JP6670228B2 - Gaming machine - Google Patents

Description

  The present invention relates to a gaming machine.

  Conventionally, a game called a pachislot provided with a plurality of reels provided with a plurality of symbols on each surface, a start switch, a stop switch, a stepping motor provided corresponding to each reel, and a control unit Machines are known. The start switch detects that a start lever has been operated by a player (hereinafter, also referred to as a “start operation”) after a game medium such as a medal or a coin has been inserted into the gaming machine, and detects the rotation of all reels. Outputs a signal requesting start. The stop switch detects that a stop button provided for each reel is pressed by a player (hereinafter, also referred to as a "stop operation") and outputs a signal requesting that the rotation of the corresponding reel be stopped. I do. The stepping motor transmits the driving force to the corresponding reel. The control unit controls the operation of the stepping motor based on the signals output from the start switch and the stop switch, and performs the rotation operation and the stop operation of each reel.

  In such a gaming machine, when a start operation is detected, a lottery process using a random number (hereinafter, referred to as “internal lottery process”) is performed on a program, and the result of the lottery (hereinafter, “internal winning combination”) is performed. ) And the timing of the stop operation, the rotation of the reel is stopped. Then, when the rotation of all reels is stopped and a symbol combination (display combination) related to winning is displayed, a privilege corresponding to the symbol combination is given to the player. Examples of the privilege given to the player include payout of a game medium (medal or the like) (hereinafter, also referred to as “small win”), and a re-game (in which the internal lottery process is performed again without consuming the game medium). Hereinafter, it may be referred to as “replay”), a bonus game in which the chance of paying out game media increases, and the like.

  Conventionally, in a gaming machine having the above-described configuration, a function of navigating the establishment of a specific small role (role related to the payout of game media) by a ramp or the like, that is, a function of assist time (hereinafter, referred to as “AT”) A game machine equipped with it has been developed. Conventionally, a gaming machine having a function of operating a game state in which a winning probability of replay is higher than usual when a specific symbol combination is displayed, that is, a function of a replay time (hereinafter, referred to as “RT”) has also been developed. Have been. Further, conventionally, a pachislot having an assist replay time (hereinafter, referred to as “ART”) function in which the AT and the RT operate simultaneously has been developed.

  Conventionally, in a gaming machine having an ART function, there has been known a gaming machine in which a gaming state shifts to an ART state via a specific gaming state called a chance zone (CZ) (for example, see Patent Document 1). ). In this gaming machine, a lottery is performed to determine whether or not to shift the gaming state to the ART state in a specific gaming state (CZ). The gaming machine also has a function of giving a bonus game called a big bonus (BB) to the player as a privilege in each game state.

JP 2014-42658 A

  As described above, conventionally, a gaming machine in which a gaming state shifts to an ART state via a specific gaming state (CZ) is known. Therefore, in recent years, in such a gaming machine, there has been a demand for the development of a technology capable of further enhancing the interest of the game in a specific gaming state (CZ).

  SUMMARY An advantage of some aspects of the invention is to provide a gaming machine that can enhance the interest of a game in a specific game state (CZ).

  In order to solve the above problems, the present invention provides a gaming machine having the following configuration.

A notifying unit (for example, a display device 11 described later) for notifying information on the game,
A specific game state (for example, a CZ state to be described later) capable of determining whether or not to provide a notification game state (for example, an ART state to be described later) in which information advantageous to the player can be provided by the notification means as a privilege. Specific game control means (for example, a main control circuit 90 described later) for controlling the game of
Lock execution means (for example, a game lock to be described later) for generating a lock for disabling a game operation by a player for a predetermined period at a predetermined timing in a unit game when a predetermined condition is satisfied;
Effect execution means (for example, a later-described sub-control circuit 200) capable of executing a predetermined effect according to a game situation,
In a game state other than the specific game state, when a specific condition is satisfied and a start of a special game (for example, BB to be described later) is determined, a first lock (for example, a bonus to be described later) by the lock execution unit is performed. A winning game lock), and a special game start effect for notifying the start of the special game during the first lock period is executed by the effect execution means,
In the specific game state, when the specific condition is satisfied and the start of the special game is determined, the first lock by the lock execution unit does not occur, and the special game start by the effect execution unit is not performed. A gaming machine characterized in that the same effect as the effect is not executed.

In the gaming machine of the present invention, when the start of the special game is determined in the specific game state, even after the start of the special game, the effect execution means, before the start of the special game Continue to perform the effect of the specific game state that has been executed,
After the special game is started in the specific game state, when an end condition of the specific game state (for example, a CZ battle victory described later) is satisfied, the effect execution means sets the specific game state to End the production,
After the end of the effect of the specific game state, a second lock (for example, a game lock at the end of CZ described later) by the lock execution unit is generated, and the specific game is performed during the second lock. A specific game end effect that notifies the end of the state is executed by the effect execution means,
After the end of the specific game end effect, the effect executing means may start an effect corresponding to the special game being executed.

  According to the gaming machine of the present invention having the above configuration, it is possible to further enhance the interest of the game in a specific gaming state.

