in the non-display state. Thereby, not only the display contents of the first notification display device 201 and the second notification display device 202 but also whether or not the third notification display device 203 is in the non-display state, the game history It is possible to clearly identify which one of the management result display and the display corresponding to the setting value changeable state is performed by the first to fourth notification display devices 201 to 204.

  In addition, it is limited to a configuration in which only one type of display content corresponding to the changeable state in which the setting state of the pachinko machine 10 in the first and second notification display devices 201 and 202 can be changed is set. However, a configuration in which a plurality of types are set may be employed. In this case, the display order of the plurality of types of display contents may be determined in advance, and the display contents to be displayed may be changed according to the display order each time a changeable state is newly executed. As described above, even when there are a plurality of types of display contents corresponding to the setting value changeable state, the display contents are displayed in the display segment 201a that is in the light emitting state when the management result of the game history is displayed. -201g and 202a-202g are displayed, and the display contents are not displayed when the management result of the game history is displayed.

  In addition, in one of the case of displaying the management result of the game history and the case of performing the display corresponding to the changeable state in which the setting state of the pachinko machine 10 can be changed, the first and second notification display devices It is good also as a structure by which blink display is performed in 201,202 and the display which maintains lighting is performed on the other. In this case, the game hall manager can specify which of the display of the game history management result and the display corresponding to the changeable state depending on whether it is blinking display or lighting display. The combination of the display segments 201a to 201g and 202a to 202g that are in the light emitting state in the display corresponding to the possible state may be a combination used when displaying the management result of the game history, and management of the game history Combinations that are not used when displaying results may also be used. In addition, the lighting period and the extinguishing period in the blinking display may be the same in the first notification display device 201 and the second notification display device 202, or may be completely shifted. Alternatively, a configuration in which only a part overlaps may be used.

<13th Embodiment>
In the present embodiment, when an abnormal state occurs in the pachinko machine 10, the display corresponding thereto is performed using the first to fourth notification display devices 201 to 204, unlike the eleventh embodiment. Yes. Hereinafter, a configuration different from the eleventh embodiment will be described. The description of the same configuration as that of the eleventh embodiment is basically omitted.

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

  The abnormality display area 211 is an area for storing information on abnormal states to be displayed on the first to fourth notification display devices 201 to 204. In the abnormality display area 211, a plurality of unit areas 211a to 211d are provided. Specifically, a first unit area 211a, a second unit area 211b, a third unit area 211c, and a fourth unit area 211d are provided. Each of the first to fourth unit areas 211a to 211d can store information on the abnormal state of the pachinko machine 10 one by one. That is, the abnormality display area 211 can store and hold up to four pieces of information on the abnormal state of the pachinko machine 10.

  Here, in the present embodiment, the main CPU 63 specifies all information on the abnormal state that occurs in the pachinko machine 10. For example, when an abnormality relating to the payout of the game ball (for example, a full tank in the lower plate 56a, no ball in the tank 75, a payout abnormality by the payout device 76) occurs, a command corresponding to the generated abnormality is issued to the payout CPU 92. To the main CPU 63. Further, the pachinko machine 10 is provided with a radio wave detection sensor and a vibration detection sensor (not shown), and when the radio wave detection sensor detects an improper radio wave, a corresponding abnormal signal is transmitted to the main CPU 63 and an abnormal signal is detected. When vibration is detected by the vibration detection sensor, a corresponding abnormality signal is transmitted to the main CPU 63. Further, based on the fact that normal signal transmission from each of the incoming detection sensors 42a to 49a is not specified, occurrence of disconnection abnormality of the incoming detection sensors 42a to 49a is specified.

  The type of abnormal state specified by the main CPU 63 is larger than the maximum number of abnormal state information that can be stored in the abnormal display area 211. Then, when a large number of abnormal states occur simultaneously, it is assumed that new abnormal information occurs even though the maximum number of abnormal state information is already stored in the abnormal display area 211. On the other hand, for the abnormal state information, the storage priority is set at the setting stage of the pachinko machine 10, and a new number of abnormal state information is already stored in the abnormal display area 211. When an abnormal state occurs, information on the abnormal state having a high storage priority is left in the abnormal display area 211. Thereby, it becomes possible to give priority to the notification of the abnormal state having a high storage priority.

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

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

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

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

  When the value of the abnormality target counter is the maximum value (step S3303: YES), priority comparison processing is executed (step S3304). In the priority comparison process, first, the abnormal state information having the lowest storage priority is specified from the abnormal state information stored in the first to fourth unit areas 211a to 211d of the abnormal display area 211. The storage priority is determined in advance at the design stage of the pachinko machine 10, and specifically, the bottom of the lower plate 56a is full, the ball of the tank 75 is absent, the vibration is detected abnormally, the payout is abnormal due to the payout device 76, and the ball is detected. Storage priority increases in the order of disconnection abnormality of 49a to radio wave detection abnormality. In the priority comparison process, whichever storage priority is higher, the information on the abnormal state with the lowest storage priority stored in the first to fourth unit areas 211a to 211d and the abnormality display target that has occurred this time. To make a comparison.

  When the storage priority of the abnormality display target that has occurred this time is lower (step S3305: NO), information on the abnormal state corresponding to the abnormality display target that has occurred this time is not stored in the abnormality display area 211. Thereby, in the configuration in which the number of types of abnormality display objects is larger than the number of the first to fourth unit areas 211a to 211d provided in the abnormality display area 211, information on the abnormal state having a high storage priority is displayed. It can be left in the abnormality display area 211.

  When the storage priority of the abnormality display target generated this time is higher (step S3305: YES), the abnormality display area 211 setting processing is executed (step S3306). In the setting process of the abnormal display area 211 executed when an affirmative determination is made in step S3305, this occurs in the unit areas 211a to 211d identified as storing information on the abnormal state with the lowest storage priority. Overwrite the abnormal status information corresponding to the abnormal display target.

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

  In step S3306, when there is only one abnormal state information stored in the abnormal display area 211, the abnormal state information is stored in the first unit area 211a, and the abnormal display area 211 is displayed. When there is a plurality of abnormal state information stored in the area, the abnormal state information is stored in order from the area with the smallest value of “n” in the n-th unit areas 211a to 211b.

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

  If an affirmative determination is made in step S3308, the abnormality display area 211 is erased (step S3309). In the erasing process, it is specified whether or not the information on the abnormal state corresponding to the abnormality display target that has been canceled this time is stored in any of the first to fourth unit areas 211a to 211d of the abnormality display area 211. If it is stored, the information on the abnormal state is erased by clearing the stored area to “0”. In this case, if there is only one abnormal state information stored in the abnormal display area 211 after erasure, the abnormal state information is stored in the first unit area 211a. When there are a plurality of abnormal state information stored in the display area 211, the abnormal state information is stored in order from the area of the nth unit areas 211a to 211b having the smallest “n” value. Further, 1 is subtracted from the value of the abnormality target counter in the main RAM 65 (step S3310).

  In the abnormality setting process, it is determined whether or not an abnormality display start operation has occurred (step S3311). The abnormality display start operation is performed by pressing the update button 68b with the gaming machine main body 12 being opened forward with respect to the outer frame 11 in a situation where the setting state of the pachinko machine 10 is not changeable. This is done by operating.

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

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

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

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

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

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

  First, the turning-off process of the first and second notification display devices 201 and 202 is executed (step S3401). Specifically, display data that is all “0” is output to the first and second display ICs 205 and 206. As a result, all the display segments of the first and second notification display devices 201 and 202 are turned off, and the first and second notification display devices 201 and 202 are not displayed.

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

  When an affirmative determination is made in step S3403, a display target counter update process provided in the main RAM 65 is executed (step S3404). In this update process, if this time is the first process of the abnormal display process after “1” is set in the abnormal display flag of the main RAM 65, “0” is set in the display target counter. The value of the display target counter corresponds to the first to fourth unit areas 211a to 211d of the abnormality display area 211. Specifically, the value of “0” of the display target counter corresponds to the first unit area 211a. The value “1” of the display target counter corresponds to the second unit area 211b, the value “2” of the display target counter corresponds to the third unit area 211c, and “3” of the display target counter. "Corresponds to the fourth unit area 211d. In the update process, if the current abnormal display process time is not the first abnormal display process after the abnormality display flag of the main RAM 65 is set to “1”, the value of the display target counter is incremented by one.

  Thereafter, it is determined whether or not abnormal state information is stored in an area corresponding to the current value of the display target counter among the first to fourth unit areas 211a to 211d (step S3405). Here, as described above, when only one piece of abnormal state information is stored, the abnormal state information is stored in the first unit area 211a, and a plurality of pieces of abnormal state information are stored. In this case, information on abnormal states is stored in order from the area with the smallest value of “n” in the n-th unit areas 211a to 211b. Therefore, if no abnormal state information is stored in the area corresponding to the current value of the display target counter, the abnormal state information is also stored in the area corresponding to a value larger than the value of the display target counter. There will be no. If the value of the display target counter after the addition of 1 exceeds the maximum value “3”, the corresponding area does not exist in the first place, so that the information on the abnormal state is not stored. .

  If an affirmative determination is made in step S3405, the value of the display target counter in the main RAM 65 is cleared to “0” (step S3406). Here, it is assumed that all the abnormal states that are the targets of the abnormality display are canceled in the situation where the abnormality display is performed. In this case, even if the abnormal display process is executed, the abnormal display area 211 does not store the abnormal state information. In such a situation, the third and fourth notification display devices 203 and 204 display to indicate that no abnormal state information is stored.

  If a negative determination is made in step S3405 or if the process of step S3406 is executed, display target display data corresponding to the value of the display target counter in the main RAM 65 is read from the main ROM 64 (step S3407). Specifically, the information stored in the area corresponding to the value of the display target counter of the main RAM 65 is read out from the first to fourth unit areas 211a to 211d of the abnormality display area 211. Then, display data corresponding to the information is read from the main ROM 64. The display data is set in a one-to-one correspondence with the abnormal state information, and the display contents of the third and fourth notification display devices 203 and 204 based on the display data are displayed for each type of abnormal state information. It is different. There is also display data corresponding to the absence of abnormal state information, which is different from the display data corresponding to abnormal state information. Therefore, when there is no abnormal state information, the display contents of the third and fourth notification display devices 203 and 204 are different from the display contents when the abnormal state information exists.

  On the other hand, the display content corresponding to the information on the abnormal state in the third and fourth notification display devices 203 and 204 and the display content corresponding to the absence of the information on the abnormal state are The display contents when the management results of the game history are displayed on the fourth notification display devices 203 and 204 overlap with the display contents of the set values on the fourth notification display device 204. On the other hand, when the management result of the game history is displayed, all of the first to fourth notification display devices 201 to 204 are in a display state, and the setting state of the pachinko machine 10 can be changed. In the state, the first to third notification display devices 201 to 203 are in a non-display state and the fourth notification display device 204 is in a display state. Since 201 and 202 are in a non-display state and the third and fourth notification display devices 203 and 204 are in a display state, even if the display contents overlap as described above, any situation is supported. The administrator of the game hall can grasp whether the display is displayed.

  Thereafter, display control is performed on the third notification display device 203 in accordance with the display data read in step S3407 (step S3408), and display control is performed on the fourth notification display device 204 (step S3409). In this case, the display device 203 for the third notification and the fourth notification device 4 are used for either the display corresponding to the information on the abnormal state or the display corresponding to the absence of the information on the abnormal state. None of the display devices 204 are in a non-display state (that is, they are not completely turned off), and are in some display state.

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

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

  In the configuration in which the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, the display corresponding to the abnormal state of the pachinko machine 10 is displayed on the first to fourth notification display devices 201 to 204. Done. Accordingly, the first to fourth notification display devices 201 to 204 can be used not only for displaying the management result of the game history but also as a display device for performing display corresponding to the abnormal state.

  When the first to fourth notification display devices 201 to 204 perform the display corresponding to the abnormal state when no abnormal state has occurred in the pachinko machine 10, the first to fourth notification display devices 201 to 204 A display corresponding to the fact that no abnormal condition has occurred is performed. Accordingly, it is possible to clearly identify whether or not an abnormal state has occurred in the pachinko machine 10 by checking the first to fourth notification display devices 201 to 204.

  A period in which the management result of the game history is displayed on the first to fourth notification display devices 201 to 204 and a display corresponding to the abnormal state of the pachinko machine 10 are performed on the first to fourth notification display devices 201 to 204. It is distinguished from the period of time. Thereby, any display is performed in the first to fourth notification display devices 201 to 204 by grasping the situation in which the display is performed in the first to fourth notification display devices 201 to 204. It is possible to specify whether or not

  When the display corresponding to the abnormal state of the pachinko machine 10 is performed, the first to fourth notification display devices 201 to 204 are configured so as to have a display mode different from the display mode when the management result of the game history is displayed. Display controlled. Thereby, by identifying the display mode of the first to fourth notification display devices 201 to 204, it is specified which display is being performed on the first to fourth notification display devices 201 to 204. It becomes possible.

  A plurality of notification display devices 201 to 204 are provided. This makes it possible to perform a wide variety of displays as displays corresponding to the game history management results. In addition, due to the presence of a plurality of notification display devices 201 to 204, the display mode is greatly increased when the management result of the game history is displayed and when the display corresponding to the abnormal state of the pachinko machine 10 is performed. It is possible to make it different.

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

  When the display corresponding to the abnormal state of the pachinko machine 10 is performed, the third and fourth notification display devices 203 and 204 are in the display state, and the display content is the third when the management result of the game history is displayed. , Display contents that can be displayed on the fourth notification display devices 203 and 204. In this way, by allowing the display contents on the third and fourth notification display devices 203 and 204 to overlap, a display corresponding to the case where the management result of the game history is displayed and the abnormal state of the pachinko machine 10 is displayed. It is possible to prevent the display contents from being restricted when they are performed. In addition, even when the display contents on the third and fourth notification display devices 203 and 204 can overlap, the first and first notifications are displayed when the display corresponding to the abnormal state of the pachinko machine 10 is performed. 2 Since the notification display devices 201 and 202 are not displayed, it is possible to specify which display is being performed on the first to fourth notification display devices 201 to 204.

  In addition, when an abnormal display start operation is performed in a situation where abnormal state information is not stored in the abnormal display area 211, the abnormal state information is displayed on the first to fourth notification display devices 201 to 204 at that time. It is good also as a structure by which the display corresponding to not having been memorize | stored is performed.

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

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

  First, it is determined whether or not “1” is set in the management start flag provided in the main RAM 65 (step S3501). The management start flag is a flag for the main CPU 63 to specify whether or not the history information should be stored in the history memory 117. In this embodiment, after the supply of operating power to the pachinko machine 10 is started (that is, after the supply of operating power to the MPU 62 is started), the total number of game balls discharged from the game area PA is the management start reference. When the total number of game balls discharged from the game area PA is equal to or greater than the number corresponding to the management start reference value without storing history information in the history memory 117 until the number corresponding to the value is equal to or greater than the number. The storage of history information in the history memory 117 is started. In the shipping stage of the pachinko machine 10 and the like, an operation check of the pachinko machine 10 may be performed before the shipment. In this case, the game balls are maintained in the respective ball-entry portions and the subsequent operation is checked. On the other hand, history information is not stored in the history memory 117 until the total number of game balls discharged from the game area PA after the start of supply of operating power to the pachinko machine 10 is equal to or greater than the management start reference value. By doing so, it is possible to prevent the result of entering the ball at the time of the operation check as described above from being stored as history information.

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

  Thereafter, it is determined whether or not “1” is set in the output flag of the main RAM 65 corresponding to the value of the start-time management counter (step S3503). Specifically, when the value of the start time management counter is “7” and corresponds to the first winning mouth detection sensor 42a, it is determined whether or not “1” is set in the first output flag. When the value of the start time management counter is “6” and corresponds to the second prize opening detection sensor 43a, it is determined whether or not “1” is set in the second output flag, and the start time management is determined. If the value of the counter is “5” and corresponds to the third prize opening detection sensor 44a, it is determined whether or not “1” is set in the third output flag, and the value of the start time management counter is If “4” corresponds to the special electric power detection sensor 45a, it is determined whether or not “1” is set in the fourth output flag, and the value of the start time management counter is “3”. If it corresponds to the working port detection sensor 46a, the fifth output flag is set. It is determined whether or not “1” is set. If the value of the start time management counter is “2” and corresponds to the second working port detection sensor 47a, “1” is set to the sixth output flag. If the value of the start time management counter is “1” and corresponds to the out port 24a, it is determined whether or not “1” is set in the seventh output flag. . Note that “1” is set to the first to seventh output flags in the ball entry detection process (FIG. 15) as already described.

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

  Thereafter, it is determined whether or not the value of the discharge number counter is equal to or greater than the management start reference value (step S3506). The management start reference value is set to “300”, but is not limited to this, and may be configured to have a number smaller than “300” or may be configured to be larger than “300”. .

  If a negative determination is made in step S3503 or a negative determination is made in step S3506, the value of the start time management counter in the main RAM 65 is decremented by 1 (step S3507). Then, it is determined whether or not the value of the start management counter after the 1 subtraction is “0” (step S3508). If a negative determination is made in step S3508, the process returns to step S3503, and if an affirmative determination is made in step S3508, the management output process is terminated.

  On the other hand, if the value of the discharge number counter of the main RAM 65 is equal to or greater than the management start reference value (step S3506: YES), “1” is set to the management start flag of the main RAM 65 (step S3509). Thereafter, a management process is executed (step S3510). The management process is also executed when the management start flag is set to “1” and an affirmative determination is made in step S3501 (step S3510). The processing contents of the management process are the same as steps S1001 to S1012 of the management output process (FIG. 25) in the first embodiment.

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

  Here, after the supply of the operating power to the pachinko machine 10 is started as described above, until the total number of game balls discharged from the game area PA becomes equal to or greater than the number corresponding to the management start reference value, In the configuration in which the history information is not stored in the memory 117, the management result of the game history during that time cannot be calculated. Therefore, in such a situation, the first to fourth notification display devices 201 to 204 may be configured to perform display corresponding to the situation. For example, it is good also as a structure which makes all the display segments light-emit in each of the 1st-4th alerting | reporting display apparatuses 201-204. The display content is not displayed either when displaying the management result of the game history or when displaying the changeable state in which the setting state of the pachinko machine 10 can be changed. By confirming the first to fourth notification display devices 201 to 204, it is possible to specify whether or not the history information is stored as described above.

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

  In addition, history information is stored in the history memory 117 until the total number of game balls discharged from the game area PA after the supply of operating power to the pachinko machine 10 is equal to or greater than the management start reference value. Instead of the configuration having no history, an area for storing history information may be provided separately from the history memory 117 until the total number of game balls reaches the management start reference value or more. Thereby, it becomes possible to specify the management result of the game history in the said situation.

  In addition, history information is stored in the history memory 117 until the total number of game balls discharged from the game area PA after the supply of operating power to the pachinko machine 10 is equal to or greater than the management start reference value. As a condition under which no situation occurs, a condition may be added in which supply of operating power to the pachinko machine 10 is started in a situation where history information is not stored in the history memory 117. In this case, when supply of operating power to the pachinko machine 10 is started in a situation where history information is already stored in the history memory 117, the total number of game balls discharged from the game area PA is the management start reference. Regardless of whether or not the value is greater than or equal to the value, history information is stored in the history memory 117 from the beginning.

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

  In addition, history information is stored in the history memory 117 until the total number of game balls discharged from the game area PA after the supply of operating power to the pachinko machine 10 is equal to or greater than the management start reference value. In addition to or instead of the configuration, the history information may not be stored in the history memory 117 in a situation where the gaming machine main body 12 or the front door frame 14 is opened. Thereby, it is possible to prevent the history information from being stored for an event that occurs in a situation where the gaming machine main body 12 or the front door frame 14 is opened.

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

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

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

  FIG. 67 is an explanatory diagram for explaining a program and data setting mode in the main ROM 64. In correspondence with the fact that the control executed by the main CPU 63 is distinguished from the specific control and the non-specific control, as shown in FIG. The addresses of the areas where the data, the program for non-specific control and the data for non-specific control are stored are clearly distinguished.

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

  As described above, the program for specific control and the data for specific control, and the program for non-specific control and the data for non-specific control are independent of the execution order of the processes for executing the corresponding control, For example, when checking only the program for specific control and the data for specific control by being stored in areas of different ranges of addresses, the address for storing the program for specific control and the data for specific control is stored. For example, when checking only the program for non-specific control and the data for non-specific control, the address where the program for non-specific control and the data for non-specific control are stored. You only need to check the range area. Therefore, it is possible to efficiently perform the work when checking the program and data by distinguishing between specific control and non-specific control. Along with this, it is possible to efficiently perform the work in the case where the program and data are distinguished and corrected by specific control and non-specific control.

  No data is stored between the address range of the area where the program for specific control and the data for specific control are stored and the address range of the area where the program for non-specific control and data for non-specific control are stored Since the address range of the unused area that has not been set is set, the boundary between the address range for the specific control and the address range for the non-specific control can be easily grasped during the check operation.

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

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

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

  As described above, when the specific control work area 221 and the non-specific control work area 223 are set differently, the main CPU 63 executes specific control and non-specific control. Thus, different areas of the main RAM 65 are used when various calculations are performed. Thereby, when one of the specific control and the non-specific control is executed, it is possible to make it difficult to generate an event that information on the main side RAM 65 necessary for the other is deleted. Incidentally, when writing information to each work area 221, 223 and reading information from each work area 221, 223, the main CPU 63 issues a load instruction.

  Since the stack area 222 for specific control and the stack area 224 for non-specific control are set differently, the main CPU 63 executes the specific control and executes the non-specific control. When the information stored in the register of the side CPU 63 is saved and when the return address information on the program is stored, different areas of the main side RAM 65 are used. As a result, when the information stored in the register of the main CPU 63 is saved in the situation where one of the specific control and the non-specific control is being executed, and when the return address information on the program is stored, it is used on the other side. It is possible to make it difficult to generate an event that information to be deleted is deleted. Incidentally, the main CPU 63 issues a push command when writing information to the stack areas 222 and 224, and the main CPU 63 issues a pop command when reading information from the stack areas 222 and 224. Further, when information is read from each stack area 222, 224, the order of writing to the stack area 222, 224 becomes the target to be read first from the later information.

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

  When the main CPU 63 executes processing corresponding to non-specific control, the main CPU 63 can write information to the work area 223 for non-specific control and the stack area 224 for non-specific control. In addition, information can be read from the work area 223 for non-specific control and the stack area 224 for non-specific control. On the other hand, when the main CPU 63 executes processing corresponding to non-specific control, the main CPU 63 can read information from the specific control work area 221 and the specific control stack area 222. Information cannot be written to the work area 221 for specific control and the stack area 222 for specific control. As a result, in a situation where processing corresponding to non-specific control is being executed, it is possible to prevent information used in processing corresponding to specific control from being deleted by mistake.

  Note that backup power is supplied to the main-side RAM 65 even after the pachinko machine 10 is powered off. The backup power includes the work area 221 for specific control, the stack area 222 for specific control, and the non-specific control. Are supplied to all the work area 223 and the stack area 224 for non-specific control. As a result, the information stored in the work area 221 for specific control, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control is stored in the power-off state of the pachinko machine 10. The data is stored and held while the backup power is supplied.

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

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

  FIG. 70 is a flowchart showing the management process. Note that the processing from step S3801 to step S3805 in the management processing is executed by the main CPU 63 using a program for specific control and data for specific control.

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

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

  Thereafter, the management execution process is started by reading a subroutine program corresponding to the management execution process set in the non-specific control program (step S3803). In this case, information for specifying the return address of the management process after execution of the management execution process is written into the stack area 222 for specific control by a push command. When the management execution process ends, information for specifying the return address is read by the pop instruction, and the process returns to the management process program indicated by the return address.

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

  Thereafter, in order to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which it is permitted, an interrupt permission is set (step S3805). Thereby, a new execution of the timer interrupt process can be performed.

  FIG. 71 is a flowchart showing management execution processing. Note that the processing of steps S3901 to S3915 in the management execution processing is executed by the main CPU 63 using a program for non-specific control and data for non-specific control.

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

  By the way, in the case where both the stack area 222 for specific control and the stack area 224 for non-specific control are additionally set in spite of information being set in all storage areas, All areas of the main RAM 65 are cleared to “0” because an abnormality has occurred regarding the storage process. This makes it possible to prevent the game from proceeding as it is despite the occurrence of an abnormality with respect to the storage process.

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

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

  These WA register, BC register, DE register, HL register, IX register and IY register are registers used in the check process (step S3908) which is a process corresponding to non-specific control. By saving the information set in such a register to the work area 223 for non-specific control prior to the execution of the check process (step S3908), the information of these registers used for the specific control is non-specific controlled. It is possible to evacuate before starting. Therefore, even if these registers are overwritten during non-specific control, when the non-specific control is terminated, the information saved in the non-specific control work area 223 is restored to these registers, so that the state of these registers is restored. Can be returned to a state corresponding to the specific control before the non-specific control is executed.

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

  In addition, the register information is not saved in the non-specific control stack area 224, but is saved in the non-specific control work area 223, thereby reducing the capacity of the non-specific control stack area 224. It becomes possible. Further, when using the non-specific control stack area 224, the information writing order is read first from the later information as already described, and therefore the information reading order is shifted due to some noise or the like. If this happens, all of the subsequent reading order information will be restored to a different register. The occurrence probability of such an event increases as the amount of information saved in the non-specific control stack area 224 increases. On the other hand, by saving the register information in the work area 223 for non-specific control, it becomes possible to prevent the above event from occurring even when there is a lot of information to be saved. .

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

  After execution of the check process, “LD SP, Y (r + α)” is set to Y (r + α) as a fixed address when returning to the specific control in the stack pointer of the main CPU 63 as “LD SP, Y (r + α)” (step S3909). ). The address of Y (r + α) is set as an address between Y (r + 8) and Y (s) in the stack area 222 for specific control.

  The amount of information stored in the stack area 222 for specific control is always constant immediately before the execution of the management execution process subroutine in step S3803 of the management process (FIG. 70), and accordingly, the main amount at that timing is The information on the stack pointer of the side CPU 63 (that is, the value of the stack pointer) is constant. In this case, the information stored in the stack area 222 for specific control includes, for example, information on the return address of the management process (FIG. 70) after the management execution process (FIG. 71) ends, and the management process ( Information on the return address of the timer interrupt processing (FIG. 69) after the completion of FIG. The constant information of the stack pointer is Y (r + α). Therefore, when the check process corresponding to the non-specific control ends and the process returns to the process corresponding to the specific control, Y (r + α) that is the constant information is set in the stack pointer of the main CPU 63. As a result, the information of the stack pointer can be restored to the information immediately before the process corresponding to the non-specific control is started. In this way, by setting fixed information in the stack pointer, the information corresponding to the stack pointer is restored to the information immediately before the processing corresponding to the non-specific control is started. It is no longer necessary to save the stack pointer information of the main CPU 63 corresponding to the specific control to the main RAM 65 before starting the operation. Therefore, it is possible to reduce the processing load, and it is not necessary to secure an area for the retreat in the main RAM 65.

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

  Here, when processing corresponding to non-specific control is executed, information stored in the flag register and various registers of the main CPU 63 is not saved in the main RAM 65 when processing corresponding to specific control is resumed. . Accordingly, it is not necessary to secure a storage area for saving the information in the work area 221 for specific control and the stack area 222 for specific control.

  Further, when processing corresponding to non-specific control is executed, information stored in the flag register and various registers of the main CPU 63 is processed by processing corresponding to non-specific control after returning to the processing corresponding to specific control. This information is not used when it is started again. In other words, the information necessary for the plurality of processing times corresponding to the non-specific control executed with the process corresponding to the specific control in between is the non-specific control work area 223 or the non-specific control stack area. 224 and is not stored in the flag register and various registers of the main CPU 63. Therefore, when the process corresponding to the non-specific control is executed, even if the information stored in the flag register and various registers of the main CPU 63 is not saved in the main RAM 65, the process corresponding to the non-specific control is executed. No problem.

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

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

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

  Each counter 231a to 231e in the normal counter area 231 is a target entry portion 24a in a situation where the front door frame 14 is in a closed state and is not in either the opening / closing execution mode or the high frequency support mode. It is used to measure the number of game balls that have entered 31-34. Each of the counters 232a to 232e in the opening / closing execution mode counter area 232 enters the target entrances 24a, 31 to 34 in the situation where the front door frame 14 is in the closed state and is in the opening / closing execution mode. Used to count the number of game balls that have been balled. Each of the counters 233a to 233e in the high frequency support mode counter area 233 is a state in which the front door frame 14 is in a closed state and is a target entry portion 24a, 31 to 34 in the high frequency support mode. It is used to measure the number of game balls that have entered the ball.

  It should be noted that the situation where the front door frame 14 is in the open state is not subject to measurement because the game ball enters the ball entry parts 24a, 31 to 34 with the front door frame 14 open. This is in order to exclude the number of entered balls from the measurement target. However, the present invention is not limited to this, and the situation in which the front door frame 14 is in an open state may be a measurement target in the same manner as the situation in which the front door frame 14 is in a closed state.

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

  FIG. 73 is a flowchart showing a check process executed when a subroutine program is called in step S3908. Note that the processing from step S4001 to step S4008 in the check processing, including subroutine processing, is executed by the main CPU 63 using a program for non-specific control and data for non-specific control. When executing a subroutine process, the return address information after the subroutine process is executed is written in the storage area corresponding to the current stack pointer value of the main CPU 63 in the non-specific control stack area 224. At the same time, the value of the stack pointer is updated to the address information of the storage area to be stored in the next order. Further, when the subroutine processing is completed, the return address information is read from the storage area corresponding to the value in the previous order with respect to the current stack pointer value of the main CPU 63, and the return address information is handled. While returning to the program, the value of the stack pointer is updated to the address information of the storage area from which the return address information is read.

  In the check process, when the front door frame 14 is in the open state (step S4001: YES), the normal entrance management process (step S4004), the entrance management process during the opening / closing execution mode (step S4005), and the high frequency A result calculation process (step S4007) and a display process (step S4008), which will be described later, are executed without executing any of the pitch management processes (step S4006) in the support mode. When the front door frame 14 is in an open state because the game area PA is formed by a space partitioned back and forth by the back surface of the window panel 52 provided on the front door frame 14 and the front surface of the game board 24. Even if the game area PA is opened toward the front and the game ball is launched toward the game area PA in that situation, the game ball cannot normally flow down the game area PA. In addition, when the front ball frame 14 is in an open state, a game ball entering the ball entry portions 24a, 31 to 34 is generated by the manager of the game hall for maintenance or resolution of problems. This is a case where the front door frame 14 is in an open state and a game ball enters due to care or the like. Since such a game ball entry is not a game ball entry in a regular game execution situation, it is not necessary to manage such a game ball entry as a management target. Therefore, in the check process, if the front door frame 14 is in the open state as described above, none of the processes in steps S4004 to S4006 are executed.

  When the front door frame 14 is in the closed state and is not in either the opening / closing execution mode or the high frequency support mode (step S4001 to step S4003: NO), a normal entry management process is executed (step S4004). Further, when the front door frame 14 is in the closed state and is in the opening / closing execution mode (step S4001: NO, step S4002: YES), the entrance management process in the opening / closing execution mode is executed (step S4005). Further, when the front door frame 14 is in the closed state and is in the high frequency support mode (step S4001: NO, step S4003: YES), the entrance management process in the high frequency support mode is executed (step S4006).

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

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

  In the case of the entrance management process in the opening / closing execution mode, the value of the general winning counter 232a for the opening / closing execution mode is incremented by 1 as a process corresponding to steps S4102, S4104, and S4106, and the entry in the high frequency support mode is performed. If it is a ball management process, 1 is added to the value of the general winning counter 233a for the high frequency support mode as a process corresponding to steps S4102, S4104, and S4106. Also, in the ball entry detection process (step S3709) of the timer interruption process (FIG. 69) executed as the process corresponding to the specific control, the detection results of the first to third prize opening detection sensors 42a to 44a are monitored. Processing for causing the number of game balls corresponding to the general winning port 31 to be paid out when it is determined that any one of the first to third winning port detection sensors 42a to 44a has been detected. Execute.

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

  If it is a pitch management process in the open / close execution mode, the value of the special power prize counter 232b for the open / close execution mode is incremented by 1 as a process corresponding to step S4108, and if it is a pitch management process in the high frequency support mode. As a process corresponding to step S4108, 1 is added to the value of the special power prize counter 233b for the high frequency support mode. In addition, the detection result of the special electric detection sensor 45a is also monitored in the ball entry detection process (step S3709) of the timer interruption process (FIG. 69) executed as a process corresponding to the specific control. When it is determined that a game ball has been detected, a process for causing the number of game balls corresponding to the special prize device 32 to be paid out is executed and a process for specifying the end timing of the round game is executed.

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

  If it is a pitch management process in the open / close execution mode, the value of the first operation counter 232c for the open / close execution mode is incremented by 1 as a process corresponding to step S4110, and the pitch management process in the high frequency support mode may be performed. For example, as the process corresponding to step S4110, the value of the first operation counter 233c for the high frequency support mode is incremented by one. The detection result of the first working port detection sensor 46a is also monitored in the ball entry detection processing (step S3709) of the timer interruption processing (FIG. 69) executed as processing corresponding to the specific control, and the first working port detection sensor. If it is determined at 46a that one game ball has been detected, processing is performed so that the number of game balls corresponding to the first operating port 33 is paid out, and the holding information for special figure is acquired. Execute processing to identify the trigger.

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

  If it is a pitch management process during the open / close execution mode, the value of the second operation counter 232d for the open / close execution mode is incremented by 1 as a process corresponding to step S4112, and the pitch management process during the high frequency support mode may be performed. For example, as a process corresponding to step S4112, the value of the second operation counter 233d for the high frequency support mode is incremented by one. The detection result of the second working port detection sensor 47a is also monitored in the ball entry detection processing (step S3709) of the timer interruption processing (FIG. 69) executed as processing corresponding to the specific control, and the second working port detection sensor. If it is determined at 47a that one game ball has been detected, processing is performed so that the number of game balls corresponding to the second operation port 34 is paid out, and acquisition of hold information for special figures Execute processing to identify the trigger.

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

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

  As described above, by executing the processing from step S4004 to step S4006, the number of game balls entered into the general winning opening 31 is measured using the general winning counters 231a, 232a, 233a, and the special electric prize winning device 32 is obtained. The number of game balls that enter the game is measured using the special electricity prize counters 231b, 232b, and 233b, and the number of game balls that enter the first operation port 33 uses the first operation counters 231c, 232c, and 233c. The number of game balls entering the second operation port 34 is measured using the second operation counters 231d, 232d, and 233d, and the number of game balls entering the out port 24a is measured by the out counter 231e, Measurement is performed using 232e and 233e. Thereby, it becomes possible for the main CPU 63 to grasp the entry history of each entry unit 24a, 31-34. In addition, the normal counter area 231, the opening / closing execution mode counter area 232, and the high-frequency support mode counter area 233 are separately provided, so that neither the opening / closing execution mode nor the high-frequency support mode is present. In addition, the main CPU 63 can recognize the entry history of the entry units 24 a and 31 to 34 by distinguishing between the situation in the opening / closing execution mode and the situation in the high frequency support mode.

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

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

  First, it is determined whether or not “1” is set in the management start flag provided in the work area 223 for non-specific control (step S4201). The management start flag is a flag for the main CPU 63 to specify whether or not the game history collection for calculating the game history management result is to be executed. In this embodiment, when supply of operating power to the pachinko machine 10 is started for the first time after the manufacture of the pachinko machine 10 (that is, when supply of operating power to the MPU 62 is started), the game discharged from the game area PA Until the total number of balls reaches or exceeds the number corresponding to the management start reference value, the total number of game balls discharged from the game area PA without collecting the game history for calculating the game history management result When the number exceeds the number corresponding to the management start reference value, game history collection for calculating the game history management result is executed. In the shipping stage of the pachinko machine 10 and the like, an operation check of the pachinko machine 10 may be performed before the shipment. In this case, the game balls are maintained in the respective ball-entry portions and the subsequent operation is checked. On the other hand, the game for calculating the management result of the game history until the total number of game balls discharged from the game area PA after starting the supply of the operating power to the pachinko machine 10 becomes equal to or higher than the management start reference value. By preventing the collection of history, it is possible to prevent the result of entering the ball at the time of the operation check as described above from being collected as a game history for calculating the management result of the game history. Become.

  Here, when supply of operating power to the pachinko machine 10 is started for the first time after the manufacture of the pachinko machine 10 (that is, supply of operating power to the MPU 62 is started), the value of the management start flag is “0”. It has become. In this case, the values of the counters 231a to 231e in the normal counter area 231; the values of the counters 232a to 232e in the open / close execution mode counter area 232; and the values of the counters 233a to 233e in the counter area 233 for the high frequency support mode Is also “0”. On the other hand, in the situation where the value of the management start flag is “1”, the supply of the operating power to the pachinko machine 10 is stopped, and then the operating power to the pachinko machine 10 is supplied in the situation where the backup power is supplied to the main RAM 65. When the supply is started, the value of the management start flag remains “1”. In this case, the values of the counters 231a to 231e in the normal counter area 231; the values of the counters 232a to 232e in the open / close execution mode counter area 232; and the values of the counters 233a to 233e in the counter area 233 for the high frequency support mode In addition, the state before the supply of the operating power to the pachinko machine 10 is stopped is maintained. Due to the above configuration, when the value of the management start flag is “0”, the value of each counter 231a to 231e in the normal counter area 231; the value of each counter 232a to 232e in the counter area 232 for opening / closing execution mode; The values of the counters 233a to 233e in the high-frequency support mode counter area 233 are also “0”.

  Incidentally, when the main RAM 65 clear process is executed in step S105 or step S117 in the main process (FIG. 9), the clear process is targeted for the specific control work area 221 and the specific control stack. The non-specific control work area 223 and the non-specific control stack area 224 are excluded from the clear process. Thus, the game hall manager cannot intentionally clear the work area 223 for non-specific control and the stack area 224 for non-specific control “0” intentionally.

  Further, the main CPU 63 confirms whether or not an abnormality has occurred in the work area 223 for non-specific control and the stack area 224 for non-specific control in a timer interrupt process (FIG. 69) described later, and the occurrence of the abnormality. In such a case, the work area 223 for non-specific control and the stack area 224 for non-specific control may be cleared to “0”. As a result, when an abnormality occurs in the work area 223 for non-specific control and the stack area 224 for non-specific control, initialization can be performed. In addition, when an abnormality occurs in the work area 223 for non-specific control in the configuration, the work area 223 for non-specific control is cleared to “0” without clearing the stack area 224 for non-specific control. However, when an abnormality occurs in the non-specific control stack area 224, the non-specific control stack area 224 is cleared to "0" without clearing the non-specific control work area 223 to "0". Also good. Further, even if an abnormality occurs in the work area 223 for non-specific control and the stack area 224 for non-specific control, the calculation result storage area 234 may be excluded from the target of “0” clear.

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

  When an affirmative determination is made in step S4203, "1" is set to the management start flag of the work area 223 for non-specific control (step S4204). Also, all the counters 231a to 231e in the normal counter area 231, the counters 232a to 232e in the open / close execution mode counter area 232, and the counters 233a to 233e in the high frequency support mode counter area 233 are all cleared to “0”. (Step S4205). Thereby, after the supply of operating power to the pachinko machine 10 is started (that is, after the supply of operating power to the MPU 62 is started), the total number of game balls discharged from the game area PA is the management start reference value. All game history information collected up to the number corresponding to is deleted. Therefore, collection of game history for calculating the management result of the game history until the total number of game balls discharged from the game area PA after starting the supply of the operating power to the pachinko machine 10 becomes equal to or greater than the management start reference value. Can be prevented from being executed.

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

When an affirmative determination is made in step S4207, various parameter calculation processing is executed (step S4208). Specifically, the values of the various counters 231a to 231e in the normal counter area 231 are set to K61 to K65, and the values of the various counters 232a to 232e in the open / close execution mode counter area 232 are set to K71 to K75, for the high frequency support mode. When the values of the various counters 233a to 233e in the counter area 233 are K81 to K85, the following 61st parameter to 68th parameter are calculated.
61st parameter: total number of game balls to be paid out (“K61 + K71 + K81” × “number of winning balls for winning in the general winning opening 31” + “K62 + K72 + K82” × “number of winning balls for winning in the special electricity winning device 32” + “K63 + K73 + K83” ”ד Number of winning balls for winning in the first operating port 33 ”+“ K64 + K74 + K84 ”ד Number of winning balls for winning in the second operating port 34 ”) / total number of game balls discharged from the work area PA ( Ratio of K61 + K62 + K63 + K64 + K65 + K71 + K72 + K73 + K74 + K75 + K81 + K82 + K83 + K84 + K85) · 62nd parameter: Total number of game balls paid out during normal times (K61 × “Number of winning balls for winning in the general winning opening 31” + K62 × “Winning for special winning device 63 + winning ball for special prize winning device 63” “The number of winning balls for winning in the first operating port 33” + K64 × “the number of winning balls for winning in the second operating port 34”) / total number of game balls discharged from the skill area PA in the normal time (K61 + K62 + K63 + K64 + K65) Ratio / 63th parameter: Total number of game balls to be paid out in the opening / closing execution mode (K71 × “number of winning balls for winning in the general winning opening 31” + K72 × “number of winning balls for winning in the special electricity winning device 32” + K73 X "Number of winning balls for winning in the first operating port 33" + K74 x "Number of winning balls for winning in the second operating port 34") / Total number of game balls discharged from the technique area PA in the open / close execution mode Ratio of (K71 + K72 + K73 + K74 + K75) / 64th parameter: Total number of game balls to be paid out in the high frequency support mode (K81 × “Number of winning balls for winning to the general winning opening 31” + K82 × “Number of winning balls for winning to the special electricity winning device 32” + K83 × “Number of winning balls for winning to the first operating port 33” + K84 × “Second operation” Number of winning balls for winning a prize in the mouth 34) / A ratio of the total number of gaming balls discharged from the technique area PA in the high frequency support mode (K81 + K82 + K83 + K84 + K85). 65th parameter: Total number of gaming balls in the general winning opening 31 Number of balls entered (K61 + K71 + K81) / total number of game balls discharged from the game area PA (K61 + K62 + K63 + K64 + K65 + K71 + K72 + K73 + K74 + K75 + K81 + K82 + K83 + K84 + K85) 66th parameter: total number of K balls in the first operating hole 33 (K) +63 K (73) Ratio of the total number of game balls discharged from the area PA (K61 + K62 + K63 + K64 + K65 + K71 + K72 + K73 + K74 + K75 + K81 + K82 + K83 + K84 + K85) 67th parameter: (“K62 + K72 + K82” × “the number of winning balls for winning to the special electricity winning device 32” + “84” K × 74 × K) No. of winning balls for winning a prize) / total number of game balls to be paid out (“K61 + K71 + K81” × “the number of winning balls for winning the general winning slot 31” + “K62 + K72 + K82” × “the winning ball for winning the special electric prize device 32” (Number) + “K63 + K73 + K83” × “the number of winning balls for winning in the first working port 33” + “K64 + K74 + K84” × “the number of winning balls for winning in the second operating port 34”) / 68th parameter : “K62 + K72 + K82” × “the number of winning balls for winning in the special prize winning device 32” / total number of game balls to be paid out (“K61 + K71 + K81” × “the number of winning balls for winning in the general winning slot 31” + “K62 + K72 + K82” × “special electricity” “Number of winning balls for winning to the winning device 32” + “K63 + K73 + K83” × “number of winning balls for winning to the first operating port 33” + “K64 + K74 + K84” × “number of winning balls for winning to the second operating port 34”) Thereafter, the 61st to 68th parameters calculated in step S4208 are overwritten in the calculation result storage area 234 (step S4209). In this case, the 61st to 68th parameters of the calculation results in the previous processing times that have already been stored in the calculation result storage area 234 are deleted. Even if the supply of operating power to the pachinko machine 10 is stopped, backup power is supplied to the main RAM 65, so if the backup power is being supplied to the pachinko machine 10, Even immediately after the start of the supply of the operating power, the calculation result storage area 234 stores information on the 61st to 68th parameters calculated before the supply of the operating power to the pachinko machine 10 is stopped.

  Thereafter, all the counters 231a to 231e in the normal counter area 231, the counters 232a to 232e in the open / close execution mode counter area 232, and the counters 233a to 233e in the high frequency support mode counter area 233 are all cleared to “0”. (Step S4210). As a result, when the 61st to 68th parameters are calculated, the game history information can be temporarily deleted at that time.

  It should be noted that immediately after the management start flag is set to “1”, when the total number of game balls discharged from the game area PA is equal to or greater than the value obtained by subtracting the management start reference value from the calculation reference number, Steps S4208 to S4208 are performed. The process of step S4210 may be executed, and thereafter, the process of steps S4208 to S4210 may be executed when the total number of game balls discharged from the game area PA is equal to or greater than the calculation reference number.

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

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

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

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

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

  When a negative determination is made in step S4304, or when the process of step S4305 is executed, the first notification display device 69a is displayed so that information corresponding to the type of parameter corresponding to the value of the display target counter is displayed. Control is performed (step S4306). In addition, the parameter corresponding to the value of the display target counter is read from the calculation result storage area 234, the read parameter is multiplied by 100, and the number corresponding to the tenth digit is displayed on the second notification display device 69b. The number corresponding to the 1's place is displayed on the third notification display device 69c (step S4307).

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

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

  When supply of operating power to the main CPU 63 is started by executing the display process as described above, the management results of the game history are displayed on the first to third notification display devices 69a to 69c. Is done. The management result of the game history is displayed regardless of whether or not the game is continued, and the main body 60 is opened from the front of the pachinko machine 10 by opening the gaming machine main body 12 with respect to the outer frame 11. This is done regardless of whether it is visible. As described above, the display control of the first to third notification display devices 69a to 69c is executed regardless of the game situation and the state of the pachinko machine 10, and thereby the first to third notification display devices 69a. It becomes possible to simplify the processing configuration for display control of .about.69c.

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

  The main RAM 65 is provided with a work area 221 for specific control and a stack area 222 for specific control, a work area 223 for non-specific control, and a stack area 224 for non-specific control. In the work area 221 for specific control and the stack area 222 for specific control, processing corresponding to specific control is executed by the main CPU 63 using a program for specific control and data for specific control. In contrast, information can be stored and read out, while processing corresponding to non-specific control is executed by the main CPU 63 using a program for non-specific control and data for non-specific control. In some cases, information can be read but information cannot be stored. The non-specific control work area 223 and the non-specific control stack area 224 can store information and read information when processing corresponding to non-specific control is executed by the main CPU 63. On the other hand, when the process corresponding to the specific control is executed by the main CPU 63, the information can be read but the information cannot be stored. Thus, the work area 221 for specific control and the stack area 222 for specific control are handled as a dedicated storage area for processing corresponding to the specific control, and the work area 223 for non-specific control and the stack area for non-specific control 224 can be handled as a dedicated storage area for processing corresponding to non-specific control. Therefore, the storage destination of information in the main RAM 65 can be clearly different between the process corresponding to the specific control and the process corresponding to the non-specific control. Therefore, it is possible to prevent information used in the other process from being deleted when one of the processes corresponding to the specific control and the process corresponding to the non-specific control is executed.

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

  A normal counter area 231 in which information for managing a game history is stored, an open / close execution mode counter area 232, a high frequency support mode counter area 233, and a calculation result storage area 234 are provided in the main RAM 65. As a result, the main CPU 63 can complete the process for managing the game history. It is also possible to prevent unauthorized access and unauthorized modification to game history information and various parameter information calculated using the game history information.

  When the situation corresponding to the specific control is executed from the situation where the process corresponding to the non-specific control is executed or the situation corresponding to the non-specific control is executed, the main CPU 63 Register information is saved in the main RAM 65. As a result, when processing corresponding to non-specific control is executed, it is possible to prevent information stored in various registers of the main CPU 63 from being rewritten when executing processing corresponding to specific control. Become. Further, when the process corresponding to the non-specific control is completed or after the process is completed, the information saved in the main RAM 65 is returned to various registers of the main CPU 63. Thereby, when the process corresponding to the non-specific control is completed, it is possible to execute the process corresponding to the specific control from the state of the various registers of the main CPU 63 before the execution of the process corresponding to the non-specific control. Become.

  When the situation corresponding to the non-specific control is executed from the situation where the process corresponding to the specific control is executed or the situation corresponding to the non-specific control is executed, the various registers of the main CPU 63 Among them, information of some registers is saved in the main RAM 65. As a result, it is possible to suppress the storage capacity necessary for saving the register information of the main CPU 63 in the main RAM 65.

  When the situation corresponding to the non-specific control is executed from the situation where the process corresponding to the specific control is executed or the situation corresponding to the non-specific control is executed, the various registers of the main CPU 63 Among these, the information of the register that is the storage target of information is saved in the main RAM 65 in the process corresponding to the non-specific control. Thereby, when the process corresponding to the non-specific control is completed, it is possible to restart the process corresponding to the specific control from the register state of the main CPU 63 before the execution of the process corresponding to the non-specific control. In the main RAM 65, the storage capacity necessary for saving the register information of the main CPU 63 can be reduced.

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

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

  The information in the WA register, BC register, DE register, HL register, IX register, and IY register is not saved in the non-specific control stack area 224, but is saved in the non-specific control work area 223. It is possible to reduce the capacity of the stack area 224 for specific control. In addition, when the stack area 224 for non-specific control is used, the information writing order is read first from the later information. Therefore, if the information reading order is shifted due to some noise or the like, All of the subsequent reading order information is restored to a different register. The occurrence probability of such an event increases as the amount of information saved in the non-specific control stack area 224 increases. On the other hand, by saving the register information in the work area 223 for non-specific control, it becomes possible to prevent the above event from occurring even when there is a lot of information to be saved. .

  The stack pointer of the main CPU 63 when the situation corresponding to the non-specific control is executed from the situation where the process corresponding to the specific control is executed or when the situation corresponding to the non-specific control is executed This information is a fixed information, and the information of the stack pointer is not saved in the main RAM 65 at the start of processing corresponding to non-specific control. As a result, it is not necessary to secure a capacity for saving information of the stack pointer in the main RAM 65, so that the storage capacity of the main RAM 65 can be reduced accordingly. Further, even when the stack pointer information is not saved in this way, the situation corresponding to the non-specific control is changed from the situation where the process corresponding to the specific control is executed to the situation where the process corresponding to the non-specific control is executed. When the corresponding process is executed, the stack pointer information of the main CPU 63 becomes fixed information. Therefore, the process corresponding to the non-specific control can be performed without saving the stack pointer information as described above. When the processing is completed, it is possible to restore the stack pointer information before the processing corresponding to the non-specific control is started.

  In addition, when the process corresponding to the non-specific control is executed, the flag register information of the main CPU 63 is saved in the main RAM 65 in the process corresponding to the specific control. However, the present invention is not limited to this. Alternatively, the flag register information may be saved in the main RAM 65 in a process corresponding to non-specific control. In addition, after the process corresponding to the non-specific control is completed, the return of information to the flag register of the main CPU 63 is performed in the process corresponding to the specific control. However, the present invention is not limited to this. The configuration may be such that the return of information to the flag register is performed in a process corresponding to non-specific control.

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

<Sixteenth Embodiment>
In the present embodiment, the processing configuration of the management process is different from that of the fifteenth embodiment. Hereinafter, a configuration different from the fifteenth embodiment will be described. The description of the same configuration as that of the fifteenth embodiment is basically omitted.

  FIG. 77 is a flowchart showing the management process in the present embodiment executed by the main CPU 63. Note that the processing in steps S4401 to S4405 in the management processing is executed by the main CPU 63 using a program for specific control and data for specific control.

  First, in order to prohibit the generation of the timer interrupt process (FIG. 69), interrupt prohibition is set (step S4401). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and started in the middle of the management execution process described later, which is a process corresponding to the non-specific control. Is possible.

  After that, as “LD (_PSWBUF), PSW”, the information of the flag register of the main CPU 63 is saved in the PSW buffer set in the work area 221 for specific control by a load instruction (step S4402). The flag register includes a carry flag, a zero flag, a P / V flag, a sine flag, a half carry flag, and the like, and the information in the flag register changes depending on the execution result of the arithmetic instruction, rotate instruction, input / output instruction, and the like. By saving the flag register information before the subroutine program corresponding to the management execution process is started, the flag register in the state before the subroutine is changed or changed after the subroutine is started is saved. Information can be saved in the work area 221 for specific control.

  Thereafter, the management execution process is started by reading a subroutine program corresponding to the management execution process set in the non-specific control program (step S4403). In this case, information for specifying the return address of the management process after execution of the management execution process is written into the stack area 222 for specific control by a push command. When the management execution process ends, information for specifying the return address is read by the pop instruction, and the process returns to the management process program indicated by the return address.

  When returning to the management process program after the execution of the management execution process, “LD PSW, (_PSWBUF)” is saved in the PSW buffer in the work area 221 for specific control in step S4402 as a load instruction. The flag register information is returned to the flag register of the main CPU 63 (step S4404). As a result, the information in the flag register of the main CPU 63 is restored to the information at the time when step S4402 was executed last time. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

  Thereafter, in order to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which it is permitted, an interrupt permission is set (step S4405). Thereby, a new execution of the timer interrupt process can be performed.

  According to the above configuration, the flag register information of the main CPU 63 immediately before switching from the specific control to the non-specific control is saved in the work area 221 for specific control instead of the stack area 222 for specific control. As a result, the flag register information can be saved while suppressing the capacity of the stack area 222 for specific control.

  The PSW buffer in the work area 221 for specific control is secured as a dedicated area. However, the present invention is not limited to this, and a configuration may also be used where other information can be written. In other words, in the situation where the management process is not executed, it is not necessary to save the flag register information of the main CPU 63 corresponding to the specific control. A configuration may also be used in which a shared area that is also used as a PSW buffer is used when performing arithmetic processing. In this case, the shared area is surely used to save the flag register information when the management process is executed. Therefore, before the management process is executed as information other than the flag register information, It is necessary to have a configuration in which unnecessary information is written in the shared area.

<Seventeenth embodiment>
In this embodiment, the processing configuration of the management execution process is different from that of the fifteenth embodiment. Hereinafter, a configuration different from the fifteenth embodiment will be described. The description of the same configuration as that of the fifteenth embodiment is basically omitted.

  FIG. 78 is a flowchart showing management execution processing in the present embodiment executed by the main CPU 63. Note that the processes in steps S4501 to S4515 in the management execution process are executed by the main CPU 63 using a program for non-specific control and data for non-specific control.

  First, as in step S3901 of the management execution process (FIG. 71) in the fifteenth embodiment, “LD SP, Y (u + 2)” is used as a load instruction to start the non-specific control on the stack pointer of the main CPU 63. Y (u + 2) is set as a fixed address at (step S4501).

  Thereafter, as a “PUSH WA”, the information of the WA register of the main CPU 63 is saved in a storage area corresponding to the current stack pointer information of the main CPU 63 in the non-specific control stack area 224 by a push command (step S4502). In this case, the WA register information is saved in the storage area corresponding to the fixed address set in the stack pointer of the main CPU 63 in step S4501. Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the next order.

  After that, as a “PUSH BC”, the information in the BC register of the main CPU 63 is saved in the storage area corresponding to the current stack pointer information of the main CPU 63 in the non-specific control stack area 224 by a push command (step S4503). Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the next order.

  After that, as a “PUSH DE”, the DE register information of the main CPU 63 is saved in a storage area corresponding to the current stack pointer information of the main CPU 63 in the non-specific control stack area 224 by a push instruction (step S4504). Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the next order.

  Thereafter, as “PUSH HL”, the information in the HL register of the main CPU 63 is saved in a storage area corresponding to the current stack pointer information of the main CPU 63 in the non-specific control stack area 224 by a push command (step S4505). Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the next order.

  Thereafter, as “PUSH IX”, the information in the IX register of the main CPU 63 is saved in a storage area corresponding to the current stack pointer information of the main CPU 63 in the non-specific control stack area 224 by a push command (step S4506). Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the next order.

  After that, as “PUSH IY”, the information in the IY register of the main CPU 63 is saved in the storage area corresponding to the current stack pointer information of the main CPU 63 in the non-specific control stack area 224 by a push command (step S4507). Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the next order.

  After executing the processing of step S4502 to step S4507, check processing is executed (step S4508). When executing the check process, a subroutine program corresponding to the check process set in the non-specific control program is executed. When executing the program of the subroutine, information for specifying the return address of the management execution process after the execution of the check process is sent to the current stack pointer of the main CPU 63 in the non-specific control stack area 224 by a push command. Write to the storage area corresponding to the information. When the check process is completed, information for specifying the return address is read by the pop instruction, and the program returns to the management execution process program indicated by the return address. The contents of the check process are the same as those in the fifteenth embodiment.

  Thereafter, as in step S3909 of the management execution process (FIG. 71) in the fifteenth embodiment, “LD SP, Y (r + α)” is used to return the stack pointer of the main CPU 63 to the specific control by the load instruction. Y (r + α) is set as the fixed address at (step S4509). The address of Y (r + α) is set as an address between Y (r + 8) and Y (s) in the stack area 222 for specific control.

  After that, as “POP IY”, the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The IY register of the main CPU 63 is overwritten (step S4510). Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the previous order.

  After that, as “POP IX”, the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The IX register of the main CPU 63 is overwritten (step S4511). Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the previous order.

  After that, as “POP HL”, the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The HL register of the main CPU 63 is overwritten (step S4512). Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the previous order.

  After that, as “POP DE”, the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The DE register of the main CPU 63 is overwritten (step S4513). Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the previous order.

  After that, as “POP BC”, the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The BC register of the main CPU 63 is overwritten (step S4514). Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the previous order.

  After that, as “POP WA”, the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The WA register of the main CPU 63 is overwritten (step S4515). Also, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the previous order.

  By executing the processing of steps S4510 to S4515, processing corresponding to non-specific control is started for each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63. It is possible to return to the information corresponding to the specific control immediately before starting.

  In addition to the flag register, the general-purpose CPU 63 includes various general-purpose registers, auxiliary registers, and index registers. In this case, in Steps S4502 to S4507, information on each of the WA register, BC register, DE register, HL register, IX register, and IY register, which are some of the various general-purpose registers, auxiliary registers, and index registers. Are saved in the stack area 224 for non-specific control. These WA register, BC register, DE register, HL register, IX register and IY register are registers used in the check process (step S4508) which is a process corresponding to non-specific control. By saving the information set in such a register to the non-specific control stack area 224 prior to the execution of the check process (step S4508), the information of these registers used in the specific control is non-specific controlled. It is possible to evacuate before starting. Therefore, even if these registers are overwritten during non-specific control, when the non-specific control is terminated, the information saved in the non-specific control stack area 224 is restored to these registers so that the state of these registers is restored. Can be returned to a state corresponding to the specific control before the non-specific control is executed.

  Also, instead of saving all the information in the various general-purpose registers, auxiliary registers, and index registers to the non-specific control stack area 224, the WA to be used in the check process corresponding to the non-specific control. Register information is saved in the non-specific control stack area 224 by selectively saving information in the register, BC register, DE register, HL register, IX register, and IY register to the non-specific control stack area 224. Therefore, it is possible to suppress the capacity to be secured. Therefore, it is possible to save the register information as described above while ensuring a large capacity of the stack area 224 for non-specific control that can be used in the check process.

<Eighteenth embodiment>
In this embodiment, the processing configuration of the management execution process is different from that of the fifteenth embodiment. Hereinafter, a configuration different from the fifteenth embodiment will be described. The description of the same configuration as that of the fifteenth embodiment is basically omitted.

  FIG. 79 is a flowchart showing the management execution process in the present embodiment executed by the main CPU 63. Note that the processing from step S4601 to step S4605 in the management execution processing is executed by the main CPU 63 using a program for non-specific control and data for non-specific control.

  First, as in step S3901 of the management execution process (FIG. 71) in the fifteenth embodiment, “LD SP, Y (u + 2)” is used as a load instruction to start the non-specific control on the stack pointer of the main CPU 63. Y (u + 2) is set as the fixed address at (step S4601).

  After that, as “LD (_ALLBUF), ALL”, the information of all registers of the main CPU 63 is saved in the ALL buffer set in the work area 223 for non-specific control by a load instruction (step S4602). As a result, not only the WA register, BC register, DE register, HL register, IX register, and IY register used in the check process, which is a process corresponding to non-specific control, but also all other registers are included. Register information is collectively saved in the ALL buffer of the work area 223 for non-specific control. Thus, by saving all the registers of the main CPU 63 to the work area 223 for non-specific control, it is not necessary to selectively save the register information of the main CPU 63.

  Here, the registers to be saved include a flag register. The information in the flag register is saved in the specific control stack area 222 in step S3802 of the management process (FIG. 70). In step S4602, the information in the flag register is saved in the work area 223 for non-specific control. Is done. Thereby, it is not necessary to selectively save the register information of the main CPU 63 including the flag register information. Even if the information in the flag register is saved in an overlapping manner in this way, after the management execution process is completed, the main CPU 63 is moved from the special control stack area 222 in step S3804 of the management process (FIG. 70). Since the information is returned to the flag register, the information in the flag register of the main CPU 63 can be returned to the state immediately before the execution of the management execution process when returning to the process corresponding to the specific control. It becomes.

  Thereafter, a check process is executed (step S4603). When executing the check process, a subroutine program corresponding to the check process set in the non-specific control program is executed. When executing the program of the subroutine, information for specifying the return address of the management execution process after the execution of the check process is sent to the current stack pointer of the main CPU 63 in the non-specific control stack area 224 by a push command. Write to the storage area corresponding to the information. When the check process is completed, information for specifying the return address is read by the pop instruction, and the program returns to the management execution process program indicated by the return address. The contents of the check process are the same as those in the fifteenth embodiment.

  Thereafter, as in step S3909 of the management execution process (FIG. 71) in the fifteenth embodiment, “LD SP, Y (r + α)” is used to return the stack pointer of the main CPU 63 to the specific control by the load instruction. Y (r + α) is set as the fixed address at (step S4604). The address of Y (r + α) is set as an address between Y (r + 8) and Y (s) in the stack area 222 for specific control.

  After that, as “LD ALL, (_ALLBUF)”, the information saved in the ALL buffer of the work area 223 for non-specific control is overwritten in the register corresponding to each of the main CPUs 63 by the load instruction (step S4605). As a result, it is possible to restore each piece of information in all the registers of the main CPU 63 to information corresponding to the specific control immediately before the processing corresponding to the non-specific control is started.

  According to the above configuration, the register information of the main CPU 63 is not saved in the non-specific control stack area 224 but is saved in the non-specific control work area 223, so that the non-specific control stack area is increased accordingly. The capacity of 224 can be kept small. In addition, when the stack area 224 for non-specific control is used, the information writing order is read first from the later information. Therefore, if the information reading order is shifted due to some noise or the like, All of the subsequent reading order information is restored to a different register. The occurrence probability of such an event increases as the amount of information saved in the non-specific control stack area 224 increases. On the other hand, by saving the register information in the work area 223 for non-specific control, it becomes possible to prevent the above event from occurring even when there is a lot of information to be saved. .

  Further, when saving the register information of the main CPU 63 to the work area 223 for non-specific control, the WA register, BC register, DE register, and HL register used in the check process corresponding to the non-specific control. The information of all registers including not only the IX register and the IY register but also other registers is collectively saved in the ALL buffer of the work area 223 for non-specific control. Thus, by saving all the registers of the main CPU 63 to the work area 223 for non-specific control, it is not necessary to selectively save the register information of the main CPU 63.

  Note that the information of all registers of the main CPU 63 is saved in the main RAM 65 in the process corresponding to the non-specific control after the process corresponding to the non-specific control is started. In other words, the information of all the registers may be saved in the main RAM 65 in the process corresponding to the specific control. In addition, when the process corresponding to the non-specific control is completed, the information is returned to all the registers by the process corresponding to the non-specific control. The return of the information may be performed in a process corresponding to the specific control after the process corresponding to the non-specific control is completed.

<Nineteenth embodiment>
In this embodiment, the processing configuration of the management execution process is different from that of the fifteenth embodiment. Hereinafter, a configuration different from the fifteenth embodiment will be described. The description of the same configuration as that of the fifteenth embodiment is basically omitted.

  FIG. 80 is a flowchart showing the management execution process in the present embodiment executed by the main CPU 63. Note that the processing of steps S4701 to S4706 in the management execution processing is executed by the main CPU 63 using a program for non-specific control and data for non-specific control.

  First, as “LD (_SPBUF), SP”, the stack pointer information of the main CPU 63 is saved in the SP buffer set in the work area 223 for non-specific control by a load instruction (step S4701). As a result, information on the stack pointer corresponding to the specific control immediately before the process corresponding to the non-specific control is started is saved in the work area 223 for non-specific control.

  After that, as in step S3901 of the management execution process (FIG. 71) in the fifteenth embodiment, “LD SP, Y (u + 2)” is used as the load instruction to start the non-specific control on the stack pointer of the main CPU 63. Y (u + 2) is set as the fixed address at (step S4702).

  After that, as a “PUSH ALL”, the information of all registers of the main CPU 63 is transferred from the storage area corresponding to the current stack pointer information of the main CPU 63 in the non-specific control stack area 224 and the storage area by a push command. The data is saved in a continuous storage area (step S4703). In this case, since the information of all the registers of the main CPU 63 cannot be stored in one storage area in the non-specific control stack area 224, the current state of the main CPU 63 in the non-specific control stack area 224 as described above. The storage area corresponding to the stack pointer information and the storage area continuing from the storage area are used as the saving destination of the register information. In addition, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written in the next order with respect to the storage area in which the last information is stored when saving the information of all registers.

  Thereafter, a check process is executed (step S4704). When executing the check process, a subroutine program corresponding to the check process set in the non-specific control program is executed. When executing the program of the subroutine, information for specifying the return address of the management execution process after the execution of the check process is sent to the current stack pointer of the main CPU 63 in the non-specific control stack area 224 by a push command. Write to the storage area corresponding to the information. When the check process is completed, information for specifying the return address is read by the pop instruction, and the program returns to the management execution process program indicated by the return address. The contents of the check process are the same as those in the fifteenth embodiment.

  After that, as “POP ALL”, information saved in the storage area corresponding to the current stack pointer information of the main CPU 63 in the stack area 224 for non-specific control and information saved from the storage area to a continuous storage area by a pop instruction Is overwritten in the register corresponding to each of the main CPUs 63 (step S4705). As a result, it is possible to return the information of all registers of the main CPU 63 to the information corresponding to the specific control immediately before the processing corresponding to the non-specific control is started.

  Thereafter, as “LD SP, (_SPBUF)”, the information saved in the SP buffer of the work area 223 for non-specific control is overwritten on the stack pointer of the main CPU 63 by the load instruction (step S4706). As a result, the stack pointer information of the main CPU 63 returns to the information corresponding to the specific control immediately before the processing corresponding to the non-specific control is started.

  According to the above configuration, when the register information of the main CPU 63 is saved in the non-specific control stack area 224, the WA register, BC register, DE used in the check process that is a process corresponding to the non-specific control. Information on all registers including not only registers, HL registers, IX registers, and IY registers but also other registers is collectively saved in the stack area 224 for non-specific control. Thus, by saving all the registers of the main CPU 63 in the non-specific control stack area 224, it is not necessary to selectively save the register information of the main CPU 63.

  Information on the stack pointer corresponding to the specific control immediately before the processing corresponding to the non-specific control is started is saved in the work area 223 for non-specific control. As a result, even if the information of the stack pointer corresponding to the specific control immediately before the process corresponding to the non-specific control is started can be changed, the process corresponding to the non-specific control is ended and the specific control is performed. When returning to the corresponding process, it is possible to return the information of the stack pointer of the main CPU 63 to the information corresponding to the specific control immediately before the process corresponding to the non-specific control is started.

  Note that the information of all registers of the main CPU 63 is saved in the main RAM 65 in the process corresponding to the non-specific control after the process corresponding to the non-specific control is started. In other words, the information of all the registers may be saved in the main RAM 65 in the process corresponding to the specific control. In addition, when the process corresponding to the non-specific control is completed, the information is returned to all the registers by the process corresponding to the non-specific control. The return of the information may be performed in a process corresponding to the specific control after the process corresponding to the non-specific control is completed.

<20th Embodiment>
In the present embodiment, the processing configurations of the management process and the management execution process are different from those of the fifteenth embodiment. Hereinafter, a configuration different from the fifteenth embodiment will be described. The description of the same configuration as that of the fifteenth embodiment is basically omitted.

  FIG. 81 is a flowchart showing the management process in the present embodiment executed by the main CPU 63. Note that the processing from step S4801 to step S4811 in the management processing is executed by the main CPU 63 using the specific control program and the specific control data.

  First, in order to prohibit the generation of the timer interrupt process (FIG. 69), interrupt prohibition is set (step S4801). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and started in the middle of the management execution process described later, which is a process corresponding to the non-specific control. Is possible.

  After that, the information of the flag register of the main CPU 63 is saved in the stack area 222 for specific control by a push command as “PUSH PSW” (step S4802). The flag register includes a carry flag, a zero flag, a P / V flag, a sine flag, a half carry flag, and the like, and the information in the flag register changes depending on the execution result of the arithmetic instruction, rotate instruction, input / output instruction, and the like. By saving the flag register information before the subroutine program corresponding to the management execution process is started, the flag register in the state before the subroutine is changed or changed after the subroutine is started is saved. Information can be saved in the stack area 222 for specific control.

  Thereafter, as “LD WA, 0”, the WA register of the main CPU 63 is cleared to “0” by the load instruction (step S4803). Further, as “LD BC, 0”, the BC register of the main CPU 63 is cleared to “0” by the load instruction (step S4804). Further, as “LD DE, 0”, the DE register of the main CPU 63 is cleared to “0” by the load instruction (step S4805). Further, as “LD HL, 0”, the HL register of the main CPU 63 is cleared to “0” by the load instruction (step S4806). Further, as “LD IX, 0”, the load command clears the IX register of the main CPU 63 to “0” (step S4807). Also, as “LD IY, 0”, the IY register of the main CPU 63 is cleared to “0” by the load instruction (step S4808).

  In addition to the flag register, the general-purpose CPU 63 includes various general-purpose registers, auxiliary registers, and index registers. In this case, in step S4803 to step S4808, each of the WA register, BC register, DE register, HL register, IX register, and IY register, which are some of these general-purpose registers, auxiliary registers, and index registers, is set. Clear “0”. These WA register, BC register, DE register, HL register, IX register, and IY register are registers used in the check process (step S4902) that is a process corresponding to non-specific control. Prior to execution of processing corresponding to non-specific control by clearing such registers to “0” prior to execution of management execution processing (step S4809) which is processing corresponding to non-specific control. In addition, it is possible to set the state immediately after the supply of operating power to the main CPU 63 is started.

  Each information of the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register before the process corresponding to the non-specific control is started is after the process corresponding to the non-specific control is completed. This is unnecessary information in the processing corresponding to the specific control. Therefore, even if the information in these registers is cleared to “0” without being saved, no problem occurs in the process corresponding to the specific control that is restored after the process corresponding to the non-specific control is completed.

  After executing the processing in steps S4803 to S4808, the management execution processing is started by reading out a subroutine program corresponding to the management execution processing set in the program for non-specific control (step S4809). In this case, information for specifying the return address of the management process after execution of the management execution process is written into the stack area 222 for specific control by a push command. When the management execution process ends, information for specifying the return address is read by the pop instruction, and the process returns to the management process program indicated by the return address.

  When returning to the management process program after the execution of the management execution process, the main CPU 63 stores the information of the flag register saved in the specific control stack area 222 in step S4802 as a “POP PSW” by a pop instruction. Is returned to the flag register (step S4810). As a result, the information in the flag register of the main CPU 63 is restored to the information at the time when step S4802 was previously executed. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

  Thereafter, in order to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which it is permitted, an interrupt permission is set (step S4811). Thereby, a new execution of the timer interrupt process can be performed.

  FIG. 82 is a flowchart showing the management execution process in the present embodiment executed by the main CPU 63. Note that the processing in steps S4901 to S4909 in the management execution processing is executed by the main CPU 63 using a program for non-specific control and data for non-specific control.

  First, as in step S3901 of the management execution process (FIG. 71) in the fifteenth embodiment, “LD SP, Y (u + 2)” is used to load the stack pointer of the main CPU 63 at the start of non-specific control as a load instruction. Y (u + 2) is set as a fixed address (step S4901).

  Thereafter, a check process is executed (step S4902). When executing the check process, a subroutine program corresponding to the check process set in the non-specific control program is executed. Information for specifying the return address of the execution process is written to the stack area 224 for non-specific control by a push command. When the check process is completed, information for specifying the return address is read by the pop instruction, and the process returns to the management execution process program indicated by the return address. The contents of the check process are the same as those in the fifteenth embodiment.

  Thereafter, as “LD WA, 0”, the WA register of the main CPU 63 is cleared to “0” by the load instruction (step S4903). Further, as “LD BC, 0”, the BC register of the main CPU 63 is cleared to “0” by the load instruction (step S4904). Also, as “LD DE, 0”, the DE register of the main CPU 63 is cleared to “0” by the load instruction (step S4905). Further, as “LD HL, 0”, the HL register of the main CPU 63 is cleared to “0” by the load instruction (step S4906). Further, as “LD IX, 0”, the load command clears the IX register of the main CPU 63 to “0” (step S4907). Also, as “LD IY, 0”, the IY register of the main CPU 63 is cleared to “0” by the load instruction (step S4908).

  These WA register, BC register, DE register, HL register, IX register, and IY register are registers used in the check process (step S4902) that is a process corresponding to non-specific control as already described. Prior to returning from processing corresponding to non-specific control to processing corresponding to specific control, such registers are cleared to “0” before the return to processing corresponding to specific control. The state immediately after the supply of operating power to the side CPU 63 is started can be achieved.

  In addition, each information of the WA register, BC register, DE register, HL register, IX register, and IY register before the process corresponding to the specific control is started is not specified after the process corresponding to the specific control is completed. This is unnecessary information in the processing corresponding to the control. Therefore, even if the information in these registers is cleared to “0” without being saved, no problem occurs in the process corresponding to the non-specific control that is restored after the process corresponding to the specific control is completed.

  Thereafter, as in step S3909 of the management execution process (FIG. 71) in the fifteenth embodiment, “LD SP, Y (r + α)” is used to return the stack pointer of the main CPU 63 to the specific control by the load instruction. Y (r + α) is set as the fixed address at (step S4909). The address of Y (r + α) is set as an address between Y (r + 8) and Y (s) in the stack area 222 for specific control.

  According to the above configuration, the WA register, BC register, DE register, HL register, and IX register of the main CPU 63 when the process corresponding to the non-specific control is started from the situation where the process corresponding to the specific control is being executed. The IY register is cleared to “0”. Thereby, it is not necessary to save the information of each register in the main RAM 65. Therefore, it is not necessary to secure a capacity for saving these pieces of information.

  Further, when returning from the situation where the process corresponding to the non-specific control is being executed to the process corresponding to the specific control, the WA register, BC register, DE register, HL register, IX register and IY register of the main CPU 63 are also changed. “0” is cleared. Thereby, when returning to the process corresponding to specific control, it becomes possible to return the state of each of these registers to the state immediately before the process corresponding to non-specific control is started.

  The state in which each register is cleared to “0” is a state when supply of operating power to the MPU 62 is started. As a result, it is possible to simplify the processing configuration for setting the registers to a predetermined state when starting processing corresponding to non-specific control and when returning to processing corresponding to specific control. .

  When starting the process corresponding to the non-specific control and returning to the process corresponding to the specific control, the registers subject to execution of “0” clear are some of the various registers of the main CPU 63. This makes it possible to reduce the processing load for setting the registers to a predetermined state when processing corresponding to non-specific control is started and when processing returns to processing corresponding to specific control.

  In the configuration in which the WA register, BC register, DE register, HL register, IX register, and IY register are cleared to “0” when processing corresponding to non-specific control is started and when processing corresponding to specific control is restored. Registers other than "0" are not cleared. Thereby, it is possible to prevent information necessary for the process corresponding to the specific control from being erased at the start of the process corresponding to the non-specific control.

  Further, information of registers other than the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register is not saved in the main RAM 65 at the start of processing corresponding to non-specific control. Thus, it is not necessary to secure an area for saving the information in the main RAM 65.

  Information on the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 before the process corresponding to the non-specific control is started is after the process corresponding to the non-specific control is completed. This information is not used in the process corresponding to the specific control. As a result, even if the above-described registers are cleared to “0” when the process corresponding to the non-specific control is started, it corresponds to the specific control after the process corresponding to the non-specific control is completed. It becomes possible not to affect the processing.

  In addition, instead of the configuration in which the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 are cleared to “0” in steps S4803 to S4808 in the management process (FIG. 81), The register may be initialized. That is, when the supply of operating power to the MPU 62 is started, each register of the main CPU 63 is once cleared to “0” and then the information setting of each register is performed so as to be in the initial state, but step S4803 In step S4808, each register may be set so as to be in this initial state. In this case, in each of steps S4903 to S4908, each register is set so as to be in the initial state, and when returning to the processing corresponding to the specific control, the state of each register is not specified. It is possible to return to the state immediately before the processing corresponding to the control is started.

  Also, instead of the configuration in which the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 are cleared to “0” in steps S4803 to S4808 in the management process (FIG. 81), A configuration may be adopted in which “1” is set in all of the registers. In this case, also in steps S4903 to S4908, when “1” is set to all the above-described registers to return to the processing corresponding to the specific control, the state of each of the registers corresponds to the non-specific control. It is possible to return to the state immediately before starting.

  Further, when the processing corresponding to the non-specific control is executed, the flag register information of the main CPU 63 is saved in the main RAM 65 in the processing corresponding to the specific control. However, the present invention is not limited to this. Alternatively, the flag register information may be saved in the main RAM 65 in a process corresponding to non-specific control. In addition, after the process corresponding to the non-specific control is completed, the return of information to the flag register of the main CPU 63 is performed in the process corresponding to the specific control. However, the present invention is not limited to this. The configuration may be such that the return of information to the flag register is performed in a process corresponding to non-specific control.

  In addition, the process of clearing the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 to “0” is a process corresponding to the specific control before the process corresponding to the non-specific control is started. However, the present invention is not limited to this, and a process of clearing these registers to “0” may be executed in a process corresponding to non-specific control. In addition, when the process corresponding to the non-specific control is completed, the process of clearing each register “0” is performed in the process corresponding to the non-specific control. However, the present invention is not limited to this. The process of clearing each register “0” may be performed in a process corresponding to the specific control after the process corresponding to the non-specific control is completed.

  Further, in the management process (FIG. 81), the “PUSH PSW” process in step S4802 is executed before setting “0” in each register in steps S4803 to S4808. The process of “PUSH PSW” in step S4802 is executed after setting “0” in each register in steps S4803 to S4808 and before the subroutine program corresponding to the management execution process is read in step S4809. It is good also as a structure to be made. As a result, it becomes possible to save the information in the flag register after being changed by the load instruction in steps S4803 to S4808 in the stack area 222 for specific control.

<Twenty-first embodiment>
In the present embodiment, the configuration for collecting game history information is different from that of the fifteenth embodiment. Hereinafter, a configuration different from the fifteenth embodiment will be described. The description of the same configuration as that of the fifteenth embodiment is basically omitted.

  FIG. 83 is an explanatory diagram for explaining an electrical configuration according to the present embodiment.

  Similar to the fifteenth embodiment, the MPU 62 is provided with a main CPU 63, a main ROM 64, and a main RAM 65. Further, unlike the fifteenth embodiment, the management RAM 241 is electrically connected to the MPU 62. That is, a management RAM 241 is provided separately from the main RAM 65 built in the MPU 62, and the management RAM 241 is externally attached to the MPU 62.

  Similar to the fifteenth embodiment, the main RAM 65 is provided with a work area 221 for specific control, a stack area 222 for specific control, a work area 223 for non-specific control, and a stack area 224 for non-specific control. ing. Therefore, when the main CPU 63 executes a process corresponding to the specific control using the program for specific control in the main ROM 64 and the data for specific control, the work area 221 for specific control in the main RAM 65 and When the specific control stack area 222 is used and the main CPU 63 executes a process corresponding to the non-specific control using the non-specific control program and the non-specific control data in the main ROM 64. The work area 223 for non-specific control and the stack area 224 for non-specific control in the main RAM 65 are used.

  The management RAM 241 includes a normal counter area 231, an opening / closing execution mode counter area 232, a high frequency support mode counter area 233, and an operation result storage area 234. The contents of these areas 231 to 234 are the same as those in the fifteenth embodiment. Also in the present embodiment, a management execution process including a check process is executed as a process corresponding to the non-specific control in the main CPU 63. In the check process, the game history is collected through the update of the normal counter area 231, the opening / closing execution mode counter area 232, and the high frequency support mode counter area 233, as in the fifteenth embodiment. The 61st to 68th parameters calculated by using the collected game history are written in the calculation result storage area 234. That is, since the management RAM 241 is used when the main CPU 63 executes a process corresponding to non-specific control, the management RAM 241 is used as a work area for non-specific control.

  In addition, when the 61st to 68th parameters are calculated using game history collection and the collected history information, the non-specific control work area 223 and the non-specific control stack area 224 of the main RAM 65 are provided. Used as appropriate.

  According to the above configuration, the normal counter area 231, the open / close execution mode counter area 232, the high frequency support mode counter area 233, and the calculation result storage area 234 are provided in the management RAM 241 externally attached to the MPU 62. As a result, it is possible to store the collected game history information while not increasing the necessary storage capacity in the work area 223 for non-specific control in the main RAM 65, and use the game history. It is possible to store the calculated 61st to 68th parameters. Further, it is possible to increase the storage capacity for storing game history information while using the general-purpose MPU 62.

  Non-specific control work area 223 and non-specific control stack area 224 in main RAM 65 are used as appropriate when collecting the game history and calculating the 61st to 68th parameters using the collected history information. Is done. As a result, it is possible to prevent the processing speed from being extremely reduced when processing related to history information is executed.

  In addition to or instead of the configuration in which the management RAM 241 is provided with the normal counter area 231, the opening / closing execution mode counter area 232, the high frequency support mode counter area 233, and the calculation result storage area 234, the first embodiment described above. A storage area corresponding to the history memory 117 in the form or the like may be set. In this case, it is necessary to increase the storage capacity necessary for storing the history information, but the management RAM 241 externally attached to the MPU 62 is used as a storage unit for storing the history information. Therefore, it is possible to flexibly cope with an increase in storage capacity.

<Twenty-second embodiment>
In the present embodiment, the processing configuration executed by the main CPU 63 is different from that of the fifteenth embodiment. Hereinafter, a configuration different from the fifteenth embodiment will be described. The description of the same configuration as that of the fifteenth embodiment is basically omitted.

  FIG. 84 is a flowchart showing the main processing in the present embodiment executed by the main CPU 63. Note that the processing in steps S5001 to S5019 in the main processing is executed by the main CPU 63 using a program for specific control and data for specific control.

  First, a power-on wait process is executed (step S5001). In the power-on wait process, for example, the process waits without proceeding to the next process until a predetermined time for waiting (specifically, 1 second) elapses after the main process is activated. The operation start and initial setting of the symbol display device 41 are completed during the execution period of the power-on wait process. Thereafter, access to the main RAM 65 is permitted (step S5002).

  Thereafter, it is determined whether or not the reset button 68c has been pressed (step S5003), and it is determined whether or not the setting key insertion unit 68a has been turned ON using the setting key (step S5004). 13 determines whether or not the front door frame 14 is open (step S5005), and determines whether or not the gaming machine main body 12 is open relative to the outer frame 11 (step S5006).

  In the present embodiment, a front door opening sensor 95 for detecting whether or not the front door frame 14 is open with respect to the inner frame 13 is electrically connected to the main CPU 63, and the front door opening sensor The detection result 95 is input to the main CPU 63. In this case, when the front door frame 14 is closed with respect to the inner frame 13, the front door opening sensor 95 transmits a closing detection signal to the main CPU 63, and the front door frame 14 is open with respect to the inner frame 13. In this case, the front door opening sensor 95 transmits an opening detection signal to the main CPU 63. When the main CPU 63 receives the closing detection signal from the front door opening sensor 95, the main CPU 63 specifies that the front door frame 14 is in the closed state, and receives the opening detection signal from the front door opening sensor 95. It specifies that the front door frame 14 is an open state.

  In the present embodiment, a main body opening sensor 96 for detecting whether or not the gaming machine main body 12 is open with respect to the outer frame 11 is electrically connected to the main CPU 63, and the main body opening sensor 96 detection results are input to the main CPU 63. In this case, when the gaming machine main body 12 is in the closed state with respect to the outer frame 11, the main body opening sensor 96 transmits a closing detection signal to the main CPU 63, and the gaming machine main body 12 is in the open state with respect to the outer frame 11. In some cases, the main body opening sensor 96 transmits an opening detection signal to the main CPU 63. The main CPU 63 specifies that the gaming machine main body 12 is in a closed state when a closing detection signal is received from the main body opening sensor 96, and a gaming machine when the opening detection signal is received from the main body opening sensor 96. It is specified that the main body 12 is in an open state.

  If the reset button 68c is pressed (step S5003: YES) and if a negative determination is made in any of steps S5004 to S5006, a clear process at the time of non-setting update is executed (step S5007). . In the clear processing at the time of non-setting update, the specific control is performed except for an area (specifically, a set value counter) in which set value information indicating the set state of the pachinko machine 10 is set in the work area 221 for specific control. The work area 221 is cleared to “0” and initial setting is performed for the area that has been cleared to “0”. As a result, the area indicating whether or not the lottery mode is the high probability mode is cleared to “0”, so that the lottery regardless of the lottery mode immediately before the supply of the operating power to the pachinko machine 10 is stopped. The mode is a low probability mode. In addition, the game turn is not executed, the opening / closing execution mode is not executed, and the general-purpose display portion 38a is not variably displayed, and the general utility 34a is in a closed state. Situation. In addition, since the hold storage area 65a and the power train hold area 65c provided in the work area 221 for specific control are also cleared to “0”, the hold information for the special figure display section 37a is deleted and the map display section. The hold information for 38a is deleted. Further, in the clear process at the time of non-setting update, the stack area 222 for specific control is cleared to “0”. In the clear process at the time of non-setting update, various registers of the main CPU 63 are also cleared after “0” is cleared.

  In the clear process at the time of non-setting update, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to “0”. As a result, even if the supply of operating power to the pachinko machine 10 is started with the reset button 68c being pressed, the non-specific control work area 223 and the non-specific control stack area 224 are not cleared to "0". It becomes possible to do so.

  When the reset button 68c is not pressed (step S5003: NO), it is determined whether or not “1” is set in the power failure flag (step S5008). The power failure flag is provided in the work area 221 for specific control, and when the predetermined power failure process is normally executed when the supply of operating power to the main CPU 63 is stopped, the power failure flag “1” will be set to. If “1” is set in the power failure flag, it is determined whether or not the checksum calculation result matches the checksum stored when the power is shut off, that is, the validity of the stored data is determined (step S5009). . If clear processing at the time of non-setting update is executed in step S5007, or if an affirmative determination is made in step S5009, the setting of the pachinko machine 10 is confirmed by checking the value of the setting value counter in the work area 221 for specific control It is determined whether or not the value is normal (step S5010). Specifically, it is determined to be normal when the set value set in the set value counter is any of “setting 1” to “setting 6”, and abnormal when it is “0” or 7 or more. Judge that there is.