It is a figure for explaining a functional flow of a game machine in a 1st embodiment of the present invention. FIG. 1 is a perspective view showing an external structure of a gaming machine according to a first embodiment of the present invention. It is a figure showing an internal structure of a game machine in a 1st embodiment of the present invention. It is a figure showing an internal structure of a game machine in a 1st embodiment of the present invention. It is a figure showing the schematic structure of various display screens displayed on the sub-display of a 1st embodiment of the present invention. FIG. 5 is a diagram illustrating a transition example of a display screen of the sub display device according to the first embodiment of the present invention. FIG. 2 is a block diagram illustrating an overall configuration of a circuit included in the gaming machine according to the first embodiment of the present invention. FIG. 2 is a block diagram illustrating an internal configuration of a main control circuit according to the first embodiment of the present invention. FIG. 2 is a block diagram illustrating an internal configuration of the microprocessor according to the first embodiment of the present invention. FIG. 3 is a block diagram illustrating an internal configuration of a sub control circuit according to the first embodiment of the present invention. FIG. 3 is a configuration diagram of various registers included in a main CPU according to the first embodiment of the present invention. FIG. 3 is a diagram illustrating a memory map of a main control circuit according to the first embodiment of the present invention. It is a figure showing the transition flow of the game state between the bonus state and the non-bonus state of the pachislot in the first embodiment of the present invention. It is a figure in the 1st Embodiment of this invention which shows the transition flow of the game state among the ART game state of a pachislo, the non-ART game state, and the bonus state. It is a figure showing an example of a symbol arrangement table in a 1st embodiment of the present invention. It is a figure showing an example of an internal lottery table in a 1st embodiment of the present invention. It is a figure showing an example of an internal lottery table in a 1st embodiment of the present invention. It is a figure showing an example of the symbol combination determination table in the first embodiment of the present invention. It is a figure showing an example of the symbol combination determination table in the first embodiment of the present invention. It is a figure showing an example of the symbol combination determination table in the first embodiment of the present invention. It is a figure showing an example of the symbol combination determination table in the first embodiment of the present invention. It is a figure showing an example of the symbol combination determination table in the first embodiment of the present invention. It is a figure showing an example of the symbol combination determination table in the first embodiment of the present invention. It is a figure showing the correspondence of an internal winning combination and a stop symbol combination in the first embodiment of the present invention. It is a figure showing the correspondence of an internal winning combination and a stop symbol combination in the first embodiment of the present invention. FIG. 4 is a diagram illustrating an example of a reel stop initialization table according to the first embodiment of the present invention. It is a figure showing an example of a pull-in priority table in a 1st embodiment of the present invention. FIG. 4 is a diagram illustrating a configuration (part 1) of a hit request flag storage area and a winning operation flag storage area according to the first embodiment of the present invention. It is a figure showing the structure (the 2) of the hit request flag storage area and the winning operation flag storage area in the first embodiment of the present invention. It is a figure showing (3) of the hit request flag storage area and the winning operation flag storage area in the first embodiment of the present invention. It is a figure showing the composition of the carryover combination storage area in a 1st embodiment of the present invention. It is a figure showing composition of a game state flag storage field in a 1st embodiment of the present invention. It is a figure showing composition of an operation stop button storage area in a 1st embodiment of the present invention. FIG. 3 is a diagram illustrating a configuration of a pressing order storage area according to the first embodiment of the present invention. It is a figure showing composition of a design code storage area in a 1st embodiment of the present invention. It is a figure showing the correspondence table (the 1) of an internal winning combination and a sub flag in a 1st embodiment of the present invention. It is a figure showing the correspondence table (the 2) of an internal winning combination and a sub flag in a 1st embodiment of the present invention. FIG. 7 is a diagram for explaining a notification operation when a sub-flag EX “triple lip” or “reach eye lip” is won in the gaming machine of the first embodiment of the present invention. It is a figure for explaining the flow of the game in the general game state in a 1st embodiment of the present invention. It is a figure showing an example of the normal medium-high probability lottery table in a 1st embodiment of the present invention. It is a figure showing an example of the CZ lottery table in a 1st embodiment of the present invention. It is a figure showing an example of CZ1 mode up lottery table in a 1st embodiment of the present invention. It is a figure showing an example of the CZ2 middle point lottery table in a 1st embodiment of the present invention. It is a figure showing an example of CZ ART lottery table (for CZ1, CZ2) in a 1st embodiment of the present invention. It is a figure showing an example of CZ ART lottery table (for CZ3) in a 1st embodiment of the present invention. It is a figure for explaining the flow of the game during normal ART in a 1st embodiment of the present invention. It is a figure showing an example of the flag conversion lottery table under ART in a 1st embodiment of the present invention. FIG. 4 is a diagram illustrating an example of an ART level determination table according to the first embodiment of the present invention. It is a figure showing an example of a normal ART medium-high probability lottery table in a 1st embodiment of the present invention. It is a figure showing an example of a CT random determination table during ART in a 1st embodiment of the present invention. It is a figure showing an example of the addition in a normal ART lottery table in a 1st embodiment of the present invention. It is a figure for explaining the flow of the game in CT state in a 1st embodiment of the present invention. It is a figure showing an example of a table during a CT table lottery table in a 1st embodiment of the present invention. It is a figure showing an example of the flag change lottery table under CT in a 1st embodiment of the present invention. It is a figure showing an example of a CT addition super lottery table in a 1st embodiment of the present invention. It is a figure showing an example of a lottery table in addition to the number of sets in CT in a 1st embodiment of the present invention. It is a figure for explaining the flow of the game in the bonus state in the first embodiment of the present invention. It is a figure showing an example of the bonus type lottery table in a 1st embodiment of the present invention. FIG. 7 is a diagram illustrating an example of a lottery table in which the number of ART games during bonus is added according to the first embodiment of the present invention. It is a figure showing an example of the CT lottery table at the time of the end of a bonus in a 1st embodiment of the present invention. It is a figure for explaining a flow of a game (others) in a general game state in a 1st embodiment of the present invention. FIG. 7 is a diagram illustrating an example of a non-ART flag conversion lottery table according to the first embodiment of the present invention. FIG. 4 is a diagram showing a correspondence relationship between main navigation data and sub navigation data according to the first embodiment of the present invention. It is a flowchart which shows the example at the time of power-on (reset interruption) performed by the main control circuit of the gaming machine in the first embodiment of the present invention. FIG. 5 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a power-on process according to the first embodiment of the present invention. It is a flow chart which shows the example of game return processing in a 1st embodiment of the present invention. It is a figure showing an example of a source program for performing various processing in a flow chart of game return processing in a 1st embodiment of the present invention. 6 is a flowchart illustrating an example of a setting change confirmation process according to the first embodiment of the present invention. FIG. 5 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a setting change confirmation process according to the first embodiment of the present invention. 6 is a flowchart illustrating an example of a setting change command generation and storage process according to the first embodiment of the present invention. FIG. 4 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a setting change command generation and storage process according to the first embodiment of the present invention. 5 is a flowchart illustrating an example of a communication data storage process according to the first embodiment of the present invention. FIG. 4 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a communication data storage process according to the first embodiment of the present invention. 5 is a flowchart illustrating an example of a communication data pointer update process according to the first embodiment of the present invention. FIG. 6 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a communication data pointer update process according to the first embodiment of the present invention. 6 is a flowchart illustrating an example of processing at the time of power interruption (external) according to the first embodiment of the present invention. 5 is a flowchart illustrating an example of a checksum generation process (not defined) according to the first embodiment of the present invention. An example of a source program for executing various processes in the flowchart of the checksum generation process according to the first embodiment of the present invention, an operation of updating a stack pointer executed in the checksum generation process, and an operation of updating data to a register FIG. 7 is a diagram illustrating a state of a read operation. It is a flow chart which shows the example of the sum check processing (undefined) in a 1st embodiment of the present invention. It is a flow chart which shows the example of the sum check processing (undefined) in a 1st embodiment of the present invention. FIG. 4 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a sum check process according to the first embodiment of the present invention. It is a flow chart which shows the example of the main processing (main operation processing) performed by the main control circuit of the game machine in the first embodiment of the present invention. It is a flow chart which shows the example of the medal acceptance and start check processing in a 1st embodiment of the present invention. FIG. 6 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a medal acceptance / start check process according to the first embodiment of the present invention. It is a flow chart which shows the example of the medal insertion processing in a 1st embodiment of the present invention. FIG. 5 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a medal shooting process according to the first embodiment of the present invention. It is a flow chart which shows the example of the medal insertion check processing in a 1st embodiment of the present invention. FIG. 6 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a medal insertion check process according to the first embodiment of the present invention. 5 is a flowchart illustrating an example of an error process according to the first embodiment of the present invention. FIG. 5 is a diagram illustrating an example of a configuration of an error table that is actually referred to on a source program for error processing according to the first embodiment of the present invention. 5 is a flowchart illustrating an example of a random number acquisition process according to the first embodiment of the present invention. It is a flow chart which shows the example of the internal lottery processing in a 1st embodiment of the present invention. It is a figure showing an example of a source program for performing various processings in a flowchart of internal lottery processing in a 1st embodiment of the present invention. It is a figure showing an example of composition of an internal lottery table (for general games) which is actually referred on a source program of internal lottery processing in a first embodiment of the present invention. It is a figure showing an example of composition of an RT state classified lottery value selection table actually referred on a source program of internal lottery processing in a 1st embodiment of the present invention. Internal lottery value table selection table, 1 byte internal lottery value table, 2 byte internal lottery value table, 1 byte setting internal It is a figure showing an example of composition of a lottery value table and a 2 byte setting internal lottery value table. 5 is a flowchart illustrating an example of a symbol setting process according to the first embodiment of the present invention. It is a figure showing the correspondence of a special prize (bonus) winning number and a small winning combination number and an internal winning combination in the first embodiment of the present invention. FIG. 6 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a symbol setting process according to the first embodiment of the present invention. It is a figure showing an example of composition of a hit request flag table actually referred on a source program of symbol setting processing in a first embodiment of the present invention. 5 is a flowchart illustrating an example of compressed data storage processing according to the first embodiment of the present invention. 5 is a flowchart illustrating an example of a second interface board control process (not defined) according to the first embodiment of the present invention. 6 is a flowchart illustrating an example of a second interface board output process according to the first embodiment of the present invention. It is a flowchart which shows the example of the control processing according to state in 1st Embodiment of this invention. 6 is a flowchart illustrating an example of a sub-flag conversion process according to the first embodiment of the present invention. FIG. 4 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a sub-flag conversion process according to the first embodiment of the present invention. FIG. 7 is a diagram illustrating an example of a configuration of a sub-flag conversion table that is actually referred to on a source program of a sub-flag conversion process according to the first embodiment of the present invention. 5 is a flowchart illustrating an example of a navigation set process according to the first embodiment of the present invention. It is a figure showing an example of a source program for performing various processings in a flow chart of a navigation set processing in a 1st embodiment of the present invention. FIG. 5 is a diagram illustrating an example of a configuration of a navigation data table that is actually referred to on a source program for a navigation set process according to the first embodiment of the present invention. 5 is a flowchart illustrating an example of a flag conversion process according to the first embodiment of the present invention. It is a flowchart which shows the example of the process at the time of the normal start in 1st Embodiment of this invention. It is a flowchart which shows the example of the process at the time of the start during CZ in 1st Embodiment of this invention. It is a flow chart which shows the example of processing in CZ1 (CZ2) in a 1st embodiment of the present invention. It is a flow chart which shows the example of processing in CZ1 (CZ2) in a 1st embodiment of the present invention. It is a flow chart which shows an example of processing in CZ3 in a 1st embodiment of the present invention. It is a flowchart which shows the example of the process at the time of the start during normal ART in 1st Embodiment of this invention. It is a flowchart which shows the example of the process at the time of the start during CT in 1st Embodiment of this invention. It is a flowchart which shows the example of CT random determination processing in CT in 1st Embodiment of this invention. 5 is a flowchart illustrating an example of a table data acquisition process according to the first embodiment of the present invention. FIG. 6 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a table data acquisition process according to the first embodiment of the present invention. It is a figure showing an example of composition of a CT lottery table in CT actually referred on a source program of table data acquisition processing in a 1st embodiment of the present invention. It is a flow chart which shows the example of 1 byte lottery processing in a 1st embodiment of the present invention. It is a figure showing an example of a source program for performing various processings in a flow chart of 1 byte lottery processing in a 1st embodiment of the present invention. It is a flowchart which shows the example of the process at the time of the start during BB in 1st Embodiment of this invention. 5 is a flowchart illustrating an example of a pull-in priority order storage process according to the first embodiment of the present invention. FIG. 5 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a pull-in priority storing process according to the first embodiment of the present invention. It is a flow chart which shows the example of the design code acquisition processing in a 1st embodiment of the present invention. It is a figure showing an example of a source program for performing various processings in a flow chart of a symbol code acquisition processing in a first embodiment of the present invention. It is referred to at the time of setting the first body (left reel) symbol arrangement table and the first body symbol arrangement table which are actually referred to on the source program of the symbol code acquisition processing according to the first embodiment of the present invention. It is a figure showing an example of composition of a symbol corresponding winning operation table. It is referred to at the time of setting the second body (middle reel) symbol arrangement table and the second body symbol arrangement table which are actually referred to on the source program of the symbol code acquisition processing in the first embodiment of the present invention. It is a figure showing an example of composition of a symbol corresponding winning operation table. It is referred to at the time of setting the third body (right reel) symbol arrangement table and the third body symbol arrangement table which are actually referred to on the source program of the symbol code acquisition processing in the first embodiment of the present invention. It is a figure showing an example of composition of a symbol corresponding winning operation table. 5 is a flowchart illustrating an example of a logical product operation process according to the first embodiment of the present invention. It is a flowchart which shows the example of the attraction priority acquisition process in 1st Embodiment of this invention. It is a flowchart which shows the example of the attraction priority acquisition process in 1st Embodiment of this invention. FIG. 5 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a pull-in priority acquisition process according to the first embodiment of the present invention. It is a figure which shows an example of a structure of the attraction priority table which is actually referred on the source program of the attraction priority acquisition processing in the first embodiment of the present invention. 6 is a flowchart illustrating an example of a reel stop control process according to the first embodiment of the present invention. FIG. 6 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a reel stop control process according to the first embodiment of the present invention. FIG. 6 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a reel stop control process according to the first embodiment of the present invention. 5 is a flowchart illustrating an example of a reel stop enable signal OFF process (not specified) according to the first embodiment of the present invention. It is a flowchart which shows the example of the reel stop enable signal ON process (out of specification) in the first embodiment of the present invention. 5 is a flowchart illustrating an example of an undefined port output process according to the first embodiment of the present invention. FIG. 5 is a diagram illustrating an example of a source program for executing various processes in a flowchart of an undefined port output process according to the first embodiment of the present invention. It is a flow chart which shows the example of the winning search processing in a 1st embodiment of the present invention. FIG. 6 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a winning search process according to the first embodiment of the present invention. It is a figure showing an example of composition of a payout number data table actually referred to on a source program of a winning search processing in a 1st embodiment of the present invention. 5 is a flowchart illustrating an example of an illegal hit check process according to the first embodiment of the present invention. FIG. 4 is a diagram illustrating an example of a source program for executing various processes in a flowchart of an illegal hit check process according to the first embodiment of the present invention. It is a flow chart which shows an example of winning check and medal payout processing in a 1st embodiment of the present invention. It is a figure showing an example of a source program for performing various processing in a flow chart of a winning check and medal payout processing in a first embodiment of the present invention. It is a flow chart which shows an example of medal payout number check processing in a 1st embodiment of the present invention. FIG. 5 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a medal payout number check process according to the first embodiment of the present invention. 6 is a flowchart illustrating an example of a BB check process according to the first embodiment of the present invention. 6 is a flowchart illustrating an example of an RT check process according to the first embodiment of the present invention. 6 is a flowchart illustrating an example of an RT check process according to the first embodiment of the present invention. 6 is a flowchart illustrating an example of a process at the time of ending CZ / ART according to the first embodiment of the present invention. It is a flowchart which shows the example of the interruption process performed by the main control circuit of the gaming machine in the first embodiment of the present invention. 6 is a flowchart illustrating an example of a 7-segment LED driving process according to the first embodiment of the present invention. FIG. 4 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a 7-segment LED driving process according to the first embodiment of the present invention. 5 is a flowchart illustrating an example of 7-segment display data generation processing according to the first embodiment of the present invention. FIG. 4 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a 7-segment display data generation process according to the first embodiment of the present invention. FIG. 6 is a diagram illustrating an example of a configuration of a 7-segment cathode table that is actually referred to on a source program for 7-segment display data generation processing according to the first embodiment of the present invention. 6 is a flowchart illustrating an example of a timer update process according to the first embodiment of the present invention. FIG. 6 is a diagram illustrating an example of a source program for executing various processes in a flowchart of a timer update process according to the first embodiment of the present invention. It is a flowchart which shows the example of the test-fire test signal control processing (out of specification) in the 1st Embodiment of this invention. 5 is a flowchart illustrating an example of a turning drum braking signal generation process according to the first embodiment of the present invention. It is a flow chart which shows the example of the special prize signal control processing in a 1st embodiment of the present invention. It is a flow chart which shows an example of condition device signal control processing in a 1st embodiment of the present invention. It is a flow chart which shows an example of condition device signal control processing in a 1st embodiment of the present invention. It is a flowchart which shows the example of the sub side navigation control processing performed by the sub control circuit of the gaming machine in the first embodiment of the present invention. It is a flow chart which shows the example of the player registration processing in a 1st embodiment of the present invention. 5 is a flowchart illustrating an example of a history management process according to the first embodiment of the present invention. It is a figure in the modification 1 of this invention which shows the flow of the game during CT precursor. It is a figure showing the correspondence of an internal winning combination and a stop symbol combination in the modification 2 of the present invention. FIG. 13 is a diagram showing a correspondence relationship between main navigation data and sub navigation data in a third modification of the present invention. FIG. 14 is a diagram showing a correspondence between a pressing order and a locked state in a fifth modification of the present invention. It is a figure showing a transition flow of a main game state in a pachislo of a 2nd embodiment of the present invention. It is a figure showing the transition flow (game flow) of the payout state in the pachislot of the second embodiment of the present invention. It is a figure showing an example of a symbol arrangement table in a 2nd embodiment of the present invention. It is a figure showing an example of the symbol combination table (the 1) in a 2nd embodiment of the present invention. It is a figure showing an example of the symbol combination table (the 2) in a 2nd embodiment of the present invention. It is a figure showing an example of the symbol combination table (the 3) in a 2nd embodiment of the present invention. It is a figure showing an example of the symbol combination table (the 4) in a 2nd embodiment of the present invention. It is a figure showing an example of a table at the time of a bonus operation in a 2nd embodiment of the present invention. It is a figure showing an example of RT transition table in a 2nd embodiment of the present invention. It is a figure showing an example of an internal lottery table decision table in a 2nd embodiment of the present invention. It is a figure showing an example of the internal lottery table for RT0 (the 1) in a 2nd embodiment of the present invention. It is a figure showing an example of the internal lottery table for RT0 (the 2) in a 2nd embodiment of the present invention. It is a figure showing an example of RT1 internal lottery table (the 1) in a 2nd embodiment of the present invention. It is a figure showing an example of the internal lottery table for RT1 (the 2) in a 2nd embodiment of the present invention. It is a figure showing an example of RT2 internal lottery table (the 1) in a 2nd embodiment of the present invention. It is a figure showing an example of the internal lottery table for RT2 (the 2) in a 2nd embodiment of the present invention. It is a figure showing an example of the internal lottery table for RT3 (the 1) in a 2nd embodiment of the present invention. It is a figure showing an example of the internal lottery table for RT3 (the 2) in a 2nd embodiment of the present invention. It is a figure showing an example of the internal lottery table (the 1) for the BB3 flag in a 2nd embodiment of the present invention. It is a figure showing an example of the BB3 flag internal lottery table (the 2) in a 2nd embodiment of the present invention. It is a figure showing an example of the internal lottery table for the BB2 flag interval (the 1) in a 2nd embodiment of the present invention. It is a figure showing an example of the internal lottery table for the BB2 flag interval (the 2) in a 2nd embodiment of the present invention. It is a figure showing an example of the BB1 flag internal lottery table (the 1) in a 2nd embodiment of the present invention. It is a figure showing an example of the internal lottery table (part 2) for between BB1 flags in a 2nd embodiment of the present invention. It is a figure showing an example of BB2 and BB3 inside internal lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of BB1 inside internal lottery table in a 2nd embodiment of the present invention. It is a figure showing correspondence between an internal winning combination and a special prize winning number in a second embodiment of the present invention. It is a figure showing correspondence between an internal winning combination and a small combination winning number in a second embodiment of the present invention. It is a figure showing an example of the symbol combination decision table (the 1) in a 2nd embodiment of the present invention. It is a figure showing an example of the symbol combination decision table (the 2) in a 2nd embodiment of the present invention. It is a figure showing an example of the symbol combination decision table (the 3) in a 2nd embodiment of the present invention. It is a figure showing an example of the symbol combination decision table (the 4) in a 2nd embodiment of the present invention. It is a figure showing an example of the symbol combination decision table (the 5) in a 2nd embodiment of the present invention. It is a figure showing an example of the symbol combination decision table (the 6) in a 2nd embodiment of the present invention. It is a figure showing an example of the symbol combination determination table (part 7) in the second embodiment of the present invention. It is a figure in the 2nd Embodiment of this invention which shows an example of the symbol combination determination table (the 8). It is a figure in the 2nd Embodiment of this invention which shows an example of the symbol combination determination table (the 9). It is a figure in the 2nd Embodiment of this invention which shows an example of the symbol combination determination table (the 10). It is a figure showing an example of the symbol combination determination table (No. 11) in the second embodiment of the present invention. It is a figure showing an example of the symbol combination determination table (part 12) in the second embodiment of the present invention. It is a figure showing an example of a symbol corresponding winning operation flag data table in the second embodiment of the present invention. It is a figure showing correspondence between an internal winning combination and a sub flag in a 2nd embodiment of the present invention. It is a figure showing the correspondence of the sub flag and various payout lottery flags in a 2nd embodiment of the present invention. It is a figure showing an example of CZ lottery mode lottery table in a 2nd embodiment of the present invention. It is a figure showing the lottery index list used by CZ lottery mode lottery in a 2nd embodiment of the present invention. It is a figure showing an example of the CZ lottery mode cycle game number lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of the CZ lottery 1 table in a 2nd embodiment of the present invention. It is a figure showing the lottery index list used by CZ lottery 1 in a 2nd embodiment of the present invention. It is a figure showing an example of the CZ lottery 2 table in a 2nd embodiment of the present invention. It is a figure showing an example of a cycle management mode shift lottery table in a 2nd embodiment of the present invention. It is a figure showing the lottery index list used by cycle management mode change lottery in a 2nd embodiment of the present invention. It is a figure showing an example of a P point lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of a P point initial value lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of an ART direct hit lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of an episode BB premium ART lottery table in a 2nd embodiment of the present invention. It is a figure showing the lottery index list used for episode BB lottery and premium ART lottery in a 2nd embodiment of the present invention. It is a figure showing an example of the CZ enemy character lottery table in a 2nd embodiment of the present invention. FIG. 13 is a diagram illustrating a correspondence between a CZ enemy character type and an initial value of an enemy HP according to the second embodiment of the present invention. It is a figure showing an example of the CZ level lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of the special effect lottery table in a 2nd embodiment of the present invention. It is a figure showing the lottery index list used for the special effect lottery in a 2nd embodiment of the present invention. It is a figure showing an example of the special effect game number lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of a damage lottery table in a 2nd embodiment of the present invention. It is a figure showing the lottery index list used for damage random determination in a 2nd embodiment of the present invention. It is a figure showing an example of the CZ end lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of the ART set number lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of a safe zone game number lottery table in a 2nd embodiment of the present invention. It is a figure showing the lottery index list used by the safety zone game number random determination in a 2nd embodiment of the present invention. It is a figure showing an example of the ART enemy character lottery table in a 2nd embodiment of the present invention. It is a figure showing the lottery index list used in ART enemy character lottery in a 2nd embodiment of the present invention. It is a figure showing an example of the battle B lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of the special mode contents lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of HP recovery and a weapon lottery table in a 2nd embodiment of the present invention. It is a figure showing the lottery index list used by HP recovery and weapon lottery in a 2nd embodiment of the present invention. It is a figure showing an example of a reward lottery table in a 2nd embodiment of the present invention. It is a figure showing the lottery index list used by reward lottery in a 2nd embodiment of the present invention. It is a figure showing an example of HP recovery amount lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of a friend HP addition lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of the number-of-weapons lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of the battle B damage lottery table in a 2nd embodiment of the present invention. It is a figure showing an example of the battle B guarantee reward table in a 2nd embodiment of the present invention. It is a figure showing an example of the CZ required point lottery table in a 2nd embodiment of the present invention. It is a figure showing the lottery index list used by CZ required point lottery in a 2nd embodiment of the present invention. It is a figure showing an example of the CZ point lottery table in a 2nd embodiment of the present invention. It is a figure showing the composition of the display combination storage area (internal winning combination storage area) in a 2nd embodiment of the present invention. It is a figure showing the composition of the carryover combination storage area in a 2nd embodiment of the present invention. It is a figure showing composition of a game state flag storage field in a 2nd embodiment of the present invention. It is a figure showing composition of a payout state flag storage field in a 2nd embodiment of the present invention. It is a figure showing composition of a design code storage area in a 2nd embodiment of the present invention. It is a figure showing composition of an instruction flag storage field in a 2nd embodiment of the present invention. It is a figure showing the correspondence (the 1) of the internal winning combination, the pressing order, and the symbol combination in the second embodiment of the present invention. It is a figure showing the correspondence (the 2) of the internal winning combination, the pressing order, and the symbol combination in the second embodiment of the present invention. FIG. 11 is a diagram illustrating a correspondence between a pressing order navigation type and an instruction monitor number according to the second embodiment of the present invention. It is a figure showing the correspondence (the 1) of the internal winning combination and the pressing order navigation type (instruction monitor number) in the second embodiment of the present invention. It is a figure showing the correspondence (the 2) of the internal winning combination and the pressing order navigation type (instruction monitor number) in the second embodiment of the present invention. It is a figure for explaining contents of various game locks in a 2nd embodiment of the present invention. It is a flowchart which shows the example at the time of power-on (reset interrupt) performed by the main control circuit of the gaming machine in the second embodiment of the present invention. 11 is a flowchart illustrating an example of a power return process according to the second embodiment of the present invention. It is a flow chart which shows an example of processing at the time of setting change in a 2nd embodiment of the present invention. It is a flow chart which shows the example of the main processing (main operation processing) performed by the main control circuit of the game machine in a second embodiment of the present invention. It is a flow chart which shows the example of the internal lottery processing in a 2nd embodiment of the present invention. It is a flow chart which shows the example of acquisition processing of the special prize winning number and the small winning combination number in a 2nd embodiment of the present invention. It is a flow chart which shows the example of the lottery processing at the time of lever ON in a 2nd embodiment of the present invention. It is a flow chart which shows an example of friend HP addition processing in a 2nd embodiment of the present invention. It is a flowchart which shows the example of the process at the time of the start during BB in 2nd Embodiment of this invention. It is a flowchart which shows the example of the process at the time of the start during CZ in 2nd Embodiment of this invention. It is a flowchart which shows the example of the process at the time of the start during CZ in 2nd Embodiment of this invention. It is a flow chart which shows an example of processing at the time of CZ victory in a 2nd embodiment of the present invention. It is a flow chart which shows an example of lottery result processing at the time of CZ end in a 2nd embodiment of the present invention. It is a flow chart which shows an example of CZ continuation processing in a 2nd embodiment of the present invention. It is a flow chart which shows the example of ART comprehensive lottery processing in a 2nd embodiment of the present invention. It is a flow chart which shows the example of ART comprehensive lottery processing in a 2nd embodiment of the present invention. It is a flowchart which shows the example of the process at the time of the start during ART in 2nd Embodiment of this invention. It is a flowchart which shows the example of the process at the time of the start during ART in 2nd Embodiment of this invention. It is a flow chart which shows an example of CZ point acquisition processing in a 2nd embodiment of the present invention. It is a flow chart which shows an example of safe zone game number preservation processing in a 2nd embodiment of the present invention. It is a flow chart which shows the example of battle B shift processing in a 2nd embodiment of the present invention. It is a flow chart which shows the example of battle B shift processing in a 2nd embodiment of the present invention. It is a flow chart which shows an example of battle B damage reflection processing in a 2nd embodiment of the present invention. It is a flow chart which shows an example of battle B damage reflection processing in a 2nd embodiment of the present invention. It is a flowchart which shows the example of the process at the time of the start during normal in 2nd Embodiment of this invention. It is a flowchart which shows the example of the normal ART lottery process in 2nd Embodiment of this invention. It is a flow chart which shows the example of RT state control processing in a 2nd embodiment of the present invention. It is a flow chart which shows the example of the production lottery processing at the time of the end of a game in a 2nd embodiment of the present invention. It is a flowchart which shows the example of the effect lottery process at the time of completion | finish of a normal game in 2nd Embodiment of this invention. It is a flowchart which shows the example of the effect lottery process at the time of completion | finish of a normal game in 2nd Embodiment of this invention. It is a flow chart which shows the example of the production lottery processing at the time of the end of game during BB1 in a 2nd embodiment of the present invention. 11 is a flowchart illustrating an example of an ART initialization process according to the second embodiment of the present invention. It is a flow chart which shows an example of safe zone game number storage processing in a 2nd embodiment of the present invention. It is a flowchart which shows the example of the process at the time of the ART chapter start in 2nd Embodiment of this invention. 11 is a flowchart illustrating an example of a CZ level setting process according to the second embodiment of the present invention. It is a flow chart which shows the example of CZ lottery mode lottery processing (at the time of transition to normal, when the CZ lottery cycle has elapsed) in the second embodiment of the present invention. It is a flow chart which shows the example of the production lottery processing at the time of the end of the CZ game in a 2nd embodiment of the present invention. It is a flow chart which shows the example of the production lottery processing at the time of the end of the CZ game in a 2nd embodiment of the present invention. It is a flowchart in the 2nd Embodiment of this invention which shows the example of the process after the number determination of the number of safety zone games. 11 is a flowchart illustrating an example of a normal transition process according to the second embodiment of the present invention. It is a flowchart which shows the example of the effect lottery process at the time of the end of the game in ART in 2nd Embodiment of this invention. It is a flowchart which shows the example of the effect lottery process at the time of the end of the game in ART in 2nd Embodiment of this invention. It is a flowchart which shows the example of the effect lottery process at the time of the end of the game in ART in 2nd Embodiment of this invention. It is a flow chart which shows the example of the safe zone game number setting processing in a 2nd embodiment of the present invention. It is a flow chart which shows an example of CZ required point confirmation processing in a 2nd embodiment of the present invention. It is a flow chart which shows the example of the bonus end check processing in a 2nd embodiment of the present invention. It is a flow chart which shows the example of the production lottery processing at the time of the end of a bonus in a 2nd embodiment of the present invention. It is a flow chart which shows the example of CZ lottery mode lottery processing (at the time of bonus end) in a 2nd embodiment of the present invention. It is a flow chart which shows the example of the bonus operation check processing in a 2nd embodiment of the present invention. 13 is a flowchart illustrating an example of a main board communication task performed by a sub CPU according to the second embodiment of the present invention. It is a flowchart which shows the example of the effect registration task performed by the sub CPU in 2nd Embodiment of this invention. It is a flowchart which shows the example of the effect content determination processing performed by the sub CPU in 2nd Embodiment of this invention. It is a figure which shows the structure of the ratio display in the modification 9 of this invention, the example of attachment, and the display content of information.