  If a negative determination is made in any of steps S5008 to S5010, an operation prohibiting process is executed. In the operation prohibition process, after executing an error notification process for notifying the hole manager or the like of the occurrence of an error (step S5011), an infinite loop is entered. The operation prohibiting process is canceled by executing a setting updating clear process (step S5018), which will be described later.

  When an affirmative determination is made in all of steps S5008 to S5010, a power-on setting process is executed (step S5012). In the power-on setting process, a predetermined area of the work area 221 for specific control such as initialization of a power failure flag is set to an initial value, and a command corresponding to the current gaming state is transmitted to the sound emission control device 81.

  The main CPU 63 is configured to periodically execute the timer interrupt process, but the timer interrupt process is prohibited from occurring at the stage where the main process is started. The state where the generation of the timer interrupt process is prohibited is canceled at the timing before the process of step S5012 is completed and the process of step S5013 is executed, and the execution of the timer interrupt process is permitted. Thereby, when the supply of operating power to the main CPU 63 is started, the power-on setting process in step S5012 ends, and the timer interrupt process is not executed until the stage before the process in step S5013 is started. Therefore, the process for advancing the game in the main CPU 63 is not started until this situation is reached.

  Thereafter, the process proceeds to the remaining process of steps S5013 to S5016. That is, the main CPU 63 is configured to periodically execute the timer interrupt process, but a remaining time occurs between one timer interrupt process and the next timer interrupt process. The remaining time varies depending on the processing completion time of each timer interrupt process, but the remaining processes in steps S5013 to S5016 are repeatedly executed using the irregular time. In this regard, it can be said that the remaining processes in steps S5013 to S5016 are non-periodic processes that are performed irregularly. In steps S5013 to S5016, the same processes as those in steps S113 to S116 of the main process (FIG. 9) in the first embodiment are executed.

  On the other hand, if the reset button 68c is pressed (step S5003: YES) and if a positive determination is made in all of steps S5004 to S5006, processing for updating the set value is executed. Specifically, first, a setting value copy process is executed (step S5017). In the copy process, information on the setting value counter used for specifying the setting value of the pachinko machine 10 in the work area 221 for specific control is stored in a copy area provided in the work area 221 for specific control. . Thereby, even if the information of the set value counter is cleared to “0” in the clear process at the time of setting update (step S5018) executed thereafter, the main process before the clear process at the time of update of the set value is executed. It becomes possible to grasp the set value of the pachinko machine 10 (that is, the set value of the pachinko machine 10 before the supply of operating power to the pachinko machine 10 is stopped).

  Thereafter, a clear process at the time of setting update is executed (step S5018). In the clear process at the time of setting update, the work area 221 for specific control is set to “0” except for the area indicating whether or not the lottery mode in the work area 221 for specific control is the high probability mode and the copy area. "Is cleared, and initial setting is performed for the area cleared" 0 ". As a result, the game times are not executed, the opening / closing execution mode is not executed, and the general-purpose display portion 38a is not variably displayed. It becomes a certain situation. In addition, since the hold storage area 65a and the power train hold area 65c provided in the work area 221 for specific control are also cleared to “0”, the hold information for the special figure display section 37a is deleted and the map display section. The hold information for 38a is deleted. In the clear process at the time of setting update, the stack area 222 for specific control is cleared to “0” and initial setting is performed for the area cleared to “0”. In the clear process at the time of setting update, the set value counter used for specifying the set value of the pachinko machine 10 is cleared to “0”. In the clear process at the time of setting update, various registers of the main CPU 63 are also cleared after “0” is cleared.

  On the other hand, the clearing process at the time of setting update does not clear “0” in the area indicating whether or not the winning lottery mode is the high probability mode, so even if the setting value updating process (step S5019) is executed, the winning / failing lottery mode Can be maintained in the mode before the supply of operating power to the pachinko machine 10 is stopped. In addition, since the copy area is not cleared to “0” in the clear process at the time of setting update, the set value set before the clear process at the time of setting update is executed can be specified thereafter.

  In the clear process at the time of setting update, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to “0”. Thereby, even if the set value update process capable of changing the set value of the pachinko machine 10 is executed, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to “0”. It becomes possible to do so.

  Then, after executing the set value update process in step S5019, the process proceeds to step S5012. Hereinafter, the setting value update process will be described. FIG. 85 is a flowchart showing the set value update processing. In addition, the process of step S5101-step S5114 in a setting value update process is performed in the main side CPU63 using the program for specific control, and the data for specific control.

  First, “1” is set to the set value counter provided in the work area 221 for specific control (step S5101). The set value counter is a counter for the main CPU 63 to specify which set value the set state of the pachinko machine 10 is. When “1” is set in the setting value counter, when the setting value update process is executed, the setting value becomes “setting 1” regardless of the setting value up to that point.

  Thereafter, a display start process of the set value is executed (step S5102). In the setting value display start process, the third notification display device 69c is controlled to display the number “1” corresponding to “setting 1”. The manager of the game hall can grasp the current setting state of the pachinko machine 10 by checking the third notification display device 69c when changing the setting value.

  Thereafter, it is determined whether or not one game ball is detected by the outlet detection sensor 48a (step S5103). Specifically, it is determined whether or not the signal received from the out port detection sensor 48a has switched from the LOW level to the HI level. If a negative determination is made in step S5103, it is determined whether or not the update button 68b has been pressed once (step S5104). Specifically, it is determined whether or not the signal from the sensor that detects the pressing operation of the update button 68b is switched from the LOW level to the HI level. If a negative determination is made in step S5104, the process returns to step S5103, and it is determined whether or not one game ball is detected by the outlet detection sensor 48a.

  When the update button 68b is pressed once (step S5104: YES), the value of the set value counter in the work area 221 for specific control is incremented by 1 (step S5105). If the value of the set value counter after adding 1 exceeds “6” (step S5106: YES), “1” is set to the set value counter (step S5107). As a result, each time the update button 68b is pressed, the setting value is updated to one level higher. When the update button 68b is pressed once in the state of “setting 6”, the setting value is set to “setting 1”. Will return.

  If a negative determination is made in step S5106, or if the process of step S5107 is executed, a display update process for the set value is executed (step S5108). In the set value display update process, display control is performed on the third notification display device 69c so that a number corresponding to the value of the set value counter in the work area 221 for specific control is displayed. The manager of the game hall can grasp the setting state of the pachinko machine 10 after pressing the update button 68b by checking the third notification display device 69c.

  After executing the process of step S5108, the process returns to step S5103, and it is determined whether or not one game ball is detected by the outlet detection sensor 48a. When one out-of-game ball is not detected by the out mouth detection sensor 48a (step S5103: NO), the processing after step S5104 is executed again. When one game ball is detected by the out mouth detection sensor 48a (step S5103: YES), it is determined whether or not the setting key insertion unit 68a is switched from the ON state to the OFF state (step S5109). In this case, it is not specified whether or not the setting key insertion unit 68a is in the OFF state, but it is specified whether or not the switching from the ON state to the OFF state has occurred, and the switching has occurred. If specified, an affirmative determination is made in step S5109.

  If it is not switched to the OFF state (step S5109: NO), the process of step S5109 is executed again. As a result, the progress of the process is waited until the setting key insertion unit 68a is turned off. When the state is switched to the OFF state (step S5109: YES), a set value display end process is executed (step S5110). In the set value display end process, the display of the set value on the third notification display device 69c is ended. In this case, display of information on various parameters stored in the calculation result storage area 234 provided in the work area 223 for non-specific control is started by the first to third notification display devices 69a to 69c.

  After that, a setting value comparison process is executed (step S5111). In the setting value comparison process, it is determined whether or not the information of the setting value counter in the work area 221 for specific control matches the information stored in the copy area in the work area 221 for specific control. That is, it is determined whether or not the setting value set before the supply of operating power to the pachinko machine 10 is the same as the setting value set in the current setting value update process.

  When the set value set before the supply of operating power to the pachinko machine 10 is stopped and the set value set in the current set value update process are the same (step S5112: NO), non- A notification process at the time of change is executed (step S5113). In the notification process at the time of non-change, a setting maintenance command indicating that the setting value has not been changed is transmitted to the sound emission control device 81. Upon receiving the setting maintaining command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the setting maintenance, and outputs a sound “setting is maintained” from the speaker unit 54. In addition, a character image “setting is maintained” is displayed on the symbol display device 41.

  These notifications are maintained until a notification execution period (for example, 10 seconds) elapses after the setting maintenance command is transmitted, and are ended when the notification execution period has elapsed. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the administrator of the game hall. As the notification end operation, for example, the update button 68b may be pressed, or the reset button 68c may be pressed. By confirming the notification, the manager of the game hall can grasp that the set value has been maintained. In the non-change notification process, the set value is maintained by setting the display content on at least one of the first to third notification display devices 69a to 69c to the display content corresponding to the setting maintenance. It is good also as a structure which alert | reports this, and it is good also as a structure which performs the external output which shows that the setting value was maintained.

  If the set value set before the supply of operating power to the pachinko machine 10 is stopped and the set value set in the current set value update process are not the same (step S5112: YES), change An hour notification process is executed (step S5114). In the notification process at the time of change, a setting change command indicating that the setting value has been changed is transmitted to the sound emission control device 81. Upon receiving the setting change command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to the setting change, and outputs a sound “setting change” from the speaker unit 54. In addition, a character image “setting change” is displayed on the symbol display device 41.

  These notifications are maintained until a notification execution period (for example, 10 seconds) elapses after the setting change command is transmitted, and are ended when the notification execution period has elapsed. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the administrator of the game hall. As the notification end operation, for example, the update button 68b may be pressed, or the reset button 68c may be pressed. By confirming the notification, the manager of the game hall can grasp that the set value has been changed. In the notification process at the time of the change, the setting value has been changed by setting the display content on at least one of the first to third notification display devices 69a to 69c as the display content corresponding to the setting change. It is good also as a structure which alert | reports, and it is good also as a structure which performs the external output which shows that the setting value was changed.

  As described above, in order to execute the setting value update process in the present embodiment, not only the setting key insertion portion 68a is turned ON, but also the reset button 68c is pressed, and the front door frame 14 is opened. Therefore, the gaming machine main body 12 needs to be opened. This makes it difficult to execute the set value update process illegally.

  Further, in order to execute the set value update process, the front door frame 14 and the gaming machine main body 12 need to be opened. As a result, even if the setting value update process is attempted to be executed illegally, the front door frame 14 and the gaming machine main body 12 are in an open state, so that the illegal action becomes conspicuous, and the administrator of the gaming hall It becomes easier to detect fraud.

  In particular, in order to execute the set value update process, not only the opening operation of the gaming machine main body 12 necessary for exposing the main control device 60 but also the opening operation of the front door frame 14 is required. It becomes possible to make the work of the illegal act complicated, and to make the illegal action stand out.

  In addition, in the configuration that does not return to the process for advancing the game when the set value update process is not completed, in order to confirm the set value selected in the set value update process and end the set value update process, It is necessary to cause a game ball to enter the out port 24a and cause the out port detection sensor 48a to detect the game ball, and then to turn off the setting key insertion portion 68a. Thereby, even if the set value update process is executed illegally, it is possible to make it difficult to perform an operation for ending the set value update process and then returning to the process for proceeding with the game.

  Further, the set value set before the supply of operating power to the pachinko machine 10 is stopped and the set value selected in the set value update process are compared, and whether or not both set values are the same. Notification corresponding to this is executed. Thereby, the manager of the game hall can easily grasp whether or not the set value can be changed by the set value update process.

  FIG. 86 is a flowchart showing timer interrupt processing in the present embodiment, which is executed by the main CPU 63. The timer interrupt process is executed periodically (for example, at a cycle of 4 milliseconds) in a state where the processes of steps S5013 to S5016 are being executed in the main process (FIG. 84). Note that the program corresponding to the timer interrupt process is set as a program for specific control.

  In steps S5201 to S5205, the same processes as those in steps S301 to S305 of the timer interrupt process (FIG. 11) in the first embodiment are executed. These processes are executed by the main CPU 63 using a program for specific control and data for specific control.

  Thereafter, a setting confirmation process is executed (step S5206). When executing the setting confirmation process, a subroutine program corresponding to the setting confirmation process set in the specific control program is executed. When executing the subroutine program, the setting confirmation process is executed. The information for specifying the return address of the timer interrupt process after the execution of is written in the stack area 222 for specific control by the push command. When the setting confirmation processing is completed, information for specifying the return address is read by the pop instruction, and the program returns to the timer interrupt processing program indicated by the return address.

  FIG. 87 is a flowchart showing a setting confirmation process. Note that the processing from step S5301 to step S5312 in the setting confirmation processing is executed by the main CPU 63 using the specific control program and the specific control data.

  First, it is determined whether or not the third notification display device 69c displays a setting value corresponding to the information of the setting value counter in the work area 221 for specific control (step S5301). If a negative determination is made in step S5301, it is determined whether or not the game times or the opening / closing execution mode is in effect (step S5302), and the pattern change display times and the general electric utility 34a are released in the general-purpose display unit 38a. It is determined whether or not any of the open states that can enter the state (step S5303), and it is determined whether or not the front door frame 14 is open with respect to the inner frame 13 (step S5304). 11 determines whether or not the gaming machine main body 12 is in an open state (step S5305), and determines whether or not the setting key insertion portion 68a is ON-operated (step S5306). Whether the front door frame 14 is in the open state is determined based on the detection result of the front door open sensor 95 as in step S5005 in the main process (FIG. 84), and whether the gaming machine main body 12 is in the open state. This determination is made based on the detection result of the main body opening sensor 96 as in step S5006 in the main process (FIG. 84).

  If a negative determination is made in any of steps S5302 to S5306, the setting confirmation process is terminated without executing the processes of steps S5307 to S5309. When affirmative determination is made in all of step S5302 to step S5306, a setting value display start process is executed (step S5307). In the set value display start processing, the third notification display device 69c is controlled to display the set value number corresponding to the set value counter information in the work area 221 for specific control. The manager of the game hall can grasp the current setting state of the pachinko machine 10 by visually checking the third notification display device 69c when checking the set value.

  Thereafter, “1” is set to the game stop flag provided in the work area 221 for specific control (step S5308). The game stop flag is a situation where an affirmative determination is made in step S5207 in the timer interruption process (FIG. 86) and the process of steps S5208 to S5221 is not executed, that is, the execution of the process for advancing the game is to be stopped. This is a flag for specifying whether or not there is a main CPU 63. When “1” is set in the game stop flag, an affirmative determination is made in step S5207 of the timer interrupt process (FIG. 86), so that the process of steps S5208 to S5221 is not executed. As a result, the setting value is confirmed in a situation where the execution of the process for advancing the game is stopped. However, even if the game stop flag is set to “1”, the processing of steps S5201 to S5205 in the timer interrupt processing (FIG. 86) is executed, and the setting value is being confirmed. Even in this case, the power failure monitoring is executed, and the hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and further illegal detection is executed.

  Thereafter, a confirmation notification start command is transmitted to the sound emission control device 81 (step S5309). Upon receiving the confirmation notification start command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the setting confirmation, and outputs a sound “setting confirmation is in progress” from the speaker unit 54. . Further, a character image “Setting is being confirmed” is displayed on the symbol display device 41. These notifications are continued until a confirmation notification end command is received from the main CPU 63. Note that an external output indicating that the set value is being confirmed may be performed.

  As described above, on the condition that it is neither a game time nor an opening / closing execution mode, nor is it any of the variable display time of the picture on the general-purpose display portion 38a and the general power release state in which the general electric utility 34a can be in the open state. By making the display for confirming the set value on the third notification display device 69c, it is possible to prevent the set value from being confirmed in a situation where a game is being performed. It becomes possible.

  In addition, in order to display the setting value on the third notification display device 69c, not only the setting key insertion portion 68a is turned ON, but also the front door frame 14 is in an open state. Therefore, the gaming machine main body 12 needs to be opened. This makes it difficult to display the setting value confirmation display illegally.

  Further, in order for the display for confirming the set value to be performed on the third notification display device 69c, the front door frame 14 and the gaming machine main body 12 need to be in an open state. As a result, even if the display for confirming the set value is illegally performed, since the front door frame 14 and the gaming machine main body 12 are in the open state, the illegal act becomes conspicuous, and management of the gaming hall It becomes easy for a person to find the fraud.

  In particular, not only the opening operation of the gaming machine main body 12 necessary for exposing the main control device 60 but also the display for confirming the set value is performed on the third notification display device 69c. Further, by requiring the opening operation of the front door frame 14, it becomes possible to make the work of the illegal act complicated and to make the illegal action stand out.

  If an affirmative determination is made in step S5301, it is determined whether or not the setting key insertion unit 68a has been turned OFF (step S5310). If an OFF operation has been performed (step S5310: YES), the game stop flag in the work area 221 for specific control is cleared to “0” (step S5311). As a result, a negative determination is made in step S5207 of the timer interrupt process (FIG. 86), so that the processes in steps S5208 to S5221 are executed. Thereby, the state in which execution of the process for advancing a game is stopped is cancelled.

  Thereafter, a confirmation notification end command is transmitted to the sound emission control device 81 (step S5312). By receiving the confirmation notification end command, the sound emission control device 81 ends the notification indicating that the set values are being confirmed in the symbol display device 41, the display light emitting unit 53, and the speaker unit 54.

  Returning to the description of the timer interrupt process (FIG. 86), after the setting confirmation process in step S5206 is completed, it is determined whether or not the game is stopped (step S5207). In this case, if the game stop flag in the work area 221 for specific control is set to “1” in the setting confirmation process in step S5206, an affirmative determination is made in step S5207, and steps S5208 to S5221 are performed. Do not execute processing. Further, also when the occurrence of fraud is detected in the fraud detection process in step S5205, an affirmative determination is made in step S5207, and the processes in steps S5208 to S5221 are not executed.

  In steps S5208 to S5219, the same processes as those in steps S307 to S318 of the timer interrupt process (FIG. 11) in the first embodiment are executed. These processes are executed by the main CPU 63 using a program for specific control and data for specific control. In step S5221, the same process as step S3719 of the timer interrupt process (FIG. 69) in the fifteenth embodiment is executed.

  On the other hand, in step S5220, a RAM monitoring process is executed. When executing the RAM monitoring process, a subroutine program corresponding to the RAM monitoring process set in the program for specific control is executed, but after executing the RAM monitoring process, the subroutine program is executed. The information for specifying the return address of the timer interrupt processing at is written in the stack area 222 for specific control by a push command. When the RAM monitoring process is completed, information for specifying the return address is read by the pop instruction, and the process returns to the timer interrupt process program indicated by the return address.

  FIG. 88 is a flowchart showing the RAM monitoring process. Note that the processing from step S5401 to step S5412 in the RAM monitoring processing is executed by the main CPU 63 using a program for specific control and data for specific control.

  First, monitoring processing of the work area 221 for specific control is executed (step S5401). In the monitoring process, it is monitored whether an abnormality has occurred in the information stored in the work area 221 for specific control due to noise or the like. Although this monitoring method is arbitrary, for example, in the work area 221 for specific control, whether or not the state of the storage area where information is not written by various controls in the main CPU 63 is different from the initial state. And a method of determining that an abnormality has occurred when the state is different from the initial state. In this case, if the initial state of the storage area is a value of “0”, it is determined that an abnormality has occurred when “1” is stored in the storage area, and the initial state of the storage area is “1”. When the value is “0”, it is determined that an abnormality has occurred when the storage area has a value “0”. In addition to the monitoring method described above, a configuration may be adopted in which it is determined that an abnormality has occurred when the value of a predetermined byte is a value different from a value that can be set in a normal state.

  If it is determined in step S5401 that there is an abnormality (step S5402: YES), processing in steps S5409 to S5412 is executed. If it is not determined in step S5401 that there is an abnormality (step S5402: NO), the process proceeds to step S5403.

  In step S5403, the monitoring process for the stack area 222 for specific control is executed. In the monitoring process, it is monitored whether an abnormality has occurred in the information stored in the stack area 222 for specific control due to noise or the like. Although this monitoring method is arbitrary, for example, in the stack area 222 for specific control, whether or not the state of the storage area where information is not written by various controls in the main CPU 63 is different from the initial state. And a method of determining that an abnormality has occurred when the state is different from the initial state. In this case, if the initial state of the storage area is a value of “0”, it is determined that an abnormality has occurred when “1” is stored in the storage area, and the initial state of the storage area is “1”. When the value is “0”, it is determined that an abnormality has occurred when the storage area has a value “0”. In addition to the monitoring method described above, a configuration may be adopted in which it is determined that an abnormality has occurred when the value of a predetermined byte is a value different from a value that can be set in a normal state.

  If it is determined in step S5403 that there is an abnormality (step S5404: YES), processing in steps S5409 to S5412 is executed. If it is not determined that there is an abnormality in step S5403 (step S5404: NO), the process proceeds to step S5405.

  In step S5405, a monitoring process for the work area 223 for non-specific control is executed. In the monitoring process, it is monitored whether or not an abnormality has occurred in the information stored in the work area 223 for non-specific control due to noise or the like. Although this monitoring method is arbitrary, for example, in the work area 223 for non-specific control, whether or not the state of the storage area where information is not written by various controls in the main CPU 63 is different from the initial state. There is a method of monitoring whether or not an abnormality has occurred when the state is different from the initial state. In this case, if the initial state of the storage area is a value of “0”, it is determined that an abnormality has occurred when “1” is stored in the storage area, and the initial state of the storage area is “1”. When the value is “0”, it is determined that an abnormality has occurred when the storage area has a value “0”. In addition to the monitoring method described above, a configuration may be adopted in which it is determined that an abnormality has occurred when the value of a predetermined byte is a value different from a value that can be set in a normal state.

  If it is determined in step S5405 that there is an abnormality (step S5406: YES), processing in steps S5409 to S5412 is executed. If it is not determined that there is an abnormality in step S5405 (step S5406: NO), the process proceeds to step S5407.

  In step S5407, the non-specific control stack area 224 is monitored. In this monitoring process, it is monitored whether or not an abnormality has occurred in the information stored in the non-specific control stack area 224 due to noise or the like. Although this monitoring method is arbitrary, for example, in the stack area 224 for non-specific control, whether or not the state of the storage area where information is not written by various controls in the main CPU 63 is different from the initial state. There is a method of monitoring whether or not an abnormality has occurred when the state is different from the initial state. In this case, if the initial state of the storage area is a value of “0”, it is determined that an abnormality has occurred when “1” is stored in the storage area, and the initial state of the storage area is “1”. When the value is “0”, it is determined that an abnormality has occurred when the storage area has a value “0”. In addition to the monitoring method described above, a configuration may be adopted in which it is determined that an abnormality has occurred when the value of a predetermined byte is a value different from a value that can be set in a normal state.

  If it is determined in step S5407 that there is an abnormality (step S5408: YES), processing in steps S5409 to S5412 is executed. Specifically, first, a setting value copy process is executed (step S5409). In the copy process, information on the setting value counter used for specifying the setting value of the pachinko machine 10 in the work area 221 for specific control is stored in a copy area provided in the work area 221 for specific control. . As a result, even if the information of the set value counter is cleared to “0” in the abnormality clearing process (step S5410) executed thereafter, the pachinko machine 10 before the abnormality clearing process is executed. It becomes possible to grasp the set value.

  Thereafter, a clear process at the time of abnormality is executed (step S5410). In the abnormal clear process, the work area 221 for specific control is cleared to “0” except for the copy area, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack for non-specific control. The area 224 is cleared to “0”. The initial setting is performed after clearing “0”. That is, in the RAM monitoring process, an abnormality occurs in any one of the work area 221 for specific control, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control. When it is specified that the work area 221 for specific control is cleared to “0” except for the copy area, the stack area 222 for specific control, the work area 223 for non-specific control, and the non-specific control use area Clear the stack area 224 of “0”. As a result, when there is a possibility that some information abnormality has occurred in the main RAM 65, neither the process corresponding to the specific control nor the process corresponding to the non-specific control is executed as it is. It becomes possible to do so.

  When the stack area 222 for specific control is cleared to “0”, the return address information after execution of the RAM monitoring process is also deleted. Therefore, when the stack area 222 for specific control is cleared to “0”, the process returns to a predetermined program after the process of step S5412 is completed. Specifically, it is configured to uniquely return to the process of step S5013 in the main process (FIG. 22). However, the program that uniquely returns is not limited to step S5013, and may be step S5221 in the timer interrupt process (FIG. 86). When the stack area 222 for specific control is cleared to “0”, the stack order of the stack pointer 222 for the main CPU 63 is set to the address of the first storage area.

  Thereafter, an abnormal command indicating that a clear process at the time of abnormality has occurred is transmitted to the sound emission control device 81 (step S5411). Upon receiving the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to forced clearing, and outputs a sound “forcibly cleared” from the speaker unit 54. Further, the character image “forced clear” is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are terminated when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the administrator of the game hall. As the notification end operation, for example, the update button 68b may be pressed, or the reset button 68c may be pressed. By confirming the notification, the game hall manager can grasp that the main RAM 65 has been forcibly cleared.

  Thereafter, a set value update process is executed (step S5412). In other words, when the clear process at the time of abnormality occurs, “0” clear is executed including the set value counter in the work area 221 for specific control, so the set value of the pachinko machine 10 is reset. A set value update process is executed to perform this. The processing content of the set value update processing is the same as step S5019 of the main processing (FIG. 84). Accordingly, each time the update button 68b is pressed once, the set value is updated one step at a time, and the set value being selected is determined by detecting the game ball with the out port detection sensor 48a. The setting value in the middle of updating and the determined setting value are displayed on the third notification display device 69c. Thereafter, when the setting key insertion unit 68a is switched from the ON state to the OFF state, it is determined that the end condition of the setting value update process is satisfied.

  Here, it is not determined that the end condition is satisfied only by the setting key insertion unit 68a being in the OFF state, and the end condition is determined when the setting key insertion unit 68a is switched from the ON state to the OFF state. It is determined that it has been established. When the set value update process is executed in the RAM monitoring process (FIG. 88), the setting key insertion unit 68a is in the OFF state at the start of the set value update process. In order to establish it, it is necessary to insert the setting key into the setting key insertion unit 68a and perform the ON operation after once performing the ON operation. As a result, it is possible to prevent the setting value update process from ending even though a regular operation by the game hall manager is not performed.

  When the setting key insertion unit 68a is switched from the ON state to the OFF state and the end condition of the set value update process is satisfied, step S5111 in the set value update process (FIG. 85) is executed. It is compared whether or not the set value stored in the copy area in the work area 221 for specific control and the set value set this time in the set value counter in the work area 221 for specific control are the same. That is, it is determined whether or not the set value set before the execution of the clear process at the time of abnormality (step S5410) is the same as the set value set in the current set value update process. When both set values are the same (step S5112: NO), the already-described setting maintenance notification is performed by executing the non-change notification process (step S5113). On the other hand, when the two setting values are different (step S5112: YES), the already-described setting change notification is performed by executing the notification process at the time of change (step S5114).

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

  In order to execute the set value update process when the supply of operating power to the pachinko machine 10 is started, not only the setting key insertion unit 68a is turned ON, but also the reset button 68c is pressed. The front door frame 14 is in an open state, and the gaming machine main body 12 needs to be in an open state. This makes it difficult to execute the set value update process illegally.

  In order to execute the set value update process, the front door frame 14 and the gaming machine main body 12 need to be in an open state. As a result, even if the setting value update process is attempted to be executed illegally, the front door frame 14 and the gaming machine main body 12 are in an open state, so that the illegal action becomes conspicuous, and the administrator of the gaming hall It becomes easier to detect fraud.

  In particular, in order to execute the set value update process, not only the opening operation of the gaming machine main body 12 necessary for exposing the main control device 60 but also the opening operation of the front door frame 14 is required. It becomes possible to make the work of the illegal act complicated, and to make the illegal action stand out.

  In a configuration in which the process does not return to the process for advancing the game when the set value update process is not completed, the set value selected in the set value update process is confirmed and the set value update process is terminated. It is necessary to cause a game ball to enter 24a and cause the out-port detection sensor 48a to detect the game ball, and then to turn off the setting key insertion portion 68a. Thereby, even if the set value update process is executed illegally, it is possible to make it difficult to perform an operation for ending the set value update process and then returning to the process for proceeding with the game.

  The set value set before the supply of operating power to the pachinko machine 10 is stopped and the set value selected in the set value update process are compared, and whether or not both set values are the same. Corresponding notification is executed. Thereby, the manager of the game hall can easily grasp whether or not the set value can be changed by the set value update process.

  The set value is set on the condition that it is neither the game time nor the opening / closing execution mode, nor is it in either the variable display time of the pattern in the general-purpose display portion 38a or the general power release state in which the general utility 34a can be in the open state. By making the display for confirmation to be performed on the third notification display device 69c, it becomes possible to prevent the setting value confirmation work from being performed in a situation where a game is being performed. .

  In order to display the setting value on the third notification display device 69c, the setting key insertion portion 68a is not only turned ON, but the front door frame 14 is opened. The gaming machine main body 12 needs to be in an open state. This makes it difficult to display the setting value confirmation display illegally.

  In order for the display for confirming the set value to be performed on the third notification display device 69c, the front door frame 14 and the gaming machine main body 12 need to be in an open state. As a result, even if the display for confirming the set value is illegally performed, since the front door frame 14 and the gaming machine main body 12 are in the open state, the illegal act becomes conspicuous, and management of the gaming hall It becomes easy for a person to find the fraud.

  In particular, not only the opening operation of the gaming machine main body 12 necessary for exposing the main control device 60 but also the display for confirming the set value is performed on the third notification display device 69c. Further, by requiring the opening operation of the front door frame 14, it becomes possible to make the work of the illegal act complicated and to make the illegal action stand out.

  When it is specified that an error has occurred in any one of the work area 221 for specific control, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control Clears the work area 221 for specific control except for the copy area, and sets the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control to “0”. "clear. As a result, when there is a possibility that some information abnormality has occurred in the main RAM 65, both the process corresponding to the specific control and the process corresponding to the non-specific control are executed as they are. It is possible to prevent it from being lost.

  In the process corresponding to the specific control, an information abnormality occurs not only in the work area 221 for specific control and the stack area 222 for specific control, but also in the work area 223 for non-specific control and the stack area 224 for non-specific control. It is monitored whether or not As a result, it is possible to simplify the processing configuration compared to a configuration in which whether or not an information abnormality has occurred is divided into processing corresponding to specific control and processing corresponding to non-specific control.

  When it is specified that an error has occurred in any one of the work area 221 for specific control, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control In the process corresponding to the specific control, not only the work area 221 for specific control and the stack area 222 for specific control but also the work area 223 for non-specific control and the stack area 224 for non-specific control are “0”. Cleared. As a result, it is possible to simplify the processing configuration as compared with a configuration in which “0” clear is performed separately for processing corresponding to specific control and processing corresponding to non-specific control.

  When the clear process at the time of abnormality is executed due to the occurrence of the information abnormality, the set value update process is executed. As a result, it is possible to prevent the game from proceeding although the set value is not set. In this case, when the set value that was set before the clear process at the time of abnormality is the same as the set value that was set by the set value update process after the execution of the clear process at the time of abnormality The setting maintenance notification is performed. Thereby, even if the clear process at the time of abnormality is executed, the setting maintenance notification is performed by resetting the setting value set in the previous situation, and the clear process at the time of abnormality is executed It is possible to clearly indicate to the player that the set value has not changed. By the way, since it is common to record the set values of each installed pachinko machine 10 in the game hall, the set value update process after executing the clear process at the time of abnormality so as to become the recorded set value Can be performed.

  Note that the condition for executing the set value update process when the supply of operating power to the pachinko machine 10 is started may be a condition different from the above embodiment. FIG. 89 is a flowchart showing a main process according to another embodiment. In the main process, the same processes as steps S5001 to S5019 of the main process (FIG. 84) in the above embodiment are executed in steps S5501 to S5506 and steps S5508 to S5520. On the other hand, in the main process, it is determined in step S5507 whether or not the operation handle of the firing operation device 28 operated to fire the game ball in the game area PA has been rotated from the initial rotation position. Then, the reset button 68c is pressed (step S5503: YES), the setting key insertion portion 68a is turned ON (step S5504: YES), and the front door frame 14 is in an open state with respect to the inner frame 13. (Step S5505: YES), the gaming machine main body 12 is open with respect to the outer frame 11 (step S5506: YES), and the operation handle of the firing operation device 28 is rotated from the initial rotation position. If so (step S5507: YES), the set value update process (step S5520) is executed. Thus, in order to execute the setting value update process when the supply of operating power to the pachinko machine 10 is started, not only the setting key is inserted into the setting key insertion unit 68a but the ON operation is performed, It becomes necessary to start supply of operating power to the pachinko machine 10 in a state where the operation handle of the operation device 28 is rotated. Therefore, it is possible to make it difficult to perform an act of changing the set value illegally. In step S5507, it is not determined whether or not the operation handle of the firing operation device 28 is rotated from the initial rotation position, but it is determined whether or not the firing operation device 28 is touched by the player. It is good also as a structure.

  In addition, as a condition for executing the set value update process when the supply of operating power to the pachinko machine 10 is started, the front door frame 14 is in an open state with respect to the inner frame 13 and the outside Although both conditions that the gaming machine main body 12 is in an open state are set for the frame 11, only one of these conditions may be set.

  In addition, as a condition for executing the set value update process when the supply of operating power to the pachinko machine 10 is started, a condition that the reset button 68c is pressed is set. However, a configuration in which the condition is not set may be employed.

  In addition, as a condition for executing the set value update process when the supply of operating power to the pachinko machine 10 is started, the operation to the pachinko machine 10 in a situation where a game ball is detected by the gate detection sensor 49a. It is also possible to adopt a configuration in which a condition that power supply is started is set. Thus, in order to execute the setting value update process when the supply of operating power to the pachinko machine 10 is started, not only the setting key is inserted into the setting key insertion unit 68a but the ON operation is performed, and the through operation is performed. It is necessary to start supply of operating power to the pachinko machine 10 with the game ball remaining in the gate 35. Therefore, it is possible to make it difficult to perform an act of changing the set value illegally.

  In addition, the content of the operation for confirming the set value in the set value update process may be different from that in the above embodiment. FIG. 90 is a flowchart showing a setting value update process according to another embodiment. In the set value update process, the same processes as steps S5101 to S5102 and steps S5104 to S5114 of the set value update process (FIG. 85) in the above embodiment are executed in steps S5601 to S5602 and S5604 to S5614. . On the other hand, in the set value update processing, in step S5603, it is not determined whether or not a game ball is detected by the outlet detection sensor 48a, but the ON signal is continuously output from the gate detection sensor 49a. It is determined whether or not the ON duration period is equal to or longer than the end reference period (specifically, 5 seconds). If an affirmative determination is made in step S5603, the currently selected set value is confirmed, and the flow advances to step S5609. According to this configuration, in order to determine the set value being selected, it is necessary to intentionally retain the game ball in the through gate 35 over the end reference period. The game ball staying in the through gate 35 for more than the end reference period does not occur in a situation where a normal game is being performed. As a result, it is possible to prevent or make it difficult to establish a condition for determining the set value being selected in a situation where a normal game is being performed. Further, even if the setting value update process is started due to injustice, it is possible to make it difficult to perform an operation for determining the setting value being selected in the setting value update process.

  Further, in the setting value update process, the setting value being selected may be determined when the operation handle of the firing operation device 28 is rotated from the initial rotation position, and the firing operation device 28 is touched by the player. In this case, the setting value being selected may be determined.

  In addition, in the setting value update processing, when the special electricity detection sensor 45a detects that a game ball has entered the special electricity prize winning device 32 provided with an opening / closing member, the setting value being selected may be determined. Alternatively, the setting value being selected may be determined when the second operation port detection sensor 47a detects that a game ball has entered the second operation port 34 provided with the opening / closing member. In this case, in order to determine the set value being selected, it is necessary to care for the game ball after manually setting the target pitching part to an open state, so that it is difficult to illegally change the set value. It becomes possible.

  Further, in the set value update process, the selection is made based on the detection that the game ball has entered the second ball entry part after the game ball has been detected to have entered the first ball entry part. It is good also as a structure by which an inside setting value is decided. In this case, in order to fix the set value being selected, it is necessary to enter the game balls into a plurality of ball-entry parts according to a predetermined order. Is possible. In this case, the workability of regular work is not drastically reduced by making both the first and second entrance parts be entrance parts without opening and closing members. It becomes possible to do.

  Further, in the setting value update process, the setting key insertion unit 68a is switched from the ON state to the OFF state, so that the setting value being selected is confirmed and the end condition of the setting value update process is satisfied.

  In addition, the operation for updating the setting value by one step in the setting value updating process is not limited to the pressing operation of the update button 68b, and the setting value is set to one step by pressing the reset button 68c. It is good also as a structure updated.

  Further, in the situation where the reset button 68c is pressed and the setting key insertion portion 68a is turned ON by the setting key, the supply of operating power to the pachinko machine 10 is started. When the front door frame 14 is not in an open state with respect to the frame 13 or when the gaming machine main body 12 is not in an open state with respect to the outer frame 11, a clear process (step S5007) at the time of non-setting update is executed. The configuration is not limited, and the configuration may be such that the clear process at the time of non-setting update is not executed. Thereby, it becomes possible to prevent the clear process at the time of non-setting update from being executed against the intention of the manager of the game hall.

  Further, when the supply of operating power to the pachinko machine 10 is started in a situation where the reset button 68c is pressed and the setting key insertion portion 68a is not turned ON by the setting key, When the front door frame 14 is not in an open state with respect to the frame 13 or when the gaming machine main body 12 is not in an open state with respect to the outer frame 11, a clear process (step S5007) at the time of non-setting update is executed. The configuration is not limited, and the configuration may be such that the clear process at the time of non-setting update is not executed. As a result, it is possible to make it difficult to execute the clear process at the time of non-setting update illegally.

<Twenty-third embodiment>
In the present embodiment, the processing configuration of the main process is different from that of the twenty-second embodiment. Hereinafter, a configuration different from the twenty-second embodiment will be described. The description of the same configuration as that of the twenty-second embodiment is basically omitted.

  FIG. 91 is a flowchart showing main processing in the present embodiment which is executed by the main CPU 63. Note that the processing in steps S5701 to S5720 in the main processing is executed by the main CPU 63 using a program for specific control and data for specific control.

  First, power-on wait processing is executed (step S5701). In the power-on wait process, for example, the process waits without proceeding to the next process until a predetermined time for waiting (specifically, 1 second) elapses after the main process is activated. The operation start and initial setting of the symbol display device 41 are completed during the execution period of the power-on wait process. Thereafter, access to the main RAM 65 is permitted (step S5702).

  Thereafter, based on the detection result of the front door opening sensor 95, it is determined whether or not the front door frame 14 is in an open state with respect to the inner frame 13 (step S5703). Based on the detection result of the main body opening sensor 96, the outer frame 11 is determined. On the other hand, it is determined whether or not the gaming machine main body 12 is in an open state (step S5704), and it is determined whether or not the reset button 68c is pressed (step S5705). If a negative determination is made in any of steps S5703 to S5705, the processes of steps S5706 to S5714 are executed. The processes in steps S5706 to S5714 are the same as steps S5008 to S5016 in the main process (FIG. 84) in the twenty-second embodiment.

  When affirmative determination is made in all of steps S5703 to S5705, a selection process is executed (step S5715). In the selection process, the clear process at the time of non-setting update is executed and the set value update process is not executed, and the clear process at the time of setting update is executed and the set value update process is executed. A process of determining whether or not based on a selection operation by the manager of the game hall is executed. Specifically, every time the update button 68b is pressed, the state is switched from the state in which one of the above states is selected to the state in which the other state is selected. The selection operation may be performed by operating the reset button 68c, or may be performed by operating another operation unit. Further, when the clear process at the time of non-setting update is executed and the setting value update process is not executed is selected, “O” is displayed on the first notification display device 69a and the second notification display device 69b. When the third notification display device 69c is turned off, the clear processing at the time of setting update is executed, and the setting value update processing is executed, “O” is displayed on the second notification display device 69b. And the first notification display device 69a and the third notification display device 69c are turned off. In addition, when the reset button 68c is continuously pressed for a fixed selection period (specifically, 10 seconds) or more, the selected situation among the above situations is confirmed as the current selection target. To do.

  In addition, when the update button 68b is continuously pressed for a fixed selection period (specifically, 10 seconds) or more, the selected situation among the above situations is confirmed as the current selection target. It may be configured, and when the other operation unit is continuously pressed for more than the fixed selection period (specifically, 10 seconds), the situation on the selected side among the above situations is selected this time It is good also as a structure decided as an object. Moreover, it is good also as a structure which confirms the situation of the side selected among said each situation as this selection object by operating the operation handle of the firing operation apparatus 28. FIG.

  In the selection process, when the clear process at the time of non-setting update is executed and the setting value update process is not executed is determined as the current selection target (step S5716: NO), the clear process at the time of non-setting update is executed. (Step S5717). The processing content of the clear processing at the time of non-setting update is the same as step S5007 of the main processing (FIG. 84) in the twenty-second embodiment.

  In the selection process, when the clearing process at the time of setting update is executed and the situation in which the setting value update process is executed is determined as the current selection target (step S5716: YES), the setting value copy process is executed (step S5716). In step S5718, a clear process at the time of setting update is executed (step S5719), and a set value update process is executed (step S5720). The processing content of these steps S5718 to S5720 is the same as that of steps S5017 to S5019 of the main processing (FIG. 84) in the twenty-second embodiment.

  According to the above configuration, even when the setting key insertion unit 68a is not provided, the clear process at the time of non-setting update is executed and the setting value update process is not executed, and the clear process at the time of setting update is executed. At the same time, it becomes possible for the manager of the game hall to select which of the situations in which the set value update process is executed.

  In addition, not only when the set value update process is executed but also when the clear process at the time of non-setting update is executed, the operation power is supplied to the pachinko machine 10 while the reset button 68c is pressed. In addition to starting, it is necessary to open the front door frame 14 relative to the inner frame 13 and open the gaming machine body 12 relative to the outer frame 11. As a result, it is possible to make it difficult to execute the clear process at the time of non-setting update illegally.

  As a condition for executing the selection process when the supply of operating power to the pachinko machine 10 is started, the front door frame 14 is open with respect to the inner frame 13 and the outer frame. 11, the game machine main body 12 is in a state in which both conditions for being in an open state are set, but only one of these conditions may be set.

  Further, as a condition for executing the selection process when the supply of operating power to the pachinko machine 10 is started, a condition that the firing handle of the firing operation device 28 is rotated is added. A configuration in which a condition that the firing operation device 28 is touched may be added, or a condition that a game ball is detected in the gate detection sensor 49a is added. Also good.

<Twenty-fourth embodiment>
In the present embodiment, the processing configuration of the RAM monitoring process is different from that of the twenty-second embodiment. Hereinafter, a configuration different from the twenty-second embodiment will be described. The description of the same configuration as that of the twenty-second embodiment is basically omitted.

  FIG. 92 is a flowchart showing the RAM monitoring process in the present embodiment which is executed by the main CPU 63. Note that the processing from step S5801 to step S5814 in the RAM monitoring processing is executed by the main CPU 63 using a specific control program and specific control data.

  First, monitoring processing of the work area 221 for specific control is executed (step S5801). The contents of the monitoring process are the same as step S5401 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined in step S5801 that there is an abnormality (step S5802: YES), processing in steps S5805 to S5808 is executed.

  If it is not determined that there is an abnormality in step S5801 (step S5802: NO), monitoring processing for the stack area 222 for specific control is executed (step S5803). The contents of the monitoring process are the same as step S5403 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined in step S5803 that there is an abnormality (step S5804: YES), processing in steps S5805 to S5808 is executed.

  For details of the processes in steps S5805 to S5808, first, a setting value copy process is executed (step S5805). In the copy process, information on the setting value counter used for specifying the setting value of the pachinko machine 10 in the work area 221 for specific control is stored in a copy area provided in the work area 221 for specific control. . As a result, even if the information of the set value counter is cleared to “0” in the abnormality clear process (step S5806) executed thereafter, the pachinko machine 10 before the abnormality clear process is executed. It becomes possible to grasp the set value.

  Thereafter, a clear process at the time of abnormality is executed (step S5806). In the clear process at the time of abnormality, the work area 221 for specific control is cleared to “0” except for the copy area, and the stack area 222 for specific control is cleared to “0”. The initial setting is performed after clearing “0”. On the other hand, “0” clearing of the work area 223 for non-specific control and the stack area 224 for non-specific control is not executed. That is, in the RAM monitoring process according to the present embodiment, when it is specified that an abnormality has occurred in either the work area 221 for specific control or the stack area 222 for specific control, the specific control is excluded except for the copy area. The work area 221 is cleared to “0” and the stack area 222 for specific control is cleared to “0”. As a result, when there is a possibility that some kind of information abnormality has occurred in the work area 221 for specific control or the stack area 222 for specific control, processing corresponding to the specific control is executed as it is. It is possible to prevent it from being lost. Further, even if an information abnormality occurs in the work area 221 for specific control or the stack area 222 for specific control, the work area 223 for non-specific control and the stack area 224 for non-specific control are cleared to “0”. As a result, the non-specific control work area 223 and the non-specific control stack area 224 are cleared to “0” in response to an information abnormality in the specific control work area 221 or the specific control stack area 222. It becomes possible not to be.

  When the stack area 222 for specific control is cleared to “0”, the return address information after execution of the RAM monitoring process is also deleted. Therefore, when the stack area 222 for specific control is cleared to “0”, the process returns to a predetermined program after the process of step S5808 is completed. Specifically, it is configured to uniquely return to the process of step S5013 in the main process (FIG. 22). However, the program that uniquely returns is not limited to step S5013, and may be step S5221 in the timer interrupt process (FIG. 86). When the stack area 222 for specific control is cleared to “0”, the stack order of the stack pointer 222 for the main CPU 63 is set to the address of the first storage area.

  Thereafter, an abnormal command indicating that a clear process at the time of abnormality has occurred is transmitted to the sound emission control device 81 (step S5807). Upon receiving the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to forced clearing, and outputs a sound “forcibly cleared” from the speaker unit 54. Further, the character image “forced clear” is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are terminated when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the administrator of the game hall. As the notification end operation, for example, the update button 68b may be pressed, or the reset button 68c may be pressed. By confirming the notification, the manager of the game hall can grasp that the work area 221 for specific control and the stack area 222 for specific control have been forcibly cleared.

  Thereafter, a set value update process is executed (step S5808). The processing content of the setting value update processing is the same as that in step S5412 in the RAM monitoring processing (FIG. 88) in the twenty-second embodiment.

  If it is not determined that there is an abnormality in both step S5801 and step S5803 (step S5802 and step S5804: NO), monitoring processing for the work area 223 for non-specific control is executed (step S5809). The contents of the monitoring process are the same as step S5405 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined in step S5809 that there is an abnormality (step S5810: YES), the work area 223 for non-specific control is cleared to “0” and initial setting is performed (step S5811). In this case, all of the normal counter area 231, the open / close execution mode counter area 232, the high frequency support mode counter area 233, the calculation result storage area 234 and the management start flag are cleared to “0”. Thereby, it becomes possible to eliminate the information abnormality in the work area 223 for non-specific control.

  On the other hand, in step S5811, the work area 221 for specific control, the stack area 222 for specific control, and the stack area 224 for non-specific control are not cleared to “0”. As a result, even if an information abnormality occurs in the work area 223 for non-specific control, the work area 221 for specific control, the stack area 222 for specific control, and the stack area 224 for non-specific control are “ It becomes possible not to clear “0”.

  In step S5811, although the normal counter area 231, the open / close execution mode counter area 232, the high frequency support mode counter area 233, and the calculation result storage area 234 are cleared to “0”, the management start flag is not cleared to “0”. It is good also as a structure. In step S5811, the normal counter area 231, the open / close execution mode counter area 232, the high frequency support mode counter area 233, and the management start flag are cleared to “0”, but the calculation result storage area 234 is not cleared to “0”. It is good also as a structure. In step S5811, the normal counter area 231, the open / close execution mode counter area 232, and the high frequency support mode counter area 233 are cleared to “0”, but the calculation result storage area 234 and the management start flag are not cleared to “0”. It is good also as a structure.

  When a negative determination is made in step S5810 or when the process of step S5811 is executed, a monitoring process for the stack area 224 for non-specific control is executed (step S5812). The contents of the monitoring process are the same as step S5407 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined in step S5812 that there is an abnormality (step S5813: YES), the stack area 224 for non-specific control is cleared to “0” and initial setting is performed (step S5814). Thereby, it is possible to eliminate the information abnormality in the non-specific control stack area 224.

  On the other hand, in step S5814, the work area 221 for specific control, the stack area 222 for specific control, and the work area 223 for non-specific control are not cleared to “0”. Thus, even if an information abnormality occurs in the non-specific control stack area 224, the specific control work area 221, the specific control stack area 222, and the non-specific control work area 223 are " It becomes possible not to clear “0”.

  According to the above configuration, when it is specified that an abnormality has occurred in either the specific control work area 221 or the specific control stack area 222, the specific control work area 221 except for the copy area. Is cleared to “0” and the stack area 222 for specific control is cleared to “0”. As a result, when there is a possibility that some kind of information abnormality has occurred in the work area 221 for specific control or the stack area 222 for specific control, processing corresponding to the specific control is executed as it is. It is possible to prevent it from being lost.

  Even if an information abnormality occurs in the work area 221 for specific control or the stack area 222 for specific control, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to “0”. Accordingly, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to “0” when an information abnormality occurs in the work area 221 for specific control or the stack area 222 for specific control. It becomes possible to do so.

  Even if an information abnormality occurs in the work area 223 for non-specific control, the work area 221 for specific control, the stack area 222 for specific control, and the stack area 224 for non-specific control are not cleared to “0”. This prevents the work area 221 for specific control, the stack area 222 for specific control, and the stack area 224 for non-specific control from being cleared to “0” triggered by an information abnormality in the work area 223 for non-specific control. It becomes possible.

  Even if an information abnormality occurs in the non-specific control stack area 224, the specific control work area 221, the specific control stack area 222, and the non-specific control work area 223 are not cleared to "0". This prevents the work area 221 for specific control, the stack area 222 for specific control, and the work area 223 for non-specific control from being cleared to “0” triggered by an information abnormality in the stack area 224 for non-specific control. It becomes possible.

  If an information abnormality has occurred in the work area 221 for specific control, the work area 221 for specific control except for the copy area is cleared to “0”, while the stack area 222 for specific control is “ The configuration may not be cleared to “0”.

  Further, when an information abnormality has occurred in the stack area 222 for specific control, the stack area 222 for specific control is cleared to “0”, while the work area 221 for specific control is not cleared to “0”. It is good. In this case, even if the stack area 222 for specific control is cleared to “0”, the process from step S5805 to step S5808 may not be executed.

<25th Embodiment>
In the present embodiment, the processing configuration for monitoring whether or not an information abnormality has occurred in each of the areas 221 to 224 of the main RAM 65 is different from that in the twenty-second embodiment. Hereinafter, a configuration different from the twenty-second embodiment will be described. The description of the same configuration as that of the twenty-second embodiment is basically omitted.

  FIG. 93 is a flowchart showing the RAM monitoring process in the present embodiment which is executed by the main CPU 63. Note that the processing from step S5901 to step S5908 in the RAM monitoring processing is executed by the main CPU 63 using a program for specific control and data for specific control.

  First, monitoring processing of the work area 221 for specific control is executed (step S5901). The contents of the monitoring process are the same as step S5401 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined in step S5901 that there is an abnormality (step S5902: YES), processing in steps S5905 to S5908 is executed.

  If it is not determined in step S5901 that there is an abnormality (step S5902: NO), monitoring processing for the stack area 222 for specific control is executed (step S5903). The contents of the monitoring process are the same as step S5403 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined in step S5903 that there is an abnormality (step S5904: YES), processing in steps S5905 to S5908 is executed.

  For details of the processes in steps S5905 to S5908, first, a set value copy process is executed (step S5905). In the copy process, information on the setting value counter used for specifying the setting value of the pachinko machine 10 in the work area 221 for specific control is stored in a copy area provided in the work area 221 for specific control. . Thereby, even if the information of the set value counter is cleared to “0” in the clear process at the time of abnormality (step S5906) executed thereafter, the pachinko machine 10 before the clear process at the time of the abnormality is executed. It becomes possible to grasp the set value.

  Thereafter, clear processing at the time of abnormality is executed (step S5906). In the clear process at the time of abnormality, the work area 221 for specific control is cleared to “0” except for the copy area, and the stack area 222 for specific control is cleared to “0”. The initial setting is performed after clearing “0”. On the other hand, “0” clearing of the work area 223 for non-specific control and the stack area 224 for non-specific control is not executed. That is, in the RAM monitoring process according to the present embodiment, when it is specified that an abnormality has occurred in either the work area 221 for specific control or the stack area 222 for specific control, the specific control is excluded except for the copy area. The work area 221 is cleared to “0” and the stack area 222 for specific control is cleared to “0”. As a result, when there is a possibility that some kind of information abnormality has occurred in the work area 221 for specific control or the stack area 222 for specific control, processing corresponding to the specific control is executed as it is. It is possible to prevent it from being lost. Further, even if an information abnormality occurs in the work area 221 for specific control or the stack area 222 for specific control, the work area 223 for non-specific control and the stack area 224 for non-specific control are cleared to “0”. As a result, the non-specific control work area 223 and the non-specific control stack area 224 are cleared to “0” in response to an information abnormality in the specific control work area 221 or the specific control stack area 222. It becomes possible not to be.

  Thereafter, an abnormal command indicating that a clear process at the time of abnormality has occurred is transmitted to the sound emission control device 81 (step S5907). Upon receiving the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to the forced clearing of the work area 221 for specific control and the stack area 222 for specific control, and the speaker unit 54. To output a voice saying "Forced clear has been executed for specific control." In addition, a character image “Forced clear for specific control has been executed” is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are terminated when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the administrator of the game hall. As the notification end operation, for example, the update button 68b may be pressed, or the reset button 68c may be pressed. By confirming the notification, the manager of the game hall can grasp that the work area 221 for specific control and the stack area 222 for specific control have been forcibly cleared.

  Thereafter, a set value update process is executed (step S5908). The processing content of the setting value update processing is the same as that in step S5412 in the RAM monitoring processing (FIG. 88) in the twenty-second embodiment.

  In the RAM monitoring process that is executed using the specific control program and the specific control data as described above, information abnormality monitoring is performed for the specific control work area 221 and the specific control stack area 222. However, information abnormality monitoring is not performed for the work area 223 for non-specific control and the stack area 224 for non-specific control. The monitoring of the information abnormality about the work area 223 for non-specific control and the stack area 224 for non-specific control is a process corresponding to non-specific control in which a program for non-specific control and data for non-specific control are used. Executed.

  FIG. 94 is a flowchart showing management execution processing in the present embodiment executed by the main CPU 63. The management execution process is executed by reading out a subroutine program in the management process (FIG. 70) as in the fifteenth embodiment. Further, the processes in steps S6001 to S6016 in the management execution process are executed by the main CPU 63 using a program for non-specific control and data for non-specific control.

  In Steps S6001 to S6008 and Steps S6010 to S6016, the same processing as Steps S3901 to S3915 of the management execution processing (FIG. 71) in the fifteenth embodiment is executed. In step S6009, another monitoring process is executed. When executing the separate monitoring process, a subroutine program corresponding to the separate monitoring process set in the non-specific control program is executed. When executing the subroutine program, the separate monitoring process is executed. Information for specifying the return address of the later management execution process is written to the non-specific control stack area 224 by a push command. When the separate monitoring process is completed, information for specifying the return address is read by the pop instruction, and the process returns to the management execution process program indicated by the return address.

  FIG. 95 is a flowchart showing another monitoring process. Note that the processing in steps S6101 to S6108 in the separate monitoring processing is executed by the main CPU 63 using a program for non-specific control and data for non-specific control.

  First, monitoring processing of the work area 223 for non-specific control is executed (step S6101). The contents of the monitoring process are the same as step S5405 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined in step S6101 that there is an abnormality (step S6102: YES), the work area 223 for non-specific control is cleared to “0” and initial setting is performed (step S6103). In this case, all of the normal counter area 231, the open / close execution mode counter area 232, the high frequency support mode counter area 233, the calculation result storage area 234 and the management start flag are cleared to “0”. Thereby, it becomes possible to eliminate the information abnormality in the work area 223 for non-specific control.

  On the other hand, in step S6103, the work area 221 for specific control, the stack area 222 for specific control, and the stack area 224 for non-specific control are not cleared to “0”. As a result, even if an information abnormality occurs in the work area 223 for non-specific control, the work area 221 for specific control, the stack area 222 for specific control, and the stack area 224 for non-specific control are “ It becomes possible not to clear “0”.

  In step S6103, although the normal counter area 231, the open / close execution mode counter area 232, the high frequency support mode counter area 233, and the calculation result storage area 234 are cleared to “0”, the management start flag is not cleared to “0”. It is good also as a structure. In step S6103, the normal counter area 231, the opening / closing execution mode counter area 232, the high frequency support mode counter area 233, and the management start flag are cleared to “0”, but the calculation result storage area 234 is not cleared to “0”. It is good also as a structure. In step S6103, although the normal counter area 231, the open / close execution mode counter area 232, and the high frequency support mode counter area 233 are cleared to “0”, the calculation result storage area 234 and the management start flag are not cleared to “0”. It is good also as a structure.

  Thereafter, a clear notification process is executed (step S6104). In the clear notification process, a command indicating that the work area 223 for non-specific control is cleared to “0” is transmitted to the sound emission control device 81. Upon receiving the command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the forced clearing of the work area 223 for non-specific control, and “history information is forcibly cleared from the speaker unit 54. Sound is output. In addition, a character image “history information has been forcibly cleared” is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are terminated when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the administrator of the game hall. As the notification end operation, for example, the update button 68b may be pressed, or the reset button 68c may be pressed. By confirming the notification, the manager of the game hall can grasp that the work area 223 for non-specific control has been forcibly cleared.

  If a negative determination is made in step S6102, or if the process of step S6104 is executed, a monitoring process for the stack area 224 for non-specific control is executed (step S6105). The contents of the monitoring process are the same as step S5407 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined in step S6105 that there is an abnormality (step S6106: YES), the stack area 224 for non-specific control is cleared to “0” and initial setting is performed (step S6107). Thereby, it is possible to eliminate the information abnormality in the non-specific control stack area 224.

  On the other hand, in step S6107, the work area 221 for specific control, the stack area 222 for specific control, and the work area 223 for non-specific control are not cleared to “0”. Thus, even if an information abnormality occurs in the non-specific control stack area 224, the specific control work area 221, the specific control stack area 222, and the non-specific control work area 223 are " It becomes possible not to clear “0”.

  Thereafter, a clear notification process is executed (step S6108). In the clear notification process, a command indicating that the stack area 224 for non-specific control is cleared to “0” is transmitted to the sound emission control device 81. Upon receiving the command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the forced clearing of the stack area 224 for non-specific control. "Forcibly cleared" is output. In addition, a character image “Non-specific control stack has been forcibly cleared” is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are terminated when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the administrator of the game hall. As the notification end operation, for example, the update button 68b may be pressed, or the reset button 68c may be pressed. By confirming the notification, the manager of the game hall can grasp that the stack area 224 for non-specific control has been forcibly cleared.

  When the stack area 224 for non-specific control is forcibly cleared, the address of the program in step S6010 in the management execution process (FIG. 94) is uniquely set as return address information after the execution of the separate monitoring process. . Thereby, even if the stack area 224 for non-specific control is forcibly cleared, it is possible to return to the program that should be returned in the management execution process. When the stack area 224 for non-specific control is forcibly cleared, the stack order of the stack pointer of the main CPU 63 is also set to the address of the first storage area in the stack area 224 for non-specific control.

  According to the above configuration, whether or not an information abnormality has occurred in the work area 221 for specific control and the stack area 222 for specific control is executed in the process corresponding to the specific control in the main CPU 63, Whether or not an information abnormality has occurred in the work area 223 for specific control and the stack area 224 for non-specific control is executed in a process corresponding to the non-specific control in the main CPU 63. Thereby, not only clearly distinguishing the areas 221 to 224 of the main RAM 65 to be used by the process corresponding to the specific control and the process corresponding to the non-specific control, the area of the main RAM 65 to be monitored. 221 to 224 can also be clearly distinguished.

  When the work area 223 for non-specific control is cleared to “0”, it is information on various registers of the main CPU 63 that is used in the processing corresponding to the specific control and is stored in the work area 223 for non-specific control. The saved information is also cleared to “0”. In this case, even if the process corresponding to the non-specific control ends and returns to the process corresponding to the specific control, it may not be possible to return to the state before the process corresponding to the non-specific control is started. Therefore, when the work area 2223 for non-specific control is cleared to “0”, the work area 221 for specific control and the stack area 222 for specific control may be cleared to “0”. In this configuration, since the set value counter in the work area 221 for specific control is also cleared to “0”, when the process corresponding to the non-specific control is returned to the process corresponding to the specific control, the specific control is performed. As a corresponding process, the setting value update process may be executed first.

<Twenty-sixth embodiment>
In the present embodiment, the processing configuration of the management process is different from that of the twentieth embodiment. Hereinafter, a configuration different from the twentieth embodiment will be described. The description of the same configuration as that of the twentieth embodiment is basically omitted.

  FIG. 96 is a flowchart showing the management process in the present embodiment executed by the main CPU 63. Note that the processing from step S6201 to step S6219 in the management processing is executed by the main CPU 63 using the specific control program and the specific control data.

  First, in order to prohibit the generation of the timer interrupt process (FIG. 69), the interrupt prohibition is set (step S6201). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and started in the middle of the management execution process described later, which is a process corresponding to the non-specific control. Is possible.

  Thereafter, the stack pointer information of the main CPU 63 is overwritten in the HL register of the main CPU 63 by the load instruction as “LD HL, SP” (step S6202). In this case, since the information amount of the stack pointer is 16 bits and the information amounts of the H register and the L register are 8 bits, the continuous 8-bit information from the upper side of the stack pointer is the H register. The 8-bit information from the lower side of the stack pointer is overwritten in the L register.

  After that, “LD (HL), 0” is set to “0” as the one byte storage area corresponding to the stack pointer information stored in the HL register of the main CPU 63 in the stack area 222 for specific control. Clear (step S6203). Note that the HL register of the main CPU 63 is overwritten with the stack pointer information of the main CPU 63 in step S6202, and the stack pointer of the main CPU 63 is updated until the processing of step S6203 is executed. In step S6203, the 1-byte storage area corresponding to the stack pointer information of the main CPU 63 in the specific control stack area 222 is cleared to “0”.

  After that, as the “LD SP, SP-1”, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written next in the specific control stack area 222 by the load instruction. (Step S6204). When using the stack area 222 for specific control, the information to be stored is stored from the storage area of the last address in the stack area 222 for specific control, and for each time the information to be stored is added The storage area of the storage destination is changed toward the first address side in the stack area 222. Accordingly, in step S6204, the stack pointer information of the main CPU 63 is updated to the address information corresponding to the smaller storage area in the stack area 222 for specific control. By executing the processing in step S6204, the next storage area is set as the information storage target by the next push command with respect to the storage area cleared to “0” in step S6203, and in step S6203. The storage area that has been cleared to “0” is set as a target for reading information by the next pop instruction.

  Thereafter, as “LD WA, 0”, the WA register of the main CPU 63 is cleared to “0” by the load instruction (step S6205). Also, as “LD BC, 0”, the BC register of the main CPU 63 is cleared to “0” by the load instruction (step S6206). Also, as “LD DE, 0”, the DE register of the main CPU 63 is cleared to “0” by the load instruction (step S6207). Further, as “LD HL, 0”, the HL register of the main CPU 63 is cleared to “0” by the load instruction (step S6208). Further, as “LD IX, 0”, the load command clears the IX register of the main CPU 63 to “0” (step S6209). Further, as “LD IY, 0”, the IY register of the main CPU 63 is cleared to “0” by the load instruction (step S6210).

  In addition to the flag register, the general-purpose CPU 63 includes various general-purpose registers, auxiliary registers, and index registers. In this case, in steps S6205 to S6210, the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register, which are some of the various general-purpose registers, auxiliary registers, and index registers, are changed. Clear “0”. These WA register, BC register, DE register, HL register, IX register and IY register are registers used in the management execution process (step S6212) which is a process corresponding to non-specific control. Prior to execution of processing corresponding to non-specific control, the state of these registers is cleared by clearing “0” prior to execution of management execution processing (step S6212) which is processing corresponding to non-specific control. In addition, it is possible to set the state immediately after the supply of operating power to the main CPU 63 is started.

  Each information of the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register before the process corresponding to the non-specific control is started is after the process corresponding to the non-specific control is completed. This is unnecessary information in the processing corresponding to the specific control. Therefore, even if the information in these registers is cleared to “0” without being saved, no problem occurs in the process corresponding to the specific control that is restored after the process corresponding to the non-specific control is completed.

  Thereafter, as a “POP PSW”, information is read from the storage area of the previous writing order with respect to the storage area corresponding to the stack pointer information of the main CPU 63 in the stack area 222 for specific control by a pop instruction, The read information is overwritten in the flag register of the main CPU 63 (step S6211). The information of the stack pointer of the main CPU 63 immediately before the execution of the pop instruction in step S6211 is the storage area of the next writing order with respect to the storage area in the specific control stack area 222 cleared to “0” in step S6203. It becomes information corresponding to. Therefore, the storage area of the previous writing order with respect to the storage area corresponding to the stack pointer information of the main CPU 63 in the specific control stack area 222 is the storage area cleared to “0” in step S6203. . Then, the information read from the storage area is overwritten on the flag register of the main CPU 63, whereby the flag register is cleared to "0". Note that one storage area in the stack area 222 for specific control has an information amount of 8 bits (1 byte) and the flag register of the main CPU 63 also has an information amount of 8 bits (1 byte). . Before the process corresponding to the non-specific control is started, the flag register is cleared to “0” prior to the execution of the management execution process (step S6212) which is a process corresponding to the non-specific control. A state immediately after the supply of operating power to the main CPU 63 is started can be achieved.

  Thereafter, the management execution process is started by reading out a subroutine program corresponding to the management execution process set in the non-specific control program (step S6212). In this case, information for specifying the return address of the management process after execution of the management execution process is written into the stack area 222 for specific control by a push command. When the management execution process ends, information for specifying the return address is read by the pop instruction, and the process returns to the management process program indicated by the return address.

  The processing contents of the management execution process are the same as the management execution process (FIG. 82) in the twentieth embodiment. Therefore, after the check process is completed in the management execution process, the WA register, BC register, DE register, HL register, IX register, and IY register are cleared to “0”. As a result, these registers are cleared to “0” prior to returning from the process corresponding to the non-specific control to the process corresponding to the specific control, and the state of these registers is changed to the process corresponding to the specific control. A state immediately after the supply of operating power to the main CPU 63 is started can be achieved.

  When returning to the management process program after executing the management execution process, a process for clearing the flag register of the main CPU 63 to “0” is executed. Specifically, first, as “PUSH HL”, the information of the HL register of the main CPU 63 is saved in the stack area 222 for specific control by a push command (step S6213). After execution of the push instruction, the information on the stack pointer of the main CPU 63 is information corresponding to the storage area of the next writing order with respect to the storage area in which the information of the HL register is saved in the stack area 222 for specific control. Become.

  After that, as “LD HL, SP”, the stack pointer information of the main CPU 63 is overwritten in the HL register of the main CPU 63 by the load instruction (step S6214). In this case, since the information amount of the stack pointer is 16 bits and the information amounts of the H register and the L register are 8 bits, the continuous 8-bit information from the upper side of the stack pointer is the H register. The 8-bit information from the lower side of the stack pointer is overwritten in the L register.

  After that, “LD (HL), 0” is set to “0” as the one byte storage area corresponding to the stack pointer information stored in the HL register of the main CPU 63 in the stack area 222 for specific control. Clear (step S6215). Note that the information on the stack pointer of the main CPU 63 is overwritten in step S6214 in the HL register of the main CPU 63, and the information on the stack pointer of the main CPU 63 is not updated until the processing of step S6215 is executed. In step S6215, the 1-byte storage area corresponding to the stack pointer information of the main CPU 63 in the stack area 222 for specific control is cleared to “0”.

  After that, as the “LD SP, SP-1”, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written next in the specific control stack area 222 by the load instruction. (Step S6216). When using the stack area 222 for specific control, the information to be stored is stored from the storage area of the last address in the stack area 222 for specific control, and for each time the information to be stored is added The storage area of the storage destination is changed toward the first address side in the stack area 222. Therefore, in step S 6216, the stack pointer information of the main CPU 63 is updated to the address information corresponding to the storage area on the side having a smaller address in the stack area 222 for specific control. By executing the processing of step S6216, the storage area of the next order is set as a storage target of information by the next push command with respect to the storage area cleared to “0” in step S6215, and in step S6215. The storage area that has been cleared to “0” is set as a target for reading information by the next pop instruction.

  Thereafter, as a “POP PSW”, information is read from the storage area of the previous writing order with respect to the storage area corresponding to the stack pointer information of the main CPU 63 in the stack area 222 for specific control by a pop instruction, The read information is overwritten in the flag register of the main CPU 63 (step S6217). The information of the stack pointer of the main CPU 63 immediately before the execution of the pop instruction in step S6217 is the storage area of the next writing order with respect to the storage area in the specific control stack area 222 cleared to “0” in step S6215. It becomes information corresponding to. Therefore, the storage area in the write order immediately before the storage area corresponding to the stack pointer information of the main CPU 63 in the specific control stack area 222 is cleared to “0” in step S6215. It becomes a storage area in the stack area 222. Then, the information read from the storage area is overwritten on the flag register of the main CPU 63, whereby the flag register is cleared to "0". Note that one storage area in the stack area 222 for specific control has an information amount of 8 bits (1 byte) and the flag register of the main CPU 63 also has an information amount of 8 bits (1 byte). . After the process corresponding to the non-specific control is completed by clearing “0” after the execution of the management execution process (step S6212) that is a process corresponding to the non-specific control, the main CPU 63 It is possible to set the state immediately after the supply of the operating power to is started. Further, when the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is the previous one.

  After that, as “POP HL”, the HL register information saved in the specific control stack area 222 in step S6213 is returned to the HL register of the main CPU 63 by a pop instruction (step S6218). Since the HL register is cleared to “0” immediately before the management execution process (step S6212) ends, the information cleared to “0” is saved in the stack area 222 for specific control in step S6213. At the same time, in step S6218, the information cleared to “0” is restored to the HL register of the main CPU 63. As a result, the HL register of the main CPU 63 is cleared to “0”. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the write order in the stack area 222 for specific control is two previous.

  Thereafter, in order to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which it is permitted, an interrupt permission is set (step S6219). Thereby, a new execution of the timer interrupt process can be performed.

  According to the said structure, in addition to the effect demonstrated in the said 20th Embodiment, there can exist the following effects.

  When the process corresponding to the non-specific control is started from the situation where the process corresponding to the specific control is being executed, the flag register of the main CPU 63 is cleared to “0”. Accordingly, it is not necessary to save the flag register information used in the process corresponding to the specific control in the main RAM 65 in a situation where the process corresponding to the non-specific control is being executed. Therefore, it is not necessary to secure a capacity for saving the information.

  In addition, the flag register of the main CPU 63 is cleared to “0” even when the process corresponding to the non-specific control is returned to the process corresponding to the specific control. Thereby, when returning to the process corresponding to specific control, it becomes possible to return the state of a flag register to the state immediately before the process corresponding to non-specific control is started.

  The state where the flag register is cleared to “0” is a state when supply of operating power to the MPU 62 is started. This makes it possible to simplify the processing configuration for setting the flag register to a predetermined state when processing corresponding to non-specific control is started and when processing returns to processing corresponding to specific control.

  The information in the flag register of the main CPU 63 before the process corresponding to the non-specific control is started is information that is not used in the process corresponding to the specific control after the process corresponding to the non-specific control is completed. As a result, even if the flag register is cleared to “0” when the process corresponding to the non-specific control is started, the process corresponding to the specific control after the process corresponding to the non-specific control is completed. It becomes possible not to affect.

  “0” is cleared in a predetermined storage area of the stack area 222 for specific control, and the flag register is cleared to “0” by overwriting the flag register with the pop instruction by the pop instruction. It is a configuration. As a result, even if “0” clearing to the flag register is restricted directly by the load instruction, the flag register can be cleared to “0”.

  Note that the flag register may be initialized instead of the flag register being cleared to “0”. That is, when the supply of operating power to the MPU 62 is started, information setting is performed so that the flag register of the main CPU 63 is once cleared to “0” and then the initial state is set, but the steps S6202 to S6204 and In step S6211, the flag register may be set so as to be in this initial state. In this case, the flag register is set so as to be in the initial state in steps S6213 to S6218, and the state of the flag register is set to non-specific control when returning to the processing corresponding to the specific control. It is possible to return to the state immediately before the processing corresponding to is started.

  In steps S6202 to S6204 and step S6211, the flag register of the main CPU 63 may be set to “1” in place of the configuration of clearing the flag register of “0”. In this case, also in step S6213 to step S6218, by setting “1” to all the flag registers, when returning to the process corresponding to the specific control, the process corresponding to the non-specific control is started. It is possible to return to the state immediately before the operation.

  Further, instead of the processing of step S6202 to step S6204 and step S6211, it is possible to set “LD PSW, 0” to directly clear “0” in the flag register of the main CPU 63 by a load instruction. Further, instead of the processing of step S6213 to step S6218, “LD PSW, 0” may be configured to directly clear “0” in the flag register of the main CPU 63 by a load instruction.

  Further, instead of the configuration in which the processing of step S6213 and step S6218 is executed, the configuration may be such that “0” is cleared in the HL register by “LD HL, 0” by a load instruction. Even in this case, it is possible to return the state of the HL register to the state immediately before the execution of the management execution process that is a process corresponding to the non-specific control.

  Further, instead of the configuration in which the process of clearing the flag register “0” is executed in the process corresponding to the specific control, a configuration in which the process is executed in a process corresponding to the non-specific control may be adopted.

<Twenty-seventh embodiment>
In the present embodiment, the processing configuration of the management process is different from that of the twentieth embodiment. Hereinafter, a configuration different from the twentieth embodiment will be described. The description of the same configuration as that of the twentieth embodiment is basically omitted.

  FIG. 97 is a flowchart showing management processing in the present embodiment, which is executed by the main CPU 63. Note that the processing from step S6301 to step S6323 in the management processing is executed by the main CPU 63 using a program for specific control and data for specific control.

  First, in order to prohibit the generation of the timer interrupt process (FIG. 69), interrupt prohibition is set (step S6301). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and started in the middle of the management execution process described later, which is a process corresponding to the non-specific control. Is possible.

  Thereafter, as “PUSH AF”, the information of the A register and the flag register of the main CPU 63 are stored in correspondence with the current stack pointer information of the main CPU 63 in the stack area 222 for specific control by a push command. The area and the storage area are evacuated to each storage area in the next writing order (step S6302). Since the A register and the flag register of the main CPU 63 each have an 8-bit (1 byte) information amount, the information of the A register and the information of the flag register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area after the write order in the stack area 222 for specific control.

  Thereafter, the information of the A register and the information of the flag register saved in the stack area 222 for specific control in step S6302 are overwritten in the HL register of the main CPU 63 by a pop instruction as “POP HL” (step S6303). . In this case, the information of the A register saved in the specific control stack area 222 is overwritten on the H register of the main CPU 63, and the flag register information saved in the specific control stack area 222 is changed to the L of the main CPU 63. The register is overwritten. The H and L registers of the main CPU 63 each have an information amount of 8 bits (1 byte). When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  Thereafter, as “LD A, 0”, the A register of the main CPU 63 is cleared to “0” by a load instruction (step S6304). Then, the information of the A register of the main CPU 63 is overwritten on the L register of the main CPU 63 by the load instruction as “LD L, A” (step S6305), and the load instruction as “LD H, A” The information in the A register of the main CPU 63 is overwritten on the H register of the main CPU 63 (step S6306). Since the A register is cleared to “0” in step S6304, the L register and the H register are overwritten with the information of the A register, and the L register and the H register are cleared to “0”. It becomes.

  Thereafter, as “PUSH HL”, the information of the HL register (that is, the H register and the L register) of the main CPU 63 corresponds to the current stack pointer information of the main CPU 63 in the stack area 222 for specific control by a push instruction. The storage area and the storage area of the next writing order with respect to the storage area are saved (step S6307). Since the H and L registers of the main CPU 63 each have an information amount of 8 bits (1 byte), the information of the H register and the information of the L register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area after the write order in the stack area 222 for specific control.

  Thereafter, as “LD BC, 0”, the BC register of the main CPU 63 is cleared to “0” by the load instruction (step S6308). Further, as “LD DE, 0”, the DE register of the main CPU 63 is cleared to “0” by the load instruction (step S6309). Further, as “LD IX, 0”, the load command clears the IX register of the main CPU 63 to “0” (step S6310). Also, as “LD IY, 0”, the IY register of the main CPU 63 is cleared to “0” by the load instruction (step S6311).

  In addition to the flag register, the general-purpose CPU 63 includes various general-purpose registers, auxiliary registers, and index registers. In this case, in steps S6308 to S6311, the BC register, the DE register, the IX register, and the IY register, which are some of the various general-purpose registers, auxiliary registers, and index registers, are cleared to “0”. In step S6305 and step S6306, the HL register is cleared to “0”. These BC register, DE register, HL register, IX register, and IY register are registers used in the management execution process (step S6313) that is a process corresponding to non-specific control. Prior to execution of processing corresponding to non-specific control, the state of these registers is cleared by clearing “0” prior to execution of management execution processing (step S6313) which is processing corresponding to non-specific control. In addition, it is possible to set the state immediately after the supply of operating power to the main CPU 63 is started.

  In addition, each information of the BC register, DE register, HL register, IX register, and IY register before the processing corresponding to the non-specific control is started is performed in the specific control after the processing corresponding to the non-specific control is completed. It is unnecessary information in the corresponding processing. Therefore, even if the information in these registers is cleared to “0” without being saved, no problem occurs in the process corresponding to the specific control that is restored after the process corresponding to the non-specific control is completed.

  Thereafter, as a “POP AF”, the information of the H register and the information of the L register saved in the specific control stack area 222 in step S6307 is overwritten in the A register and the flag register of the main CPU 63 by a pop instruction ( Step S6312). In this case, the information of the H register saved in the specific control stack area 222 is overwritten on the A register of the main CPU 63, and the information of the L register saved in the specific control stack area 222 is the flag of the main CPU 63. The register is overwritten. Since both the H register information and the L register information saved in the stack area 222 for specific control are all “0” information, the A register of the main CPU 63 is changed by executing the processing of step S6312. “0” is cleared and the flag register of the main CPU 63 is cleared to “0”. As a result, the state of the flag register can be set to the state immediately after the supply of operating power to the main CPU 63 is started before the processing corresponding to the non-specific control is started. When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  Thereafter, the management execution process is started by reading a subroutine program corresponding to the management execution process set in the non-specific control program (step S6313). In this case, information for specifying the return address of the management process after execution of the management execution process is written into the stack area 222 for specific control by a push command. When the management execution process ends, information for specifying the return address is read by the pop instruction, and the process returns to the management process program indicated by the return address.

  Note that after the check process is completed in the management execution process, the BC register, DE register, HL register, IX register, and IY register are cleared to “0”. As a result, these registers are cleared to “0” prior to returning from the process corresponding to the non-specific control to the process corresponding to the specific control, and the state of these registers is changed to the process corresponding to the specific control. A state immediately after the supply of operating power to the main CPU 63 is started can be achieved.

  When returning to the management process program after executing the management execution process, a process for clearing the flag register of the main CPU 63 to “0” is executed. Specifically, first, as “PUSH HL”, the information in the HL register of the main CPU 63 is saved in the stack area 222 for specific control by a push command (step S6314). After execution of the push instruction, the information on the stack pointer of the main CPU 63 is information corresponding to the storage area of the next writing order with respect to the storage area in which the information of the HL register is saved in the stack area 222 for specific control. Become.

  Thereafter, as “PUSH AF”, the information of the A register and the flag register of the main CPU 63 are stored in correspondence with the current stack pointer information of the main CPU 63 in the stack area 222 for specific control by a push command. The area and the storage area are evacuated to each storage area in the next writing order (step S6315). Since the A register and the flag register of the main CPU 63 each have an 8-bit (1 byte) information amount, the information of the A register and the information of the flag register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area after the write order in the stack area 222 for specific control.

  After that, as a “POP HL”, the A register information and the flag register information saved in the specific control stack area 222 in step S6315 are overwritten in the HL register of the main CPU 63 by a pop instruction (step S6316). . In this case, the information of the A register saved in the specific control stack area 222 is overwritten on the H register of the main CPU 63, and the flag register information saved in the specific control stack area 222 is changed to the L of the main CPU 63. The register is overwritten. The H and L registers of the main CPU 63 each have an information amount of 8 bits (1 byte). When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  Thereafter, as “LD A, 0”, the A register of the main CPU 63 is cleared to “0” by a load instruction (step S6317). Then, the information of the A register of the main CPU 63 is overwritten in the L register of the main CPU 63 by the load instruction as “LD L, A” (step S6318), and the load instruction as “LD H, A” The information in the A register of the main CPU 63 is overwritten on the H register of the main CPU 63 (step S6319). Since the A register is cleared to “0” in step S6317, each of the L register and the H register is cleared to “0” by overwriting the information in the A register to each of the L register and the H register. It becomes.

  Thereafter, as “PUSH HL”, the information of the HL register (that is, the H register and the L register) of the main CPU 63 corresponds to the current stack pointer information of the main CPU 63 in the stack area 222 for specific control by a push instruction. The storage area and the storage area in the next writing order with respect to the storage area are saved (step S6320). Since the H and L registers of the main CPU 63 each have an information amount of 8 bits (1 byte), the information of the H register and the information of the L register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area after the write order in the stack area 222 for specific control.

  After that, as “POP AF”, the information of the H register and the information of the L register saved in the specific control stack area 222 in step S6320 are overwritten in the A register and the flag register of the main CPU 63 by a pop instruction ( Step S6321). In this case, the information of the H register saved in the specific control stack area 222 is overwritten on the A register of the main CPU 63, and the information of the L register saved in the specific control stack area 222 is the flag of the main CPU 63. The register is overwritten. Since both the H register information and the L register information saved in the stack area 222 for specific control are all “0” information, the processing of step S6321 is executed, so that the A register of the main CPU 63 is changed. “0” is cleared and the flag register of the main CPU 63 is cleared to “0”. By clearing the flag register to “0” after the execution of the management execution process (step S6313), which is a process corresponding to non-specific control, the main CPU 63 after the process corresponding to the non-specific control is completed. It is possible to set the state immediately after the supply of the operating power to is started. When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  After that, as “POP HL”, the information of the HL register saved in the stack area 222 for specific control in step S6314 is returned to the HL register of the main CPU 63 by a pop instruction (step S6322). Since the HL register is cleared to “0” immediately before the management execution process (step S6313) ends, the information cleared to “0” is saved in the stack area 222 for specific control in step S6314. At the same time, in step S6322, the information cleared to “0” is restored to the HL register of the main CPU 63, and as a result, the HL register of the main CPU 63 is cleared to “0”. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the write order in the stack area 222 for specific control is two previous.

  Thereafter, in order to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which it is permitted, an interrupt permission is set (step S6323). Thereby, a new execution of the timer interrupt process can be performed.

  According to the above configuration, the flag register of the main CPU 63 can be cleared to “0” without executing the process of clearing “0” to a predetermined storage area in the stack area 222 for specific control by a load instruction. It becomes. As a result, even if the configuration is such that clearing “0” with respect to a predetermined storage area in the stack area 222 for specific control is restricted by the load instruction, the flag register of the main CPU 63 is cleared to “0”. Is possible.

  Note that the flag register may be initialized instead of the flag register being cleared to “0”. That is, when the supply of operating power to the MPU 62 is started, information setting is performed so that the flag register of the main CPU 63 is once cleared to “0” and then the initial state is set, but the steps S6302 to S6307 and In step S6312, the flag register may be set so as to be in this initial state. In this case, by setting the flag register so that the initial state is set also in steps S6314 to S6322, the state of the flag register is set to non-specific control when returning to the processing corresponding to the specific control. It is possible to return to the state immediately before the processing corresponding to is started.

  Further, in steps S6302 to S6307 and S6312, instead of a configuration in which the flag register of the main CPU 63 is cleared to “0”, “1” may be set in all the flag registers. In this case, also in step S6314 to step S6322, by setting “1” to all the flag registers, when returning to the process corresponding to the specific control, the process corresponding to the non-specific control is started. It is possible to return to the state immediately before the operation.

  Moreover, it is good also as a structure where the process of step S6302 and step S6303 is not performed. In this case, the processing configuration can be simplified.

  Moreover, it is good also as a structure by which the process of step S6315 and step S6316 is not performed. In this case, the processing configuration can be simplified.

  Further, instead of the configuration for executing the processing of steps S6302 to S6306, “LD HL, 0” is set to “LD HL, 0”, the HL register is cleared to “0” by the load instruction, and then the “0” cleared HL register is pushed to the push instruction. The flag register of the main CPU 63 may be cleared to “0” by restoring the saved information to the AF register by a pop instruction after saving to the stack area 222 for specific control.

  Further, instead of the configuration in which the process of clearing the flag register “0” is executed in the process corresponding to the specific control, a configuration in which the process is executed in a process corresponding to the non-specific control may be adopted.

<Twenty-eighth embodiment>
In the present embodiment, the processing configuration of the management process is different from that of the fifteenth embodiment. Hereinafter, a configuration different from the fifteenth embodiment will be described. The description of the same configuration as that of the fifteenth embodiment is basically omitted.

  FIG. 98 is a flowchart showing management processing in the present embodiment, which is executed by the main CPU 63. Note that the processing from step S6401 to step S6416 in the management processing is executed by the main CPU 63 using a specific control program and specific control data.

  First, in order to prohibit the generation of the timer interrupt process (FIG. 69), an interrupt prohibition is set (step S6401). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and started in the middle of the management execution process described later, which is a process corresponding to the non-specific control. Is possible.

  After that, as “PUSH WA”, the information of the WA register (that is, the W register and the A register) of the main CPU 63 corresponds to the current stack pointer information of the main CPU 63 in the stack area 222 for specific control by a push command. The storage area and the storage area in the next writing order are saved in the storage area (step S6402). Since the W register and A register of the main CPU 63 each have 8 bits (1 byte) of information, the information in the W register and A register is individually saved in two storage areas with consecutive addresses. The When the push instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area after the write order in the stack area 222 for specific control.

  Thereafter, the information of the flag register of the main CPU 63 is overwritten in the A register of the main CPU 63 by the load instruction as “LD A, PSW” (step S6403). In this case, both the flag register and the A register have an information amount of 8 bits (1 byte). Then, as “LD (_FGBUF), A”, the information of the A register of the main CPU 63 is saved in the FG buffer set in the work area 221 for specific control by a load instruction (step S6404). Since the register A is overwritten with the information in the flag register in step S6403, the information in the flag register is saved in the work area 221 for specific control by executing step S6404.

  After that, as a “POP WA”, the WA register information saved in the specific control stack area 222 in step S6402 is returned to the WA register of the main CPU 63 by a pop instruction (step S6405). As a result, even if the A register is used to save the flag register information to the work area 221 for specific control, the state of the A register can be returned to the state before the saving is performed. Become. When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  Thereafter, the management execution process is started by reading a subroutine program corresponding to the management execution process set in the non-specific control program (step S6406). In this case, information for specifying the return address of the management process after execution of the management execution process is written into the stack area 222 for specific control by a push command. When the management execution process ends, information for specifying the return address is read by the pop instruction, and the process returns to the management process program indicated by the return address.