1. First Embodiment Hereinafter, a pachislot machine will be described as an example of a gaming machine according to a first embodiment of the present invention, and its configuration and operation will be described with reference to the drawings. In the present embodiment, a pachislot having a bonus operation function and an ART function will be described.

<Function flow>
First, a functional flow of the pachislot will be described with reference to FIG. In the pachislo of the present embodiment, medals are used as game media for performing a game. In addition, as a game medium, for example, coins, game balls, point data for games, tokens, and the like can be applied in addition to medals.

  When a player inserts a medal into a pachislot and operates the start lever, one value (hereinafter, referred to as a random number value) is extracted from random numbers in a predetermined numerical range (for example, 0 to 65535).

  The internal lottery means performs a lottery based on the extracted random number value and determines an internal winning combination. The internal lottery means is one of various processing means (processing functions) provided in a main control circuit described later. By determining the internal winning combination, a combination of symbols permitted to be displayed along an effective line (winning determination line) described later is determined. In addition, the types of symbol combinations include those related to "winning" in which a bonus such as payout of medals, activation of replays (replay), activation of bonuses, etc. are given to a player, and other so-called "losing". Such is provided. In the following, the combination relating to the payout of medals is referred to as “small combination”, and the combination relating to the operation of the replay (replay) is referred to as “replay combination”. In addition, a hand related to the operation of the bonus (bonus game) is also referred to as a “bonus hand”.

  When the start lever is operated, the rotation of the plurality of reels is performed. Thereafter, when the stop button corresponding to the predetermined reel is pressed by the player, the reel stop control means performs control to stop the rotation of the corresponding reel based on the internal winning combination and the timing at which the stop button is pressed. Do. The reel stop control means is one of various processing means (processing functions) provided in a main control circuit described later.

  In the pachislo, basically, control for stopping the rotation of the relevant reel is performed within a specified time (190 msec) from when the stop button is pressed. In the present embodiment, the number of symbols that move with the rotation of the reel within the specified time is referred to as “the number of sliding pieces”. In the present embodiment, when the prescribed period is 190 msec, the maximum number of sliding pieces (maximum number of sliding pieces) is determined to be four symbols.

  When the internal winning combination that permits the display of the combination of the symbols related to the winning is determined, the reel stop control means normally sets the combination of the symbols to the active line within a specified time of 190 msec (for four symbols of the symbol). The rotation of the reel is stopped so as to be displayed as much as possible. Further, the reel stop control means stops the rotation of the reels using the specified time so that a combination of symbols whose display is not permitted by the internal winning combination is not displayed along the activated line.

  When the rotations of the plurality of reels are all stopped in this way, the winning determination means determines whether or not the combination of the symbols displayed along the activated line is a winning combination. This winning determination means is also one of various processing means (processing functions) provided in a main control circuit described later. When the displayed combination of symbols is determined to be a winning combination by the winning determination unit, a bonus such as a medal payout is given to the player. In the pachislot, the above-described series of flows is performed as one game (unit game).

  Also, in the pachislot, in the flow of the above-described game operation, various effects are displayed by using a display device or the like to display an image, output light from various lamps, output sound from a speaker, or a combination thereof. Is performed.

  Specifically, when the start lever is operated, a random number value for effect is extracted separately from the random number value used for determining the internal winning combination described above. When the random number value for the effect is extracted, the effect content determination means determines the effect to be executed this time by lottery from among a plurality of types of effect contents associated with the internal winning combination. The effect content determining means is one of various processing means (processing functions) provided in a sub-control circuit described later.

  Next, when the effect content is determined by the effect content determining means, the effect executing means interlocks with the respective effects such as when the rotation of the reels is started, when the rotation of each reel is stopped, and when a win is determined. Execute In this way, in the pachislot, for example, by executing the effect contents associated with the internal winning combination, an opportunity to know or predict the determined internal winning combination (in other words, a combination of symbols to be aimed at) is provided. Is provided to the player, and the interest of the player can be improved.

<Pachislot structure>
Next, the structure of the pachislo according to the first embodiment of the present invention will be described with reference to FIGS.

[Appearance structure]
FIG. 2 is a perspective view showing an external structure of the pachislot 1.

  As shown in FIG. 2, the pachislot 1 includes an exterior body (game machine main body) 2. The exterior body 2 includes a cabinet 2a that accommodates reels, circuit boards, and the like, and a front door 2b that is attached to the cabinet 2a so that the opening of the cabinet 2a can be opened and closed.

  Inside the cabinet 2a, three reels 3L, 3C, 3R (variable display means, display columns) are provided side by side in a row. Hereinafter, each of the reels 3L, 3C, 3R (main reel) is also referred to as a left reel 3L, a middle reel 3C, and a right reel 3R, respectively. Each of the reels 3L, 3C, 3R includes a reel body formed in a cylindrical shape, and a translucent sheet material mounted on a peripheral surface of the reel body. On the surface of the sheet material, a plurality (for example, 20) of symbols are drawn at predetermined intervals along the circumferential direction (the rotation direction of the reel).

  The front door 2b includes a door body 9, a front panel 10, a waist panel 12, and a pedestal 13. The door body 9 is attached to the cabinet 2a using a hinge (not shown) so as to be openable and closable. The hinge is provided at the left side end of the door body 9 when viewed from the front side (player side) of the pachislot 1.

  The front panel 10 is provided on the upper part of the door body 9. The front panel 10 is formed of a frame-shaped member having an opening 10a. The opening 10a of the front panel 10 is closed by a display device cover 30, and the display device cover 30 is disposed so as to face a display device 11 described later disposed inside the cabinet 2a.

The display device cover 30 is formed of a black translucent synthetic resin. Therefore, the player can visually recognize the video (image) displayed by the display device 11 described later via the display device cover 30. Further, in the present embodiment, the display device cover 30 is formed of a translucent black synthetic resin, thereby suppressing the entrance of external light into the cabinet 2a, and displaying the image (image) displayed by the display device 11. Is clearly visible.

  A lamp group 21 is provided on the front panel 10. The lamp group 21 includes, for example, lamps 21a and 21b provided above the front panel 10 when viewed from the player side. Each lamp constituting the lamp group 21 is configured by an LED (Light Emitting Diode) or the like (refer to an LED group 85 in FIG. 7 described later), and turns on and off the light in a pattern corresponding to the effect contents.

  The waist panel 12 is provided substantially at the center of the door body 9. The waist panel 12 includes a decorative panel on which an arbitrary image is drawn, and a light source (an LED included in an LED group 85 described later) that emits light for illuminating the decorative panel from the back side.

  The pedestal 13 is provided between the front panel 10 and the waist panel 12. The pedestal section 13 includes a symbol display area 4 and various devices to be operated by the player (medal slot 14, MAX bet button 15a, 1 bet button 15b, start lever 16, three stop buttons 17L, 17C, 17R, a settlement button (not shown), and the like.

  The symbol display area 4 is an area that overlaps with the three reels 3L, 3C, and 3R when viewed from the front, and is arranged at a position closer to the player than the three reels 3L, 3C, and 3R. It has a size that allows 3L, 3C, and 3R to be viewed. The symbol display area 4 functions as a display window, and has a configuration in which the reels 3L, 3C, and 3R provided behind the symbol display area 4 can be visually recognized. Hereinafter, the symbol display area 4 is referred to as a reel display window 4.

  When the rotation of the three reels 3L, 3C, 3R provided behind the reel display window 4 is stopped, the reel display window 4 is provided with three consecutively arranged symbols among a plurality of symbols provided on the peripheral surface of each reel. Two symbols are displayed in the frame. That is, when the rotation of the three reels 3L, 3C, and 3R is stopped, one symbol is provided in each of the upper, middle, and lower regions for each reel in the frame of the reel display window 4 (three symbols in total). ) Is displayed (in the frame of the reel display window 4, symbols are displayed in a form of 3 rows × 3 columns). In the present embodiment, a pseudo line (center line) connecting the middle region of the left reel 3L, the middle region of the middle reel 3C, and the middle region of the right reel 3R within the frame of the reel display window 4, It is defined as an active line for determining whether or not a winning has been achieved.

  The reel display window 4 is formed by an opening of a frame member 31 provided on the base 13. A substantially horizontal pedestal region is provided below the frame member 31 defining the reel display window 4. When viewed from the player's side, a medal slot 14 is provided on the right side of the pedestal area, and a MAX bet button 15a and a 1-bet button 15b are provided on the left side.

  The medal insertion slot 14 is provided for receiving a medal dropped by the player into the pachislot 1 from outside. The medals received from the medal slot 14 are used for one game with a predetermined number (for example, three) set as an upper limit, and the medals exceeding the predetermined number are deposited in the pachislot 1. (So-called credit function (game medium storage means)).

  The MAX bet button 15a and the 1-bet button 15b are provided for determining the number of medals stored in the cabinet 2a to be used in one game. Note that a bet button LED (not shown) that lights when a medal can be inserted is provided inside the MAX bet button 15a. The settlement button is provided for pulling out (discharging) medals stored in the pachislot 1 to the outside.

  When the player presses the MAX bet button 15a, medals corresponding to the number of bets (3) per unit game are inserted, and the activated line is activated. On the other hand, one medal is inserted each time the 1-bet button 15b is pressed once. When the one bet button 15b is operated three times, medals corresponding to the number of bets (three) per unit game are inserted, and the activated line is activated.

  Hereinafter, the operation of the MAX bet button 15a, the operation of the 1-bet button 15b, and the operation of inserting medals into the medal insertion slot 14 (the operation of inserting medals for performing a game) are all referred to as “insertion operations”.

  The start lever 16 is provided for starting rotation of all reels (3L, 3C, 3R). The stop buttons 17L, 17C, 17R are provided in association with the left reel 3L, the middle reel 3C, and the right reel 3R, respectively, and each stop button is provided to stop the rotation of the corresponding reel. Hereinafter, the stop buttons 17L, 17C, and 17R are also referred to as a left stop button 17L, a middle stop button 17C, and a right stop button 17R, respectively.

  An information display 6 is provided substantially at the center of the pedestal area in a substantially horizontal plane below the reel display window 4. The information display 6 is covered with a transparent window cover (not shown).

  The information display 6 has a two-digit 7-segment LED for digitally displaying (notifying) information of the number of medals to be paid out to the player as a privilege (hereinafter referred to as “payout number”) to the player. (Hereinafter referred to as "7-segment LED") and information such as the number of medals deposited in the pachislot 1 (hereinafter referred to as "credit number") for digitally displaying (notifying) to the player. A 2-digit 7-segment LED is provided. In the present embodiment, the two-digit seven-segment LED for displaying the number of payout medals is a two-digit seven-segment LED for digitally displaying (notifying) information of error occurrence and error type to the player. Is also used. Therefore, when an error occurs, the display mode of the 2-digit 7-segment LED for displaying the number of medals to be paid is switched from the display mode of the number of medals to the display mode of the information of the error type.

  Further, the information display 6 is provided with an instruction monitor (not shown) for notifying information of a stop operation necessary for displaying a symbol combination corresponding to a combination determined as an internal winning combination along the activated line. ing. The instruction monitor (instruction display) is composed of, for example, a 2-digit 7-segment LED. Then, the instruction monitor informs the player of necessary stop operation information by turning on, blinking or extinguishing the two-digit seven-segment LED in a manner that uniquely corresponds to the information of the stop operation to be notified. I do.

  Here, the mode that uniquely corresponds to the information of the stop operation to be notified is, for example, a case where the push order “1st (the first stop operation is performed on the left reel 3L)” is notified. When the numerical value "1" is displayed on the instruction monitor and the pressing order "2nd (the first stop operation is performed on the middle reel 3C)" is notified, the numerical value "2" is displayed on the instruction monitor and the pressing order is displayed. In the case of notifying "3rd (performing the first stop operation to the right reel 3R)", this means a mode such as displaying a numerical value "3" on the instruction monitor. The notification mode of the stop operation information on the instruction monitor (navigation data determined on the main side described later) will be described later in detail with reference to FIG. 63 described later.

  The information display 6 is electrically connected to a main control board 71 through a door relay terminal plate 68 and a game operation display board 81, as shown in FIG. It is controlled by a main control circuit 90 described later in the control board 71. The above-described control method for the various 7-segment LEDs is dynamic lighting control.

  In the pachislo 1 of the present embodiment, in addition to the instruction monitor controlled by the main control board 71, a configuration for notifying the information of the stop operation using other means controlled by the sub control board 72 is provided. Specifically, the information of the stop operation is notified by a display device 11 described later configured by a projector mechanism 211 and a display unit 212 (see FIG. 3 and FIG. 7 described below).

  When such a configuration is applied, the mode of notification on the instruction monitor and the mode of notification on other units controlled by the sub-control board 72 may be different from each other. In other words, the instruction monitor only needs to notify in a form that uniquely corresponds to the information of the stop operation to be notified, and it is not always necessary to directly notify the information of the stop operation (for example, the numerical value “1” in the instruction monitor). Is displayed, there is a possibility that the content of the notification may not be specified depending on the player, and it cannot be said that the notification is direct.) On the other hand, in the notification on the sub side (sub control board side) by other means such as the display device 11 described later, the information of the stop operation may be directly notified. For example, when the push order “1st” is notified, the instruction monitor displays a numerical value “1” that uniquely corresponds to the notified push order, but other means (for example, the display device 11 or the like) use the left reel 3L. May be directly notified of instruction information for causing the first stop operation to be performed.

  In the pachislot 1 having such a configuration, not only the control of the sub-control board 72 but also the control of the main control board 71 can notify the information of the necessary stop operation according to the internal winning combination. The presence or absence of the notification of the information of such a stop operation may be controlled according to the game state. For example, the information of the stop operation may be reported in the later-described ART game state (see FIG. 14 described later) without reporting the information of the stop operation in the later-described general game state (non-ART game state).

  Further, a sub display device 18 is provided on the left side of the reel display window 4 when viewed from the player side. As shown in FIG. 2, the sub-display device 18 is provided so as to stand substantially vertically from a pedestal region of a substantially horizontal plane of the pedestal portion 13 on the front surface of the door body 9. The sub-display device 18 includes a liquid crystal display and an organic EL (Electro-Luminescence) display, and displays various information.

  A touch sensor 19 is provided on the display surface of the sub display device 18 (see FIG. 7 described later). The touch sensor 19 operates according to a predetermined operation principle such as a capacitance method, and when receiving an operation of a player, outputs a signal corresponding to the operation as touch input information. The pachislo 1 of the present embodiment has a function of enabling the display of the sub-display device 18 to be switched according to a player operation (touch input information output from the touch sensor 19) received via the touch sensor 19. Having. The sub display device 18 is controlled by a later-described sub control board 72 (see FIG. 7 described later) based on touch input information output from the touch sensor 19.

  In the lower part of the door body 9, a medal payout port 24, a medal tray 25, two speaker holes 20L, 20R and the like are provided. The medal payout exit 24 guides medals discharged by driving a medal payout device 51 described below to the outside. The medal tray 25 stores medals discharged from the medal payout exit 24. From the two speaker holes 20L and 20R, sound such as sound effects or music corresponding to the effect contents is output.

[Internal structure]
Next, the internal structure of the pachislot 1 will be described with reference to FIGS. FIG. 3 is a diagram showing the internal structure of the cabinet 2a, and FIG. 4 is a diagram showing the internal structure of the back side of the front door 2b.

  As shown in FIG. 3, the cabinet 2a has a top plate 27a, a bottom plate 27b, left and right side plates 27c and 27d, and a back plate 27e. Then, the display device 11 is disposed in an upper part in the cabinet 2a.

  The display device 11 includes a projector mechanism 211 and a box-shaped projection member 212a onto which the image light projected from the projector mechanism 211 is projected, and performs image display by projection mapping. Specifically, the display device 11 generates image light based on the position (projection distance, angle, and the like) and shape of the projection target member 212a that is a three-dimensional object, and the video light is generated by the projector mechanism 211 by the projector mechanism 211. It is projected on the surface of 212a. By providing such an effect function, an advanced and powerful effect can be performed. Although not shown in FIG. 3, another projected member having a curved display surface is provided on the back side of the box-shaped projected member 212a, and one of the projected members is provided depending on a game state. Is used as a screen on which image light is projected. Therefore, a function (not shown) for switching the projection target member according to the game state is provided in the cabinet 2a.