  The processing content of the management execution process is the same as the management execution process (FIG. 71) in the fifteenth embodiment. Therefore, before the check process is started in the management execution process, each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 is saved in the work area 223 for non-specific control. In addition, after the check process is completed in the management execution process, each information saved in the work area 223 for non-specific control is the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63. Returned to This makes it possible to make the states of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 the same before and after the check process.

  However, the present invention is not limited to this, and the processing content of the management execution process may be the same as the management execution process (FIG. 78) in the seventeenth embodiment, and the management execution process in the eighteenth embodiment. The configuration may be the same as (FIG. 79), or the same configuration as the management execution process (FIG. 80) in the nineteenth embodiment.

  When returning to the management process program after the execution of the management execution process, a process for returning the information in the flag register of the main CPU 63 to the state before the execution of the management execution process is executed. Specifically, first, as “PUSH HL”, the information of the HL register of the main CPU 63 is saved in the stack area 222 for specific control by a push command (step S6407). After execution of the push instruction, the information on the stack pointer of the main CPU 63 is information corresponding to the storage area of the next writing order with respect to the storage area in which the information of the HL register is saved in the stack area 222 for specific control. Become.

  Thereafter, as a “PUSH WA”, the information of the WA register of the main CPU 63 is saved in the stack area 222 for specific control by a push command (step S6408). After execution of the push instruction, the stack pointer information of the main CPU 63 includes information corresponding to the storage area of the next writing order with respect to the storage area in which the WA register information is saved in the stack area 222 for specific control. Become.

  Thereafter, the stack pointer information of the main CPU 63 is overwritten in the HL register of the main CPU 63 by the load instruction as “LD HL, SP” (step S6409). In this case, since the information amount of the stack pointer is 16 bits and the information amounts of the H register and the L register are 8 bits, the continuous 8-bit information from the upper side of the stack pointer is the H register. The 8-bit information from the lower side of the stack pointer is overwritten in the L register.

  After that, as “LD A, (_FGBUF)”, the information of the flag register saved in the FG buffer in the work area 221 for specific control is overwritten in the A register of the main CPU 63 by the load instruction (step S6406) S6410). Then, as “LD (HL), A”, the main instruction stores in the 1-byte storage area corresponding to the stack pointer information stored in the HL register of the main CPU 63 in the stack area 222 for specific control. Information on the A register of the CPU 63 is stored (step S6411). As a result, the flag register information saved in the FG buffer in the work area 221 for specific control in step S6404 is saved in the stack area 222 for specific control.

  After that, as the “LD SP, SP-1”, the stack pointer information of the main CPU 63 is updated to the address information of the storage area to be written next in the specific control stack area 222 by the load instruction. (Step S6412). When using the stack area 222 for specific control, the information to be stored is stored from the storage area of the last address in the stack area 222 for specific control, and for each time the information to be stored is added The storage area of the storage destination is changed toward the first address side in the stack area 222. Accordingly, in step S6412, the stack pointer information of the main CPU 63 is updated to the address information corresponding to the smaller storage area in the stack area 222 for specific control. By executing the process of step S6412, the next storage area is set as the information storage target by the next push instruction with respect to the storage area in which the information of the A register is saved in step S6411. In S6411, the storage area in which the information in the A register is saved is set as the information read target by the next pop instruction.

  Thereafter, as a “POP PSW”, information is read from the storage area of the previous writing order with respect to the storage area corresponding to the stack pointer information of the main CPU 63 in the stack area 222 for specific control by a pop instruction, The read information is overwritten in the flag register of the main CPU 63 (step S6413). The stack pointer information of the main CPU 63 immediately before the execution of the pop instruction in step S6413 is information corresponding to the storage area of the next writing order with respect to the storage area in which the information of the A register is saved in step S6411. It has become. Therefore, in the storage area corresponding to the stack pointer information of the main CPU 63 in the stack area 222 for specific control, the storage area in the previous write order is the storage in which the information in the A register is saved in step S6411. It becomes an area. The information read from the storage area is overwritten in the flag register of the main CPU 63, so that the information in the flag register saved in the FG buffer in the work area 221 for specific control in step S6404 is the flag of the main CPU 63. It is restored to the register. When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is the previous one.

  Thereafter, as a “POP WA”, the WA register information saved in the specific control stack area 222 in step S6408 is returned to the WA register of the main CPU 63 by a pop instruction (step S6414). When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous. Also, as “POP HL”, the HL register information saved in the specific control stack area 222 in step S6407 is returned to the HL register of the main CPU 63 by a pop instruction (step S6415). When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  Thereafter, in order to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which it is permitted, an interrupt permission is set (step S6416). Thereby, a new execution of the timer interrupt process can be performed.

  According to the above configuration, when the process corresponding to the non-specific control is started from the situation where the process corresponding to the specific control is being executed, the flag register information of the main CPU 63 is not the specific control stack area 222. It is possible to retreat to the work area 221 for specific control. When the process corresponding to the non-specific control is returned to the process corresponding to the specific control, the information in the flag register saved in the work area 221 for the specific control is the flag of the main CPU 63. Return to register. As a result, information can be restored from the storage area of the work area 221 for specific control specified in the program to the flag register of the main CPU 63 without referring to the information of the stack pointer of the main CPU 63. Even when the information of the stack pointer of the side CPU 63 is rewritten due to noise or the like, the information can be returned to the flag register of the main side CPU 63.

  Further, instead of the configuration in which the process of saving the flag register information in the main RAM 65 is executed in the process corresponding to the specific control, the process may be executed in a process corresponding to the non-specific control. Further, instead of the configuration in which the process of returning the flag register information saved in the main RAM 65 to the flag register of the main CPU 63 is executed in the process corresponding to the specific control, the process corresponding to the non-specific control is performed. It may be configured to be executed.

<Twenty-ninth embodiment>
In the present embodiment, the processing configuration of the management process is different from that of the fifteenth embodiment. Hereinafter, a configuration different from the fifteenth embodiment will be described. The description of the same configuration as that of the fifteenth embodiment is basically omitted.

  FIG. 99 is a flowchart showing the management process in the present embodiment executed by the main CPU 63. Note that the processing from step S6501 to step S6519 in the management processing is executed by the main CPU 63 using a program for specific control and data for specific control.

  First, in order to prohibit the generation of the timer interrupt process (FIG. 69), interrupt prohibition is set (step S6501). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and started in the middle of the management execution process described later, which is a process corresponding to the non-specific control. Is possible.

  Thereafter, as “PUSH HL”, the information of the HL register (that is, the H register and the L register) of the main CPU 63 corresponds to the current stack pointer information of the main CPU 63 in the stack area 222 for specific control by a push instruction. The storage area and the storage area of the next writing order are saved in the storage area (step S6502). Since the H and L registers of the main CPU 63 each have an 8-bit (1 byte) information amount, the information in the H and L registers is individually saved in two storage areas with consecutive addresses. The When the push instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area after the write order in the stack area 222 for specific control.

  Thereafter, as “PUSH AF”, the information of the A register and the flag register of the main CPU 63 are stored in correspondence with the current stack pointer information of the main CPU 63 in the stack area 222 for specific control by a push command. The area and the storage area are evacuated to each storage area in the next writing order (step S6503). Since the A register and the flag register of the main CPU 63 each have an 8-bit (1 byte) information amount, the information of the A register and the information of the flag register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area after the write order in the stack area 222 for specific control.

  After that, as a “POP HL”, the A register information and the flag register information saved in the specific control stack area 222 in step S6503 are overwritten in the HL register of the main CPU 63 by a pop instruction (step S6504). . In this case, the information of the A register saved in the specific control stack area 222 is overwritten on the H register of the main CPU 63, and the flag register information saved in the specific control stack area 222 is changed to the L of the main CPU 63. The register is overwritten. When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  Thereafter, as “LD A, L”, the information in the L register of the main CPU 63 is overwritten in the A register of the main CPU 63 by the load instruction (step S6505). Since the information in the flag register of the main CPU 63 is overwritten in step S6504 in the L register, the information in the flag register is overwritten in the A register by overwriting the information in the L register. Become. Then, as “LD (_FGBUF), A”, the information of the A register of the main CPU 63 is saved in the FG buffer set in the work area 221 for specific control by a load instruction (step S6506). Since the register A is overwritten with the information of the flag register in step S6505, the information of the flag register is saved in the work area 221 for specific control by executing step S6506.

  Thereafter, as “PUSH HL”, the information of the HL register (that is, the H register and the L register) of the main CPU 63 corresponds to the current stack pointer information of the main CPU 63 in the stack area 222 for specific control by a push instruction. The storage area and the storage area in the next writing order with respect to the storage area are saved (step S6507). In this case, since the A register information and the flag register information are overwritten in step S6504, the A register information and flag register information are saved in the stack area 222 for specific control in step S6507. I was allowed to. When the push instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area after the write order in the stack area 222 for specific control.

  After that, as “POP AF”, the information of the H register and the information of the L register saved in the specific control stack area 222 in step S6507 are overwritten in the A register and the flag register of the main CPU 63 by a pop instruction ( Step S6508). In this case, the information of the H register saved in the specific control stack area 222 is overwritten on the A register of the main CPU 63, and the information of the L register saved in the specific control stack area 222 is the flag of the main CPU 63. The register is overwritten. The H register information saved in the specific control stack area 222 is the A register information at the time of step S6503, and the L register information saved in the specific control stack area 222 is the flag at the time of step S6503. Register information. Therefore, by executing the processing of step S6508, the states of the A register and flag register of the main CPU 63 are restored to the state at the time of step S6503. When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  After that, as “POP HL”, the information of the HL register saved in the stack area 222 for specific control in step S6502 is returned to the HL register of the main CPU 63 by a pop instruction (step S6509). As a result, the state of the HL register of the main CPU 63 returns to the state at the time of step S6502. When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  Thereafter, the management execution process is started by reading a subroutine program corresponding to the management execution process set in the non-specific control program (step S6510). In this case, information for specifying the return address of the management process after execution of the management execution process is written into the stack area 222 for specific control by a push command. When the management execution process ends, information for specifying the return address is read by the pop instruction, and the process returns to the management process program indicated by the return address.

  In the management execution process, the BC register, DE register, HL register, IX register, and IY register information of the main CPU 63 is saved in the work area 223 for non-specific control before the check process is started. After the check process is completed in the management execution process, each information saved in the non-specific control work area 223 is returned to the BC register, DE register, HL register, IX register, and IY register of the main CPU 63. As a result, the BC register, DE register, HL register, IX register, and IY register of the main CPU 63 can be set to the same state before and after the check process.

  However, the present invention is not limited to this, and the processing content of the management execution process may be the same as the management execution process (FIG. 78) in the seventeenth embodiment, and the management execution process in the eighteenth embodiment. The configuration may be the same as (FIG. 79), or the same configuration as the management execution process (FIG. 80) in the nineteenth embodiment.

  When returning to the management process program after the execution of the management execution process, a process for returning the information in the flag register of the main CPU 63 to the state before the execution of the management execution process is executed. Specifically, first, as “PUSH HL”, the information in the HL register of the main CPU 63 is saved in the stack area 222 for specific control by a push command (step S6511). After execution of the push instruction, the information on the stack pointer of the main CPU 63 is information corresponding to the storage area of the next writing order with respect to the storage area in which the information of the HL register is saved in the stack area 222 for specific control. Become.

  After that, as “PUSH AF”, the information of the A register and the flag register of the main CPU 63 are stored in correspondence with the current stack pointer information of the main CPU 63 in the stack area 222 for specific control by a push command. The area and the storage area are evacuated to each storage area in the next writing order (step S6512). Since the A register and the flag register of the main CPU 63 each have an 8-bit (1 byte) information amount, the information of the A register and the information of the flag register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area after the write order in the stack area 222 for specific control.

  After that, as a “POP HL”, the A register information and the flag register information saved in the stack area 222 for specific control in step S6512 are overwritten in the HL register of the main CPU 63 by a pop instruction (step S6513). . In this case, the information of the A register saved in the specific control stack area 222 is overwritten on the H register of the main CPU 63, and the flag register information saved in the specific control stack area 222 is changed to the L of the main CPU 63. The register is overwritten. When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  After that, as “LD A, (_FGBUF)”, the information of the flag register at the time of step S6503 saved in the FG buffer in the specific control work area 221 in step S6506 by the load instruction is stored in the A register of the main CPU 63. Is overwritten (step S6514). Then, as “LD L, A”, the information of the A register of the main CPU 63 is overwritten on the L register of the main CPU 63 by the load instruction (step S6515). Since the information of the flag register of the main CPU 63 at the time of step S6503 is restored to the A register in step S6514, the information of the A register is overwritten on the L register by the information of the A register at the time of step S6503. The information in the flag register is overwritten.

  Thereafter, as “PUSH HL”, the information of the HL register (that is, the H register and the L register) of the main CPU 63 corresponds to the current stack pointer information of the main CPU 63 in the stack area 222 for specific control by a push instruction. The storage area and the storage area of the next writing order are saved in the storage area (step S6516). In this case, since the information of the A register at the time of step S6512 is overwritten in step S6513 in step S6513, the information of the A register is saved in the stack area 222 for specific control in step S6516. Become. Further, since the information of the flag register at the time of step S6503 is overwritten in step S6515 in step S6515, the information of the flag register is saved in the stack area 222 for specific control in step S6516.

  After that, as “POP AF”, the information of the H register and the information of the L register saved in the specific control stack area 222 in step S6516 are overwritten in the A register and the flag register of the main CPU 63 by a pop instruction ( Step S6517). In this case, the information of the H register saved in the specific control stack area 222 is overwritten on the A register of the main CPU 63, and the information of the L register saved in the specific control stack area 222 is the flag of the main CPU 63. The register is overwritten. Information on the H register saved in the stack area 222 for specific control is information on the A register at the time of step S6512, and information on the L register saved in the stack area 222 for specific control is the flag at the time of step S6503. Register information. Therefore, by executing the process of step S6517, the state of the A register of the main CPU 63 returns to the state of step S6512, and the state of the flag register returns to the state at the time of step S6503.

  Incidentally, the A register of the main CPU 63 is not used in the management execution process. Therefore, the state of the A register at the time of step S6512 is the state of the A register at the time of step S6508, and the state of the A register at the time of step S6508 is the state of the A register at the time of step S6503. Therefore, by executing the process of step S6517, the states of the A register and the flag register of the main CPU 63 are restored to the state at the time of step S6503. When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  After that, as “POP HL”, the HL register information saved in the stack area 222 for specific control in step S6511 is returned to the HL register of the main CPU 63 by a pop instruction (step S6518). As a result, the state of the HL register of the main CPU 63 returns to the state at the time of step S6511. When the pop instruction is executed, the information on the stack pointer of the main CPU 63 is updated to information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two previous.

  Thereafter, in order to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which it is permitted, an interrupt permission is set (step S6519). Thereby, a new execution of the timer interrupt process can be performed.

  According to the above configuration, the flag register information of the main CPU 63 is executed without executing the process of directly overwriting the flag register information on the other registers of the main CPU 63 from the flag register of the main CPU 63 by the load instruction. Can be saved in the work area 221 for specific control.

  Instead of executing the processing of steps S6505 to S6508, instead of executing the processing of step S6504, the flag register information is overwritten by the load instruction as “LD (_FGBUF), L”. The information of the flag register may be saved in the work area 221 for specific control by saving the information in the L register in the FG buffer.

  Instead of executing the processing of step S6514 and step S6515, instead of executing the processing of step S6513, a work area for specific control is obtained as “LD L, (_FGBUF)” by a load instruction. The flag register information saved in 221 may be overwritten in the L register.

  Further, instead of the configuration in which the process of saving the flag register information in the main RAM 65 is executed in the process corresponding to the specific control, the process may be executed in a process corresponding to the non-specific control. Further, instead of the configuration in which the process of returning the flag register information saved in the main RAM 65 to the flag register of the main CPU 63 is executed in the process corresponding to the specific control, the process corresponding to the non-specific control is performed. It may be configured to be executed.

<Thirty Embodiment>
In the present embodiment, the processing configuration executed by the main CPU 63 is different from that of the fifteenth embodiment. Hereinafter, a configuration different from the fifteenth embodiment will be described. The description of the same configuration as that of the fifteenth embodiment is basically omitted.

  FIG. 100 is a flowchart showing a main process in the present embodiment executed by the main CPU 63. Note that the processing in steps S6601 to S6621 in the main processing is executed using a program for specific control and data for specific control in the main CPU 63.

  First, power-on wait processing is executed (step S6601). In the power-on wait process, for example, the process waits without proceeding to the next process until a predetermined time for waiting (specifically, 1 second) elapses after the main process is activated. The operation start and initial setting of the symbol display device 41 are completed during the execution period of the power-on wait process. Thereafter, access to the main RAM 65 is permitted (step S6602).

  Thereafter, it is determined whether or not “1” is set in the power failure flag provided in the work area 221 for specific control in the main RAM 65 (step S6603). If “1” is set in the power failure flag (step S6603: YES), a checksum is calculated for the work area 221 for specific control and the stack area 222 for specific control (step S6604).

  Although the checksum calculation method is arbitrary, for example, there is a calculation method of adding all the numerical values of the storage area that is the checksum calculation target. This checksum calculation method is the same as the checksum calculation method in power failure processing described later. The checksum calculated in the power failure processing described later is stored in the work area 221 for specific control. The storage area of the work area 221 for specific control in which this checksum is stored is calculated as a checksum. At this time, it is excluded from the storage area to be calculated.

  That is, in calculating the checksum, a part of the storage area in the work area 221 for specific control and the stack area 222 for specific control is a calculation target. In the storage area to be calculated, the checksum is calculated in the power failure process when the supply of the operating power to the MPU 62 is stopped, and then the supply of the operating power to the MPU 62 is resumed and the process of step S6604 is executed. Until this is done, when the power supply such as the backup power to the work area 221 for specific control and the stack area 222 for specific control is continued, the information is basically not rewritten. Accordingly, the information on the work area 221 for specific control and the stack area 222 for specific control is not changed after the supply of operating power to the MPU 62 is stopped until the supply of operating power to the MPU 62 is resumed. In this case, the checksum for the work area 221 for specific control and the stack area 222 for specific control is the same as that immediately before the supply of operating power to the MPU 62 is stopped. In addition, in the storage area to be calculated when calculating the checksum, an area (specifically, a set value counter) in which set value information indicating the set state of the pachinko machine 10 is set in the work area 221 for specific control. )It is included.

  Thereafter, the work area 221 for specific control and the stack area for specific control that are calculated and stored in the work area 221 for specific control, which are calculated in the power failure process executed immediately before the supply of the operating power to the MPU 62 is stopped. The checksum for 222 is read from the work area 221 for specific control, and the read checksum is compared with the checksum calculated in step S6604 (step S6605). Then, it is determined whether or not the checksums match (step S6606).

  Here, the power failure information storage process executed by the main CPU 63 will be described with reference to the flowchart of FIG. The power failure information storage process is executed in step S6801 in a timer interrupt process (FIG. 103) described later.

  In the power failure information storage process, first, information “10”, which is information on the number of repetitions for a power failure signal, is set in a repetition counter provided in the work area 221 for specific control (step S6701), and the work area for specific control The power failure detection counter provided at 221 is cleared to “0” (step S6702).

  Then, the process which reads the information of the power failure signal received to the input port of MPU62 is performed (step S6703). In this case, when a power failure signal (LOW level power failure signal) corresponding to the fact that the power shutdown has not occurred is received, information of “0” is stored as non-power failure information in the input port. When a power failure signal (HI level power failure signal) corresponding to the occurrence of power interruption has been received, information “1” is stored as power interruption occurrence information in the input port. In step S6703, the process which reads the information of this power failure signal into the register | resistor of main side CPU63 is performed.

  If the information of the power failure signal read in step S6703 corresponds to the occurrence of a power failure (power failure occurrence) (step S6704: YES), 1 is added to the numerical information of the power failure detection counter (step S6705). If a negative determination is made in step S6704 or if the process of step S6705 is executed, 1 is subtracted from the numerical information of the repeat counter (step S6706). Then, it is determined whether or not the numerical information of the repetition counter after the 1 subtraction is “0” (step S6707). If a negative determination is made in step S6707, the process returns to step S6703 and the processes in steps S6703 to S6706 are repeated. On the other hand, if a positive determination is made in step S6707, the process proceeds to step S6708.

  In step S6708, it is determined whether the current numerical information of the power failure detection counter is equal to or greater than the trigger reference number corresponding to the occurrence of the power failure. If it is less than the trigger reference number, the power failure information storage process is terminated as it is. On the other hand, when the number is the trigger reference number or more, the power failure processing in steps S6709 to S6712 is executed.

  Specifically, first, “1” is set in the power failure flag provided in the work area 221 for specific control (step S6709). As a result, when the power failure process is normally executed and the information storage in the main RAM 65 is normally performed, the operation power supply to the main CPU 63 is started again for the specific control. That is, “1” is set in the power failure flag of the work area 221.

  Thereafter, a checksum is calculated for the work area 221 for specific control and the stack area 222 for specific control (step S6710). In this case, the storage area in the work area 221 for specific control and the stack area 222 for specific control, which are calculation targets when calculating the checksum, is a checksum calculation target in step S6604 of the main process (FIG. 100). It is the same as the storage area in the work area 221 for specific control and the stack area 222 for specific control. In addition, in the storage area that is a calculation target when calculating the checksum, an area (specifically, a setting value counter) in which setting value information indicating the setting state of the pachinko machine 10 in the work area 221 for specific control is set. )It is included. Then, the calculated checksum is stored in a storage area for storing the checksum in the work area 221 for specific control and excluded from the checksum calculation target.

  Thereafter, all the output port information in the register of the main CPU 63 is set to “0” (step S6711), and access to the main RAM 65 is prohibited (step S6712). Then, the infinite loop is continued until the power supply is completely shut down and processing cannot be executed.

  Since the power failure information storage process is executed as the first process of the timer interrupt process, there is no need to execute the timer interrupt process in the middle of the power recovery. As a result, it is not necessary to store the address of the process executed when the power failure occurs in the main RAM 65 as the stack information, and the processing load of the process when the power failure occurs can be reduced.

  Returning to the description of the main process (FIG. 100), when a negative determination is made in step S6603 or step S6606, a clear process for non-setting update is executed (step S6607). In the clear processing at the time of non-setting update, the specific control is performed except for an area (specifically, a set value counter) in which set value information indicating the set state of the pachinko machine 10 is set in the work area 221 for specific control. The work area 221 is cleared to “0” and initial setting is executed. As a result, the area indicating whether or not the lottery mode is the high probability mode is cleared to “0”, so that the lottery regardless of the lottery mode immediately before the supply of the operating power to the pachinko machine 10 is stopped. The mode is a low probability mode. In addition, the game turn is not executed, the opening / closing execution mode is not executed, and the general-purpose display portion 38a is not variably displayed, and the general utility 34a is in a closed state. Situation. In addition, since the hold storage area 65a and the power train hold area 65c provided in the work area 221 for specific control are also cleared to “0”, the hold information for the special figure display section 37a is deleted and the map display section. The hold information for 38a is deleted. Further, in the clear process at the time of non-setting update, the stack area 222 for specific control is cleared to “0” and initial setting is executed. Further, in the clear process at the time of non-setting update, various registers of the main CPU 63 are cleared to “0” and then the initial setting is executed.

  On the other hand, the non-specific control work area 223 and the non-specific control stack area 224 are not cleared to “0” in the clear process at the time of non-setting update. As a result, even if the power failure flag is not set to “1” because the power failure process is not normally executed, the work area 223 for non-specific control and the stack area 224 for non-specific control are “0”. It becomes possible not to be cleared. In addition, even if an abnormality occurs regarding the checksum for the work area 221 for specific control and the stack area 222 for specific control, the work area 223 for non-specific control and the stack area 224 for non-specific control are cleared to “0”. It becomes possible not to be done.

  When a negative determination is made in step S6603 or S6606, after executing the clear process at the time of non-setting update in step S6607, the value of the set value counter in the work area 221 for specific control is confirmed to check the pachinko machine. It is determined whether or not the set value of 10 is normal (step S6608). Specifically, it is determined to be normal when the set value set in the set value counter is any of “setting 1” to “setting 6”, and abnormal when it is “0” or 7 or more. Judge that there is. If the set value is abnormal (step S6608: NO), processing (steps S6619 to S6621) for newly setting a set value to be described later is executed. As a result, it is possible to monitor whether or not the set value is normal even when a negative determination is made in step S6603 or step S6606 and the clear process at the time of non-setting update (step S6607) is executed. In addition, when the set value is abnormal, it is possible to reset the set value.

  If the set value is normal (step S6608: YES), the power-on setting process is executed (step S6609). In the power-on setting process, a predetermined area of the work area 221 for specific control such as initialization of a power failure flag is set to an initial value, and a command corresponding to the current gaming state is transmitted to the sound emission control device 81.

  The main CPU 63 is configured to periodically execute the timer interrupt process, but the timer interrupt process is prohibited from occurring at the stage where the main process is started. The state in which the generation of the timer interrupt process is prohibited is canceled at the timing before the process of step S6609 is completed and the process of step S6610 is executed, and the execution of the timer interrupt process is permitted. As a result, when the supply of operating power to the main CPU 63 is started, the power-on setting process in step S6609 is terminated, and the timer interrupt process is not executed until the stage before the process in step S6610 is started. Therefore, the process for advancing the game in the main CPU 63 is not started until this situation is reached.

  Thereafter, the process proceeds to the remaining process of steps S6610 to S6613. That is, the main CPU 63 is configured to periodically execute the timer interrupt process, but a remaining time occurs between one timer interrupt process and the next timer interrupt process. The remaining time varies depending on the processing completion time of each timer interrupt process, but the remaining processes in steps S6610 to S6613 are repeatedly executed using such irregular time. In this regard, it can be said that the remaining processes in steps S6610 to S6613 are non-periodic processes that are performed irregularly. In steps S6610 to S6613, the same processes as those in steps S113 to S116 of the main process (FIG. 9) in the first embodiment are executed.

  As described above, in this embodiment, when the supply of operating power to the main CPU 63 is started, if the power failure flag of the work area 221 for specific control is not set, or the checksums do not match. In this case, after executing the clear process at the time of non-setting update, if the set value is normal (step S6608: YES), the process proceeds to a process for advancing the game. As a result, even if the power failure flag is not set to “1” because the power failure process has not been executed normally, the supply of operating power to the main CPU 63 is started and the power is turned ON / OFF again. There is no need to turn it off. Further, even if an abnormality occurs regarding the checksum for the specific control work area 221 and the specific control stack area 222, the power supply is turned ON / OFF again after the supply of operating power to the main CPU 63 is started. There is no need to operate.

  When an affirmative determination is made in both step S6603 and step S6606, it is determined whether or not the set value of the pachinko machine 10 is normal by checking the value of the set value counter in the work area 221 for specific control (step S6614). ). Specifically, it is determined to be normal when the set value set in the set value counter is any of “setting 1” to “setting 6”, and abnormal when it is “0” or 7 or more. Judge that there is. If the set value is abnormal (step S6614: NO), processing (step S6619 to step S6621) for newly setting a set value to be described later is executed.

  If the set value is normal (step S6614: YES), it is determined whether or not the reset button 68c is pressed (step S6615), and whether or not the setting key insertion unit 68a is turned ON using the setting key. Whether or not the front door frame 14 is in an open state with respect to the inner frame 13 (step S6617), and the gaming machine main body 12 is in an open state with respect to the outer frame 11. It is determined whether or not there is (step S6618).

  In the present embodiment, a front door opening sensor 95 for detecting whether or not the front door frame 14 is open with respect to the inner frame 13 is electrically connected to the main CPU 63, and the front door opening sensor The detection result 95 is input to the main CPU 63. In this case, when the front door frame 14 is closed with respect to the inner frame 13, the front door opening sensor 95 transmits a closing detection signal to the main CPU 63, and the front door frame 14 is open with respect to the inner frame 13. In this case, the front door opening sensor 95 transmits an opening detection signal to the main CPU 63. When the main CPU 63 receives the closing detection signal from the front door opening sensor 95, the main CPU 63 specifies that the front door frame 14 is in the closed state, and receives the opening detection signal from the front door opening sensor 95. It specifies that the front door frame 14 is an open state.

  In the present embodiment, a main body opening sensor 96 for detecting whether or not the gaming machine main body 12 is open with respect to the outer frame 11 is electrically connected to the main CPU 63, and the main body opening sensor 96 detection results are input to the main CPU 63. In this case, when the gaming machine main body 12 is in the closed state with respect to the outer frame 11, the main body opening sensor 96 transmits a closing detection signal to the main CPU 63, and the gaming machine main body 12 is in the open state with respect to the outer frame 11. In some cases, the main body opening sensor 96 transmits an opening detection signal to the main CPU 63. The main CPU 63 specifies that the gaming machine main body 12 is in a closed state when a closing detection signal is received from the main body opening sensor 96, and a gaming machine when the opening detection signal is received from the main body opening sensor 96. It is specified that the main body 12 is in an open state.

  If the reset button 68c has not been pressed (step S6615: NO), after executing the power-on setting process in step S6609, the remaining processes in steps S6610 to S6613 are repeated. That is, when the reset button 68c is not pressed, the process proceeds to the process for controlling the progress of the game without executing the clear process of the work area 221 for specific control and the stack area 222 for specific control. .

  If the reset button 68c is pressed (step S6615: YES), and if a negative determination is made in any of steps S6616 to S6618, the clear process at the time of non-setting update is executed (step S6607). ), On condition that the set value is normal (step S6608: YES), the process proceeds to a process for controlling the progress of the game in step S6609 and thereafter. The processing content of the clear processing at the time of non-setting update is as already described.

  If the reset button 68c is pressed (step S6615: YES), and if a positive determination is made in all of steps S6616 to S6618, processing for updating the set value is executed. Also, when it is determined in step S6608 or step S6614 that the set value is abnormal, a process for updating the set value is executed.

  Specifically, first, a setting value copy process is executed (step S6619). In the copy process, information on the setting value counter used for specifying the setting value of the pachinko machine 10 in the work area 221 for specific control is stored in a copy area provided in the work area 221 for specific control. . As a result, even if the information of the set value counter is cleared to “0” in the clear process at the time of setting update executed thereafter (step S6620), the main data before the clear process at the time of update of the set value is executed It becomes possible to grasp the set value of the pachinko machine 10 (that is, the set value of the pachinko machine 10 before the supply of operating power to the pachinko machine 10 is stopped).

  Thereafter, a clear process at the time of setting update is executed (step S6620). In the clear process at the time of setting update, the work area 221 for specific control is set to “0” except for the area indicating whether or not the lottery mode in the work area 221 for specific control is the high probability mode and the copy area. Clear and execute the initial setting. As a result, the game times are not executed, the opening / closing execution mode is not executed, and the general-purpose display portion 38a is not variably displayed. It becomes a certain situation. In addition, since the hold storage area 65a and the power train hold area 65c provided in the work area 221 for specific control are also cleared to “0”, the hold information for the special figure display section 37a is deleted and the map display section. The hold information for 38a is deleted. In the clear process at the time of setting update, the stack area 222 for specific control is cleared to “0” and initial setting is executed. In the clear process at the time of setting update, the set value counter used for specifying the set value of the pachinko machine 10 is cleared to “0”. In the clear process at the time of setting update, the various registers of the main CPU 63 are also cleared to “0” and then the initial setting is executed.

  On the other hand, the clearing process at the time of setting update does not clear “0” in the area indicating whether or not the winning lottery mode is the high probability mode. Can be maintained in the mode before the supply of operating power to the pachinko machine 10 is stopped. In addition, since the copy area is not cleared to “0” in the clear process at the time of setting update, the set value set before the clear process at the time of setting update is executed can be specified thereafter. Note that the present invention is not limited to the above-described configuration, and the setting value counter used for specifying the setting value of the pachinko machine 10 may not be cleared to “0” in the clear process at the time of setting update. In the clearing process, an area indicating whether or not the lottery mode is the high probability mode may be cleared to “0”.

  In the clear process at the time of setting update, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to “0”. Thereby, even if the set value update process capable of changing the set value of the pachinko machine 10 is executed, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to “0”. It becomes possible to do so.

  Thereafter, a setting value update process is executed in step S6621. The processing content of the set value update process is the same as the set value update process (FIG. 85) in the twenty-second embodiment. After executing the set value update process, the process proceeds to a process for controlling the progress of the game after step S6609.

  According to the above configuration, when the set value is abnormal, the set value update process is started without requiring a special operation by the manager of the game hall. Then, when the set value update process is completed, the process proceeds to a process for controlling the progress of the game. This makes it possible to play a game in a situation where the normal set value is set. On the other hand, in order to complete the setting value update process, it is necessary to turn off the setting key with respect to the setting key insertion unit 68a. It is possible to prevent the occurrence of an event that occurs.

  Next, a description will be given of a configuration for forcibly stopping the progress of the game when the main CPU 63 cannot perform various processes normally. FIG. 102A is a block diagram for explaining the configuration of the MPU 62.

  As shown in FIG. 102A, the MPU 62 is provided with a main CPU 63, a main ROM 64, and a main RAM 65, as well as a reset signal output unit 251 and a program monitoring unit 252. The reset signal output unit 251 has a function of outputting a reset signal to the main CPU 63. Specifically, the reset signal output unit 251 outputs the reset signal as the HI level signal when the operating power is supplied from the power source / launch control device 78 and the output disable condition is not satisfied. When the operating power is not supplied from the power source / launch control device 78 or when the operating power is not supplied even if the operating power is not satisfied, the reset signal is sent to the main CPU 63. Is not output. The main CPU 63 executes various processes when operating power is supplied from the power / fire control device 78 and receives a reset signal from the reset signal output unit 251, and Even when operating power is supplied, if the reset signal is not received from the reset signal output unit 251, various processes are not executed. Further, when the main CPU 63 is switched from a situation in which no reset signal is received from the reset signal output unit 251 to a situation in which a reset signal is received when operating power is supplied from the power supply / launch control device 78. The main process (FIG. 100) is started.

  The program monitoring unit 252 has a function of monitoring whether or not the main CPU 63 can perform various processes normally. Specifically, the program monitoring unit 252 monitors whether or not the value of the program counter provided in the main CPU 63 is an abnormal value. The program counter is for storing an address where an instruction to be executed in the main CPU 63 is stored. A possible value is determined for the program counter, and the program monitoring unit 252 monitors whether the value of the program counter is a value other than the possible value. Further, the program monitoring unit 252 monitors whether or not the address designated as the writing destination area is an abnormal address when information is written in the work area 221 for specific control by the load instruction. The program monitoring unit 252 may be configured to monitor whether or not the address designated as the area to be read is an abnormal address when information is read from the work area 221 for specific control by a load instruction.

  When the program monitoring unit 252 determines that the value of the program counter is an abnormal value, or when it is determined that the address specified when writing information by a load instruction is an abnormal address, the reset signal output unit 251 A monitoring error signal is output to. When the reset signal output unit 251 receives a monitoring abnormality signal from the program monitoring unit 252, the reset signal output unit 251 temporarily stops the output of the reset signal even when operating power is supplied from the power supply / launch control device 78, and continues to stop. After stopping the output of the reset signal over a period, the output of the reset signal is restarted. The stop continuation period is a period sufficient for the main CPU 63 to specify that the output of the reset signal is stopped. As a result, when the value of the program counter becomes an abnormal value, or when the address specified when writing information by the load instruction becomes an abnormal address, the main CPU 63 passes through the reset signal OFF / ON. The main process is executed at

  FIG. 102B is a time chart showing how the reset signal output unit 251 outputs a reset signal. FIG. 102 (b1) shows a period during which operating power is supplied from the power supply / emission control device 78, FIG. 102 (b2) shows a period during which a reset signal is output from the reset signal output unit 251, and FIG. b3) indicates the timing at which a monitoring abnormality signal is output from the program monitoring unit 252.

  First, the case where a monitoring abnormality signal is not output from the program monitoring unit 252 will be described. At the timing t1, supply of operating power from the power supply / launch control device 78 to the MPU 62 is started as shown in FIG. , T2 starts to output a reset signal from the reset signal output unit 251 as shown in FIG. Thereafter, the supply of operating power from the power supply / launch control device 78 to the MPU 62 is stopped at the timing of t3 as shown in FIG. 102 (b1), so that the reset is performed at the timing of t4 as shown in FIG. The output of the reset signal from the signal output unit 251 is stopped.

  Next, the case where a monitoring abnormality signal is output from the program monitoring unit 252 will be described. At the timing t5, as shown in FIG. As a result, as shown in FIG. 102B, the reset signal output unit 251 starts outputting the reset signal at the timing t6. Thereafter, at the timing of t7, the program counter value becomes an abnormal value, or the address designated when information is written by the load instruction becomes an abnormal address, so that the program monitoring is performed as shown in FIG. A monitoring abnormality signal is output from the unit 252 to the reset signal output unit 251. As a result, as shown in FIG. 102 (b2), the output of the reset signal from the reset signal output unit 251 is temporarily stopped at the timing of t7 and restarted at the timing of t8 thereafter.

  In this case, the main CPU 63 stops the execution of various processes at the timing of t7, and starts the main process (FIG. 100) at the timing of t8, which is the timing when the rising edge of the reset signal is confirmed. However, since the power failure process is not performed when the execution of the various processes of the main CPU 63 is stopped, the main process (FIG. 100) is performed in a situation where the power failure flag in the work area 221 for specific control is not set. Is started, and the main process (FIG. 100) is started without storing the checksum for the work area 221 for specific control and the stack area 222 for specific control. Therefore, in the main process (FIG. 100), a negative determination is made in step S6603 or step S6606, and a clear process (step S6607) at the time of non-setting update is executed. As a result, when the monitoring error signal is output from the program monitoring unit 252 because the value of the program counter becomes an abnormal value or the address specified when writing information by a load instruction becomes an abnormal address, It is possible to execute a clear process at the time of non-setting update in which a predetermined storage area of the work area 221 for specific control and the stack area 222 for specific control is cleared to “0”. .

  However, the non-specific control work area 223 and the non-specific control stack area 224 are not cleared to “0” in the clear process at the time of non-setting update. As a result, even if a monitoring abnormality signal is output from the program monitoring unit 252 due to an abnormal value of the program counter value or an address specified when information is written by a load instruction, It is possible to prevent the work area 223 for specific control and the stack area 224 for non-specific control from being cleared to “0”.

  Returning to the description of FIG. 102 (b), the supply of operating power from the power supply / launch control device 78 to the MPU 62 is stopped as shown in FIG. 102 (b1) at the timing of t9, and then at the timing of t10. As shown in FIG. 102 (b2), the output of the reset signal from the reset signal output unit 251 is stopped.

  Next, timer interrupt processing in the present embodiment executed by the main CPU 63 will be described with reference to the flowchart of FIG. The timer interrupt process is executed periodically (for example, at a cycle of 4 milliseconds) in a state where the processes of steps S6610 to S6613 are being executed in the main process (FIG. 100). Note that the program corresponding to the timer interrupt process is set as a program for specific control.

  In steps S6801 to S6819, the same processing as steps S5201 to S5219 of the timer interrupt processing (FIG. 86) in the twenty-second embodiment is executed. These processes are executed by the main CPU 63 using a program for specific control and data for specific control. Thereafter, a setting monitoring process is executed (step S6820). FIG. 104 is a flowchart showing the setting monitoring process.

  It is determined whether or not the set value of the pachinko machine 10 is normal by checking the value of the set value counter in the work area 221 for specific control (step S6901). Specifically, it is determined to be normal when the set value set in the set value counter is any of “setting 1” to “setting 6”, and abnormal when it is “0” or 7 or more. Judge that there is.

  If the set value is abnormal (step S6901: NO), first, a set value copy process is executed (step S6902). In the copy process, information on the setting value counter used for specifying the setting value of the pachinko machine 10 in the work area 221 for specific control is stored in a copy area provided in the work area 221 for specific control. . Thereby, it becomes possible to grasp the set value of the pachinko machine 10 before the execution of the set value update process executed thereafter.

  Thereafter, an abnormality command indicating that an abnormality of the set value has occurred is transmitted to the sound emission control device 81 (step S6903). Upon receiving the abnormal command, the voice light emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to the set value abnormality, and a sound “The set value abnormality has been detected” is output from the speaker unit 54. Output. In addition, a character image “Setting value abnormality detected” is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are terminated when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the administrator of the game hall. As the notification end operation, for example, the update button 68b may be pressed, or the reset button 68c may be pressed. By confirming the notification, the manager of the game hall can grasp that a set value abnormality has occurred.

  Thereafter, a set value update process is executed (step S6904). In other words, every time the timer interrupt process (FIG. 103) is executed, it is monitored whether or not an abnormality has occurred in the set value. The set value update process is executed to The processing content of the set value update process is the same as the set value update process (FIG. 85) in the twenty-second embodiment. Accordingly, each time the update button 68b is pressed once, the set value is updated one step at a time, and the set value being selected is determined by detecting the game ball with the out port detection sensor 48a. The setting value in the middle of updating and the determined setting value are displayed on the third notification display device 69c. Thereafter, when the setting key insertion unit 68a is switched from the ON state to the OFF state, it is determined that the end condition of the setting value update process is satisfied. After executing the set value update process, the process returns to the timer interrupt process (FIG. 103).

  Here, in the setting value update process, it is not determined that the end condition is satisfied only by the setting key insertion unit 68a being in the OFF state, and the setting key insertion unit 68a is switched from the ON state to the OFF state. It is determined that the end condition is satisfied. When the setting value updating process is executed in the setting monitoring process, the setting key insertion unit 68a is in the OFF state at the start of the setting value updating process. Needs to be turned OFF after the setting key is inserted into the setting key insertion portion 68a and once turned ON. As a result, it is possible to prevent the setting value update process from ending even though a regular operation by the game hall manager is not performed.

  When the setting key insertion unit 68a is switched from the ON state to the OFF state and the end condition of the set value update process is satisfied, step S5111 in the set value update process (FIG. 85) is executed. It is compared whether or not the set value stored in the copy area in the work area 221 for specific control and the set value set this time in the set value counter in the work area 221 for specific control are the same. That is, it is determined whether or not the set value set before the set value update process (step S6904) is executed and the set value set in the current set value update process are the same. When both set values are the same (step S5112: NO), the already-described setting maintenance notification is performed by executing the non-change notification process (step S5113). On the other hand, when the two setting values are different (step S5112: YES), the already-described setting change notification is performed by executing the notification process at the time of change (step S5114).

  In a configuration in which a set value update process is executed when a set value abnormality has occurred, the set value set before the set value update process is executed and the set value update process are set. If the set value is the same, the setting maintenance notification is performed. As a result, even if the setting value update process is executed due to the setting value abnormality, the setting maintenance notification is performed by resetting the setting value set in the previous situation, and the setting value update due to the setting value abnormality is performed. Even if the process is executed, it is possible to clearly indicate to the player that the set value has not changed. By the way, since it is common to record the set values of each installed pachinko machine 10 in the game hall, it is possible to execute a set value update process due to a set value abnormality so as to be the recorded set value. Is possible.

  Returning to the description of the timer interrupt process (FIG. 103), after executing the setting monitoring process in step S6820, the management process is executed in step S6821. When executing the management process, a subroutine program corresponding to the management process set in the program for specific control is executed. After executing the management process, the subroutine program is executed. The information for specifying the return address of the timer interrupt processing at is written in the stack area 222 for specific control by a push command. When the management process is completed, information for specifying the return address is read by the pop instruction, and the process returns to the timer interrupt process program indicated by the return address.

  FIG. 105 is a flowchart showing the management process in the present embodiment executed by the main CPU 63. Note that the processing in steps S7001 to S7005 in the management processing is executed by the main CPU 63 using a program for specific control and data for specific control.

  First, in order to prohibit the generation of the timer interrupt process (FIG. 103), an interrupt prohibition is set (step S7001). This prevents the timer interrupt process (FIG. 103), which is a process corresponding to the specific control, from being interrupted and started in the middle of the management execution process described later, which is a process corresponding to the non-specific control. Is possible.

  Then, as “LD (_PSWBUF), PSW”, the information of the flag register of the main CPU 63 is saved in the PSW buffer set in the work area 221 for specific control by a load instruction (step S7002). The flag register includes a carry flag, a zero flag, a P / V flag, a sine flag, a half carry flag, and the like, and the information in the flag register changes depending on the execution result of the arithmetic instruction, rotate instruction, input / output instruction, and the like. By saving the flag register information before the subroutine program corresponding to the management execution process is started, the flag register in the state before the subroutine is changed or changed after the subroutine is started is saved. Information can be saved in the work area 221 for specific control.

  Thereafter, the management execution process is started by reading a subroutine program corresponding to the management execution process set in the non-specific control program (step S7003). In this case, information for specifying the return address of the management process after execution of the management execution process is written into the stack area 222 for specific control by a push command. When the management execution process ends, information for specifying the return address is read by the pop instruction, and the process returns to the management process program indicated by the return address.

  When returning to the management process program after the execution of the management execution process, “LD PSW, (_PSWBUF)” is saved in the PSW buffer in the work area 221 for specific control in step S7002 as a load instruction. The flag register information is returned to the flag register of the main CPU 63 (step S7004). As a result, the information in the flag register of the main CPU 63 is restored to the information at the time when step S7002 was executed last time. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

  Thereafter, in order to switch from the state in which the generation of the timer interrupt process (FIG. 103) is prohibited to the state in which it is permitted, an interrupt permission is set (step S7005). Thereby, a new execution of the timer interrupt process can be performed.

  FIG. 106 is a flowchart showing the management execution process in the present embodiment executed by the main CPU 63. Note that the processing of steps S7101 to S7116 in the management execution processing is executed by the main CPU 63 using a program for non-specific control and data for non-specific control.

  In steps S7101 to S7108 and S71010 to S7116, the same processes as those in steps S4501 to S4515 of the management execution process (FIG. 78) in the seventeenth embodiment are executed. In step S7109, another monitoring process is executed. When executing the separate monitoring process, a subroutine program corresponding to the separate monitoring process set in the non-specific control program is executed. When executing the subroutine program, after executing the separate monitoring process Information for specifying the return address of the management execution process is written to the non-specific control stack area 224 by a push command. When the separate monitoring process is completed, information for specifying the return address is read by the pop instruction, and the process returns to the management execution process program indicated by the return address.

  FIG. 107 is a flowchart showing another monitoring process. Note that the processing in steps S7201 to S7206 in the separate monitoring processing is executed by the main CPU 63 using a program for non-specific control and data for non-specific control.

  In the separate monitoring process, it is determined whether or not the value of the pointer indicating the processing position of the process being executed in the non-specific control program exceeds the normal numerical value range (step S7201). The information stored in the normal counter area 231, the opening / closing execution mode counter area 232, and the high frequency support mode counter area 233 provided in the work area 223 for non-specific control is clearly abnormal information. It is determined whether or not (step S7202). For example, in the normal counter area 231, if the value of the normal general winning counter 231a is 1000 or more even though the value of the normal out counter 231e is “0”, it is determined as abnormal. Further, it is determined whether or not the information stored in the calculation result storage area 234 provided in the work area 223 for non-specific control is clearly abnormal information (step S7203). For example, when any of the 62nd to 64th parameters is not “0” even though the 61st parameter is “0”, it is determined as abnormal.

  If an affirmative determination is made in any of steps S7201 to S7203, it is determined that an information abnormality has occurred in the work area 223 for non-specific control, and a partial clear process for the work area 223 for non-specific control is executed. (Step S7204). In the partial clear process, the storage area other than the management start flag is cleared to “0” in the work area 223 for non-specific control. In this case, all of the normal counter area 231, the open / close execution mode counter area 232, the high frequency support mode counter area 233 and the calculation result storage area 234 are cleared to “0”. Thereby, it becomes possible to eliminate the information abnormality in the work area 223 for non-specific control.

  Also, by not clearing the management start flag to “0”, it becomes possible to maintain the state where “1” is already set in the management start flag, and the pachinko machine 10 has already been continued in the game hall. In spite of being used, it is possible to prevent regulation of the shipment stage of the pachinko machine 10 with respect to the collection of history information. However, the present invention is not limited to this. In step S7204, the entire work area 223 for non-specific control including the management start flag may be cleared to “0”.

  In step S7204, the stack area 224 for non-specific control is not cleared to “0”. In the non-specific control stack area 224, information on various registers used in the processing corresponding to the specific control is saved in steps S7102 to S7107 in the management execution processing (FIG. 106). In this case, by not clearing the stack area 224 for non-specific control to “0”, information on various registers used in processing corresponding to this specific control, which is a stack area for non-specific control It is possible to prevent the information saved in 224 from being erased. The non-specific control stack area 224 stores information on the return address of the management execution process (FIG. 106) after the separate monitoring process ends. By not clearing, it is possible to prevent the information of this return address from being erased.

  Thereafter, initial setting processing is executed (step S7205). In the initial setting process, initial setting is performed for the storage area that is the target of “0” clear in step S7204 in the work area 223 for non-specific control.

  Thereafter, a clear notification process is executed (step S7206). In the clear notification process, a command indicating that the work area 223 for non-specific control is cleared to “0” is transmitted to the sound emission control device 81. Upon receiving the command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the forced clearing of the work area 223 for non-specific control, and “history information is forcibly cleared from the speaker unit 54. Sound is output. In addition, a character image “history information has been forcibly cleared” is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are terminated when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the administrator of the game hall. As the notification end operation, for example, the update button 68b may be pressed, or the reset button 68c may be pressed. By confirming the notification, the manager of the game hall can grasp that the work area 223 for non-specific control has been forcibly cleared.

  If a negative determination is made in all of steps S7201 to S7203, or if the process of step S7206 is executed, the separate monitoring process is terminated and the process returns to the monitoring execution process (FIG. 106).

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

  When the program monitoring unit 252 specifies that the address specified when writing information by the load instruction is an abnormal address, the reset signal output unit 251 turns the reset signal from OFF to ON, thereby causing the main CPU 63. Then, the main process (FIG. 100) is executed in the same manner as when the supply of operating power is newly started. When the reset signal is turned OFF → ON, “1” is not set in the power failure flag in the work area 221 for specific control, and the checksum at the time of power failure is stored in the work area 221 for specific control. Since it is not performed, the clear process (step S6607) at the time of non-setting update is forcibly executed. In the clear process at the time of non-setting update, the storage area other than the storage area in which the set value of the pachinko machine 10 is stored in the work area 221 for specific control is cleared to “0” and the stack area 222 for specific control is “ “0” is cleared, and further, initial setting processing of these areas is executed. As a result, when there is a possibility that an information abnormality has occurred regarding the work area 221 for specific control or the stack area 222 for specific control, the work area 221 for specific control and the stack area 222 for specific control are displayed. On the other hand, by executing the “0” clear process and the initial setting process, the information abnormality can be resolved.

  When the program monitoring unit 252 determines that the value of the program counter of the main CPU 63 is an abnormal value, the reset signal output unit 251 switches the reset signal from OFF to ON, thereby causing the main CPU 63 to reduce the operating power. The main process (FIG. 100) is executed in the same manner as when the supply is newly started. When the reset signal is turned OFF → ON, “1” is not set in the power failure flag in the work area 221 for specific control, and the checksum at the time of power failure is stored in the work area 221 for specific control. Since it is not performed, the clear process (step S6607) at the time of non-setting update is forcibly executed. In the non-setting update clear process, the internal storage area of the main CPU 63 including various registers is cleared to “0” and the initial setting process is executed. As a result, when there is a possibility that an information abnormality has occurred with respect to the internal storage area of the main CPU 63, the "0" clear and initial setting process are executed for the internal storage area of the main CPU 63. It is possible to eliminate the information abnormality.

  On the other hand, the non-specific control work area 223 and the non-specific control stack area 224 are not cleared to “0” in the clear process at the time of non-setting update. As a result, “0” is cleared with respect to the internal storage area of the main CPU 63, the work area 221 for specific control, and the stack area 222 for specific control because the information abnormality is specified in the program monitoring unit 252 as described above. Even if the initial setting process is executed, it is possible to prevent the game history information from being erased and to prevent the game history management result information from being erased. It becomes possible to do.

  If the power failure flag is not set to “1” in the main process (FIG. 100) when supply of operating power to the main CPU 63 is started, or if the checksums do not match, clear at non-setting update In the configuration in which the process (step S6607) is executed, when the occurrence of an information abnormality is specified by the program monitoring unit 252, "1" is not set in the power failure flag by turning the reset signal from OFF to ON At the same time, the main process (FIG. 100) is executed in a situation where no checksum is stored. As a result, it is possible to eliminate the information abnormality identified by the program monitoring unit 252 using a configuration for eliminating the information abnormality at the start of supply of operating power.

  In the configuration in which whether or not the checksum is normal is monitored in the main process (FIG. 100) when the supply of operating power to the main CPU 63 is started, the checksum calculation target is for specific control. The work area 221 and the stack area 222 for specific control are included, and the work area 223 for non-specific control and the stack area 224 for non-specific control are not included. Thereby, it is possible to specify whether or not an information abnormality has occurred only in the storage area corresponding to the specific control in the main RAM 65.

  When it is specified that the checksum is abnormal in the main process (FIG. 100) when the supply of operating power to the main CPU 63 is started, a clear process (step S6607) at the time of non-setting update is executed. However, in the clear process at the time of non-setting update, a process of clearing “0” and an initial setting process are executed in the work area 221 for specific control and the stack area 222 for specific control. On the other hand, the process of clearing “0” is not executed in the work area 223 for non-specific control and the stack area 224 for non-specific control. This prevents the processing corresponding to the specific control from being continuously executed in the state as it is despite the occurrence of information abnormality in the work area 221 for the specific control and the stack area 222 for the specific control. “0” is cleared to the storage area corresponding to the non-specific control of the main RAM 65 triggered by the information abnormality in the work area 221 for specific control and the stack area 222 for specific control. It becomes possible not to be.

  In the power failure information storage processing (FIG. 101) (steps S6709 to S6712), the checksum is calculated for the work area 221 for specific control and the stack area 222 for specific control. No checksum is calculated for the storage area corresponding to the non-specific control. As a result, it is possible to prevent the processing period required for completing the power failure process from becoming excessively long.

  Corresponding to non-specific control when occurrence of abnormality is specified for information stored in work area 223 for non-specific control in another monitoring process (FIG. 107) executed in the process corresponding to non-specific control In the separate monitoring process (FIG. 107) that is to be performed, the work area 223 for non-specific control is cleared to “0” and the initial setting process is executed. As a result, the processing corresponding to the non-specific control is executed in a state where the information of the work area 223 for non-specific control is retained as it is even though some abnormality has occurred in the work area 223 for non-specific control. It is possible to prevent it from being lost. Further, the process of clearing the work area 223 for non-specific control to “0” and the process of initial setting are executed in the process corresponding to the non-specific control. It is possible to prevent the processing corresponding to the specific control from intervening.

  In another monitoring process (FIG. 107) that is a process corresponding to non-specific control, whether or not an abnormality has occurred in the work area 223 for non-specific control is executed, and when an abnormality has occurred The process for clearing the work area 223 for non-specific control to “0” and the process for initial setting are executed. As a result, a series of processes in the process corresponding to the non-specific control includes monitoring whether or not an abnormality has occurred in the work area 223 for non-specific control and executing the initialization of the work area 223 for non-specific control. Can be executed as

  When the occurrence of an abnormality is specified for the information stored in the work area 223 for non-specific control in another monitoring process (FIG. 107) executed in the process corresponding to non-specific control, Although the process of clearing “0” and the process of initial setting are executed for the work area 223, the process of clearing “0” and the process of initial setting are not executed for the stack area 224 for non-specific control. This makes it possible to eliminate information abnormality in the work area 223 for non-specific control, and information on various registers used in the processing corresponding to the specific control saved in the stack area 224 for non-specific control and separate management. It is possible to prevent the return address information from being deleted after the processing is completed.

  The process of clearing the work area 221 for specific control and the stack area 222 for specific control to “0” and initial setting is executed in the process corresponding to the specific control, and the work area 223 for non-specific control is set to “0”. The process of clearing and initial setting is executed in a process corresponding to non-specific control. As a result, regarding such initialization processing, the work area 221 for specific control and the stack area 222 for specific control are handled as dedicated storage areas for processing corresponding to specific control, and for non-specific control. The work area 223 can be handled as a dedicated storage area for processing corresponding to non-specific control.

  In the main process (FIG. 100), it is configured to monitor whether or not the set value is normal in steps S6608 and S6614. However, the process for monitoring whether or not these set values are normal is performed. It is good also as a structure which is not performed. As a result, it is possible to reduce the processing load of the process at the start of the supply of operating power that is executed when the supply of operating power to the main CPU 63 is started. In addition, even if the setting value is not normally monitored in the process at the start of supply of operating power in this way, the timer interrupt that is executed after the process at the start of supply of operating power is completed In the setting monitoring process (step S6820) of the process (FIG. 103), it is monitored whether or not the setting value is normal. Therefore, if the setting value is abnormal, it can be dealt with.

  The setting monitoring process (step S6820) is not limited to a configuration that is executed every time the timer interrupt process (FIG. 103) is started. For example, the timer interrupt process (FIG. 103) is defined as a plurality of triggers. The configuration may be such that the setting monitoring process (step S6820) is executed every time the number of times (for example, 10,000 times) is executed. In this case, it is possible to suppress the execution frequency of the monitoring while periodically monitoring whether or not the set value is normal.

  The setting monitoring process (step S6820) may be executed in the remaining process (steps S6610 to S6613) in the main process (FIG. 100). In this case, it is possible to monitor whether or not the set value is normal using the idle time when the timer interrupt process is not executed.

  Further, the configuration monitoring process (step S6820) may be executed when a game round is newly started. More specifically, the configuration monitoring process (step S6820) may be executed before the success / failure determination process is executed when a game round is newly started. As a result, it is possible to prevent the determination process from being executed in a situation where the set value is abnormal.

  When the setting monitoring process (step S6820) specifies that the set value is abnormal, the setting control process area 221 is provided in place of the configuration for shifting to the set value update process (step S6904). The game stop flag may be set to “1”. In this case, by making an affirmative determination in step S6807 in the timer interrupt process (FIG. 103), the process from step S6808 to step S6821 is not executed, so that the progress of the game is stopped when the set value is abnormal. It becomes. However, since the processing of steps S6801 to S6806 is executed, power failure monitoring is executed, and the hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and Fraud detection is performed. In addition, when “1” is set in the game stop flag, a notification indicating that the setting value should be updated may be executed to prompt the execution of the setting value update process. In this case, the game hall administrator who has confirmed the notification performs the power-off operation after the power-off operation, and the game stop flag is cleared to “0”. As a result, the state in which the progress of the game is stopped is released, and the set value update process is executed to set a normal set value.

  When the setting monitoring process (step S6820) specifies that the setting value is abnormal, the main process (with the setting abnormality flag set in the work area 221 for specific control set to “1”) (FIG. 100) may be configured, and in order to stop the progress of the game with the setting abnormality flag set to “1” and release the state where the progress of the game is stopped, the power is turned off → It is good also as a structure which needs ON. In this case, even if an operation for causing the set value update process to be executed is not performed in the main process (FIG. 100), the setting is forcibly set when “1” is set in the setting abnormality flag. By executing the value update process, it is possible to force a new setting value to be set using the set value update process set in the main process (FIG. 100).

  In addition, when the occurrence of an information abnormality is specified by the program monitoring unit 252 and the reset signal is forcibly turned from OFF to ON, initialization processing is performed on the work area 221 for specific control. The setting value of the pachinko machine 10 may be “setting 1”. In addition, when the occurrence of an information abnormality is specified by the program monitoring unit 252 and the reset signal is forcibly turned from OFF to ON, the setting is performed after the initialization process is executed for the work area 221 for specific control. The value update process may be executed.

  In addition, when the occurrence of an information abnormality is specified by the program monitoring unit 252, the reset signal is not forcibly turned OFF → ON, and the clear process (step S6607) at the time of non-setting update is executed. Alternatively, the configuration may be such that the clear process at the time of setting update (step S6620) and the set value update process (step S6621) are executed.

  Further, in the clear process at the time of non-setting update (step S6607), the setting value of the pachinko machine 10 becomes “setting 1” by initializing the storage area for storing the setting value information in the work area 221 for specific control. It is good also as a structure and it is good also as a structure used as predetermined setting values other than "setting 1". Thereby, when the clear process at the time of non-setting update is executed, it becomes possible to set a predetermined set value.

  Further, in the non-setting update clear process (step S6607), the non-specific control work area 223 and the non-specific control stack area 224 are not cleared to “0”, but may be configured to be cleared to “0”. Good.

  Further, in step S7204 in the separate monitoring process (FIG. 107), the management start flag is not cleared to “0”, but the management start flag may be cleared to “0”. In step S7204 in the separate monitoring process (FIG. 107), the normal counter area 231, the open / close execution mode counter area 232, and the high frequency support mode counter area 233 may not be cleared to “0”. The configuration may be such that 234 is not cleared to “0”.

  In step S7204 in the separate monitoring process (FIG. 107), the “0” clear process and the initial setting process are executed not only for the work area 223 for non-specific control but also for the stack area 224 for non-specific control. It is good also as a structure. In this case, in the stack area 224 for non-specific control, it is used in the processing corresponding to the specific control saved in the stack area 224 for non-specific control and the information on the return address of the management execution process after the completion of the separate monitoring process. It is preferable not to erase the information in various registers.

  In another monitoring process (FIG. 107), it is monitored whether or not an abnormality has occurred in the non-specific control stack area 224. The stack area 224 may be configured to execute “0” clear processing and initial setting processing. In this case, it is preferable not to delete the return address information of the management execution process after the completion of the separate monitoring process in the stack area 224 for non-specific control.

  The specific control work area 221 and the specific control stack area 222 are not limited to the configuration in which the checksum is calculated, and only the specific control work area 221 is the checksum calculation target. Alternatively, only the stack area 222 for specific control may be a checksum calculation target.

<Thirty-first embodiment>
In the present embodiment, the processing configuration of the main process executed by the main CPU 63 is different from that of the thirtieth embodiment. Hereinafter, a configuration different from the thirtieth embodiment will be described. The description of the same configuration as that of the thirtieth embodiment is basically omitted.

  FIG. 108 is a flowchart showing main processing in the present embodiment, which is executed by the main CPU 63. In addition, the process of step S7301-step S7322 in a main process is performed using the program for specific control in the main side CPU63, and the data for specific control.

  First, a power-on wait process is executed (step S7301). In the power-on wait process, for example, the process waits without proceeding to the next process until a predetermined time for waiting (specifically, 1 second) elapses after the main process is activated. The operation start and initial setting of the symbol display device 41 are completed during the execution period of the power-on wait process. Thereafter, access to the main RAM 65 is permitted (step S7302).

  Thereafter, it is determined whether or not “1” is set in the power failure flag provided in the work area 221 for specific control in the main RAM 65 (step S7303). When “1” is set in the power failure flag (step S7303: YES), a checksum is calculated for the work area 221 for specific control and the stack area 222 for specific control (step S7304). The checksum calculation method is the same as that in step S6604 of the main process (FIG. 100) in the thirtieth embodiment.

  Thereafter, the work area 221 for specific control and the stack area for specific control which are calculated and stored in the work area 221 for specific control calculated in the power failure process executed immediately before the supply of the operating power to the MPU 62 is stopped. The checksum for 222 is read from the work area 221 for specific control, and the read checksum is compared with the checksum calculated in step S7304 (step S7305). Then, it is determined whether or not the checksums match (step S7306).

  If an affirmative determination is made in step S7306, the processing in steps S7307 to S7320 is executed. In this case, the processing contents of steps S7307 to S7314 are the same as steps S6614 to S6621 of the main processing (FIG. 100) in the thirtieth embodiment, and steps S7316 to S7320 are the main processing in the thirtieth embodiment. This is the same as steps S6609 to S6613 of the process (FIG. 100).

  If the reset button 68c is pressed (step S7308: YES), but a negative determination is made in any of steps S7309 to S7311, a clear process at the time of non-setting update is executed (step S7308: YES) S7315). The processing content of the clear processing at the time of non-setting update is the same as step S6607 of the main processing (FIG. 100) in the thirtieth embodiment. However, in the present embodiment, after executing the clear process at the time of non-setting update, the process proceeds to steps S7316 to S7320 without determining whether or not the set value is normal. Only when a negative determination is made in any of steps S7309 to S7311, the clear process at the time of non-setting update (step S7315) is executed, but before the processes of steps S7309 to S7311 are executed. Since it is determined whether or not the set value is normal in step S7307, it is not necessary to determine whether or not the set value is normal after executing the clear process at the time of non-setting update.

  If a negative determination is made in step S7303 or step S7306, that is, if a power failure flag in the work area 221 for specific control is not set to "1" or if a checksum abnormality occurs, clear processing at the time of abnormality is executed (Step S7321). FIG. 109 is a flowchart showing a clear process at the time of abnormality. Note that the processing in steps S7401 to S7405 in the clear processing at the time of abnormality is executed in the main CPU 63 using a program for specific control and data for specific control.

  First, clear processing of the work area 221 for specific control is executed (step S7401). In the clear process, the work area for the specific control, except for the area (specifically, the set value counter) in which the set value information indicating the set state of the pachinko machine 10 is set in the work area 221 for the specific control. 221 is cleared to “0” and initial setting is performed for the area where “0” is cleared. As a result, the area indicating whether or not the lottery mode is the high probability mode is cleared to “0”, so that the lottery regardless of the lottery mode immediately before the supply of the operating power to the pachinko machine 10 is stopped. The mode is a low probability mode. In addition, the game turn is not executed, the opening / closing execution mode is not executed, and the general-purpose display portion 38a is not variably displayed, and the general utility 34a is in a closed state. Situation. In addition, since the hold storage area 65a and the power train hold area 65c provided in the work area 221 for specific control are also cleared to “0”, the hold information for the special figure display section 37a is deleted and the map display section. The hold information for 38a is deleted.

  Thereafter, clear processing of the stack area 222 for specific control is executed (step S7402). In the clear processing, the stack area 222 for specific control is cleared to “0” and initial setting is performed.

  Thereafter, the information of the flag register of the main CPU 63 is saved in the stack area 222 for specific control by “push instruction” as “PUSH PSW” (step S7403). The flag register includes a carry flag, a zero flag, a P / V flag, a sine flag, a half carry flag, and the like, and the information in the flag register changes depending on the execution result of the arithmetic instruction, rotate instruction, input / output instruction, and the like. By saving the flag register information before the subroutine program corresponding to the clear processing for non-specific control is started, the flag in the state before changing after the subroutine is called or the subroutine is started It is possible to save the register information in the stack area 222 for specific control. The amount of information in the flag register is 1 byte.

  Thereafter, the non-specific control clear process is started by reading the subroutine program corresponding to the non-specific control clear process set in the non-specific control program (step S7404). In this case, information for specifying the return address of the clear process at the time of abnormality after execution of the non-specific control clear process is written to the specific control stack area 222 by a push command. When the clear process for non-specific control is completed, information for specifying the return address is read by the pop instruction, and the process returns to the clear process program at the time of abnormality indicated by the return address.

  When returning to the program of the clear process at the time of abnormality after executing the clear process for the non-specific control, the flag register saved as “POP PSW” in the specific control stack area 222 in step S7402 by the pop instruction Is returned to the flag register of the main CPU 63 (step S7405). As a result, the information in the flag register of the main CPU 63 is restored to the information at the time when step S7402 was executed. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

  FIG. 110 is a flowchart showing a clear process for non-specific control. Note that the processing in steps S7501 to S7516 in the clear processing for non-specific control is executed by the main CPU 63 using a program for non-specific control and data for non-specific control.

  First, as “LD SP, Y (u + 2)”, Y (u + 2) is set as a fixed address at the start of non-specific control in the stack pointer of the main CPU 63 by a load instruction (step S7501). In this case, as in step S3901 of the management execution process (FIG. 71) in the fifteenth embodiment, information on the last address in the non-specific control stack area 224 is set in the stack pointer.

  After that, as “LD (_WABUF), WA”, the information of the WA register of the main CPU 63 is saved in the WA buffer set in the work area 223 for non-specific control by a load instruction (step S7502). Also, as “LD (_BCBUF), BC”, the information in the BC register of the main CPU 63 is saved to the BC buffer set in the work area 223 for non-specific control by a load instruction (step S7503). Further, as “LD (_DEBUF), DE”, the DE register information of the main CPU 63 is saved in the DE buffer set in the work area 223 for non-specific control by a load instruction (step S7504). Also, as “LD (_HLBUF), HL”, the information of the HL register of the main CPU 63 is saved in the HL buffer set in the work area 223 for non-specific control by a load instruction (step S7505). Also, as “LD (_IXBUF), IX”, the information of the IX register of the main CPU 63 is saved in the IX buffer set in the work area 223 for non-specific control by a load instruction (step S7506). Further, as “LD (_IYBUF), IY”, the information in the IY register of the main CPU 63 is saved in the IY buffer set in the work area 223 for non-specific control by a load instruction (step S7507).

  The general-purpose CPU 63 has various general-purpose registers, auxiliary registers, and index registers in addition to the flag registers described above. In this case, in steps S7502 to S7507, information on each of the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register, which are some of the various general-purpose registers, auxiliary registers, and index registers. Are saved in a corresponding buffer in the work area 223 for non-specific control. The amount of information in each of the WA register, BC register, DE register, HL register, IX register, and IY register is 2 bytes.

  The WA register, BC register, DE register, HL register, IX register, and IY register are partially cleared (step S7508) and initial setting process (step S7508) in the work area 223 for non-specific control, which is processing corresponding to non-specific control. This is the register used in step S7509). The information set in such a register is saved in the work area 223 for non-specific control prior to the execution of the partial clear process (step S7508) and the initial setting process (step S7509) of the work area 223 for non-specific control. By doing so, it is possible to save the information of these registers used in the specific control before the non-specific control is started. Therefore, even if these registers are overwritten during non-specific control, when the non-specific control is terminated, the information saved in the non-specific control work area 223 is restored to these registers, so that the state of these registers is restored. Can be returned to a state corresponding to the specific control before the non-specific control is executed.

  Further, instead of saving all the information in the various general-purpose registers, auxiliary registers, and index registers in the non-specific control work area 223, the non-specific control work area 223 is a process corresponding to non-specific control. Information for WA register, BC register, DE register, HL register, IX register and IY register to be used in partial clear processing (step S7508) and initial setting processing (step S7509) is selectively used for non-specific control. By retreating to the work area 223, it is possible to suppress the capacity reserved for retreating register information in the work area 223 for non-specific control. Therefore, while ensuring a large capacity of the work area 223 for non-specific control that can be used in the partial clear process (step S7508) and the initial setting process (step S7509) of the work area 223 for non-specific control, Such register information can be saved. Of course, among the various general-purpose registers, auxiliary registers, and index registers in the main CPU 63, registers other than the WA register, BC register, DE register, HL register, IX register, and IY register support non-specific control. The information set before the process to start is stored and held until the process corresponding to the non-specific control is completed and the process corresponding to the specific control is resumed.

  In addition, the register information is not saved in the non-specific control stack area 224, but is saved in the non-specific control work area 223, thereby reducing the capacity of the non-specific control stack area 224. It becomes possible. Further, when using the non-specific control stack area 224, the information writing order is read first from the later information as already described, and therefore the information reading order is shifted due to some noise or the like. If this happens, all of the subsequent reading order information will be restored to a different register. The occurrence probability of such an event increases as the amount of information saved in the non-specific control stack area 224 increases. On the other hand, by saving the register information in the work area 223 for non-specific control, it becomes possible to prevent the above event from occurring even when there is a lot of information to be saved. .

  After executing the processing of steps S7502 to S7507, the partial clear processing of the work area 223 for non-specific control is executed (step S7508). In the partial clear processing, among the storage areas of the work area 223 for non-specific control, the storage areas other than the storage area where the information of various registers of the main CPU 63 used in the processing corresponding to the specific control is saved Is cleared to “0”. Specifically, among the storage areas of the non-specific control work area 223, the WA buffer, BC buffer, DE buffer, HL buffer, IX buffer, and IY buffer are not cleared to “0”, but other than these various buffers are stored. Clear the area to “0”.

  In this case, all of the normal counter area 231, the open / close execution mode counter area 232, the high frequency support mode counter area 233, the calculation result storage area 234 and the management start flag are cleared to “0”. Thereby, it becomes possible to eliminate the information abnormality in the work area 223 for non-specific control. Further, the processing corresponding to the non-specific control is completed by not clearing the storage area where the information of the various registers of the main CPU 63 used in the processing corresponding to the specific control is saved to “0”. When returning to the process corresponding to the specific control, the information used in the process corresponding to the specific control can be returned to the various registers of the main CPU 63.

  In step S7508, the stack area 224 for non-specific control is not cleared to “0”. The non-specific control stack area 224 stores information on the return address of the clear process (FIG. 109) at the time of abnormality after the non-specific control clear process is completed. By preventing 224 from being cleared to “0”, it is possible to prevent the information at this return address from being erased.

  Thereafter, an initial setting process is executed (step S7509). In the initial setting process, initial setting is performed for the storage area that is the target of “0” clear in step S7508 in the work area 223 for non-specific control.

  After that, as “LD SP, Y (r + α)”, the stack pointer of the main CPU 63 is returned to the specific control by the load instruction, as in step S3909 of the management execution process (FIG. 71) in the fifteenth embodiment. Y (r + α) is set as a fixed address at the time (step S7510). The address of Y (r + α) is set as an address between Y (r + 8) and Y (s) in the stack area 222 for specific control.

  After that, as “LD WA, (_WABUF)”, the information saved in the WA buffer of the work area 223 for non-specific control is overwritten in the WA register of the main CPU 63 by the load instruction (step S7511). In addition, as “LD BC, (_BCBUF)”, the information saved in the BC buffer of the work area 223 for non-specific control is overwritten in the BC register of the main CPU 63 by the load instruction (step S7512). Also, as “LD DE, (_DEBUF)”, the information saved in the DE buffer of the work area 223 for non-specific control is overwritten in the DE register of the main CPU 63 by the load instruction (step S7513). Further, as “LD HL, (_HLBUF)”, the information saved in the HL buffer of the work area 223 for non-specific control is overwritten in the HL register of the main CPU 63 by the load instruction (step S7514). Further, as “LD IX, (_IXBUF)”, the information saved in the IX buffer of the work area 223 for non-specific control is overwritten in the IX register of the main CPU 63 by the load instruction (step S7515). Further, as “LD IY, (_IYBUF)”, the information saved in the IY buffer of the work area 223 for non-specific control is overwritten in the IY register of the main CPU 63 by the load instruction (step S7516). By executing the processing of step S7511 to step S7516, processing corresponding to non-specific control is started for each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63. It is possible to return to the information corresponding to the specific control immediately before starting.

  According to the above configuration, when the power failure flag is not set to “1” in the main process (FIG. 108) executed when the supply of operating power to the main CPU 63 is started, or the checksum is abnormal. In some cases, the clear process at the time of abnormality (step S7321) is executed, so that not only the work area 221 for specific control and the stack area 222 for specific control but also the work area 223 for non-specific control is “0”. Cleared and initialized. If an information abnormality has occurred in the work area 221 for specific control, there may be an information abnormality in the work area 223 for non-specific control. The work area 223 is also initialized so that the processing corresponding to the non-specific control is not executed in the state as it is even though the information abnormality has occurred in the work area 223 for the non-specific control. It becomes possible to do.

  Even when the process of clearing “0” and the process of initial setting are executed for the work area 223 for non-specific control in the clear process at the time of abnormality (step S7321), the work area for non-specific control Information of various registers used in the process corresponding to the specific control saved in the H.223 is not cleared to “0”. As a result, the process of clearing “0” to the work area 223 for non-specific control while not erasing the information used in the process corresponding to the specific control after the process corresponding to the non-specific control is completed. In addition, it is possible to execute initialization processing.

  Even when the process of clearing “0” and the process of initial setting are executed for the work area 223 for non-specific control in the clear process at the time of abnormality (step S7321), the stack area 224 for non-specific control is executed. The process for clearing “0” and the process for initial setting are not executed. Thereby, it is possible to prevent the information of the return address from being deleted after the non-specific control clear process (FIG. 110) is completed.

  The process of clearing the work area 221 for specific control and the stack area 222 for specific control to “0” and the process of initial setting are executed in a process corresponding to the specific control, and the work area 223 for non-specific control is designated as “ The process of clearing “0” and the process of initial setting are executed in a process corresponding to non-specific control. Accordingly, regarding the process of clearing “0” and the process of initial setting, the work area 221 for specific control and the stack area 222 for specific control are treated as a dedicated storage area for the process corresponding to the specific control, and non- The work area 223 for specific control can be handled as a dedicated storage area for processing corresponding to non-specific control.

  It should be noted that both the specific control work area 221 and the specific control stack area 222 are not limited to the configuration in which the checksum is calculated, and only the specific control work area 221 is the checksum calculation target. Alternatively, only the stack area 222 for specific control may be a checksum calculation target.

  Further, the configuration may be such that the work area 223 for non-specific control is a checksum calculation target. In this case, the work area 221 for specific control and the work area 223 for non-specific control may be a checksum calculation target, and the stack area 222 for specific control and the work area 223 for non-specific control are checked. The configuration may be a sum calculation target, or the specific control work area 221, the specific control stack area 222, and the non-specific control work area 223 may be a check sum calculation target.

  The stack area 224 for non-specific control may be a checksum calculation target. In this case, the work area 221 for specific control and the stack area 224 for non-specific control may be subject to checksum calculation, and the stack area 222 for specific control and the stack area 224 for non-specific control are checked. The configuration may be a sum calculation target, or the specific control work area 221, the specific control stack area 222, and the non-specific control stack area 224 may be a check sum calculation target.

  The work area 223 for non-specific control and the stack area 224 for non-specific control may be a checksum calculation target. In this case, the work area 221 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control may be a checksum calculation target. The specific control work area 223 and the non-specific control stack area 224 may be a checksum calculation target. The specific control work area 221, the specific control stack area 222, and the non-specific control stack area 224 may be used. The work area 223 and the non-specific control stack area 224 may be a checksum calculation target.

  In step S7508 and step S7509 in the non-specific control clear process (FIG. 110), not only the non-specific control work area 223 but also the non-specific control stack area 224 is cleared. The initial setting process may be executed. In this case, it is preferable not to delete the return address information of the clear process at the time of abnormality after the completion of the clear process for non-specific control.

  Further, in step S7508 in the clear process for non-specific control (FIG. 110), the management start flag is cleared to “0”, but the management start flag may not be cleared to “0”. In step S7508 in the non-specific control clear process (FIG. 110), the normal counter area 231, the open / close execution mode counter area 232, and the high frequency support mode counter area 233 may not be cleared to “0”. The calculation result storage area 234 may not be cleared to “0”.

<Thirty-second embodiment>
In the present embodiment, the processing configuration relating to monitoring of information abnormality in the main RAM 65 using a checksum is different from that in the thirtieth embodiment. Hereinafter, a configuration different from the thirtieth embodiment will be described. The description of the same configuration as that of the thirtieth embodiment is basically omitted.

  FIG. 111 is a flowchart showing the power failure information storage process in the present embodiment executed by the main CPU 63. The power failure information storage process is executed in step S6801 in the timer interrupt process (FIG. 103). In addition, the processes in steps S7601 to S7613 in the power failure information storage process are executed by the main CPU 63 using the specific control program and the specific control data.

  In steps S7601 to S7608 in the power failure information storage process, the same processes as steps S6701 to S6708 in the power failure information storage process (FIG. 101) in the 30th embodiment are executed. When the occurrence of a power failure is specified, an affirmative determination is made in step S7608, and the power failure process in steps S7609 to S7613 is executed.

  Specifically, first, “1” is set in the power failure flag provided in the work area 221 for specific control (step S7609). As a result, when the power failure process is normally executed and the information storage in the main RAM 65 is normally performed, the operation power supply to the main CPU 63 is started again for the specific control. That is, “1” is set in the power failure flag of the work area 221.

  Thereafter, a checksum is calculated for the work area 221 for specific control and the stack area 222 for specific control (step S7610). In this case, the storage area in the work area 221 for specific control and the stack area 222 for specific control, which are calculation targets when calculating the checksum for specific control, is stored in step S7701 of checksum monitoring processing (FIG. 112) described later. These are the same as the storage areas in the work area 221 for specific control and the stack area 222 for specific control that are the targets of calculation of the checksum for specific control. Further, in the storage area to be calculated when calculating the checksum for specific control, an area (specifically, information on setting values indicating the setting state of the pachinko machine 10 in the work area 221 for specific control is set). Includes a set value counter). The calculated checksum for specific control is a storage area for storing the checksum for specific control in the work area 221 for specific control, and is excluded from the calculation target of the checksum for specific control. Store in the storage area.

  Thereafter, a checksum is calculated for the work area 223 for non-specific control and the stack area 224 for non-specific control (step S7611). In this case, the storage areas in the non-specific control work area 223 and the non-specific control stack area 224, which are calculation targets when calculating the check sum for non-specific control, checksum monitoring processing described later (FIG. 112). This is the same as the storage area in the work area 223 for non-specific control and the stack area 224 for non-specific control, which is the calculation target of the check sum for non-specific control in step S7706. The calculated checksum for non-specific control is a storage area for storing the checksum for non-specific control in the work area 221 for specific control, and is excluded from the calculation target of the checksum for specific control. Stored in the storage area.

  Thereafter, all the output port information in the register of the main CPU 63 is set to “0” (step S7612), and access to the main RAM 65 is prohibited (step S7613). Then, the infinite loop is continued until the power supply is completely shut down and processing cannot be executed.

  Next, a checksum monitoring process executed by the main CPU 63 will be described with reference to the flowchart of FIG. Note that the checksum monitoring process is executed in the main process (FIG. 100) instead of steps S6604 to S6606. In addition, the processes in steps S7701 to S7711 in the checksum monitoring process are executed in the main CPU 63 using a program for specific control and data for specific control.

  First, a checksum for specific control is calculated for the work area 221 for specific control and the stack area 222 for specific control (step S7701). The calculation method of the checksum for specific control is the same as that in step S7610 in the power failure information storage process (FIG. 111). Thereafter, the checksum for specific control calculated in step S7610 of the power failure process executed immediately before the supply of operating power to the MPU 62 is stopped and stored in the work area 221 for specific control is used for specific control. And the read checksum for specific control is compared with the checksum for specific control calculated in step S7701 (step S7702). Then, it is determined whether or not the checksums for specific control match (step S7703).

  If the checksums for specific control do not match (step S7703: NO). Clear processing of the work area 221 for specific control is executed (step S7704). In the clear process, the work area for the specific control, except for the area (specifically, the set value counter) in which the set value information indicating the set state of the pachinko machine 10 is set in the work area 221 for the specific control. 221 is cleared to “0” and initial setting is executed. As a result, the area indicating whether or not the lottery mode is the high probability mode is cleared to “0”, so that the lottery regardless of the lottery mode immediately before the supply of the operating power to the pachinko machine 10 is stopped. The mode is a low probability mode. In addition, the game turn is not executed, the opening / closing execution mode is not executed, and the general-purpose display portion 38a is not variably displayed, and the general utility 34a is in a closed state. Situation. In addition, since the hold storage area 65a and the power train hold area 65c provided in the work area 221 for specific control are also cleared to “0”, the hold information for the special figure display section 37a is deleted and the map display section. The hold information for 38a is deleted. In the clear process, the various registers of the main CPU 63 are cleared to “0”, and then the initial setting is executed. Further, the stack area 222 for specific control is cleared to “0” and initial setting is executed (step S7705).

  If an affirmative determination is made in step S7703, or if the processing in step S7705 is executed, a checksum for nonspecific control is calculated for the work area 223 for nonspecific control and the stack area 224 for nonspecific control (step S7706). The checksum calculation method for non-specific control is the same as that in step S7611 in the power failure information storage process (FIG. 111). Thereafter, the non-specific control checksum calculated in step S7611 of the power failure process executed immediately before the operation power supply to the MPU 62 is stopped and stored in the specific control work area 221 is specified. The non-specific control checksum read out from the work area 221 is compared with the non-specific control checksum calculated in step S7706 (step S7707). Then, it is determined whether or not the checksums for non-specific control match (step S7708).

  If the checksums for non-specific control do not match (step S7708: NO), the information of the flag register of the main CPU 63 is saved to the specific control stack area 222 as a “PUSH PSW” by a push command ( Step S7709). The flag register includes a carry flag, a zero flag, a P / V flag, a sine flag, a half carry flag, and the like, and the information in the flag register changes depending on the execution result of the arithmetic instruction, rotate instruction, input / output instruction, and the like. By saving the flag register information before the subroutine program corresponding to the clear processing for non-specific control is started, the flag in the state before changing after the subroutine is called or the subroutine is started It is possible to save the register information in the stack area 222 for specific control. The amount of information in the flag register is 1 byte.

  Thereafter, the non-specific control clear process is started by reading the subroutine program corresponding to the non-specific control clear process set in the non-specific control program (step S7710). In this case, information for specifying the return address of the checksum monitoring process after execution of the non-specific control clear process is written to the specific control stack area 222 by a push command. When the clear process for non-specific control is completed, information for specifying the return address is read by the pop instruction, and the process returns to the checksum monitoring process program indicated by the return address.

  When returning to the program of the clear process at the time of abnormality after executing the clear process for the non-specific control, the flag register saved as “POP PSW” in the stack area 222 for the specific control in step S7709 by the pop instruction Is returned to the flag register of the main CPU 63 (step S7711). As a result, the information in the flag register of the main CPU 63 is restored to the information at the time when step S7709 was executed. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

  FIG. 113 is a flowchart showing a clear process for non-specific control. Note that the processing in steps S7801 to S7818 in the clear processing for non-specific control is executed by the main CPU 63 using a program for non-specific control and data for non-specific control.

  In steps S7801 to S7807 in the non-specific control clear process, the same processes as steps S7501 to S7507 in the non-specific control clear process (FIG. 110) in the thirty-first embodiment are executed.

  Thereafter, a partial clear process of the work area 223 for non-specific control is executed (step S7808). In the partial clear processing, among the storage areas of the work area 223 for non-specific control, the storage areas other than the storage area where the information of various registers of the main CPU 63 used in the processing corresponding to the specific control is saved Is cleared to “0”. Specifically, among the storage areas of the non-specific control work area 223, the WA buffer, BC buffer, DE buffer, HL buffer, IX buffer, and IY buffer are not cleared to “0”, but other than these various buffers are stored. Clear the area to “0”.

  In this case, all of the normal counter area 231, the open / close execution mode counter area 232, the high frequency support mode counter area 233, the calculation result storage area 234 and the management start flag are cleared to “0”. Thereby, it becomes possible to eliminate the information abnormality in the work area 223 for non-specific control. Further, the processing corresponding to the non-specific control is completed by not clearing the storage area where the information of the various registers of the main CPU 63 used in the processing corresponding to the specific control is saved to “0”. When returning to the process corresponding to the specific control, the information used in the process corresponding to the specific control can be returned to the various registers of the main CPU 63.

  Thereafter, initial setting processing is executed (step S7809). In the initial setting process, initial setting is performed for the storage area that is the target of clearing “0” in step S7808 in the work area 223 for non-specific control.

  Thereafter, a partial clear process of the stack area 224 for non-specific control is executed (step S7810). In the partial clear process, information on the return address of the checksum monitoring process (FIG. 112) after the non-specific control clear process is completed is stored in each storage area of the non-specific control stack area 224. “0” is cleared in storage areas other than the storage area. As a result, the information on the return address in the checksum monitoring process (FIG. 112) after the non-specific control clear process is completed is not erased, and the information abnormality in the non-specific control stack area 224 is detected. Can be eliminated.