  A medal payout device (hereinafter, referred to as a hopper device) 51, a medal auxiliary storage 52, and a power supply device 53 are provided in a lower portion of the cabinet 2a.

  The hopper device 51 is attached to the center of the bottom plate 27b in the cabinet 2a. The hopper device 51 has a structure capable of storing a large amount of medals and discharging them one by one. The hopper device 51 pays out medals when the number of stored medals exceeds, for example, 50, or when the settlement button is pressed to execute the settlement of medals. Then, the medals paid out by the hopper device 51 are discharged from the medal payout exit 24 (see FIG. 2).

  The medal auxiliary storage 52 stores medals overflowing from the hopper device 51. The medal auxiliary storage 52 is disposed on the right side of the hopper device 51 when the inside of the cabinet 2a is viewed from the front. The medal auxiliary storage 52 is detachably attached to the bottom plate 27b of the cabinet 2a.

  The power supply device 53 has a power switch 53a and a power supply board 53b (power supply means) (see FIG. 7 described later). The power supply device 53 is disposed on the left side of the hopper device 51 when the inside of the cabinet 2a is viewed from the front, and is attached to the left side plate 27c. The power supply device 53 converts power of an AC voltage of 100 V supplied from a sub power supply device (not shown) into power of a DC voltage required in each unit, and supplies the converted power to each unit.

  A sub-control board case 57 that accommodates a sub-control board 72 (see FIG. 7 described later) is provided above the power supply device 53 in the cabinet 2a. The sub-control board 72 housed in the sub-control board case 57 is mounted with a sub-control circuit 200 (to be described later, see FIG. 10). The sub-control circuit 200 is a circuit that controls execution of an effect by displaying an image or the like. The specific configuration of the sub-control circuit 200 will be described later.

  A sub relay board 61 is provided above the sub control board case 57 in the cabinet 2a. The sub relay board 61 is a relay board on which wiring for connecting a sub control board 72 and a main control board 71 described later is mounted. The sub-relay board 61 is a relay board on which wiring for connecting the sub-control board 72 to a board disposed around the sub-control board 72 and various devices (units) is mounted.

  Although not shown in FIG. 3, a cabinet-side relay board 44 (see FIG. 7 described later) is provided in the cabinet 2a. The cabinet-side relay board 44 includes a main control board 71 (see FIG. 7 described later), a hopper device 51, a medal auxiliary storage switch 74 (see FIG. 7 described later), and a medal payout count switch (not shown). Is a relay board on which wiring for connecting is mounted.

  As shown in FIG. 4, a middle door 41 is provided at a central portion on the back side of the front door 2b, and the reel display window 4 (see FIG. 2) is attached to be openable and closable from the back side. Although not shown in FIG. 4, three reels 3L, 3C and 3R are attached to the reel display window 4 side of the middle door 41, and main control is provided on the opposite side of the middle door 41 to the reel display window 4 side. A main control board case 55 accommodating a board 71 (see FIG. 7 described later) is attached. A stepping motor (not shown) is connected to the three reels 3L, 3C, 3R via gears having a predetermined reduction ratio.

  The main control board 71 housed in the main control board case 55 has a main control circuit 90 described later (see FIG. 9 described later). The main control circuit 90 (main control means) is a circuit for controlling a main flow of the game in the pachislo 1 such as determination of an internal winning combination, rotation and stop of each of the reels 3L, 3C, 3R, and determination of presence or absence of a prize. . In the present embodiment, the main control circuit 90 also controls, for example, a lottery process for determining whether or not the ART has been determined, a process for displaying navigation information on an instruction monitor, and a process for transmitting various test signals. The specific configuration of the main control circuit 90 will be described later.

  Speakers 65L and 65R are provided below the middle door 41 on the back side of the front door 2b. The speakers 65L, 65R are arranged at positions facing the speaker holes 20L, 20R (see FIG. 2), respectively.

  A selector 66 and a door open / close monitoring switch 67 are provided above the speaker 65L. The selector 66 is a device for selecting whether or not the material and the shape of the medal are appropriate, and guides the proper medal inserted into the medal insertion slot 14 to the hopper device 51. A medal sensor (game medium detecting means: not shown) for detecting that a proper medal has passed is provided on a path through which the medal passes in the selector 66.

  The door opening / closing monitoring switch 67 is disposed diagonally below and to the left of the selector 66 when the front door 2b is viewed from the back side. The door opening / closing monitoring switch 67 outputs a security signal for notifying the opening / closing of the front door 2b to the outside of the pachislot 1.

  Although not shown in FIG. 4, a door relay terminal plate 68 is provided below the reel display window 4 in an area opened and closed by the middle door 41 with the front door 2 b on the back surface. 7). The door relay terminal plate 68 includes a main control board 71 in the main control board case 55, various buttons and switches, a sub relay board 61, a selector 66, a game operation display board 81, a first interface board 301 for a testing machine, This is a relay board on which wiring for connecting to each of the tester second interface boards 302 is mounted. The various buttons and switches include, for example, a MAX bet button 15a, a bet button 15b, a door open / close monitoring switch 67, a BET switch 77 described later, a start switch 79, and the like.

<Display example of sub display device>
Here, various display screens displayed on the sub display device 18 will be described with reference to FIGS. 5A to 5E. FIG. 5A is a diagram showing the top screen 221 displayed on the sub display device 18, and FIG. 5B is a diagram showing a menu screen 222 displayed on the sub display device 18. 5C to 5E are diagrams showing game information screens 223, 224, and 225 displayed on the sub display device 18. FIG.

  Various display screens are displayed on the sub display device 18 by a touch operation of the player. As shown in FIGS. 5A to 5E, various display screens including a top screen 221, a menu screen 222, and game information screens 223, 224, and 225 are displayed. The display screen is displayed. These display screens are switched based on a player operation signal received via the touch sensor 19.

  The top screen 221 is an initial screen among the display screens displayed on the sub-display device 18. On the top screen 221, a “MENU” button 221 a and a summary game history 221 b are displayed. The “MENU” button 221a is an operation button for calling the menu screen 222 shown in FIG. 5B. When a predetermined operation (for example, a tap) is performed on the “MENU” button 221a by the player, the menu screen 222 is called. It is. On the top screen 221, a part of the pachislot 1 game history (summary game history) is displayed as the overview game history 221b. In the present embodiment, for example, the number of bonuses, the number of ARTs, and the number of games (the number of games) are displayed as the summary game history 221b.

  The menu screen 222 is a screen that displays a menu that can be displayed on the sub-display device 18. On the menu screen 222, a “return” button 222a, a “register” button 222b, an “explanation” button 222c, and an “array payout” button 222d , A "reach eye" button 222e, a "web site" button 222f and a "volume" button 222g are displayed. The “return” button 222a is an operation button for calling the top screen 221. When the player performs an operation on the “return” button 222a, the top screen 221 is called. The “Registration” button 222b to the “Volume” button 222g are operation buttons for calling a display screen of the corresponding menu content, and when an operation is performed on each button by the player, the corresponding menu content is displayed. The display screen is called.

  For example, when the “registration” button 222 b is operated by the player on the menu screen 222, a registration screen (not shown) for registering the player who is playing the game is called on the display screen of the sub display device 18. In pachislot in recent years, a service for registering a player for each model and managing various information such as the achievement status of a predetermined mission based on the game history of the player so far is widely performed. The registration screen called by the “registration” button 222b is a display screen for registering a player when receiving the provision of this service.

  Further, for example, when the “description” button 222 c is operated by the player on the menu screen 222, the description screen (not shown) of the pachislot 1 is called on the display screen of the sub display device 18. The information displayed on the explanation screen includes, for example, a description about the specifications of the pachislot 1 such as a bonus winning probability and an ART winning probability for each set value, and an introduction description of characters appearing in the performance of the pachislot 1.

  Further, for example, when the “array payout” button 222d is operated by the player on the menu screen 222, the array payout screen (not shown) of the pachislot 1 is called on the display screen of the sub display device 18. On the arrangement payout screen, for example, the correspondence (payout table) between the combination of the symbols determined to be a winning in the pachislot 1 and the privilege at the time of determining the winning, and drawn on each of the reels 3L, 3C, 3R. A symbol row (reel arrangement) and the like are displayed.

  Further, for example, when the “reach eye” button 222 e is operated by the player on the menu screen 222, the reach eye screen (not shown) of the pachislot 1 is called on the display screen of the sub display device 18. On the reach screen, information of a symbol combination called “reach eye” set in the pachislot 1 is displayed. In addition, the symbol combination called "reach eyes" is a symbol combination to which a special privilege is given by displaying the symbol combination along the activated line. The symbol combination corresponding to the abbreviation “Reach eye lip” shown in the content column of the winning operation flag storage area in FIGS. Then, in the present embodiment, when the symbol combination relating to the “reach eye lip” is displayed along the activated line, then, in a state advantageous to the player (for example, a bonus state, normal ART or CT (see FIG. 14 described later) See))).

  Further, for example, when the “Web site” button 222 f is operated by the player on the menu screen 222, the web introduction screen (not shown) of the pachislot 1 is called on the display screen of the sub display device 18. On the WEB introduction screen, for example, a two-dimensional code (for example, a QR code (registered trademark)) indicating a URL of an arbitrary WEB site such as a special WEB site provided for each model of the Pachislot 1 or a WEB site of a manufacturer of the Pachislot 1 is displayed. Is displayed. The player can access the corresponding WEB site by reading the two-dimensional code displayed on the WEB introduction screen with a mobile phone or the like.

  Further, for example, when a “volume” button 222g is operated by a player on the menu screen 222, a volume adjustment screen (not shown) capable of adjusting the volume of the sound output from the speakers 65L and 65R is displayed on the sub display device. 18 is called on the display screen. The player can adjust the volume of the effect sound of the pachislot 1 via the volume adjustment screen.

  Note that the sub display device 18 is provided separately from the above-described display device 11 (the projector mechanism 211 and the display unit 212), and thus can be controlled separately from the display device 11. Therefore, in the pachislo 1 of the present embodiment, the display screen of the sub-display device 18 can be switched by the operation of the player even during the game (during the performance of the display device 11). As a result, for example, when the player wants to know the character appearing in the effect of the display device 11, the player operates the “description” button 222c to call the description screen, and the character Information such as the relationship of the game can be grasped during the game. Also, for example, when the player wants to grasp a symbol to be a guide for winning the rare role during the rotation of the reel when the so-called “rare role” is won during the game, the player: By operating the "array payout" button 222d to call the array payout screen, the reel array can be grasped.

  The game information screens 223, 224, and 225 are display screens that display detailed game history information including an outline game history displayed on the top screen 221 of the game history of the pachislot 1.

  On the game information screen 223, a “return” button 223a, a “MENU” button 223b, a “previous” button 223c, a “next” button 223d, and a game history 223e are displayed. The “return” button 223 a and the “MENU” button 223 b are operation buttons for calling the top screen 221 and the menu screen 222 on the display screen of the sub display device 18, respectively. Display screen is called. The “Previous” button 223c and the “Next” button 223d are operation buttons for switching the game information screen in a predetermined order. When the “Previous” button 223c is operated by the player, the display screen is displayed. Is switched from the game information screen 223 to the game information screen 225, and when the “next” button 223d is operated by the player, the display screen is switched from the game information screen 223 to the game information screen 224. 5C, the number of games (number of games), the number of bonuses, the number of ARTs, and the number of CZ (chance zones) are displayed as the game history 223e.

  On the game information screen 224, a “return” button 224a, a “MENU” button 224b, a “previous” button 224c, a “next” button 224d, and a game history 214e are displayed. The “return” button 224 a and the “MENU” button 224 b are operation buttons for calling the top screen 221 and the menu screen 222 on the display screen of the sub display device 18, respectively. Display screen is called. The “Previous” button 224c and the “Next” button 224d are operation buttons for switching the game information screen in a predetermined order, and when the “Previous” button 224c is operated by the player, the display screen is changed to a game. The screen is switched from the information screen 224 to the game information screen 223, and when the “next” button 224d is operated by the player, the display screen is switched from the game information screen 224 to the game information screen 225. Further, as the game history 224e, the number of times of entry and the number of successes of CZ (chance zone) described later are displayed. As described later, in the present embodiment, three types of CZs, CZ1, CZ2, and CZ3, are provided as CZs. Therefore, as shown in FIG. 5D, the number of times of entry and the number of successes of CZ1 to CZ3 are displayed as the game history 224e.

  On the game information screen 225, a “return” button 225a, a “MENU” button 225b, a “previous” button 225c, a “next” button 225d, and a game history 225e are displayed. The “return” button 225 a and the “MENU” button 225 b are operation buttons for calling the top screen 221 and the menu screen 222 on the display screen of the sub-display device 18, respectively. Display screen is called. The “Previous” button 225c and the “Next” button 225d are operation buttons for switching the game information screen in a predetermined order. When the “Previous” button 225c is operated by the player, the display screen is changed. Is switched from the game information screen 225 to the game information screen 224, and when the “next” button 225d is operated by the player, the display screen is switched from the game information screen 225 to the game information screen 223. In addition, as shown in FIG. 5E, the number of wins of the small win and the probability of win (fraction with a numerator of 1) are displayed as the game history 225e.

  In addition, as a method of switching the display screen displayed on the sub-display device 18, for example, a method of switching based on a tap operation on an operation button displayed on each display screen may be adopted. A method of switching based on a swipe operation on the display screen may be adopted.

<Various switching functions of the display screen of the sub display device>
Next, various switching functions of the display screen of the sub display device 18 in the pachislo 1 of the embodiment will be described.

[Example of transition of display screen of sub display device]
First, with reference to FIGS. 6A and 6B, a transition example (switching mode) of the display screen of the sub-display device 18 in the pachislot 1 of the present embodiment will be described. 6A is a diagram showing a transition example of the display screen of the sub display device 18 in a situation where the player registration state is not set, and FIG. 6B is a view showing a sub display in a situation where the player registration state is set. FIG. 9 is a diagram showing a transition example of a display screen of the device 18.

  In the situation where the player registration state is not set, as shown in FIG. 6A, the display screen of the sub display device 18 transitions between the top screen 221 and the menu screen 222 and from the menu screen 222 and the menu screen 222. The transition can be made only between various display screens that can be performed, and the transition between these display screens is controlled by the sub control board 72 (sub CPU 201 described later). For example, the sub-control board 72 switches between the top screen 221 and the menu screen 222 based on a touch operation (for example, a tap operation on a predetermined button or a swipe operation on a display screen) acquired via the touch sensor 19. Switch the display screen. However, when the player registration state is not set, the sub-control board 72 controls the game information screens 223, 224, and 225 so as not to be displayed. That is, in a situation where the player registration state is not set, the player cannot display the game information screens 223, 224, and 225 on the sub display device 18.

  On the other hand, in the situation where the player registration state is set, as shown in FIG. 6B, the display screen of the sub display device 18 is between the top screen 221 and the menu screen 222, and between the menu screen 222 and the menu screen 222. In addition to the various display screens that can be transitioned from, the transition can be made between the menu screen 222 and the game information screens 223, 224, and 225. It is controlled by the CPU 201). That is, based on the touch operation acquired via the touch sensor 19, the sub-control board 72 controls not only between the top screen 221 and the menu screen 222 but also each of the top screen 221 and the menu screen 222 and the game information screen. The display screen can be switched between 223, 224, and 225. Therefore, in the present embodiment, when the player registration state is set, the player can display the game information screens 223, 224, and 225 on the sub display device 18.

  As shown in FIG. 6B, the order of transition of the display screen among the top screen 221, the menu screen 222, and the game information screens 223, 224, and 225 is arbitrary. Therefore, for example, it may be configured to be able to directly transition from the top screen 221 to the game information screens 223, 224, and 225, or may be changed from the top screen 221 to the game information screens 223, 224, and 225 only via the menu screen 222. A configuration that enables transition is also possible.

  In the pachislot 1 of the present embodiment, a configuration in which transition from the top screen 221 to the game information screens 223, 224, and 225 is possible only via the menu screen 222 (a configuration in which transition from the top screen 221 to the game information screens 223, 224, and 225 is not directly possible) ). In the pachislo 1 of the present embodiment, when the player performs a swipe operation (not a menu selection operation) on the menu screen 222 on the menu screen 222, the display screen is changed from the menu screen 222 to the game information screens 223 and 224. , 225.

  In the present embodiment, the game information screens 223, 224, and 225 are display screens provided completely independently of the menu screen 222. That is, in the pachislot 1 of the present embodiment, information indicating a result of a game in which a player has a strong interest during the game, which is a game history, is used independently as information irrelevant to the result of the game such as a payout arrangement or volume control. To display. In the present embodiment, in a situation where the player registration state is set, the game information screens 223, 224, and 225 can be displayed on the menu screen 222 without the player performing a menu selection operation. . Therefore, in the present embodiment, when the player registration state is set, the player can easily access information game history information desired by the player.

  Further, in the present embodiment, in the menu selection operation on the menu screen 222, the display screen cannot be changed to the game information screens 223, 224, and 225, and the swipe operation on the menu screen 222 (specified in the menu display). If no operation is performed, the display screen cannot be changed to the game information screens 223, 224, and 225. Therefore, in the pachislo 1 of the present embodiment, the swipe operation for changing the display screen to the game information screens 223, 224, and 225 can be handled as a hidden command in a situation where the player registration state is set. In this case, for the player, his / her knowledge of the pachislot 1 allows him to see more detailed game history information that cannot be seen by other players with little knowledge, The game can be played advantageously, and as a result, the player can be expected to play the game positively.

[Display switching function from game information screen to top screen]
The pachi-slot 1 of the present embodiment has a function of changing the display screen of the sub-display device 18 from the game information screens 223, 224, and 225 to the top screen 221 manually or automatically by the player. Specifically, in this embodiment, when the “return” button is operated on the game information screens 223, 224, and 225, the display screen changes from the game information screens 223, 224, and 225 to the top screen 221 (manual transition). function). In the present embodiment, when a predetermined condition is satisfied in a state where the game information screens 223, 224, and 225 are displayed, the display screen is automatically changed to the top screen 221 regardless of the operation of the player. Transition (automatic transition function).

  More specifically, in the pachislot 1, in a state where the game information screens 223, 224, and 225 are displayed, an insertion operation (operation to the MAX bet button 15 a, operation to the 1 bet button 15 b, and When a medal is inserted), the display screen of the sub display device 18 automatically transitions to the top screen 221. Note that in a gaming state (high lip state) in which the probability of the replay combination being determined as the internal winning combination, such as the ART gaming state, medals are automatically inserted due to the operation of the replay game accompanying the replay combination winning. As a result, in the high lip state, the opportunity to display the game information screens 223, 224, and 225 may be limited. Therefore, in the pachislot 1 of the present embodiment, when a medal is automatically inserted by the operation of the replay, the display screen is automatically changed to a game information screen 223 not by a medal insertion operation but by a start operation. , 224, 225 to the top screen 221.

  That is, in the present embodiment, when the replay is activated and the game information screens 223, 224, and 225 are displayed, the display screens are automatically changed to the game information screens 223 and 224 upon the start operation. , 225 to the top screen 221. On the other hand, when the operation of the re-game is not performed, the display screen automatically transitions from the game information screens 223, 224, and 225 to the top screen 221 upon the insertion operation.

[Display switching function from menu content display screen to top screen (or menu screen)]
The pachislo 1 of the present embodiment is configured such that the display screen of the sub display device 18 can be changed by a menu selection operation on the menu screen 222, such as various menu contents display screens (registration screen, explanation screen, array payout screen, reach screen, WEB introduction) Screen and a volume adjustment screen) to have the function of transitioning to the top screen 221 (or the menu screen 222) manually or automatically by the player. Specifically, in this embodiment, when a predetermined button (for example, a “return to TOP” button) is operated on the menu content display screen, the display screen transitions from the menu content display screen to the top screen 221 ( Manual transition function). In the present embodiment, when a specific button (for example, a “return” button) is operated on the menu content display screen, the display screen transitions from the menu content display screen to the menu screen 222 (manual transition). function).

  Further, in the present embodiment, when a predetermined time has elapsed while the menu content display screen is displayed, the display screen is automatically changed to the top screen 221 (or the menu screen 222) regardless of the operation of the player. Transition (automatic transition function). At this time, the predetermined time that triggers automatic transition to the top screen 221 (or the menu screen 222) differs depending on the type of the menu content display screen currently displayed. For example, if the volume adjustment screen for adjusting the volume output from the pachislot 1 is displayed for a long time, the volume may be adjusted to an unintended volume due to an erroneous operation, and other players may be erroneously operated. It can also be uncomfortable. Therefore, the volume adjustment screen is set to automatically transition to the top screen 221 (or the menu screen 222) in a shorter time than the other menu content display screens. On the other hand, the registration screen is set to automatically transition to the top screen 221 (or the menu screen 222) in a longer time than other menu content display screens in order to facilitate the registration of the player. .