  Thereafter, an initial setting process is executed (step S7811). In the initial setting process, initial setting is performed for the storage area that is the target of “0” clear in step S7810 in the stack area 224 for non-specific control.

  Thereafter, the processing of step S7812 to step S7818 is executed. The processes in steps S7812 to S7818 execute the same processes as steps S7510 to S7516 in the clear process for non-specific control (FIG. 110) in the thirty-first embodiment.

  According to the above configuration, the checksum for the work area 221 for specific control and the stack area 222 for specific control, and the checksum for the work area 223 for non-specific control and the stack area 224 for non-specific control Calculated individually. As a result, it is possible to individually specify information abnormality for each of the storage area corresponding to the specific control in the main RAM 65 and the storage area corresponding to the non-specific control in the main RAM 65.

  If there is an abnormality in the checksum for specific control, “0” clear processing and initial setting processing are executed for the work area 221 for specific control and the stack area 222 for specific control, and for non-specific control If there is an abnormality in the checksum, “0” clear processing and initial setting processing are executed for the work area 223 for non-specific control and the stack area 224 for non-specific control. As a result, it is possible to narrow down the targets for executing the “0” clearing process and the initial setting process to the area where the checksum abnormality is specified.

  The process of clearing the work area 221 for specific control and the stack area 222 for specific control to “0” and the process of initial setting are executed in a process corresponding to the specific control, and the work area 223 for non-specific control is designated as “ The process of clearing “0” and the process of initial setting are executed in a process corresponding to non-specific control. As a result, regarding the process of clearing “0” and the initial setting process, the work area 221 for specific control and the stack area 222 for specific control are handled as dedicated storage areas for processes corresponding to the specific control, and are not specified. The control work area 223 can be handled as a dedicated storage area for processing corresponding to non-specific control.

  In step S7808 in the clear process for non-specific control (FIG. 113), the management start flag is cleared to “0”, but the management start flag may not be cleared to “0”. In step S7808 in the clear process for non-specific control (FIG. 113), the normal counter area 231, the open / close execution mode counter area 232, and the high frequency support mode counter area 233 may not be cleared to “0”. The calculation result storage area 234 may not be cleared to “0”.

<Thirty-third embodiment>
In the present embodiment, the processing configuration executed by the main CPU 63 is different from that of the fifteenth embodiment. Hereinafter, a configuration different from the fifteenth embodiment will be described. The description of the same configuration as that of the fifteenth embodiment is basically omitted.

  FIG. 114 is a flowchart showing main processing in the present embodiment, which is executed by the main CPU 63. Note that the processing from step S7901 to step S7924 in the main processing is executed using a program for specific control and data for specific control in the main CPU 63.

  First, power-on initial setting processing is executed (step S7901). In the power-on initial setting process, for example, the process waits without proceeding to the next process until a predetermined time for waiting (specifically, 1 second) elapses after the main process is activated. The operation start and initial setting of the symbol display device 41 are completed in the predetermined period for the wait. In addition, access to the main RAM 65 is permitted.

  Thereafter, an internal function register setting process is executed (step S7902). In the internal function register setting process, the interrupt period of the first timer interrupt process (FIG. 117), which is a process that is activated by periodically interrupting the main process, is set to the first interrupt period (specifically, 4 milliseconds). And the interrupt period of the second timer interrupt process (FIG. 123), which is a process that is periodically interrupted and started with respect to the main process, is a second interrupt period that is shorter than the first interrupt period. (Specifically, 2 milliseconds).

  That is, in the present embodiment, the first timer interrupt process and the second timer interrupt process exist so that the interrupt cycle is relatively short as the timer interrupt process. Both the first timer interrupt process and the second timer interrupt process are started by interrupting the main process. The second timer interrupt process is started by interrupting the first timer interrupt process. On the other hand, the first timer interrupt process is not started by interrupting the second timer interrupt process. Further, when both the first interrupt cycle and the second interrupt cycle have elapsed in a situation where both the first timer interrupt processing and the second timer interrupt processing are not executed, the second timer interrupt processing is performed regardless of the elapsed order of the cycles. It is started first from timer interrupt processing. In this regard, it can be said that the second timer interrupt process is a process activated in preference to the first timer interrupt process.

  In the internal function register setting process, the first interrupt period of the first timer interrupt process is set in a predetermined register of the main CPU 63 and the second interrupt period of the second timer interrupt process is set in a specific register of the main CPU 63 To do. In addition, in the internal function register setting process, in addition to the setting of the first and second interrupt cycles, for example, the setting process of numerical ranges of various counters such as the numerical range of the hit random number counter C1 is executed.

  After that, “1” is set to the startup processing flag provided in the work area 221 for specific control (step S7903). The startup process flag indicates that the first timer interrupt process should be terminated without executing the various processes set in the first timer interrupt process even if the first timer interrupt process is started. Is a flag for specifying the main CPU 63. By setting “1” to the startup processing in progress flag, even if the first timer interrupt process is started, the various processes set in the first timer interrupt process are not executed. Timer interrupt processing will be terminated.

  Thereafter, interrupt permission is set (step S7904). Thus, the first timer interrupt process (FIG. 117) is interrupted and started at the first interrupt cycle, and the second timer interrupt process (FIG. 123) is interrupted and started at the second interrupt period. However, since “1” is set in the startup process flag in step S7903, even if the first timer interrupt process is started, various processes set in the first timer interrupt process are executed. The first timer interrupt process is terminated without any processing.

  Thereafter, it is determined whether or not the reset button 68c is pressed (step S7905). That is, it is determined whether or not the power supply operation of the pachinko machine 10 is performed and the supply of operating power to the MPU 62 is started in a state where the reset button 68c is pressed. Here, in the present embodiment, the main controller 60 is provided with the setting key insertion portion 68a and the reset button 68c, but is not provided with the update button 68b. Further, the main control device 60 is provided with first to fourth notification display devices 201 to 204 as in the eleventh embodiment instead of the first to third notification display devices 69a to 69c.

  If the reset button 68c has not been pressed (step S7905: NO), it is determined whether or not “1” is set in the power failure flag provided in the work area 221 for specific control (step S7906). When a power failure process is executed in a power failure information storage process (step S8202) of a first timer interrupt process (FIG. 117) described later, “1” is set to the power failure flag. The power failure flag is a flag for the main CPU 63 to specify whether or not the power failure processing has been appropriately performed at the time of the previous power shutdown.

  If “1” is set in the power failure flag (step S7906: YES), a checksum is calculated for the work area 221 for specific control and the stack area 222 for specific control (step S7907). The checksum calculation method is arbitrary, but the same calculation method as that used when the checksum is calculated in the power failure information storage process (step S8202) of the first timer interrupt process (FIG. 117) described later. It has become a method. The checksum calculated in the power failure process is stored in the work area 221 for specific control. The storage area of the work area 221 for specific control in which the checksum is stored is used when the checksum is calculated. It is excluded from the storage area to be calculated.

  In other words, when calculating the checksum, the storage area that is a calculation target in the work area 221 for specific control and the stack area 222 for specific control is a calculation target. In the storage area to be calculated, the supply of the operating power to the MPU 62 is resumed after the checksum is calculated in the power failure process when the operating power supply to the MPU 62 is stopped, and the process of step S7907 is executed. Until this is done, when the power supply such as the backup power to the work area 221 for specific control and the stack area 222 for specific control is continued, the information is basically not rewritten. Accordingly, the information on the work area 221 for specific control and the stack area 222 for specific control is not changed after the supply of operating power to the MPU 62 is stopped until the supply of operating power to the MPU 62 is resumed. In this case, the checksum for the work area 221 for specific control and the stack area 222 for specific control is the same as that immediately before the supply of operating power to the MPU 62 is stopped. In addition, in the storage area that is a calculation target when calculating the checksum, an area (specifically, a setting value counter) in which setting value information indicating the setting state of the pachinko machine 10 in the work area 221 for specific control is set. )It is included. The checksum calculation target does not include the work area 223 for non-specific control and the stack area 224 for non-specific control.

  Thereafter, the work area 221 for specific control and the stack area for specific control which are calculated and stored in the work area 221 for specific control calculated in the power failure process executed immediately before the supply of the operating power to the MPU 62 is stopped. The checksum for 222 is read from the work area 221 for specific control, and the read checksum is compared with the checksum calculated in step S7907 (step S7908). Then, it is determined whether or not these checksums match (step S7909).

  When a negative determination is made in step S7906 or S7909, that is, when the power failure flag is not set to "1" or the checksums do not match, the game stop flag provided in the work area 221 for specific control Is set to "1" (step S7910). The game stop flag makes a positive determination in step S8207 in the first timer interrupt process (FIG. 117) described later and stops executing the process of steps S8208 to S8221, that is, the process for proceeding with the game. This is a flag for the main CPU 63 to specify whether or not the situation should be. By setting “1” to the game stop flag, an affirmative determination is made in step S8207 of the first timer interrupt process (FIG. 117) described later, so that the process of steps S8208 to S8221 is not executed. As a result, if the power failure flag is not set to “1” because the power failure process was not properly performed at the time of the previous power shutdown, the progress of the game is stopped and for the specific control. If at least one of the work area 221 and the stack area 222 for specific control does not match the checksum due to a change in the storage state of information since the last power-off, the progress of the game is stopped It becomes a state.

  In this case, in the storage area to be calculated when the checksum is calculated, the setting value information indicating the setting state of the pachinko machine 10 is set in the work area 221 for specific control as described above (specifically, Set value counter). Therefore, if the set value abnormality has occurred after the previous power-off, the checksums do not match, and the progress of the game is stopped.

  On the other hand, even if the game stop flag is set to “1”, the processing from step S8202 to step S8206 in the first timer interrupt processing (FIG. 117) is executed. Therefore, even if the progress of the game is stopped, the power failure monitoring is performed, and the hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated. Fraud detection is performed.

  Thereafter, an abnormality command indicating that an abnormality has occurred with respect to the power failure flag or the checksum at the start of supply of operating power is transmitted to the sound emission control device 81 (step S7911). Upon receiving the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the information abnormality at the start of the supply of operating power, and “change the setting from the speaker unit 54. Is output. In addition, a character image “Please change settings” is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are terminated when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of operating power to the pachinko machine 10 is temporarily stopped, the above notification is issued when the supply of operating power to the pachinko machine 10 is resumed until the set value update process (step S7918) is executed. It is good also as a structure continued.

  The manager of the game hall who confirmed the notification in the situation where the progress of the game is stopped temporarily stops the supply of the operating power to the pachinko machine 10 and then restarts the supply of the operating power to the pachinko machine 10 In the case of performing the setting operation, an operation for performing the setting value update processing (step S7918) is performed. As a result, when an abnormality occurs regarding the power failure flag or the checksum at the start of supply of operating power, a new setting value can be set in the setting value update process (step S7918). .

  In particular, as described above, in the storage area to be calculated when calculating the checksum, an area (specifically, a set value) in which set value information indicating the set state of the pachinko machine 10 is set in the work area 221 for specific control as described above. Counter), if there is an abnormality in the checksum, there is a possibility that an abnormality has occurred in the set value. On the other hand, when an abnormality occurs with respect to the checksum as described above, the execution of the set value update process (step S7918) is prompted to prevent the game from being played with the abnormal set value. It becomes possible to do.

  When “1” is set in the power failure flag and the checksum is normal (step S7906 and step S7909: YES), it is determined whether or not the setting key insertion unit 68a is turned ON using the setting key. Then, it is determined whether or not the front door frame 14 is open with respect to the inner frame 13 and the gaming machine main body 12 is open with respect to the outer frame 11 (step S7913). Whether the front door frame 14 is open or not with respect to the inner frame 13 is detected using the front door opening sensor 95 in the same manner as in the thirtieth embodiment, and the gaming machine main body 12 is The main body opening sensor 96 is used for detecting whether or not the body is in the open state, as in the thirtieth embodiment. The setting key insertion portion 68a is turned ON using the setting key (step S7912: YES), and the front door frame 14 is in an open state with respect to the inner frame 13 and the gaming machine main body with respect to the outer frame 11 When 12 is in an open state (step S7913: YES), a setting confirmation process is executed (step S7914). In the setting confirmation process, the current setting value of the pachinko machine 10 is confirmed on the first to fourth notification display devices 201 to 204 used for displaying various parameters that are management results of the game history. The process for performing the display indicating the current status and the display indicating the current set value of the pachinko machine 10 is executed.

  FIG. 115 is a flowchart showing the setting confirmation process. Note that the processing in steps S8001 to S8003 in the setting confirmation processing is executed using a program for specific control and data for specific control in the main CPU 63.

  First, “1” is set to the setting confirmation display flag provided in the work area 221 for specific control (step S8001). The setting confirmation display flag is a flag for the main CPU 63 to specify that the current setting value of the pachinko machine 10 is being confirmed. When “1” is set in the setting confirmation display flag, the corresponding display control is performed on the first to fourth notification display devices 201 to 204 in the second timer interrupt process (FIG. 123) described later. Is called. Thereby, the display which shows the present setting value of the pachinko machine 10, and the display which shows the present setting value of the pachinko machine 10 in the display devices 201 to 204 for the first to fourth notifications. Is done.

  Thereafter, it is determined whether or not the setting key insertion unit 68a has been turned OFF using the setting key (step S8002). In this case, it may be configured to determine whether the setting key insertion unit 68a has been switched from the ON state to the OFF state, or may be configured to determine whether the setting key insertion unit 68a is in the OFF state. If the setting key insertion unit 68a has not been turned OFF (step S8002: NO), the process of step S8002 is repeated as it is.

  When the setting key insertion unit 68a is turned OFF (step S8002: YES), the setting confirmation display flag in the work area 221 for specific control is cleared to “0” (step S8003). Thereby, the display which shows the present setting value of the pachinko machine 10, and the display which shows the present setting value of the pachinko machine 10 in the display devices 201 to 204 for the first to fourth notifications. Is released. In this case, the first to fourth notification display devices 201 to 204 start displaying the management result of the game history.

  As described above, in the present embodiment, the power on operation of the pachinko machine 10 is performed in a state in which the setting key insertion portion 68a is turned on with the setting key without pressing the reset button 68c, thereby operating power to the main CPU 63. When the reset button 68c is not pressed and the setting key insertion portion 68a is turned on in the situation where the supply of the game is started and the main process is started, the process that allows the game to proceed in the main process is performed. The setting confirmation process is executed in a situation where the process at the start of the supply of operating power, which is the situation before execution, is being executed. This makes it possible to check the set value in a situation where no game is played.

  Assuming the case where the set value is confirmed in a situation where the progress of the game is continued, for example, when the set value is confirmed during the execution of the game round, the set value is being confirmed. May cause the transition to the opening / closing execution mode. In this case, there is a possibility that the game ball cannot be launched toward the special electricity prize winning device 32 in spite of the opening / closing execution mode being started. In addition, when the setting value is confirmed during the execution of the opening / closing execution mode, the opening / closing execution mode proceeds in a situation where the setting value is being confirmed. There is a possibility that the game ball cannot be launched toward the.

  Assuming that the progress of the game is stopped when the set value is confirmed, the progress of the game is stopped halfway when the confirmation of the set value is started in the situation where the game is being performed. There is a risk that the processing will be complicated. For example, if the confirmation of the set value is started in the middle of execution of a game and it is attempted to stop the progress of the game, a process for stopping the game is required. In this case, when the confirmation of the set value is started, the symbol variation display on the symbol display device 41 is stopped halfway, and when the confirmation of the set value is completed, the symbol variation display on the symbol display device 41 is resumed. Attempting to do so requires complicated processing. Further, for example, if the confirmation of the set value is started during the execution of the opening / closing execution mode and the progress of the game is to be stopped halfway, a process for stopping the opening / closing execution mode is required. In addition, when the confirmation of the set value is started in the middle of the execution of the variation display of the picture in the normal map display unit 38a and the progress of the game is stopped halfway, a process for stopping the variation display of the pattern is performed. Necessary. In addition, if the confirmation of the set value is started in the middle of the execution of the open execution state of the power utility 34a and the progress of the game is stopped in the middle, a process for stopping the release execution state in the middle is required. Become. On the other hand, a configuration is also possible in which the set value is confirmed after all the games are completed. There is a need to wait until a state where none of the execution execution states of the object 34a is executed, and there is a possibility that the waiting time until the confirmation of the set value is started becomes long.

  On the other hand, when the supply of operating power to the main CPU 63 is started, the main process that is executed when the operation is started is the state before the process that allows the game to proceed is executed. Since the setting confirmation process is executed in a situation where the process is being executed, the setting value is confirmed in a situation where the progress of the game has already been stopped. This makes it possible to prevent the setting value from being checked while the game is in progress, and to stop the progress of the game when checking the setting value, or to stop the progress of the game. There is no need to wait for confirmation of the set value until Therefore, it is possible to appropriately check the set value.

  Returning to the description of the main process (FIG. 114), when the reset button 68c is pressed (step S7905: YES), a RAM clear process is executed (step S7915). In the RAM clear process, except for an area (specifically, a setting value counter) in which setting value information indicating the setting state of the pachinko machine 10 is set in the work area 221 for specific control, the work area for specific control 221 is cleared to “0” and initial setting is executed. As a result, the area indicating whether or not the lottery mode is the high probability mode is cleared to “0”, so that the lottery regardless of the lottery mode immediately before the supply of the operating power to the pachinko machine 10 is stopped. The mode is a low probability mode. In addition, the game turn is not executed, the opening / closing execution mode is not executed, and the general-purpose display portion 38a is not variably displayed, and the general utility 34a is in a closed state. Situation. In addition, since the hold storage area 65a and the power train hold area 65c provided in the work area 221 for specific control are also cleared to “0”, the hold information for the special figure display section 37a is deleted and the map display section. The hold information for 38a is deleted. In the RAM clear process, the stack area 222 for specific control is cleared to “0” and initial setting is executed. In the RAM clear process, the initial setting is executed after clearing various registers of the main CPU 63 to “0”. In this initial setting, processing similar to the internal function register setting processing (step S7902) in step S7902 is executed.

  On the other hand, in the RAM clear process, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to “0”. Thereby, it is possible to prevent the work area 223 for non-specific control and the stack area 224 for non-specific control from being cleared to “0” by the clear operation by the manager of the game hall.

  Thereafter, it is determined whether or not the setting key insertion portion 68a is turned on using the setting key (step S7916), and the front door frame 14 is open with respect to the inner frame 13 and the outer frame 11 is also opened. It is then determined whether or not the gaming machine main body 12 is in an open state (step S7917). Whether the front door frame 14 is open or not with respect to the inner frame 13 is detected using the front door opening sensor 95 in the same manner as in the thirtieth embodiment, and the gaming machine main body 12 is The main body opening sensor 96 is used for detecting whether or not the body is in the open state, as in the thirtieth embodiment. The setting key insertion portion 68a is turned ON using the setting key (step S7916: YES), and the front door frame 14 is in an open state with respect to the inner frame 13 and the gaming machine main body with respect to the outer frame 11 When 12 is in an open state (step S7917: YES), a set value update process is executed (step S7918).

  FIG. 116 is a flowchart showing the setting value update processing. In addition, the process of step S8101-step S8107 in a setting value update process is performed using the program for specific control in the main side CPU63, and the data for specific control.

  First, “1” is set to the setting update display flag provided in the work area 221 for specific control (step S8101). The setting update display flag is a flag for the main CPU 63 to specify that the setting value of the pachinko machine 10 is being updated. When “1” is set in the setting update display flag, display control corresponding to the second timer interrupt processing (FIG. 123) described later is performed on the first to fourth notification display devices 201 to 204. Is called. Thereby, on the first to fourth notification display devices 201 to 204, a display indicating that the set value of the pachinko machine 10 is being updated and a display indicating the current set value of the pachinko machine 10 are performed. Is called.

  Thereafter, it is determined whether or not the value of the setting value counter provided in the work area 221 for specific control is 1 or more corresponding to “setting 1” and 6 or less corresponding to “setting 6” (step). S8102). If the value of the set value counter is “0” or 7 or more, a negative determination is made in step S8102, and “1” is set in the set value counter (step S8103). Thereby, the setting value of the pachinko machine 10 becomes “setting 1”.

  If an affirmative determination is made in step S8102, or if the process of step S8103 is executed, it is determined whether the setting key insertion unit 68a is turned off using the setting key (step S8104). In this case, it may be configured to determine whether the setting key insertion unit 68a has been switched from the ON state to the OFF state, or may be configured to determine whether the setting key insertion unit 68a is in the OFF state.

  When the setting key insertion portion 68a is not operated to be turned off (step S8104: NO), on condition that the reset button 68c is pressed (step S8105: YES), the set value counter in the work area 221 for specific control Is incremented by 1 (step S8106). As a result, each time the reset button 68c is pressed once, the set value is updated to one level higher. If the reset button 68c is not pressed (step S8105: NO), or if the value of the set value counter is incremented by 1, the process returns to step S8102, but the set value counter is updated in step S8102. If it is determined that the value is 7 or more, “1” is set to the set value counter in step S8103. As a result, when the reset button 68c is pressed once in the state of “setting 6”, the setting returns to “setting 1”.

  When the setting key insertion unit 68a is turned OFF (step S8104: YES), the setting update display flag in the work area 221 for specific control is cleared to “0” (step S8107). Thereby, on the first to fourth notification display devices 201 to 204, a display indicating that the set value of the pachinko machine 10 is being updated and a display indicating the current set value of the pachinko machine 10 are performed. The state to be released is released. In this case, the first to fourth notification display devices 201 to 204 start displaying the management result of the game history.

  As described above, in the present embodiment, when the power-on operation of the pachinko machine 10 is performed while pressing the reset button 68c, the supply of operating power to the main CPU 63 is started and the main process is started. The button 68c is pressed, and the RAM clear process (step S7915) is executed regardless of whether the setting key insertion portion 68a is turned on. Accordingly, the operation content of turning on the power of the pachinko machine 10 while pressing the reset button 68c is uniquely linked to the execution of the RAM clear process (step S7915), and the RAM clear process (step S7915) is performed. The operation content to be generated can be easily understood by the game hall manager.

  Even if the RAM clear process (step S7915) is executed, the set value counter in the work area 221 for specific control is not cleared to “0” and the information of the set value counter is not changed. Thereby, even if the RAM clear process (step S7915) is executed, it is possible to prevent the setting value from being changed.

  RAM clear processing based on not only turning on the power of the pachinko machine 10 while pressing the reset button 68c but also turning on the power of the pachinko machine 10 while turning on the setting key insertion portion 68a with the setting key. Not only (Step S7915) but also the set value update processing (Step S7918) is executed. Further, as described above, the setting confirmation processing (step S7914) is performed based on the power ON operation of the pachinko machine 10 while the setting key insertion portion 68a is turned ON with the setting key without pressing the reset button 68c. Executed. As a result, the ON operation for the setting key insertion unit 68a can be made common as an operation for executing the process related to the setting value. Therefore, it is possible to make the operation content for generating the processing related to the set value easy to understand for the game hall manager.

  Further, when the power-on operation of the pachinko machine 10 is performed while the setting key insertion portion 68a is turned on by the setting key, and the pressing operation of the reset button 68c is not added, the setting confirmation process is executed and the reset is performed. When a pressing operation of the button 68c is added, a set value update process is executed. Accordingly, it is possible to make the execution target process different among the setting confirmation process and the set value update process depending on whether or not the reset button 68c is pressed. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for executing a desired process among the setting confirmation process and the setting value update process. Further, by increasing the operation content for executing the set value update process as compared with the setting confirmation process, it is possible to make it particularly difficult to perform an act of performing the set value update process illegally.

  Returning to the description of the main process (FIG. 114), when the process of step S7911 is executed, when a negative determination is made at step S7912 or step S7913, when the process of step S7914 is executed, negative at step S7916 or step S7917. When the determination is made, or when the process of step S7918 is executed, the startup process flag in the work area 221 for specific control is cleared to “0” (step S7919). By clearing the start processing flag “0”, the state in which various processes set in the first timer interrupt process are not executed even when the first timer interrupt process is started is released. In step S7919, the power failure flag in the work area 221 for specific control is also cleared to “0”.

  Thereafter, a return command is transmitted to the sound emission control device 81 (step S7920). The return command indicates information indicating the number of hold information for the special figure display section 37a, information indicating the current lottery mode, information indicating the current support mode, and whether the open / close execution mode is being executed. Information and information indicating whether or not the game times are being executed are included. These pieces of information are set based on information stored in the work area 221 for specific control. By receiving the return command, the voice light emission control device 81 responds to the various information set in the return command with respect to the display content of the symbol display device 41, the light emission content of the display light emitting unit 53, and the sound output content of the speaker unit 54. The content to be

  Here, when confirming the set value of the pachinko machine 10, it is necessary to turn on the power of the pachinko machine 10 while turning on the setting key insertion portion 68a with the setting key. Then, for example, when it becomes necessary to check the set value during the game round, the power-off operation of the pachinko machine 10 is performed during the game round, and then the setting key insertion portion 68a is set by the setting key. The power ON operation of the pachinko machine 10 is performed while the ON operation is performed. In this case, since the backup power is not supplied to the RAM provided in the sound emission control device 81, the effect for game play in the RAM of the sound emission control device 81 is performed when the power-off operation of the pachinko machine 10 is performed. Information for controlling is deleted. On the other hand, the backup power is supplied to the main RAM 65 and the clearing process of the main RAM 65 is not executed when the set value is confirmed. Therefore, the pachinko machine 10 is turned off during the game round. After that, when the power-on operation of the pachinko machine 10 is performed while the setting key insertion unit 68a is turned on with the setting key, the variation display of the pattern is displayed on the special figure display unit 37a after the setting confirmation processing is executed. Will be resumed. As a result, a situation occurs in which the symbol display is not performed on the symbol display device 41 even though the symbol variation display is performed on the special symbol display unit 37a.

  On the other hand, a return command is transmitted to the sound emission control device 81 after the setting confirmation processing is completed, and the return command includes information indicating whether or not a game round is being executed. When the sound emission control device 81 receives the return command, the symbol display device 41 starts the symbol variation display. Thereby, it is possible to prevent a situation in which the symbol display is not performed on the symbol display device 41 even though the symbol variation display is performed on the special symbol display unit 37a. . This variation display of symbols is performed at a relatively high speed so that each symbol in the variation display is indistinguishable or difficult to identify for the player. Further, the return command does not include the result of the determination process of the game times to be resumed and the result of the distribution determination process, and does not include information indicating the end timing of the game times to be resumed. Therefore, when the sound emission control device 81 starts the variable display of the symbols on the symbol display device 41 based on the return command, if the game number to be resumed corresponds to the result of losing, the next game number is started. When a command to be displayed or a command to be displayed on the demo display is received by the symbol display device 41, the symbol variation display based on the return command is terminated, the display corresponding to the newly received command is started, and the restart target If the game time corresponds to the jackpot result, when the opening command indicating the start of the opening / closing execution mode is received, the symbol variation display based on the return command is terminated and the opening effect is started.

  When the return command includes information indicating that the opening / closing execution mode is being executed, the sound display controller 81 starts a display effect indicating that the opening / closing execution mode is in the symbol display device 41. To be. This makes it possible for the player to recognize that the opening / closing execution mode is being executed.

  Thereafter, the process proceeds to the remaining process of steps S7921 to S7924. That is, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 117) and the second timer interrupt process (FIG. 123), but between one timer interrupt process and the next timer interrupt process. The remaining time will occur. The remaining time varies depending on the processing completion time of each timer interrupt process, but the remaining processes in steps S7921 to S7924 are repeatedly executed using such irregular time. In this regard, it can be said that the remaining processes in steps S7921 to S7924 are non-periodic processes that are performed irregularly. In steps S7921 to S7924, the same processes as those in steps S113 to S116 of the main process (FIG. 9) in the first embodiment are executed.

  Next, the first timer interrupt process executed by the main CPU 63 will be described with reference to the flowchart of FIG. The first timer interrupt process is periodically started at a 4 millisecond period which is the first interrupt period as already described. A program corresponding to the first timer interrupt process is set as a program for specific control.

  First, it is determined whether or not “1” is set in the startup processing flag in the work area 221 for specific control (step S8201). As already described, “1” is set to the startup processing flag in step S7903 of the main processing (FIG. 114). If “1” is set in the startup process flag (step S8201: YES), the first timer interrupt process is terminated without executing the various processes of steps S8202 to S8221. As a result, when the supply of operating power to the pachinko machine 10 is started and the main process (FIG. 114) is started, the execution of the first timer interrupt process and the second timer interrupt process is permitted early. Even if there is, various processes for controlling the progress of the game in the first timer interrupt process until the execution of the process for controlling the progress of the game is permitted after the process at the start of the supply of operating power is completed. It is possible to prevent execution.

  As already described, the startup process flag is cleared to “0” in step S7919 when the process for starting the supply of operating power is completed in the main process (FIG. 114). In the first timer interrupt process, when “1” is not set in the start-up process flag (step S8201: NO), the processes after step S8202 are executed.

  In steps S8202 to S8219 and S8221, the same processing as that in steps S3701 to S3719 of the timer interrupt processing (FIG. 69) in the fifteenth embodiment is executed. These processes are executed by the main CPU 63 using a program for specific control and data for specific control. In this case, as already described, when it is determined in the main process (FIG. 114) that “1” is not set in the power failure flag (step S7906: NO), or when it is determined that the checksums do not match (step S7906). S7909: NO), “1” is set to the game stop flag in the work area 221 for specific control (step S7910). When the game stop flag is set to “1”, the processing of steps S8201 to S8206 is executed in the first timer interrupt processing, but the processing of steps S8208 to S8221 is performed by making an affirmative determination in step S8207. Do not execute. As a result, if the power failure flag is not set to “1” because the power failure process was not properly performed at the time of the previous power shutdown, the progress of the game is stopped and for the specific control. If at least one of the work area 221 and the stack area 222 for specific control does not match the checksum due to a change in the storage state of information since the last power-off, the progress of the game is stopped It becomes a state. For example, the launch of the game ball is prohibited because the process of step S8212 is not executed. Further, the execution of the game times and the opening / closing execution mode is prohibited because the process of step S8214 is not executed. In addition, the payout of the game ball is prohibited because the process of step S8218 is not executed.

  On the other hand, even in the situation where the progress of the game is stopped in this way, the power failure monitoring in step S8202 is executed, and the hit random number counter C1, the big hit type counter C2, the reach random number counter C3 in steps S8203 and S8204. Then, the random number initial value counter CINI is updated, and the fraud detection in step S8206 is performed.

  In the first timer interrupt process, a setting monitoring process is executed in step S8220. FIG. 118 is a flowchart showing the setting monitoring process. Note that the processing from step S8301 to step S8303 in the setting monitoring processing is executed using a program for specific control and data for specific control in the main CPU 63.

  It is determined whether or not the set value of the pachinko machine 10 is normal by checking the value of the set value counter in the work area 221 for specific control (step S8301). Specifically, it is determined to be normal when the set value set in the set value counter is any of “setting 1” to “setting 6”, and abnormal when it is “0” or 7 or more. Judge that there is.

  If the set value is abnormal (step S8301: NO), similarly to step S7910 in the main process (FIG. 114), “1” is set to the game stop flag in the work area 221 for specific control (step S8302). When “1” is set in the game stop flag, an affirmative determination is made in step S8207 of the first timer interrupt process (FIG. 117), so that the process of steps S8208 to S8221 is not executed. Thereby, when it is specified that the set value is abnormal, the progress of the game is stopped. On the other hand, even if the game stop flag is set to “1”, the process from step S8202 to step S8206 in the first timer interrupt process (FIG. 117) is executed, so the progress of the game is stopped. Even in such a situation, the power failure monitoring is performed, and the hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and further fraud detection is performed.

  Thereafter, an abnormal command indicating that the set value is abnormal is transmitted to the sound emission control device 81 (step S8303). Upon receiving the abnormal command, the voice light emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to the set value abnormality, and outputs a voice “Please change setting” from the speaker unit 54. . In addition, a character image “Please change settings” is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are terminated when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of operating power to the pachinko machine 10 is temporarily stopped, the supply of operating power to the pachinko machine 10 is resumed until the set value update process (step S7918) of the main process (FIG. 114) is executed. It is good also as a structure by which the said alerting | reporting is continued when it is made.

  The manager of the game hall who confirmed the notification in the situation where the progress of the game is stopped temporarily stops the supply of the operating power to the pachinko machine 10 and then restarts the supply of the operating power to the pachinko machine 10 In the case of performing the setting operation, an operation for performing the setting value update processing (step S7918) is performed. As a result, when a set value abnormality occurs, a new set value can be set in the set value update process (step S7918).

  Here, the monitoring process of whether or not the set value is abnormal is executed in the first timer interrupt process (FIG. 117) that is periodically started. This makes it possible to monitor whether or not the set value is abnormal even in a situation where a game is being performed. Therefore, it is possible to prevent the game from continuing even though the set value is abnormal. Also, monitoring whether the set value is abnormal is executed every time a monitoring trigger occurs. Thereby, it becomes possible to increase the frequency of monitoring whether or not the set value is abnormal.

  In the main process (FIG. 114), a process for monitoring whether or not the set value is normal is not set. If a process for monitoring whether or not the set value is normal is set in the process at the start of supply of operating power in the main process (FIG. 114), a power failure flag and checksum are set at the start of supply of operating power. In addition to monitoring, it is necessary to monitor whether or not the set value is normal, which increases the monitoring load. Further, when it is specified that the set value is abnormal at the start of supply of operating power, if the RAM clear process (step S7915) and the set value update process (step S7918) are attempted to be executed, the processing configuration accordingly. Will be complicated. On the other hand, since the process for monitoring whether the set value is normal is not set in the main process (FIG. 114), the processing configuration of the process at the start of supply of operating power is preferable. It becomes possible. Even if the process for monitoring whether the set value is normal is not set in the process at the start of supply of operating power in this way, the first timer interrupt process (FIG. 117) is performed as described above. Therefore, when the setting value is abnormal, it is possible to cope with the setting monitoring process (step S8220).

  In the configuration in which the first timer interrupt process is executed as described above, the second timer interrupt process (FIG. 123) is performed separately from the first timer interrupt process (FIG. 117) as the timer interrupt process as already described in the present embodiment. In addition, the second timer interrupt process is activated by interrupting the first timer interrupt process even during the execution of the first timer interrupt process. In this case, although illustration is omitted in the first timer interrupt process, the timer interrupt process is prohibited and the timer interrupt process is permitted before and after each process in steps S8201 to S8221. For example, the timer interrupt process is prohibited before the lottery random number update process (step S8203) is executed, and the timer interrupt process is allowed after the lottery random number update process (step S8203) is executed. As a result, it is possible to prevent the second timer interrupt process from being interrupted and started during the lottery random number update process. Also, the timer interrupt process is prohibited before executing the special figure special power control process (step S8214), and the timer interrupt process is permitted after executing the special figure special electric control process (step S8214). As a result, it is possible to prevent the second timer interrupt process from being interrupted and started during the execution of the special figure special electric control process.

  Next, a configuration for controlling display of various display units by the main CPU 63 will be described. FIG. 119 is a block diagram for explaining a configuration for controlling display of various display units by the main CPU 63.

  As a target on which display control is performed by the main CPU 63, a special map display unit 37a, a special map hold display unit 37b, a general map display unit 38a, a general map hold display unit 38b, and first to fourth notification display devices 201 to 201. 204 exists. These are all provided as a segment display section in which a plurality of display segments using LEDs are arranged. These segment display units are set to light emission state by setting data corresponding to the light emission state (for example, “1” data which is one of the binary data), and data corresponding to the light-off state (for example, binary data). When the other data “0” is set, the light is turned off.

  The main control board 61 is provided with a first display circuit 261 corresponding to the special figure display unit 37a, and a second display circuit 262 corresponding to the special figure display unit 37b. A third display circuit 263 is provided corresponding to the display unit 38a, a fourth display circuit 264 is provided corresponding to the general-purpose hold display unit 38b, and the first to fourth notification display devices 201- A fifth display circuit 265 is provided in correspondence with 204. In the eleventh embodiment, the main control board 61 is provided with the first to fourth display ICs 205 to 208 in a one-to-one correspondence with the first to fourth notification display devices 201 to 204. However, in the present embodiment, these first to fourth display ICs 205 to 208 are not provided.

  The first display circuit 261 provides data corresponding to the supplied display data to each of the plurality of display segments of the special figure display unit 37a. Thereby, each display segment of the special figure display part 37a will be in a light emission state or a light extinction state in the aspect corresponding to the display data provided to the 1st display circuit 261. In this case, the first display circuit 261 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but the display data gradually becomes all “0” when the predetermined period elapses. It will approach the state of. Accordingly, the display segment of the special figure display unit 37a that is in the light emission state by the display data provided to the first display circuit 261 passes a predetermined period without providing new display data to the first display circuit 261. This will gradually turn off the lights. Further, the display data output process of the previous display data is not only performed when the display content of the special figure display unit 37a is changed but also when the display content of the special figure display unit 37a is not changed. The same display data as the first time is supplied to the first display circuit 261.

  The number of display segments provided in the special figure display unit 37a is eight. Therefore, 8-bit data is provided to the first display circuit 261 as display data for display control of the special figure display unit 37a.

  The second display circuit 262 provides data corresponding to the supplied display data to each of the plurality of display segments of the special figure hold display unit 37b. Thereby, each display segment of the special figure hold display unit 37b is in a light emitting state or a light-off state in a manner corresponding to the display data provided to the second display circuit 262. In this case, the second display circuit 262 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but the display data gradually becomes all “0” when the predetermined period elapses. It will approach the state of. Therefore, the display segment of the special figure hold display unit 37b that is in a light emitting state by the display data provided to the second display circuit 262 has a predetermined period without new display data being provided to the second display circuit 262. As time elapses, the light is gradually turned off. In addition, because of such a configuration, not only when the display content of the special figure hold display unit 37b is changed but also when the display content of the special figure hold display unit 37b is not changed, the previous display data The same display data as the output processing times is supplied to the second display circuit 262.

  The number of display segments provided in the special figure hold display section 37b is four. Therefore, 4-bit data is provided to the second display circuit 262 as display data for display control of the special figure hold display section 37b. However, since the display data is provided in units of 8 bits, 8-bit data is also provided when the display data is provided to the second display circuit 262. Of these, 4 bits are provided in the special figure hold display section. 37b is used as display data for display control.

  The third display circuit 263 provides data corresponding to the supplied display data to each of the plurality of display segments of the general-purpose display unit 38a. As a result, each display segment of the general-purpose display unit 38a is turned on or off in a manner corresponding to the display data provided to the third display circuit 263. In this case, the third display circuit 263 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but when the predetermined period elapses, the display data gradually becomes all “0”. It will approach the state of. Accordingly, the display segment of the general-purpose display unit 38a that is in a light emitting state by the display data provided to the third display circuit 263 has passed a predetermined period without new display data being provided to the third display circuit 263. This will gradually turn off the lights. Further, the display data output process of the previous display data is not only performed when the display content of the general map display unit 38a is changed but also when the display content of the general map display unit 38a is not changed. The same display data as the first time is supplied to the third display circuit 263.

  The number of display segments provided in the general-purpose display unit 38a is eight. Therefore, 8-bit data is provided to the third display circuit 263 as display data for controlling the display of the general-purpose display unit 38a.

  The fourth display circuit 264 provides data corresponding to the supplied display data to each of the plurality of display segments of the general-purpose hold display unit 38b. Thereby, each display segment of the general-purpose hold display unit 38b is turned on or off in a manner corresponding to the display data provided to the fourth display circuit 264. In this case, the fourth display circuit 264 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but when the predetermined period elapses, the display data gradually becomes all “0”. It will approach the state of. Accordingly, the display segment of the general-purpose hold display unit 38b that is in a light emitting state by the display data provided to the fourth display circuit 264 has a predetermined period of time without new display data being provided to the fourth display circuit 264. As time elapses, the light is gradually turned off. Further, with this configuration, not only when the display content of the general map hold display unit 38b is changed but also when the display content of the general map hold display unit 38b is not changed, The same display data as the output processing times is supplied to the fourth display circuit 264.

  The number of display segments provided in the general map hold display section 38b is four. Therefore, 4-bit data is provided to the fourth display circuit 264 as display data for display control of the general-purpose hold display unit 38b. However, since the display data is provided in units of 8 bits, 8-bit data is also provided when display data is provided to the fourth display circuit 264. Of these, 4 bits are used for the reserved display section. 38b is used as display data for display control.

  The fifth display circuit 265 provides data corresponding to the supplied display data to each of the plurality of display segments provided in each of the first to fourth notification display devices 201 to 204. As a result, the display segments of the first to fourth notification display devices 201 to 204 are turned on or off in a manner corresponding to the display data provided to the fifth display circuit 265. In this case, the fifth display circuit 265 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but when the predetermined period elapses, the display data gradually becomes all “0”. It will approach the state of. Accordingly, new display data is provided to the fifth display circuit 265 in the display segments of the first to fourth notification display devices 201 to 204 that are in a light emitting state by the display data provided to the fifth display circuit 265. The light is gradually turned off when the predetermined period has passed. In addition, the display content of the first to fourth notification display devices 201 to 204 is changed not only when the display content of the first to fourth notification display devices 201 to 204 is changed. Even if not, the same display data as the previous display data output process is supplied to the fifth display circuit 265.

  Each of the first to fourth notification display devices 201 to 204 is provided with seven display segments. On the other hand, display data is provided in units of 8 bits. When the display data of the first to fourth notification display devices 201 to 204 is provided to the fifth display circuit 265, the 7-bit display data corresponding to the first notification display device 201 is provided as 8-bit data. Thereafter, 7-bit display data corresponding to the second notification display device 202 is provided as 8-bit data, and thereafter, 7-bit display data corresponding to the third notification display device 203 is provided in 8-bit units. Finally, 7-bit display data corresponding to the fourth notification display device 204 is provided as 8-bit data.

  In the configuration in which the first to fifth display circuits 261 to 265 are provided as described above, the main CPU 63 supplies display data to the display IC 266. That is, the display ICs 266 are not provided on the first to fifth display circuits 261 to 265 on a one-to-one basis, but are provided so as to be common to all the first to fifth display circuits 261 to 265. The display IC 266 is provided. When the main CPU 63 supplies display data to the display IC 266, the main CPU 63 also supplies type data indicating which of the first to fifth display circuits 261 to 265 corresponds to the display data to the display IC 266.

  The electrical connection between the main CPU 63 and the display IC 266 will be described in detail. The main CPU 63 and the display IC 266 include the type data signal line LN1, the type clock signal line LN2, the display data signal line LN3, and the display clock signal. It is electrically connected using the line LN4. These signal lines LN1 to LN4 are all signal lines for transmitting signals from the main CPU 63 to the display IC 266 by one-way communication.

  The classification data is transmitted from the main CPU 63 to the display IC 266 by serial communication using the classification data signal line LN1. In this case, each 1-bit segment of classification data by serial communication is indicated by a classification clock signal transmitted from the main CPU 63 to the display IC 266 using the classification clock signal line LN2. The type data is data indicating which of the first to fifth display circuits 261 to 265 corresponds to the display data to be transmitted. The type data is transmitted as 5-bit data consisting of the first to fifth bits. When the display data corresponds to the first display circuit 261, the first bit is at the HI level and the other bits are at the LOW level. When the display data corresponds to the second display circuit 262, the second bit is at the HI level and the other bits are at the LOW level. When the display data corresponds to the third display circuit 263, the third bit is at the HI level and the other bits are at the LOW level. When the display data corresponds to the fourth display circuit 264, the fourth bit is at the HI level and the other bits are at the LOW level. When the display data corresponds to the fifth display circuit 265, the fifth bit is at the HI level and the other bits are at the LOW level.

  Display data is transmitted from the main CPU 63 to the display IC 266 by serial communication using the display data signal line LN3. In this case, each 1-bit break of display data by serial communication is indicated by a display clock signal transmitted from the main CPU 63 to the display IC 266 using the display clock signal line LN4. The display data is transmitted in units of 8 bits by the 1st to 8th bits.

  The main CPU 63 transmits display data corresponding to each of the first to fifth display circuits 261 to 265 to the display IC 266 in a second timer interrupt process (FIG. 123) described later. In this case, display data is transmitted to one of the first to fifth display circuits 261 to 265 in one processing time of the second timer interrupt process, and the nth display circuit → the n + 1th display. The display circuits 261 to 265 to which display data is to be transmitted are changed one by one each time a new processing time of the second timer interrupt processing occurs according to the order of the circuits. Further, in the second timer interrupt processing in the processing time subsequent to the processing time for transmitting the display data corresponding to the fifth display circuit 265 that is the last order in the order, the first display circuit 261 that is the first order in the order. Display data corresponding to is sent. Note that, in the processing time of the second timer interrupt processing for transmitting display data to any one of the first to fourth display circuits 261 to 264, only one piece of display data in units of 8 bits is transmitted, but the fifth display circuit 265 is used. In the processing time of the second timer interrupt process for transmitting the display data, four pieces of display data in units of 8 bits are transmitted corresponding to the number of the first to fourth notification display devices 201 to 204.

  In the configuration in which the main CPU 63 transmits display data as described above, various storage areas referred to by the main CPU 63 for transmitting display data to the work area 221 for specific control and the work area 223 for non-specific control. Is set. 120A is an explanatory diagram for explaining various buffers 271 to 275 provided in the work area 221 for specific control, and FIG. 120B is provided in the work area 223 for non-specific control. It is explanatory drawing for demonstrating the various storage areas 234,276.

  As shown in FIG. 120A, the work area 221 for specific control includes a first display data buffer 271, a second display data buffer 272, a third display data buffer 273, a fourth display data buffer 274, A fifth display data buffer 275 is provided.

  Display data to be supplied to the first display circuit 261 is stored in the first display data buffer 271. Since the first display circuit 261 is provided corresponding to the special figure display unit 37a as described above, the first display data buffer 271 has display data for causing the special figure display unit 37a to perform a predetermined display. Will be stored. In this case, the display data is stored in the first display data buffer 271 in the display control process (step S 8216) based on the contents of the special figure special electric control process (step S 8214) in the first timer interrupt process (FIG. 117). . Further, when the second timer interrupt process (FIG. 123) for transmitting display data to the first display circuit 261 is reached, only when the display data stored in the first display data buffer 271 is changed. Instead, even if the display data is not changed, the display data stored in the first display data buffer 271 is transmitted to the display IC 266.

  Display data to be supplied to the second display circuit 262 is stored in the second display data buffer 272. Since the second display circuit 262 is provided in correspondence with the special figure hold display unit 37b as described above, the second display data buffer 272 has a display for causing the special figure hold display unit 37b to perform a predetermined display. Data will be stored. In this case, display data is stored in the second display data buffer 272 in the display control process (step S 8216) based on the contents of the special figure special power control process (step S 8214) in the first timer interrupt process (FIG. 117). . In addition, when the second timer interrupt process (FIG. 123) for transmitting display data to the second display circuit 262 is reached, only when the display data stored in the second display data buffer 272 is changed. Instead, even when the display data is not changed, the display data stored in the second display data buffer 272 is transmitted to the display IC 266.

  Display data to be supplied to the third display circuit 263 is stored in the third display data buffer 273. Since the third display circuit 263 is provided corresponding to the universal map display unit 38a as described above, the third display data buffer 273 has display data for causing the universal map display unit 38a to perform a predetermined display. Will be stored. In this case, the display data is stored in the third display data buffer 273 in the display control process (step S 8216) based on the contents of the general power control process (step S 8215) in the first timer interrupt process (FIG. 117). Is called. Further, when the second timer interrupt process (FIG. 123) for transmitting display data to the third display circuit 263 is reached, only when the display data stored in the third display data buffer 273 is changed. Instead, even when the display data is not changed, the display data stored in the third display data buffer 273 is transmitted to the display IC 266.

  The fourth display data buffer 274 stores display data to be supplied to the fourth display circuit 264. As described above, the fourth display circuit 264 is provided in correspondence with the general map hold display unit 38b. Therefore, the fourth display data buffer 274 has a display for causing the general map hold display unit 38b to perform a predetermined display. Data will be stored. In this case, display data is stored in the fourth display data buffer 274 in the display control process (step S 8216) based on the contents of the general power control process (step S 8215) in the first timer interrupt process (FIG. 117). Is called. Further, when the second timer interrupt process (FIG. 123) for transmitting display data to the fourth display circuit 264 is reached, only when the display data stored in the fourth display data buffer 274 is changed. Instead, even when the display data is not changed, the display data stored in the fourth display data buffer 274 is transmitted to the display IC 266.

  The fifth display data buffer 275 stores display data to be supplied to the fifth display circuit 265. Since the fifth display circuit 265 is provided corresponding to the first to fourth notification display devices 201 to 204 as already described, the fifth display data buffer 275 includes the first to fourth notification display devices 201. Display data for making the predetermined data displayed in .about.204 is stored. When the processing time of the second timer interrupt processing for transmitting display data to the fifth display circuit 265 is reached, not only the display data stored in the fifth display data buffer 275 is changed, but also the display data. Even if no change has been made, the display data stored in the fifth display data buffer 275 is transmitted to the display IC 266.

  Here, in the first to fourth notification display devices 201 to 204, display corresponding to the management result of the game history is performed, and the setting confirmation processing (FIG. 115) or the setting value update processing (FIG. 116) is executed. Display corresponding to the current set value. In this case, since the fifth display data buffer 275 is provided in the work area 221 for specific control, the process of storing the display data in the fifth display data buffer 275 is performed as a process corresponding to the specific control. On the other hand, the process for deriving the management result of the game history is performed as a process corresponding to the non-specific control, and the 61st to 68th parameters which are the management result of the game history are the first to fourth notification display devices. In 201-204, it becomes a display object sequentially.

  Therefore, as shown in FIG. 120B, not only the calculation result storage area 234 for storing the 61st parameter to the 68th parameter but also the 61st parameter to the 68th parameter in the work area 223 for non-specific control. Among these, a display target setting area 276 for storing parameters to be displayed on the first to fourth notification display devices 201 to 204 is provided. Even in this embodiment, since the calculation result of one parameter is continuously displayed for 10 seconds as in the fifteenth embodiment, the processing corresponding to non-specific control is 10 seconds. Whenever the second elapses, the calculation result of the parameter to be displayed is read from the calculation result storage area 234 in accordance with a predetermined display order, and the calculation result of the read parameter is stored in the display target setting area 276. The When the game history management results are displayed on the first to fourth notification display devices 201 to 204, the second timer interrupt process (FIG. 123) is a process corresponding to the specific control. The display data stored in the display target setting area 276 is read out, and the read display data is stored in the fifth display data buffer 275.

  On the other hand, when the setting confirmation process (FIG. 115) is being executed, the first to fourth notification displays are performed in the second timer interrupt process (FIG. 123), which is a process corresponding to the specific control. The display data for displaying that the current setting values of the pachinko machine 10 are being confirmed in the devices 201 to 204 and the display showing the current setting values of the pachinko machine 10 are the fifth. Stored in the display data buffer 275. When the setting value update process (FIG. 116) is being executed, the first to fourth notification displays are performed in the second timer interrupt process (FIG. 123), which is a process corresponding to the specific control. The display data for displaying that the setting values of the pachinko machine 10 are being updated in the devices 201 to 204 and the display showing the current setting values of the pachinko machine 10 are the fifth display data. Stored in the buffer 275.

  In the configuration in which the first to fifth display data buffers 271 to 275 are provided as described above, the main CPU 63 performs display data corresponding to the processing times in each processing time of the second timer interrupt processing (FIG. 123). The display data is read from the buffers 271 to 275, the read display data is transmitted to the display IC 266, and type data indicating which of the first to fifth display circuits 261 to 265 corresponds to the display data. The data is transmitted to the display IC 266. FIG. 121 is an explanatory diagram for describing an electrical configuration of the display IC 266.

  As shown in FIG. 121, the display IC 266 includes a type data buffer 281, a selection signal output unit 282, a display data buffer 283, and a display data output unit 284. Display data received from the main CPU 63 is stored in the display data buffer 283. The display data output unit 284 transmits the display data stored in the display data buffer 283 to the first to fifth display circuits 261 to 265. The type data buffer 281 stores type data received from the main CPU 63. The selection signal output unit 282 is a selection signal for designating the display circuits 261 to 265 corresponding to the classification data stored in the classification data buffer 281 among the first to fifth display circuits 261 to 265 as the reception destination of the display data. Is output.

  Specifically, as shown in FIG. 119, the display IC 266 and the first display circuit 261 are electrically connected using a display signal group 291. The display signal group 291 is provided so that 8-bit display data can be transmitted at a time, and the display data in units of 8 bits is transmitted from the display IC 266 by parallel communication. A branch signal group 292 is provided by branching from the display signal group 291. The branch signal group 292 includes the second display circuit 262, the third display circuit 263, the fourth display circuit 264, and the fifth display circuit 265. Are electrically connected to each of the. Similar to the display signal group 291, the branch signal group 292 is provided so that 8-bit display data can be transmitted at a time. Display data in units of 8 bits is transmitted from the display IC 266 by parallel communication. The

  By providing the display signal group 291 and the branch signal group 292 as described above, when the display data stored in the display data buffer 283 is transmitted by the display data output unit 284, the display data is the first data. To all of the fifth display circuits 261 to 265. In this case, first to fifth selection signal lines 301 to 305 are provided to specify display circuits 261 to 265 to receive and use the supplied display data.

  The first selection signal line 301 is provided so as to electrically connect the display IC 266 and the first display circuit 261. When the type data corresponding to the first display circuit 261 is stored in the type data buffer 281, the display data supplied from the display data output unit 284 is received by the first display circuit 261 and used. The selection signal output unit 282 of the display IC 266 transmits the first selection signal to the first display circuit 261 through the first selection signal line 301. Accordingly, display data supplied to all of the first to fifth display circuits 261 to 265 through the display signal group 291 and the branch signal group 292 is received and used only by the first display circuit 261.

  The second selection signal line 302 is provided so as to electrically connect the display IC 266 and the second display circuit 262. When the type data corresponding to the second display circuit 262 is stored in the type data buffer 281, the display data supplied from the display data output unit 284 is received by the second display circuit 262 and used. The selection signal output unit 282 of the display IC 266 transmits the second selection signal to the second display circuit 262 through the second selection signal line 302. Accordingly, display data supplied to all of the first to fifth display circuits 261 to 265 through the display signal group 291 and the branch signal group 292 is received and used only by the second display circuit 262.

  The third selection signal line 303 is provided so as to electrically connect the display IC 266 and the third display circuit 263. When the type data corresponding to the third display circuit 263 is stored in the type data buffer 281, the display data supplied from the display data output unit 284 is received by the third display circuit 263 and used. The selection signal output unit 282 of the display IC 266 transmits the third selection signal to the third display circuit 263 through the third selection signal line 303. Thus, display data supplied to all of the first to fifth display circuits 261 to 265 through the display signal group 291 and the branch signal group 292 is received and used only by the third display circuit 263.

  The fourth selection signal line 304 is provided to electrically connect the display IC 266 and the fourth display circuit 264. When the type data corresponding to the fourth display circuit 264 is stored in the type data buffer 281, the display data supplied from the display data output unit 284 is received by the fourth display circuit 264 and used. The selection signal output unit 282 of the display IC 266 transmits the fourth selection signal to the fourth display circuit 264 through the fourth selection signal line 304. Accordingly, display data supplied to all of the first to fifth display circuits 261 to 265 through the display signal group 291 and the branch signal group 292 is received and used only by the fourth display circuit 264.

  The fifth selection signal line 305 is provided to electrically connect the display IC 266 and the fifth display circuit 265. When the type data corresponding to the fifth display circuit 265 is stored in the type data buffer 281, the display data supplied from the display data output unit 284 is received by the fifth display circuit 265 and used. The selection signal output unit 282 of the display IC 266 transmits the fifth selection signal to the fifth display circuit 265 through the fifth selection signal line 305. Accordingly, display data supplied to all of the first to fifth display circuits 261 to 265 through the display signal group 291 and the branch signal group 292 is received and used only by the fifth display circuit 265.

  122 shows that the type data and the display data are transmitted from the main CPU 63 to the display IC 266, and the display data transmitted from the display IC 266 is received by the first display circuit 261 or the second display circuit 262. It is a time chart. 122A shows a transmission period of the type data signal from the main CPU 63 to the display IC 266, and FIG. 122B shows a transmission period of the type clock signal from the main CPU 63 to the display IC 266. FIG. ) Shows the transmission period of the display data signal from the main CPU 63 to the display IC 266, FIG. 122 (d) shows the transmission period of the display clock signal from the main CPU 63 to the display IC 266, and FIG. 122 (e) shows the display IC 266. 122 (f) shows the transmission period of the first selection signal from the display IC 266 to the first display circuit 261, FIG. 122 (f) shows the transmission period of the second selection signal from the display IC 266 to the second display circuit 262, and FIG. A display data transmission period from the display IC 266 to the first to fifth display circuits 261 to 265 is shown. The same applies to the case where display data is received by the third to fifth display circuits 263 to 265.

  Type data from the main CPU 63 to the display IC 266 at the timing t1 after the supply of operating power to the pachinko machine 10 including the main CPU 63, the display IC 266, and the first to fifth display circuits 261 to 265 is started. And transmission of display data is started. Specifically, as shown in FIG. 122B, a pulse type clock signal is transmitted at each of timings t1, t2, t3, t4, and t5. As shown in (a), the pulse type data signal is transmitted in correspondence with the transmission of the pulse type clock signal at the timing t1. Thereby, information corresponding to the first display circuit 261 is stored in the type data buffer 281 of the display IC 266.

  In addition, as shown in FIG. 122 (d), a pulsed display clock at each of the timing t1, timing t2, timing t3, timing t4, timing t5, timing t6, timing t7, and timing t8. As shown in FIG. 122 (c), a pulsed display data signal is transmitted in correspondence with transmission of a pulsed display clock signal at timings t2, t3, t5, and t7. Is sent. As a result, display data corresponding to the information form is stored in the display data buffer 283 of the display IC 266.

  When the transmission of the display clock signal of the 8th bit is completed at the timing of t9 as shown in FIG. 122 (d), the type data buffer 281 is stored at the timing of the t9 as shown in FIG. 122 (e). As shown in FIG. 122 (g), transmission of the first selection signal is started by the selection signal output unit 282 of the display IC 266 toward the first display circuit 261 corresponding to the stored type data, and at the timing t9. Then, the display data output unit 284 of the display IC 266 starts transmission of the display data stored in the display data buffer 283. Thereby, the display data is received and used by the first display circuit 261.

  Thereafter, at timing t10, as shown in FIGS. 122A to 122D, transmission of type data and display data from the main CPU 63 to the display IC 266 is newly started. In this case, at the timing t10, transmission of the first selection signal from the display IC 266 to the first display circuit 261 is stopped as shown in FIGS. 122 (e) and 122 (g), and the display IC 266 Transmission of display data toward the first to fifth display circuits 261 to 265 is stopped.

  For details on the new transmission of the type data and the display data, as shown in FIG. 122 (b), a pulse type clock at each of the timing t10, the timing t11, the timing t12, the timing t13, and the timing t14 is shown. A signal is transmitted, and a pulse type data signal is transmitted in correspondence with the transmission of the pulse type clock signal at the timing t11 as shown in FIG. 122 (a). Thus, information corresponding to the second display circuit 262 is stored in the type data buffer 281 of the display IC 266.

  In addition, as shown in FIG. 122 (d), a pulsed display clock at each of the timing t10, the timing t11, the timing t12, the timing t13, the timing t14, the timing t15, the timing t16, and the timing t17. As shown in FIG. 122 (c), it corresponds to transmission of a pulsed display clock signal at timing t10, timing t11, timing t12, timing t15, timing t16, and timing t17. Thus, a pulsed display data signal is transmitted. As a result, display data corresponding to the information form is stored in the display data buffer 283 of the display IC 266.

  Then, when the transmission of the 8-bit display clock signal is completed as shown in FIG. 122 (d) at the timing of t18, it is stored in the type data buffer 281 as shown in FIG. 122 (f) at the timing of t18. As shown in FIG. 122 (g), transmission of the second selection signal is started by the selection signal output unit 282 of the display IC 266 toward the second display circuit 262 corresponding to the type data, and at the timing t18. Transmission of display data stored in the display data buffer 283 is started by the display data output unit 284 of the display IC 266. Thereby, the display data is received and used by the second display circuit 262.

  For the first to fourth display circuits 261 to 264, only one display data is transmitted in the second timer interrupt process (FIG. 123) that is a display data transmission target. In the second timer interrupt process (FIG. 123) that is the display data transmission target, four display data are transmitted in correspondence with the number of the first to fourth notification display devices 201 to 204. As described above, the second timer interrupt process (FIG. 123) is started in the second interrupt cycle (specifically, 2 milliseconds). Each processing time is set so that one processing time is completed within the second interrupt cycle.

  With the above configuration, display data can be transmitted to the plurality of display circuits 261 to 265 using one display IC 266. Here, as described above, each of the first to fifth display circuits 261 to 265 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but the predetermined period has elapsed. Then, the display data gradually approaches the state of all “0”. In this case, if the display data is received by the display circuits 261 to 265 for a predetermined period, the special figure display unit 37a, the special figure hold display unit 37b, the general figure display unit 38a, the general figure hold display unit 38b, Even if the display contents are not changed in the first to fourth notification display devices 201 to 204, the display segment that is in the light emitting state temporarily approaches the light-off state, and as a result, the light in the display segment May blink. On the other hand, in the present embodiment, apart from the first timer interrupt process (FIG. 117) started in the first interrupt cycle (specifically, 4 milliseconds), the second interrupt shorter than the first interrupt cycle. A second timer interrupt process (FIG. 123) activated at a cycle (specifically, 2 milliseconds) is set, and transmission of display data to the display IC 266 is collectively performed in the second timer interrupt process. .

  Hereinafter, the second timer interrupt process will be described with reference to the flowchart of FIG. Note that the processing from step S8401 to step S8413 in the second timer interrupt processing is executed using the specific control program and the specific control data in the main CPU 63.

  First, in order to prohibit the generation of the first timer interrupt process (FIG. 117) and the second timer interrupt process (FIG. 123), an interrupt prohibition is set (step S8401). By prohibiting the generation of the first timer interrupt process (FIG. 117), the first timer interrupt process (FIG. 117) interrupts the second timer interrupt process (FIG. 123) even if the first interrupt cycle elapses. It becomes possible not to be started by. In addition, if the second timer interrupt process (FIG. 123) is inhibited, even if the second interrupt cycle elapses during the execution of the second timer interrupt process (FIG. 123), the second timer interrupt process is performed. It is possible to prevent the processing (FIG. 123) from being activated twice.

  Thereafter, it is determined whether or not “1” is set in the setting update display flag in the work area 221 for specific control (step S8402). The setting update display flag is a flag for specifying in the main CPU 63 whether or not the main CPU 63 is executing the setting value update processing (FIG. 116). As already described, the setting value update process (FIG. 116) is a situation where the process at the start of the supply of operating power is being executed in the main process (FIG. 114) when the supply of operating power to the main CPU 63 is started. Although the second timer interrupt process (FIG. 123) will be executed, it is interrupted and activated even when the process at the start of supplying the operating power is being executed. Even in the situation where the value update process (FIG. 116) is being executed, the second timer interrupt process (FIG. 123) is interrupted and activated.

  The situation where the setting update display flag is set to “1” means that the current processing time of the second timer interrupt process (FIG. 123) is the setting value update process (FIG. 116) being executed by the main CPU 63. It means that the process has been started by interrupting the situation. If an affirmative determination is made in step S8402, the setting process for the fifth display data buffer 275 during the setting update is executed (step S8403). In the setting process, a display indicating that the setting value of the pachinko machine 10 is being updated in the first to fourth notification display devices 201 to 204 and a display indicating the current setting value of the pachinko machine 10 are displayed. Display data for execution is stored in the fifth display data buffer 275.

  When the display data stored in the fifth display data buffer 275 is transmitted to the fifth display circuit 265 via the display IC 266, the first to fourth notification display devices 201 to 204 will be described with reference to FIG. The display shown in the figure is performed. Specifically, when a display indicating that the setting value is being updated in the first to fourth notification display devices 201 to 204 is performed, the first to fourth notification display devices 201 to 204 are displayed. In each case, at least one display segment is in a light emitting state. That is, each of the first to fourth notification display devices 201 to 204 is in a display state. Thereby, even if it is a case where the display which shows that it is the condition which is updating the setting value is performed, it will be confirmed that the display apparatus 201-204 for 1st-4th notification is not out of order. The administrator can grasp it. Even when the management result of the game history is displayed, at least one display segment is in a light emitting state in each of the first to fourth notification display devices 201 to 204, and the first to fourth notifications are displayed. Each of the display devices 201 to 204 is in a display state.

  In detail about each display content of the first to fourth notification display devices 201 to 204, in the first notification display device 201, one central display segment is in a light emitting state, and the remaining display segments are in an unlit state. It becomes. Even if the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, one central display segment in the first notification display device 201 can be in a light emitting state. When the management result of the game history is displayed, the display content of the first notification display device 201 includes the display content in which one central display segment is in a light emitting state and the remaining display segments are in an off state. Not. Thereby, even when the management result of the game history is displayed, the display contents of the first notification display device 201 in the situation where the set value is being updated while using the display segment that can be in the light emitting state are displayed as the game history. It is possible to make the display contents not displayed in the management result.

  In the second notification display device 202, as in the first notification display device 201, one display segment at the center is in a light emitting state, and the remaining display segments are in an unlit state. Even if the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, one central display segment in the second notification display device 202 can be in a light emitting state. When the management result of the game history is displayed, the display content of the second notification display device 202 includes the display content in which one display segment in the center is in a light emitting state and the remaining display segments are in an unlit state. Not. Thereby, even when the management result of the game history is displayed, the display contents of the second notification display device 202 in the situation where the setting value is updated while using the display segment that can be in the light emitting state are displayed. It is possible to make the display contents not displayed in the management result.

  In the third notification display device 203, some display segments are in a light emitting state and the remaining display segments are in an unlit state so that the letter “H” is displayed. In this case, the display segment that is in the light emitting state can be in the light emitting state even when the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, but the management result of the game history is The display content of the third notification display device 203 when displayed does not include the display content in which the letter “H” is displayed. Thereby, even when the management result of the game history is displayed, the display content of the third notification display device 203 in the situation where the set value is being updated while using the display segment that can be in the light emitting state is displayed as the game history. It is possible to make the display contents not displayed in the management result. In addition, the display content of the third notification display device 203 in the situation where the set value is being confirmed does not include the display content in which the letter “H” is displayed. Thus, by displaying “H” on the third notification display device 203, it is possible to notify the manager of the game hall that the setting value is being updated.

  In the fourth notification display device 204, some display segments are turned on and the remaining display segments are turned off so that display corresponding to the current set value is performed. In the case of FIG. 124A, since the current setting value is “setting 2”, “2” corresponding to “setting 2” is displayed on the fourth notification display device 204. By checking the fourth notification display device 204, the manager of the game hall can grasp the current set value. It should be noted that the display content of the fourth notification display device 204 in the situation where the set value is being updated can be displayed in both the situation where the management result of the game history is displayed and the situation where the set value is confirmed.

  Returning to the description of the second timer interrupt process (FIG. 123), if a negative determination is made in step S8402, it is determined whether or not “1” is set in the setting confirmation display flag in the work area 221 for specific control. (Step S8404). The setting confirmation display flag is a flag for identifying in the main CPU 63 whether or not the main CPU 63 is executing the setting confirmation processing (FIG. 115). As already described, the setting confirmation process (FIG. 115) is a situation in which the process at the start of the operation power supply is executed in the main process (FIG. 114) when the operation power supply to the main CPU 63 is started. Although the second timer interrupt process (FIG. 123) will be executed, it is interrupted and activated even when the process at the start of supplying the operating power is being executed. Even in the situation where the confirmation process (FIG. 115) is being executed, the second timer interrupt process (FIG. 123) is interrupted and started.

  The situation where the setting confirmation display flag is set to “1” means that the current processing time of the second timer interruption process (FIG. 123) is the setting confirmation process (FIG. 115) being executed by the main CPU 63. It means that the process has been started by interrupting the situation. If an affirmative determination is made in step S8404, a setting process for the fifth display data buffer 275 during setting confirmation is executed (step S8405). In the setting process, a display indicating that the setting values of the pachinko machine 10 are being confirmed on the first to fourth notification display devices 201 to 204 and a display indicating the current setting values of the pachinko machine 10 are displayed. Display data for execution is stored in the fifth display data buffer 275.

  When the display data stored in the fifth display data buffer 275 is transmitted to the fifth display circuit 265 via the display IC 266, the first to fourth notification display devices 201 to 204 will be described with reference to FIG. 124 (b). The display shown in the figure is performed. Specifically, when a display indicating that the setting value is being updated in the first to fourth notification display devices 201 to 204 is performed, the first to fourth notification display devices 201 to 204 are displayed. In each case, at least one display segment is in a light emitting state. That is, each of the first to fourth notification display devices 201 to 204 is in a display state. Thereby, even if it is a case where the display which shows that it is the condition which is confirming a setting value is performed, it is confirmed that the display apparatus 201-204 for 1st-4th notification has not failed. The administrator can grasp it.

  In detail about each display content of the first to fourth notification display devices 201 to 204, in the first notification display device 201, one central display segment is in a light emitting state, and the remaining display segments are in an unlit state. It becomes. Even if the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, one central display segment in the first notification display device 201 can be in a light emitting state. When the management result of the game history is displayed, the display content of the first notification display device 201 includes the display content in which one central display segment is in a light emitting state and the remaining display segments are in an off state. Not. Thereby, even when the management result of the game history is displayed, the display content of the first notification display device 201 in the situation where the set value is confirmed while using the display segment that can be in the light emitting state is displayed as the game history. It is possible to make the display contents not displayed in the management result.

  In the second notification display device 202, as in the first notification display device 201, one display segment at the center is in a light emitting state, and the remaining display segments are in an unlit state. Even if the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, one central display segment in the second notification display device 202 can be in a light emitting state. When the management result of the game history is displayed, the display content of the second notification display device 202 includes the display content in which one display segment in the center is in a light emitting state and the remaining display segments are in an unlit state. Not. Thereby, even when the management result of the game history is displayed, the display content of the second notification display device 202 in the situation where the set value is confirmed while using the display segment that can be in the light emitting state is displayed as the game history. It is possible to make the display contents not displayed in the management result.

  Here, the display contents on the first notification display device 201 and the second notification display device 202 are the same regardless of whether the setting value is being updated or the setting value is being confirmed. Accordingly, the first notification display device 201 and the second notification display device 202 indicate that the display target in the first to fourth notification display devices 201 to 204 relates to the set value, not the management result of the game history. It becomes possible to clearly notify the manager of the game hall by the display.

  In the third notification display device 203, some display segments are in a light-emitting state and the remaining display segments are in a light-off state so that the letter “k” is displayed. In this case, the display segment that is in the light emitting state can be in the light emitting state even when the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, but the management result of the game history is The display content of the third notification display device 203 when displayed does not include the display content in which the character “k” is displayed. Thereby, even when the management result of the game history is displayed, the display content of the third notification display device 203 in the situation where the set value is confirmed while using the display segment that can be in the light emitting state is displayed as the game history. It is possible to make the display contents not displayed in the management result. Further, “H” is displayed on the third notification display device 203 in a situation where the set value is being updated, whereas “k” is displayed on the third notification display device 203 in a situation where the set value is being confirmed. Is displayed. Accordingly, by confirming the display content of the third notification display device 203, the game hall manager is notified of whether the setting value is being updated or the setting value is being checked. It becomes possible.

  In the fourth notification display device 204, some display segments are turned on and the remaining display segments are turned off so that display corresponding to the current set value is performed. In the case of FIG. 124 (b), the current setting value is “setting 2”, so that “2” corresponding to “setting 2” is displayed on the fourth notification display device 204. By checking the fourth notification display device 204, the manager of the game hall can grasp the current set value. Note that the display content of the fourth notification display device 204 in the situation where the set value is being confirmed can be displayed both in the situation where the management result of the game history is displayed and in the situation where the set value is being updated.

  Returning to the description of the second timer interrupt process (FIG. 123), if a negative determination is made in step S8404, a process for setting the fifth display data buffer 275 in the normal state is executed (step S8406). In this case, information is read from the display target setting area 276 in the work area 223 for non-specific control, and the parameters corresponding to the read information are displayed on the first to fourth notification display devices 201 to 204. Display data is stored in the fifth display data buffer 275. By transmitting the display data to the fifth display circuit 265 via the display IC 266, the first to fourth notification display devices 201 to 204 calculate the current display target parameters among the 61st to 68th parameters. The result is displayed.

  When the process of step S8403, step S8405, or step S8406 is executed, the transmission state of the signal through the type data signal line LN1 and the type clock signal line LN2 is turned off (step S8407), and the display data signal line LN3 and the display are displayed. The transmission state of the signal through the clock signal line LN4 is turned off (step S8408). Thereafter, the type counter provided in the work area 221 for specific control is updated (step S8409).

  The type counter is a counter for the main CPU 63 to specify a display data transmission target in the first to fifth display data buffers 271 to 275 in the current processing of the second timer interrupt process. When the value of the type counter is “1”, the display data of the first display data buffer 271 is a transmission target. When the value of the type counter is “2”, the display data of the second display data buffer 272 is a transmission target. When the value of the type counter is “3”, the display data in the third display data buffer 273 is to be transmitted, and when the value of the type counter is “4”, the display data in the fourth display data buffer 274 is If the type counter value is “5”, the display data in the fifth display data buffer 275 is the transmission target. In the type counter update process, 1 is added to the value of the type counter, and when the value of the type counter after the addition of 1 exceeds the upper limit “5”, the value of the type counter is set to “1”. . As a result, the display data transmission target is sequentially changed in the first to fifth display data buffers 271 to 275 for each processing time of the second timer interrupt process.

  Thereafter, the type data corresponding to the value of the type counter is read from the main ROM 64 (step S8410). Specifically, when the value of the type counter is “1”, the type data corresponding to the first display circuit 261 is read from the main ROM 64, and when the value of the type counter is “2”, the second value is read. If the type data corresponding to the display circuit 262 is read from the main ROM 64 and the value of the type counter is “3”, the type data corresponding to the third display circuit 263 is read from the main ROM 64 and the value of the type counter is If “4”, the type data corresponding to the fourth display circuit 264 is read from the main ROM 64, and if the value of the type counter is “5”, the type data corresponding to the fifth display circuit 265 is read. Read from the side ROM 64.

  Thereafter, display data is read from the display data buffers 271 to 275 corresponding to the value of the type counter (step S8411). Specifically, the display data is read from the first display data buffer 271 when the value of the type counter is “1”, and is read from the second display data buffer 272 when the value of the type counter is “2”. When the display data is read, the display data is read from the third display data buffer 273 when the value of the type counter is “3”, and from the fourth display data buffer 274 when the value of the type counter is “4”. The display data is read, and when the value of the type counter is “5”, the display data is read from the fifth display data buffer 275.

  Thereafter, transmission processing of various signals is executed (step S8412). In the transmission process, signal output is performed on the classification data signal line LN1 and the classification clock signal line LN2 so that the classification data read in step S8410 is transmitted to the display IC 266. In the transmission process, signal output to the display data signal line LN3 and the display clock signal line LN4 is performed so that the display data read in step S8411 is transmitted to the display IC 266.

  Thereafter, in order to permit the generation of the first timer interrupt process (FIG. 117) and the second timer interrupt process (FIG. 123), the interrupt permission is set (step S8413).

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

  Supply of operating power to the main CPU 63 is started by turning on the power of the pachinko machine 10 in a state where the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c. In the situation where the main process (FIG. 114) is started, the reset button 68c is not pressed and the setting key insertion portion 68a is turned ON, and a process that allows the game to proceed in the main process is executed. The setting confirmation process is executed in the situation where the process at the start of the supply of operating power is being executed. As a result, it is possible to make it difficult to perform an act of illegally checking the set value.

  Assuming the case where the set value is confirmed in a situation where the progress of the game is continued, for example, when the set value is confirmed during the execution of the game round, the set value is being confirmed. May cause the transition to the opening / closing execution mode. In this case, there is a possibility that the game ball cannot be launched toward the special electricity prize winning device 32 in spite of the opening / closing execution mode being started. In addition, when the setting value is confirmed during the execution of the opening / closing execution mode, the opening / closing execution mode proceeds in a situation where the setting value is being confirmed. There is a possibility that the game ball cannot be launched toward the.

  Assuming that the progress of the game is stopped when the set value is confirmed, the progress of the game is stopped halfway when the confirmation of the set value is started in the situation where the game is being performed. There is a risk that the processing will be complicated. For example, if the confirmation of the set value is started in the middle of execution of a game and it is attempted to stop the progress of the game, a process for stopping the game is required. In this case, when the confirmation of the set value is started, the symbol variation display on the symbol display device 41 is stopped halfway, and when the confirmation of the set value is completed, the symbol variation display on the symbol display device 41 is resumed. Attempting to do so requires complicated processing. Further, for example, if the confirmation of the set value is started during the execution of the opening / closing execution mode and the progress of the game is to be stopped halfway, a process for stopping the opening / closing execution mode is required. In addition, when the confirmation of the set value is started in the middle of the execution of the variation display of the picture in the normal map display unit 38a and the progress of the game is stopped halfway, a process for stopping the variation display of the pattern is performed. Necessary. In addition, if the confirmation of the set value is started in the middle of the execution of the open execution state of the power utility 34a and the progress of the game is stopped in the middle, a process for stopping the release execution state in the middle is required. Become. On the other hand, a configuration is also possible in which the set value is confirmed after all the games are completed. There is a need to wait until a state where none of the execution execution states of the object 34a is executed, and there is a possibility that the waiting time until the confirmation of the set value is started becomes long.

  On the other hand, when the supply of operating power to the main CPU 63 is started, the main process that is executed when the operation is started is the state before the process that allows the game to proceed is executed. Since the setting confirmation process is executed in a situation where the process is being executed, the setting value is confirmed in a situation where the progress of the game has already been stopped. This makes it possible to prevent the setting value from being checked while the game is in progress, and to stop the progress of the game when checking the setting value, or to stop the progress of the game. There is no need to wait for confirmation of the set value until Therefore, it is possible to appropriately check the set value.

  In a situation where the supply of operating power to the main CPU 63 is started and main processing (FIG. 114) is started by turning on the power of the pachinko machine 10 while pressing the reset button 68c. The RAM clear process (step S7915) is executed regardless of whether or not the setting key insertion portion 68a is turned on. As a result, the operation of turning on the power of the pachinko machine 10 while pressing the reset button 68c is uniquely linked to the execution of the RAM clear process (step S7915), and the RAM clear process (step S7915). It is possible to make the operation content for generating the game hall easy to understand for the manager of the game hall.

  Even if the RAM clear process (step S7915) is executed, the set value counter in the work area 221 for specific control is not cleared to “0” and the information of the set value counter is not changed. Thereby, even if the RAM clear process (step S7915) is executed, it is possible to prevent the setting value from being changed.

  Based on not only turning on the power of the pachinko machine 10 while pressing the reset button 68c, but also turning on the power of the pachinko machine 10 while turning on the setting key insertion portion 68a with the setting key. Not only the clear process (step S7915) but also the set value update process (step S7918) is executed. Further, as described above, the setting confirmation process is performed based on the power-on operation of the pachinko machine 10 while the setting key insertion portion 68a is turned on with the setting key without pressing the reset button 68c (step S7914). Is executed. As a result, the ON operation for the setting key insertion unit 68a can be made common as an operation for executing the process related to the setting value. Therefore, it is possible to make the operation content for generating the processing related to the set value easy to understand for the game hall manager.

  When the power of the pachinko machine 10 is turned on while the setting key insertion portion 68a is turned on by the setting key, and the pressing operation of the reset button 68c is not added, a setting confirmation process is executed, and the reset button When the pressing operation 68c is added, a set value update process is executed. Accordingly, it is possible to make the execution target process different among the setting confirmation process and the set value update process depending on whether or not the reset button 68c is pressed. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for executing a desired process among the setting confirmation process and the setting value update process. Further, by increasing the operation content for executing the set value update process as compared with the setting confirmation process, it is possible to make it particularly difficult to perform an act of performing the set value update process illegally.

  A monitoring process for determining whether the set value is abnormal is executed in a first timer interrupt process (FIG. 117) that is periodically started. This makes it possible to monitor whether or not the set value is abnormal even in a situation where a game is being performed. Therefore, it is possible to prevent the game from continuing even though the set value is abnormal.

  Whether the set value is abnormal is monitored every time a monitoring trigger occurs. More specifically, it is executed each time the first timer interrupt process (FIG. 117) is activated. Thereby, it becomes possible to increase the frequency of monitoring whether or not the set value is abnormal.

  In the main process (FIG. 114), a process for monitoring whether or not the set value is normal is not set. If a process for monitoring whether or not the set value is normal is set in the process at the start of supply of operating power in the main process (FIG. 114), a power failure flag and checksum are set at the start of supply of operating power. In addition to monitoring, it is necessary to monitor whether or not the set value is normal, which increases the monitoring load. Further, when it is specified that the set value is abnormal at the start of supply of operating power, if the RAM clear process (step S7915) and the set value update process (step S7918) are attempted to be executed, the processing configuration accordingly. Will be complicated. On the other hand, since the process for monitoring whether the set value is normal is not set in the main process (FIG. 114), the processing configuration of the process at the start of supply of operating power is preferable. It becomes possible. Even if the process for monitoring whether the set value is normal is not set in the process at the start of supply of operating power in this way, the setting monitoring is performed in the first timer interrupt process (FIG. 117). Since the configuration is such that the process (step S8220) is executed, it is possible to cope with the case where the set value is abnormal.

  Note that an update button 68b is provided as in the first embodiment, and in the set value update process (FIG. 116), the set value is updated by one step each time the reset button 68c is pressed. Alternatively, the set value may be updated one step each time the update button 68b is pressed. In addition, positions corresponding to “setting 1” to “setting 6” are set as rotation operation positions when the setting key is inserted into the setting key insertion portion 68a and the rotation operation is performed. A setting value corresponding to the rotation operation position of the part 68a may be set. Further, the setting key insertion portion 68a can be further rotated from the ON position, and the setting value being updated is set to the setting value in the next order each time the rotation operation beyond the ON position is performed. It is good also as a structure updated.

  In the set value update process (FIG. 116), the set key insertion unit 68a is turned OFF to confirm the set value being selected, and the reset button 68c is further pressed to complete the set value update process. It is good also as a structure to be made. In the configuration in which the update button 68b is provided, in the setting value update process (FIG. 116), the setting key insertion unit 68a is turned OFF to confirm the setting value being selected, and the update button 68b is further pressed. The setting value update process may be terminated when operated.

  Further, as a condition for executing the set value update process (FIG. 116), a configuration in which the condition that the gaming machine main body 12 is in an open state may not be set, and the front door frame 14 is in an open state. It is good also as a structure in which the condition that this is not set, and it is good also as a structure in which both the conditions that the game machine main body 12 is an open state, and the conditions that the front door frame 14 is an open state are not set.

  In addition, as a condition for executing the setting confirmation process (FIG. 115), a configuration in which the condition that the gaming machine main body 12 is in the open state may not be set, and the front door frame 14 is in the open state. It is good also as a structure in which the condition that this is not set, and it is good also as a structure in which both the conditions that the game machine main body 12 is an open state, and the conditions that the front door frame 14 is an open state are not set.

  Further, in the main process (FIG. 114) executed when the supply of operating power to the main CPU 63 is started, it is specified that the power failure flag is not set to “1” or that the checksum is abnormal. In such a case, the RAM clear process (step S7915) may be executed. In this case, after the RAM clear process (step S7915) is executed, the set value update process (step S7918) may be executed, and notification indicating that the set value update process (step S7918) should be executed. May be configured to stop the progress of the game and to start processing for controlling the progress of the game.

  Further, instead of the configuration in which the setting confirmation process (step S7914) is executed after the determination process of whether or not the power failure flag is set to “1” and the checksum comparison process in the main process (FIG. 114). The configuration may be executed before these processes. In this case, it is possible to prioritize processing for confirming the set value.

  Further, the configuration monitoring process (step S8220) is not limited to a configuration that is executed every time the first timer interrupt process (FIG. 117) is activated. For example, a plurality of first timer interrupt processes (FIG. 117) are provided. A configuration may be adopted in which the setting monitoring process (step S8220) is executed every time a predetermined number of triggers (for example, 10,000 times) is executed. In this case, it is possible to suppress the execution frequency of the monitoring while periodically monitoring whether or not the set value is normal.

  Further, the setting monitoring process (step S8220) may be executed in the remaining process (steps S7921 to S7924) in the main process (FIG. 114). In this case, it is possible to monitor whether or not the set value is normal using the idle time when the first timer interrupt process (FIG. 117) and the second timer interrupt process (FIG. 123) are not executed. It becomes possible.

  Moreover, it is good also as a structure by which a setting monitoring process (step S8220) is performed when game times are newly started. More specifically, when the game times are newly started, the setting monitoring process (step S8220) may be executed before the success / failure determination process is executed. As a result, it is possible to prevent the determination process from being executed in a situation where the set value is abnormal.

  Further, when it is specified that the setting value is abnormal in the setting monitoring process (step S8220), the configuration may be shifted to the setting value update process (step S7918).

  When the setting monitoring process (step S8220) specifies that the setting value is abnormal, the main process (with the setting abnormality flag set in the work area 221 for specific control set to “1”) FIG. 114) may be configured to stop the progress of the game with the setting abnormality flag set to “1” and to release the state where the progress of the game is stopped → It is good also as a structure which needs ON. In this case, even if an operation for executing the set value update process is not performed in the main process (FIG. 114), if the setting abnormality flag is set to “1”, the setting is forcibly set. By executing the value update process, it is possible to force a new setting value to be set using the set value update process set in the main process (FIG. 114).

  In addition, the hold information acquired when the game ball enters the first operation port 33 and the hold information acquired when the game ball enters the second operation port 34 are stored separately. It is good also as a structure by which the 1st special figure display part and the 2nd special figure display part are provided as the special figure display part 37a corresponding to those hold information. In this case, the variation display of the pattern on the first special figure display unit and the variation display of the pattern on the second special figure display unit can be executed in an overlapping manner, and when one of the predetermined game states is entered, It is good also as a structure to which the continuous period of the fluctuation display of the picture in a special figure display part becomes extremely long. In this configuration, if it is attempted to wait for the confirmation of the set value until no game is played, the waiting time becomes longer. On the other hand, the setting confirmation process (step S7914) is performed in the process at the start of the supply of operating power in the main CPU 63, so that the set value can be obtained without causing the standby time as described above. Can be confirmed.

  Further, in the low frequency support mode, the duration of the variable pattern display on the normal map display unit 38a may be extremely long. In this configuration, if it is attempted to wait for the confirmation of the set value until no game is played, the waiting time becomes longer. On the other hand, the setting confirmation process (step S7914) is performed in the process at the start of the supply of operating power in the main CPU 63, so that the set value can be obtained without causing the standby time as described above. Can be confirmed.

  In addition, the display content of the first to fourth notification display devices 201 to 204 when the setting confirmation process (FIG. 115) is executed is not limited to the display content in the above-described embodiment. Instead of displaying the letter “k” on the display device 203, only the central display segment may be in a light emitting state as in the first notification display device 201 and the second notification display device 202. . Alternatively, the first to third notification display devices 201 to 203 may be turned off and the fourth notification display device 204 may perform display corresponding to the current set value.

  In addition, the display content of the first to fourth notification display devices 201 to 204 when the set value update process (FIG. 116) is executed is not limited to the display content in the above-described embodiment. Instead of displaying the letter “H” on the display device 203, only the central display segment may be in a light emitting state as in the first notification display device 201 and the second notification display device 202. . Alternatively, the first to third notification display devices 201 to 203 may be turned off and the fourth notification display device 204 may perform display corresponding to the current set value.

  Further, instead of the configuration in which the main CPU 63 transmits the type data and the display data to the display IC 266 at the same time, the main CPU 63 may start the display data transmission after starting the transmission of the type data. In this case, transmission of display data may be started in the middle of transmission of classification data, or transmission of display data may be started after transmission of classification data is completed. The transmission of the type data may be started after the display data transmission is started. In this case, transmission of the classification data may be started in the middle of transmission of the display data, or transmission of the classification data may be started after transmission of the display data is completed.

  In addition, the display IC 266 is not limited to the configuration in which only one display IC 266 is provided so as to be common to the first to fifth display circuits 261 to 265, and the first to fifth display circuits 261 to 265 are not limited. It is good also as a structure provided by corresponding to each one to one. In this configuration, if the display data is stored and held in each display IC provided in a one-to-one correspondence with the first to fifth display circuits 261 to 265, the display data on each display IC is stored. Depending on the provision cycle, unintentional blinking may occur in each display unit. On the other hand, by integrating the processing for transmitting display data into the second timer interrupt processing (FIG. 123) having a relatively short interrupt cycle as in the above-described embodiment, the display data to be displayed on each display IC is consolidated. The provision cycle can be shortened, and unintentional blinking can be prevented from occurring in each display unit.

  Further, instead of the configuration in which the hit random number counter C1 is provided in the main RAM 65, a configuration in which a random number circuit for updating the random number acquired in the validity determination process is provided. In this case, in the internal function register setting process in the main process (FIG. 114), setting for associating the random number of the random number circuit with the random number acquired in the validity determination process is performed.

<Thirty-fourth embodiment>
In the present embodiment, the processing configuration of the set value update process executed by the main CPU 63 is different from that of the thirty-third embodiment. The following describes the configuration that is different from the thirty-third embodiment. The description of the same configuration as that of the thirty-third embodiment is basically omitted. In the present embodiment, an update button 68b is provided on the main control board 61 as in the first embodiment.

  FIG. 125 is a flowchart showing the set value update processing in the present embodiment executed by the main CPU 63. Note that the processing from step S8501 to step S8508 in the set value update processing is executed using the specific control program and the specific control data in the main CPU 63.

  First, “1” is set to the setting update display flag provided in the work area 221 for specific control (step S8501). Thereafter, it is determined whether or not the value of the setting value counter provided in the work area 221 for specific control is 1 or more corresponding to “setting 1” and 6 or less corresponding to “setting 6” (step). S8502). If the value of the set value counter is “0” or 7 or more, a negative determination is made in step S8502 and “1” is set in the set value counter (step S8503). Thereby, the setting value of the pachinko machine 10 becomes “setting 1”.

  When an affirmative determination is made in step S8502 or when the process of step S8503 is executed, it is determined whether or not the reset button 68c is pressed (step S8504). When the reset button 68c is not pressed (step S8504: NO), the value of the set value counter in the work area 221 for specific control is provided on the condition that the update button 68b is pressed (step S8505: YES). 1 is added (step S8506). As a result, each time the update button 68b is pressed once, the set value is updated to one level higher. If the update button 68b is not pressed (step S8505: NO) or if the value of the set value counter is incremented by 1, the process returns to step S8502; however, in step S8502, the set value counter If it is determined that the value is 7 or more, “1” is set in the set value counter in step S8503. As a result, when the update button 68b is pressed once in the state of “setting 6”, the setting returns to “setting 1”.

  If the reset button 68c has been pressed (step S8504: YES), the current set value is confirmed and the process proceeds to step S8507. In step S8507, it is determined whether the setting key insertion unit 68a has been turned OFF using the setting key. In this case, it may be configured to determine whether the setting key insertion unit 68a has been switched from the ON state to the OFF state, or may be configured to determine whether the setting key insertion unit 68a is in the OFF state. If the setting key insertion unit 68a has not been turned OFF (step S8507: NO), the process of step S8507 is executed again.

  When the setting key insertion unit 68a is turned OFF (step S8507: YES), the setting update display flag in the work area 221 for specific control is cleared to “0” (step S8508).

  According to the above configuration, in the configuration in which the set value is updated by pressing the update button 68b, the set value is confirmed by pressing the reset button 68c, and the setting key insertion unit 68a is turned OFF. This completes the set value update process. That is, in order to end the set value update process after the set value is updated in the set value update process, it is necessary not only to turn off the set key insertion unit 68a but also to press the reset button 68c. As a result, it is possible to make it difficult to perform an act of playing a game with the set value after the set value is illegally updated.

<Thirty-fifth embodiment>
In the present embodiment, the processing configuration relating to the display control of the first to fourth notification display devices 201 to 204 executed by the main CPU 63 is different from the thirty-third embodiment. The following describes the configuration that is different from the thirty-third embodiment. The description of the same configuration as that of the thirty-third embodiment is basically omitted.

  FIG. 126 is an explanatory diagram for explaining the electrical configuration of the calculation result storage area 234 provided in the work area 223 for non-specific control.

  In the calculation result storage area 234, information on base values calculated by the main CPU 63 is stored. The base value is based on the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in a situation where neither the opening / closing execution mode or the high frequency support mode based on the jackpot result is found. It is the ratio of the total number of game balls to be paid out.

In detail regarding the calculation of the base value, although the normal counter area 231 is provided in the work area 223 for non-specific control in this embodiment, the open / close execution mode counter area 232 and the high frequency support mode counter area 233 are provided. Is not provided. In the normal counter area 231, as in the fifteenth embodiment, the normal general winning counter 231a, the special special electric winning counter 231b, the normal first operating counter 231c, the normal second operating counter 231d, and A normal out counter 231e is provided. In a situation where neither the opening / closing execution mode or the high-frequency support mode based on the jackpot result is entered, when one game ball enters the general winning opening 31, the value of the normal general winning counter 231a is incremented by one, and the special electricity When one game ball enters the winning device 32, the value of the special special electricity prize counter 231b is incremented by 1, and when one game ball enters the first operating port 33, the normal use The value of the first operation counter 231c is incremented by 1, and when one game ball enters the second operation port 34, the value of the normal second operation counter 231d is incremented by 1 and the value is output to the out port 24a. When one game ball enters, the value of the normal out counter 231e is incremented by one. The base values are as follows when the values of the various counters 231a to 231e in the normal counter area 231 are K91 to K95 in a situation where neither the opening / closing execution mode or the high frequency support mode is a jackpot result.
Base value: Total number of game balls to be paid out (K91 × “number of winning balls for winning in the general winning opening 31” + K92 × “number of winning balls for winning in the special electric winning device 32” + K93 × “to the first operation port 33” The number of winning balls for winning the game “+ K94 ד the number of winning balls for winning the second operating port 34 ”) / the total number of game balls discharged from the work area PA (K91 + K92 + K93 + K94 + K95).

  The base value is calculated every time the result calculation process (FIG. 130) described later is executed in the management process (step S8920) of the first timer interrupt process (FIG. 133) described later. The values of the various counters 231a to 231e of 231 indicate a situation in which “1” is not set in the management start flag provided in the work area 223 for non-specific control, and the opening / closing execution mode and the high frequency support mode based on the jackpot result When the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) becomes the management start reference number in a situation that is not any of the above, it is cleared to “0”. In the situation where the management start flag is set to “1”, the open / close execution mode and the high frequency support mode based on the jackpot result The total number of game balls discharged from the gaming area PA (i.e. the total number of ball game which is supplied to the game area PA) is "0" cleared by the shift reference number in nor availability deviation.

  The management start reference number is set to 300, which is smaller than the shift reference number, as in the fifteenth embodiment. In the shipping stage of the pachinko machine 10 and the like, an operation check of the pachinko machine 10 may be performed before the shipment. In this case, the game balls are maintained in the respective ball-entry portions and the subsequent operation is checked. Under such circumstances, the base value may be different from the situation in which a normal game is played. Therefore, the total number of game balls discharged from the game area PA in a situation where the management start flag is not set to “1” and neither the opening / closing execution mode or the high-frequency support mode based on the jackpot result (ie, game When the total number of game balls supplied to the area PA) reaches the management start reference number that is smaller than the shift reference number, the counters 231a to 231e in the normal counter area 231 are once cleared to "0". Thus, it becomes possible to reduce the influence of the operation check on the base value in a situation where a normal game is being performed after the pachinko machine 10 is shipped.

  The shift reference number is set to 60000. In the pachinko machine 10, a maximum of 100 game balls are fired per minute, so 60000 is the maximum number of fires in 10 hours. In this case, the general business hours in the game hall are about 13 hours, and the game is performed for about 10 hours in the situation where neither the opening / closing execution mode or the high-frequency support mode due to the jackpot result. Therefore, the shift reference number is set on the assumption of the maximum number of game balls to be fired in one business day. By clearing the various counters 231a to 231e in the normal counter area 231 to “0” every time the shift reference number is reached, the base value can be calculated within the range of the shift reference number.

  The calculation result storage area 234 is provided with a current area 311, a first history area 312, a second history area 313, and a third history area 314 as storage areas for storing the base value information. Yes. Each of these various areas 311 to 314 has the same storage capacity, and specifically has a capacity of 1 byte so that base value information can be stored.

  The current area 311 stores the base value calculated in the latest result calculation process (FIG. 130). That is, the current base area 311 stores the latest base value.

  The first history area 312 stores the final base value in the previous calculation period. In this case, if the previous calculation period is after the management start flag is set to “1”, the first history area 312 has an opening / closing execution mode based on the jackpot result in the previous calculation period. And the base value at the timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) becomes the shift reference number in a situation other than the high frequency support mode. Stored. Further, if the management start flag is set to “1” after the previous calculation period has elapsed, the first history area 312 includes an opening / closing execution mode based on the jackpot result in the previous calculation period, and The base value at the timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in the situation other than the high frequency support mode becomes the management start reference number. Stored.

  In the second history area 313, the final base value in the previous calculation period is stored. In this case, if the previous calculation period is after the management start flag is set to “1”, the second history area 313 has an opening / closing execution mode based on the jackpot result in the previous calculation period. And the base value at the timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) becomes the shift reference number in a situation other than the high frequency support mode. Stored. If the management start flag is set to “1” after the previous calculation period has elapsed, the second history area 313 includes an opening / closing execution mode based on the jackpot result in the previous calculation period and The base value at the timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in the situation other than the high frequency support mode becomes the management start reference number. Stored.

  In the third history area 314, the final base value in the calculation period three times before is stored. In this case, if the third calculation period is after the management start flag is set to “1”, the third history area 314 has an opening / closing execution mode based on the jackpot result in the third calculation period. And the base value at the timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) becomes the shift reference number in a situation other than the high frequency support mode. Stored. Further, if the management start flag is set to “1” after the calculation period three times before, the third history area 314 has an opening / closing execution mode based on the jackpot result in the calculation period three times before and The base value at the timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in the situation other than the high frequency support mode becomes the management start reference number. Stored.

  The base values stored in the current status area 311, the first history area 312, the second history area 313, and the third history area 314 are sequentially notified by the first to fourth notification display devices 201 to 204. Specifically, every time the display continuation period (specifically, 5 seconds) elapses, the current area 311 → the first history area 312 → the second history area 313 → the third history area 314 is determined in a predetermined order. The base value to be notified is switched, and the switching of the base value to be notified in the predetermined order is repeated.

  127 (a) to 127 (d) are for the first to fourth notifications when the base values stored in the various areas 311 to 314 are notified in a situation where the management start flag is set to “1”. It is explanatory drawing for demonstrating the display content of the display apparatuses 201-204. FIG. 127A shows an example of display contents of the first to fourth notification display devices 201 to 204 when the base value stored in the current area 311 is notified, and FIG. 127B shows the first history. FIG. 127C shows an example of display contents of the first to fourth notification display devices 201 to 204 when the base value stored in the area 312 is notified. FIG. 127C shows the base stored in the second history area 313. FIG. 127 (d) shows an example of the display contents of the first to fourth notification display devices 201 to 204 when the value is notified, and FIG. 127 (d) shows the case where the base value stored in the third history area 314 is notified. An example of the display content of the display apparatuses 201 to 204 for the first to fourth notifications is shown.

  As shown in FIGS. 127 (a) to 127 (d), each of the first to fourth notification display devices 201 to 204 has eight display segments 321 to 324. Of the eight display segments 321-324, the seven display segments 321-324 are all bar-shaped light emitting areas having the same shape and the same size, and are arranged so as to generate the character “8”. Has been. On the other hand, each of the display segments 321 to 324 is a circular light emitting region, and is located at the lower right position with respect to the seven display segments 321 to 324 arranged in the shape of “8”. Is provided. Even when any base value of the various areas 311 to 314 is notified, at least one of the display segments 321 to 324 is in a light emitting state in each of the first to fourth notification display devices 201 to 204.

  In the first notification display device 201, a display indicating that the base value is being notified in the first to fourth notification display devices 201 to 204 is performed. Specifically, even if any base value in the various areas 311 to 314 is notified, the first notification display device 201 displays the letter “b”. When information other than the base value is notified in the first to fourth notification display devices 201 to 204, the letter “b” is not displayed on the first notification display device 201. Thus, by confirming that the character “b” is displayed on the first notification display device 201, the manager of the game hall can change the base on the first to fourth notification display devices 201-204. It is possible to grasp that the value is notified.

  In the second notification display device 202, display indicating which of the various areas 311 to 314 is reporting the base value is performed. Specifically, in a situation where the base value of the current area 311 is informed, the letters “L.” are displayed on the second notification display device 202 as shown in FIG. In a situation where the base value of the first history area 312 is informed, the characters “1.” are displayed on the second notification display device 202 as shown in FIG. In a situation where the base value of the second history area 313 is informed, the character “2.” is displayed on the second notification display device 202 as shown in FIG. In a situation where the base value of the third history area 314 is informed, the character “3.” is displayed on the second notification display device 202 as shown in FIG. 127 (d). Thus, by checking the characters displayed on the second notification display device 202, the manager of the game hall can determine which base value is notified on the first to fourth notification display devices 201-204. It is possible to grasp whether the current period is within the calculation period.

  In the second notification display device 202, the circular display segments 321 to 324 are in a light emitting state even in a situation where any base value of the various areas 311 to 314 is being notified. As will be described later, the third notification display device 203 and the fourth notification display device 204 display any number from “0” to “9” as the display corresponding to the base value. In this case, when any of the numbers “1” to “3” is displayed on the second notification display device 202, three numbers are displayed on the second to fourth notification display devices 202 to 204. It becomes difficult to grasp the base value. On the other hand, when the circular display segments 321 to 324 provided at the lower right of the second notification display device 202 are in the light emitting state, the second notification display device 202 has “1” to “1” to “ 3 ”is displayed, the number displayed on the second notification display device 202 and the third notification display device 203 and the fourth notification display device 204 are displayed. It becomes possible to distinguish and distinguish numbers.

  In the third notification display device 203 and the fourth notification display device 204, the number of the base value to be notified is displayed. The base value is calculated as a decimal number up to the second decimal place. The first decimal place number of the base value is displayed on the third notification display device 203. The second number is displayed on the fourth notification display device 204. Here, when the base value is “1.00”, a number “0” is displayed on each of the third notification display device 203 and the fourth notification display device 204. On the other hand, when the base value is not yet stored in the areas 311 to 314 that are the notification target, the third notification display device 203 and the fourth notification display are displayed as shown in the explanatory diagram of FIG. Each device 204 displays a “-” character. As a result, even when the base value calculated as the decimal number to the second decimal place is notified on the two display devices of the third notification display device 203 and the fourth notification display device 204, the base value Can be distinguished from the case where the base value is not yet stored in the areas 311 to 314 to be notified.

  Note that the display contents of the combination of the third notification display device 203 and the fourth notification display device 204 are the same when the base value is “1.00” and when the base value is “0.00”. On the other hand, in order to distinguish between the two, the light emission state of “00” display may be maintained on one of the former and the latter, and the display of “00” may be blinking on the other.

  Next, in the situation where the management start flag is set to “1” with reference to the time chart of FIG. 129, the base values of the various areas 311 to 314 are notified on the first to fourth notification display devices 201 to 204. The state of being performed will be described. FIG. 129A shows a period during which the base value stored in the current area 311 is notified by the first to fourth notification display devices 201 to 209, and FIG. 129B is stored in the first history area 312. FIG. 129 (c) shows the period when the base value stored in the first to fourth notification display devices 201 to 209 is notified, and the base value stored in the second history area 313 is the first to fourth notifications. 129 (d) shows the period of time notified by the display devices 201-209, and the base value stored in the third history area 314 is notified by the first to fourth notification display devices 201-209. FIG. 129 (e) shows the total number of game balls discharged from the game area PA in a situation where neither the opening / closing execution mode or the high-frequency support mode based on the jackpot result has occurred since the base value calculation period was newly started. Number The total number of game balls supplied to the game area PA Chi) indicates the time to reach the initial reference number (6000 in particular).

  As shown in FIG. 129 (a), notification of the base value stored in the current area 311 is started in the first to fourth notification display devices 201 to 204 at the timing of t1. In this notification, as shown in FIG. 127 (a), the first notification display device 201 displays that the base value is a notification target, and the second notification display device 202 stores it in the current area 311. The display indicating that the base value is the notification target is performed, and the display corresponding to the base value stored in the current area 311 is performed on the third notification display device 203 and the fourth notification display device 204.

  Here, as shown in FIG. 129 (e), the calculation initial display is performed from the timing t1 to the timing t2. Specifically, since the base value calculation period is newly started, the total number of game balls discharged from the game area PA in a situation where neither the opening / closing execution mode or the high-frequency support mode based on the jackpot result (that is, the game area) In the period until the total number of game balls supplied to the PA reaches the initial reference number (specifically, 6000), the first notification display device 201 and the second notification display device 202 become display targets. Instead of continuing to turn on the characters, the display target characters are blinked and displayed as the initial calculation display. Immediately after the start of the calculation period, there is little game history information for calculating the base value, so the actual measured value of the base value can be a value that is significantly different from the theoretical value range of the base value. On the other hand, by making the calculation initial display immediately after the calculation period is started in this way, it is possible to make the game hall manager recognize that it is immediately after the calculation period starts. .

  In addition, the third notification display device 203 and the fourth notification display device 204 that display a number corresponding to the base value in the initial calculation display continue to light the number, whereas the first notification display device In 201 and the second notification display device 202, characters to be displayed are blinked. Thus, it is possible to notify that the calculation period has just started, while preventing the visibility of the base value from being lowered. However, the present invention is not limited to this, and even in the initial calculation display, the display may be blinked on at least one of the third notification display device 203 and the fourth notification display device 204. It is good also as a structure by which a display is performed, and it is good also as a structure by which blink display is performed only in one of the display apparatus 201 for 1st notifications, and the display apparatus 202 for 2nd notifications.

  At the timing of t2, the total number of game balls discharged from the game area PA in a situation where neither the opening / closing execution mode or the high frequency support mode based on the jackpot result from the timing of t1 (that is, the number of game balls supplied to the game area PA) When the total number) reaches the initial reference number (specifically, 6000), the calculation initial display is terminated as shown in FIG. 129 (e). Thereby, the lighting display is started not only in the third notification display device 203 and the fourth notification display device 204 but also in the first notification display device 201 and the second notification display device 202.

  After that, when the display continuation period elapses from the timing t1 at the timing t3, the notification of the base value stored in the current area 311 is ended as shown in FIG. 129 (a), and FIG. As shown, notification of the base value stored in the first history area 312 is started. In this case, since the base value stored in the first history area 312 is the final calculation result of the base value in the previous calculation period, the calculation initial display is not performed.

  Thereafter, when the display continuation period elapses from the timing t3 at the timing t4, the notification of the base value stored in the first history area 312 is finished as shown in FIG. 129 (b), and FIG. ), The notification of the base value stored in the second history area 313 is started. In this case, since the base value stored in the second history area 313 is the final calculation result of the base value in the previous calculation period, the calculation initial display is not performed.

  Thereafter, when the display continuation period elapses from the timing t4 at the timing t5, the notification of the base value stored in the second history area 313 is terminated as shown in FIG. ), The notification of the base value stored in the third history area 314 is started. In this case, since the base value stored in the third history area 314 is a calculation result of the final base value in the calculation period three times before, the calculation initial display is not performed.

  After that, when the display continuation period elapses from the timing t5 at the timing t6, the notification of the base value stored in the third history area 314 is terminated as shown in FIG. 129 (d), and FIG. ), Notification of the base value stored in the current area 311 is started. In this case, since the calculation period of the base value is newly started, the total number of game balls discharged from the game area PA in a state where neither the opening / closing execution mode or the high frequency support mode based on the jackpot result (that is, in the game area PA) In order to notify that the period until the total number of supplied game balls) reaches the initial reference number (specifically, 6000) is shown in FIG. The calculation initial display is performed as shown in FIG.

  After that, when the display continuation period elapses from the timing t6 at the timing t8, the notification of the base value stored in the current area 311 is terminated as shown in FIG. 129 (a), and FIG. As shown, notification of the base value stored in the first history area 312 is started. In this case, since the base value stored in the first history area 312 is the final calculation result of the base value in the previous calculation period, the calculation initial display is not performed.

  Next, a processing configuration for enabling notification of the base value as described above will be described.

  The management process (step S8920) in the first timer interrupt process (FIG. 133) described later is a process corresponding to non-specific control in step S3803 as in the management process (FIG. 70) in the fifteenth embodiment. Read the management execution processing program. In this management execution process (FIG. 71), a check process is executed in step S3908 as in the fifteenth embodiment.

  In the check process, in the situation where neither the opening / closing execution mode or the high-frequency support mode based on the jackpot result is specified, when a single game ball is entered into the general winning opening 31, the normal general winning counter 231a is used. When the value is incremented by 1 and the entry of one game ball into the special electricity prize winning device 32 is specified, the value of the special special electricity prize counter 231b is incremented by 1 and one entry to the first operation port 33 is made. When the entry of the game ball is specified, the value of the normal first operation counter 231c is incremented by 1, and when the entry of one game ball into the second operation port 34 is specified, the normal use When the value of the second operation counter 231d is incremented by 1 and the entry of one game ball into the out port 24a is specified, the value of the normal out counter 231e is incremented by 1. In the check process, a result calculation process and a display process are executed.

  FIG. 130 is a flowchart showing the result calculation process. In addition, the process of step S8601-step S8615 in a result calculation process is performed using the program for nonspecific control in the main side CPU63, and the data for nonspecific control.

  First, base value calculation processing is executed (step S8601). In the calculation processing, the base value is calculated using the values of the various counters 231a to 231e in the normal counter area 231. The calculation method of the base value is as already described. Then, the calculated base value is overwritten in the current area 311 (step S8602).

  Thereafter, it is determined whether or not “1” is set in the management start flag provided in the work area 223 for non-specific control (step S8603). The management start flag has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. In addition, when the work area 223 for non-specific control is initialized by clearing “0” including the management start flag, the value of the management start flag becomes “0”. The total number of game balls discharged from the game area PA (that is, in the game area PA) in a situation where the management start flag has a value of “0” and is not in either the opening / closing execution mode or the high frequency support mode based on the jackpot result The management start flag is set to “1” when the total number of supplied game balls) becomes the management start reference number. When the management start flag is set to “1”, the values of the various counters 231a to 231e in the normal counter area 231 are cleared to “0” and a new calculation period is started. Thereby, it becomes possible to make the influence of the operation check at the shipping stage of the pachinko machine 10 difficult to the base value in the situation where the normal game is performed after the shipment of the pachinko machine 10.

  If a negative determination is made in step S8603, the total number is calculated by adding all the values of the various counters 231a to 231e in the normal counter area 231 (step S8604). Then, it is determined whether or not the calculated total number is larger than 300 which is the management start reference number (step S8605).

  If an affirmative determination is made in step S8605, “1” is set to the management start flag (step S8606). Thereafter, a data shift process is executed (step S8607). In the data shift process, the information stored in the current status area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 is changed from the second history area 313 to the third history area 314. The first history area 312 → the second history area 313 and the current status area 311 → the first history area 312 are shifted in this order. As a result, the final base value in the previous calculation period is stored in the third history area 314 as the final base value in the previous three calculation period, and the final base value in the previous previous calculation period. Is stored in the second history area 313 as the final base value in the previous calculation period, and the last base value calculated in the current calculation period is the final base value in the previous calculation period. One history area 312 is stored. In the data shift process, an LDIR instruction is used when shifting information as described above. In the LDIR instruction, the information stored in the storage source area is shifted (copied) to the storage destination area by specifying the address of the information storage source area and the address of the information storage destination area. It becomes.

  However, in the situation where “1” is not set in the management start flag, the base value information is basically not stored in the first to third history areas 312 to 314, and therefore in step S8607, the management is substantially performed. Only the shift of the final base value of the calculation period to the first history area 312 in a situation where “1” is not set in the start flag is performed. Thereafter, all the counters 231a to 231e in the normal counter area 231 are cleared to “0” (step S8608).

  If an affirmative determination is made in step S8603, the total number is calculated by adding all the values of the various counters 231a to 231e in the normal counter area 231 (step S8609). Then, it is determined whether or not the calculated total number is larger than the initial reference number of 6000 (step S8610). If a negative determination is made in step S8610, "1" is set to the calculation initial flag provided in the work area 223 for non-specific control (step S8611), and if an affirmative determination is made in step S8610, The calculation initial flag is cleared to “0” (step S8612). The calculation initial flag is a total number of game balls discharged from the game area PA in a situation where neither the opening / closing execution mode or the high-frequency support mode based on the jackpot result has been started since the base value calculation period was newly started (that is, the game area This is a flag for the main CPU 63 to specify whether or not the total number of game balls supplied to the PA has reached the initial reference number.

  When the process of step S8611 or step S8612 is executed, it is determined whether the total number calculated in step S8609 is equal to or greater than the shift reference number of 60000 (step S8613). If an affirmative determination is made in step S8613, data shift processing is executed (step S8614). In the data shift process, the information stored in the current area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 is changed from the second history area 313 to the second history area in the same manner as step S 8607. 3 history area 314, first history area 312 → second history area 313, current status area 311 → first history area 312 are shifted in this order. As a result, the final base value in the previous calculation period is stored in the third history area 314 as the final base value in the previous three calculation period, and the final base value in the previous previous calculation period. Is stored in the second history area 313 as the final base value in the previous calculation period, and the last base value calculated in the current calculation period is the final base value in the previous calculation period. One history area 312 is stored. In the data shift process, an LDIR instruction is used when shifting information as described above. In the LDIR instruction, the information stored in the storage source area is shifted (copied) to the storage destination area by specifying the address of the information storage source area and the address of the information storage destination area. It becomes. Thereafter, all the counters 231a to 231e in the normal counter area 231 are cleared to “0” (step S8615).

  FIG. 131 is a flowchart showing the display process. Note that the processing from step S8701 to step S8714 in the display processing is executed using a non-specific control program and non-specific control data in the main CPU 63.

  First, it is determined whether or not “1” is set in the management start flag provided in the work area 223 for non-specific control (step S8701). If an affirmative determination is made in step S8701, 1 is subtracted from the value of the switching timing counter provided in the work area 223 for non-specific control (step S8702). The switching timing counter displays the first to fourth notification displays among the base values stored in the current area 311, the first history area 312, the second history area 313, and the third history area 314 of the calculation result storage area 234. This is a counter for the main CPU 63 to specify that it is the timing for switching the base value to be notified in the devices 201-204. As described above, every time a display continuation period (specifically, 5 seconds) elapses, notification is made in a predetermined order: current area 311 → first history area 312 → second history area 313 → third history area 314. The target base value is switched, and the switching of the base value to be notified in the predetermined order is repeated.

  When the process of step S8702 is executed, it is determined whether or not the value of the switching timing counter after 1 subtraction is “0”, so that the base value that is the current notification target becomes the notification target. Whether or not the display continuation period has elapsed is determined (step S8703). When an affirmative determination is made in step S8703, the value of the display target counter provided in the work area 223 for non-specific control is incremented by 1 (step S8704). If the value of the display target counter after adding 1 exceeds the maximum value “3” (step S8705: YES), the display target counter value is cleared to “0” (step S8706).

  The display target counter includes first to fourth notification displays among the base values stored in the current area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234. This is a counter for the main CPU 63 to specify a base value to be notified in the devices 201 to 204. Specifically, when the value of the display target counter is “0”, the base value stored in the current area 311 is a notification target, and when the value of the display target counter is “1”, the first history area When the base value stored in 312 is a notification target and the value of the display target counter is “2”, the base value stored in the second history area 313 is the notification target, and the value of the display target counter is “3”. ", The base value stored in the third history area 314 is a notification target.

  If a negative determination is made in step S8705, or if the process of step S8706 is executed, the display continuation period (specifically, the value corresponding to the next notification target switching timing is displayed in the switching timing counter of the work area 223 for non-specific control. Specifically, a value corresponding to 5 seconds) is set (step S8707).

  When a negative determination is made in step S8703, or when the process of step S8707 is executed, the display target setting area 276 provided in the work area 223 for non-specific control corresponds to the base value that is the current notification target. A process for setting display data to be executed is executed. Specifically, first, display type data corresponding to the value of the display target counter is set in the display target setting area 276 (step S8708). The display type data includes display data for causing the first notification display device 201 to display that the notification target of the first to fourth notification display devices 201 to 204 is the base value, and the notification target base. A display indicating whether the value corresponds to any of the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 is displayed on the second notification display device 202. Display data to be performed.

  Thereafter, the base value is read from the area corresponding to the value of the display target counter among the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234, and the read base The calculation result data corresponding to the first decimal place number and the second decimal place number is set in the display target setting area 276 (step S8709). The calculation result data includes display data for causing the third notification display device 203 to perform display corresponding to the first digit of the decimal point in the base value to be notified, and the second digit of the decimal point in the base value to be notified. Display data for causing the fourth notification display device 204 to perform display corresponding to the above.

  As described above, display data composed of display type data and calculation result data is set in the display target setting area 276. When the display data is transmitted to the display IC 266 in a second timer interruption process (FIG. 134) described later, the display corresponding to the display data is performed in the first to fourth notification display devices 201 to 204. .

  Further, the process of step S8709 is executed each time the display process (FIG. 131) is executed regardless of the timing of switching the base value to be notified. As described above, every time the calculation result storing process (FIG. 130) is executed, the base value is calculated using the current value in each of the counters 231a to 231e in the normal counter area 231, and the calculated base value is It is stored in the current state area 311 of the calculation result storage area 234. In this case, whenever the processing in step S8709 for setting the calculation result data in the display target setting area 276 as described above is performed, the display processing (FIG. 131) is executed irrespective of the base value switching timing of the notification target. When the base value is changed in a situation in which the base value of the current area 311 is a notification target, the changed base value can be notified.

  Thereafter, based on the value of the display target counter, it is determined whether or not the base value of the current area 311 is a notification target (step S8710), and the calculation initial flag provided in the work area 223 for non-specific control is set to “ It is determined whether or not “1” is set (step S8711). As described above, the calculation initial flag is the total number of game balls discharged from the game area PA in a situation where neither the opening / closing execution mode or the high frequency support mode is caused by the jackpot result since the base value calculation period is newly started. This is a flag for the main CPU 63 to specify whether or not the total number of game balls supplied to the game area PA has reached the initial reference number. When an affirmative determination is made in both step S8710 and step S8711, “1” is set to the initial display flag provided in the work area 223 for non-specific control (step S8712), and either of step S8710 or step S8711 is performed. If a negative determination is made at, the initial display flag is cleared to “0” (step S8713).

  The initial display flag is a first notification display device 201 for notifying that the base value in the current area 311 is the base value at the initial stage of calculation after the start of the calculation period in a situation where the base value is the notification target. And a flag for the main CPU 63 to specify that the second notification display device 202 should be blinked. When it is specified that the initial display flag is set to “1” in the second timer interrupt process (FIG. 134) described later, it is not necessary to simply transmit the display data stored in the display target setting area 276 to the display IC 266. In the case where the display corresponding to the display data is performed by the first to fourth notification display devices 201 to 204, the first notification display device 201 and the second notification display device 202 are blinked and displayed. The notification display device 203 and the fourth notification display device 204 are turned on. When it is specified that the initial display flag is not set to “1” in the second timer interrupt process (FIG. 134) described later, the display corresponding to the display data stored in the display target setting area 276 is displayed. When the first to fourth notification display devices 201 to 204 are used, all of the first to fourth notification display devices 201 to 204 are lit.

  On the other hand, if “1” is not set in the management start flag provided in the work area 223 for non-specific control and a negative determination is made in step S8701, the current area 311 is changed regardless of the value of the display target counter. The base value is read out, and operation result data corresponding to the first decimal place number and the second decimal place number in the read base value is set in the display target setting area 276 (step S8714). By transmitting display data corresponding to the calculation result data to the display IC 266, the first decimal place number in the base value of the current area 311 is displayed on the third notification display device 203, and the base of the current area 311 is displayed. The second decimal place in the value is displayed on the fourth notification display device 204. Due to the above configuration, in a situation where “1” is not set in the management start flag, the base value in the past calculation period is not notified, and only the base value calculated in the current calculation period is notified. Is done.

  In a situation in which “1” is not set in the management start flag, calculation result data is set in the display target setting area 276, but display type data is not set. Although details will be described later, when the base value is notified in a situation where the management start flag is not set to “1”, the display contents of the first notification display device 201 and the second notification display device 202 are managed. The display contents are different from those in the case where the base value is notified in the situation where the start flag is set to “1”.

  Next, main processing in the present embodiment executed by the main CPU 63 will be described with reference to the flowchart of FIG. Note that the processes in steps S8801 to S8825 in the main process are executed using a program for specific control and data for specific control in the main CPU 63.

  First, power-on initial setting processing is executed (step S8801). In the power-on initial setting process, for example, the process waits without proceeding to the next process until a predetermined time for waiting (specifically, 1 second) elapses after the main process is activated. The operation start and initial setting of the symbol display device 41 are completed in the predetermined period for the wait. In addition, access to the main RAM 65 is permitted.

  Thereafter, an internal function register setting process is executed (step S8802). In the internal function register setting process, the interrupt period of the first timer interrupt process (FIG. 133), which is a process that is activated by periodically interrupting the main process, is set to the first interrupt period (specifically, 4 milliseconds). And the interrupt period of the second timer interrupt process (FIG. 134), which is a process that is activated by periodically interrupting the main process, is a second interrupt period that is shorter than the first interrupt period. (Specifically, 2 milliseconds).

  That is, in the present embodiment, as in the above-described thirty-third embodiment, the first timer interrupt process and the second timer interrupt process exist so that the interrupt cycle is relatively long as the timer interrupt process. Both the first timer interrupt process and the second timer interrupt process are started by interrupting the main process. The second timer interrupt process is started by interrupting the first timer interrupt process. On the other hand, the first timer interrupt process is not started by interrupting the second timer interrupt process. Further, when both the first interrupt cycle and the second interrupt cycle have elapsed in a situation where both the first timer interrupt processing and the second timer interrupt processing are not executed, the second timer interrupt processing is performed regardless of the elapsed order of the cycles. It is started first from timer interrupt processing. In this regard, it can be said that the second timer interrupt process is a process activated in preference to the first timer interrupt process. However, the present invention is not limited to this, and the first timer interrupt process may be activated in preference to the second timer interrupt process.

  In the internal function register setting process, the first interrupt period of the first timer interrupt process is set in a predetermined register of the main CPU 63 and the second interrupt period of the second timer interrupt process is set in a specific register of the main CPU 63 To do. In addition, in the internal function register setting process, in addition to the setting of the first and second interrupt cycles, for example, the setting process of numerical ranges of various counters such as the numerical range of the hit random number counter C1 is executed.

  After that, “1” is set to the startup processing flag provided in the work area 221 for specific control (step S8803). Even if the first timer interrupt process is activated, the start-up process in-process flag executes the process for performing power failure monitoring, updating of various counters, and fraud monitoring among various processes set in the first timer interrupt process. On the other hand, this is a flag for the main CPU 63 to specify that the first timer interrupt process should be terminated without executing the process for advancing the game.

  FIG. 133 is a flowchart showing the first timer interrupt process in the present embodiment executed by the main CPU 63. The first timer interrupt process is periodically started at a 4 millisecond period which is the first interrupt period as already described. A program corresponding to the first timer interrupt process is set as a program for specific control.

  In steps S8901 to S8905, the same processes as those in steps S301 to S305 of the timer interrupt process (FIG. 11) in the first embodiment are executed. That is, the power failure monitoring is executed by executing the power failure information storage process in step S8901. Specifically, as in the power failure information storage process (FIG. 101) in the thirtieth embodiment, the power failure monitoring board 67 monitors whether or not a power failure signal corresponding to the occurrence of power interruption has been received. When the occurrence of the error is specified, an infinite loop occurs after the power failure process is executed. In the power failure process, “1” is set to a power failure flag provided in the work area 221 for specific control, a checksum is calculated, and the calculated checksum is stored in the work area 221 for specific control. Further, by executing the lottery random number update process in step S8902, the numerical information of the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the universal utility release counter C4 is updated, and in step S8903 The numerical information of the random number initial value counter CINI is updated by executing the random number initial value updating process, and the numerical information of the variation type counter CS is updated by executing the fluctuation counter updating process in step S8904. In step S8905, fraud detection processing is executed to monitor whether an event set as a fraud monitoring target has occurred. In the fraud detection process, the occurrence of multiple types of events is monitored, and by confirming that any of these multiple types of events has occurred, the game stop provided in the work area 221 for specific control Set “1” to the flag.

  After executing the processing of step S8901 to step S8905, it is determined whether or not “1” is set in any of the game stop flag and the startup processing flag provided in the work area 221 for specific control. (Step S8906). When “1” is not set in any of the game stop flag and the startup process flag (step S8906: NO), the processes of steps S8907 to S8920 are executed. In steps S8907 to S8919, the same processing as that in steps S8208 to S8220 of the first timer interrupt processing (FIG. 117) in the thirty-third embodiment is executed. In step S8920, although the management process is executed in the same manner as in step S8221 of the first timer interrupt process (FIG. 117) in the thirty-third embodiment, the content of the check process of the management execution process called in the management process Has already been explained. In the check process, update processing of the counters 231a to 231e in the normal counter area 231 is executed, and result calculation processing (FIG. 130) and display processing (FIG. 131) are executed.

  On the other hand, if “1” is set in at least one of the game stop flag and the startup process flag (step S8906: YES), the first timer interrupt process is executed without executing the processes of steps S8907 to S8920. finish. In other words, not only the situation where the game stop flag is set to “1” but also the case where the start-up process flag is set to “1”, the processing from step S8901 to step S8905 is performed in the first timer interrupt processing. On the other hand, the processing of step S8907 to step S8920 is not executed.

  As in the case of the thirty-third embodiment, the start-up processing flag indicates that the processing at the start of operating power supply (step S8801 to step S8819) is started in the main processing (FIG. 132) and interrupt permission (step S8805) is set. “1” is set before the operation is performed, and “0” is cleared before the process at the start of supplying the operating power is finished and the remaining process (steps S8822 to S8825) is started. In this case, as described above, in the first timer interrupt process, when the start process flag is set to “1”, the process of steps S8907 to S8920 is not executed, thereby supplying the operating power. It is possible to prevent the process for advancing the game from being executed in a situation where the process at the start (steps S8801 to S8819) is being executed. On the other hand, in the first timer interrupt process as described above, even when the start process flag is set to “1”, the process from step S8901 to step S8905 is executed to start the operation power supply start. Power outage monitoring is performed even in the situation where the above process (steps S8801 to S8819) is executed, and the hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated. Executed, and fraud detection is performed.

  In particular, even when the start-up process flag is set to “1”, the power failure information storage process (step S8901) is executed, so that the process at the start of supply of operating power (steps S8801 to S8819) ), Even if a power failure occurs, the power failure process can be executed on the power failure. In the power failure process, as described above, “1” is set to the power failure flag provided in the work area 221 for specific control, a checksum is calculated, and the calculated checksum is stored in the work area 221 for specific control. Therefore, when the supply of operating power is started again, it is possible to prevent the main RAM 65 from being identified as having an abnormality. As a result, even if a power failure occurs during the setting value update process (step S8819), the setting value selected at that time can be stored and held as the current setting value of the pachinko machine 10. . Therefore, even if a power failure occurs during the execution of the set value update process, it is not necessary to execute the set value update process again when the supply of operating power is started again.

  Incidentally, in the situation where the set value update process is being executed, neither the first timer interrupt process (FIG. 133) nor the second timer interrupt process (FIG. 134) is prohibited from being interrupted at any timing. It is possible. In this case, if the first timer interrupt process (FIG. 133) or the second timer interrupt process (FIG. 134) is interrupted and activated in the main process (FIG. 132) including the set value update process, The information of the return address of the main process (FIG. 132) for returning after the timer interrupt process is completed is saved in the stack area 222 for specific control, and the main side immediately before the timer interrupt process is started Information of various registers of the CPU 63 is saved in the stack area 222 for specific control. Then, when the timer interrupt process to be activated is completed, the process returns to the process of the main process (FIG. 132) corresponding to the return address information saved in the stack area 222 for specific control. The information saved in the specific control stack area 222 is restored to the various registers of the main CPU 63.

  Returning to the description of the main process (FIG. 132), after setting the startup process flag to “1” in step S8803, the initial check period (specifically, in the check counter provided in the work area 221 for specific control). A value corresponding to 5 seconds is set (step S8804). In this embodiment, when the supply of operating power to the main CPU 63 is started, can the display segments 321 to 324 provided in the first to fourth notification display devices 201 to 204 be in a normal light emission state? In order to make the game hall manager confirm whether or not, the display for check is performed on the first to fourth notification display devices 201 to 204 until the initial check period elapses after the processing of step S8804 is started. . Specifically, as the display for checking, as shown in the explanatory diagram of FIG. 128B, all the display segments 321 to 324 of the first to fourth notification display devices 201 to 204 are maintained in the light emitting state. . In step S8804, information corresponding to this initial check period is set in the checking counter.

  Note that the initial check period is required until the process for controlling the progress of the game is started when none of the processes in steps S8811, S8812, S8815, and S8819, which will be described later, is executed in the main process. The time is set longer than the maximum time. Therefore, the game may be started in a situation where the display for check is performed on the first to fourth notification display devices 201 to 204.

  Thereafter, interrupt permission is set (step S8805). As a result, the first timer interrupt process (FIG. 133) is interrupted and started at the first interrupt period, and the second timer interrupt process (FIG. 134) is interrupted and started at the second interrupt period. However, since “1” is set in the startup processing flag in step S8803, even if the first timer interrupt processing is started, outage monitoring and various counters of the various processing of the first timer interrupt processing are performed. While the process for performing update and fraud monitoring is executed, the first timer interrupt process is terminated without executing the process for advancing the game.

  Thereafter, in steps S8806 to S8825, processing similar to that in steps S7905 to S7924 of the main processing (FIG. 114) in the thirty-third embodiment is executed. Specifically, it is determined whether or not the reset button 68c has been pressed in step S8806. That is, it is determined whether or not the power supply operation of the pachinko machine 10 is performed and the supply of operating power to the MPU 62 is started in a state where the reset button 68c is pressed. Here, in the present embodiment, as in the thirty-third embodiment, the main controller 60 is provided with the setting key insertion portion 68a and the reset button 68c, but is not provided with the update button 68b. Further, the main control device 60 is provided with first to fourth notification display devices 201 to 204 as in the eleventh embodiment instead of the first to third notification display devices 69a to 69c.

  If the reset button 68c has not been pressed (step S8806: NO), it is determined whether or not “1” is set in the power failure flag provided in the work area 221 for specific control (step S8807). When the process at power failure is executed in the power failure information storage process (step S8901) of the first timer interrupt process (FIG. 133), “1” is set to the power failure flag. The power failure flag is a flag for the main CPU 63 to specify whether or not the power failure processing has been appropriately performed at the time of the previous power shutdown.

  If “1” is set in the power failure flag (step S8807: YES), a checksum is calculated for the work area 221 for specific control and the stack area 222 for specific control (step S8808). The checksum calculation method is the same as in the thirty-third embodiment. Thereafter, the work area 221 for specific control and the stack area for specific control which are calculated and stored in the work area 221 for specific control calculated in the power failure process executed immediately before the supply of the operating power to the MPU 62 is stopped. The checksum for 222 is read from the work area 221 for specific control, and the read checksum is compared with the checksum calculated in step S8808 (step S8809). Then, it is determined whether or not the checksums match (step S8810).

  If a negative determination is made in step S8807 or step S8810, that is, if "1" is not set in the power failure flag or the checksums do not match, the game stop flag provided in the work area 221 for specific control Is set to “1” (step S8811). When “1” is set in the game stop flag, the processing of step S8901 to step S8905 is executed in the first timer interrupt processing (FIG. 133), while the determination in step S8906 is affirmative, so that step S8907 is executed. The process of S8920 is not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the time of the previous power shutdown, or the work area 221 for specific control and the stack area 222 for specific control. If at least one of the checksums does not match due to a change in the information storage state since the last power-off, the process for power failure monitoring, various counter updates, and fraud monitoring is executed. On the other hand, the process for advancing the game is not executed.

  Thereafter, an abnormal command indicating that an abnormality has occurred regarding the power failure flag or the checksum at the start of the supply of operating power is transmitted to the sound emission control device 81 (step S8812). Upon receiving the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the information abnormality at the start of the supply of operating power, and “change the setting from the speaker unit 54. Is output. In addition, a character image “Please change settings” is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are terminated when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of operating power to the pachinko machine 10 is temporarily stopped, the above notification is issued when the supply of operating power to the pachinko machine 10 is resumed until the set value update process (step S8819) is executed. It is good also as a structure continued.

  When “1” is set in the power failure flag and the checksum is normal (step S8807 and step S8810: YES), it is determined whether or not the setting key insertion unit 68a is turned on using the setting key. Then, it is determined whether or not the front door frame 14 is open with respect to the inner frame 13 and the gaming machine main body 12 is open with respect to the outer frame 11 (step S8814). Whether the front door frame 14 is open or not with respect to the inner frame 13 is detected using the front door opening sensor 95 in the same manner as in the thirtieth embodiment, and the gaming machine main body 12 is The main body opening sensor 96 is used for detecting whether or not the body is in the open state, as in the thirtieth embodiment. The setting key insertion portion 68a is turned on using the setting key (step S8813: YES), and the front door frame 14 is in an open state with respect to the inner frame 13 and the gaming machine main body with respect to the outer frame 11 When 12 is in an open state (step S8814: YES), a setting confirmation process is executed (step S8815). Details of the setting confirmation process will be described later.

  If the reset button 68c has been pressed (step S8806: YES), a RAM clear process is executed (step S8816). The contents of the RAM clear process are the same as step S7915 of the main process (FIG. 114) in the thirty-third embodiment. Thereafter, the setting key insertion portion 68a is turned ON using the setting key (step S8817: YES), and the front door frame 14 is in an open state with respect to the inner frame 13, and the game is performed with respect to the outer frame 11. When the main body 12 is in the open state (step S8818: YES), the set value update process is executed (step S8819). Details of the set value update processing will be described later.

  When the process of step S8812 is executed, when the negative determination is made at step S8813 or step S8814, when the process of step S8815 is executed, when the negative determination is made at step S8817 or step S8818, or the process of step S8819 is executed. If it has been executed, the startup process flag in the work area 221 for specific control is cleared to “0” (step S8820). When the start-up process flag is cleared to “0”, the state in which the process for advancing the game is not executed even if the first timer interrupt process is started is released. In step S8820, the power failure flag in the work area 221 for specific control is also cleared to “0”.

  Thereafter, a return command is transmitted to the sound emission control device 81 (step S8821). The content of the information included in the return command and the processing content of the sound emission control device 81 when the return command is received are the same as in step S7920 of the main process (FIG. 114) in the thirty-third embodiment. .

  Thereafter, the process proceeds to the remaining process of steps S8822 to S8825. That is, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), but between one timer interrupt process and the next timer interrupt process. The remaining time will occur. The remaining time varies depending on the processing completion time of each timer interrupt process, but the remaining processes in steps S8822 to S8825 are repeatedly executed using such irregular time. In this regard, it can be said that the remaining processes in steps S8822 to S8825 are non-periodic processes that are performed irregularly. In steps S8822 to S8825, the same processes as steps S113 to S116 of the main process (FIG. 9) in the first embodiment are executed.

  Next, the second timer interrupt process in the present embodiment executed by the main CPU 63 will be described with reference to the flowchart of FIG. Note that the processing in steps S9001 to S9014 in the second timer interrupt processing is executed by the main CPU 63 using a program for specific control and data for specific control.

  First, in order to prohibit the generation of the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), an interrupt prohibition is set (step S9001). By prohibiting the generation of the first timer interrupt process (FIG. 133), the first timer interrupt process (FIG. 133) interrupts the second timer interrupt process (FIG. 134) even if the first interrupt period has elapsed. It becomes possible not to be started by. In addition, if the second timer interrupt process (FIG. 134) is inhibited from occurring, even if the second interrupt cycle elapses during the execution of the second timer interrupt process (FIG. 134), the second timer interrupt process is performed. It is possible to prevent the processing (FIG. 134) from being activated twice.

  Thereafter, update processing of the checking counter is executed (step S9002). In the updating process of the checking counter, when the value of the checking counter provided in the work area 221 for specific control is 1 or more, 1 is subtracted from the value of the checking counter. As a result, when the initial check period is measured using the checking counter, the value of the checking counter is periodically subtracted every time the second timer interrupt process (FIG. 134) is started. The Rukoto.

  Thereafter, it is determined whether or not “1” is set in the setting update display flag in the work area 221 for specific control (step S9003). The setting update display flag is a flag for specifying in the main CPU 63 whether or not the main CPU 63 is executing the setting value update processing (FIG. 137). As already described, the setting value update process (FIG. 137) is a situation where the process at the start of the supply of operating power is executed in the main process (FIG. 132) when the supply of operating power to the main CPU 63 is started. Although the second timer interrupt process (FIG. 134) will be executed, it is activated and interrupted even when the process at the start of supplying the operating power is being executed. Even in the situation where the value update process (FIG. 137) is being executed, the second timer interrupt process (FIG. 134) is interrupted and activated.

  The situation where the setting update display flag is set to “1” means that the current processing time of the second timer interrupt process (FIG. 134) is the setting value update process (FIG. 137) being executed by the main CPU 63. It means that the process has been started by interrupting the situation. When an affirmative determination is made in step S9003, a setting process for the fifth display data buffer 275 during the setting update is executed (step S9004). In the setting process, the set value of the pachinko machine 10 is updated by the first to fourth notification display devices 201 to 204, similarly to step S8403 of the second timer interruption process (FIG. 123) in the thirty-third embodiment. Display data for displaying the current status and the current setting value of the pachinko machine 10 are stored in the fifth display data buffer 275. As a result, as in the thirty-third embodiment, the first to fourth notification display devices 201 to 204 display that indicates that the setting value is being updated and display that indicates the current setting value. Is done.

  If a negative determination is made in step S9003, it is determined whether or not “1” is set in the setting confirmation display flag in the work area 221 for specific control (step S9005). The setting confirmation display flag is a flag for the main CPU 63 to specify whether or not the main CPU 63 is executing the setting confirmation processing (FIG. 136). As already described, the setting confirmation process (FIG. 136) is a situation where the process at the start of the supply of operating power is executed in the main process (FIG. 132) when the supply of operating power to the main CPU 63 is started. Although the second timer interrupt process (FIG. 134) will be executed, it is activated and interrupted even when the process at the start of supplying the operating power is being executed. Even in the situation where the confirmation process (FIG. 136) is being executed, the second timer interrupt process (FIG. 134) is interrupted and activated.

  The situation where the setting confirmation display flag is set to “1” means that the current processing time of the second timer interruption process (FIG. 134) is the setting confirmation process (FIG. 137) being executed by the main CPU 63. It means that the process has been started by interrupting the situation. If an affirmative determination is made in step S9005, a setting process for the fifth display data buffer 275 during setting confirmation is executed (step S9006). In the setting process, the set value of the pachinko machine 10 is confirmed on the first to fourth notification display devices 201 to 204 as in step S8405 of the second timer interrupt process (FIG. 123) in the thirty-third embodiment. Display data for displaying the current status and the current setting value of the pachinko machine 10 are stored in the fifth display data buffer 275. Accordingly, as in the thirty-third embodiment, the first to fourth notification display devices 201 to 204 display that indicates that the setting value is being confirmed and display that indicates the current setting value. Is done.

  If a negative determination is made in step S9005, a normal setting process is executed (step S9007). The normal setting process will be described later in detail.

  When the process of step S9004, step S9006, or step S9007 is executed, the process of step S9008 to step S9014 is executed. The processing contents of steps S9008 to S9014 are the same as those of steps S8407 to S8413 of the second timer interrupt process (FIG. 123) in the thirty-third embodiment.

  Specifically, first, the transmission state of the signal through the classification data signal line LN1 and the classification clock signal line LN2 is turned off (step S9008), and the transmission of the signal through the display data signal line LN3 and the display clock signal line LN4. The state is set to the OFF state (step S9009). Thereafter, the type counter update process provided in the work area 221 for specific control is executed (step S9010).

  The type counter is a counter for the main CPU 63 to specify a display data transmission target in the first to fifth display data buffers 271 to 275 in the current processing of the second timer interrupt process. When the value of the type counter is “1”, the display data of the first display data buffer 271 is a transmission target. When the value of the type counter is “2”, the display data of the second display data buffer 272 is a transmission target. When the value of the type counter is “3”, the display data in the third display data buffer 273 is to be transmitted, and when the value of the type counter is “4”, the display data in the fourth display data buffer 274 is If the type counter value is “5”, the display data in the fifth display data buffer 275 is the transmission target. In the type counter update process, 1 is added to the value of the type counter, and when the value of the type counter after the addition of 1 exceeds the upper limit “5”, the value of the type counter is set to “1”. . As a result, the display data transmission target is sequentially changed in the first to fifth display data buffers 271 to 275 for each processing time of the second timer interrupt process.

  Thereafter, type data corresponding to the value of the type counter is read from the main ROM 64 (step S9011). Specifically, when the value of the type counter is “1”, the type data corresponding to the first display circuit 261 is read from the main ROM 64, and when the value of the type counter is “2”, the second value is read. If the type data corresponding to the display circuit 262 is read from the main ROM 64 and the value of the type counter is “3”, the type data corresponding to the third display circuit 263 is read from the main ROM 64 and the value of the type counter is If “4”, the type data corresponding to the fourth display circuit 264 is read from the main ROM 64, and if the value of the type counter is “5”, the type data corresponding to the fifth display circuit 265 is read. Read from the side ROM 64.

  Thereafter, display data is read from the display data buffers 271 to 275 corresponding to the value of the type counter (step S9012). Specifically, the display data is read from the first display data buffer 271 when the value of the type counter is “1”, and is read from the second display data buffer 272 when the value of the type counter is “2”. When the display data is read, the display data is read from the third display data buffer 273 when the value of the type counter is “3”, and from the fourth display data buffer 274 when the value of the type counter is “4”. The display data is read, and when the value of the type counter is “5”, the display data is read from the fifth display data buffer 275.

  Thereafter, transmission processing of various signals is executed (step S9013). In the transmission process, signal output is performed on the classification data signal line LN1 and the classification clock signal line LN2 so that the classification data read in step S9011 is transmitted to the display IC 266. Further, in the transmission process, signal output to the display data signal line LN3 and the display clock signal line LN4 is performed so that the display data read in step S9012 is transmitted to the display IC 266.

  Thereafter, in order to permit the generation of the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), an interrupt permission is set (step S9014).

  FIG. 135 is a flowchart showing the normal setting process in step S9007 of the second timer interrupt process (FIG. 134). Note that the processing in steps S9101 to S9109 in the normal setting processing is executed by the main CPU 63 using a program for specific control and data for specific control.

  First, it is determined whether or not the value of the checking counter provided in the work area 221 for specific control is 1 or more (step S9101). When the value of the checking counter is 1 or more (step S9101: YES), it means that it is an initial check period. In this case, the check display data is set in the fifth display data buffer 275 in the work area 221 for specific control (step S9102). The display data set in the fifth display data buffer 275 is display data for controlling the display of the first to fourth notification display devices 201 to 204 as already described. In addition, the check display data is display data for causing the first to fourth notification display devices 201 to 204 to perform the display for check, that is, the first to fourth notification display devices 201 to 204. This is display data for setting all the display segments 321 to 324 to the light emitting state. By supplying the check display data to the display IC 266, as shown in the explanatory diagram of FIG. 128B, all of the first to fourth notification display devices 201 to 204 serve as check displays. The display segments 321 to 324 are in a light emitting state. Thereby, the manager of the game hall can grasp whether or not each of the display segments 321 to 324 of the first to fourth notification display devices 201 to 204 can be normally in a light emitting state.

  Here, the initial check period can be canceled when confirming the setting or updating the setting value. Such a cancelable configuration will be described. FIG. 136 is a flowchart showing the setting confirmation process executed in step S8815 of the main process (FIG. 132). Note that the processing from step S9201 to step S9206 in the setting confirmation processing is executed using the specific control program and the specific control data in the main CPU 63.

  First, an operation instruction command is transmitted to the sound emission control device 81 (step S9201). Upon receiving the operation instruction command, the sound emission control device 81 outputs a sound “Please operate the reset button 68 c” from the speaker unit 54. The notification is continued until the reset button 68c is pressed.

  Thereafter, it is determined whether or not the reset button 68c has been pressed (step S9202). If the reset button 68c has not been pressed, the process waits in step S9202. When the reset button 68c is pressed (step S9202: YES), the checking counter provided in the work area 221 for specific control is cleared to “0” (step S9203). This cancels the initial check period.

  Thereafter, “1” is set to a setting confirmation display flag provided in the work area 221 for specific control (step S9204). When “1” is set in the setting confirmation display flag, the second timer interrupt process (FIG. 134) makes an affirmative determination in step S9005 as already described, and the first to fourth notification display devices 201 to 201 are used. In the fifth display data buffer 275, a display indicating that the setting value of the pachinko machine 10 is being confirmed at 204 and a display indicating the current setting value of the pachinko machine 10 are stored in the fifth display data buffer 275. (Step S9006). Accordingly, as in the thirty-third embodiment, the first to fourth notification display devices 201 to 204 display that indicates that the setting value is being confirmed and display that indicates the current setting value. Is done.

  Thereafter, on condition that the setting key insertion unit 68a is turned off (step S9205: YES), the setting confirmation display flag in the work area 221 for specific control is cleared to “0” (step S9206). Thereby, the display which shows the present setting value of the pachinko machine 10, and the display which shows the present setting value of the pachinko machine 10 in the display devices 201 to 204 for the first to fourth notifications. Is released. In this case, the first to fourth notification display devices 201 to 204 start displaying the base value.

  When the setting confirmation process is started as described above, the initial check period is canceled halfway on the condition that the reset button 68c is pressed, and the first to fourth notification display devices 201 to 204 The set value is notified. Thereby, when supply of operating power to the main CPU 63 is started and main processing (FIG. 132) is started in the main CPU 63, processing at the start of supplying operating power in the main processing is executed. Even when the initial check period is started and the display for check is performed on the first to fourth notification display devices 201 to 204 in the situation where the operation is performed, the process at the start of supplying the operating power is executed. When confirming the set value in the current situation, it is possible to cancel the initial check period and display the current set value on the first to fourth notification display devices 201 to 204. Therefore, the set value can be confirmed without waiting for the initial check period to elapse.

  Further, even when the setting confirmation process (FIG. 136) is executed in the main process (FIG. 132), the initial check period starts first. It is possible to confirm the set value after confirming whether or not each of the display segments 321 to 324 can be normally in a light emitting state. This makes it possible to check the set value accurately.

  FIG. 137 is a flowchart showing the set value update processing executed in step S8819 of the main processing (FIG. 132). In addition, the process of step S9301-step S9310 in a setting value update process is performed using the program for specific control in the main side CPU63, and the data for specific control.

  First, an update start command is transmitted to the sound emission control device 81 (step S9301). Upon receiving the update start command, the voice light emission control device 81 outputs a voice “setting is being changed” from the speaker unit 54. The notification is continued until the set value update process is completed.

  Thereafter, it is determined whether or not the value of the setting value counter provided in the work area 221 for specific control is 1 or more corresponding to “setting 1” and 6 or less corresponding to “setting 6” (step). S9302). If the value of the set value counter is “0” or 7 or more, a negative determination is made in step S9302 and “1” is set in the set value counter (step S9303). Thereby, the setting value of the pachinko machine 10 becomes “setting 1”.

  If an affirmative determination is made in step S9302 or if the process of step S9303 is executed, it is determined whether or not the setting key insertion unit 68a is turned off using the setting key (step S9304). In this case, it may be configured to determine whether the setting key insertion unit 68a has been switched from the ON state to the OFF state, or may be configured to determine whether the setting key insertion unit 68a is in the OFF state.

  If the setting key insertion portion 68a has not been turned OFF (step S9304: NO), it is determined whether or not the reset button 68c has been pressed (step S9305). When the reset button 68c is pressed (step S9305: YES), on condition that “1” is not set in the setting update display flag provided in the work area 221 for specific control (step S9306: NO). In addition, “1” is set in the setting update display flag (step S9307), and the checking counter provided in the work area 221 for specific control is cleared to “0” (step S9308).

  The initial check period is canceled when the checking counter is cleared to “0”. Further, by setting “1” in the setting update display flag, the second timer interrupt process (FIG. 134) makes an affirmative determination in step S9003 as already described, and the first to fourth notification display devices. Display data for displaying the setting value of the pachinko machine 10 in 201 to 204 and the display data for displaying the current setting value of the pachinko machine 10 in the fifth display data buffer 275. Store (step S9004). As a result, as in the thirty-third embodiment, the first to fourth notification display devices 201 to 204 display that indicates that the setting value is being updated and display that indicates the current setting value. Is done.

  When an affirmative determination is made in step S9306, or when the process of step S9308 is executed, the value of the set value counter in the work area 221 for specific control is incremented by 1 (step S9309). As a result, each time the reset button 68c is pressed once, the set value is updated to one level higher. If the reset button 68c is not pressed (step S9305: NO) or if the value of the set value counter is incremented by 1, the process returns to step S9302, but the set value counter is updated in step S9302. If it is determined that the value is 7 or more, “1” is set to the set value counter in step S9303. As a result, when the reset button 68c is pressed once in the state of “setting 6”, the setting returns to “setting 1”.

  When the setting key insertion unit 68a is turned off (step 9304: YES), the setting update display flag in the work area 221 for specific control is cleared to “0” (step S9310). Thereby, on the first to fourth notification display devices 201 to 204, a display indicating that the set value of the pachinko machine 10 is being updated and a display indicating the current set value of the pachinko machine 10 are performed. The state to be released is released. In this case, the first to fourth notification display devices 201 to 204 start displaying the base value.

  When the set value update process is executed as described above, the initial check period is canceled halfway on the condition that the reset button 68c is pressed, and the first to fourth notification display devices 201 to 204 The set value is notified. Thereby, when supply of operating power to the main CPU 63 is started and main processing (FIG. 132) is started in the main CPU 63, processing at the start of supplying operating power in the main processing is executed. Even when the initial check period is started and the display for check is performed on the first to fourth notification display devices 201 to 204 in the situation where the operation is performed, the process at the start of supplying the operating power is executed. When the set value is updated in the current situation, it is possible to cancel the initial check period and display the current set value on the first to fourth notification display devices 201 to 204. Therefore, it is possible to update the set value while confirming the current set value without waiting for the initial check period to elapse.

  Further, even when the set value update process (FIG. 137) is executed in the main process (FIG. 132), the initial check period starts first, so that the first to fourth notification display devices 201 to 204 It is possible to update the set value after confirming whether or not each of the display segments 321 to 324 can be normally in a light emitting state. As a result, the set value can be updated accurately.

  In addition, the initial check period is canceled when the reset button 68c is pressed to update the set value in the set value update process (FIG. 137). Thereby, when the reset button 68c is pressed to update the set value, the initial check period is canceled accordingly, and the operability for canceling the initial check period can be improved. Become.

  Returning to the description of the normal setting process (FIG. 135), when the value of the checking counter is “0” and not the initial check period (step S9101: NO), the non-specific control work area 223 is provided. It is determined whether or not “1” is set in the management start flag (step S9103). If “1” is not set in the management start flag (step S9103: NO), the pre-management start display setting process is executed for the first and second notification display devices 201 and 202 (step S9104). In the setting process, display data for setting all display segments 321 and 322 in the light emitting state in the first and second notification display devices 201 and 202 is set in the fifth display data buffer 275. The first and second notification display devices 201 and 202 are not limited to the configuration in which all the display segments 321 and 322 are in a light emitting state, and the first and second notification display devices 201 and 202 are not limited to the configuration. A configuration may be adopted in which blinking display is performed in all the display segments 321 and 322 in each of 202.

  Thereafter, the calculation result data set in the display target setting area 276 in the work area 223 for non-specific control is read (step S9105), and the read calculation result data is read to the third and fourth notification display devices 203 and 204. The display data to be applied is set in the fifth display data buffer 275 (step S9106). As described above, in the display process (FIG. 131), when “1” is not set in the management start flag (step S8701: NO), the base value is read from the current area 311 and the first decimal point in the read base value is read. The calculation result data corresponding to the first digit and the second digit of the decimal point is set in the display target setting area 276 (step S8714). In step S9106, the calculation result data is set in the fifth display data buffer 275 as display data to be applied to the third and fourth notification display devices 203 and 204.

  As the display data set in the fifth display data buffer 275 in step S9104 and step S9106 is supplied to the display IC 266, the first and second notification displays are displayed as shown in the explanatory diagram of FIG. In the situation where all the display segments 321 and 322 are in the light emitting state in each of the devices 201 and 202, the first decimal place of the base value calculated in the current calculation period by the third notification display device 203 Are displayed, and the fourth informing display device 204 displays the number of the second decimal place of the base value calculated in the current calculation period. In each of the first and second notification display devices 201 and 202, the numbers corresponding to the base values are displayed on the third and fourth notification display devices 203 and 204 while all the display segments 321 and 322 are in a light emitting state. By doing so, it becomes possible for the manager of the game hall to recognize that the currently reported base value is a base value in a situation where “1” is not set in the management start flag.

  Further, in the situation where “1” is set in the management start flag, as already explained, every time the display continuation period (specifically, 5 seconds) elapses, the current area 311 → the first history area 312 → the second The base value to be notified is switched in the first to fourth notification display devices 201 to 204 in a predetermined order of 2 history area 313 to 3rd history area 314, while the management start flag is set to “ In a situation where “1” is not set, the base value of the current area 311 is maintained as a notification target. Thereby, when the operation check of the pachinko machine 10 is performed at the shipment stage of the pachinko machine 10, the current base value can be confirmed at an arbitrary timing.

  When “1” is set in the management start flag (step S9103: YES), the display data set in the display target setting area 276 in the work area 223 for non-specific control is read, and the read display data is read as the first display data. 5 is set in the display data buffer 275 (step S9107). If the display data is supplied to the display IC 266 and the base value of the current area 311 is to be notified, the display as shown in the explanatory diagram of FIG. 127 (a) is for the first to fourth notifications. If the base value of the first history area 312 is a notification target that is displayed on the display devices 201 to 204, a display as shown in the explanatory diagram of FIG. 127 (b) is displayed for the first to fourth notifications. If the base value of the second history area 313 is a notification target, the display shown in the explanatory diagram of FIG. 127 (c) is displayed on the first to fourth notification devices. If the base value of the third history area 314 is a notification target, the display as shown in the explanatory diagram of FIG. 127 (d) is displayed in the first to fourth notification display devices 201. ~ 204.

  Thereafter, it is determined whether or not “1” is set in the initial display flag provided in the work area 223 for non-specific control (step S9108). The initial display flag is a first notification in order to notify that the base value is an initial calculation base value after the start of the calculation period in the situation where the base value of the current area 311 is a notification target as described above. This is a flag for the main CPU 63 to specify that the display device 201 and the second notification display device 202 should be blinked. When “1” is set in the initial display flag (step S9108: YES), the flashing setting process is executed for the first and second notification display devices 201 and 202 (step S9109).

  In the blink setting process, when the display corresponding to the display data currently set in the fifth display data buffer 275 is performed on the first and second notification display devices 201 and 202, the display is blinked. Make settings to make it work. Specifically, the display data for the first and second notification display devices 201 and 202 is set to the display data currently set in the fifth display data buffer 275 as the setting for causing the display to blink. Corresponding data is transmitted to the display IC 266 until a predetermined lighting period (for example, 0.5 seconds) elapses, and then all the display segments 321 and 322 of the first and second notification display devices 201 and 202 are turned off. Data to be set is transmitted to the display IC 266 until a predetermined extinction period (for example, 0.5 seconds) elapses, and thereafter, the predetermined lighting period and the predetermined extinction period are alternately repeated. As a result, when the base value in the current area 311 becomes a notification target immediately after the start of the new calculation period of the base value, the calculation initial display is performed on the first and second notification display devices 201 and 202. The management of the game hall may be made aware that the current base value reported on the first to fourth notification display devices 201 to 204 is immediately after the start of a new calculation period. It becomes possible.

  Next, display contents of the first to fourth notification display devices 201 to 204 when supply of operating power to the main CPU 63 is started will be described with reference to the time chart of FIG. 138. FIG. 138 (a) shows the initial check period, and FIG. 138 (b) shows the base value in the first to fourth notification display devices 201 to 204 in a situation where “1” is not set in the management start flag. 138 (c) shows the base values stored in the various areas 311 to 314 of the calculation result storage area 234 in the first to fourth notification display devices 201 to 204 in sequence. 138 (d) shows a display indicating that the set value of the pachinko machine 10 is being updated and a display indicating the current set value of the pachinko machine 10 are first to fourth. FIG. 138 (e) shows a display period indicating that the set value of the pachinko machine 10 is being confirmed and the current state of the pachinko machine 10 and the display period during the setting update performed in the notification display devices 201 to 204. Setting value It shows the setting confirmation during a display period that is performed in the display is the first to fourth notification display device 201 to 204 shown, FIG. 138 (f) shows the timing of the reset button 68c is pressed.

  First, when the supply of operating power to the main CPU 63 is started in a situation where the management start flag is not set to “1”, a setting confirmation process (FIG. 136) A case where the set value update process (FIG. 137) is not executed will be described.

  At the timing of t1, the initial check period starts as shown in FIG. 138 (a). Thereby, as shown in the explanatory diagram of FIG. 128B, the display for check is started in the first to fourth notification display devices 201 to 204.

  Thereafter, at the timing of t2, the initial check period ends without being canceled halfway as shown in FIG. 138 (a). In this case, as shown in FIG. 138 (b), the pre-management display period starts at the timing t2. In the display period before the start of management, as shown in the explanatory diagram of FIG. 128C, in the first notification display device 201 and the second notification display device 202, all the display segments 321 and 322 are in the light emitting state, On the third notification display device 203 and the fourth notification display device 204, a number corresponding to the current base value is displayed.

  After that, at the timing of t3, in the situation where “1” is not set in the management start flag and neither the opening / closing execution mode or the high frequency support mode due to the jackpot result, the game balls discharged from the game area PA The total number (that is, the total number of game balls supplied to the game area PA) reaches the management start reference number that is smaller than the shift reference number. As a result, when the management start flag is set to “1”, the pre-management display period ends as shown in FIG. 138 (b). In this case, the normal display period starts at the timing t3 as shown in FIG. 138 (c). In the normal display period, as shown in FIGS. 127 (a) to 127 (d), the base values stored in the various areas 311 to 314 in the calculation result storage area 234 are the first to fourth notification display devices 201 to 204. Will be notified sequentially.

  Next, in the situation where “1” is set in the management start flag, the supply of operating power to the main CPU 63 is started, and the setting confirmation processing (FIG. 136) is performed in the processing at the start of operating power supply. ) And the setting value update process (FIG. 137) are not executed.

  As shown in FIG. 138 (a), the initial check period starts at the timing of t4. Thereby, as shown in the explanatory diagram of FIG. 128B, the display for check is started in the first to fourth notification display devices 201 to 204.

  Thereafter, at the timing of t5, as shown in FIG. 138 (a), the initial check period ends without being canceled halfway. In this case, the normal display period starts at the timing t5 as shown in FIG. 138 (c). In the normal display period, as shown in FIGS. 127 (a) to 127 (d), the base values stored in the various areas 311 to 314 in the calculation result storage area 234 are the first to fourth notification display devices 201 to 204. Will be notified sequentially.

  Next, when the supply of operating power to the main CPU 63 is started in a situation where the management start flag is set to “1”, the set value update processing (FIG. 137) is performed in the processing at the start of operating power supply. ) Will be described.

  At the timing of t6, the initial check period is started as shown in FIG. 138 (a). Thereby, as shown in the explanatory diagram of FIG. 128B, the display for check is started in the first to fourth notification display devices 201 to 204.

  Thereafter, set value update processing (FIG. 137) is started in the middle of the initial check period, and the reset button 68c is pressed at the timing of t7 as shown in FIG. 138 (f). As a result, the initial check period is ended halfway at the timing of t7 as shown in FIG. 138 (a), and the display period during setting update is started at the timing of t7 as shown in FIG. 138 (d). The

  Thereafter, as shown in FIG. 138 (d), the display period during setting update ends at the timing of t8. In this case, the normal display period starts at the timing t8 as shown in FIG. 138 (c). In the normal display period, as shown in FIGS. 127 (a) to 127 (d), the base values stored in the various areas 311 to 314 in the calculation result storage area 234 are the first to fourth notification display devices 201 to 204. Will be notified sequentially.

  Next, in the situation where “1” is set in the management start flag, the supply of operating power to the main CPU 63 is started, and the setting confirmation processing (FIG. 136) is performed in the processing at the start of operating power supply. ) Will be described.

  At the timing of t9, the initial check period starts as shown in FIG. 138 (a). Thereby, as shown in the explanatory diagram of FIG. 128B, the display for check is started in the first to fourth notification display devices 201 to 204.

  Thereafter, setting confirmation processing (FIG. 136) is started in the middle of the initial check period, and the reset button 68c is pressed at the timing of t10 as shown in FIG. 138 (f). As a result, the initial check period ends in the middle as shown in FIG. 138 (a) at the timing of t10, and the display period during setting confirmation starts as shown in FIG. 138 (e) at the timing of t10. The

  Thereafter, as shown in FIG. 138 (e), the display period during setting confirmation ends at the timing of t11. In this case, the normal display period starts at the timing t11 as shown in FIG. 138 (c). In the normal display period, as shown in FIGS. 127 (a) to 127 (d), the base values stored in the various areas 311 to 314 in the calculation result storage area 234 are the first to fourth notification display devices 201 to 204. Will be notified sequentially.

  It should be noted that the setting confirmation process is performed in the process at the start of the supply of the operating power when the supply of the operating power to the main CPU 63 is started in the situation where the management start flag is not set to “1” (FIG. 136). Alternatively, when the setting value update process (FIG. 137) is executed and the initial check period is canceled halfway, the display period before the start of management is started after the display period during setting update or the display period during setting confirmation is ended. It will be.

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

  As a check display, an initial check period in which each of the display segments 321 to 324 in each of the first to fourth notification display devices 201 to 204 is in a light emitting state may occur. As a result, it is possible to confirm whether or not each of the display segments 321 to 324 is in a light emitting state, and confirm whether or not the first to fourth notification display devices 201 to 204 are normal. It becomes possible to do.

  When the supply of operating power to the main CPU 63 is started, the initial check period of the first to fourth notification display devices 201 to 204 is started. Thereby, when the supply of operating power is started, it is possible to quickly confirm whether or not the first to fourth notification display devices 201 to 204 are normal.

  Each time the supply of operating power to the main CPU 63 is started, the initial check period of the first to fourth notification display devices 201 to 204 is started. Thereby, it is possible to check whether or not the first to fourth notification display devices 201 to 204 are normal each time the supply of operating power is started.

  When supply of operating power to the main CPU 63 is started, the initial check period of the first to fourth notification display devices 201 to 204 is started without requiring any special operation. Thereby, it becomes possible to make it easy to confirm whether or not the first to fourth notification display devices 201 to 204 are normal.

  Even when the initial check period has not elapsed, when a cancel trigger occurs, the above-described check display on the first to fourth notification display devices 201 to 204 is terminated halfway. Thereby, even during the initial check period, it is possible to end the above-mentioned display for check and cause the first to fourth notification display devices 201 to 204 to perform another display.

  In the case where the supply of operating power to the main CPU 63 is started and before the process for controlling the progress of the game is executed, the initial check period is started and the first to fourth notification display devices 201 to 201 are started. At 204, the check display is started. Thereby, it is possible to check whether or not the first to fourth notification display devices 201 to 204 are normal before the game is started.

  In a configuration in which processing at the start of supply of operating power is being executed, in a configuration in which predetermined setting related processing such as setting confirmation processing (FIG. 136) and setting value update processing (FIG. 137) is executed, start of supply of operating power The initial check period is started in the situation where the time process is being executed. As a result, it is possible to consolidate not only predetermined setting-related processing but also processing for starting the initial check period with respect to processing at the start of supply of operating power.

  In the setting confirmation process (FIG. 136) and the setting value update process (FIG. 137), these predetermined settings are used in the configuration in which the display corresponding to the current setting value is performed on the first to fourth notification display devices 201 to 204. Before the related process is executed, an initial check period is started, and the display for checking is started on the first to fourth notification display devices 201 to 204. Thus, after confirming whether or not the first to fourth notification display devices 201 to 204 are normal, the current set values are confirmed using the first to fourth notification display devices 201 to 204. It becomes possible to do. Therefore, the set value can be confirmed accurately.

  Based on the execution of the setting confirmation process (FIG. 136) or the set value update process (FIG. 137) in the situation of the initial check period, even if the initial check period has not elapsed, the first to fourth notifications are used. The check display on the display devices 201 to 204 is terminated halfway. Thereby, when the setting confirmation process (FIG. 136) or the set value update process (FIG. 137) is executed, the first to fourth notification display devices 201 to 201 do not have to wait for the initial check period to elapse. It is possible to display the current set values on the first to fourth notification display devices 201 to 204 by terminating the above-described checking process in 204. Therefore, the current set value can be confirmed at an early stage.

  When the setting check process (FIG. 136) or the set value update process (FIG. 137) is executed in the situation of the initial check period, and the reset button 68c is pressed, the initial check period has elapsed. Even if it does not exist, the display for checking in the first to fourth notification display devices 201 to 204 is terminated halfway. As a result, the initial check period can be ended at an arbitrary timing after the setting confirmation processing (FIG. 136) or the setting value update processing (FIG. 137) is started. For example, when the setting confirmation process (FIG. 136) or the set value update process (FIG. 137) is started, the game hall manager sufficiently confirms that the first to fourth notification display devices 201 to 204 are normal. After confirming the above, it is possible to end the above-mentioned display for checking in the first to fourth notification display devices 201 to 204 and start displaying the current set values.

  In the setting value update process (FIG. 137), the setting value to be selected is updated by pressing the reset button 68c. In this case, when the reset button 68c is pressed as described above, the display for checking is ended in the first to fourth notification display devices 201 to 204, and the display of the current set value is started. By doing so, a dedicated operation for ending the display for checking and starting the display of the current set value is not necessary. Therefore, it is possible to improve the workability of the work for updating the set value.

  The calculation result storage area 234 stores a plurality of base values derived using information in the normal counter area 231 in different periods. As a result, it is possible to grasp the base value in a plurality of periods, so that it is possible to accurately grasp the ratio of the number of prize balls to the number of game balls supplied to the game area PA.

  The calculation result storage area 234 is provided with a current area 311 in which the latest base value is stored and first to third history areas 312 to 314 in which base values derived earlier are stored. Yes. Thereby, it is possible to grasp not only the latest one but also the past one in the ratio of the number of prize balls to the number of game balls supplied to the game area PA.

  Base values that are repeatedly calculated at a relatively short period before one calculation period elapses are stored in the current area 311, and the base values calculated when one calculation period elapses are the first to third base values. Stored in the history areas 312 to 314. As a result, it becomes possible to grasp the latest ratio of the number of prize balls to the number of game balls supplied to the game area PA, and to grasp the above-mentioned ratio in the past in one calculation period. Is possible. Moreover, since the base value in the unit of one calculation period is stored in the first to third history areas 312 to 314, the number of base values stored in the first to third history areas 312 to 314 is suppressed. It becomes possible.

  Based on the elapse of one calculation period, the various counters 231a to 231e in the normal counter area 231 are cleared to “0”. This makes it possible to reduce the storage capacity required in the normal counter area 231. Even if the various counters 231a to 231e in the normal counter area 231 are cleared to “0” as described above, the base values calculated when one calculation period has passed are the first to third base values. Since it is stored in the history areas 312 to 314, it becomes possible to grasp the ratio of the number of prize balls to the number of game balls supplied to the game area PA in the past calculation period later.

  A plurality of history areas 312 to 314 are provided as areas for storing past base values. Thereby, it becomes possible to compare base values in a plurality of past calculation periods.

  The base values stored in each of the current area 311, the first history area 312, the second history area 313, and the third history area 314 are sequentially displayed on the first to fourth notification display devices 201 to 204. Thereby, it becomes possible to grasp | ascertain the base value in a some calculation period separately, suppressing the number of the apparatuses 201-204 for alerting | reporting.

  Even when the process for starting the supply of operating power is being executed, the occurrence of a power failure is monitored and the occurrence of a power failure is identified by executing the power failure information storage process (step S8901). Processing at power failure is executed. As a result, when a power failure occurs in a situation where the process at the start of the supply of operating power is being performed, it is possible to appropriately deal with it.

  In the configuration in which the power failure information storage process (step S8901) is included in the first timer interrupt process (FIG. 133), the first timer interrupt process is performed even when the process at the start of the supply of operating power is being executed. Interrupted and activated. As a result, it is possible to periodically monitor the occurrence of a power outage even in a situation where processing at the start of supplying operating power is being performed.

  The first timer interrupt process (FIG. 133) is interrupted and activated even when the remaining process is being executed after the process at the start of the supply of operating power is completed. As a result, it is possible to periodically monitor the occurrence of a power failure in the situation where the process at the start of the supply of operating power is being executed using the first timer interrupt process that is activated by interrupting the remaining process. Become.

  If the first timer interrupt process (FIG. 133) is interrupted and activated in the situation where the process at the start of the supply of operating power is being executed, the startup process in progress flag provided in the work area 221 for specific control is set to “ When “1” is set, processing for advancing the game is not executed. As a result, even in the situation where the process at the start of the supply of operating power is being executed, the first timer interrupt process is interrupted and activated to periodically monitor the occurrence of a power failure. It is possible to prevent the process for advancing the game from being executed in a situation where the process at the start of supply is being executed.

  In the configuration in which the setting value update process (FIG. 137) is executed in the situation where the process at the start of the supply of operating power is being performed, the power failure information A storage process (step S8901) is executed. As a result, even if a power failure occurs during the setting of the setting value to be used, it is possible to appropriately cope with it.

  The check display of the first to fourth notification display devices 201 to 204 is not limited to a configuration that is ended when the initial check period has elapsed, and an operation for ending the check display. It is good also as a structure by which the said display for a check is continued until is performed. For example, the reset button 68c may be operated regardless of whether the setting confirmation process (FIG. 136) or the setting value update process (FIG. 137) is executed. Alternatively, an operation unit other than the reset button 68c may be operated. In this case, the display for checking is continued in the first to fourth notification display devices 201 to 204 until the base value or the set value is confirmed on the first to fourth notification display devices 201 to 204. Therefore, it is possible to confirm the base value or the set value after confirming whether the first to fourth notification display devices 201 to 204 are normal. Further, since the display for check is terminated based on the operation of the operation unit, the display for check can be terminated at a desired timing.

  In addition, when a predetermined operation unit such as the update button 68b or the reset button 68c is operated regardless of whether the supply of operating power is started, the first to fourth notification display devices 201 to 204 are used for checking. The display may be configured to start. In this case, the check display can be started at a desired timing when the base value or the set value is confirmed. Further, in the configuration, the check display may be terminated when a predetermined period (for example, 5 seconds) elapses, and the predetermined operation unit operated to start the check display or a different operation from the predetermined operation unit. The display for checking may be terminated when the operation unit is operated.

  In addition, when supply of operating power to the main CPU 63 is started in a state where a specific operation unit other than the reset button 68c such as the update button 68b is operated, the display devices 201 to 204 of the first to fourth notifications are displayed. A configuration may be adopted in which the display for check is not started when the display for check is started and the supply of the operating power to the main CPU 63 is started without operating the specific operation unit. In this case, in the configuration in which the check display is performed when the supply of the operating power is started, it is possible to select whether or not to start the check display by the operation of the game hall manager.

  In addition, regardless of whether or not the gaming machine main body 12 is in the open state, it is not limited to the configuration in which the base value is displayed on the first to fourth notification display devices 201 to 204. May be configured such that the base value is displayed on the first to fourth notification display devices 201 to 204 when it is specified based on the detection result of the main body opening sensor 96 that the device is in the open state. In this case, when the gaming machine main body 12 is in an open state, first, the check display of the first to fourth notification display devices 201 to 204 is started, and then the first to fourth notification display devices 201 to 201 are started. The base value may be displayed at 204. Thereby, before confirming the base value, it is possible to confirm whether or not the first to fourth notification display devices 201 to 204 are normal. Further, in the configuration, the check display may be terminated when a predetermined period (for example, 5 seconds) elapses, and the predetermined operation unit operated to start the check display or a different operation from the predetermined operation unit. The display for checking may be terminated when the operation unit is operated.

  Further, when the main process (FIG. 132) is started in a state where the condition for executing the setting confirmation process (FIG. 136) is satisfied, the check display of the first to fourth notification display devices 201 to 204 is displayed. If the main process is started without satisfying the condition for executing the setting confirmation process without being started, the check display may be started. In this case, it is possible to prevent the display for checking from being performed when it is determined that the setting value is confirmed.

  Further, when the main process (FIG. 132) is started in a state where the condition for executing the set value update process (FIG. 137) is satisfied, the display for check of the first to fourth notification display devices 201 to 204 is displayed. When the main process is started without satisfying the condition for executing the set value update process without being started, the display for check may be started. In this case, it is possible to prevent the check display from being performed when it is determined that the set value is updated.

  When the main process (FIG. 132) is started in a state where either the condition for executing the setting confirmation process (FIG. 136) or the condition for executing the set value update process (FIG. 137) is satisfied. The main process in a state where both the conditions for executing the setting confirmation process and the conditions for executing the set value update process are not satisfied without the display for checking of the first to fourth notification display devices 201 to 204 being started. The display for checking may be configured to start when is started. In this case, it is possible to prevent the check display from being performed when it is confirmed that the setting value is confirmed or the setting value is updated.

  Moreover, in the display for a check, it is not limited to the structure by which each display segment 321-324 in each of the 1st-4th alerting | reporting display apparatuses 201-204 is maintained in a light emission state, The 1st-4th alerting | reporting. The display segments 321 to 324 in the display devices 201 to 204 may be in a blinking state. Further, in the display for check, each of the display segments 321 to 324 in the first to fourth notification display devices 201 to 204 is sequentially turned on one by one or a plurality of parts, and the range of the initial check period The display segments 321 to 324 may be in a light emitting state at least once.

  In addition, the process for performing the display for check in the first to fourth notification display devices 201 to 204 is not limited to the configuration executed as the process corresponding to the specific control, and the process corresponding to the non-specific control. It is good also as a structure performed as.

  When no base value is stored in any of the first to third history areas 312 to 314 of the calculation result storage area 234, the history areas 312 to 314 are displayed in the first to fourth notification display devices 201. It is good also as a structure which is not a notification target in -204. In this case, for example, when base values are stored in the current status area 311 and the first history area 312, but base values are not stored in the second history area 313 and the third history area 314, the display continuation period Each time, the notification target in the first to fourth notification display devices 201 to 204 is switched between the current area 311 and the first history area 312, and the second history area 313 and the third history area 314 are It will not be a notification target.

  Further, the current value area 311, the first history area 312, the second history area 313, and the third history area 314 of the calculation result storage area 234 store base values expressed as decimal numbers up to the second decimal place. However, the present invention is not limited to this, and information on the combination of the first digit of the decimal point and the second digit of the decimal point in the base value may be stored. The total number of game balls to be calculated (K91 × “the number of winning balls for winning in the general winning opening 31” + K92 × “the number of winning balls for winning in the special electricity winning device 32” + K93 × “the number The number of winning balls for winning in the first operating port 33 + K94 × “the number of winning balls for winning in the second operating port 34”) and the total number of game balls discharged from the technique area PA (K91 + K92 + K93 + K9) + K95) a combination of information and may be configured to be stored. In the former case, it is possible to set the information of the various areas 311 to 314 as they are in the display target setting area 276, and in the latter case, the base value is calculated after using the information of the various areas 311 to 314. Information about the first decimal place number and the second decimal place number extracted from the base value is set in the display target setting area 276.

  Further, the calculation result storage area 234 may be configured to include only the current area 311 and the first history area 312 as areas for storing the base value. Only two history areas 313 may be provided. Further, a configuration may be adopted in which four or more areas are provided as history areas for storing past base value information.

  In addition, the calculation result storage area 234 has various areas 311 to 314 fixed on the address, and the base value is not limited to the configuration in which the various areas 311 to 314 are shifted as necessary. ˜314 may be provided as ring buffers.

  Further, instead of the configuration in which the base value is calculated as the aspect information, the 61st to 68th parameters may be calculated as in the fifteenth embodiment. In this case, all of the 61st to 68th parameters may be stored in each of the current area 311, the first history area 312, the second history area 313, and the third history area 314 of the calculation result storage area 234. The current area 311 may store the 61st to 68th parameters, but the first to third history areas 312 to 314 may store some parameters such as only the 61st parameter.

  In addition to or instead of the base value, the occurrence probability of the jackpot result may be calculated and stored as the aspect information, or the occurrence probability of the high frequency support mode may be calculated and stored.

  Also, the trigger for shifting the base value in the various areas 311 to 314 in the calculation result storage area 234 is limited to the case where the total number of game balls discharged from the game area PA is equal to or greater than the shift reference number. Instead, the shift may be performed when a predetermined period (for example, 8 hours) elapses, or the shift may be performed when the supply of operating power to the main CPU 63 is stopped. The shift may be performed when the supply of operating power to the CPU 63 is started, or the shift may be performed when the set value of the pachinko machine 10 is changed. Moreover, it is good also as a structure where there are multiple kinds of triggers for the shift.

  Further, until “1” is set to the management start flag provided in the work area 223 for non-specific control, the display segments 321 and 322 in the first and second notification display devices 202 are in the light-emitting state. The display segments 321 and 322 in each of the first and second notification display devices 202 may be in a blinking state. Further, until “1” is set in the management start flag, “bL .--” → “b1 .--” → “b2 .--” → in the first to fourth notification display devices 201 to 204 → The display of “b3 .--” may be repeated.

  In addition, until “1” is set in the management start flag provided in the work area 223 for non-specific control, the display segments 321 to 324 in the first to fourth notification display devices 201 to 204 are displayed. The display segments 321 and 322 in each of the first and second notification display devices 201 and 202 are in the light emission state or the blinking state without performing the display for checking to be in the light emission state, and the third and fourth notifications. The display corresponding to the fact that “1” is not set in the management start flag may be performed such that the display corresponding to the current base value is performed on the display devices 203 and 204 for use.

  Also, if the game stop flag is set to “1” because the power failure flag is not set to “1” or the check sum does not match, the progress of the game is stopped. In the display devices 201 to 204, the display segments 321 to 324 may be in a light emitting state as in the check display, and the display segments 321 to 324 may be in a blinking state.

  Further, the display control of the first to fourth notification display devices 201 to 204 is not limited to the configuration performed by the main CPU 63, and may be configured by dedicated control means, and the sound emission control device 81. The configuration may be performed by the display control device 82. In this case, when the base value is displayed on the first to fourth notification display devices 201 to 204, the base value to be notified is transmitted from the main CPU 63 to the control means serving as the control subject. When displaying the set value on the fourth notification display devices 201 to 204, the set value to be notified is transmitted from the main CPU 63 to the control means serving as the control subject. In addition, when processing at the start of supply of operating power is executed in the main CPU 63, the first to fourth notification display devices 201 to 204 are in a situation where processing at the start of supply of operating power is being executed. Thus, information corresponding to the start of the check display is transmitted from the main CPU 63 to the control means serving as the control entity so that the check display is started.

<Thirty-sixth embodiment>
In the present embodiment, the processing configuration of the main process executed by the main CPU 63 is different from that of the 35th embodiment. Hereinafter, a configuration different from the above-described thirty-fifth embodiment will be described. The description of the same configuration as that in the thirty-fifth embodiment is basically omitted.

  FIG. 139 is a flowchart showing main processing in the present embodiment which is executed by the main CPU 63. Note that the processing in steps S9401 to S9426 in the main processing is executed using a program for specific control and data for specific control in the main CPU 63.

  In steps S9401 to S9403, the same processes as those in steps S8801 to S8803 of the main process (FIG. 132) in the thirty-fifth embodiment are executed. Thereafter, interrupt permission is set (step S9404). As a result, the first timer interrupt process (FIG. 133) is interrupted and started at the first interrupt period, and the second timer interrupt process (FIG. 134) is interrupted and started at the second interrupt period. However, since “1” is set in the startup process flag in step S9403, even if the first timer interrupt process is started, outage monitoring and various counters of the various processes of the first timer interrupt process are started. While the process for performing update and fraud monitoring is executed, the first timer interrupt process is terminated without executing the process for advancing the game.

  After that, information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the work area 221 for specific control (step S9405). The value set in the checking counter is decremented by 1 every time the second timer interrupt process (FIG. 134) is started, as in the 35th embodiment. When a value of 1 or more is set in the checking counter, the display for checking is performed in the first to fourth notification display devices 201 to 204 as in the thirty-fifth embodiment.

  Thereafter, it is determined whether or not the value of the checking counter is “0” (step S9406). Then, the process waits in step S 9406 until the value of the checking counter becomes “0”. Thereby, the display for check in the first to fourth notification display devices 201 to 204 is continued until the initial check period set in step S9405 elapses.

  Then, the process of step S9407-step S9426 is performed. The processing content of these steps S9407 to S9426 is the same as that of steps S8806 to S8825 of the main processing (FIG. 132) in the thirty-fifth embodiment.

  According to the above configuration, when supply of operating power to the main CPU 63 is started and processing at the start of supplying operating power is started in the main CPU 63, the first to fourth notification display devices 201 to 204 are displayed. The check display is performed, and the progress of the process at the start of the supply of operating power is stopped until the initial check period elapses in that situation. Thereby, it is possible to prevent the setting confirmation and the setting value update from being executed during the initial check period, and it is possible to suppress an increase in processing load. Further, it is possible to prevent the game from being started in the middle of the initial check period.

<Thirty-seventh embodiment>
In the present embodiment, the processing configuration of the main process executed by the main CPU 63 is different from that of the 35th embodiment. Hereinafter, a configuration different from the above-described thirty-fifth embodiment will be described. The description of the same configuration as that in the thirty-fifth embodiment is basically omitted.

  FIG. 140 is a flowchart showing the main processing in the present embodiment executed by the main CPU 63. Note that the processing from step S9501 to step S9525 in the main processing is executed using a program for specific control and data for specific control in the main CPU 63.

  In steps S9501 to S9518, the same processes as those in steps S7901 to S7918 of the main process (FIG. 114) in the thirty-third embodiment are executed. Thereafter, information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the work area 221 for specific control (step S9519). The value set in the checking counter is decremented by 1 every time the second timer interrupt process (FIG. 134) is started, as in the 35th embodiment. When a value of 1 or more is set in the checking counter, the display for checking is continued in the first to fourth notification display devices 201 to 204 as in the thirty-fifth embodiment.

  Thereafter, the processing after step S9520 is executed. The processing content of steps S9520 to S9525 is the same as that of steps S7919 to S7924 of the main processing (FIG. 114) in the thirty-third embodiment.

  According to the above configuration, when the supply of operating power to the main CPU 63 is started, the remaining processing is performed after the processing (step S9501 to step S9518) at the start of the supply of operating power is completed in the main CPU 63. Before the (step S9522 to step S9525) is started, the initial check period is started. As a result, it is not necessary to control the initial check period in the situation where the process at the start of the supply of operating power is being executed, and thus the processing load in the situation where the process at the start of the supply of operating power is being executed is reduced. It becomes possible.

  Further, the setting confirmation process (step S9514) and the set value update process (step S9518) are executed as processes at the start of supply of operating power, whereas the processes at the start of supply of operating power are performed during the initial check period. It starts after it finishes. As a result, even if the display for check is performed on the first to fourth notification display devices 201 to 204 during the initial check period, the set value is displayed using the first to fourth notification display devices 201 to 204. It becomes possible not to affect.

  It should be noted that the process after step S9520 may not be started until the initial check period elapses. In this case, it is possible to prevent the game from being started in a situation where the display for check is performed on the first to fourth notification display devices 201 to 204.

<Thirty-eighth embodiment>
In the present embodiment, the processing configuration of the normal setting process executed by the main CPU 63 is different from that of the thirty-fifth embodiment. Hereinafter, a configuration different from the above-described thirty-fifth embodiment will be described. The description of the same configuration as that in the thirty-fifth embodiment is basically omitted.

  FIG. 141 is a flowchart showing a normal setting process in the present embodiment executed by the main CPU 63. Note that the processing in steps S9601 to S9605 in the normal setting processing is executed using the specific control program and the specific control data in the main CPU 63.

  First, it is determined whether or not “1” is set in the management start flag provided in the work area 223 for non-specific control (step S9601). If “1” is not set in the management start flag (step S9601: NO), the display data for check is set in the fifth display data buffer 275 in the work area 221 for specific control (step S9602). When the check display data is supplied to the display IC 266, the first to fourth notification display devices 201 to 204 start the check display. Specifically, in each of the first to fourth notification display devices 201 to 204, all the display segments 321 to 324 are in a light emitting state. Thereby, the manager of the game hall can grasp whether or not each of the display segments 321 to 324 of the first to fourth notification display devices 201 to 204 can be normally in a light emitting state.

  If “1” is set in the management start flag (step S9601: YES), the processing of steps S9603 to S9605 is executed. The processing contents of steps S9603 to S9605 are the same as steps S9107 to S9109 in the normal setting process (FIG. 135) in the thirty-fifth embodiment. By executing the processing of step S9603 to step S9605, the base values stored in the various areas 311 to 314 of the calculation result storage area 234 are sequentially notified on the first to fourth notification display devices 201 to 204. At the same time, when the base value of the current area 311 is notified immediately after the start of the new calculation period, the calculation initial display is performed on the first and second notification display devices 201 and 202.

  According to the above configuration, when the management start flag is not set to “1”, the initial check period during which the check display is performed on the first to fourth notification display devices 201 to 204 is performed. As a result, the situation in which the initial check period is started when the supply of operating power to the main CPU 63 is started is limited to a situation in which “1” is not set in the management start flag in the shipping stage of the pachinko machine 10 or the like. Is possible.

<Other embodiments>
In addition, it is not limited to the description content of embodiment mentioned above, A various deformation | transformation improvement is possible within the range which does not deviate from the meaning of this invention. For example, you may change as follows. Incidentally, the following configuration of another embodiment may be applied individually or in combination to the configuration of the above embodiment.

  (1) In the first to fourteenth embodiments, the number of occurrences of the opening / closing execution mode per unit game is calculated as a parameter indicating the occurrence frequency of the opening / closing execution mode. Thus, the result of dividing the number of occurrences of the opening / closing execution mode by the total number of game balls discharged from the game area PA may be calculated. In addition to or instead of this, a configuration is obtained in which a result obtained by dividing the number of occurrences of the opening / closing execution mode by the total number of balls entering the first operation port 33 and the number of balls entering the second operation port 34 is calculated. It is good. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  (2) In the first to fourteenth embodiments, as the parameter indicating the frequency of occurrence of the high-frequency support mode, the high-frequency support mode with respect to the frequency of occurrence of the high-frequency support mode per unit game time and the frequency of occurrence of the opening / closing execution mode However, in addition to or in place of this, it is also possible to calculate the result of dividing the number of occurrences of the high-frequency support mode by the total number of game balls discharged from the game area PA. Good. In addition to or instead of this, the result of dividing the number of occurrences of the high-frequency support mode by the total number of balls entering the first operating port 33 and the number of balls entering the second operating port 34 is calculated. It is good also as a structure. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  (3) Not only the jackpot result but also the jackpot result may exist as a game result that triggers the occurrence of the opening / closing execution mode. In the case of a small hit result, the open / close execution mode is generated, but the success / failure lottery mode and the support mode are not changed before and after the open / close execution mode. Moreover, it is good also as a structure which becomes low frequency prize-winning mode in the opening / closing execution mode which became a small hit result. In this case, when a jackpot result occurs, history information corresponding to the occurrence of the jackpot result is stored in the history memory 117, and when a jackpot result occurs, history information corresponding to the occurrence of the jackpot result is recorded as history. The configuration may be stored in the memory 117 for use. In this configuration, a parameter indicating the occurrence frequency of the big hit result and a parameter indicating the occurrence frequency of the small hit result may be calculated by using the history information stored in the history memory 117. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  Moreover, it is good also as a structure which changes according to the setting state of the pachinko machine 10, and it is good also as a structure which does not change. In the case of a configuration in which the probability of winning the small hit result changes according to the setting state of the pachinko machine 10, a higher setting value may have a higher probability of winning the small hit result, and a higher setting value wins the small hit result. It is good also as a structure with a low probability of doing.

  Further, in a configuration in which a small hit result exists, the hold information acquired when a game ball enters the first operation port 33 and the game information that is acquired when the game ball enters the second operation port 34 are acquired. When the jackpot result is different from the holding information, the distribution ratio of the type of jackpot result is different, and when aiming to enter the first operating port 33, the variable display unit 36 in the game area PA In addition, the launch operation is performed so that the game ball flows down the left area, and when aiming to enter the second operation port 34, the game ball flows down the right area from the variable display unit 36 in the game area PA. In addition, a configuration in which a launch operation is performed, and a configuration in which a small hit result can be generated based on the hold information acquired when a game ball enters the first operation port 33 may be possible.

In this configuration, the following 51st parameter may exist as a game history management result. Note that the normal period is the sum of the execution period of the opening / closing execution mode triggered by the small hit result based on the ball entering the first operating port 33 and the execution period of the low-frequency support mode instead of the opening / closing execution mode. To do. Also, the number of balls entered into the out port 24a during the normal period is the number of balls entered K51, and the number of balls entered into the general prize port 31 during the normal period is the number of balls entered K52. The number of balls entered is K53, the number of balls entering the first operating port 33 during the normal period is the number K54 of incoming balls, and the number of balls entering the second operating port 34 during the normal period is the number of incoming balls K55.
51st parameter: the total number of game balls to be paid out during the normal period (K52 × “the number of winning balls for winning in the general winning opening 31” + K53 × “the number of winning balls for winning in the special electricity winning device 32” + K54 × “first” The number of winning balls for winning in the operating port 33 + K55 × “the number of winning balls for winning in the second operating port 34”) / the ratio of the total number of gaming balls discharged from the work area PA in the normal period (K51 + K52 + K53 + K54 + K55) In the configuration in which the 51st parameter is calculated, if the winning probability of the small hit result varies according to the setting state of the pachinko machine 10, the normal value of the 51st parameter varies according to the setting state of the pachinko machine 10. It becomes. Therefore, it is preferable that the history information used for calculating the 51st parameter is deleted when the setting state of the pachinko machine 10 is changed. On the other hand, when the winning probability of the small hit result does not vary according to the setting state of the pachinko machine 10, the normal value of the 51st parameter does not vary according to the setting state of the pachinko machine 10. Therefore, it is preferable that the history information used for calculating the 51st parameter is not deleted even if the setting state of the pachinko machine 10 is changed.

  (4) In the first to fourteenth embodiments, the history information corresponding to the occurrence of the opening / closing execution mode is stored in the history memory 117 regardless of the type of jackpot result. The history information corresponding to the type of jackpot result may be stored in the history memory 117. In this case, a configuration may be adopted in which a parameter indicating the occurrence frequency is calculated for each type of jackpot result. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  (5) In the first to fourteenth embodiments, various parameters (first to eighth parameters, eleventh to eighteenth parameters, twenty-first to twenty-sixth parameters, thirty-first parameter, and thirty-first to forty-second parameters are periodically added. However, the present invention is not limited to this. For example, various parameters are calculated when the total number of game balls discharged from the game area PA reaches the calculation trigger number (for example, 10,000). It is also possible to adopt a configuration in which various parameters are calculated when the supply of operating power to the pachinko machine 10 is stopped, and the number of game times executed is the number of times of calculation (for example, 1000 times). In some cases, various parameters may be calculated. In this case, the history memory 117 may be cleared to “0” at the timing when various parameters are calculated. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  (6) In the first to fourteenth embodiments, the first to eighth parameters, the 11th to 18th parameters, the 21st to 26th parameters, the 31st parameter, and the Although all of the 41st to 42nd parameters are calculated, the present invention is not limited to this. Only one of the various parameters is subject to calculation at one calculation timing, and each time the calculation timing is reached. Alternatively, the parameter group to be calculated may be sequentially changed. For example, the first to eighth parameters are calculated at one calculation timing, the first to eighteenth parameters are calculated at the next calculation timing, the twenty-first to twenty-sixth parameters are calculated at the next calculation timing, and the next calculation is calculated. In the timing, the 31st parameter and the 41st to 42nd parameters may be calculated, and thereafter, the calculation target may be changed in the above order every time the calculation timing comes. As a result, it is possible to reduce the processing load for calculating the parameter when one calculation timing is reached. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  (7) In the first to fourteenth embodiments, various parameters may be calculated using history information in the history memory 117 on condition that a game is being played. For example, the calculation of various parameters may be executed on condition that a game ball is supplied to the game area PA. As a result, it is possible to prevent the calculation of various parameters from being unnecessarily repeated even though no game is being played. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  (8) The first to fourteenth embodiments are not limited to the configuration in which the management IC 66 is provided separately from the main CPU 63, and the function of the management IC 66 is performed by the main CPU 63. It is good also as a structure. In this case, the correspondence information is stored in advance in the main ROM 64. In addition, a history memory 117, a calculation result memory 131, and a separate storage memory 171 may be provided separately from the main RAM 65. The history RAM 117, the calculation result memory 131, and the separate memory 171 may be provided in the main RAM 65. A configuration in which the function of the storage memory 171 is performed may be employed. In the configuration in which the functions of the history memory 117, the calculation result memory 131, and the separate storage memory 171 are performed in the main RAM 65, when the clear processing (step S105, step S117) of the main RAM 65 is executed, the history memory A part or all of the areas corresponding to the memory 117, the calculation result memory 131, and the separate storage memory 171 may be cleared to “0”. The history memory 117, the calculation result memory 131, and the separate storage The area corresponding to each of the memory 171 may be excluded from the “0” clear target, and “0” may be cleared when the corresponding clear condition in each of the above embodiments is satisfied. Further, in the main RAM 65, the manual operation contents for executing the clear process in the areas corresponding to the history memory 117, the calculation result memory 131, and the separate storage memory 171 and the other areas may be different. Good. The function of the management IC 66 may be performed by the sound emission control device 81.

  (9) When a new setting of the pachinko machine 10 is performed in the first to fourteenth embodiments, the history information in the history memory 117 is stored and held without being erased. Various parameters stored in the result memory 131 may be deleted. Thus, after a new setting state is set, it is possible to prevent notification of various parameters calculated before the setting is made. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  (10) In the third to fifth embodiments, even if a new setting state of the pachinko machine 10 is performed (that is, even if the setting value update process is executed in the main CPU 63), If the set value is not changed before and after the setting, the history memory 117 may not be cleared. As a result, it is possible to prevent the history information in the history memory 117 from being erased even though the setting value has not been changed.

  In this configuration, even if the clearing process (step S117) is executed for all the areas for storing the setting values in the main RAM 65, the setting value updating process ( It becomes possible for the main CPU 63 to specify whether or not the set value has been changed before and after step S118). In this case, when the main CPU 63 specifies that the setting value has not been changed, the management CPU 112 outputs a signal to the management CPU 112 so that the setting update recognition process is not executed, and the main CPU 63 When it is specified that the setting value has been changed, the management CPU 112 may output a signal to the management CPU 112 so that the setting update recognition process is executed.

  Further, when a signal indicating that the setting state of the pachinko machine 10 is newly set is received from the main CPU 63, the management CPU 112 refers to the history information stored in the history memory 117. It may be configured to specify whether or not the set value has been changed. In this case, if the management CPU 112 specifies that the setting value has not been changed, the history memory 117 is not cleared, and the management CPU 112 has specified that the setting value has been changed. In this case, the history memory 117 can be cleared.

  (11) In the third to fifth embodiments, even if a new setting state of the pachinko machine 10 is performed (that is, even if the set value update process is executed in the main CPU 63), When the set value is not changed before and after the setting, the configuration may be such that the calculation processing of various parameters triggered by the new setting of the setting state is not executed. As a result, it is possible to prevent various parameters from being calculated in response to a new setting state even though the setting value has not been changed.

  In this configuration, even if the clearing process (step S117) is executed for all the areas for storing the setting values in the main RAM 65, the setting value updating process ( It becomes possible for the main CPU 63 to specify whether or not the set value has been changed before and after step S118). In this case, when the main CPU 63 specifies that the setting value has not been changed, the management CPU 112 outputs a signal to the management CPU 112 so that the setting update recognition process is not executed, and the main CPU 63 When it is specified that the setting value has been changed, the management CPU 112 may output a signal to the management CPU 112 so that the setting update recognition process is executed.

  Further, when a signal indicating that the setting state of the pachinko machine 10 is newly set is received from the main CPU 63, the management CPU 112 refers to the history information stored in the history memory 117. It may be configured to specify whether or not the set value has been changed. In this case, when the management side CPU 112 specifies that the setting value has not been changed, the management side CPU 112 does not execute the calculation of various parameters triggered by the new setting of the current setting state. When it is specified that the value has been changed, it is possible to execute various parameter calculations triggered by the new setting of the current setting state.

  (12) In the third to fifth embodiments, when a new setting state of the pachinko machine 10 is set, various parameters are calculated in various calculation processes (step S1807) at that time. Rather, the various parameters stored in the calculation result memory 131 at that time are stored in the storage target area in the first to fifth separate storage areas 172 to 176 of the separate storage memory 171 and the calculation is performed. The information stored in the result memory 131 may be cleared to “0”. In this case, since it is not necessary to calculate various parameters in a situation where the setting state of the pachinko machine 10 is newly set, it is possible to complete the storage of various parameters in the separate storage memory 171 at an early stage. Become.

  (13) In the third to fifth embodiments, when the contents of various parameters stored in the first to fifth separate storage areas 172 to 176 of the separate storage memory 171 are subjected to a predetermined display start operation. It is good also as a structure displayed on the display apparatus 69a-69c for 1st-3rd information, or another display apparatus. The predetermined display start operation may be performed by operating a dedicated operation unit, or by performing a predetermined dedicated operation on an operation unit for performing other operations. As a result, various parameters stored in the separate storage memory 171 can be easily confirmed.

  (14) Although all of the out port 24a, the general winning port 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34 are set as the storage targets of the history information (or the ball entering history), It is not limited to this, and only a part of the out port 24a, the general winning port 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34 is a storage target of history information. It is good. For example, only the general winning opening 31, the special prize winning device 32, and the second operation opening 34 may be configured to store history information, and only the general winning opening 31 is configured to store history information. It ’s good. Even in this case, it is possible to grasp the game ball entry mode in a predetermined period for the ball entry part for which history information is to be stored.

  (15) A signal path for transmitting information corresponding to the result of entering the game ball in association with each of the first prize opening detection sensor 42a, the second prize opening detection sensor 43a, and the third prize opening detection sensor 44a. Although 118a-118c was set as the structure, it is not limited to this, The information corresponding to the entrance result about the same type of entrance part has two or more entrance parts of the same type. In addition, a configuration in which a plurality of entrance detection sensors exist corresponding thereto may be transmitted as one type of information. As a result, the number of types of information transmitted from the main CPU 63 to the management IC 66 can be suppressed.

  (16) In the first to fourteenth embodiments, the correspondence information indicating the correspondence between the type of information transmitted from the main CPU 63 to the management IC 66 and the buffers 122a to 122o is used for management from the main CPU 63. Although the configuration is such that the information is transmitted to the IC 66, the present invention is not limited to this, and the correspondence information may be stored in advance in the management IC 66. In this case, it is not necessary to execute processing for causing the management IC 66 to recognize the correspondence information, and thus the processing load on the main CPU 63 can be reduced.

  (17) In the first to fourteenth embodiments, the main CPU 63 receives the correspondence information indicating the correspondence between the type of information transmitted from the main CPU 63 to the management IC 66 and the buffers 122a to 122o. However, the present invention is not limited to this. For example, the main CPU 63 and the management IC 66 are capable of two-way communication, and are used for management. The configuration may be such that the correspondence information is transmitted from the main CPU 63 to the management IC 66 when a signal requesting transmission of the correspondence information is received from the IC 66. In this case, the correspondence memory 116 is provided as a non-volatile memory and used for both reading and writing. Correspondence information provided from the main CPU 63 to the management IC 66 after shipment of the pachinko machine 10 is sent to the main CPU 63. Even when the supply of operating power is stopped, the correspondence memory 116 is configured to store and hold the operation power. Thereby, it becomes possible to reduce the frequency with which correspondence information is transmitted.

  (18) In the first to fourteenth embodiments, the main CPU 63 receives the correspondence information indicating the correspondence between the type of information transmitted from the main CPU 63 to the management IC 66 and the buffers 122a to 122o. Is transmitted using the signal paths 118a to 118g for transmitting the detection result information of the respective entrance detection sensors 42a to 48a, but the present invention is not limited to this. A configuration may be adopted in which a dedicated signal path for transmitting information from the main CPU 63 to the management IC 66 is provided. As a result, the management IC 66 can determine which type of information is received from the main CPU 63 based on the types of the buffers 122a to 122o that receive the information.

  (19) In the first to fourteenth embodiments, information is transmitted from the main CPU 63 to the management IC 66, but information is not transmitted from the management IC 66 to the main CPU 63. However, the present invention is not limited to this. The information may be transmitted from the management IC 66 to the main CPU 63. For example, various parameters calculated by the management CPU 112 based on the history information may be transmitted to the main CPU 63. In this case, the main CPU 63 may be configured to directly execute notification control of the notification means so that notification corresponding to the contents of the received various parameters is performed. By transmitting a command corresponding to the content of the parameter to the sound emission control device 81, notification corresponding to the content of various parameters is executed using the symbol display device 41, the display light emitting unit 53, and the speaker unit 54. It may be configured to

  (20) In the first to fourteenth embodiments, when the supply of operating power to the main CPU 63 is started, the main CPU 63 or the management CPU 112 is notified based on the history information stored in the history memory 117. Various parameters may be calculated, and the contents of the calculated parameters may be notified using the symbol display device 41, the display light emitting unit 53, the speaker unit 54, and the like. In this case, it is possible to confirm whether or not the game ball entering mode of the game area PA on the previous business day was normal when the game hall started business. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  (21) If the various parameters calculated based on the history information stored in the history memory 117 in the first to fourteenth embodiments are abnormal results, the pachinko machine 10 until the prohibition canceling operation is performed. It is good also as a structure which cannot start a game. As a configuration for preventing the game from starting, for example, a configuration in which the launch of the game ball may be prohibited, a configuration in which each of the ball detection sensors 42a to 49a is invalidated, or the first operation port Even if a winning to 33 or the 2nd operation mouth 34 occurs, it is good also as composition which does not perform the success-and-failure determination processing. Further, the prohibition canceling operation may be an operation of turning on the power of the pachinko machine 10 again with the reset button 68c being pressed, and can be operated when the gaming machine main body 12 is released from the outer frame 11. It is good also as operation of the operation means used. As a result, it is possible to prevent the game from being played as it is in a situation where the game ball entering mode in the game area PA is in an abnormal mode. In addition, it is possible to prevent the game from being played as it is in a situation where the frequency of occurrence of the opening / closing execution mode is abnormal. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  (22) Although the history information corresponding to the detection results of the entrance detection sensors 42a to 48a is stored in the history memory 117 in the first to fourteenth embodiments, various parameters are calculated using the history information. The configuration may be such that neither the main CPU 63 nor the management CPU 112 executes. In this case, the history information may be read by an external device electrically connected to the reading terminal 68d, and various parameters may be calculated using the read history information by an operator of the reading work. Alternatively, the configuration may be such that various parameters are calculated using the read history information in the external device. In this case, the processing load on the main CPU 63 and the management CPU 112 can be reduced. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  (23) In the first to fourteenth embodiments, the management IC 66 is provided with a power source different from the main CPU 63, and even if the supply of operating power to the main CPU 63 is stopped, the management IC 66 The configuration may be such that the calculation of various parameters using history information and the output of history information or various parameters information may be performed. As a result, even when the supply of operating power to the main CPU 63 is stopped, history information and various parameters can be read by an external device.

  (24) In the first to fourteenth embodiments, the reading terminal 68d used for reading a program from the main ROM 64 is also used as a terminal used for reading history information or various parameters with an external device. However, the present invention is not limited to this, and a terminal used for reading history information or various parameters by an external device is a reading terminal 68d for reading a program from the main ROM 64. It is good also as a structure provided separately. In this case, the terminal used for reading history information or various parameters may be provided in the MPU 62 or may be provided in a position different from the MPU 62 in the main control board 61.

  (25) In the first to fourteenth embodiments, the correspondence relationship memory 116, the history memory 117, and the calculation result memory 131 are limited to the configuration provided as nonvolatile storage means such as a flash memory. For example, any one of these memories 116, 117, and 131 is provided as a volatile storage means that requires power supply to store and store information, and backup power is supplied to the memory so that the main side Even if the supply of the operating power to the CPU 63 is stopped, the information may be stored and held. In this case, a configuration may be adopted in which a dedicated backup power device is provided for the memory, and backup power is supplied to the memory from the power supply / launch control device 78 that supplies the main RAM 65 with backup power. Also good.

  (26) In the first to fourteenth embodiments, the management IC 66 includes the management CPU 112 as a general-purpose CPU, and performs history information storage processing and various parameter calculation processing based on programs and data stored in the management ROM 113. The configuration to be executed is not limited, and a hardware circuit designed to have these functions may be formed in the management IC 66. Specifically, for example, in the case of the first embodiment, the hardware circuit receives a signal indicating that a game ball has been detected by any of the detection sensors 42a to 48a from the main CPU 63. The correspondence information corresponding to the buffer that received the signal is stored in the history memory 117 from the correspondence memory 116, and the information of the RTC 115 at that time is stored in the history memory 117. To do. For example, in the case of the sixth embodiment, when the hardware circuit receives a signal indicating that a game ball has been detected by any of the detection sensors 42a to 48a from the main CPU 63, the hardware circuit has received the signal. The counter value corresponding to the buffer is incremented by one. In addition, when an operation trigger occurs in the first embodiment or the like, the hardware circuit calculates various parameters using history information at that time. In addition, when an external output trigger to the reading terminal 68d occurs, the hardware circuit externally outputs various parameters as calculation results and externally outputs history information.

  (27) In the first to fourteenth embodiments, the main CPU 63 and the management IC 66 may be provided as separate chips, may be provided as separate boards, or may be provided as separate control devices. It is good also as a structure provided as.

  (28) Regarding the number of game balls that have entered the out port 24a, the number of balls entered is measured, while the number of game balls such as the general winning port 31, the special prize winning device 32, the first operating port 33, and the second operating port 34 is increased. The history information including the RTC information may be stored for the entry into the bonus opportunity entry part that becomes the trigger for the payout of winning balls and the determination process. As a result, it is possible to calculate the frequency of game balls entering each privilege opportunity ball portion with respect to the total number of game balls discharged while allowing the game ball entry history to the privilege opportunity ball portion to be extracted. Become.

  (29) A configuration other than those in the above embodiments may be included as a predetermined event that triggers storage of history information. For example, at least one of the timing when the lower plate 56a becomes full, the timing when the full state is started, and the timing when the full state is released may be stored as history information. It may be configured that at least one of the timing when the ball has become unsatisfied, the timing at which the ball has no state is started, and the timing at which the state without the ball is released is stored as history information, and the dispensing device 76 becomes in an abnormal state. In addition, at least one of the timing at which the abnormal state of the payout device 76 is started and the timing at which the abnormal state of the payout device 76 is canceled may be stored as history information. In this case, it is possible to grasp the frequency of occurrence of these events.

  (30) In the first embodiment, the configuration in which the sixteenth buffer 122p of the input port 121 in the management-side I / F 111 corresponds to the output instruction signal is preset in the design stage of the management IC 66. However, the present invention is not limited to this, and the fact that the sixteenth buffer 122p corresponds to the output instruction signal is also recognized by the management IC 66 when the type identification command is transmitted from the main CPU 63. It is good. In the first embodiment, the configuration is such that the fifteenth buffer 122o of the input port 121 in the management-side I / F 111 corresponds to the set value update signal is preset in the design stage of the management IC 66. However, the present invention is not limited to this, and the fact that the fifteenth buffer 122o is compatible with the set value update signal is also recognized by the management IC 66 by transmitting a type identification command from the main CPU 63. It is good also as a structure. In this case, it is not necessary to previously set the correspondence relationship between the buffers 122a to 122p and the types of signals input to the buffers 122a to 122p in the management IC 66.

  (31) In the first to fourteenth embodiments, the management IC 66 may be configured to transmit a normal operation signal to the main CPU 63 when operating normally. In this case, the main CPU 63 can monitor whether or not the management IC 66 is operating normally.

  (32) The display device that displays the setting value being updated in the setting value update processing is not limited to the first to fourth notification display devices 201 to 204, and may be the symbol display device 41. A dedicated display device may be used. Further, the display device that displays the set value in the setting confirmation process is not limited to the first to fourth notification display devices 201 to 204, and may be the symbol display device 41 or a dedicated display device. It may be.

  (33) The operation unit operated to update the set value in the set value update process is not limited to the update button 68b, and may be the reset button 68c. In addition, positions corresponding to “setting 1” to “setting 6” are set as rotation operation positions when the setting key is inserted into the setting key insertion portion 68a and the rotation operation is performed. A setting value corresponding to the rotation operation position of the part 68a may be set. Further, the setting key insertion portion 68a can be further rotated from the ON position, and the setting value being updated is set to the setting value in the next order each time the rotation operation beyond the ON position is performed. It is good also as a structure updated.

  (34) In the first to tenth and fifteenth to twenty-first embodiments, the first to third notification display devices 69a to 69c are arranged side by side, but are arranged in parallel in the vertical direction. It is good also as a structure currently arranged, it is good also as a structure arranged in parallel diagonally, and good also as a structure arranged in parallel so that it may become two steps of upper and lower sides. In the 11th to 14th embodiments, the first to fourth notification display devices 201 to 204 are arranged side by side. However, the display devices 201 to 204 may be arranged side by side in the vertical direction. It is good also as a structure currently arranged in parallel, and it is good also as a structure arranged in parallel so that it may become two steps of upper and lower sides. In the fifteenth to twenty-first embodiments, the first to fourth notification display devices 201 to 204 may be used as display devices for displaying the management result of the game history.

  (35) In the first to fourteenth embodiments, history information used for calculating a parameter whose normal value varies according to the setting state of the pachinko machine 10 (hereinafter referred to as variation target history information). ) And history information used to calculate a parameter whose normal value does not vary according to the setting state of the pachinko machine 10 (hereinafter referred to as non-variable history information) are different areas in the history memory 117. It is good also as a structure memorize | stored in. In this case, when the setting state of the pachinko machine 10 is newly set or when the setting state of the pachinko machine 10 is changed, an area in which history information to be changed is stored in the history memory 117 is “0”. On the other hand, the area in which history information that is not changed is stored in the history memory 117 may be configured not to be cleared to “0”. Thereby, the calculation of the parameter whose normal value fluctuates according to the setting state of the pachinko machine 10 can be accurately performed even after the setting value is changed, and the normal value does not fluctuate according to the setting state of the pachinko machine 10. The accuracy of parameter calculation can be increased. Further, the configuration may be applied to the fifteenth to thirty-eighth embodiments.

  (36) In the fifteenth to twenty-first embodiments, the stack area 222 for specific control and the stack area 224 for non-specific control may not be specified in the main RAM 65 in advance. Even in this case, the areas corresponding to the stack areas 222 and 224 are designated in the main RAM 65 at the design stage of the pachinko machine 10, but the area is designated exceeding the storage capacity of the area. When information storage processing is executed, information that is not originally planned is written in an area that is not originally planned, so the main RAM 65 may be cleared to “0”.

  (37) In the fifteenth to twenty-first embodiments, when the main RAM 65 clear process (step S105, step S117) is executed, the work area 221 for specific control and the stack area 222 for specific control are “ Although “0” is cleared, the non-specific control work area 223 and the non-specific control stack area 224 are not cleared to “0”. Instead, the main RAM 65 is cleared (step S105, In step S117), not only the work area 221 for specific control and the stack area 222 for specific control but also the work area 223 for non-specific control and the stack area 224 for non-specific control may be cleared to “0”. . In the main RAM 65 clear process (steps S105 and S117), not only the specific control work area 221 and the specific control stack area 222 but also the normal counter area 231, the open / close execution mode counter area 232, and the high frequency. The support mode counter area 233 may be cleared to “0”, but the calculation result storage area 234 may not be cleared to “0”. In this case, the information stored in the calculation result storage area 234 can be protected.

  (38) In the fifteenth to twenty-fifth embodiments, the operation for clearing the specific control work area 221 and the specific control stack area 222 to “0”, the non-specific control work area 223 and the non-specific control work area 223 The specific control stack area 224 may be configured to be different from the operation for clearing “0”. For example, when supply of operating power to the pachinko machine 10 is started while operating the reset button 68c, the work area 221 for specific control and the stack area 222 for specific control are cleared to “0”, and the update button 68b is updated. When supply of operating power to the pachinko machine 10 is started while operating, the work area 223 for non-specific control and the stack area 224 for non-specific control may be cleared to “0”. Thereby, each information can be selectively deleted. Further, in the configuration, when supply of operating power to the pachinko machine 10 is started while operating both the update button 68b and the reset button 68c, the work area 221 for specific control and the stack area 222 for specific control are started. The non-specific control work area 223 and the non-specific control stack area 224 may all be cleared to “0”. As a result, in the configuration that enables selective erasure as described above, it is possible to improve workability when erasing information in each area 221 to 224 collectively.

  (39) In the fifteenth to eighteenth and twentieth embodiments, as in the nineteenth embodiment, when the processing corresponding to non-specific control is started, the information on the stack pointer of the main CPU 63 is used for non-specific control work. A configuration may be adopted in which the saved information is returned to the stack pointer of the main CPU 63 when returning to the process corresponding to the specific control while being saved in the area 223. Thereby, even if the stack pointer information of the main CPU 63 when the process corresponding to the non-specific control is started can be changed, the main side when the process corresponding to the non-specific control is completed. It becomes possible to return the state of the stack pointer of the CPU 63 to the state before the processing corresponding to the non-specific control is started.

  (40) Processing for collecting game history information as processing corresponding to non-specific control in the fifteenth to twenty-fifth embodiments, processing for calculating various parameters using the collected history information, and The process for notifying the calculation result is executed, but only part of these processes is executed as a process corresponding to non-specific control, and the other is executed as a process corresponding to specific control. It is good. In addition to or instead of the process for collecting game history information, the process for calculating various parameters using the collected history information, and the process for notifying the calculation result, The process may be executed as a process corresponding to non-specific control. For example, at least one of the fraud monitoring and the monitoring result notification may be executed as a process corresponding to non-specific control.

  (41) In the fifteenth to twenty-fifth embodiments, when returning to the process corresponding to the specific control from the situation where the process corresponding to the non-specific control is executed in the main CPU 63, the flag register of the main CPU 63, Although neither the stack pointer nor the various registers are saved in the main RAM 65, instead, the main CPU 63 performs processing corresponding to the specific control from the situation where the processing corresponding to the non-specific control is being executed. When returning, at least part of the flag register, stack pointer, and various registers of the main CPU 63 is saved in the main RAM 65, and the process corresponding to the non-specific control is started again. In this case, it may be configured to be restored to the corresponding storage area of the main CPU 63. Thereby, it is possible to carry over and use the information of the main CPU 63 used in the processing corresponding to the non-specific control.

  (42) In the fifteenth to twenty-fifth embodiments, the various parameters are calculated when the total number of game balls discharged from the game area is 6000. The total number of game balls may be larger or smaller than 6000. For example, various parameters may be calculated when the total number of game balls discharged from the game area reaches 60000. In this case, the storage capacity necessary for storing the game history information increases, but the game history information is stored in the management RAM 241 externally attached to the MPU 62 as in the twenty-first embodiment. By adopting the storage configuration, it is possible to flexibly cope with the increase in the storage capacity.

  (43) In the fifteenth to twenty-fifth embodiments, the 61st to 68th parameters are calculated as the game history management results. A configuration may be employed in which at least a part of the parameters, the 41st parameter, and the 42nd parameter are calculated.

  (44) In the fifteenth to twenty-fifth embodiments, when processing for newly setting the setting state of the pachinko machine 10 is executed or when the setting state of the pachinko machine 10 is changed, the work area 221 for specific control Further, not only the stack area 222 for specific control but also the work area 223 for non-specific control and the stack area 224 for non-specific control may be cleared. In this case, when processing for newly setting the setting state of the pachinko machine 10 is executed or when the setting state of the pachinko machine 10 is changed, the normal counter area 231, the opening / closing execution mode counter area 232, and the high frequency The support mode counter area 233 and the calculation result storage area 234 are cleared to “0”.

  In addition, when processing for newly setting the setting state of the pachinko machine 10 is executed or when the setting state of the pachinko machine 10 is changed, not only the work area 221 for specific control and the stack area 222 for specific control The normal counter area 231, the opening / closing execution mode counter area 232, and the high frequency support mode counter area 233 may be cleared to “0”, but the calculation result storage area 234 may not be cleared to “0”. In this case, the information stored in the calculation result storage area 234 can be protected.

  Further, when the process for newly setting the setting state of the pachinko machine 10 is executed or when the setting state of the pachinko machine 10 is changed, the work area 221 for specific control and the stack area 222 for specific control are “0”. The work area 223 for non-specific control and the stack area 224 for non-specific control may be configured so that “0” is not cleared, although cleared. In this case, the information stored in the non-specific control work area 223 and the non-specific control stack area 224 can be protected.

  Further, when the configuration of (43) is provided, the first setting is performed when a process for newly setting the setting state of the pachinko machine 10 is executed or when the setting state of the pachinko machine 10 is changed. Although the history information for calculating the 31st parameter, the 41st parameter, and the 42nd parameter in the embodiment is deleted, the normal counter area 231, the open / close execution mode counter area 232, and the high frequency support mode counter area 233 are deleted. The calculation result storage area 234 may not be cleared to “0”.

  (45) In the first to thirty-eighth embodiments, instead of the configuration in which the total number of game balls discharged from the game area PA is used to calculate various parameters, the game balls are supplied to the game area PA. The total supply number of game balls may be used. In this case, for example, a detection sensor is provided to detect a game ball that has been launched from the game ball launching mechanism 27 and has reached the game area PA, and the game balls supplied to the game area PA based on the detection result of the detection sensor. It is good also as a structure which measures a number. In this configuration, since it is not necessary to measure the number of game balls discharged from the out port 24a, the out port detection sensor 48a may not be provided.

  (46) In the fifteenth to thirty-eighth embodiments, at least part of the information of the various registers and stack pointers of the main CPU 63 is relative to the stack area 222 for specific control or the stack area 224 for non-specific control. It may be configured to be saved by a load instruction. In this case, it is necessary to update the information on the stack pointer of the main CPU 63 when saving the information to the stack areas 222 and 224. The information saved in the stack areas 222 and 224 may be restored to the corresponding storage area of the main CPU 63 by a load instruction. Also in this case, it is necessary to update the stack pointer information of the main CPU 63 when the information is restored from the stack areas 222 and 224.

  (47) When the set value update process is executed in each of the above embodiments, a corresponding notification may be performed by any of the symbol display device 41, the display light emitting unit 53, and the speaker unit 54. Thereby, the manager of the game hall can clearly grasp that the set value update processing is being executed.

  (48) In the above embodiments, a history that a set value is newly set may be stored in the main RAM 65. Further, a history that a set value is newly set may be stored in a RAM provided in the sound emission control device 81. In this case, every time the set value update process is completed, a command including information on the set value set in the set value update process is transmitted from the main CPU 63 to the sound emission control device 81, and the sound emission control device Each time the command 81 is received, information indicating that the set value is newly set and information indicating the set value at that time are cumulatively stored in the RAM of the sound emission control device 81. In the configuration, when a predetermined operation is performed, a setting history of setting values accumulated in the RAM of the sound emission control device 81 may be displayed on the symbol display device 41.

  (49) In each of the above embodiments, when the set value is newly set in the set value update process, the information indicating the number of game balls to be paid out stored in the payout control device 77 is not erased. However, instead of this, the information indicating the number of game balls to be paid out may be deleted. If the set value update process is executed but the set value is not changed, the information indicating the number of game balls to be paid out is not deleted, and if the set value is changed, the payout schedule is set. The information indicating the number of game balls may be deleted.

  (50) If the set value update processing is executed in each of the above embodiments but the set value is not changed, each area 221 to 224 of the main RAM 65 is not cleared to “0”, and the set value is If changed, at least a part of the areas 221 to 224 of the main RAM 65 may be cleared to “0”. For example, when the set value is changed, the area other than the set value counter in the work area 221 for specific control may be cleared to “0”.

  (51) In the twenty-second to thirty-eighth embodiments, even if the main CPU 63 is executing a process for confirming the set value in the setting confirmation process (FIG. 87), it is beneficial to the game. It is good also as a structure by which operation | movement of the movable object which participates is continued. For example, a V zone and a non-V zone are provided in the entrance means that can enter in the opening / closing execution mode, and game balls that enter the entrance means are distributed to either the V zone or the non-V zone. In the configuration including the distribution member, the operation of the distribution member may be continued even in a situation where the processing for confirming the set value is performed in the setting confirmation processing. In this case, even if it is attempted to stop the operation of the sorting member by illegally generating a situation in which the process for confirming the set value is executed in the process for confirming the setting, it is possible to disable it. In addition, in addition to the above-mentioned distribution member, the movable member that has continued to operate even when the process for confirming the set value is performed in the setting confirmation process has entered the ball entry means. The game ball is either an advantageous opening that will cause a round game after the game ball has entered, or a discharge opening that discharges the game ball that has entered the ball entry means without entering the advantageous opening. It is possible to use a sorting member that sorts.

  (52) In the twenty-second to thirty-eighth embodiments, at least one of the non-specific control work area 223 and the non-specific control stack area 224 may be configured not to be monitored for information abnormality. In this case, even if it is specified that an information abnormality has occurred in the work area 221 for specific control and the stack area 222 for specific control, the work area 223 for non-specific control and the stack area for non-specific control The configuration in which 224 is not cleared to “0” does not cause a situation where the work area 223 for non-specific control and the stack area 224 for non-specific control are cleared to “0” based on the occurrence of an information abnormality. It becomes possible to do.

  (53) In the twenty-second to thirty-eighth embodiments, information abnormality occurs in the work area 221 for specific control, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control. A configuration may be adopted in which all the monitoring of whether or not it occurs is performed in a process corresponding to non-specific control. Moreover, it is good also as a structure by which all the processes for clearing each area 221-224 "0" when information abnormality generate | occur | produces are the processes corresponding to non-specific control.

  (54) In each of the above embodiments, the main RAM 65 needs to be supplied with power to store and hold information, and backup power is supplied to the main RAM 65 even when the power of the pachinko machine 10 is OFF. However, the main RAM 65 may be a non-volatile memory that does not require power supply to store and store information.

  (55) In each of the above embodiments, the various clear processes of the main RAM 65 are configured to initialize the target area by executing a process of clearing “0” and a process of initial setting for the target area of the main RAM 65. Instead of this, the above-described target area may be initialized by executing the initial setting process without executing the process of clearing “0”.

  (56) In the above embodiments, when the supply of operating power to the main CPU 63 is started, if the setting key insertion unit 68a is turned ON, the setting value update process is executed without requiring any other operation. It is good also as a structure to be made. Further, instead of the setting key insertion portion 68a that is turned ON / OFF by a setting key, a setting switch that is directly turned ON / OFF by a hand may be provided. If the reset button 68c is pressed when the setting key insertion portion 68a is not provided and the supply of operating power to the main CPU 63 is started, the setting value is not required. It is good also as a structure by which an update process is performed. In this case, a cover member may be provided so that it can be switched between a closed state that covers the reset button 68c and an open state that does not cover it, and the locking device that locks the cover member in a closed position. It is good also as a structure provided.

  (57) Configuration in which the setting value being selected is confirmed and the setting value updating process is terminated when the setting key insertion unit 68a has been operated to the OFF position in the setting value updating process for a predetermined period. It is good. Further, when an end reference period (for example, 5 minutes) has elapsed since the setting value update process was started, the setting value being selected is automatically confirmed and the setting value update process is terminated. In addition, when the update button 68b or the reset button 68c is pressed for more than the end reference period (for example, 10 seconds) in the set value update process, the selected set value is determined and the set value update process is ended. It is good also as a structure.

  (58) The setting key insertion portion 68a can be further rotated from the ON position, and the setting value being updated is the next set value every time the rotation operation beyond the ON position is performed. In the configuration updated, the setting confirmation process is started to enable the confirmation of the set value when the supply of the operating power to the main CPU 63 is started in the situation where the setting key insertion unit 68a is operated to the ON position. The setting confirmation processing may be terminated when the setting key insertion unit 68a is operated to the OFF position. In addition, when the update button 68b or the reset button 68c is pressed, when the supply of operating power to the main CPU 63 is started, a setting confirmation process that enables confirmation of the set value is started. The configuration confirmation process may be terminated when the pressing operation is released. Further, in a configuration in which a setting switch that is directly turned ON / OFF by hand is provided in place of the setting key insertion portion 68a that is turned ON / OFF by a setting key, the main switch is turned on when the setting switch is turned ON. When the supply of operating power to the side CPU 63 is started, a setting confirmation process that allows the setting value to be confirmed is started, and when the setting switch is turned OFF or turned ON after the OFF operation The configuration confirmation process may be terminated. Further, in a configuration in which a setting switch that is directly turned ON / OFF by hand is provided in place of the setting key insertion portion 68a that is turned ON / OFF by a setting key, the main switch is turned on when the setting switch is turned ON. The setting confirmation process that enables the confirmation of the set value is started when the supply of operating power to the side CPU 63 is started, and the setting confirmation process is ended when the reset button 68c is pressed. Also good.

  (59) Display control based on a command transmitted from the main control device 60 instead of a configuration in which the display control device 82 is controlled by the sound emission control device 81 based on a command transmitted from the main control device 60 The device 82 may be configured to control the sound emission control device 81. Further, instead of the configuration in which the sound emission control device 81 and the display control device 82 are separately provided, the both control devices may be provided as one control device, and one of the two control devices has a function. May be integrated into the main control device 60, and both functions of these two control devices may be integrated into the main control device 60. The configuration of the command transmitted from the main control device 60 to the sound emission control device 81 and the configuration of the command transmitted from the sound emission control device 81 to the display control device 82 are also arbitrary.

  (60) Other types of pachinko machines different from the above embodiments, for example, a pachinko machine in which an electric accessory is released a predetermined number of times when a game ball enters a specific area of a special device, or a game ball in a specific area of a special device The present invention can also be applied to a pachinko machine that generates a right if a player enters, a pachinko machine equipped with other objects, an arrangement ball machine, a sparrow ball, and other gaming machines.

  Also, a non-ball-type gaming machine, for example, a plurality of reels with a plurality of types of symbols attached in the circumferential direction, starts rotation of the reel by inserting a medal and operating a start lever, and a stop switch is operated. If a specific symbol or a combination of specific symbols is established on the active line visible from the display window after the reel has stopped after a predetermined time has passed, a privilege such as paying out medals is given to the player The present invention can also be applied to a slot machine.

  In addition, the gaming machine main body that is supported by the outer frame so as to be openable and closable is provided with a storage unit and a capture device, and the start lever is operated after a predetermined number of game balls stored in the storage unit are captured by the capture device. Thus, the present invention can also be applied to a gaming machine in which a pachinko machine and a slot machine are fused, which starts rotating the reel.

  When the present invention is applied to a slot machine or a gaming machine in which a pachinko machine and a slot machine are integrated, for example, a result of a lottery process of a combination executed when starting one game based on an operation of a start lever is history information. The actual winning probability of each role may be calculated using the history information, and when a transition to a special gaming state such as a bonus game occurs, it is stored as history information, and the history The configuration may be such that the actual transition probability to the special gaming state is calculated using information, or the ratio of the number of staying games in the special gaming state to the total number of digested games may be calculated. The history information and various parameters may be readable by an external device, or notification corresponding to the calculation results of various parameters may be performed by the gaming machine itself. Further, a configuration in which a plurality of setting states such as “setting 1” to “setting 6” exist and the winning probability in the lottery process of the combination may be changed according to the setting state. In this case, the configuration in each of the above embodiments may be applied with respect to handling of history information, calculation of various parameters, and handling of repeated changes when a setting state setting is newly set or a setting value is changed. .

  (61) The characteristic configurations of the first to thirty-eighth embodiments may be mutually applied in any combination. For example, the characteristic configuration of the first embodiment, the characteristic configuration of the sixth embodiment, the characteristic configuration of the tenth embodiment, and the characteristic configuration of the thirtieth embodiment. The characteristic configuration of the second embodiment, the characteristic configuration of the fourth embodiment, the characteristic configuration of the eighth embodiment, and the eleventh configuration may be combined. The characteristic configuration of the first embodiment and the characteristic configuration of the thirty-third embodiment may be combined, and the characteristic configuration of the first embodiment and the characteristic configuration of the fifteenth embodiment may be combined. The characteristic configuration of the twenty-first embodiment, the characteristic configuration of the twenty-ninth embodiment, and the characteristic configuration of the thirty-fourth embodiment may be combined. The characteristic configuration of the second embodiment, the characteristic configuration of the sixteenth embodiment, and the twenty-second embodiment And characteristic configuration of the may be combined and characteristic configuration of the embodiment of the 35th. Further, the configuration of the above-described another embodiment may be applied in any combination to the configuration in which the characteristic configurations of the first to thirty-eighth embodiments are applied in a predetermined combination.

<Invention Group Extracted from Each Embodiment>
Hereinafter, the characteristics of the invention group extracted from each of the above-described embodiments will be described while showing effects and the like as necessary. In the following, for easy understanding, the corresponding configuration in each of the above embodiments is appropriately shown in parentheses, but is not limited to the specific configuration shown in parentheses.

<Feature A group>
Feature A1. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
History storage execution means (function to execute history setting processing in the management CPU 112) that stores history information of a game corresponding to a predetermined event when the game is executed in the history storage means (history memory 117) )When,
An information erasure unit (a third erasure unit) that erases at least a part of the history information stored in the history storage unit, based on at least one condition that the setting value to be used is set by the setting unit. In the fifth embodiment, the function of executing the process of step S1809 in the management CPU 112, the function of executing the process of step S2109 in the management CPU 112 in the fifth embodiment, and the steps S2306 to S2 in the management CPU 112 in the sixth embodiment. A function for executing the process of S2308, a function for executing the process of step S2608 in the management CPU 112 in the eighth embodiment),
A gaming machine characterized by comprising:

  According to the feature A1, since a setting value to be used is set from among a plurality of stages of setting values corresponding to the player's advantage, the player has a more advantageous setting value to be used. You will expect that. When a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage means. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented.

  In this case, at least a part of the history information stored in the history storage means is erased on the basis of at least one condition that the setting value to be used is newly set. As a result, it is possible to adjust the contents of the history storage unit so that the occurrence frequency of the predetermined event in the situation after the setting value to be used is newly set can be suitably managed. .

Feature A2. A ball entry means (first operation port 33, second operation port 34) capable of entering a game ball flowing down the game area;
Information acquisition means (a function of executing the processing of step S401 in the main CPU 63) for acquiring special information based on the game ball entering the ball entry means;
Grant determination means (function for executing the processes of steps S503 and S504 in the main CPU 63) for determining whether or not the special information corresponds to the grant information;
Based on the result of granting that the special information corresponds to the granting information in the granting determination, a privilege granting unit (step in the main CPU 63) for granting a privilege (opening / closing execution mode) to the player The function of executing the processes of S409 to S412),
With
The gaming machine according to Feature A1, wherein a probability of the grant correspondence result varies in the grant determination according to the set value.

  According to the feature A2, in the so-called pachinko machine, it is possible to vary the probability of the assignment correspondence result according to the set value. In this case, since the configuration of the feature A1 is provided, the history storage unit can appropriately manage the occurrence frequency of the predetermined event in the situation after the probability of the assignment correspondence result is changed. The contents can be adjusted.

  Feature A3. The information erasing means erases all of the history information stored in the history storage means on the condition that at least one of the setting values to be used by the setting means has been set. A gaming machine according to the feature A1 or A2.

  According to the feature A3, setting of the setting value to be used is performed by erasing all the history information stored in the history storage unit when the setting value to be used is newly set. It is possible to specify the frequency of occurrence of a predetermined event with reference to the timing at which this is newly performed.

  Feature A4. The information erasing unit erases a part of the history information stored in the history storage unit, with at least one condition that the setting value to be used is set by the setting unit, The gaming machine according to feature A1 or A2, wherein a part of the history information stored in the history storage means is left.

  According to the feature A4, when a setting value to be used is newly set, history information unnecessary for managing the occurrence frequency of a predetermined event thereafter is deleted, and the occurrence frequency of the predetermined event thereafter is managed. Necessary history information can be left. Thereby, it is possible to suitably manage the occurrence frequency of the predetermined event after the setting value to be used is newly set.

Feature A5. The history information stored in the history storage means includes first history information in which an occurrence probability of the predetermined event corresponding to the history information varies according to the set value (history indicating that an opening / closing execution mode has occurred). Information) and second history information that does not vary according to the set value (history information indicating that a game ball has been discharged from the game area PA),
The information erasure unit erases the first history information stored in the history storage unit, with at least one condition that the setting value to be used is set by the setting unit, The gaming machine according to Feature A4, wherein the second history information stored in history storage means is left.

  According to the feature A5, when the setting value to be used is newly set, the first history information corresponding to a predetermined event whose occurrence probability varies according to the setting value is deleted, and the occurrence probability is the set value. The second history information corresponding to the predetermined event that does not vary according to the is not deleted. Accordingly, when the first history information before the setting value to be used is newly set is inherited after the setting value is newly set, a predetermined event corresponding to the first history information is generated. The first history information which is not preferable in specifying the frequency can be deleted when the setting value is newly set. On the other hand, the second history information is referred to when the frequency of occurrence of a predetermined event corresponding to the second history information is specified by not deleting even if a setting value to be used is newly set. Since a large number of second history information can be secured, it is possible to specify the occurrence frequency of a predetermined event corresponding to the second history information with high accuracy.

Feature A6. A ball entry means (first operation port 33, second operation port 34) capable of entering a game ball flowing down the game area;
Information acquisition means (a function of executing the processing of step S401 in the main CPU 63) for acquiring special information based on the game ball entering the ball entry means;
Grant determination means (function for executing the processes of steps S503 and S504 in the main CPU 63) for determining whether or not the special information corresponds to the grant information;
Based on the result of granting that the special information corresponds to the granting information in the granting determination, a privilege granting unit (step in the main CPU 63) for granting a privilege (opening / closing execution mode) to the player The function of executing the processes of S409 to S412),
With
According to the setting value, the probability of the grant correspondence result in the grant determination varies.
The first history information includes information corresponding to the provision of the privilege,
The gaming machine according to Feature A5, wherein the second history information includes information corresponding to a game ball being discharged from the gaming area in a predetermined manner.

  According to the feature A6, since the privilege grant probability varies depending on the set value, the first history information is deleted when the set value to be used is newly set. Thus, it is possible to specify the privilege grant frequency under the setting value that has been newly set. On the other hand, since the frequency at which game balls are discharged from the game area does not vary according to the set value, the second history information is not deleted even if a set value to be used is newly set, It becomes possible to specify the frequency with which the game balls are discharged from the game area in a predetermined manner with high accuracy.

  Feature A7. The information erasure unit is configured to set at least the history information when the setting unit sets the setting value to be used and when the history storage unit stores a predetermined amount of the history information. The gaming machine according to any one of features A1 to A6, wherein a part is erased.

  According to the feature A7, when predetermined history information is not stored in the history storage unit in a predetermined amount or more, the history information is not erased even if a new setting value to be used is set. As a result, even if a new setting value is repeated in a situation where no game is played, it is possible to prevent the history information in the history storage unit from being repeatedly erased.

  Feature A8. Corresponding to the result of a game in a predetermined period using the history information stored in the history storage means, on the condition that the setting value to be used by the setting means has been set Information deriving means for deriving the mode information to be performed (a function for executing the processing of step S1807 in the management CPU 112 in the third embodiment, and a function of executing the processing of step S2107 in the management CPU 112 in the fifth embodiment). The gaming machine according to any one of features A1 to A7, wherein:

  According to the feature A8, at least a part of the history information stored in the history storage unit has the configuration of the feature A1 and is stored on the basis of at least one condition that a setting value to be used is newly set. An aspect corresponding to the result of a game in a predetermined period by using history information stored in the history storage means when a new setting value to be used is set in the configuration to be deleted Information is derived. As a result, even if at least a part of the history information is deleted when the setting value is changed, the management result of the game history such as the occurrence frequency of a predetermined event in the situation before the setting value is changed is grasped. It becomes possible to do.

  Feature A9. The gaming machine according to feature A8, further comprising aspect information storage means (another storage memory 171) for storing the aspect information derived by the information deriving means.

  According to the feature A9, the mode information corresponding to the result of the game in a predetermined period using the history information stored in the history storage unit when the setting value to be used is newly set. Is derived, the aspect information is stored in the aspect information storage means. Thereby, even if the set value is changed, it becomes possible to grasp the management result of the game history in a situation before the set value is changed at an arbitrary timing thereafter.

  Feature A10. The gaming machine according to Feature A9, wherein the aspect information storage means is capable of storing a plurality of the aspect information.

  According to the feature A10, since a plurality of pieces of aspect information can be stored in the aspect information storage unit, the management results of the game history in a plurality of periods are grasped based on the timing when a new setting value is set. It becomes possible to do. In addition, even if a new setting value is repeated under a situation where no game is played, the mode information derived using the history information of the situation where the game is being played is substantially the mode information storage means. It is possible to increase the possibility of remaining in

Feature A11. The aspect information storage means can store a predetermined number of the aspect information,
The gaming machine is a means for executing special processing when the setting value set by the setting means exceeds the predetermined number under a predetermined condition (in the third embodiment, in the management CPU 112). The gaming machine according to feature A9 or A10, further comprising a function of executing a monitoring process of repeated changes, a function of executing a monitoring process of repeated changes in the main CPU 63 in the fourth embodiment.

  According to the feature A11, the setting value is set in a situation where the game is not performed so that the aspect information derived using the history information of the situation where the game is substantially performed does not remain in the aspect information storage unit. When the new setting is repeated, a special process is performed on the new setting. Thereby, it becomes possible to cope with the action.

  Feature A12. The gaming machine according to any one of features A8 to A11, wherein the information deriving unit derives the mode information when a predetermined amount or more of the predetermined history information is stored in the history storage unit. .

  According to the feature A12, since the aspect information is derived when a predetermined amount or more of the predetermined history information is stored in the history storage unit, it is possible to prevent the aspect information from being unnecessarily derived. .

  Feature A13. The information erasing unit erases the history information from when the setting value to be used is set by the setting unit until a predetermined amount or more of the history information is stored in the history storage unit. Without setting the setting value when a predetermined amount or more of the history information is stored in the history storage unit after the setting unit sets the setting value to be used by the setting unit. The gaming machine according to any one of features A1 to A12, wherein the history information stored in the history storage means is deleted.

  According to the feature A13, until a specific amount of predetermined history information is newly stored in the history storage unit, even if a new setting value to be used is set, it is stored before the setting is performed. The history information that has been set is not deleted. Thereby, even if a new setting value is set, it is possible to specify the management result of the game history in a predetermined period.

Feature A14. The history storage means includes first history storage means (first history memory 191) and second history storage means (second history memory 192),
The history storage executing means includes
When the predetermined event occurs in a predetermined period from when the setting value to be used by the setting unit is set to when the release condition is satisfied, the history information corresponding to the predetermined event is stored in the first history storage unit and Means for storing in both the second history storage means (function to execute the process of step S2604 in the management CPU 112);
Means for storing the history information corresponding to the first history storage means and the second history storage means set as a storage target when the predetermined event occurs in a period other than the predetermined period (Function for executing the process of step S2603 in the management-side CPU 112);
With
The information erasure unit erases the history information stored in the storage target of the first history storage unit and the second history storage unit until the cancellation condition is satisfied. The gaming machine according to any one of features A1 to A13, wherein:

  According to the feature A14, until a specific amount of history information is newly stored in the history storage unit, even if a new setting value to be used is set, it is stored before the setting is performed. History information is not deleted. Thereby, even if a new setting value is set, it is possible to specify the management result of the game history in a predetermined period. In addition, it is possible to produce the effect simply by appropriately changing the history storage unit that is the storage target of the history information between the first history storage unit and the second history storage unit.

  Feature A15. Deriving mode information corresponding to a game result in a predetermined period using the history information stored on the side set as the storage target of the first history storage means and the second history storage means The gaming machine according to Feature A14, further comprising information deriving means (a function of executing the processing of Step S2703 in the management CPU 112).

  According to the feature A15, even when the history information is stored in both the first history storage unit and the second history storage unit due to the new setting value setting, the history information is used. Information can be appropriately derived.

  In addition, with respect to the configuration of the features A1 to A15, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature B group>
Feature B1. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
History storage execution means (function to execute history setting processing in the management CPU 112) that stores history information of a game corresponding to a predetermined event when the game is executed in the history storage means (history memory 117) )When,
With
The predetermined history information stored in the history storage unit before setting of the setting value to be used by the setting unit is set to the setting value to be used by the setting unit. The gaming machine is stored and held in the history storage means even after the game.

  According to the feature B1, since the setting value to be used is set from among a plurality of setting values corresponding to the player's degree of advantage, the player has a more advantageous setting value to be used. You will expect that. When a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage means. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented.

  In this case, even if the setting value to be used is newly set, the history information stored in the history storage means is stored and held without being erased. As a result, even if the setting value to be used is set, the history information up to that time can be continuously stored in the history storage means and accumulated in the history storage means over a long period of time. The management result of the game history can be specified using the history information.

  Feature B2. The history storage execution means, when the setting value to be used is set by the setting means, the history storage means corresponding to the setting is stored in the history storage means (first storage The game according to Feature B1, including a function for executing the process of step S1307 in the management-side CPU 112 in the embodiment, and a function for executing the process of step S2408 in the management-side CPU 112 in the seventh embodiment. Machine.

  According to the feature B2, the setting value to be used is newly set in the configuration in which the history information is stored and held without being erased even if the setting value to be used is newly set. The corresponding history information is stored in the history storage means. As a result, it is possible to distinguish between history information before the setting of the setting value to be used is newly performed and history information after the setting is performed.

  Feature B3. The storage execution unit at the time of setting causes the history storage unit to store information corresponding to the set setting value as the history information when the setting value to be used is set by the setting unit. The gaming machine according to Feature B2, wherein the gaming machine is characterized by that.

  According to the feature B3, it is possible to specify the content of the setting value set in the past by referring to the history information.

  Feature B4. The history storage means includes a plurality of corresponding history storage means (history memories 181 to 186 for settings 1 to 6) corresponding to each of a plurality of types of setting values that can be set by the setting means. The gaming machine according to any one of features B1 to B3.

  According to the feature B4, since the correspondence history storage means is provided corresponding to each setting value, it is possible to store history information separately for each setting value.

  Feature B5. In the case where the setting value to be used is set by the setting means, the correspondence history storage means corresponding to the setting value for which the setting has been made is a storage target of the history information (management side The gaming machine according to Feature B4, further including a function of executing the process of Step S2406 in the CPU 112).

  According to the feature B5, when a setting value to be used is newly set, the corresponding history storage unit corresponding to the setting value is a storage target of subsequent history information. It is possible to store history information in distinction.

  Feature B6. Information deriving means for deriving mode information corresponding to a game result in a predetermined period using the history information stored in the correspondence history storing means as the storage target (display output processing in the management CPU 112) The gaming machine according to Feature B5, which is provided with a function of

  According to the feature B6, in the configuration in which history information is stored separately for each set value, it is possible to derive the mode information corresponding to the currently set value.

Feature B7. A ball entry means (first operation port 33, second operation port 34) capable of entering a game ball flowing down the game area;
Information acquisition means (a function of executing the processing of step S401 in the main CPU 63) for acquiring special information based on the game ball entering the ball entry means;
Grant determination means (function for executing the processes of steps S503 and S504 in the main CPU 63) for determining whether or not the special information corresponds to the grant information;
Based on the result of granting that the special information corresponds to the granting information in the granting determination, a privilege granting unit (step in the main CPU 63) for granting a privilege (opening / closing execution mode) to the player The function of executing the processes of S409 to S412),
With
The gaming machine according to any one of features B1 to B6, wherein a probability of the grant correspondence result varies in the grant determination according to the set value.

  According to the feature B7, in the so-called pachinko machine, it is possible to vary the probability of the result of giving correspondence according to the set value.

  In addition, with respect to the configuration of the features B1 to B7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature C group>
Feature C1. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
History storage execution means (function to execute history setting processing in the management CPU 112) that stores history information of a game corresponding to a predetermined event when the game is executed in the history storage means (history memory 117) )When,
The post-setting handling means that does not erase the history information until the setting of the setting value to be used by the setting means is performed until at least a predetermined amount of the history information is stored in the history storage means. (Function to execute the processing of step S2506 and step S2605 to step S2609 in the management-side CPU 112);
A gaming machine characterized by comprising:

  According to the feature C1, since a setting value to be used is set from among a plurality of stages of setting values corresponding to the player's degree of advantage, the player has a more advantageous setting value to be used. You will expect that. When a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage means. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented.

  In this case, until a specific amount of predetermined history information is newly stored in the history storage means, even if a new setting value to be used is set, it is stored before the setting is performed. History information is not deleted. Thereby, even if a new setting value is set, it is possible to specify the management result of the game history in a predetermined period.

  Feature C2. The post-setting handling means sets the setting value when a predetermined amount of history information is stored in the history storage means after the setting value to be used is set by the setting means. The gaming machine according to C1, wherein the history information stored in the history storage means is erased before the game is performed.

  According to the feature C2, when a specific amount of history information is stored in the history storage unit, the management result of the game history in a predetermined period after the setting value is newly set can be specified. The history information stored in the history storage means before the new setting value is set is deleted. Thereby, it is possible to prevent unnecessary history information from being continuously stored in the history storage means.

Feature C3. The history storage means includes first history storage means (first history memory 191) and second history storage means (second history memory 192),
The history storage executing means includes
When the predetermined event occurs, the history information corresponding to the history information corresponding to the first history storage means and the second history storage means set as a storage target (step S2603 in the management CPU 112) Function to execute processing)
After the setting value to be used is set by the setting unit, predetermined history information is stored on the side of the first history storage unit and the second history storage unit that is not set as the storage target. Means (management-side CPU 112) for storing the history information corresponding to the occurrence of the predetermined event in both the first history storage means and the second history storage means for the occurrence of the predetermined event until the predetermined amount or more is stored. The function of executing the process of step S2604 in FIG.
With
The post-setting response means is
After the setting value to be used is set by the setting unit, predetermined history information is stored on the side of the first history storage unit and the second history storage unit that is not set as the storage target. Means for changing the storage object between the first history storage means and the second history storage means (function to execute the processing of step S2607 in the management side CPU 112) when the specified amount or more is stored;
After the setting value to be used is set by the setting unit, predetermined history information is stored on the side of the first history storage unit and the second history storage unit that is not set as the storage target. When the specified amount or more is stored, the history information on the side of the first history storage means and the second history storage means that has been set as the storage target until then (step S2608 in the management CPU 112) Function to execute processing)
A gaming machine according to the feature C1 or C2, characterized by comprising:

  According to the feature C3, until a specific amount of history information is newly stored in the history storage unit, even if a new setting value to be used is set, it is stored before the setting is performed. History information is not deleted. Thereby, even if a new setting value is set, it is possible to specify the management result of the game history in a predetermined period. In addition, it is possible to produce the effect simply by appropriately changing the history storage unit that is the storage target of the history information between the first history storage unit and the second history storage unit.

  Feature C4. Deriving mode information corresponding to a game result in a predetermined period using the history information stored on the side set as the storage target of the first history storage means and the second history storage means The gaming machine according to Feature C3, further comprising information deriving means (a function of executing the processing of Step S2703 in the management CPU 112).

  According to the feature C4, even when the history information is stored in both the first history storage unit and the second history storage unit due to a new setting value setting, the history information is used. Information can be appropriately derived.

Feature C5. A ball entry means (first operation port 33, second operation port 34) capable of entering a game ball flowing down the game area;
Information acquisition means (a function of executing the processing of step S401 in the main CPU 63) for acquiring special information based on the game ball entering the ball entry means;
Grant determination means (function for executing the processes of steps S503 and S504 in the main CPU 63) for determining whether or not the special information corresponds to the grant information;
Based on the result of granting that the special information corresponds to the granting information in the granting determination, a privilege granting unit (step in the main CPU 63) for granting a privilege (opening / closing execution mode) to the player The function of executing the processes of S409 to S412),
With
The gaming machine according to any one of features C1 to C4, wherein a probability of the grant correspondence result varies in the grant determination according to the set value.

  According to the feature C5, in the so-called pachinko machine, it is possible to vary the probability of the assignment correspondence result according to the set value.

  In addition, with respect to the configuration of the features C1 to C5, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature D group>
Feature D1. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
Special execution means for executing special processing on the basis of at least one condition that setting of the setting value to be used by the setting means is executed in a special situation (in the third embodiment, monitoring of repeated changes in the management CPU 112) A function for executing processing, a function for executing repetitive change monitoring processing in the main CPU 63 in the fourth embodiment, and a function for making a negative determination in step S2106 in the management CPU 112 in the fifth embodiment),
A gaming machine characterized by comprising:

  According to the feature D1, since a setting value to be used is set from among a plurality of stages of setting values corresponding to the player's advantage, the player has a more advantageous setting value to be used. You will expect that. In this case, the special processing is executed on at least one condition that the new setting of the setting value to be used is executed in the special situation. Thereby, it becomes possible to cope with a case where a new setting value is set under an unfavorable situation.

  Feature D2. The special execution means executes the special processing on at least one condition that the setting value to be used by the setting means is set a specific number of times or more in the special situation. The gaming machine described in 1.

  According to the feature D2, even if a new setting value to be used in a special situation is executed, the special process is not executed if the number of executions is less than a specific number. Thereby, it is possible to prevent the special process from being executed until a regular worker performs a new setting value setting less than a specific number of times in a special situation.

  Feature D3. The special execution means sets, as the special situation, a situation in which a game has not been performed since the setting value is set by the setting means or a setting value to be used by the setting means. The special process is executed on at least one condition that the setting means has set the setting value to be used in a situation where a game exceeding a predetermined standard has not been played since A gaming machine according to the feature D1 or D2.

  According to the feature D3, when a new setting of a setting value to be used is performed in a situation where no game is performed or a game is not substantially performed, special processing is executed. When this action is performed, it is possible to cope with it.

  Feature D4. The gaming machine according to any one of features D1 to D3, wherein the special execution unit executes a notification process as the special process.

  According to the feature D4, the notification process is executed under at least one condition that a new setting of a setting value to be used is executed in a special situation. As a result, when a new setting value is set under an unfavorable situation, it is possible to prompt the user to deal with it.

Feature D5. History storage execution means (function to execute history setting processing in the management CPU 112) that stores history information of a game corresponding to a predetermined event when the game is executed in the history storage means (history memory 117) )When,
Corresponding to the result of a game in a predetermined period using the history information stored in the history storage means, on the condition that the setting value to be used by the setting means has been set Information deriving means for deriving mode information to be performed (a function for executing the process of step S1807 in the management CPU 112 in the third embodiment, a function of executing the process of step S2107 in the management CPU 112 in the fifth embodiment),
A gaming machine according to any one of features D1 to D4, characterized in that

  According to the feature D5, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage unit. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented.

  In this case, the mode information corresponding to the result of the game in a predetermined period using the history information stored in the history storage means when a new setting value to be used is set. Derived. Thereby, it becomes possible to grasp the management result of the game history such as the occurrence frequency of the predetermined event in the situation before the set value is changed.

  Feature D6. The special execution means derives the mode information by the information deriving means as the special processing on the condition that the setting of the setting value to be used by the setting means is executed in the special situation. The gaming machine according to Feature D5, wherein the gaming machine is not allowed to perform.

  According to the feature D6, even if a new setting value to be used is set, the mode information is not derived when the setting is performed in an unfavorable situation. As a result, it is possible to prevent the aspect information from being unnecessarily derived.

  Feature D7. The gaming machine according to D5 or D6, further comprising mode information storage means (separate storage memory 171) for storing the mode information derived by the information deriving means.

  According to the feature D7, the mode information corresponding to the result of the game in a predetermined period using the history information stored in the history storage unit when the setting value to be used is newly set. Is derived, the aspect information is stored in the aspect information storage means. Thereby, even if the set value is changed, it becomes possible to grasp the management result of the game history in a situation before the set value is changed at an arbitrary timing thereafter.

  Feature D8. The gaming machine according to Feature D7, wherein the aspect information storage means is capable of storing a plurality of the aspect information.

  According to the feature D8, since it is possible to store a plurality of pieces of aspect information in the aspect information storage means, the management results of the game history in a plurality of periods are grasped based on the timing when a new setting value is set It becomes possible to do. In addition, even if a new setting value is repeated under a situation where no game is played, the mode information derived using the history information of the situation where the game is being played is substantially the mode information storage means. It is possible to increase the possibility of remaining in

Feature D9. The aspect information storage means can store a predetermined number of the aspect information,
The special execution means is for executing the special processing when the setting value to be used by the setting means is set to exceed the predetermined number in the special situation. Or the game machine as described in D8.

  According to the feature D9, the setting value is set in a situation where the game is not performed so that the aspect information derived using the history information of the situation where the game is substantially performed does not remain in the aspect information storage unit. When the new setting is repeated, a special process is performed on the new setting. Thereby, it becomes possible to cope with the action.

Feature D10. A ball entry means (first operation port 33, second operation port 34) capable of entering a game ball flowing down the game area;
Information acquisition means (a function of executing the processing of step S401 in the main CPU 63) for acquiring special information based on the game ball entering the ball entry means;
Grant determination means (function for executing the processes of steps S503 and S504 in the main CPU 63) for determining whether or not the special information corresponds to the grant information;
Based on the result of granting that the special information corresponds to the granting information in the granting determination, a privilege granting unit (step in the main CPU 63) for granting a privilege (opening / closing execution mode) to the player The function of executing the processes of S409 to S412),
With
The gaming machine according to any one of features D1 to D9, wherein a probability of the grant correspondence result varies in the grant determination according to the set value.

  According to the feature D10, in the so-called pachinko machine, it is possible to vary the probability of the assignment correspondence result according to the set value.

  In addition, with respect to the configuration of the features D1 to D10, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature E group>
Feature E1. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
History storage execution means (function to execute history setting processing in the management CPU 112) that stores history information of a game corresponding to a predetermined event when the game is executed in the history storage means (history memory 117) )When,
Corresponding to the result of a game in a predetermined period using the history information stored in the history storage means, on the condition that the setting value to be used by the setting means has been set Information deriving means for deriving mode information to be performed (a function for executing the process of step S1807 in the management CPU 112 in the third embodiment, a function of executing the process of step S2107 in the management CPU 112 in the fifth embodiment),
A gaming machine characterized by comprising:

  According to the feature E1, since a setting value to be used is set from among a plurality of stages of setting values corresponding to the player's advantage, the player has a more advantageous setting value to be used. You will expect that. When a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage means. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented.

  In this case, the mode information corresponding to the result of the game in a predetermined period using the history information stored in the history storage means when a new setting value to be used is set. Derived. Thereby, it becomes possible to grasp the management result of the game history such as the occurrence frequency of the predetermined event in the situation before the set value is changed.

  Feature E2. The gaming machine according to feature E1, further comprising aspect information storage means (another storage memory 171) for storing the aspect information derived by the information deriving means.

  According to the feature E2, aspect information corresponding to the result of the game in a predetermined period using the history information stored in the history storage means triggered by the new setting of the setting value to be used Is derived, the aspect information is stored in the aspect information storage means. Thereby, even if the set value is changed, it becomes possible to grasp the management result of the game history in a situation before the set value is changed at an arbitrary timing thereafter.

  Feature E3. The gaming machine according to Feature E2, wherein the aspect information storage means is capable of storing a plurality of the aspect information.

  According to the feature E3, since a plurality of pieces of aspect information can be stored in the aspect information storage unit, the management results of the game history in a plurality of periods are grasped based on the timing when a new setting value is set. It becomes possible to do. In addition, even if a new setting value is repeated under a situation where no game is played, the mode information derived using the history information of the situation where the game is being played is substantially the mode information storage means. It is possible to increase the possibility of remaining in

Feature E4. The aspect information storage means can store a predetermined number of the aspect information,
The gaming machine is a means for executing special processing when the setting value set by the setting means exceeds the predetermined number under a predetermined condition (in the third embodiment, in the management CPU 112). The gaming machine according to feature E2 or E3, further comprising a function of executing a monitoring process of repeated changes, a function of executing a monitoring process of repeated changes in the main CPU 63 in the fourth embodiment.

  According to the feature E4, the setting value is set in a situation where the game is not performed so that the aspect information derived using the history information of the situation where the game is substantially performed does not remain in the aspect information storage unit. When the new setting is repeated, a special process is performed on the new setting. Thereby, it becomes possible to cope with the action.

  Feature E5. The gaming machine according to any one of features E1 to E4, wherein the information deriving unit derives the mode information when a predetermined amount or more of the predetermined history information is stored in the history storage unit. .

  According to the feature E5, since the mode information is derived when a predetermined amount or more of the predetermined history information is stored in the history storage unit, it is possible to prevent the mode information from being unnecessarily derived. Become.

Feature E6. A ball entry means (first operation port 33, second operation port 34) capable of entering a game ball flowing down the game area;
Information acquisition means (a function of executing the processing of step S401 in the main CPU 63) for acquiring special information based on the game ball entering the ball entry means;
Grant determination means (function for executing the processes of steps S503 and S504 in the main CPU 63) for determining whether or not the special information corresponds to the grant information;
Based on the result of granting that the special information corresponds to the granting information in the granting determination, a privilege granting unit (step in the main CPU 63) for granting a privilege (opening / closing execution mode) to the player The function of executing the processes of S409 to S412),
With
The gaming machine according to any one of features E1 to E5, wherein a probability of the grant correspondence result varies in the grant determination according to the set value.

  According to the feature E6, in the so-called pachinko machine, it is possible to vary the probability of the assignment correspondence result according to the set value.

  In addition, with respect to the configuration of the features E1 to E6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature A group, the feature B group, the feature C group, the feature D group, and the feature E group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, in a pachinko gaming machine, the front of the gaming machine is provided with a dish storage unit that stores game balls given to the player, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in gaming machines such as the above-described examples, management of gaming machines needs to be performed suitably, and there is still room for improvement in this respect.

<Feature F group>
Feature F1. A ball entry means (first operation port 33, second operation port 34) capable of entering a game ball flowing down the game area;
Information acquisition means (a function of executing the processing of step S401 in the main CPU 63) for acquiring special information based on the game ball entering the ball entry means;
Grant determination means (function for executing the processes of steps S503 and S504 in the main CPU 63) for determining whether or not the special information corresponds to the grant information;
Based on the result of granting that the special information corresponds to the granting information in the granting determination, a privilege granting unit (step in the main CPU 63) for granting a privilege (opening / closing execution mode) to the player The function of executing the processes of S409 to S412),
A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
With
The grant determination means has, as the grant determination mode, a high probability mode and a low probability mode so that the probability of the grant correspondence result is relatively high and low,
The gaming machine according to claim 1, wherein the probability of the grant correspondence result varies at least in the low probability mode according to the set value.

  According to the feature F1, it is possible to change the probability of an assignment correspondence result in at least the low probability mode according to the set value in a so-called pachinko machine. Thereby, even if it is a single game machine, it becomes possible to produce the situation where it becomes advantageous or unfavorable about the probability which becomes a grant correspondence result in low probability mode. Therefore, it is possible to improve the interest of the game.

  Feature F2. The gaming machine according to Feature F1, wherein the probability of the assignment correspondence result in the high probability mode does not vary according to the set value.

  According to the feature F2, the probability of the assignment correspondence result in the low probability mode is changed according to the set value, while the probability of the assignment correspondence result in the high probability mode is not changed according to the set value. By doing so, it becomes possible to limit the influence of the set value to the situation in the low probability mode.

Feature F3. There are multiple types of benefits,
The gaming machine according to feature F1 or F2, wherein a selection mode of the privilege does not vary according to the set value.

  According to the feature F3, the probability of the result corresponding to the grant in the low probability mode is changed according to the set value, while the selection mode of the privilege is not changed according to the set value. Can be limited to situations in low probability mode.

  In addition, with respect to the configuration of the features F1 to F3, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature group F, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, in a pachinko gaming machine, the front of the gaming machine is provided with a dish storage unit that stores game balls given to the player, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in the gaming machine such as the above example, it is necessary to improve the interest of the game, and there is still room for improvement in this respect.

<Feature G group>
Feature G1. History storage execution means (function to execute history setting processing in the management CPU 112) that stores history information of a game corresponding to a predetermined event when the game is executed in the history storage means (history memory 117) )When,
Information deriving means for deriving mode information corresponding to the result of the game in a predetermined period using the history information stored in the history storage means (in the first embodiment, steps S1402 to S1412 in the management CPU 112) A function for executing the process of step S1807 in the management CPU 112 in the third embodiment, a function for executing the process of step S2107 in the management CPU 112 in the fifth embodiment),
Information display means (in the first to tenth embodiments, the first to third notification display devices 69a to 69c, the first to the first information so that the display corresponding to the aspect information derived by the information deriving means is performed). In the fourteenth embodiment, first information display control means (function to execute display processing in the management CPU 112) for controlling display of the first to fourth notification display devices 201 to 204);
Second information display control means for controlling display of the information display means so that display corresponding to different information different from the aspect information is performed (in the first to tenth embodiments, steps S202 and S208 in the main CPU 63). In the eleventh embodiment, the function of executing steps S3101, S3103, and S3109 in the main CPU 63. In the twelfth embodiment, steps S3201, S3202, and S3204 in the main CPU 63. And the function of executing the process of step S3210, the function of executing the abnormality display process in the main CPU 63 in the thirteenth embodiment),
A gaming machine characterized by comprising:

  According to the feature G1, when a predetermined event occurs, history information corresponding thereto is stored in the history storage means. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. Moreover, the aspect information corresponding to the result of the game in a predetermined period is derived using the history information stored in the history storage means. Then, display corresponding to the mode information is performed by the information display means. Thereby, it becomes possible to grasp the management result of the game history such as the occurrence frequency of the predetermined event. The information display means displays not only the display corresponding to the mode information but also the display corresponding to the other information. As a result, the information display means can be used effectively.

  Feature G2. The period according to which the display corresponding to the mode information is performed in the information display unit and the period during which the display corresponding to the other information is performed in the information display unit are distinguished from each other in the feature G1 Gaming machine.

  According to the feature G2, which of the display corresponding to the mode information and the display corresponding to the different information is performed in the information display unit by grasping the situation where the display is performed in the information display unit. Can be specified.

  Feature G3. The second information display control means controls the display of the information display means so that the display mode is different from the display mode when the display corresponding to the mode information is performed, so that the display corresponding to the different information is displayed. The gaming machine according to the characteristic G1 or G2, wherein the gaming machine is performed.

  According to the feature G3, by grasping the display mode of the information display unit, it is possible to specify which of the display corresponding to the mode information and the display corresponding to the different information is being performed in the information display unit. It becomes possible.

  Feature G4. As the information display means, individual information display means capable of performing a plurality of types of display (in the first to tenth embodiments, first to third notification display devices 69a to 69c, 11th to 14th). In the embodiment, the gaming machine according to any one of features G1 to G3, comprising a plurality of first to fourth notification display devices 201 to 204).

  According to the feature G4, it is possible to display a wide variety of aspect information by performing a display corresponding to the aspect information using a plurality of individual information display means. In addition, since there are a plurality of individual information display means, it is possible to make the display mode greatly different between the case where the display corresponding to the mode information is performed and the case where the display corresponding to the different information is performed. .

  Feature G5. The second information display control means is a predetermined individual that is not in a non-display state when a display corresponding to the aspect information is performed among the plurality of individual information display means when the display corresponding to the different information is performed. Information display means (first notification display device 69a and second notification display device 69b in the first to tenth embodiments, first notification display device 201 and second notification display devices in the eleventh and twelfth embodiments. The display device 202 and the third notification display device 203, and in the thirteenth embodiment, the first notification display device 201 and the second notification display device 202) are set in a non-display state. The gaming machine described in 1.

  According to the feature G5, when the display corresponding to the mode information is performed, the predetermined individual information display unit that is not in the non-display state is in the non-display state when the display corresponding to the other information is performed. This makes it possible to clearly identify which one of the display corresponding to the mode information and the display corresponding to the other information is performed only by grasping the type of the individual information display means that is in the non-display state. Is possible.

Feature G6. The second information display control means is a specific individual information display means (first display) that is in a display state when displaying the mode information among the plurality of individual information display means when performing display corresponding to the different information. The first notification display device 69c in the first to tenth embodiments, the fourth notification display device 204 in the eleventh and twelfth embodiments, the third notification display device 203 and the fourth notification in the thirteenth embodiment. Display device 204) in a display state,
The display content of the specific individual information display unit when the display corresponding to the different information is performed can be displayed on the specific individual information display unit when the display corresponding to the aspect information is performed. The gaming machine according to Feature G5.

  According to the feature G6, in the specific individual information display means, the display content that can be displayed when the display corresponding to the mode information is performed can be displayed also when the display corresponding to the different information is performed, It is possible to prevent the display contents from being restricted when the display corresponding to the information is performed. In addition, even if the specific individual information display means has the same display contents as described above, it is not in a non-display state when the display corresponding to the mode information is provided with the configuration of the feature G5. When the display corresponding to the different information is performed by the predetermined individual information display unit, the display is in a non-display state, and thus it is possible to specify which display is performed on the plurality of individual information display units.

  Feature G7. The gaming machine according to the characteristic G5 or G6, wherein the first information display control means sets each of the plurality of individual information display means in a display state when the display corresponding to the aspect information is performed.

  According to the feature G7, when the display corresponding to the mode information is performed, each of the plurality of individual information display means is in the display state, so that the predetermined individual information display means corresponds to the different information in the non-display state. It is possible to clearly distinguish from the case where the display is performed.

  Feature G8. The first information display control means sequentially changes the display of the aspect information on the information display means, and the predetermined individual information display means is not displayed even when the display of the aspect information is changed. The gaming machine according to any one of features G5 to G7, wherein

  According to the feature G8, when the display corresponding to the mode information is performed, the predetermined individual information display unit is not maintained in the non-display state. Thereby, regardless of the timing when the plurality of individual information display means are confirmed, it is specified which of the display corresponding to the mode information and the display corresponding to the different information is performed on the plurality of individual information display means. Is possible.

  Feature G9. The second information display control means is one specific individual information display means (in the first to tenth embodiments, the third notification display device 69c, eleventh, twelfth) among the plurality of individual information display means. In any of the features G5 to G8, in the fourth notification display device 204), display corresponding to the different information is performed in the fourth notification display device 204), and the remaining individual information display means is set in a non-display state. A gaming machine according to claim 1.

  According to the feature G9, when the display corresponding to the different information is performed, only one individual information display unit is in the display state, so that it is easy to grasp whether the display corresponding to the different information is performed. Become.

Feature G10. The plurality of individual information display means are arranged in a predetermined direction,
The gaming machine according to Feature G9, wherein the specific individual information display means is present at an end portion in the predetermined direction among the plurality of individual information display means arranged in the predetermined direction.

  According to the feature G10, since one individual information display means for displaying corresponding to the different information is present at the end in the predetermined direction, it is grasped whether the display corresponding to the different information is performed. It becomes easy to do.

Feature G11. The first information display control means is an individual information display means of a type display target that is a part of the plurality of individual information display means (first notification display device 69a, eleventh in the first to tenth embodiments). In the fourteenth embodiment, the first notification display device 201 and the second notification display device 202) perform display corresponding to the type of the aspect information to be displayed, and a plurality of the individual information display means Individual information display means of a result display object that is a part of the display information (the second notification display device 69b and the third notification display device 69c in the first to tenth embodiments, the first notification display device in the 11th to 14th embodiments. 3 notification display device 203 and fourth notification display device 204) display corresponding to the content of the aspect information to be displayed,
The gaming machine according to any one of features G5 to G10, wherein the predetermined individual information display means corresponds to the individual information display means of the type display target.

  According to the feature G11, when the display corresponding to the mode information is performed, the display corresponding to the type of the mode information to be displayed is performed in the individual information display unit of the type display target and the individual information display of the result display target The display corresponding to the content of the aspect information to be displayed in the means is performed. Thereby, it becomes easy to grasp | ascertain the aspect information used as display object. In this case, when the display corresponding to the different information is performed, the individual information display means of the type display target is in the non-display state, so the state of the type display non-display corresponds to the different information, It will be easier to grasp if other information is displayed.

Feature G12. The information display means has a plurality of unit light emitting units (display segments 201a to 201g, 202a to 202g), and performs a predetermined display by a combination of unit light emitting units in a light emitting state among the plurality of unit light emitting units. Is a possible configuration,
The second information display control means responds to the different information by setting a unit light emitting unit that can be in a light emitting state when the display corresponding to the aspect information is performed among the plurality of unit light emitting units to be in a light emitting state. When the display corresponding to the different information is performed, the combination of the unit light emitting units that is in the light emitting state when the display corresponding to the different information is performed does not exist when the display corresponding to the aspect information is performed. The gaming machine according to any one of features G1 to G11, wherein the gaming machine is a combination.

  According to the feature G12, when the display corresponding to the aspect information is performed, the display corresponding to the other information is performed by setting the unit light emitting unit that can be in the light emission state to the light emission state, thereby performing the display corresponding to the different information. In order to diversify, it is possible to limit the content of the display corresponding to the mode information as much as possible. On the other hand, when the display corresponding to the different information is performed, the combination of the unit light emitting units that are in the light emission state is a combination that does not exist when the display corresponding to the mode information is performed. Thereby, it becomes possible to grasp which one of the display corresponding to the mode information and the display corresponding to the different information is performed by grasping the combination of the unit light emitting units that are in the light emission state.

Feature G13. There are a plurality of display modes of display corresponding to the mode information in the information display means,
The game according to Feature G12, wherein the plurality of unit light emitting units include no unit light emitting unit that does not enter a light emitting state even when all the displays corresponding to the aspect information of the plurality of aspects are performed. Machine.

  According to the feature G13, when the display corresponding to the mode information is performed, the unit light emitting units in an arbitrary combination are configured to be in the light emitting state. Therefore, the mode for diversifying the display corresponding to the mode information It is possible to minimize the restrictions on the display contents corresponding to the information.

Feature G14. Specific individual information display means which is the information display means (third notification display device 69c in the first to tenth embodiments, fourth notification display device 204 in the eleventh and twelfth embodiments, thirteenth The embodiment includes a plurality of individual information display means including the third notification display device 203 and the fourth notification display device 204),
The second information display control means is a predetermined individual that is not in a non-display state when a display corresponding to the aspect information is performed among the plurality of individual information display means when the display corresponding to the different information is performed. Information display means (first notification display device 69a and second notification display device 69b in the first to tenth embodiments, first notification display device 201 and second notification display devices in the eleventh and twelfth embodiments. The display device 202 and the third notification display device 203, and in the thirteenth embodiment, the first notification display device 201 and the second notification display device 202) are set in a non-display state. Or the gaming machine described in G13.

  According to the feature G14, when the display corresponding to the mode information is performed, the predetermined individual information display unit that is not in the non-display state is in the non-display state when the display corresponding to the other information is performed. This makes it possible to clearly identify which one of the display corresponding to the mode information and the display corresponding to the other information is performed only by grasping the type of the individual information display means that is in the non-display state. Is possible.

Feature G15. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from among a plurality of setting values corresponding to the player's advantage;
The gaming machine according to any one of features G1 to G14, wherein the second information display control unit causes display corresponding to the different information to be performed in a situation where the set value can be changed.

  According to the feature G15, the information display unit that performs display corresponding to the mode information can be used as a display unit for notifying that the setting value can be changed.

  Feature G16. The gaming machine according to Feature G15, wherein the second information display control means displays information corresponding to a set value currently selected as a display corresponding to the different information.

  According to the feature G16, the information display unit that performs display corresponding to the mode information can be also used as a display unit for displaying the setting value being changed.

  Feature G17. The gaming machine according to any one of features G1 to G16, wherein the second information display control means causes a display corresponding to an abnormal state of the gaming machine to be performed as a display corresponding to the different information.

  According to the feature G17, the information display unit that performs display corresponding to the mode information can also be used as the display unit for performing display corresponding to the abnormal state of the gaming machine.

  Feature G18. The second information display control means causes the display corresponding to the absence of the abnormal state to be performed when the display corresponding to the abnormal state is performed in the situation where the abnormal state does not occur. A gaming machine according to Feature G17.

  According to the feature G18, it is possible to clearly specify whether or not an abnormal state has occurred by checking the information display means.

  In addition, with respect to the configuration of the features G1 to G18, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature H group>
Feature H1. History storage execution means (function to execute history setting processing in the management CPU 112) that stores history information of a game corresponding to a predetermined event when the game is executed in the history storage means (history memory 117) )When,
Information deriving means for deriving mode information corresponding to the result of the game in a predetermined period using the history information stored in the history storage means (in the first embodiment, steps S1402 to S1412 in the management CPU 112) A function for executing the process of step S1807 in the management CPU 112 in the third embodiment, a function for executing the process of step S2107 in the management CPU 112 in the fifth embodiment),
Information display means (in the first to tenth embodiments, the first to third notification display devices 69a to 69c, the first to the first information so that the display corresponding to the aspect information derived by the information deriving means is performed). In the fourteenth embodiment, first information display control means (function to execute display processing in the management CPU 112) for controlling display of the first to fourth notification display devices 201 to 204);
Second information display control means for controlling display of the information display means so that display corresponding to different information different from the aspect information is performed (in the first to tenth embodiments, steps S202 and S208 in the main CPU 63). In the eleventh embodiment, the function of executing steps S3101, S3103, and S3109 in the main CPU 63. In the twelfth embodiment, steps S3201, S3202, and S3204 in the main CPU 63. And the function of executing the process of step S3210, the function of executing the abnormality display process in the main CPU 63 in the thirteenth embodiment),
With
The information display means has a plurality of unit light emitting units (display segments 201a to 201g, 202a to 202g), and performs a predetermined display by a combination of unit light emitting units in a light emitting state among the plurality of unit light emitting units. Is a possible configuration,
The second information display control means responds to the different information by setting a unit light emitting unit that can be in a light emitting state when the display corresponding to the aspect information is performed among the plurality of unit light emitting units to be in a light emitting state. When the display corresponding to the different information is performed, the combination of the unit light emitting units that is in the light emitting state when the display corresponding to the different information is performed does not exist when the display corresponding to the aspect information is performed. A gaming machine characterized by being a combination.

  According to the feature H1, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage unit. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. Moreover, the aspect information corresponding to the result of the game in a predetermined period is derived using the history information stored in the history storage means. Then, display corresponding to the mode information is performed by the information display means. Thereby, it becomes possible to grasp the management result of the game history such as the occurrence frequency of the predetermined event. The information display means displays not only the display corresponding to the mode information but also the display corresponding to the other information. As a result, the information display means can be used effectively.

  In addition, when the display corresponding to the mode information is performed, the unit light emitting unit that can be in the light emitting state is set in the light emitting state, and the display corresponding to the different information is performed, thereby diversifying the display corresponding to the mode information. Therefore, it is possible to limit the display contents corresponding to the mode information as much as possible. On the other hand, when the display corresponding to the different information is performed, the combination of the unit light emitting units that are in the light emission state is a combination that does not exist when the display corresponding to the mode information is performed. Thereby, it becomes possible to grasp which one of the display corresponding to the mode information and the display corresponding to the different information is performed by grasping the combination of the unit light emitting units that are in the light emission state.

Feature H2. There are a plurality of display modes of display corresponding to the mode information in the information display means,
The game according to Feature H1, wherein the plurality of unit light emitting units do not have a unit light emitting unit that does not enter a light emitting state even if all the displays corresponding to the aspect information of the plurality of aspects are performed. Machine.

  According to the feature H2, when the display corresponding to the mode information is performed, the unit light emitting units in an arbitrary combination are configured to be in the light emitting state. Therefore, the mode for diversifying the display corresponding to the mode information It is possible to minimize the restrictions on the display contents corresponding to the information.

Feature H3. Specific individual information display means which is the information display means (third notification display device 69c in the first to tenth embodiments, fourth notification display device 204 in the eleventh and twelfth embodiments, thirteenth The embodiment includes a plurality of individual information display means including the third notification display device 203 and the fourth notification display device 204),
The second information display control means is a predetermined individual that is not in a non-display state when a display corresponding to the aspect information is performed among the plurality of individual information display means when the display corresponding to the different information is performed. Information display means (first notification display device 69a and second notification display device 69b in the first to tenth embodiments, first notification display device 201 and second notification display devices in the eleventh and twelfth embodiments. The display device 202 and the third notification display device 203, and in the thirteenth embodiment, the first notification display device 201 and the second notification display device 202) are set in a non-display state. Or the gaming machine described in H2.

  According to the feature H3, when the display corresponding to the mode information is performed, the predetermined individual information display unit that is not in the non-display state is in the non-display state when the display corresponding to the other information is performed. This makes it possible to clearly identify which one of the display corresponding to the mode information and the display corresponding to the other information is performed only by grasping the type of the individual information display means that is in the non-display state. Is possible.

  Feature H4. The game machine according to Feature H3, wherein the first information display control means puts each of the plurality of individual information display means into a display state when displaying corresponding to the aspect information.

  According to the feature H4, when the display corresponding to the mode information is performed, each of the plurality of individual information display units is in the display state, and therefore the predetermined individual information display unit corresponds to the different information in the non-display state. It is possible to clearly distinguish from the case where the display is performed.

  Feature H5. The first information display control means sequentially changes the display of the aspect information on the information display means, and the predetermined individual information display means is not displayed even when the display of the aspect information is changed. The gaming machine according to the feature H3 or H4, wherein

  According to the feature H5, when the display corresponding to the aspect information is performed, the predetermined individual information display unit is not maintained in the non-display state. Thereby, regardless of the timing when the plurality of individual information display means are confirmed, it is specified which of the display corresponding to the mode information and the display corresponding to the different information is performed on the plurality of individual information display means. Is possible.

Feature H6. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from among a plurality of setting values corresponding to the player's advantage;
The gaming machine according to any one of features H1 to H5, wherein the second information display control unit causes display corresponding to the different information to be performed in a situation where the set value can be changed.

  According to the feature H6, the information display unit that performs display corresponding to the mode information can be used as a display unit for notifying that the setting value can be changed.

  Feature H7. The gaming machine according to Feature H6, wherein the second information display control means displays information corresponding to a set value currently selected as a display corresponding to the different information.

  According to the feature H7, the information display unit that performs the display corresponding to the mode information can be used as the display unit for displaying the setting value being changed.

  In addition, with respect to the configuration of the features H1 to H7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature I group>
Feature I1. History storage execution means (function to execute history setting processing in the management CPU 112) that stores history information of a game corresponding to a predetermined event when the game is executed in the history storage means (history memory 117) )When,
Information deriving means for deriving mode information corresponding to the result of the game in a predetermined period using the history information stored in the history storage means (in the first embodiment, steps S1402 to S1412 in the management CPU 112) A function for executing the process of step S1807 in the management CPU 112 in the third embodiment, a function for executing the process of step S2107 in the management CPU 112 in the fifth embodiment),
First information display control means (management side) for controlling display of the information display means (first to fourth notification display devices 201 to 204) so that display corresponding to the aspect information derived by the information deriving means is performed. A function of executing processing for display in the CPU 112);
Second information display control means (function for executing abnormality display processing in the main CPU 63) for controlling display of the information display means so that display corresponding to an abnormal state of the gaming machine is performed;
A gaming machine characterized by comprising:

  According to the feature I1, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage unit. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. Moreover, the aspect information corresponding to the result of the game in a predetermined period is derived using the history information stored in the history storage means. Then, display corresponding to the mode information is performed by the information display means. Thereby, it becomes possible to grasp the management result of the game history such as the occurrence frequency of the predetermined event. The information display means displays not only the display corresponding to the mode information but also the display corresponding to the abnormal state of the gaming machine. As a result, the information display means can be used effectively.

  Feature I2. The second information display control means causes the display corresponding to the absence of the abnormal state to be performed when the display corresponding to the abnormal state is performed in the situation where the abnormal state does not occur. The gaming machine according to feature I1.

  According to the feature I2, it is possible to clearly specify whether or not an abnormal state has occurred by checking the information display unit.

  Feature I3. A feature I1 or I2 is characterized in that a period in which the display corresponding to the mode information is performed in the information display means is distinguished from a period in which the display corresponding to the abnormal state is performed in the information display means. The gaming machine described.

  According to the feature I3, which of the display corresponding to the mode information and the display corresponding to the abnormal state is performed in the information display unit by grasping the situation where the display is performed in the information display unit. Can be specified.

  Feature I4. The second information display control means controls the display of the information display means so that the display mode is different from the display mode when the display corresponding to the mode information is performed, so that the display corresponding to the abnormal state is displayed. The gaming machine according to the characteristic G1 or G2, wherein the gaming machine is performed.

  According to the characteristic I4, it is possible to identify which of the display corresponding to the aspect information and the display corresponding to the abnormal state is performed by the information display unit by grasping the display mode of the information display unit. It becomes possible.

  Feature I5. The information display means includes a plurality of individual information display means (first to fourth notification display devices 201 to 204) each capable of performing a plurality of types of display. The gaming machine according to any one of the above.

  According to the feature I5, it is possible to display a wide variety of aspect information by performing display corresponding to the aspect information using a plurality of individual information display means. Further, since there are a plurality of individual information display means, it is possible to make the display mode greatly different between the case where the display corresponding to the mode information is performed and the case where the display corresponding to the abnormal state is performed. .

  Feature I6. The second information display control means is a predetermined individual that does not enter a non-display state when the display corresponding to the aspect information is performed among the plurality of individual information display means when the display corresponding to the abnormal state is performed. The gaming machine according to Feature I5, wherein the information display means (the first notification display device 201 and the second notification display device 202) is in a non-display state.

  According to the feature I6, when the display corresponding to the mode information is performed, the predetermined individual information display unit that is not in the non-display state is in the non-display state when the display corresponding to the abnormal state is performed. In this way, it is possible to clearly identify which one of the display corresponding to the mode information and the display corresponding to the abnormal state is performed only by grasping the type of the individual information display means in the non-display state. Is possible.

Feature I7. When the display corresponding to the abnormal state is performed, the second information display control unit is a specific individual information display unit (first unit that is in a display state when displaying the mode information among the plurality of individual information display units. 3 notification display device 203 and fourth notification display device 204) are in a display state,
The display content of the specific individual information display means when the display corresponding to the abnormal state is performed can be displayed on the specific individual information display means when the display corresponding to the aspect information is performed. A gaming machine according to feature I6.

  According to the characteristic I7, the display content that can be displayed when the display corresponding to the mode information is performed in the specific individual information display means can be displayed even when the display corresponding to the abnormal state is performed, It is possible to prevent the display contents from being restricted when the display corresponding to the information is performed. In addition, even if the specific individual information display means has the same display content as described above, it does not become a non-display state when the display corresponding to the mode information is performed with the configuration of the feature I7. When the display corresponding to the abnormal state is performed on the predetermined individual information display means, the display is in the non-display state, so it is possible to specify which display is being performed on the plurality of individual information display means.

  Feature I8. The gaming machine according to the characteristic I6 or I7, wherein the first information display control means sets each of the plurality of individual information display means in a display state when the display corresponding to the mode information is performed.

  According to the feature I8, when the display corresponding to the mode information is performed, each of the plurality of individual information display means is in the display state, and thus the predetermined individual information display means corresponds to the abnormal state in which the display state is not displayed. It is possible to clearly distinguish from the case where the display is performed.

  Feature I9. The first information display control means sequentially changes the display of the aspect information on the information display means, and the predetermined individual information display means is not displayed even when the display of the aspect information is changed. The gaming machine according to any one of features I6 to I8, wherein

  According to the feature I9, when the display corresponding to the mode information is performed, the predetermined individual information display unit is not maintained in the non-display state. Thereby, regardless of the timing when the plurality of individual information display means are confirmed, it is specified which of the display corresponding to the mode information and the display corresponding to the abnormal state is performed on the plurality of individual information display means. Is possible.

  In addition, with respect to the configuration of the features I1 to I9, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature J group>
Feature J1. History storage execution means (function to execute history setting processing in the management CPU 112) that stores history information of a game corresponding to a predetermined event when the game is executed in the history storage means (history memory 117) )When,
Information deriving means for deriving mode information corresponding to the result of the game in a predetermined period using the history information stored in the history storage means (in the first embodiment, steps S1402 to S1412 in the management CPU 112) A function for executing the process of step S1807 in the management CPU 112 in the third embodiment, a function for executing the process of step S2107 in the management CPU 112 in the fifth embodiment),
Information display means (in the first to tenth embodiments, the first to third notification display devices 69a to 69c, the first to the first information so that the display corresponding to the aspect information derived by the information deriving means is performed). In the fourteenth embodiment, first information display control means (function to execute display processing in the management CPU 112) for controlling display of the first to fourth notification display devices 201 to 204);
With
The first information display control means sequentially changes the display corresponding to the aspect information in the information display means, and the information display means is not displayed even when the display corresponding to the aspect information is changed. A gaming machine characterized by not being maintained in a state.

  According to the feature J1, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage unit. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. Moreover, the aspect information corresponding to the result of the game in a predetermined period is derived using the history information stored in the history storage means. Then, display corresponding to the mode information is performed by the information display means. Thereby, it becomes possible to grasp the management result of the game history such as the occurrence frequency of the predetermined event. Further, when the display corresponding to the mode information is performed, the information display means is not maintained in the non-display state. Thereby, it becomes possible to specify the display corresponding to the mode information regardless of the timing when the information display means is confirmed.

  Feature J2. As the information display means, individual information display means capable of performing a plurality of types of display (in the first to tenth embodiments, first to third notification display devices 69a to 69c, 11th to 14th). In the embodiment, the gaming machine according to the feature J1 is provided with a plurality of first to fourth notification display devices 201 to 204).

  According to the feature J2, it is possible to display a wide variety of aspect information by performing a display corresponding to the aspect information using a plurality of individual information display means.

  Feature J3. The game machine according to Feature J2, wherein the first information display control means puts each of the plurality of individual information display means into a display state when displaying corresponding to the mode information.

  According to the feature J3, when the display corresponding to the aspect information is performed, each of the plurality of individual information display means is in the display state, and even when the display corresponding to the aspect information is changed, the display state is maintained. Maintained. Thereby, it becomes easy to grasp | ascertain aspect information.

  Feature J4. The first information display control means is an individual information display means of a type display target that is a part of the plurality of individual information display means (first notification display device 69a, eleventh in the first to tenth embodiments). In the fourteenth embodiment, the first notification display device 201 and the second notification display device 202) perform display corresponding to the type of the aspect information to be displayed, and a plurality of the individual information display means Individual information display means of a result display object that is a part of the display information (the second notification display device 69b and the third notification display device 69c in the first to tenth embodiments, the first notification display device in the 11th to 14th embodiments. 3 informing display device 203 and 4th informing display device 204) display corresponding to the content of the aspect information to be displayed is performed. The gaming machine according to feature J2 or J3

  According to the feature J4, when the display corresponding to the mode information is performed, the display corresponding to the type of the mode information to be displayed is performed in the individual information display unit of the type display target and the individual information display of the result display target The display corresponding to the content of the aspect information to be displayed in the means is performed. Thereby, it becomes easy to grasp | ascertain the aspect information used as display object.

  In addition, with respect to the configuration of the features J1 to J4, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature K group>
Feature K1. History storage execution means (function to execute history setting processing in the management CPU 112) that stores history information of a game corresponding to a predetermined event when the game is executed in the history storage means (history memory 117) )
The history storage execution means is means for preventing the history information from being stored in the history storage means even if the predetermined event occurs (function of making a negative determination in step S3501 in the main CPU 63) when the predetermined event occurs. ).

  According to the feature K1, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage unit. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. Further, since history information is not stored even if a predetermined event occurs in a restricted situation, it is possible to prevent history information from being stored in a situation where it is not desirable to store history information. .

  Feature K2. The gaming machine according to claim K1, wherein the restriction situation can occur as a situation from the start of supply of operating power to the history storage execution means until a restriction release event occurs.

  According to the feature K2, it is possible to prevent the occurrence of a predetermined event due to an operation check immediately after the start of supply of operating power from being stored as history information.

Feature K3. Means for setting the restriction status when the supply of operating power to the history storage execution means is started and the restriction condition is satisfied (function for executing the process of step S3610 in the main CPU 63); ,
Means for not setting the restriction status when the supply of operating power to the history storage execution means is started and the restriction condition is not satisfied (function of executing the process of step S3621 in the main CPU 63) When,
A gaming machine according to Feature K2, characterized by comprising:

  According to the feature K3, there is a case where the restriction status is set and a case where the restriction condition is not set depending on whether or not the restriction condition is satisfied. As a result, it is possible to prevent the restriction status from being set as necessary.

  Feature K4. The restriction situation may occur as a situation from the start of supply of operating power to the history storage execution means until the number of game balls discharged from the game area exceeds a predetermined reference number. The gaming machine according to any one of K1 to K3.

  According to the feature K4, it is possible to prevent the history information from being stored until the number of game balls discharged from the game area exceeds a predetermined reference number after the supply of operating power is started.

Feature K5. When a predetermined event occurs by executing a game, the history information of the game corresponding thereto is stored in history storage means (normal counter area 231, opening / closing execution mode counter area 232, high frequency support mode counter area 233). History storage execution means for storing (a function of executing a normal entrance management process in the main CPU 63, an entrance management process in the opening / closing execution mode, and an entrance management process in the high frequency support mode);
Information deriving means (function for executing the processing of step S4208 in the main CPU 63) for deriving mode information corresponding to the result of the game in a predetermined period using the history information stored in the history storage means;
With
The information derivation means does not derive the mode information when the situation is restricted.

  According to the feature K5, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage unit. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. Moreover, the aspect information corresponding to the result of the game in a predetermined period is derived using the history information stored in the history storage means. Thereby, it becomes possible to grasp the management result of the game history such as the occurrence frequency of the predetermined event. In addition, in a restricted situation, even if a predetermined event occurs, the aspect information is not derived. Therefore, it is possible to prevent the aspect information from being derived in a situation where it is not preferable to derive the aspect information. .

  Feature K6. The gaming machine according to Feature K5, wherein the restriction situation can occur as a situation from the start of supply of operating power to the history storage execution means until a restriction release event occurs.

  According to the feature K6, it is possible to prevent the mode information using the history information based on the occurrence of the predetermined event by the operation check immediately after the start of the supply of the operating power from being derived.

  Feature K7. The restriction situation may occur as a situation from the start of supply of operating power to the history storage execution means until the number of game balls discharged from the game area exceeds a predetermined reference number. A gaming machine according to K5 or K6.

  According to the feature K7, it is possible to prevent the mode information from being derived until the number of game balls discharged from the game area becomes equal to or greater than the predetermined reference number after the supply of operating power is started.

  In addition, with respect to the configuration of the features K1 to K7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature G group, the feature H group, the feature I group, the feature J group, and the feature K group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, in a pachinko gaming machine, the front of the gaming machine is provided with a dish storage unit that stores game balls given to the player, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in gaming machines such as the above-described examples, management of gaming machines needs to be performed suitably, and there is still room for improvement in this respect.

<Feature L group>
Feature L1. A control unit (main CPU 63) that executes various processes and temporarily stores information in an internal storage unit (register of the main CPU 63) when the process is executed,
The control means is
A first predetermined process execution means (a function for executing processes other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing the first predetermined process among the various processes;
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
At least one stored in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed. Saving execution means (a function for executing the processing of steps S3802 and S3902 to S3907 in the main CPU 63 in the fifteenth embodiment, In the embodiment, the function of step S4402 in the main CPU 63 is executed. In the seventeenth embodiment, the function of steps S4502 to S4507 in the main CPU 63 is executed. In the eighteenth embodiment, the step in the main CPU 63 is executed. The function of executing the processing of S4602, the main-side CP in the nineteenth embodiment Processing of step S4701 and step S4703 and the ability to perform) in 63,
The return execution means for returning the predetermined information saved in the predetermined storage means to the internal storage means (in the fifteenth embodiment, step S3804 in the main CPU 63) The function of executing steps S3910 to S3915, the function of executing step S4404 in the main CPU 63 in the sixteenth embodiment, and the processes of steps S4510 to S4515 in the main CPU 63 in the seventeenth embodiment. A function for executing the process of step S4605 in the main CPU 63 in the eighteenth embodiment, a function for executing the processes of step S4705 and step S4706 in the main CPU 63 in the nineteenth embodiment),
A gaming machine characterized by comprising:

  According to the feature L1, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed or the situation where the second predetermined process is executed is stored in the internal storage means At least a part of the information is saved in the predetermined storage means. Thus, when the second predetermined process is executed, it is possible to prevent the information stored in the internal storage unit from being rewritten when the first predetermined process is executed. In addition, when the second predetermined process is ended or after the end, the information saved in the predetermined storage unit is returned to the internal storage unit. Thereby, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process. As described above, various controls can be suitably performed.

  Feature L2. The gaming machine according to the characteristic L1, wherein the predetermined information is a part of information stored in the internal storage means.

  According to the feature L2, since only a part of the information stored in the internal storage means is saved in the predetermined storage means, the storage capacity necessary for saving the information in the internal storage means in the predetermined storage means is reduced. It becomes possible to suppress.

Feature L3. The internal storage means includes a first storage area (WA register, BC register, DE register, HL register, IX register and IY register) and a second storage area (WA register, BC register, DE register, HL register, IX register and A register other than the IY register),
The second predetermined process execution means is configured to store information in the first storage area in the second predetermined process, but not to store information in the second storage area,
The game machine according to Feature L2, wherein the save execution means saves the information stored in the first storage area to the predetermined storage means.

  According to the characteristic L3, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed, or when the situation where the second predetermined process is executed, the second predetermined process is performed in the internal storage unit. The information in the first storage area that is the storage target of information is saved in the predetermined storage means. As a result, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process. It is possible to reduce the storage capacity necessary for saving the information stored in the storage means.

Feature L4. The predetermined storage means is
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined process is executed;
A second predetermined storage area (non-specific control work area 223, non-specific control stack area 224) in which information is stored when the second predetermined process is executed;
With
The game machine according to any one of features L1 to L3, wherein the save execution means saves the predetermined information in the second predetermined storage area.

  According to the characteristic L4, since the first predetermined storage area and the second predetermined storage area are provided in the predetermined storage unit, the storage destination of the information in the predetermined storage unit is determined by the first predetermined process and the second predetermined process. It is possible to make a distinct difference. Thereby, it is possible to prevent information used in the other process from being deleted when one of the first predetermined process and the second predetermined process is executed. In this case, at least a part of the information stored in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed Is saved in the second predetermined storage area. As a result, it is possible to save the information in the internal storage unit immediately before the start of the second predetermined process, and it is possible to save the information without using the first predetermined storage area.

Feature L5. The save execution means includes
In the first predetermined process, the first predetermined information, which is a part of the information stored in the internal storage means, is changed from the situation in which the first predetermined process is executed to the situation in which the second predetermined process is executed. Means for evacuating to the first predetermined storage area (in the fifteenth embodiment, the function of executing the process of step S3802 in the main CPU 63; in the sixteenth embodiment, the function of executing the process of step S4402 in the main CPU 63); ,
When the second predetermined process is executed from the situation in which the first predetermined process is being executed, the second predetermined information, which is a part of information stored in the internal storage means, is stored in the second predetermined process. In the second predetermined storage area (in the fifteenth embodiment, the function of executing steps S3902 to S3907 in the main CPU 63; in the seventeenth embodiment, in steps S4502 to S4507 of the main CPU 63; A function of executing processing, a function of executing processing of step S4602 in the main CPU 63 in the eighteenth embodiment, a function of executing processing of steps S4702 and S4703 in the main CPU 63 in the nineteenth embodiment),
The gaming machine according to Feature L4, comprising:

  According to the feature L5, the first predetermined information which is a part of information stored in the internal storage unit is saved in the first predetermined storage area in the first predetermined process, and the part of the information stored in the internal storage unit The second predetermined information is saved in the second predetermined storage area in the second predetermined process. As a result, it is possible to perform saving at a timing suitable for each piece of information stored in the internal storage means, and the processing for saving the information is executed in a distributed manner between the first predetermined processing and the second predetermined processing. It becomes possible.

  Feature L6. The gaming machine according to Feature L5, wherein the first predetermined information is information of a flag register provided in the internal storage means.

  According to the feature L6, it is possible to appropriately save the information in the flag register when the first predetermined process is being executed.

Feature L7. The second predetermined storage area is
A stack area (stack area 224 for non-specific control) in which information can be written by a push instruction and information can be read by a pop instruction;
A work area in which information can be written and read by a load instruction (work area 223 for non-specific control);
With
The game machine according to any one of features L4 to L6, wherein the save execution means saves the predetermined information in one of the stack area and the work area.

  According to the feature L7, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed, or when the situation where the second predetermined process is executed, the stack area in the second predetermined storage area At least a part of the information stored in the internal storage means is saved in one of the work areas. As a result, it is possible to consolidate information saving destinations, and it is possible to simplify the processing configuration for saving and the processing configuration for returning.

  Feature L8. The game machine according to Feature L7, wherein the save execution means saves the predetermined information in the work area.

  According to the feature L8, since the save destination of at least a part of the information stored in the internal storage means is the work area, the information can be saved without performing a cumulative change of the stack pointer. Become.

Feature L9. The first predetermined storage area can store information and read information when the first predetermined process is executed, and can read information when the second predetermined process is executed. Information cannot be stored,
The second predetermined storage area can store information and read information when the second predetermined process is executed, and can read information when the first predetermined process is executed. The gaming machine according to any one of features L4 to L8, wherein information cannot be stored.

  According to the feature L9, the first predetermined storage area can be handled as a dedicated storage area for the first predetermined process, and the second predetermined storage area can be handled as a dedicated storage area for the second predetermined process. It becomes.

Feature L10. The predetermined storage means is
A stack area (stack area 224 for non-specific control) in which information can be written by a push instruction and information can be read by a pop instruction;
A work area in which information can be written and read by a load instruction (work area 223 for non-specific control);
With
The game machine according to any one of features L1 to L9, wherein the save execution unit saves the predetermined information in one of the stack area and the work area.

  According to the feature L10, the save destinations of the predetermined information can be aggregated, and the processing configuration for saving the predetermined information and the processing configuration for returning the predetermined information can be simplified.

  Feature L11. The game machine according to Feature L10, wherein the save execution means saves the predetermined information in the work area.

  According to the feature L11, since the save destination of the predetermined information is the work area, the information can be saved without performing a cumulative change of the stack pointer.

Feature L12. The predetermined information is a part of information stored in the internal storage means,
The save execution unit is configured to store the internal storage unit when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed. The game machine according to Feature L11, further comprising means (a function of executing the process of step S3802 in the main CPU 63) for saving specific information that is a part of information stored in the stack area to the stack area. .

  According to the feature L12, the specific information is saved in the stack area in the configuration in which the predetermined information is saved in the work area. As a result, the information stored in the internal storage means can be distributed and saved in the work area and the stack area.

  Feature L13. The gaming machine according to Feature L12, wherein the predetermined information has a larger amount of information than the specific information.

  According to the feature L13, a predetermined amount of information larger than the specific information is saved in the work area, so that a lot of information is accumulated in the stack area when saving the information stored in the internal storage unit. It is possible to prevent it from being lost.

Feature L14. Information on the stack pointer provided in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed Is a configuration that becomes fixed information,
The gaming machine according to any one of features L1 to L13, wherein the information of the stack pointer provided in the internal storage unit is not a target of saving by the saving execution unit.

  According to the feature L14, since it is not necessary to secure a capacity for saving information of the stack pointer in the predetermined storage unit, the capacity of the predetermined storage unit can be suppressed. Further, even when the information of the stack pointer is not saved as described above, the situation where the second predetermined process is executed from the situation where the first predetermined process is executed, or the situation where the second predetermined process is executed, In this case, since the stack pointer information becomes fixed information, it is possible to return to the stack pointer information before the second predetermined processing is started without saving the stack pointer information as described above. Is possible.

  Feature L15. Means for setting the fixed information in the stack pointer when or after the second predetermined process is finished (in the fifteenth embodiment, the function of executing the process of step S3909 in the main CPU 63, the seventeenth implementation) The game machine according to Feature L14, wherein the game machine has a function of executing the process of step S4509 in the main CPU 63 in the embodiment, and a function of executing the process of step S4604 in the main CPU 63 in the eighteenth embodiment. .

  According to the feature L15, it is possible to return to the information of the stack pointer when the second predetermined process is ended or after the second predetermined process is started before the second predetermined process is started.

  Feature L16. When the situation where the second predetermined process is executed from the situation where the first predetermined process is executed, or when the situation where the second predetermined process is executed, the stack pointer is changed to the second predetermined process. Means for setting corresponding second correspondence start information (in the fifteenth embodiment, the function of executing the process of step S3901 in the main CPU 63, the function of executing the process of step S4501 in the main CPU 63 in the seventeenth embodiment, In the eighteenth embodiment, the gaming machine according to the feature L14 or L15, which includes a function of executing the processing of step S4601 in the main CPU 63.

  According to the feature L16, when the second predetermined process is started, the second correspondence start information corresponding to the second predetermined process is set in the stack pointer, so that an appropriate address can be set in the second predetermined process. Information can be stored in the stack area.

Feature L17. The first predetermined process includes a process for controlling the progress of the game,
The gaming machine according to any one of features L1 to L16, wherein the second predetermined process includes a process for managing a game history.

  According to the feature L17, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, thereby controlling the progress of the game. Therefore, it is possible to prevent information used in the process for managing the game history from being rewritten when the process for executing the process is executed.

Feature L18. The predetermined storage means is
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined process is executed;
A second predetermined storage area (non-specific control work area 223, non-specific control stack area 224) in which information is stored when the second predetermined process is executed;
With
The second predetermined storage area is a history storage area (normal counter area 231, open / close execution mode counter area 232) in which a game history information corresponding to a predetermined event occurs when a game is executed. The gaming machine according to Feature L17, comprising a high-frequency support mode counter area 233).

  According to the feature L18, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent information stored in the history storage area from being rewritten during execution.

  Feature L19. The second predetermined process execution means is information derivation means (step S4208 in the main CPU 63) for deriving mode information corresponding to the game result in a predetermined period using the history information stored in the history storage area. The gaming machine according to the feature L18, which is provided with a function of executing the process (1).

  According to the feature L19, game history management such as occurrence frequency of a predetermined event is performed by deriving mode information corresponding to a game result in a predetermined period using the history information stored in the history storage area. It becomes possible to grasp the result.

  Feature L20. The gaming machine according to Feature L19, wherein the second predetermined storage area includes an aspect information storage area (calculation result storage area 234) for storing the aspect information derived by the information deriving means.

  According to the feature L20, when the aspect information corresponding to the game result in the predetermined period is derived using the history information, the aspect information is stored in the aspect information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

  In addition, with respect to the configuration of the features L1 to L20, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature M group>
Feature M1. A control unit (main CPU 63) that executes various processes and temporarily stores information in an internal storage unit (register of the main CPU 63) when the process is executed,
The control means is
A first predetermined process execution means (a function for executing processes other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing the first predetermined process among the various processes;
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
At least one stored in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed. Saving execution means for saving predetermined information, which is part information, to a predetermined storage means (main RAM 65) (in the fifteenth embodiment, the function of executing the processing of steps S3902 to S3907 in the main CPU 63, seventeenth embodiment In the eighteenth embodiment, the function of executing the processing of step S4602 in the main CPU 63, and in the nineteenth embodiment, the function of executing steps S4701 and S450 in the main CPU 63. The function of executing the processing of S4703),
When the second predetermined process is ended or after the completion, the return execution means for returning the predetermined information saved in the predetermined storage means to the internal storage means (in the fifteenth embodiment, step S3910 in the main CPU 63). A function for executing the process of step S3915; a function for executing the process of steps S4510 to S4515 in the main CPU 63 in the seventeenth embodiment; a function of executing the process of step S4605 in the main CPU 63 in the eighteenth embodiment; In the nineteenth embodiment, the function of executing the processing of step S4705 and step S4706 in the main CPU 63),
With
The retreat execution means retreats the predetermined information to the predetermined storage means by a load command.

  According to the feature M1, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed or the situation where the second predetermined process is executed is stored in the internal storage means Predetermined information, which is at least part of information, is saved in the predetermined storage means. Thus, when the second predetermined process is executed, it is possible to prevent the information stored in the internal storage unit from being rewritten when the first predetermined process is executed. In addition, when the second predetermined process is completed or after the completion, the predetermined information saved in the predetermined storage unit is returned to the internal storage unit. Thereby, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process. When the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed, the predetermined information is saved in the predetermined storage means by the load instruction. . As a result, it is possible to save the predetermined information without changing the stack pointer.

Feature M2. The predetermined storage means is
A stack area (stack area 224 for non-specific control) in which information can be written by a push instruction and information can be read by a pop instruction;
A work area in which information can be written and read by a load instruction (work area 223 for non-specific control);
With
The game machine according to feature M1, wherein the save execution means saves the predetermined information in the work area.

  According to the feature M2, when the save destination of the predetermined information, which is at least a part of information stored in the internal storage means, is the work area, the information is saved without cumulatively changing the stack pointer. It becomes possible.

Feature M3. The predetermined information is a part of information stored in the internal storage means,
The save execution unit is configured to store the internal storage unit when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed. The gaming machine according to feature M2, further comprising means (a function of executing the process of step S3802 in the main CPU 63) for saving specific information, which is a part of information stored in the storage area, to the stack area. .

  According to the feature M3, the specific information is saved in the stack area in the configuration in which the predetermined information is saved in the work area. As a result, the information stored in the internal storage means can be distributed and saved in the work area and the stack area.

  Feature M4. The gaming machine according to Feature M3, wherein the predetermined information has a larger amount of information than the specific information.

  According to the feature M4, when a predetermined amount of information larger than the specific information is saved in the work area, a large amount of information is accumulated in the stack area when the information stored in the internal storage unit is saved. It is possible to prevent it from being lost.

Feature M5. The work area is
A first work area (a work area 221 for specific control) in which information is stored when the first predetermined process is executed;
A second work area (a work area 223 for non-specific control) in which information is stored when the second predetermined process is executed;
With
The gaming machine according to any one of features M2 to M4, wherein the retreat execution unit retreats the predetermined information to the second work area.

  According to the feature M5, since the first work area and the second work area are provided in the work area, the storage destination of information in the work area is clearly different between the first predetermined process and the second predetermined process. It becomes possible. Thereby, it is possible to prevent information used in the other process from being deleted when one of the first predetermined process and the second predetermined process is executed. In this case, at least a part of the information stored in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed Is saved in the second work area. As a result, it is possible to save the information in the internal storage unit immediately before the second predetermined process is started, and it is possible to save the information without using the first work area.

Feature M6. The first work area is capable of storing information and reading information when the first predetermined process is executed, and reading information when the second predetermined process is executed. Information cannot be stored,
The second work area is capable of storing information and reading information when the second predetermined process is executed, and reading information when the first predetermined process is executed. The gaming machine according to Feature M5, wherein information cannot be stored.

  According to the feature M6, the first work area can be handled as a storage area dedicated to the first predetermined process, and the second work area can be handled as a storage area dedicated to the second predetermined process. .

Feature M7. A control unit (main CPU 63) that executes various processes and temporarily stores information in an internal storage unit (register of the main CPU 63) when the process is executed,
The control means is
A first predetermined process execution means (a function for executing processes other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing the first predetermined process among the various processes;
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
At least one stored in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed. Saving execution means for saving predetermined information, which is part information, to a predetermined storage means (main RAM 65) (in the fifteenth embodiment, the function of executing the processing of steps S3902 to S3907 in the main CPU 63, seventeenth embodiment In the eighteenth embodiment, the function of executing the processing of step S4602 in the main CPU 63, and in the nineteenth embodiment, the function of executing steps S4701 and S450 in the main CPU 63. The function of executing the processing of S4703),
When the second predetermined process is ended or after the completion, the return execution means for returning the predetermined information saved in the predetermined storage means to the internal storage means (in the fifteenth embodiment, step S3910 in the main CPU 63). A function for executing the process of step S3915; a function for executing the process of steps S4510 to S4515 in the main CPU 63 in the seventeenth embodiment; a function of executing the process of step S4605 in the main CPU 63 in the eighteenth embodiment; In the nineteenth embodiment, the function of executing the processing of step S4705 and step S4706 in the main CPU 63),
With
The predetermined storage means is
A stack area (stack area 224 for non-specific control) in which information can be written by a push instruction and information can be read by a pop instruction;
A work area in which information can be written and read by a load instruction (work area 223 for non-specific control);
With
The retreat execution means retreats the predetermined information to one of the stack area and the work area.

  According to the feature M7, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed or the situation where the second predetermined process is executed is stored in the internal storage means Predetermined information, which is at least part of information, is saved in the predetermined storage means. Thus, when the second predetermined process is executed, it is possible to prevent the information stored in the internal storage unit from being rewritten when the first predetermined process is executed. In addition, when the second predetermined process is completed or after the completion, the predetermined information saved in the predetermined storage unit is returned to the internal storage unit. Thereby, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process.

  Further, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed or the situation where the second predetermined process is executed, one of the stack area and the work area in the predetermined storage means In addition, the predetermined information is saved. As a result, it is possible to consolidate information saving destinations, and it is possible to simplify the processing configuration for saving and the processing configuration for returning.

  In addition, with respect to the configuration of the features M1 to M7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature N group>
Feature N1. A control unit (main CPU 63) that executes various processes and temporarily stores information in an internal storage unit (register of the main CPU 63) when the process is executed,
The control means is
A first predetermined process execution means (a function for executing processes other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing the first predetermined process among the various processes;
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
With
When the situation where the second predetermined process is executed from the situation where the first predetermined process is executed, the information of the stack pointer provided in the internal storage means is fixed information. To play.

  According to the feature N1, the information of the stack pointer provided in the internal storage means becomes fixed information when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed. There is no need to save the information of the stack pointer when starting predetermined processing. This eliminates the need to secure a storage area for saving the stack pointer information. In addition, when the second predetermined process is executed from the situation where the first predetermined process is executed, the stack pointer information becomes fixed information, so that the stack pointer information is not saved as described above. However, it is possible to return to the information of the stack pointer before the second predetermined process is started.

  Feature N2. Means for setting the fixed information in the stack pointer when or after the second predetermined process is finished (in the fifteenth embodiment, the function of executing the process of step S3909 in the main CPU 63, the seventeenth implementation) The game machine according to Feature N1, further comprising a function for executing the process of step S4509 in the main CPU 63 in the embodiment, and a function for executing the process of step S4604 in the main CPU 63 in the eighteenth embodiment. .

  According to the feature N2, it is possible to return to the information of the stack pointer when the second predetermined process is ended or after the second predetermined process is started.

  Feature N3. Means for setting second correspondence start information corresponding to the second predetermined processing in the stack pointer when the second predetermined processing is executed from the state in which the first predetermined processing is executed (fifteenth In the eighteenth embodiment, the function of executing the process of step S3901 in the main CPU 63, in the seventeenth embodiment, the function of executing the process of step S4501 in the main CPU 63, and in the eighteenth embodiment, the process of step S4601 in the main CPU 63. The gaming machine according to the feature N1 or N2, characterized in that the gaming machine is provided with a function of

  According to the feature N3, when the second predetermined process is started, second correspondence start information corresponding to the second predetermined process is set in the stack pointer, so that an appropriate address can be set in the second predetermined process. Information can be stored in the stack area.

Feature N4. At least one stored in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed. Saving execution means (a function for executing the processing of steps S3802 and S3902 to S3907 in the main CPU 63 in the fifteenth embodiment, In the embodiment, the function of step S4402 in the main CPU 63 is executed. In the seventeenth embodiment, the function of steps S4502 to S4507 in the main CPU 63 is executed. In the eighteenth embodiment, the step in the main CPU 63 is executed. The function of executing the processing of S4602, the main-side CP in the nineteenth embodiment Processing of step S4701 and step S4703 and the ability to perform) in 63,
The return execution means for returning the predetermined information saved in the predetermined storage means to the internal storage means (in the fifteenth embodiment, step S3804 in the main CPU 63) The function of executing steps S3910 to S3915, the function of executing step S4404 in the main CPU 63 in the sixteenth embodiment, and the processes of steps S4510 to S4515 in the main CPU 63 in the seventeenth embodiment. A function for executing the process of step S4605 in the main CPU 63 in the eighteenth embodiment, a function for executing the processes of step S4705 and step S4706 in the main CPU 63 in the nineteenth embodiment),
With
The gaming machine according to any one of features N1 to N3, wherein information of the stack pointer provided in the internal storage means is not a target of saving by the saving execution means.

  According to the feature N4, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed or the situation where the second predetermined process is executed is stored in the internal storage means At least a part of the information is saved in the predetermined storage means. Thus, when the second predetermined process is executed, it is possible to prevent the information stored in the internal storage unit from being rewritten when the first predetermined process is executed. In addition, when the second predetermined process is ended or after the end, the information saved in the predetermined storage unit is returned to the internal storage unit. Thereby, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process. Further, since the stack pointer information is not a target for saving, it is not necessary to secure a capacity for saving the stack pointer information in the predetermined storage means. Therefore, it is possible to suppress the capacity of the predetermined storage unit. Further, even when the information of the stack pointer is not saved as described above, the situation where the second predetermined process is executed from the situation where the first predetermined process is executed, or the situation where the second predetermined process is executed, In this case, since the stack pointer information becomes fixed information, it is possible to return to the stack pointer information before the second predetermined processing is started without saving the stack pointer information as described above. Is possible.

Feature N5. The predetermined storage means is
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined process is executed;
A second predetermined storage area (non-specific control work area 223, non-specific control stack area 224) in which information is stored when the second predetermined process is executed;
With
The gaming machine according to Feature N4, wherein the save execution means saves the predetermined information in the second predetermined storage area.

  According to the feature N5, since the first predetermined storage area and the second predetermined storage area are provided in the predetermined storage unit, the storage destination of the information in the predetermined storage unit is determined by the first predetermined process and the second predetermined process. It is possible to make a distinct difference. Thereby, it is possible to prevent information used in the other process from being deleted when one of the first predetermined process and the second predetermined process is executed. In this case, at least a part of the information stored in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed Is saved in the second predetermined storage area. As a result, it is possible to save the information in the internal storage unit immediately before the start of the second predetermined process, and it is possible to save the information without using the first predetermined storage area.

Feature N6. The first predetermined storage area can store information and read information when the first predetermined process is executed, and can read information when the second predetermined process is executed. It ’s impossible to memorize things,
The second predetermined storage area can store information and read information when the second predetermined process is executed, and can read information when the first predetermined process is executed. The gaming machine according to Feature N5, wherein information on things cannot be stored.

  According to the feature N6, the first predetermined storage area can be handled as a dedicated storage area for the first predetermined process, and the second predetermined storage area can be handled as a dedicated storage area for the second predetermined process. It becomes.

  In addition, with respect to the configuration of the features N1 to N6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature O group>
Feature O1. A control unit (main CPU 63) that executes various processes and temporarily stores information in an internal storage unit (register of the main CPU 63) when the process is executed,
The control means is
A first predetermined process execution means (a function for executing processes other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing the first predetermined process among the various processes;
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
At least a part of the storage in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed First state setting means (steps S4803 to S4808 in the main CPU 63) for setting the state of a predetermined storage area (WA register, BC register, DE register, HL register, IX register, and IY register) as a predetermined state. Function to execute)
A second state setting unit (a function of executing the processing of steps S4903 to S4908 in the main CPU 63) for setting the state of the predetermined storage area to the predetermined state when or after the second predetermined processing is ended;
A gaming machine characterized by comprising:

  According to the characteristic O1, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed, or when the situation where the second predetermined process is executed, the predetermined storage area of the internal storage means Is set to a predetermined state, and the state of the predetermined storage area is set to the predetermined state again when or after the second predetermined process is ended. Thereby, the state of the predetermined storage area can be set to a predetermined state before and after the second predetermined process. Therefore, it is possible to prevent the state of the predetermined storage area by one of the first predetermined process and the second predetermined process from affecting the other process. As described above, various controls can be suitably performed.

  Feature O2. The gaming machine according to Feature O1, wherein the predetermined state is a state when supply of operating power to the control means is started.

  According to the feature O2, the predetermined storage area is set to a predetermined state in a state where the supply of operating power to the control unit is started, and thus the processing configuration for setting the predetermined state is simplified. Is possible.

  Feature O3. The gaming machine according to the characteristic O1 or O2, wherein the predetermined state is a state in which the predetermined storage area is cleared to "0".

  According to the feature O3, the predetermined storage area is set to a state in which “0” is cleared as a predetermined state, so that the processing configuration for setting the predetermined state can be simplified.

  Feature O4. The gaming machine according to any one of features O1 to O3, wherein the predetermined storage area is a partial storage area in the internal storage means.

  According to the feature O4, since only a part of the storage area of the internal storage unit is set to the predetermined state, it is possible to reduce the processing load for setting to the predetermined state.

Feature O5. The internal storage means includes at least the predetermined storage area and another storage area (a register other than the WA register, BC register, DE register, HL register, IX register, and IY register),
The second predetermined process execution means is configured to store information in the predetermined storage area in the second predetermined process, but not to store information in the separate storage area,
The gaming machine according to Feature O4, wherein the first state setting means and the second state setting means do not change the state of the separate storage area.

  According to the characteristic O5, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed, or when the situation where the second predetermined process is executed, the second predetermined process is executed in the internal storage means. The predetermined storage area to be the information storage target is set to a predetermined state. As a result, it is possible to prevent the state of the predetermined storage area from the first predetermined process from affecting the second predetermined process. In addition, since the state of the separate storage area is not changed, setting the predetermined state when the second predetermined process is started may not affect the process after the second predetermined process ends. It becomes possible.

  Feature O6. The information in the predetermined storage area before the setting of the predetermined state by the first state setting means is information that is not used after the second predetermined process is completed. The gaming machine according to any one of the above.

  According to the feature O6, even if the predetermined storage area is set to the predetermined state when the second predetermined process is executed or when the second predetermined process is executed, the second predetermined process is ended. It is possible to prevent the subsequent processing from being affected.

Feature O7. A part stored in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed Saving execution means (function for executing the processing of step S4802 in the main CPU 63) for saving predetermined information (information in the flag register) as information on the information to the predetermined storage means (main RAM 65);
Return execution means for returning the predetermined information saved in the predetermined storage means to the internal storage means when the second predetermined process is ended or after the completion (function to execute the process of step S4810 in the main CPU 63) When,
The gaming machine according to any one of features O1 to O6, comprising:

  According to the feature O7, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed or the situation where the second predetermined process is executed is stored in the internal storage means Predetermined information, which is part of the information, is saved in the predetermined storage unit. As a result, when the second predetermined process is executed, the information stored in the internal storage means when the first predetermined process is executed and the information necessary for the subsequent execution of the first predetermined process is rewritten. It becomes possible not to be. In addition, when the second predetermined process is completed or after the completion, the predetermined information saved in the predetermined storage unit is returned to the internal storage unit. Thereby, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process.

Feature O8. The first predetermined process includes a process for controlling the progress of the game,
The gaming machine according to any one of features O1 to O7, wherein the second predetermined process includes a process for managing a game history.

  According to the feature O8, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process, thereby controlling the progress of the game. Therefore, it is possible to prevent information used in the process for managing the game history from being rewritten when the process for executing the process is executed.

Feature O9. The predetermined storage means is
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined process is executed;
A second predetermined storage area (non-specific control work area 223, non-specific control stack area 224) in which information is stored when the second predetermined process is executed;
With
The second predetermined storage area is a history storage area (normal counter area 231, open / close execution mode counter area 232) in which a game history information corresponding to a predetermined event occurs when a game is executed. The gaming machine according to feature O8, comprising a high-frequency support mode counter area 233).

  According to the feature O9, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent information stored in the history storage area from being rewritten during execution.

  Feature O10. The second predetermined process execution means is information derivation means (step S4208 in the main CPU 63) for deriving mode information corresponding to the game result in a predetermined period using the history information stored in the history storage area. The gaming machine according to Feature O9, which is provided with a function of executing the process (1).

  According to the feature O10, game history management such as occurrence frequency of a predetermined event is performed by deriving mode information corresponding to a game result in a predetermined period using the history information stored in the history storage area. It becomes possible to grasp the result.

  Feature O11. The gaming machine according to Feature O10, wherein the second predetermined storage area includes an aspect information storage area (calculation result storage area 234) for storing the aspect information derived by the information deriving means.

  According to the characteristic O11, when the aspect information corresponding to the game result in the predetermined period is derived using the history information, the aspect information is stored in the aspect information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

  In addition, with respect to the configuration of the features O1 to O11, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature P group>
Feature P1. A control unit (main CPU 63) that executes various processes and temporarily stores information in an internal storage unit (register of the main CPU 63) when the process is executed,
The control means is
A first predetermined process execution means (a function for executing processes other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing the first predetermined process among the various processes;
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined process is executed;
A second predetermined storage area (non-specific control work area 223, non-specific control stack area 224) in which information is stored when the second predetermined process is executed;
A gaming machine characterized by comprising:

  According to the feature P1, the first predetermined storage area and the second predetermined storage area are provided, the first predetermined storage area is treated as a dedicated storage area for the first predetermined process, and the second predetermined storage area is It is treated as a dedicated storage area for the second predetermined process. As a result, the storage destination of information in the predetermined storage unit can be clearly made different between the first predetermined process and the second predetermined process. Therefore, it is possible to prevent information used in the other process from being deleted when one of the first predetermined process and the second predetermined process is executed.

Feature P2. The first predetermined process includes a process for controlling the progress of the game,
The gaming machine according to Feature P1, wherein the second predetermined process includes a process for managing a game history.

  According to the feature P2, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process, thereby controlling the progress of the game. Therefore, it is possible to prevent information used in the process for managing the game history from being rewritten when the process for executing the process is executed.

  Feature P3. The second predetermined storage area is a history storage area (normal counter area 231, opening / closing execution mode counter area 232) that stores game history information corresponding to a predetermined event that occurs when a game is executed. The gaming machine according to Feature P2, further comprising a high-frequency support mode counter area 233).

  According to the feature P3, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent information stored in the history storage area from being rewritten during execution.

  Feature P4. The second predetermined process execution means is information derivation means (step S4208 in the main CPU 63) for deriving mode information corresponding to the game result in a predetermined period using the history information stored in the history storage area. The game machine according to Feature P3, further comprising:

  According to the feature P4, game history management such as occurrence frequency of a predetermined event is performed by deriving mode information corresponding to a game result in a predetermined period using the history information stored in the history storage area. It becomes possible to grasp the result.

  Feature P5. The gaming machine according to claim P4, wherein the second predetermined storage area includes an aspect information storage area (calculation result storage area 234) for storing the aspect information derived by the information deriving means.

  According to the feature P5, when the aspect information corresponding to the game result in the predetermined period is derived using the history information, the aspect information is stored in the aspect information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

Feature P6. In the first predetermined process, the first predetermined information, which is a part of the information stored in the internal storage unit, is changed from the situation in which the first predetermined process is executed to the situation in which the second predetermined process is executed. First evacuation means for evacuating to the first predetermined storage area (in the fifteenth embodiment, the function of executing step S3802 in the main CPU 63; in the sixteenth embodiment, executing the process of step S4402 in the main CPU 63) Function)
When the second predetermined process is executed from the situation in which the first predetermined process is being executed, the second predetermined information, which is a part of information stored in the internal storage means, is stored in the second predetermined process. In the second predetermined storage area (in the fifteenth embodiment, the function of executing steps S3902 to S3907 in the main CPU 63, in the seventeenth embodiment, the step S4502 in the main CPU 63). A function of executing the process of step S4507, a function of executing the process of step S4602 in the main CPU 63 in the eighteenth embodiment, and a function of executing the processes of steps S4701 and S4703 in the main CPU 63 in the nineteenth embodiment. When,
The gaming machine according to any one of features P1 to P5, wherein:

  According to the characteristic P6, the first predetermined information which is a part of information stored in the internal storage unit is saved in the first predetermined storage area in the first predetermined process, and the part of the information stored in the internal storage unit The second predetermined information is saved in the second predetermined storage area in the second predetermined process. As a result, it is possible to perform saving at a timing suitable for each piece of information stored in the internal storage means, and the processing for saving the information is executed in a distributed manner between the first predetermined processing and the second predetermined processing. It becomes possible.

Feature P7. When the second predetermined process is ended or after the completion, the first return execution means (in the fifteenth embodiment, the main return means) returns the first predetermined information saved in the first predetermined storage area to the internal storage means. The function of executing the process of step S3804 in the side CPU 63, the function of executing the process of step S4404 in the main CPU 63 in the sixteenth embodiment),
When the second predetermined process is completed or after the second predetermined process is completed, second return execution means (mainly in the fifteenth embodiment, the second predetermined information saved in the second predetermined storage area is returned to the internal storage means. A function for executing the processing of steps S3910 to S3915 in the side CPU 63, a function for executing the processing of steps S4510 to S4515 in the main CPU 63 in the seventeenth embodiment, and a step S4605 in the main CPU 63 in the eighteenth embodiment. A function of executing processing, a function of executing processing in steps S4705 and S4706 in the main CPU 63 in the nineteenth embodiment),
The gaming machine according to Feature P6, comprising:

  According to the characteristic P7, the first predetermined information saved in the first predetermined storage area is returned to the internal storage means when the second predetermined process is finished or after the second predetermined processing is finished, and the first predetermined information saved in the second predetermined storage area is restored. 2 Since the predetermined information is returned to the internal storage means, the state of the internal storage means can be returned to the state before the second predetermined processing is started.

  Feature P8. The gaming machine according to P6 or P7, wherein the first predetermined information includes information of a flag register provided in the internal storage means.

  According to the feature P8, it is possible to appropriately save the information in the flag register in the situation where the first predetermined process is being executed.

  Feature P9. The gaming machine according to any one of features P6 to P8, wherein the second predetermined information includes information of all registers of the internal storage means.

  According to the feature P9, the information of all the registers in the internal storage means is saved together, so there is no need to selectively save the register information.

Feature P10. The second predetermined storage area is
A stack area where information is written by a push instruction and information is read by a pop instruction (stack area 224 for non-specific control);
A work area in which information is written and read by a load instruction (work area 223 for non-specific control);
With
The gaming machine according to claim P9, wherein the second retreat execution means retreats the second predetermined information to one of the stack area and the work area.

  According to the characteristic P10, the information of all the registers in the internal storage unit is saved in one of the stack area and the work area in the second predetermined storage area. As a result, the save destinations of the information of all the registers can be collected, and the processing configuration for saving and the processing configuration for returning can be simplified.

  Feature P11. The game machine according to Feature P10, wherein the second save execution means saves the second predetermined information in the stack area.

  According to the feature P11, it is possible to save the information of all the registers without using the work area.

  Feature P12. The gaming machine according to any one of features P6 to P11, wherein the second predetermined information includes information of a stack pointer of the internal storage means.

  According to the feature P12, it is possible to appropriately save the stack pointer information when the first predetermined process is being executed.

  In addition, with respect to the configuration of the features P1 to P12, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature L group, the feature M group, the feature N group, the feature O group, and the feature P group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, a pachinko gaming machine has a dish storage unit that stores game balls given to a player on the front side of the gaming machine, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in the gaming machine such as the above example, it is necessary to suitably perform various controls, and there is still room for improvement in this respect.

<Feature Q group>
Feature Q1. A control means (MPU 62) for executing various processes and temporarily storing information in an internal storage means (register of the main CPU 63) when the processes are executed;
A history storage means (management RAM 241) that is provided as a separate chip from the control means and can temporarily store information;
With
The control means is a history storage execution means for storing a history information of a game corresponding to a predetermined event when the game is executed in the history storage means (a normal entry management process in the main CPU 63, A gaming machine having a function of executing a pitch management process during the opening / closing execution mode and a pitch management process during the high-frequency support mode.

  According to the feature Q1, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage unit. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. Further, since the history storage means is provided as a separate chip from the control means, it is possible to increase the storage capacity for storing history information while using general-purpose control means.

  Feature Q2. The gaming machine according to Feature Q1, wherein the control means includes predetermined storage means (main-side RAM 65) for temporarily storing information when various processes are executed.

  According to the feature Q2, in a configuration including not only the predetermined storage means provided in the control means but also the history storage means provided as a chip different from the control means, the history information is stored in the history storage means. A lot of history information can be stored and held.

  Feature Q3. The gaming machine according to the feature Q2, wherein the control means temporarily stores information in the predetermined storage means when executing the process related to the history information.

  According to the characteristic Q3, in the configuration in which the history storage unit for storing the history information is provided as a separate chip from the control unit, when processing related to the history information is executed, the predetermined storage unit provided in the control unit Since the information is temporarily stored, it is possible to prevent the processing speed from being extremely reduced when processing related to history information is executed.

  Feature Q4. The control means uses the history information stored in the history storage means to derive mode information corresponding to a game result in a predetermined period (executes the process of step S4208 in the main CPU 63) The gaming machine according to any one of features Q1 to Q3, wherein

  According to the feature Q4, game history management such as occurrence frequency of a predetermined event is performed by deriving mode information corresponding to a game result in a predetermined period using the history information stored in the history storage means. It becomes possible to grasp the result.

  Feature Q5. The gaming machine according to Feature Q4, wherein the second predetermined storage area includes an aspect information storage area (calculation result storage area 234) for storing the aspect information derived by the information deriving means.

  According to the feature Q5, when the aspect information corresponding to the game result in the predetermined period is derived using the history information, the aspect information is stored in the aspect information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing.

  In addition, with respect to the configuration of the features Q1 to Q5, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the above-mentioned feature Q group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, in a pachinko gaming machine, the front of the gaming machine is provided with a dish storage unit that stores game balls given to the player, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in gaming machines such as the above-described examples, management of gaming machines needs to be performed suitably, and there is still room for improvement in this respect.

<Feature R group>
Feature R1. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
When the supply of operating power to the control means having the setting means is started, a plurality of events including the first event and the second event are generated, and the setting means becomes the use target. Situation generating means (a function for executing the processing of steps S5003 to S5006 in the main CPU 63 in the twenty-second embodiment, or the main CPU 63 in another embodiment, in which setting values can be set). A function for executing the processing of steps S5503 to S5507 in FIG. 5, in the twenty-third embodiment, a function for executing the processing of steps S5703 to S5705 and S5715 in the main CPU 63),
A gaming machine characterized by comprising:

  According to the feature R1, since a setting value to be used is set from among a plurality of stages of setting values corresponding to the player's advantage, the player has a more advantageous setting value to be used. You will expect that. In this case, in order to set the setting value to be used, a plurality of events including the first event and the second event occur when the supply of the operating power to the control means is started. Need to be. As a result, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud.

Feature R2. Opening grasping means for grasping that the opening / closing body (front door frame 14) is in an open state (in the twenty-second embodiment, a function for executing the processing of step S5005 in the main CPU 63, in another embodiment, in the main CPU 63) A function for executing the process of S5505, a function for executing the process of step S5703 in the main CPU 63 in the twenty-third embodiment),
The situation generating means identifies that the first event has occurred based on the fact that the opening grasping means grasps that the opening / closing body is in an open state. The gaming machine described in 1.

  According to the feature R2, the opening / closing body needs to be in an open state in order to set the setting value to be used. As a result, when an act of setting a setting value to be used illegally is performed, it is possible to make the illegal act stand out, and as a result, it is possible to easily find the illegal act. .

Feature R3. Separate opening grasping means for grasping that the separate opening / closing body (the gaming machine main body 12) is in the open state (the function of executing step S5006 in the main CPU 63 in the twenty-second embodiment, and the main CPU 63 in the other embodiment) In step S5506, in the twenty-third embodiment, the function of executing step S5704 in the main CPU 63).
The situation generating means specifies that the second event has occurred based on the fact that the separate opening grasping means grasps that the separate opening / closing body is in an open state. A gaming machine according to feature R2.

  According to the feature R3, in order to set the setting value to be used, it is necessary not only to open the opening / closing body but also to open the other opening / closing body. Accordingly, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud, and to make the fraudulent action conspicuous.

Feature R4. The setting means performs at least one of selection of the setting value to be used and setting of the setting value to be used based on the operation of predetermined operation means (update button 68b, reset button 68c). Is a configuration to perform,
The gaming machine according to R2 or R3, wherein the predetermined operation means is configured to be operable by opening another open / close body.

  According to the feature R4, the setting value to be used cannot be set unless the opening / closing body different from the other opening / closing body opened to enable the predetermined operation means to be opened. Accordingly, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud, and to make the fraudulent action conspicuous.

Feature R5. The opening / closing body defines a gaming machine front side of a gaming area in which gaming balls flow down,
5. The gaming machine according to any one of features R2 to R4, wherein the gaming area is opened forward of the gaming machine by opening the opening / closing body.

  According to the feature R5, in order to set the setting value to be used, it is necessary to open the gaming area forward of the gaming machine by opening the opening / closing body. Accordingly, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud, and to make the fraudulent action conspicuous.

  Feature R6. The situation generating means specifies that one of the plurality of events has occurred based on a predetermined operation performed by the setting key on the setting key insertion unit (setting key insertion unit 68a). The gaming machine according to any one of features R1 to R5.

  According to the feature R6, in order to set the setting value to be used, it is necessary not only to perform a predetermined operation with the setting key to the setting key insertion unit but also to generate an event different from that. is there. As a result, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud.

  Feature R7. The situation generating means is configured to detect a plurality of events based on occurrence of a predetermined game event (operation of the launch operation device 28, entry to the through gate 35) that occurs when a game is performed. The gaming machine according to any one of features R1 to R6, wherein one of the events is identified as occurring.

  According to the feature R7, in order to set the setting value to be used, it is not only necessary to generate a predetermined game event that occurs when a game is performed, but separately from that. It is necessary to generate the event. As a result, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud.

  Feature R8. The situation generating means is based on the fact that a game ball is detected by a ball detection means (gate detection sensor 49a) for detecting that a game ball has entered a predetermined ball entrance provided in the game area. The gaming machine according to any one of features R1 to R7, wherein one of the plurality of events is identified as occurring.

  According to the feature R8, in order to set a setting value to be used, it is necessary to cause a game ball to enter a predetermined entry part and to generate an event different from that. There is. As a result, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud.

Feature R9. A setting value notifying unit (a function for executing a setting confirmation process in the main CPU 63) that causes the notifying unit to notify the setting value to be used set by the setting unit;
The setting value notifying means notifies the notifying means of the setting value to be used set by the setting means based on the occurrence of a plurality of events including the first event and the second event. The gaming machine according to any one of features R1 to R8, characterized by:

  According to the feature R9, it is possible to make it difficult to perform an act of confirming the set value due to fraud. In addition, the game hall administrator only needs to generate the first event and the second event when setting the setting value to be used and when confirming the setting value. It becomes common and it becomes easy to grasp each work.

Feature R10. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
A plurality of events including both that a predetermined operation with the setting key for the setting key insertion unit (setting key insertion unit 68a) is performed and another event different from the predetermined operation with the setting key for the setting key insertion unit Based on what has occurred, the situation generating means (in the twenty-second embodiment, in the main CPU 63) that allows the setting means to set the setting value to be used can be set. The function of executing the processing of step S5003 to step S5006, the function of executing the processing of step S5503 to step S5507 in the main CPU 63 in another form, Processing function), and
A gaming machine characterized by comprising:

  According to the feature R10, since a setting value to be used is set from among a plurality of setting values corresponding to the player's degree of advantage, the player has a more advantageous setting value to be used. You will expect that. In this case, in order to set the setting value to be used, it is necessary not only to perform a predetermined operation with the setting key on the setting key insertion unit, but also to generate another event. As a result, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud.

Feature R11. Opening grasping means for grasping that the opening / closing body (front door frame 14) is in an open state (in the twenty-second embodiment, a function for executing the processing of step S5005 in the main CPU 63, in another embodiment, in the main CPU 63) A function for executing the process of S5505, a function for executing the process of step S5703 in the main CPU 63 in the twenty-third embodiment),
The situation generating means identifies that the different event has occurred based on the fact that the opening grasping means grasps that the opening / closing body is in an open state. The gaming machine described.

  According to the feature R11, the opening / closing body needs to be in an open state in order to set the setting value to be used. As a result, when an act of setting a setting value to be used illegally is performed, it is possible to make the illegal act stand out, and as a result, it is possible to easily find the illegal act. .

Feature R12. Separate opening grasping means for grasping that the separate opening / closing body (the gaming machine main body 12) is in the open state (the function of executing step S5006 in the main CPU 63 in the twenty-second embodiment, and the main CPU 63 in the other embodiment) In step S5506, in the twenty-third embodiment, the function of executing step S5704 in the main CPU 63).
The situation generating means identifies that one of the plurality of events has occurred based on the fact that the separate opening grasping means has grasped that the separate opening / closing body is in an open state. The gaming machine according to Feature R11, wherein:

  According to the feature R12, in order to set the setting value to be used, it is necessary not only to open the opening / closing body but also to open the other opening / closing body. Accordingly, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud, and to make the fraudulent action conspicuous.

Feature R13. The setting means performs at least one of selection of the setting value to be used and setting of the setting value to be used based on the operation of predetermined operation means (update button 68b, reset button 68c). Is a configuration to perform,
The gaming machine according to R11 or R12, wherein the predetermined operation means is configured to be operable by opening another open / close body.

  According to the feature R13, the setting value to be used cannot be set unless the opening / closing body different from the other opening / closing body opened to enable the predetermined operation means is opened. Accordingly, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud, and to make the fraudulent action conspicuous.

Feature R14. The opening / closing body defines a gaming machine front side of a gaming area in which gaming balls flow down,
The gaming machine according to any one of features R11 to R13, wherein the gaming area is opened forward of the gaming machine by opening the opening / closing body.

  According to the feature R14, in order to set a setting value to be used, it is necessary to open the gaming area forward of the gaming machine by opening the opening / closing body. Accordingly, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud, and to make the fraudulent action conspicuous.

  Feature R15. The situation generating means is configured to detect a plurality of events based on occurrence of a predetermined game event (operation of the launch operation device 28, entry to the through gate 35) that occurs when a game is performed. The gaming machine according to any one of features R10 to R14, wherein one of the events is identified as occurring.

  According to the feature R15, in order to set a setting value to be used, not only a predetermined operation with a setting key is performed on the setting key insertion unit but also a predetermined that occurs when a game is performed. It is necessary to generate a game event. As a result, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud.

  Feature R16. The situation generating means is based on the fact that a game ball is detected by a ball detection means (gate detection sensor 49a) for detecting that a game ball has entered a predetermined ball entrance provided in the game area. The gaming machine according to any one of features R10 to R15, wherein one of the plurality of events is identified as occurring.

  According to the feature R16, in order to set the setting value to be used, not only the predetermined operation with the setting key is performed on the setting key insertion unit, but also the game ball is inserted into the predetermined pitching unit. Need to make a ball. As a result, it is possible to make it difficult to perform an action of setting a setting value to be used due to fraud.

Feature R17. A setting value notifying unit (a function for executing a setting confirmation process in the main CPU 63) that causes the notifying unit to notify the setting value to be used set by the setting unit;
The setting value notification means is based on the fact that the predetermined operation by the setting key with respect to the setting key insertion portion is being performed and a plurality of events including both of the different events have occurred. The gaming machine according to any one of the characteristics R10 to R16, wherein the notification unit is configured to notify the set value to be used set by the notification means.

  According to the feature R17, it is possible to make it difficult to perform an act of confirming the set value due to fraud. In addition, the game hall administrator performs a predetermined operation with the setting key to the setting key insertion portion and generates another event regardless of whether the setting value to be used is set or the setting value is confirmed. Therefore, the work is made common and it becomes easy to grasp each work.

  In addition, with respect to the configuration of the features R1 to R17, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature R group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, in a pachinko gaming machine, the front of the gaming machine is provided with a dish storage unit that stores game balls given to the player, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in the gaming machines such as the above-described examples, it is necessary to deal with illegal acts on the gaming machines, and there is still room for improvement in this respect.

<Feature S group>
Feature S1. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
Situation generating means (a step S5003 to a step S5006 and a step S5401 in the main CPU 63 in the twenty-second embodiment) in which the setting means can set the setting value to be used by the setting means. A function for executing the process of step S5408, a function for executing the process of step S5503 to step S5507 in the main CPU 63 in another form, and a process of the steps S5703 to S5705 and step S5715 in the main CPU 63 in the twenty-third embodiment. In the twenty-fourth embodiment, the function of executing steps S5801 to S5804 in the main CPU 63. In the twenty-fifth embodiment, the processes of steps S5901 to S5904 in the main CPU 63 are executed. And ability),
Setting value grasping means for grasping whether or not the setting value before the settable state is set and the setting value set by the setting means is the same (in the twenty-second embodiment, step S5017 in the main CPU 63). And a function of executing the processes of steps S5111 to S5112, and in another form, a function of executing the processes of steps S5611 to S5612 in the main CPU 63),
A gaming machine characterized by comprising:

  According to the feature S1, since a setting value to be used is set from among a plurality of stages of setting values corresponding to the player's advantage, the player has a more advantageous setting value to be used. You will expect that. In this case, it is grasped whether or not the set value before the settable situation is the same as the set value set in the settable situation. As a result, it is possible to execute processing corresponding to whether or not the set values are the same across the settable status. Therefore, when a setting value to be used is set, a preferable situation can be generated for the setting result, and a setting operation for the setting value can be suitably performed.

  Feature S2. Based on the fact that the set value grasping means grasps that the set value before the settable situation and the set value set by the setting means are the same, the corresponding simultaneous processing is performed. Same-time means to be executed (in the twenty-second embodiment, a function of executing the process of step S5113 in the main CPU 63, and in another embodiment, a function of executing the process of step S5613 in the main CPU 63). The gaming machine according to Feature S1, characterized by:

  According to the feature S2, when the set values are the same across the settable situations, the same time process is executed, so that it is possible to generate a preferable situation for the same set values. Become.

  Feature S3. The gaming machine according to claim S2, wherein the same time means executes a process for making a notification corresponding to the fact that the set value has not been changed as the same time process.

  According to the feature S3, it is possible to notify the game hall manager or the like that the set values are the same across the settable situations.

  Feature S4. Based on the fact that the set value grasping means grasps that the set value before the settable state is different from the set value set by the setting means, the corresponding non-identical processing is executed. Non-same time means (function to execute step S5114 in main CPU63 in the twenty-second embodiment, function to execute step S5614 in main CPU63 in another embodiment) The gaming machine according to any one of features S1 to S3.

  According to the feature S4, when the set values are not the same across the settable situations, a non-identical process is executed, so that a preferable situation can be generated for the change of the set values. It becomes.

  Feature S5. The gaming machine according to claim S4, wherein the non-identical means executes a process for performing notification corresponding to the change of the set value as the non-identical process. .

  According to the feature S5, it is possible to notify the game hall manager or the like that the set value has been changed across the settable situation.

  Feature S6. The status generating means is configured to perform the setting based on the necessity of erasing the information in the storage means for storing the setting value after the supply of operating power to the control means having the setting means is started. The gaming machine according to any one of features S1 to S5, wherein the gaming machine is configured to be in a possible situation.

  According to the feature S6, when it becomes necessary to delete the information stored in the storage means for storing the setting value, the setting is possible, so that the game is continued even though the setting value information is deleted. It becomes possible not to be. In this case, the configuration of the feature S1 is provided, and it is grasped whether or not the set value before the settable situation and the set value set in the settable situation are the same. As a result, it is possible to execute processing corresponding to whether or not the set values are the same across the settable status.

  Feature S7. The set value is not changed based on the fact that the set value grasping means grasps that the set value before the settable situation and the set value set by the setting means are the same. A means (in the twenty-second embodiment, a function of executing the process of step S5113 in the main CPU 63; in another embodiment, a function of executing the process of step S5613 in the main CPU 63). The gaming machine according to Feature S6, wherein the gaming machine is provided.

  According to the feature S7, even if the setting is possible due to the deletion of the information in the storage unit, the setting value is changed if the setting value is the same across the setting possibility situation. A notification corresponding to the absence is made. This makes it possible to notify the player that the set value has not been changed even if the setting is possible during the game, and the player is safe even if the setting is possible during the game. It is possible to continue the game with heart.

Feature S8. The situation generating means is:
Based on the start of the supply of operating power to the control means having the setting means, the first situation generating means (step S5003 in the main CPU 63 in the twenty-second embodiment) that makes the setting possible situation. The function of executing the process of step S5006, in another form, the function of executing the process of step S5503 to step S5507 in the main CPU 63, and in the twenty-third embodiment, the process of steps S5703 to S5705 and step S5715 in the main CPU 63 are executed. Function)
A second situation in which the settable situation is established based on the necessity of erasing information stored in the storage means for storing the set value after the supply of operating power to the control means is started. Generating means (in the twenty-second embodiment, the function of executing steps S5401 to S5408 in the main CPU 63; in the twenty-fourth embodiment, the function of executing steps S5801 to S5804 in the main CPU 63; In the embodiment, the function of executing steps S5901 to S5904 in the main CPU 63),
With
The set value grasping means is configured to be able to set the settable situation generated by the first situation generating means and the settable situation caused by the second situation generating means before entering the settable situation. The gaming machine according to any one of features S1 to S7, characterized in that it is ascertained whether or not the setting value in the setting and the setting value set by the setting means are the same.

  According to the feature S8, when it becomes necessary to delete the information stored in the storage means for storing the setting value, the setting is possible, so that the game is continued even though the setting value information is deleted. It becomes possible not to be. In this case, using the same process as when setting is possible based on the start of supply of operating power to the control means, setting is possible as information in the storage means is erased. When this occurs, it is possible to execute processing corresponding to whether or not the set values are the same across the settable situation.

  In addition, with respect to the configuration of the features S1 to S8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature S group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, in a pachinko gaming machine, the front of the gaming machine is provided with a dish storage unit that stores game balls given to the player, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in a gaming machine such as the above-described example, when a setting value that determines the advantage of the gaming machine is set, it is necessary to cause a suitable situation to the setting value, and this point is still improved. There is room for.

<Feature T group>
Feature T1. A control unit (main CPU 63) that executes various processes and temporarily stores information in an internal storage unit (register of the main CPU 63) when the process is executed,
The control means is
A first predetermined process execution means for executing a first predetermined process among the various processes (a function for executing a process other than the management execution process in the main CPU 63 in the fifteenth to twenty-fifth embodiments);
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to twenty-fifth embodiments) for executing a second predetermined process among the various processes;
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined process is executed;
A second predetermined storage area (non-specific control work area 223, non-specific control stack area 224) in which information is stored when the second predetermined process is executed;
First monitoring execution means for monitoring whether or not the first predetermined storage area is normal (in the twenty-second embodiment, the function of executing steps S5401 to S5404 in the main CPU 63, in the twenty-fourth embodiment) A function of executing processing of steps S5801 to S5804 in the main CPU 63, a function of executing processing of steps S5901 to S5904 in the main CPU 63 in the twenty-fifth embodiment, and a step S7701 in the main CPU 63 in the thirty-second embodiment. To execute the process of step S7703),
Second monitoring execution means for monitoring whether or not the second predetermined storage area is normal (in the twenty-second embodiment, the function of executing steps S5405 to S5408 in the main CPU 63, in the twenty-fourth embodiment) A function of executing processing of steps S5809, S5810, S5812, and S5813 in the main CPU 63; a function of executing processing of steps S6101, S6102, S6105, and S6106 in the main CPU 63 in the twenty-fifth embodiment; In the thirty-second embodiment, the main CPU 63 executes a process of steps S7706 to S7708),
A gaming machine characterized by comprising:

  According to the feature T1, the first predetermined storage area and the second predetermined storage area are provided, the first predetermined storage area is handled as a dedicated storage area for the first predetermined process, and the second predetermined storage area is It is treated as a dedicated storage area for the second predetermined process. As a result, the storage destination of information in the predetermined storage unit can be clearly made different between the first predetermined process and the second predetermined process. Therefore, it is possible to prevent information used in the other process from being deleted when one of the first predetermined process and the second predetermined process is executed. Further, monitoring whether the first predetermined storage area is normal and monitoring whether the second predetermined storage area is normal are executed, whereby the first predetermined process and the second predetermined storage area are executed. It is possible to specify whether or not each of the processes can be normally performed.

  Feature T2. The game according to claim T1, wherein the monitoring by the first monitoring execution unit and the monitoring by the second monitoring execution unit are executed in one of the first predetermined process and the second predetermined process. Machine.

  According to the feature T2, monitoring whether the first predetermined storage area is normal and monitoring whether the second predetermined storage area are normal are performed in one of the first predetermined process and the second predetermined process. Aggregated and executed. As a result, the processing configuration can be simplified compared to a configuration in which monitoring of each storage area is performed in a distributed manner between the first predetermined process and the second predetermined process.

  Feature T3. The gaming machine according to claim T1 or T2, wherein the monitoring by the first monitoring execution unit and the monitoring by the second monitoring execution unit are executed in the first predetermined process.

  According to the feature T3, monitoring whether the first predetermined storage area is normal and monitoring whether the second predetermined storage area is normal can be collectively performed in the first predetermined process. It becomes.

  Feature T4. Based on the fact that the first monitoring execution means specifies that the first predetermined storage area is abnormal, predetermined erasing means for erasing information in the first predetermined storage area (in the twenty-second embodiment, the main side) The function of executing the process of step S5410 in the CPU 63, the function of executing the processes of step S5806, step S5811 and step S5814 in the main CPU 63 in the twenty-fourth embodiment, and the step S5906 of step S5906 in the main CPU 63 in the twenty-fifth embodiment. The gaming machine according to any one of features T1 to T3, which includes a function of executing the processing of S6103 and step S6107.

  According to the feature T4, when the first predetermined storage area is abnormal, the information in the first predetermined storage area is deleted, and the first predetermined process is executed while the first predetermined storage area is in an abnormal state. It is possible to prevent it from being lost.

  Feature T5. The predetermined erasing means erases information in the first predetermined storage area based on the fact that the first monitoring execution means specifies that the first predetermined storage area is abnormal, and the second predetermined storage area The gaming machine according to Feature T4, wherein the area information is erased.

  According to the feature T5, when the first predetermined storage area is abnormal, not only the first predetermined storage area but also the second predetermined storage area is erased. As a result, when there is a possibility that an abnormality has occurred in the second predetermined storage area, the information in the second predetermined storage area can be deleted regardless of the monitoring result by the second monitoring execution means.

  Feature T6. The predetermined erasing unit erases the information in the second predetermined storage area based on the fact that the second monitoring execution unit specifies that the second predetermined storage area is abnormal. A gaming machine according to T4 or T5.

  According to the feature T6, when the first predetermined storage area is abnormal, the information in the first predetermined storage area is deleted, so that the first predetermined process is executed while the first predetermined storage area is in an abnormal state. It is possible to prevent it from being lost.

  Feature T7. The predetermined erasing unit erases the information in the second predetermined storage area based on the fact that the second monitoring execution unit specifies that the second predetermined storage area is abnormal, and the first predetermined storage area The gaming machine according to Feature T6, wherein the area information is erased.

  According to the feature T7, when the second predetermined storage area is abnormal, not only the second predetermined storage area but also the first predetermined storage area is erased. As a result, when there is a possibility that an abnormality has occurred in the first predetermined storage area, the information in the first predetermined storage area can be erased regardless of the monitoring result by the first monitoring execution means.

  Feature T8. The process for erasing information by the predetermined erasing unit is executed in any one of the first predetermined process and the second predetermined process, according to any one of the characteristics T4 to T7, Game machines.

  According to the feature T8, the process of deleting the information in each predetermined storage area based on the fact that it is specified to be abnormal is collectively executed in one of the first predetermined process and the second predetermined process. As a result, the processing configuration can be simplified as compared with a configuration in which erasure of information in each storage area is performed in a distributed manner between the first predetermined processing and the second predetermined processing.

  Feature T9. The gaming machine according to any one of features T4 to T7, wherein the process for erasing information by the predetermined erasing unit is executed in the first predetermined process.

  According to the feature T9, it is possible to collectively execute the process of deleting the information in each predetermined storage area based on the fact that the abnormality is specified in the first predetermined process.

Feature T10. The first predetermined process includes a process for controlling the progress of the game,
The gaming machine according to any one of features T1 to T9, wherein the second predetermined process includes a process for managing a game history.

  According to the feature T10, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process, thereby controlling the progress of the game. Therefore, it is possible to prevent information used in the process for managing the game history from being rewritten when the process for executing the process is executed.

  Feature T11. The second predetermined storage area is a history storage area (normal counter area 231, opening / closing execution mode counter area 232) that stores game history information corresponding to a predetermined event that occurs when a game is executed. The gaming machine according to feature T10, comprising a high-frequency support mode counter area 233).

  According to the feature T11, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent information stored in the history storage area from being rewritten during execution.

  Feature T12. The second predetermined process execution means is information derivation means (step S4208 in the main CPU 63) for deriving mode information corresponding to the game result in a predetermined period using the history information stored in the history storage area. A game machine according to the feature T11, which is provided with a function of executing

  According to the feature T12, game history management such as occurrence frequency of a predetermined event is performed by deriving mode information corresponding to a game result in a predetermined period using the history information stored in the history storage area. It becomes possible to grasp the result.

  Feature T13. The gaming machine according to Feature T12, wherein the second predetermined storage area includes an aspect information storage area (calculation result storage area 234) for storing the aspect information derived by the information deriving means.

  According to the feature T13, when the aspect information corresponding to the game result in the predetermined period is derived using the history information, the aspect information is stored in the aspect information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

  In addition, with respect to the configuration of the features T1 to T13, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature U group>
Feature U1. A control unit (main CPU 63) that executes various processes and temporarily stores information in an internal storage unit (register of the main CPU 63) when the process is executed,
The control means is
A first predetermined process execution means (a function for executing processes other than the management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing the first predetermined process among the various processes;
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a second predetermined process among the various processes;
A flag register provided in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed State setting means (in the twenty-sixth embodiment, the function of executing steps S6202 to S6204 and step S6211 in the twenty-sixth embodiment, the step in the main CPU63 in the twenty-seventh embodiment). A function of executing the processes of S6302 to S6307 and S6312),
A gaming machine characterized by comprising:

  According to the characteristic U1, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed or the situation where the second predetermined process is executed, the flag register of the internal storage means The state is set to a specific state. Thus, the second predetermined process can be started in a situation where the state of the flag register is in a predetermined specific state. Therefore, various controls can be suitably performed.

  Feature U2. The gaming machine according to claim U1, wherein the specific state is a state when supply of operating power to the control means is started.

  According to the characteristic U2, the flag register is set to the state when the supply of the operating power to the control unit is started as the specific state, so that the processing configuration for setting the specific state can be simplified. It becomes possible.

  Feature U3. The gaming machine according to claim U1 or U2, wherein the specific state is a state in which the flag register is cleared to "0".

  According to the feature U3, since the flag register is set to a state in which “0” is cleared as the specific state, the processing configuration for setting the specific state can be simplified.

  Feature U4. Means (in the twenty-sixth embodiment, the processing of steps S6213 to S6218 in the main CPU 63 is performed so that the state of the flag register becomes the specific state when or after the second predetermined processing is ended. The gaming machine according to any one of features U1 to U3, which is provided with a function, in the twenty-seventh embodiment, a function of executing the processing of steps S6314 to S6322 in the main CPU 63.

  According to the characteristic U4, the second predetermined process is performed not only when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed. The flag register state is also set to a specific state when the process ends or when the process ends. Thus, the first predetermined process can be restarted in a situation where the state of the flag register is a predetermined specific state. In addition, the state of the flag register can be set to a specific state before and after the second predetermined process. Therefore, it is possible to prevent the flag register state of one of the first predetermined process and the second predetermined process from affecting the other process.

Feature U5. Provided with predetermined storage means (main-side RAM 65) for temporarily storing information when the control means executes processing;
The state setting means includes
Means for bringing the state of the predetermined storage area in the predetermined storage means into the specific state (in the twenty-sixth embodiment, the function of executing steps S6202 to S6204 in the main CPU 63, in the twenty-seventh embodiment A function of executing the processes of steps S6302 to S6307 in the main CPU 63);
Means for storing the information stored in the predetermined storage area in the flag register so that the state of the flag register becomes the specific state (in the twenty-sixth embodiment, the process of step S6211 in the main CPU 63 is performed). A function to be executed, in the twenty-seventh embodiment, a function of executing the process of step S6312 in the main CPU 63),
The gaming machine according to any one of features U1 to U4, comprising:

  According to the feature U5, even if the flag register state cannot be directly set to a specific state as an instruction of the control unit, the flag is written using the information writing to the predetermined storage unit and the reading of the information. It is possible to set the register state to a specific state.

Feature U6. The predetermined storage means is
A stack area (stack area 222 for specific control) in which the control means can write information by a push command and the control means can read information by a pop command;
A work area (work area 221 for specific control) in which the control means can write and read information by a load command;
With
The gaming machine according to Feature U5, wherein the predetermined storage area is provided in the stack area.

  According to the feature U6, even if the information stored in the work area cannot be directly written to the flag register, the state of the flag register is specified by using the information writing to the stack area and the reading of the information. It becomes possible to set the state.

Feature U7. A predetermined register provided in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed (A function for executing the processing of steps S6205 to S6210 in the main CPU 63 in the twenty-sixth embodiment, and steps S6308 to S6311 in the main CPU 63 in the twenty-seventh embodiment). Function to execute processing)
The state setting means makes the state of the flag register become the specific state after the state of the predetermined register is set to the predetermined state, according to any one of the characteristics U1 to U6, Gaming machine.

  The state of the flag register can change each time various processes are executed in the control means. In this case, according to the feature U7, since the state of the flag register is set to the specific state after the state of the predetermined register is set to the predetermined state, the flag register is set to the specific state immediately before the second predetermined process is started. It becomes possible to be.

Feature U8. A control unit (main CPU 63) that executes various processes and temporarily stores information in an internal storage unit (register of the main CPU 63) when the process is executed,
The control means is a means for setting the state of the flag register to a specific state (in the twenty-sixth embodiment, the function of executing steps S6202 to S6204 and step S6211 in the main CPU 63, the twenty-seventh embodiment). Then, the gaming machine is provided with a function of executing the processing of steps S6302 to S6307 and S6312 in the main CPU63.

  According to the feature U8, the state of the flag register can be set to a specific state as necessary.

  In addition, with respect to the configuration of the features U1 to U8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature V group>
Feature V1. A control unit (main CPU 63) that executes various processes and temporarily stores information in an internal storage unit (register of the main CPU 63) when the process is executed,
The control means is
A first predetermined process execution means (a function for executing processes other than the management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing the first predetermined process among the various processes;
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a second predetermined process among the various processes;
A flag register provided in the internal storage means when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed Is stored in predetermined storage means (main RAM 65) (in the fifteenth embodiment, the function of executing step S3802 in the main CPU 63; in the sixteenth embodiment, in step S4402 in the main CPU 63). A function for executing processing, a function for executing processing in step S4802 in the main CPU 63 in the twentieth embodiment, a function for executing processing in steps S6402 to S6405 in the main CPU 63 in the twenty-eighth embodiment, In the embodiment, the processing of steps S6502 to S6509 in the main CPU 63 is performed. And the execution function),
Return execution means for returning the flag register information saved in the predetermined storage means to the flag register when the second predetermined process is ended or after the completion (in step S3804 in the main CPU 63 in the fifteenth embodiment). In the sixteenth embodiment, the function of executing the process of step S4404 in the main CPU 63, the function of executing the process of step S4810 in the main CPU 63 in the twentieth embodiment, and the twenty-eighth embodiment. In the 29th embodiment, the function of executing steps S6511 to S6518 in the main CPU 63), and the function of executing steps S6511 to S6518 in the main CPU 63),
A gaming machine characterized by comprising:

  According to the feature V1, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed, or when the situation where the second predetermined process is executed, the information in the flag register is stored in advance. Evacuated to the means. Thereby, when the second predetermined process is executed, it is possible to prevent the information stored in the flag register from being rewritten when the first predetermined process is executed. In addition, when the second predetermined process is ended or after the end, the information saved in the predetermined storage unit is returned to the flag register. Thereby, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the flag register before the execution of the second predetermined process. As described above, various controls can be suitably performed.

Feature V2. The predetermined storage means is
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined process is executed;
A second predetermined storage area (non-specific control work area 223, non-specific control stack area 224) in which information is stored when the second predetermined process is executed;
With
The game machine according to claim V1, wherein the save execution means saves information in the flag register to the first predetermined storage area.

  According to the feature V2, the first predetermined storage area and the second predetermined storage area are provided in the predetermined storage unit, so that the storage destination of the information in the predetermined storage unit is determined by the first predetermined process and the second predetermined process. It is possible to make a distinct difference. Thereby, it is possible to prevent information used in the other process from being deleted when one of the first predetermined process and the second predetermined process is executed. In this case, the information in the flag register is stored in the first predetermined storage area when the second predetermined process is executed from the situation where the first predetermined process is executed or when the second predetermined process is executed. Is evacuated. As a result, it is possible to save the information in the flag register immediately before the start of the second predetermined process, and it is possible to save the information without using the second predetermined storage area.

Feature V3. The first predetermined storage area can store information and read information when the first predetermined process is executed, and can read information when the second predetermined process is executed. Information cannot be stored,
The second predetermined storage area can store information and read information when the second predetermined process is executed, and can read information when the first predetermined process is executed. The gaming machine according to Feature V2, wherein information cannot be stored.

  According to the feature V3, the first predetermined storage area can be handled as a dedicated storage area for the first predetermined process, and the second predetermined storage area can be handled as a dedicated storage area for the second predetermined process. It becomes.

Feature V4. The predetermined storage means is
A stack area (a stack area 222 for specific control) in which information can be written by a push instruction and information can be read by a pop instruction;
A work area in which information can be written and read by a load instruction (a work area 221 for specific control);
With
The game machine according to any one of features V1 to V3, wherein the save execution means saves the information in the flag register to one of the stack area and the work area.

  According to the feature V4, when the situation where the second predetermined process is executed from the situation where the first predetermined process is executed, or when the situation where the second predetermined process is executed, the stack area in the second predetermined storage area The information in the flag register is saved in one of the work areas. As a result, it is possible to consolidate information saving destinations, and it is possible to simplify the processing configuration for saving and the processing configuration for returning.

  Feature V5. The gaming machine according to claim V4, wherein the save execution means saves the information in the flag register to the work area.

  According to the feature V5, since the save destination of the information in the flag register is the work area, the information can be saved without performing a cumulative change of the stack pointer.

Feature V6. The save execution means includes
Means for storing information of the flag register in a predetermined register provided in the internal storage means (in the twenty-eighth embodiment, the function of executing steps S6402 and S6403 in the main CPU 63, in the twenty-ninth embodiment the main register The function of executing the processing of steps S6502 to S6505 in the side CPU 63),
Means for storing the information of the flag register stored in the predetermined register in the predetermined storage means (the function of executing step S6404 in the main CPU 63 in the twenty-eighth embodiment, the main CPU 63 in the twenty-ninth embodiment) In step S6506).
A gaming machine according to any one of features V1 to V5, characterized by comprising:

  According to the feature V6, even in a configuration in which the information in the flag register cannot be directly saved in the predetermined storage unit as an instruction of the control unit, the information is written into the predetermined register and the information stored in the predetermined register is The information in the flag register can be saved in the predetermined storage means by using writing to the storage means.

  In addition, with respect to the configuration of the features V1 to V6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature W group>
Feature W1. A control means (main CPU 63) for executing various processes is provided,
The control means is
A first predetermined process execution means (a function for executing processes other than the management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing the first predetermined process among the various processes;
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a second predetermined process among the various processes;
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined process is executed;
A second predetermined storage area (non-specific control work area 223, non-specific control stack area 224) in which information is stored when the second predetermined process is executed;
An abnormal event monitoring means (program monitoring unit 252) for monitoring whether or not an abnormal event has occurred;
Based on the fact that the abnormal event has been identified by the abnormal event monitoring means, it is possible to cause a situation in which information erasure processing is executed at least for the first predetermined storage area Erasing status generating means (reset signal output unit 251) to perform,
A gaming machine characterized by comprising:

  According to the feature W1, the first predetermined storage area and the second predetermined storage area are provided, the first predetermined storage area is handled as a dedicated storage area for the first predetermined process, and the second predetermined storage area is It is treated as a dedicated storage area for the second predetermined process. As a result, the storage destination of information in the predetermined storage unit can be clearly made different between the first predetermined process and the second predetermined process. Therefore, it is possible to prevent information used in the other process from being deleted when one of the first predetermined process and the second predetermined process is executed. In addition, based on the fact that an abnormal event has occurred, information erasure processing is executed on at least the first predetermined storage area. Thereby, it is possible to prevent the first predetermined process from being executed in a state where the information in the first predetermined storage area is held as it is even though an abnormal event has occurred.

Feature W2. The control means includes
Means for executing processing for storing power failure response information when the supply of operating power to the control means is stopped (in the thirty embodiment, the function of executing steps S6709 and S6710 in the main CPU 63) In the thirty-second embodiment, the function of executing steps S7609 to S7611 in the main CPU 63),
When supply of operating power to the control means is started and processing at the start of supply is performed in a situation where the power failure response information is not stored, the information erasing process is performed at least on the first predetermined storage area (In the thirty-third embodiment, the function of executing step S6607 in the main CPU 63, in the thirty-first embodiment, the function of executing clear processing in the main CPU 63, and the thirty-second function. In the embodiment, the function of executing the processing of step S7704, step S7705, step S7808 and step S7810 in the main CPU 63),
With
The erasure status generating means starts the supply by the control means in a situation where the power failure response information is not stored based on the fact that the abnormal event has been identified by the abnormal event monitoring means. The gaming machine according to Feature W1, wherein a time process is executed.

  According to the feature W2, when supply of operating power to the control unit is started and processing at the start of supply is executed in a situation where no power failure response information is stored, the information erasing process is at least a first predetermined process. By being executed on the storage area, the information in the first predetermined storage area is retained as it is when supply of operating power to the control means is started in a situation where the processing at the time of power failure is not properly performed. It is possible to prevent the first predetermined process from being executed in the state. In this case, based on the fact that an abnormal event has occurred, the control means executes processing at the start of supply in a situation where no power failure response information is stored. As a result, when the process at the start of supply is executed by the control means in a situation where the power failure response information is not stored, the information is deleted when the abnormal event occurs. It is possible to execute the erasing process.

Feature W3. The control means executes various processes when a reset signal is received, and receives the reset signal from a situation where the reset signal is not received in a situation where operating power is supplied. The process at the start of the supply is started based on the situation being
Based on the fact that the abnormal event has been identified by the abnormal event monitoring means, the erasure status generating means sets the control means to a state in which the reset signal is not received by the control means. The game machine according to Feature W2, wherein the game apparatus is in a state of receiving the reset signal.

  According to the feature W3, the above-described excellent effect can be obtained by switching the reception state of the reset signal.

Feature W4. The control means is configured to temporarily store information in an internal storage means (a register and a program counter of the main CPU 63) during execution of processing, and the information stored in the internal storage means is the first predetermined storage. It is a configuration that can be temporarily evacuated to the area,
The abnormal event monitoring means monitors whether an abnormality has occurred in the information stored in the internal storage means as the abnormal event,
Any one of the characteristics W1 to W3, wherein the erasure status generating means generates a situation in which the erasing process of the information is executed at least for both the first predetermined storage area and the internal storage means. The gaming machine described in 1.

  According to the feature W4, since the information stored in the internal storage means can be temporarily saved in the first predetermined storage area, when an abnormality occurs with respect to the information stored in the internal storage means, 1 There is a possibility that an abnormality has occurred in the information stored in the predetermined storage area. In this case, when an abnormality has occurred with respect to the information stored in the internal storage means, information erasure processing is executed not only on the internal storage means but also on the first predetermined storage area. Thereby, it is possible to prevent the first predetermined process from being executed as it is even though an abnormality has occurred with respect to the information stored in the first predetermined storage area.

  Feature W5. The erasure status generation means prevents the information erasure process from being executed on the second predetermined storage area even if the abnormal event monitoring means specifies that the abnormal event has occurred. The gaming machine according to any one of features W1 to W4, characterized by:

  According to the feature W5, even if an abnormal event occurs, information can be stored and held in the second predetermined storage area.

  Feature W6. The erasing status generating means is configured to perform the erasing processing of the information in the first predetermined storage area and the second predetermined storage area based on the fact that the abnormal event is specified by the abnormal event monitoring means. The game machine according to any one of features W1 to W4, characterized in that a situation that is executed for both of the two is generated.

  According to the feature W6, based on the fact that an abnormal event has been identified, the information erasing process is executed for both the first predetermined storage area and the second predetermined storage area. As a result, it is possible to prevent the first predetermined process from being executed while the information in the first predetermined storage area is held as it is even though an abnormal event has occurred, and an abnormal event has occurred. In spite of this, it is possible to prevent the second predetermined process from being executed while the information in the second predetermined storage area is maintained as it is.

  Feature W7. The information erasing process for the first predetermined storage area is executed in the first predetermined process, and the information erasing process for the second predetermined storage area is executed in the second predetermined process. The gaming machine according to feature W6.

  According to the feature W7, also in the information erasing process, the first predetermined storage area is treated as a dedicated storage area for the first predetermined process, and the second predetermined storage area is treated as a dedicated storage area for the second predetermined process. It is possible to make it appear.

Feature W8. The first predetermined process includes a process for controlling the progress of the game,
The gaming machine according to any one of features W1 to W7, wherein the second predetermined process includes a process for managing a game history.

  According to the feature W8, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process, thereby controlling the progress of the game. Therefore, it is possible to prevent information used in the process for managing the game history from being rewritten when the process for executing the process is executed.

  Feature W9. The second predetermined storage area is a history storage area (normal counter area 231, opening / closing execution mode counter area 232) that stores game history information corresponding to a predetermined event that occurs when a game is executed. The gaming machine according to Feature W8, comprising a high-frequency support mode counter area 233).

  According to the feature W9, when a predetermined event occurs, corresponding history information is stored in the history storage area. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent information stored in the history storage area from being rewritten during execution.

  Feature W10. The second predetermined process execution means is information derivation means (step S4208 in the main CPU 63) for deriving mode information corresponding to the game result in a predetermined period using the history information stored in the history storage area. The game machine according to Feature W9, further comprising:

  According to the feature W10, game history management such as occurrence frequency of a predetermined event is performed by deriving mode information corresponding to a game result in a predetermined period using the history information stored in the history storage area. It becomes possible to grasp the result.

  Feature W11. The game machine according to Feature W10, wherein the second predetermined storage area includes an aspect information storage area (calculation result storage area 234) for storing the aspect information derived by the information deriving means.

  According to the feature W11, when aspect information corresponding to a game result in a predetermined period is derived using the history information, the aspect information is stored in the aspect information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

  In addition, with respect to the configuration of the features W1 to W11, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature X group>
Feature X1. A control means (main CPU 63) for executing various processes is provided,
The control means is
A first predetermined process execution means (a function for executing processes other than the management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing the first predetermined process among the various processes;
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a second predetermined process among the various processes;
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined process is executed;
A second predetermined storage area (non-specific control work area 223, non-specific control stack area 224) in which information is stored when the second predetermined process is executed;
With
The second predetermined process execution means is an erase execution means for executing an information erasure process on the second predetermined storage area as the second predetermined process based on the occurrence of an erasure trigger ( In the twenty-fifth embodiment, the function of executing steps S6103 and S6107 in the main CPU 63, in the thirty embodiment, the function of executing steps S7204 in the main CPU 63, and in the thirty-first embodiment, the main CPU 63. A game machine having a function of executing the process of step S7508 in FIG. 32, a function of executing the processes of step S7808 and step S7810 in the main CPU 63 in the thirty-second embodiment.

  According to the feature X1, the first predetermined storage area and the second predetermined storage area are provided, the first predetermined storage area is handled as a dedicated storage area for the first predetermined process, and the second predetermined storage area is It is treated as a dedicated storage area for the second predetermined process. As a result, the storage destination of information in the predetermined storage unit can be clearly made different between the first predetermined process and the second predetermined process. Therefore, it is possible to prevent information used in the other process from being deleted when one of the first predetermined process and the second predetermined process is executed.

  In addition, when an erasure trigger occurs, an information erasure process is executed on the second predetermined storage area, so that the second predetermined storage area is in spite of some abnormality occurring in the second predetermined storage area. It is possible to prevent the second predetermined process from being executed in a state where the information is held as it is. In addition, since the information erasing process is executed in the second predetermined process, it is possible to prevent the first predetermined process from being involved in updating the information in the second predetermined storage area.

  Feature X2. The erasing execution means executes the erasing process of the information on the second predetermined storage area while preventing the non-erasing target information (management monitoring flag, return address information, various register information) from being erased. The gaming machine according to Feature X1, which is characterized.

  According to the feature X2, the information erasure process for the second predetermined storage area is performed while preventing the non-erasure target information in the second predetermined storage area from being erased. Thereby, it is possible to execute the information erasing process on the second predetermined storage area while preventing even necessary information from being erased.

Feature X3. The second predetermined process execution means is configured to execute the second predetermined process from the situation in which the first predetermined process is executed or the situation in which the second predetermined process is executed. Storage execution means (in the thirty-third embodiment) for storing return correspondence information (return address information, various register information) necessary for returning to a state in which the first predetermined process is executed in the second predetermined storage area A function for executing the processes of steps S7102 to S7107 in the main CPU 63, a function for executing the processes of steps S7502 to S7507 in the main CPU 63 in the thirty-first embodiment, and a step S7802 in the main CPU 63 in the thirty-second embodiment. ~ Function of executing the process of step S7807),
The game according to claim X2, wherein the erasure executing means executes the information erasure process on the second predetermined storage area while preventing the return correspondence information from being erased as the non-erasure target information. Machine.

  According to the feature X3, the second predetermined process is performed while preventing even the return correspondence information necessary for returning from the situation in which the second predetermined process is being executed to the situation in which the first predetermined process is being executed. It is possible to execute information erasure processing on the storage area.

  Feature X4. The storage execution unit stores, as the return correspondence information, information on a return address of a program when the second predetermined process is ended and the first predetermined process is returned to the second predetermined storage area. The gaming machine according to feature X3.

  According to the feature X4, since the information erasure process is performed on the second predetermined storage area while preventing the return address information of the program when returning to the first predetermined process from being erased, the second predetermined storage area Even if the information erasing process is executed, it is possible to return to the predetermined program in the first predetermined process when the second predetermined process is completed.

Feature X5. The control means is configured to temporarily store information in an internal storage means (register of the main CPU 63) at the time of execution of processing,
The gaming machine according to the feature X3 or X4, wherein the storage execution unit stores information stored in the internal storage unit in the second predetermined storage area as the return correspondence information.

  According to the feature X5, the information erasing process is executed on the second predetermined storage area while preventing the information of the internal storage means used in the first predetermined process from being deleted. On the other hand, even if the information erasing process is executed, the information used in the first predetermined process can be returned to the internal storage means when the second predetermined process is completed.

  Feature X6. The erasing execution means causes the erasing process of the information to be executed on the second predetermined storage area as the occurrence of the erasing trigger based on the occurrence of an abnormality in the second predetermined storage area. The gaming machine according to any one of features X1 to X5.

  According to the feature X6, since the information erasing process is executed for the second predetermined storage area based on the occurrence of the abnormality in the second predetermined storage area, the abnormality occurs in the second predetermined storage area. It is possible to prevent the second predetermined process from being executed in the state where it is present.

  Feature X7. The second predetermined process execution means is means for monitoring whether the second predetermined storage area is normal as the second predetermined process (in the thirtieth embodiment, in steps S7201 to S7203 in the main CPU 63). A gaming machine according to Feature X6, further comprising a function for executing processing.

  According to the feature X7, not only the information erasing process for the second predetermined storage area but also the monitoring of whether the second predetermined storage area is normal can be performed in the second predetermined process without interposing the first predetermined process. Therefore, it is possible to execute monitoring of whether or not the second predetermined storage area is normal and execution of information erasure processing for the second predetermined storage area as a series of processes in the second predetermined process. .

Feature X8. The first predetermined process includes a process for controlling the progress of the game,
The gaming machine according to any one of features X1 to X7, wherein the second predetermined process includes a process for managing a game history.

  According to the feature X8, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process, thereby controlling the progress of the game. Therefore, it is possible to prevent information used in the process for managing the game history from being rewritten when the process for executing the process is executed.

  Feature X9. The second predetermined storage area is a history storage area (normal counter area 231, opening / closing execution mode counter area 232) that stores game history information corresponding to a predetermined event that occurs when a game is executed. The gaming machine according to Feature X8, comprising a high-frequency support mode counter area 233).

  According to the feature X9, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent information stored in the history storage area from being rewritten during execution.

  Feature X10. The second predetermined process execution means is information derivation means (step S4208 in the main CPU 63) for deriving mode information corresponding to the game result in a predetermined period using the history information stored in the history storage area. (8) The gaming machine according to feature X9.

  According to the feature X10, game history management such as occurrence frequency of a predetermined event is performed by deriving mode information corresponding to a game result in a predetermined period using the history information stored in the history storage area. It becomes possible to grasp the result.

  Feature X11. The gaming machine according to Feature X10, wherein the second predetermined storage area includes an aspect information storage area (calculation result storage area 234) for storing the aspect information derived by the information deriving means.

  According to the feature X11, when aspect information corresponding to a game result in a predetermined period is derived using history information, the aspect information is stored in the aspect information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

  In addition, with respect to the configuration of the features X1 to X11, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature Y group>
Feature Y1. A control means (main CPU 63) for executing various processes is provided,
The control means is
A first predetermined process execution means (a function for executing processes other than the management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing the first predetermined process among the various processes;
A second predetermined process execution means (a function for executing a management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a second predetermined process among the various processes;
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined process is executed;
A second predetermined storage area (non-specific control work area 223, non-specific control stack area 224) in which information is stored when the second predetermined process is executed;
First calculation means for calculating first reference numerical value information corresponding to a plurality of pieces of information stored in the first predetermined storage area (in the thirty embodiment, the processes of steps S6604 and S6710 in the main CPU 63 are executed. A function for executing processing of step S7304 in the main CPU 63 in the thirty-first embodiment, a function for executing processing of steps S7610 and S7701 in the main CPU 63 in the thirty-second embodiment), and
A gaming machine characterized by comprising:

  According to the characteristic Y1, the first predetermined storage area and the second predetermined storage area are provided, the first predetermined storage area is handled as a dedicated storage area for the first predetermined process, and the second predetermined storage area is It is treated as a dedicated storage area for the second predetermined process. As a result, the storage destination of information in the predetermined storage unit can be clearly made different between the first predetermined process and the second predetermined process. Therefore, it is possible to prevent information used in the other process from being deleted when one of the first predetermined process and the second predetermined process is executed. In this case, first reference numerical information corresponding to a plurality of pieces of information stored in the first predetermined storage area is calculated. By using the first reference numerical information, it is possible to specify whether or not an information abnormality has occurred only in the first predetermined storage area.

  Feature Y2. Information erasure means for causing information erasure processing to be executed for the first predetermined storage area based on the fact that an abnormality has occurred with respect to the first reference numerical information calculated by the first calculation means (In the thirty-third embodiment, the function of executing the processing of step S6607 in the main CPU 63, in the thirty-first embodiment, the function of executing steps S7401 and S7402 in the main CPU 63, and in the thirty-second embodiment, the main side The gaming machine according to feature Y1, further comprising a function of executing the processing of step S7704 and step S7705 in CPU63.

  According to the feature Y2, when the occurrence of an abnormality is specified for the first reference numerical information, the information erasing process is executed on the first predetermined storage area, so that the information abnormality has occurred. Therefore, it is possible to prevent the first predetermined process from being executed in a state where the information in the first predetermined storage area is held as it is.

Feature Y3. The first calculation means includes
First power failure time calculating means for calculating the first reference numerical information when supply of operating power to the control means is stopped (in the thirty embodiment, the function of executing the process of step S6710 in the main CPU 63, In the thirty-second embodiment, the function of executing the process of step S7610 in the main CPU 63),
First power-on time calculating means for calculating the first reference numerical information when supply of operating power to the control means is started (in the thirty embodiment, the function of executing step S6604 in the main CPU 63) In the thirty-first embodiment, a function of executing the process of step S7304 in the main CPU 63, and in the thirty-second embodiment, a function of executing the process of step S7701 in the main CPU 63),
With
The information erasing means is based on the fact that the first reference numerical value information calculated by the first power failure time calculating means does not match the first reference numerical value information calculated by the first power-on time calculating means. The gaming machine according to claim Y2, wherein the information erasing process is executed at least on the first predetermined storage area.

  According to the feature Y3, it is possible to specify whether or not the information of the first predetermined storage area is stored and held across the situation where the supply of operating power is stopped by calculating the first reference numerical information It becomes. If the information in the first predetermined storage area is not stored and held across the situation where the supply of operating power is stopped, the information erasure process is performed on the first predetermined storage area, so that an information abnormality It is possible to prevent the first predetermined process from being executed in a state where the information in the first predetermined storage area is retained as it is despite the occurrence of the error.

  Feature Y4. The information erasing unit does not execute the information erasing process on the second predetermined storage area even if the occurrence of an abnormality is specified for the first reference numerical information calculated by the first calculating unit. The gaming machine according to the feature Y2 or Y3.

  According to the feature Y4, when the occurrence of an abnormality is specified for the first reference numerical information, the information erasure process is performed on the first predetermined storage area, while the information erasure is performed on the second predetermined storage area. Processing is not executed. As a result, even information in the first predetermined storage area can be prevented from being erased even in the situation where the information abnormality occurs in the first predetermined storage area.

  Feature Y5. The gaming machine according to any one of features Y1 to Y4, wherein the first reference numerical value information is information that does not vary according to information stored in the second predetermined storage area.

  According to the feature Y5, in the configuration in which the first predetermined storage area and the second predetermined storage area exist, it is possible to individually specify information abnormality regarding the first predetermined storage area using the first reference numerical information. It becomes possible.

  Feature Y6. Second calculation means for calculating second reference numerical information corresponding to a plurality of pieces of information stored in the second predetermined storage area (function to execute the processes of steps S7611 and S7706 in the main CPU 63) is provided. The gaming machine according to any one of features Y1 to Y5.

  According to the feature Y6, second reference numerical value information corresponding to a plurality of pieces of information stored in the second predetermined storage area is calculated. By using the second reference numerical information, it is possible to specify whether or not an information abnormality has occurred only in the second predetermined storage area.

  Feature Y7. Means for causing an information erasure process to be executed on at least the second predetermined storage area based on the fact that an abnormality has occurred with respect to the second reference numerical information calculated by the second calculation means; The gaming machine according to feature Y6, further comprising a function of executing processing of steps S7808 and S7810 in the main CPU 63).

  According to the feature Y7, when the occurrence of an abnormality is specified for the second reference numerical information, the information erasing process is executed on the second predetermined storage area, so that the information abnormality has occurred. Therefore, it is possible to prevent the second predetermined process from being executed in a state where the information in the second predetermined storage area is held as it is.

Feature Y8. The first predetermined process includes a process for controlling the progress of the game,
The gaming machine according to any one of features Y1 to Y7, wherein the second predetermined process includes a process for managing a game history.

  According to the feature Y8, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process, thereby controlling the progress of the game. Therefore, it is possible to prevent information used in the process for managing the game history from being rewritten when the process for executing the process is executed.

  Feature Y9. The second predetermined storage area is a history storage area (normal counter area 231, opening / closing execution mode counter area 232) that stores game history information corresponding to a predetermined event that occurs when a game is executed. The gaming machine according to feature Y8, comprising a high-frequency support mode counter area 233).

  According to the feature Y9, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. In addition, since the history information is stored by the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent information stored in the history storage area from being rewritten during execution.

  Feature Y10. The second predetermined process execution means is information derivation means (step S4208 in the main CPU 63) for deriving mode information corresponding to the game result in a predetermined period using the history information stored in the history storage area. (8) The gaming machine according to feature Y9.

  According to the feature Y10, game history management such as occurrence frequency of a predetermined event is performed by deriving mode information corresponding to a game result in a predetermined period using the history information stored in the history storage area. It becomes possible to grasp the result.

  Feature Y11. The gaming machine according to feature Y10, wherein the second predetermined storage area includes an aspect information storage area (calculation result storage area 234) for storing the aspect information derived by the information deriving means.

  According to the feature Y11, when the aspect information corresponding to the game result in the predetermined period is derived using the history information, the aspect information is stored in the aspect information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. In addition, a process for controlling the progress of the game is executed as a first predetermined process, and a process for managing the game history is executed as the second predetermined process. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

  In addition, with respect to the configuration of the features Y1 to Y11, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature T group, the feature U group, the feature V group, the feature W group, the feature X group, and the feature Y group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, a pachinko gaming machine has a dish storage unit that stores game balls given to a player on the front side of the gaming machine, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in the gaming machine such as the above example, it is necessary to suitably perform various controls, and there is still room for improvement in this respect.

<Characteristic Z group>
Feature Z1. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
Situation generating means (a function for executing the processing of step S7905, step S7916 and step S7917 in the main CPU 63) so as to be a settable situation in which the setting value to be used can be set by the setting means. When,
In the situation where the supply of operating power to the control means (main CPU 63) having the setting means is started and the process at the start of the supply is executed, the setting value of the target to be used in the situation that is not the settable situation A setting notification means (a function for executing a setting confirmation process in the main CPU 63) for performing notification;
A gaming machine characterized by comprising:

  According to the feature Z1, since a setting value to be used is set from a plurality of setting values corresponding to the player's degree of advantage, the player has a more advantageous setting value to be used. You will expect that. In this case, in order to confirm the set value set as the target of use, it is necessary to temporarily stop the supply of the operating power to the control means and then restart the supply of the operating power to the control means. . As a result, it is possible to make it difficult to perform an act of illegally checking the set value. In addition, since the set value is notified in a situation where the process at the start of supply is being performed, it is not necessary to notify the set value in a situation where the game is interrupted. Therefore, it is possible to suitably notify the set value.

  Feature Z2. The game machine according to claim Z1, wherein the situation generating means is configured to be in the settable situation in a situation where the process at the start of supply is being executed.

  According to the feature Z2, the setting possible situation in which the setting value to be used can be set, and the situation in which the setting value of the usage target is notified in a situation that is not the setting possible situation, It is possible to concentrate on the situation where processing is being executed.

Feature Z3. A first specifying means for specifying the occurrence of the first trigger event (function to execute the processing of step S7912 and step S7916 in the main CPU 63);
The setting notification means can be set based on a situation in which the process at the start of supply is being executed and the occurrence of the first trigger event is specified by the first specifying means. The gaming machine according to the feature Z1 or Z2, wherein the setting value of the use target in a situation other than a situation is notified.

  According to the feature Z3, in order to notify the set value to be used, it is necessary not only to start supplying operating power to the control means but also to generate a first trigger event. As a result, it is possible to make it difficult to perform an act of illegally checking the set value.

  Feature Z4. The gaming machine according to Feature Z3, wherein the first trigger event is that a predetermined operation with a setting key is performed on a setting key insertion unit (setting key insertion unit 68a).

  According to the feature Z4, in order to notify the setting of the usage target, it is necessary to perform a predetermined operation with the setting key on the setting key insertion unit. As a result, it is possible to make it difficult to perform an act of illegally checking the set value.

Feature Z5. The setting notification means is in a state where the process at the start of the supply is being executed, and the notification condition is established based on the situation where the occurrence of the first trigger event is specified by the first specifying means. In such a case, the setting value of the target to be used is notified in a situation that is not the configurable situation,
The situation generating means is in a situation where the process at the start of supply is being executed, and the setting condition is established based on the situation where the occurrence of the first trigger event is specified by the first specifying means If so, make sure that the setting is possible,
The gaming machine according to Feature Z3 or Z4, wherein the notification condition and the setting condition are different.

  According to the feature Z5, the first trigger event is not only started to supply the operating power to the control means, either in the case where the settable situation is generated or in the case where the set value to be used is notified. Need to be generated. As a result, it is possible to make it difficult to perform both the act of setting the set value to be used due to fraud and the act of attempting to confirm the set value to be used due to fraud. On the other hand, the setting condition for generating the settable situation is different from the notification condition for informing the setting value of the use target, and therefore the settable situation and the setting value of the use target are notified. Any one of the above can be generated alone.

Feature Z6. Provided with a second specifying means for specifying the occurrence of the second trigger event (function to execute the process of step S7905 in the main CPU 63);
The setting condition is a situation in which occurrence of the first trigger event is specified by the first specifying means in a situation where the process at the start of supply is being executed, and the second specifying means sets the second It is established based on the situation where the occurrence of the trigger event is specified,
The notification condition is a situation in which occurrence of the first trigger event is specified by the first specifying means in a situation where processing at the start of supply is being executed, and the second specifying means determines the second The gaming machine according to Feature Z5, which is established based on a situation in which an occurrence of a trigger event is not specified.

  According to the feature Z6, in order to generate a settable situation, it is necessary to start the supply of operating power to the control means and to generate not only the first trigger event but also the second trigger event. Thereby, not only the setting of the setting value to be used is performed but also the case where the setting value to be used is notified, not only the operation power supply to the control means is started. In the configuration in which the first trigger event needs to be generated, the operation for generating the settable situation can be made more complicated. Therefore, it is possible to prevent the act of trying to set the setting value to be used illegally more intensively.

  Feature Z7. The gaming machine according to Feature Z6, wherein the second trigger event is that a predetermined operation means (reset button 68c) is operated.

  According to the feature Z7, in order to generate a settable situation, it is necessary to start the supply of operating power to the control unit and to operate the predetermined operation unit in addition to generating the first trigger event. As a result, it is difficult to perform an act of trying to set a setting value to be used illegally, but the operation for properly generating the settable situation is prevented from becoming excessively complicated. It becomes possible.

  Feature Z8. An information erasure unit for executing an information erasure process based on the fact that the occurrence of the second trigger event is identified by the second identification unit in the situation where the process at the start of supply is performed A gaming machine according to the feature Z6 or Z7, which is provided with a function of executing the process of step S7915 in the main CPU 63.

  According to the feature Z8, the condition for generating the settable situation using the second trigger event necessary for executing the information erasing process, and the setting value of the target to be used in the situation that is not the settable situation It becomes possible to make it different from the conditions for making the notification.

  Feature Z9. The game machine according to claim Z8, wherein the information erasure unit executes the information erasure process even when the settable situation occurs.

  According to the feature Z9, it is possible to execute the information erasing process when the setting is possible.

  Feature Z10. In the situation where the process at the start of supply is being executed, the occurrence of the second trigger event is specified by the second specifying means, and the occurrence of the first trigger event is specified by the first specifying means The gaming machine according to the feature Z8 or Z9, wherein if the situation is not performed, the information erasing process is executed by the information erasing means although the setting is not possible.

  According to the feature Z10, when the supply of operating power to the control means is started, depending on whether or not the first trigger event is generated, the information erasing process is executed and the setting is possible. It is possible to select the case where the erasure process is executed but the setting is not possible.

  In addition, with respect to the configuration of the features Z1 to Z10, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature a group>
Feature a1. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
Situation generating means (a function for executing the processing of step S7905, step S7916 and step S7917 in the main CPU 63) so as to be a settable situation in which the setting value to be used can be set by the setting means. When,
An information erasure unit (a function of executing the process of step S7915 in the main CPU 63) for executing an information erasure process;
A setting notification means (a function for executing a setting confirmation process in the main CPU 63) that performs notification of the setting value of the use target in a situation that is not the settable situation;
First specifying means for specifying the occurrence of the first trigger event (function for executing the processes of steps S7912 and S7916 in the main CPU 63);
Second specifying means for specifying the occurrence of the second trigger event (function for executing the processing of step S7905 in the main CPU 63);
With
The status generating means specifies the occurrence of the first trigger event by the first specifying means in a situation in which supply of operating power to the control means having the setting means is started and processing at the start of supply is being executed. Based on the situation where the occurrence of the second trigger event is specified by the second specifying means, so as to be the settable situation,
The information erasing unit is configured to erase the information based on a situation in which the second specifying unit has identified the occurrence of the second trigger event in the situation where the process at the start of supply is being performed. Run
In the situation where the process at the start of supply is being executed, the occurrence of the second trigger event is specified by the second specifying means, and the occurrence of the first trigger event is specified by the first specifying means If the situation is not done, the information erasure process by the information erasure means is executed, although it does not become the settable situation,
The setting notification means is a situation in which the occurrence of the first trigger event is specified by the first specifying means in a situation where the process at the start of supply is being executed, and the second specifying means performs the second A gaming machine, characterized in that, based on a situation in which an occurrence of a trigger event is not specified, the setting value of the use target in a situation that is not the configurable situation is notified.

  According to the feature a1, since a setting value to be used is set from among a plurality of setting values corresponding to the player's advantage, a more advantageous setting value is used by the player. You will expect that. Further, since the information can be erased, it is possible to prevent a game from being played even though an information abnormality has occurred. In addition, since the setting value set as the use target can be notified, the setting value can be confirmed.

  In this case, in order to confirm the set value set as the target of use, it is necessary to start the supply of operating power to the control means and generate the first trigger event. As a result, it is possible to make it difficult to perform an act of illegally checking the set value.

  In order to generate a settable situation, it is necessary not only to start supplying operating power to the control means but also to generate a second trigger event as well as a first trigger event. Thereby, not only the setting of the setting value to be used is performed but also the case where the setting value to be used is notified, not only the operation power supply to the control means is started. In the configuration in which the first trigger event needs to be generated, the operation for generating the settable situation can be made more complicated. Therefore, it is possible to prevent the act of trying to set the setting value to be used illegally more intensively.

  In addition, the second trigger event necessary for executing the information erasing process is used to notify the condition for generating the settable status and the set value of the target to be used in a status that is not the settable status. It is possible to make the conditions for doing so different.

  Further, when the supply of operating power to the control means is started, depending on whether or not the first trigger event is generated, the information erasure process is executed and the setting is possible. It is possible to select the case where the setting is executed but the setting is not possible.

  Feature a2. The gaming machine according to Feature a1, wherein the first trigger event is that a predetermined operation is performed by a setting key on a setting key insertion unit (setting key insertion unit 68a).

  According to the feature a2, in order to notify the setting of the usage target, it is necessary to perform a predetermined operation with the setting key on the setting key insertion unit. As a result, it is possible to make it difficult to perform an act of illegally checking the set value.

  Feature a3. The gaming machine according to feature a1 or a2, wherein the second trigger event is that a predetermined operation means (reset button 68c) is operated.

  According to the feature a3, in order to generate a settable situation, it is necessary not only to start the supply of operating power to the control unit and to generate the first trigger event but also to operate the predetermined operation unit. As a result, it is difficult to perform an act of trying to set a setting value to be used illegally, but the operation for properly generating the settable situation is prevented from becoming excessively complicated. It becomes possible.

  In addition, with respect to the configuration of the features a1 to a3, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature Z group and the feature a group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, a pachinko gaming machine has a dish storage unit that stores game balls given to a player on the front side of the gaming machine, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in the gaming machine such as the above-described example, there is a demand for a configuration capable of suitably confirming the setting value that determines the advantage of the gaming machine, and there is still room for improvement in this respect. .

<Feature b group>
Feature b1. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
Situation generating means (a function for executing the processing of step S7905, step S7916 and step S7917 in the main CPU 63) so as to be a settable situation in which the setting value to be used can be set by the setting means. When,
Setting monitoring means (a function for executing the process of step S8220 in the main CPU 63) for executing a setting monitoring process for monitoring whether or not the setting value to be used is abnormal;
With
A gaming machine according to claim 1, wherein the setting monitoring process is not included in a process at the start of supply, which is executed when supply of operating power to the control means having the setting means is started.

  According to the feature b1, since the setting value to be used is set from among a plurality of stages of setting values corresponding to the player's advantage, the player has a more advantageous setting value to be used. You will expect that. In addition, since the setting monitoring process for monitoring whether or not the setting value of the usage target is abnormal is executed, it is possible to cope with the case where the setting value of the usage target is abnormal. In addition, since the setting monitoring process is not included in the process at the start of supply, the above-described excellent effects can be achieved while preventing the processing load of the process at the start of supply from increasing.

  Feature b2. The game machine according to claim b1, wherein the situation generating means generates the settable situation in a situation where the process at the start of supply is being executed.

  According to the feature b2, since the setting possible situation occurs in the situation where the process at the start of supply is being executed, it becomes possible to set the set value to be used before the game is started. . In this case, since the set value to be used in the process at the start of supply is set, the processing load of the process at the start of supply increases accordingly. On the other hand, since the configuration of the feature b1 is provided and the setting monitoring process is not included in the process at the start of supply, the processing load of the process at the start of supply is not further increased and the usage target is not increased. It is possible to monitor whether or not the set value is abnormal.

  Feature b3. The gaming machine according to claim b1 or b2, wherein the setting monitoring unit executes the setting monitoring process after the process at the start of supply is completed.

  According to the feature b3, since the setting monitoring process is executed after the process at the start of supply is completed, the setting value of the target to be used is abnormal while preventing the processing load of the process at the start of supply from increasing. It is possible to monitor whether or not.

  Feature b4. The gaming machine according to the feature b3, wherein the setting monitoring unit executes the setting monitoring process every time a monitoring trigger occurs after the supply start process is completed.

  According to the feature b4, since the setting monitoring process is executed every time a monitoring trigger occurs after the process at the start of supply is completed, it is easy to specify that the setting value to be used is abnormal.

Feature b5. Means for executing interrupt processing that is periodically started up (a function of executing the first timer interrupt processing in the main CPU 63);
The gaming machine according to any one of features b1 to b4, wherein the setting process is included in the interrupt process.

  According to the feature b5, since the setting monitoring process is executed every time it is periodically activated, it is possible to increase the frequency of monitoring whether or not the setting value of the usage target is abnormal.

  Feature b6. The setting monitoring means is means for restricting the progress of the game based on the fact that the setting value of the use target is abnormal in the setting monitoring process (step S8207 in the main CPU 63 and The gaming machine according to any one of features b1 to b5, which includes a function of executing the processing of step S8302.

  According to the feature b6, when it is determined that the setting value of the usage target is abnormal, the progress of the game is restricted, so that the game is continued even though the setting value of the usage target is abnormal. It becomes possible not to be.

  Feature b7. The setting monitoring means is configured to notify the player of the fact that the settable situation should be generated based on the fact that the setting value for the use target is specified to be abnormal in the setting monitoring process. The gaming machine according to any one of features b1 to b6, further comprising means for executing the function (a function of executing the process of step S8303 in the main CPU 63).

  According to the feature b7, when it is specified that the setting value of the usage target is abnormal, a notification that allows the player to recognize that a setting possible situation should be generated is executed. When the value becomes abnormal, it is possible to prompt the game hall manager to resolve it.

  In addition, with respect to the configuration of the features b1 to b7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature b group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, a pachinko gaming machine has a dish storage unit that stores game balls given to a player on the front side of the gaming machine, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in the gaming machine such as the above-described example, it is necessary to suitably manage the set value that determines the advantage of the gaming machine, and there is still room for improvement in this respect.

<Characteristic group c>
Feature c1. Predetermined display means (first to fourth notification display devices 201 to 204);
Predetermined display control means for controlling the predetermined display means (function for executing the second timer interrupt processing in the main CPU 63);
With
The predetermined display control means is a check control means for causing the predetermined display means to perform a display for checking that allows the user to confirm whether or not the predetermined display means is normal based on the occurrence of a check trigger (No. 35). The game machine is provided with a function for executing the process of step S9102 in the main CPU 63 in the embodiment, and a function for executing the process of step S9602 in the main CPU 63 in the thirty-eighth embodiment.

  According to the feature c1, the display for checking is performed by the predetermined display unit based on the occurrence of the check trigger. Thereby, it is possible to confirm whether or not the predetermined display means is normal.

Feature c2. The predetermined display means has a plurality of light emitting portions (display segments 321 to 324),
The gaming machine according to claim c1, wherein the check display is a display that enables confirmation that each of the plurality of light emitting units can be in a light emitting state.

  According to the feature c2, each of the plurality of light emitting units of the predetermined display unit is in a light emitting state as a check display. Thereby, it is possible to check whether or not each of the plurality of light emitting units of the predetermined display means is in a light emitting state.

  Feature c3. The gaming machine according to the feature c1 or c2, wherein the check trigger occurs when supply of operating power is started.

  According to the feature c3, since the display for check is performed when the supply of the operating power is started, it is possible to quickly confirm whether or not the predetermined display unit is normal.

  Feature c4. The gaming machine according to any one of features c1 to c3, wherein the check trigger is generated each time supply of operating power is started.

  According to the feature c4, it is possible to check whether or not the predetermined display unit is normal every time the supply of operating power is started.

  Feature c5. The gaming machine according to any one of features c1 to c4, wherein the check trigger is generated without requiring an operation for generating the check trigger when supply of operating power is started.

  According to the characteristic c5, when the supply of the operating power is started, the display for checking is performed without requiring a special operation, so that it is easy to confirm whether or not the predetermined display means is normal. It becomes possible to do.

  Feature c6. The check control means causes the predetermined display means to perform the check display when the supply of operating power is started and the check trigger is generated, and the supply of operating power is started. The game machine according to any one of features c1 to c5, wherein when the check trigger has not occurred, the predetermined display means does not perform the display for checking.

  According to the feature c6, since the display for checking is performed when the supply of the operating power is started and the check trigger is generated, the predetermined display is performed before the game is started on the gaming machine. It is possible to check whether the means is normal. On the other hand, even if the supply of operating power is started, the check display is not performed when the check trigger does not occur, so the check display is performed in the situation where the check display is not required. It becomes possible not to be.

Feature c7. Based on the fact that the gaming machine has been used in a predetermined manner, it is provided with means for storing information in the use correspondence storage means (management start flag) (function to execute the process of step S8606 in the main CPU 63),
The check control means is when the check trigger is generated when the supply of operating power is started and the information stored in the use correspondence storage means does not correspond to the use correspondence information. When the predetermined display means performs the display for checking and the supply of operating power is started, and the information stored in the use correspondence storage means corresponds to the use correspondence information. The gaming machine according to claim c6, wherein the predetermined display means is not made to perform the display for checking that the check trigger has not occurred.

  According to the feature c7, when supply of operating power is started until the gaming machine is used in a predetermined mode, the display for checking is performed by the predetermined display means, and the gaming machine is used in the predetermined mode. Even if the supply of operating power is started based on this, the display for checking is not performed by the predetermined display means. Thus, for example, in the shipping stage of the gaming machine, when the supply of operating power is started, the predetermined display means performs a check display so that whether or not the predetermined display means is normal. It is possible to confirm, and after the gaming machine is installed in the gaming hall, it is possible to prevent the display for checking from being performed on the predetermined display means even if the supply of operating power is started.

Feature c8. The check control means includes
A display ending unit (a function for executing the processing of step S9002 in the main CPU 63 and a function of performing a negative determination in step S9101) for ending the check display on the predetermined display unit based on the occurrence of an end trigger;
Canceling means (a function for executing the process of step S9203 in the main CPU 63 and the canceling means for ending the display for checking in the predetermined display means based on the occurrence of a canceling trigger even in a situation where the termination trigger has not occurred) A function of performing a negative determination in step S9101, a function of executing the process of step S9308 in the main CPU 63, and a function of performing a negative determination in step S9101),
The gaming machine according to any one of features c1 to c7, comprising:

  According to the feature c8, the check display is performed on the predetermined display means because the check display is ended based on the occurrence of the cancel trigger even if the check display end trigger is not generated. Even so, it is possible to terminate the display for checking in the middle and perform another display.

  Feature c9. The game machine according to claim c8, wherein the cancellation opportunity is generated based on an operation of a predetermined operation means (reset button 68c).

  According to the feature c9, since the cancel trigger occurs based on the operation of the predetermined operation means, the check display can be terminated at an arbitrary timing.

Feature c10. The predetermined display control means is a separate display control means (a function for executing the processes of steps S9004 and S9006 in the main CPU 63) for performing a separate display different from the check display when a separate display execution state is reached. Prepared,
The gaming machine according to the feature c8 or c9, wherein the cancellation opportunity is generated based on the separate display execution status.

  According to the feature c10, since the display for check is terminated when a cancellation trigger occurs based on the occurrence of the separate display execution status, the separate display can be prioritized over the display for check.

  Feature c11. Features c1 to c include means for waiting for the progress of processing in the situation where the display for checking is being executed by the predetermined display means (function of executing the process of step S9406 in the main CPU 63). The gaming machine according to any one of c10.

  According to the feature c11, since the display for check is performed by the predetermined display unit in a state where the progress of the process is on standby, it is possible to perform the display for check while suppressing an increase in processing load.

  Feature c12. The check control means causes the predetermined display means to start the check display before the process for controlling the progress of the game is executed when the supply of operating power is started. The gaming machine according to any one of c1 to c11.

  According to the feature c12, when the supply of operating power is started, it is possible to confirm whether or not the predetermined display means is normal before a game is played on the gaming machine.

Feature c13. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
Means for executing processing at the start of supply of operating power based on the start of supply of operating power (in the thirty-fifth embodiment, a function for executing the processing of steps S8801 to S8819 in the main CPU 63, In the embodiment, the function of executing steps S9401 to S9420 in the main CPU 63),
With
In a situation where the process at the start of supplying the operating power is being executed, a predetermined setting related process (setting confirmation process, setting value update process) related to the set value can be executed,
The gaming machine according to claim c12, wherein the check control means starts the display for checking on the predetermined display means in a situation where processing at the start of supply of the operating power is being performed.

  According to the feature c13, since a setting value to be used is set from among a plurality of stages of setting values corresponding to the player's advantage, the player has a more advantageous setting value to be used. You will expect that. Further, a predetermined setting related process related to the setting value can be executed in a situation where the process at the start of supplying the operating power is being executed. As a result, the setting-related process can be executed at a stage before the game is started. In this case, the display for checking is started by the predetermined display means in a situation where the process at the start of supplying the operating power is being executed. As a result, it is possible to consolidate not only the predetermined setting related process but also the process for starting the display for checking by the predetermined display means with respect to the process at the start of the supply of operating power.

  Feature c14. The check control means is means for starting the display for checking on the predetermined display means before the timing at which the predetermined setting-related processing can be executed (in the thirty-fifth embodiment, steps S8804 and S8805 in the main CPU 63). The game machine according to Feature c13, further comprising a function of executing the process of step S9404 and the process of executing step S9405 in the main CPU 63 in the thirty-sixth embodiment.

  According to the feature c14, it is possible to check whether or not the predetermined display unit is normal before the predetermined setting-related process is executed.

  Feature c15. The predetermined display control means is means for causing the predetermined display means to display the current setting value when the predetermined setting-related processing is executed (function for executing the processing of steps S9004 and S9006 in the main CPU 63). A gaming machine according to the feature c13 or c14, characterized by comprising:

  According to the feature c15, when the predetermined setting-related process is executed, the current setting value is displayed on the predetermined display means. Therefore, the administrator of the game hall can check the current setting value by checking the predetermined display means. It becomes possible to grasp. In this case, since the configuration of the feature c13 is provided, the processing for starting the display for checking by the predetermined display means as well as the predetermined setting related processing is integrated in the processing at the start of the supply of the operating power. The process of confirming the predetermined display means and grasping whether or not the predetermined display means is normal and the work of confirming the predetermined display means and grasping the current set value are processing at the start of supply of operating power Can be performed together in a situation where

  In addition, when the configuration of the feature c14 is provided, since the display for checking is started by the predetermined display unit before the current set value is displayed by the predetermined display unit, the predetermined display unit is normal. It is possible to confirm the current set value using a predetermined display means after confirming whether or not. This makes it possible to check the set value accurately.

Feature c16. The check control means includes
Means for starting the display for checking in the predetermined display means before reaching the timing at which the predetermined setting-related processing can be executed (function of executing the processing of steps S8804 and S8805 in the main CPU 63);
Means for terminating the display for checking based on the occurrence of a canceling event in the predetermined setting-related processing in the situation where the display for checking is being performed (function and step for executing processing of step S9203 in the main CPU 63) A function of performing a negative determination in S9101, a function of executing the process of step S9308 in the main CPU 63, and a function of performing a negative determination in step S9101),
The gaming machine according to Feature c15, comprising:

  According to the feature c16, since the display for checking is started by the predetermined display unit before the current set value is displayed by the predetermined display unit, after confirming whether or not the predetermined display unit is normal Thus, it is possible to check the current set value using the predetermined display means. This makes it possible to check the set value accurately. The check display is terminated based on the fact that a predetermined setting-related process is executed and a cancel trigger occurs in a situation where the check display is being performed. Thus, when a predetermined setting-related process is executed, the present display value can be displayed on the predetermined display means by ending the display for checking without waiting for the display for checking to end. It becomes possible. Therefore, the current set value can be confirmed at an early stage.

  Feature c17. The gaming machine according to claim c16, wherein the cancellation trigger is generated based on an operation of a predetermined operation means (reset button 68c).

  According to the feature c17, since the cancellation trigger is generated based on the operation of the predetermined operation unit, the check display can be ended at an arbitrary timing.

  Feature c18. As the predetermined setting-related process, a unit for executing a process for setting the setting value to be used by the setting unit so as to be capable of setting (mainly in the 35th embodiment). A function of making an affirmative determination at step S8806, step S8817, and step S8818 in the side CPU 63, and a function of making an affirmative determination at step S9407, step S9418, and step S9419 in the main CPU 63 in the thirty-sixth embodiment). The gaming machine according to any one of features c13 to c17, characterized by:

  According to the feature c18, the process for starting the display for checking is aggregated in the predetermined display unit as well as the process for setting the setting value to be used for the process at the start of the supply of the operating power. It becomes possible.

Feature c19. The setting unit updates the setting value to be used based on the operation of a predetermined operation unit (reset button 68c) in the settable situation.
The check control means includes
Means for starting the display for checking in the predetermined display means before entering the settable status (function for executing the processing of steps S8804 and S8805 in the main CPU 63);
Means for terminating the check display based on the operation of the predetermined operation means in the settable situation in the state where the check display is being performed (the process of step S9203 in the main CPU 63 is executed) A function and a function of performing a negative determination in step S9101, a function of executing the process of step S9308 in the main CPU 63, and a function of performing a negative determination in step S9101),
With
The predetermined display control means is means for causing the predetermined display means to display the current set value after the display for checking is completed in the settable state (performs processing in steps S9004 and S9006 in the main CPU 63) A gaming machine according to the feature c18.

  According to the feature c19, since the display for check is started by the predetermined display unit before the current set value is displayed by the predetermined display unit, after confirming whether or not the predetermined display unit is normal Thus, it is possible to check the current set value using the predetermined display means. This makes it possible to check the set value accurately. In addition, when the check display is being performed, the setting becomes possible, and when the predetermined operation means is operated, the check display is terminated and the current set value is displayed. As a result, when it becomes possible to set, it is possible to end the display for checking and display the current set value on the predetermined display means without waiting for the display for checking to end. . Therefore, the current set value can be confirmed at an early stage.

  Furthermore, in the configuration in which the setting value to be used is updated based on the operation of the predetermined operation unit in the settable state, the check display is displayed based on the operation of the predetermined operation unit in the settable state. Since the current set value is displayed after the process is completed, a dedicated operation for ending the check display and displaying the current set value is not required. Therefore, it is possible to improve the workability of the work for updating the setting value to be used.

  Feature c20. As the predetermined setting related process, there is provided means for executing a process for displaying the current setting value on the predetermined display means (function for executing a setting confirmation process in the main CPU 63). The gaming machine according to any one of features c13 to c19, characterized by:

  According to the feature c20, the processing for starting the display for checking by the predetermined display unit as well as the processing for confirming the current set value can be integrated with respect to the processing at the start of supply of the operating power. It becomes possible.

  Feature c21. The predetermined display control means is provided with means for displaying information corresponding to the management result of the game history on the predetermined display means (function for executing the processing of step S8708, step S8709 and step S9107 in the main CPU 63). The gaming machine according to any one of features c1 to c20, characterized by:

  According to the feature c21, the management result of the game history can be notified to the manager of the game hall. In this case, whether or not the information corresponding to the management result of the game history in the predetermined display means is accurately displayed by the check display by the predetermined display means having the configuration of the feature c1. Can be confirmed.

  In addition, with respect to the configuration of the features c1 to c21, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature d group>
Feature d1. Predetermined display means (first to fourth notification display devices 201 to 204);
Predetermined display control means for controlling the predetermined display means (function for executing the second timer interrupt processing in the main CPU 63);
With
The predetermined display control means checks whether the predetermined display means is normal before the process for controlling the progress of the game is executed when the supply of operating power is started. Check control means for causing the predetermined display means to perform the display (function of executing step S9102 in the main CPU 63 in the thirty-fifth embodiment, execution of step S9602 in the main CPU 63 in the thirty-eighth embodiment) A gaming machine characterized by having a function of

  According to the feature d1, it is possible to confirm whether or not the predetermined display unit is normal by performing the display for checking by the predetermined display unit. In addition, when the supply of operating power is started, the display for checking is started before the process for controlling the progress of the game is executed. Therefore, when the supply of operating power is started, Thus, it is possible to confirm whether or not the predetermined display means is normal before the game is played.

Feature d2. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage;
Means for executing processing at the start of supply of operating power based on the start of supply of operating power (in the thirty-fifth embodiment, a function for executing the processing of steps S8801 to S8819 in the main CPU 63, In the embodiment, the function of executing steps S9401 to S9420 in the main CPU 63),
With
In a situation where the process at the start of supplying the operating power is being executed, a predetermined setting related process (setting confirmation process, setting value update process) related to the set value can be executed,
The gaming machine according to claim d1, wherein the check control means starts the display for checking on the predetermined display means in a situation where processing at the start of supply of the operating power is being executed.

  According to the feature d2, since a setting value to be used is set from among a plurality of stages of setting values corresponding to the player's advantage, the player is given a more advantageous setting value to be used. You will expect that. Further, a predetermined setting related process related to the setting value can be executed in a situation where the process at the start of supplying the operating power is being executed. As a result, the setting-related process can be executed at a stage before the game is started. In this case, the display for checking is started by the predetermined display means in a situation where the process at the start of supplying the operating power is being executed. As a result, it is possible to consolidate not only the predetermined setting related process but also the process for starting the display for checking by the predetermined display means with respect to the process at the start of the supply of operating power.

  Feature d3. The check control means is means for starting the display for checking on the predetermined display means before the timing at which the predetermined setting-related processing can be executed (in the thirty-fifth embodiment, steps S8804 and S8805 in the main CPU 63). The game machine according to feature d2, further comprising a function for executing the processing of step S9404 and the processing of step S9405 in the main CPU 63 in the thirty-sixth embodiment.

  According to the feature d3, it is possible to check whether or not the predetermined display unit is normal before the predetermined setting-related process is executed.

  Feature d4. The predetermined display control means is means for causing the predetermined display means to display the current setting value when the predetermined setting-related processing is executed (function for executing the processing of steps S9004 and S9006 in the main CPU 63). The gaming machine according to the feature d2 or d3, characterized by comprising:

  According to the feature d4, when the predetermined setting related process is executed, the current setting value is displayed on the predetermined display means. Therefore, the administrator of the game hall can check the predetermined display means to obtain the current setting value. It becomes possible to grasp. In this case, since the configuration of the feature d2 is provided, the processing for starting the display for checking by the predetermined display means as well as the predetermined setting related processing is integrated in the processing at the start of the supply of the operating power. The process of confirming the predetermined display means and grasping whether or not the predetermined display means is normal and the work of confirming the predetermined display means and grasping the current set value are processing at the start of supply of operating power Can be performed together in a situation where

  In addition, when the configuration of the feature d3 is provided, the display for checking is started by the predetermined display unit before the current set value is displayed by the predetermined display unit, so the predetermined display unit is normal. It is possible to confirm the current set value using a predetermined display means after confirming whether or not. This makes it possible to check the set value accurately.

Feature d5. The check control means includes
Means for starting the display for checking in the predetermined display means before reaching the timing at which the predetermined setting-related processing can be executed (function of executing the processing of steps S8804 and S8805 in the main CPU 63);
Means for terminating the display for checking based on the occurrence of a canceling event in the predetermined setting-related processing in the situation where the display for checking is being performed (function and step for executing processing of step S9203 in the main CPU 63) A function of performing a negative determination in S9101, a function of executing the process of step S9308 in the main CPU 63, and a function of performing a negative determination in step S9101),
The gaming machine according to feature d4, comprising:

  According to the feature d5, since the display for checking is started by the predetermined display unit before the current set value is displayed by the predetermined display unit, after confirming whether or not the predetermined display unit is normal Thus, it is possible to check the current set value using the predetermined display means. This makes it possible to check the set value accurately. The check display is terminated based on the fact that a predetermined setting-related process is executed and a cancel trigger occurs in a situation where the check display is being performed. Thus, when a predetermined setting-related process is executed, the present display value can be displayed on the predetermined display means by ending the display for checking without waiting for the display for checking to end. It becomes possible. Therefore, the current set value can be confirmed at an early stage.

  Feature d6. The gaming machine according to claim d5, wherein the cancellation trigger is generated based on an operation of a predetermined operation means (reset button 68c).

  According to the feature d6, the canceling trigger is generated based on the operation of the predetermined operation means, so that the check display can be ended at an arbitrary timing.

  Feature d7. As the predetermined setting-related process, a unit for executing a process for setting the setting value to be used by the setting unit so as to be capable of setting (mainly in the 35th embodiment). A function of making an affirmative determination at step S8806, step S8817, and step S8818 in the side CPU 63, and a function of making an affirmative determination at step S9407, step S9418, and step S9419 in the main CPU 63 in the thirty-sixth embodiment). The gaming machine according to any one of features d2 to d6.

  According to the feature d7, not only the process for setting the setting value to be used but also the process for starting the display for checking by the predetermined display unit is integrated with respect to the process at the start of supplying the operating power. It becomes possible.

Feature d8. The setting unit updates the setting value to be used based on the operation of a predetermined operation unit (reset button 68c) in the settable situation.
The check control means includes
Means for starting the display for checking in the predetermined display means before entering the settable status (function for executing the processing of steps S8804 and S8805 in the main CPU 63);
Means for terminating the check display based on the operation of the predetermined operation means in the settable situation in the state where the check display is being performed (the process of step S9203 in the main CPU 63 is executed) A function and a function of performing a negative determination in step S9101, a function of executing the process of step S9308 in the main CPU 63, and a function of performing a negative determination in step S9101),
With
The predetermined display control means is means for causing the predetermined display means to display the current set value after the display for checking is completed in the settable state (performs processing in steps S9004 and S9006 in the main CPU 63) A gaming machine according to the feature d7.

  According to the feature d8, since the display for check is started by the predetermined display unit before the current set value is displayed by the predetermined display unit, after confirming whether or not the predetermined display unit is normal Thus, it is possible to check the current set value using the predetermined display means. This makes it possible to check the set value accurately. In addition, when the check display is being performed, the setting becomes possible, and when the predetermined operation means is operated, the check display is terminated and the current set value is displayed. As a result, when it becomes possible to set, it is possible to end the display for checking and display the current set value on the predetermined display means without waiting for the display for checking to end. . Therefore, the current set value can be confirmed at an early stage.

  Furthermore, in the configuration in which the setting value to be used is updated based on the operation of the predetermined operation unit in the settable state, the check display is displayed based on the operation of the predetermined operation unit in the settable state. Since the current set value is displayed after the process is completed, a dedicated operation for ending the check display and displaying the current set value is not required. Therefore, it is possible to improve the workability of the work for updating the setting value to be used.

  Feature d9. As the predetermined setting related process, there is provided means for executing a process for displaying the current setting value on the predetermined display means (function for executing a setting confirmation process in the main CPU 63). The gaming machine according to any one of features d2 to d8.

  According to the feature d9, not only the process for confirming the current set value but also the process for starting the display for checking by the predetermined display unit can be integrated with the process at the start of the supply of the operating power. It becomes possible.

  Feature d10. The predetermined display control means is provided with means for displaying information corresponding to the management result of the game history on the predetermined display means (function for executing the processing of step S8708, step S8709 and step S9107 in the main CPU 63). The gaming machine according to any one of features d1 to d9, characterized by:

  According to the feature d10, the management result of the game history can be notified to the manager of the game hall. In this case, whether or not the information corresponding to the management result of the game history in the predetermined display means is accurately displayed by the check display in the predetermined display means having the configuration of the feature d1. Can be confirmed.

  In addition, with respect to the configuration of the features d1 to d10, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature c group and the feature d group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, a pachinko gaming machine has a dish storage unit that stores game balls given to a player on the front side of the gaming machine, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in the gaming machine such as the above-described example, a configuration capable of confirming whether or not the display on the predetermined display means is accurately performed is required, and there is still room for improvement in this respect. is there.

<Feature e group>
Feature e1. When a predetermined event occurs by executing a game, history storage execution means for storing the history information of the game corresponding to the predetermined event in the history storage means (normal counter area 231) (normal entry management processing in the main CPU 63) Function to execute)
Information deriving means (function for executing the process of step S8601 in the main CPU 63) for deriving mode information (base value) corresponding to the result of the game using the history information stored in the history storing means;
Aspect information storage means (calculation result storage area 234) for storing the aspect information derived by the information derivation means;
With
The aspect information storage means is capable of storing a plurality of the aspect information derived at different timings by the information deriving means.

  According to the feature e1, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage unit. Since the history information is stored in the gaming machine itself, unauthorized access to the history information and unauthorized modification can be prevented. In addition, mode information corresponding to the game result is derived using the history information stored in the history storage unit, and the derived mode information is stored in the mode information storage unit. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of the predetermined event in the gaming machine, and it is preferable to manage the occurrence frequency of the predetermined event by using this managed information. Can be performed. Further, the aspect information storage means can store a plurality of aspect information derived at different timings. Accordingly, it is possible to grasp the occurrence frequency of the predetermined event in a plurality of periods, and thus it is possible to accurately grasp the occurrence frequency of the predetermined event.

Feature e2. The aspect information storage means includes
A latest storage area (current area 311) for storing the latest aspect information derived by the information deriving means;
A past storage area (first to third history areas 312 to 314) for storing the aspect information derived by the information deriving means before the aspect information stored in the latest storage area;
The gaming machine according to feature e1, further comprising:

  According to the feature e2, since the latest mode information and the past mode information derived before that are stored, the occurrence frequency of the predetermined event is grasped not only the latest but also the past It becomes possible.

Feature e3. A period elapse specifying means (a function for executing the processing of step S8605 and step S8613 in the main CPU 63) for specifying that a predetermined period has elapsed from the occurrence of the period start opportunity to the occurrence of the period end opportunity;
Nearest memory execution means for storing the mode information derived by the information deriving means in the nearest storage area in a situation where it is not specified that the predetermined period has passed by the period elapsed specifying means (step in the main CPU 63 The function of executing the processing of S8602),
Based on the fact that the predetermined period has been specified by the period elapsed specifying means, the predetermined information derived by the information deriving means using the history information stored in the history storage means Past memory execution means (function to execute the processing of step S8607 and step S8614 in the main CPU 63) for storing period corresponding mode information corresponding to the game result in the period in the past storage area;
The gaming machine according to feature e2, further comprising:

  According to the feature e3, the aspect information derived in a situation where the predetermined period has not elapsed is stored in the latest storage area, and the aspect information derived when the predetermined period has elapsed is stored in the past storage area. Is done. As a result, it is possible to grasp the most recent occurrence frequency of the predetermined event, and it is possible to grasp the occurrence frequency of the past predetermined event in a predetermined period unit. Moreover, since the mode information in units of a predetermined period is stored in the past storage area, the number of mode information stored in the past storage area can be suppressed.

  Feature e4. A means for deleting the history information stored in the history storage means based on the fact that the predetermined period has been specified by the period elapsed specifying means (processing in steps S8608 and S8615 in the main CPU 63) The gaming machine according to feature e3, further comprising:

  According to the feature e4, since the history information in the history information storage unit is deleted when a predetermined period has elapsed, the storage capacity necessary for the history information storage unit can be suppressed. In addition, even if the history information is deleted when the predetermined period elapses in this way, the mode information derived using the history information in the predetermined period is stored in the past storage area. The occurrence frequency of the predetermined event during this period can be grasped later.

  Feature e5. The gaming machine according to any one of the characteristics e2 to e4, wherein the past storage area is capable of storing a plurality of pieces of aspect information having different derived timings.

  According to the feature e5, since a plurality of pieces of mode information are stored in the past storage area, it is possible to compare the occurrence frequencies of predetermined events corresponding to a plurality of periods.

Feature e6. Period elapse specifying means for specifying that a predetermined period from when a predetermined period start trigger occurs to when a predetermined period end trigger occurs (function of executing steps S8605 and S8613 in the main CPU 63) )When,
Based on the fact that the predetermined period has been specified by the time period specifying means, the predetermined information derived by the information deriving means using the history information stored in the history storage means. Past storage execution means (function to execute the processing of step S8607 and step S8614 in the main CPU 63) for storing the aspect information corresponding to the period corresponding to the game result in the period in the aspect information storage means;
With
The game according to any one of features e1 to e5, wherein the mode information storage means is capable of storing a plurality of mode information corresponding to each of the different predetermined periods. Machine.

  According to the feature e6, a plurality of pieces of past aspect information derived in units of a predetermined period are stored. Therefore, the number of pieces of aspect information stored in the aspect information storage unit is suppressed, and a plurality of periods are supported. It is possible to compare the frequency of occurrence of predetermined events.

  Feature e7. A means for deleting the history information stored in the history storage means based on the fact that the predetermined period has been specified by the period elapsed specifying means (processing in steps S8608 and S8615 in the main CPU 63) The gaming machine according to feature e6, further comprising:

  According to the feature e7, since the history information in the history information storage unit is deleted when a predetermined period has elapsed, the storage capacity necessary for the history information storage unit can be suppressed. In addition, even if the history information is deleted when the predetermined period elapses in this way, the mode information derived using the history information in the predetermined period is stored in the past storage area. The occurrence frequency of the predetermined event during this period can be grasped later.

  Feature e8. Means (main side) for controlling the notification means (first to fourth notification display devices 201 to 204) so that notification corresponding to each of the plurality of aspect information stored in the aspect information storage means is sequentially executed. 8. The gaming machine according to any one of features e1 to e7, further comprising a function of executing the processing of steps S8702 to S8709 in the CPU 63).

  According to the feature e8, the notification corresponding to the mode information is performed by the notification unit. Thereby, it is possible to grasp the occurrence frequency of the predetermined event. In addition, since notification corresponding to each of the plurality of pieces of aspect information is sequentially executed, it is possible to individually grasp the occurrence frequency of a predetermined event in a plurality of periods while suppressing the number of notification means.

Feature e9. The aspect information storage means includes a first storage area (first history area 312) capable of storing the aspect information and a second storage area (second history area 313) capable of storing the aspect information. ), And
The gaming machine has means for shifting the mode information stored in the first storage area to the second storage area by an instruction including at least an LDIR instruction when an information shift trigger occurs (step S8607 in the main CPU 63). And a function of executing the process of step S8614). The gaming machine according to any one of features e1 to e8, wherein:

  According to the feature e9, it is possible to shift between the storage areas of the mode information with a simple processing configuration.

  In addition, with respect to the configuration of the features e1 to e9, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature e group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, in a pachinko gaming machine, the front of the gaming machine is provided with a dish storage unit that stores game balls given to the player, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in gaming machines such as the above-described examples, management of gaming machines needs to be performed suitably, and there is still room for improvement in this respect.

<Feature f group>
Feature f1. Means for executing processing at the start of supply of operating power based on the start of supply of operating power (in the thirty-fifth embodiment, a function for executing the processing of steps S8801 to S8819 in the main CPU 63, In the embodiment, the function of executing steps S9401 to S9420 in the main CPU 63),
A power failure monitoring means (a function of executing the process of step S8901 in the main CPU 63) that enables a power failure monitoring process to monitor the occurrence of a power failure in a situation where the process at the start of supplying the operating power is being performed. )When,
A gaming machine characterized by comprising:

  According to the feature f1, since the power failure monitoring process is executed even when the process at the start of the supply of operating power is being executed, a power failure occurs in the situation where the process at the start of the supply of operating power is being executed. When it occurs, it becomes possible to cope with it appropriately.

Feature f2. Means for executing interrupt processing that is periodically started up (a function of executing the first timer interrupt processing in the main CPU 63);
The interruption process includes the power failure monitoring process,
The gaming machine according to claim f1, wherein the interrupt process can be interrupted and activated in a situation where the process at the start of supplying the operating power is being executed.

  According to the feature f2, since the interrupt process is periodically interrupted and activated even when the process at the start of the supply of operating power is being executed, the process at the start of the supply of operating power is executed. Even in situations, it is possible to regularly monitor the occurrence of power outages.

  Feature f3. The interrupt process may be interrupted and started even in a situation where post-end processing (steps S8822 to S8825 in the main CPU 63) is executed after the process at the start of supplying the operating power is completed. The gaming machine according to feature f2.

  According to the feature f3, the occurrence of a power failure is periodically monitored in the situation where the process at the start of the supply of the operating power is performed using the interrupt process that can be interrupted and started in the situation where the post-end process is being executed. Can be performed automatically.

Feature f4. The interrupt process includes a progress handling process (steps S8907 to S8920 in the main CPU 63) executed to control the progress of the game,
When the interrupt process is interrupted and started in the situation where the process at the start of supplying the operating power is being performed, the power failure monitoring process is performed, while the progress handling process is not performed,
The feature f3 is characterized in that both the power failure monitoring process and the progress handling process can be executed when the interrupt process is interrupted and started in a situation where the post-end process is being executed. Game machines.

  According to the feature f4, the occurrence of a power failure is regularly monitored in the situation where the process at the start of the supply of operating power is performed using the interrupt process that can be interrupted and started in the situation where the process after the end is being executed. In the configuration to be performed automatically, even if the interrupt process is interrupted and activated in the situation where the process at the start of the supply of operating power is being executed, the progress corresponding process for controlling the progress of the game will not be executed It becomes possible to do.

Feature f5. A setting means (a function for executing a setting value update process in the main CPU 63) for setting a setting value to be used from among a plurality of setting values corresponding to the player's advantage;
Features f1 to f4 characterized in that, in a situation where the process at the start of supply of the operating power is being executed, a setting possible situation is possible in which the setting value to be set by the setting means can be set. The gaming machine according to any one of the above.

  According to the feature f5, since the power failure monitoring process is executed even when the setting value to be used is set, a power failure occurs during the setting of the setting value to be used. Even if it does, it becomes possible to cope with it appropriately.

  Feature f6. If the supply of operating power is stopped after the occurrence of a power outage is identified in the power outage monitoring process, it is set as a target for use before the supply of operating power is stopped when the supply of operating power is resumed. The gaming machine according to feature f5, wherein a game can be played with the set value.

  According to the feature f6, even if a power failure occurs in the situation where the setting value to be used is set, the occurrence of the power failure is specified by the power failure monitoring process, so the supply of operating power is resumed. In such a case, it is possible to play a game in a situation where the set value selected at the time of the occurrence of a power failure becomes the target of use. Thereby, even if a power failure occurs in the situation where the setting value to be used is set, it is not necessary to set the setting value again when the supply of operating power is resumed.

  In addition, with respect to the configuration of the features f1 to f6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1- R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1- Any one or a plurality of configurations among b7, features c1 to c21, features d1 to d10, features e1 to e9, and features f1 to f6 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature group f, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, in a pachinko gaming machine, the front of the gaming machine is provided with a dish storage unit that stores game balls given to the player, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

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

  Here, in the gaming machine such as the above-described example, it is necessary to appropriately cope with the occurrence of a power failure, and there is still room for improvement in this respect.

  The basic configuration of the gaming machine to which the above features can be applied or applied to each feature is shown below.

  Pachinko gaming machine: operation means operated by a player, game ball launching means for launching a game ball based on the operation of the operation means, a ball path for guiding the launched game ball to a predetermined game area, and a game A gaming machine that includes each gaming component arranged in an area, and gives a bonus to a player when a gaming ball passes through a predetermined passing portion of each gaming component.

  Revolving type gaming machine such as a slot machine: equipped with a picture display device for variably displaying a plurality of pictures, variably starting display of the plurality of pictures due to the operation of the start operation means, and due to the operation of the stop operation means In addition, the game machine is configured such that the variable display of the plurality of patterns is stopped when a predetermined time elapses and a privilege is given to the player according to the pattern after the stop.

  DESCRIPTION OF SYMBOLS 10 ... Pachinko machine, 12 ... Game machine main body, 14 ... Front door frame, 28 ... Launch operation device, 33 ... 1st operation port, 34 ... 2nd operation port, 35 ... Through gate, 49a ... Gate detection sensor, 63 ... Main side CPU, 65 ... Main side RAM, 68a ... Setting key insertion part, 68b ... Update button, 68c ... Reset button, 69a ... First notification display device, 69b ... Second notification display device, 69c ... Third notification Display device 112, management CPU, 117 ... history memory, 171 ... separate storage memory, 181 to 186 ... history memory for settings 1-6, 191 ... first history memory, 192 ... second history Memory 201, first notification display device, 201a to 201g, display segment, 202 ... second notification display device, 202a-202g, display segment, 203 ... third notification display device, 2 DESCRIPTION OF SYMBOLS 4 ... Display apparatus for 4th notification, 221 ... Work area for specific control, 222 ... Stack area for specific control, 223 ... Work area for non-specific control, 224 ... Stack area for non-specific control, 231 ... Normal Counter area, 232 ... open / close execution mode counter area, 233 ... high frequency support mode counter area, 234 ... calculation result storage area, 241 ... management RAM, 251 ... reset signal output section, 252 ... program monitoring section, 311 ... current state area, 312 ... first history area, 313 ... second history area, 314 ... third history area, 321-324 ... display segment.

Claims (6)

Means for executing processing at the start of supply of operating power based on the start of supply of operating power;
A power failure monitoring means for enabling a power failure monitoring process to monitor the occurrence of a power failure in a situation where the process at the start of supplying the operating power is being performed;
A gaming machine characterized by comprising: A means for executing interrupt processing that is started periodically is provided.
The interruption process includes the power failure monitoring process,
The gaming machine according to claim 1, wherein the interrupt process can be interrupted and started in a situation where the process at the start of supplying the operating power is being executed.   The gaming machine according to claim 2, wherein the interrupt process can be interrupted and started even in a situation in which a process after the end is executed after the process at the start of supplying the operating power is completed. The interrupt process includes a progress handling process executed to control the progress of the game,
When the interrupt process is interrupted and started in the situation where the process at the start of supplying the operating power is being performed, the power failure monitoring process is performed, while the progress handling process is not performed,
4. The power failure monitoring process and the progress handling process can both be executed when the interrupt process is interrupted and started in a situation where the post-end process is being executed. The gaming machine described. A setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage,
2. A setting possible situation in which a setting value to be used by the setting unit can be set in a situation where processing at the start of supply of operating power is being performed. 4. The gaming machine according to any one of four.   If the supply of operating power is stopped after the occurrence of a power outage is identified in the power outage monitoring process, it is set as a target for use before the supply of operating power is stopped when the supply of operating power is resumed. The gaming machine according to claim 5, wherein a game can be played with the set value.

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