  That is, in each menu content display screen, an elapsed time (automatic transition time) that triggers automatic transition to the top screen 221 (or the menu screen 222) is appropriately set according to the type of the menu content display screen. On the volume adjustment screen, an automatic transition time shorter than the other menu content display screens is set, and on the registration screen, an automatic transition time longer than the other menu content display screens is set.

[Menu operation availability selection function]
In the pachislo 1 of the present embodiment, the display screen of the sub-display device 18 is changed from the menu screen 222 to a registration screen, an explanation screen, an array payout screen, a reach eye screen, a WEB introduction screen, and a volume adjustment screen, thereby playing a game. The user can perform various operations according to the menu content display screen, and can confirm various information. It should be noted that a function (a function of selecting whether or not to operate a menu) may be provided such that a function that allows the player to make a menu selection can be restricted in accordance with settings at the game arcade.

  For example, the display screen may not be able to transition from the menu screen 222 to the volume control screen (for example, the “volume” button 222g may not be displayed on the menu screen 222) by a setting on the game store side. In this case, the volume control by the player can be disabled.

<Control system of pachislot>
Next, a control system provided in the pachislo 1 will be described with reference to FIG. FIG. 7 is a circuit block diagram illustrating a configuration of a control system of the pachislo 1.

  The pachislot 1 has a main control board 71 provided on the middle door 41 and a sub control board 72 provided on the front door 2b. Further, the pachislot 1 has a reel relay terminal plate 74, a setting key type switch 54 (setting switch), and a cabinet side relay board 44 connected to the main control board 71. Further, the pachislot 1 includes an external centralized terminal plate 47, a hopper device 51, a medal auxiliary storage switch 75, a reset switch 76, and a power supply device 53 connected to the main control board 71 via the cabinet side relay board 44. Since the configuration of the hopper device 51 has been described above, the description thereof is omitted here.

  The reel relay terminal plate 74 is disposed inside the reel body of each of the reels 3L, 3C, 3R. The reel relay terminal plate 74 is electrically connected to a stepping motor (not shown) of each of the reels 3L, 3C, 3R, and relays a signal output from the main control board 71 to the stepping motor.

  The setting key type switch 54 is provided on the main control board case 55. The setting key type switch 54 is used when changing the setting of the pachislot 1 (setting 1 to setting 6) or when confirming the setting of the pachislot 1.

  The cabinet-side relay board 44 is a relay board on which wiring for connecting the main control board 71, the external centralized terminal board 47, the hopper device 51, the medal auxiliary storage switch 75, the reset switch 76, and the power supply device 53 is mounted. It is. The external concentrated terminal board 47 is provided for outputting signals such as a medal insertion signal, a medal payout signal, and a security signal to the outside of the pachislot 1. The medal auxiliary storage switch 75 is provided in the medal auxiliary storage 52 and detects whether or not the medal auxiliary storage 52 is full of medals. The reset switch 76 is used, for example, when changing the setting of the pachislot 1.

  The power supply device 53 has a power supply board 53b and a power switch 53a connected to the power supply board 53b. The power switch 53a is pressed to supply necessary power to the pachislot 1. The power supply board 53b is connected to the main control board 71 via the cabinet-side relay board 44 and also to the sub-control board 72 via the sub-relay board 61.

  The pachislot 1 has a door relay terminal plate 68, and a selector 66, a door open / close monitoring switch 67, a BET switch 77, a settlement switch 78, which are connected to the main control board 71 via the door relay terminal plate 68. It has a start switch 79, a stop switch board 80, a game operation display board 81, a sub relay board 61, a first interface board 301 for a testing machine, and a second interface board 302 for a testing machine. Since the selector 66, the door open / close monitoring switch 67, and the sub relay board 61 have been described above, the description thereof is omitted here.

  The BET switch 77 (insertion operation detecting means) detects that the MAX bet button 15a or the 1-bet button 15b has been pressed by the player. The settlement switch 78 detects that a settlement button (not shown) has been pressed by the player. The start switch 79 (start operation detecting means) detects that the start lever 16 has been operated by the player (start operation).

  The stop switch board 80 (stop operation detecting means) includes a circuit for stopping the rotating main reel, and a circuit for displaying the main reel that can be stopped by an LED or the like. Further, a stop switch (not shown) is provided on the stop switch substrate 80. The stop switch detects that each of the stop buttons 17L, 17C, 17R has been pressed by the player (stop operation).

  The game operation display board 81 is connected to the information display (7-segment display) 6 and the LED 82. The LEDs 82 are, for example, three LEDs for displaying the number of inserted medals (hereinafter, referred to as “first LEDs” to “1st LED” to “1”) that are lit in accordance with the number of medals inserted in the current game (hereinafter, referred to as “inserted number”). An LED for lighting a mark indicating that medals can be inserted, a mark indicating a game start, a mark for performing a re-game, and the like based on a signal input from the game operation display board 81) And so on. In the first to third LEDs (display means), when one medal is inserted, the first LED is turned on, and when two medals are inserted, the first and second LEDs are turned on, and three medals (game When the (startable number) is inserted, the first to third LEDs are turned on. Since the information display 6 has been described above, the description thereof is omitted here.

  Both the first interface board 301 for the testing machine and the second interface board 302 for the testing machine are relay boards used for outputting various signals related to the game to the testing machine in the pachislot 1 verification test (test shooting test) ( These relay boards are not mounted on the pachislot 1 as a release product for sale. Therefore, the main control circuit 90 of the main control board 71 for sale includes the first interface board 301 for test machine and the test machine. Various electronic components necessary for connection to the second interface board 302 are not mounted.) For example, a test signal for controlling main operations related to the game (for example, internal lottery, reel stop control, and the like) is output through the first interface board 301 for a testing machine, and is determined by the main control board 71, for example. The test signal related to the pushed order navigation is output via the tester second interface board 302.

  The sub control board 72 is connected to the main control board 71 via the door relay terminal plate 68 and the sub relay board 61. The pachislot 1 has a speaker group 84, an LED group 85, a 24h door opening / closing monitoring unit 63, a touch sensor 19, and a display unit 212, which are connected to the sub control board 72 via the sub relay board 61. Since the touch sensor 19 has been described above, the description thereof is omitted here.

  The speaker group 84 includes the speakers 65L and 65R and various speakers (not shown). The LED group 85 includes a lamp group 21 provided on the front panel 10 and a light source that emits light for illuminating the decorative panel of the waist panel 12 from the back side. The 24h door opening / closing monitoring unit 63 stores history information of opening / closing of the middle door 41. In addition, when the middle door 41 is opened, the 24h door opening / closing monitoring unit 63 outputs a signal for performing an error display on the display device 11 to the sub control board 72 (sub control circuit 200). The display unit 212 is configured to include, for example, a projection target member 212a included in the display device 11, and another projection target member having a curved display surface provided on the back side of the projection target member 212a.

  Further, the pachislot 1 has a ROM cartridge substrate 86 and a liquid crystal relay substrate 87 connected to the sub control substrate 72. The ROM cartridge board 86 and the liquid crystal relay board 87 are housed in the sub control board case 57 together with the sub control board 72.

  The ROM cartridge substrate 86 is a substrate for managing various control programs executed by the sub CPU 201, and images (videos), sound (speaker group 84), light (LED group 85), and communication data for effects. . The liquid crystal relay board 87 is a board that relays connection wiring between the sub control board 72, the projector mechanism 211 constituting the display device 11, and the sub display device 18. Since the projector mechanism 211 and the sub display device 18 have been described above, the description thereof is omitted here.

<Main control circuit>
Next, the configuration of the main control circuit 90 mounted on the main control board 71 will be described with reference to FIG. FIG. 8 is a block diagram illustrating a configuration example of the main control circuit 90 of the pachislo 1.

  The main control circuit 90 includes a microprocessor 91, a clock pulse generation circuit 92, a power management circuit 93, and a switching regulator 94 (power supply means).

  The microprocessor 91 is a microprocessor with a security function for gaming machines. In the microprocessor 91 of the present embodiment, as will be described later, various instruction codes (for example, an “LDQ” instruction to be described later) that can be specified on the source program and are unique to the microprocessor 91, and are hereinafter referred to as “main CPU 101”. A special instruction code). In the present embodiment, by using the instruction code dedicated to the main CPU 101, the processing efficiency and the program capacity are reduced. The internal configuration of the microprocessor 91 will be described in detail with reference to FIG. 9 described later, and the instruction code dedicated to the main CPU 101 provided in the microprocessor 91 will be described in detail in various processes executed by the main control circuit described later. I do.

  The clock pulse generating circuit 92 generates a clock pulse signal for operating the main CPU, and outputs the generated clock pulse signal to the microprocessor 91. The microprocessor 91 executes a control program based on the input clock pulse signal.

  The power supply management circuit 93 manages the fluctuation of the power supply voltage of DC 12V supplied from the power supply board 53b (see FIG. 7). Then, the power management circuit 93 outputs a reset signal to the “XSRST” terminal of the microprocessor 91, for example, when the power is turned on (when the power supply voltage exceeds the starting voltage value (10 V) from 0 V). When a power failure occurs (when the power supply voltage falls below the power failure voltage value (10.5 V) from 12 V), a power failure detection signal is output to the “XINT” terminal of the microprocessor 91. That is, the power management circuit 93 outputs a reset signal (start signal) to the microprocessor 91 when the power is turned on, and outputs a power cut detection signal (power cut signal) to the microprocessor 91 when a power cut occurs. (Power failure means).

  The switching regulator 94 is a DC / DC conversion circuit, generates a DC driving voltage (power supply voltage of 5 V DC) of the microprocessor 91, and outputs the generated DC driving voltage to a “VCC” terminal of the microprocessor 91.

<Microprocessor>
Next, an internal configuration of the microprocessor 91 will be described with reference to FIG. FIG. 9 is a block diagram showing the internal configuration of the microprocessor 91.

  The microprocessor 91 includes a main CPU 101, a main ROM (Read Only Memory) 102 (first storage unit), a main RAM (Random Access Memory) 103 (second storage unit), an external bus interface 104, and a clock circuit 105. , A reset controller 106, an arithmetic circuit 107, a random number circuit 110, a parallel port 111, an interrupt controller 112, a timer circuit 113, a first serial communication circuit 114, and a second serial communication circuit 115. . These components constituting the microprocessor 91 are connected to each other via a signal bus 116.

  The main CPU (Central Processing Unit) 101 executes various control programs based on the clock pulse generated by the clock circuit 105, and controls the entire game operation. Here, reel stop control will be described as an example of the control operation of the main CPU 101.

  After detecting the reel index, the main CPU 101 counts the number of times a pulse is output to the stepping motor of each of the reels 3L, 3C, 3L (main reel). Accordingly, the main CPU 101 manages the rotation angle of each reel (mainly, how many symbols the reel has rotated). The reel index is information indicating that the reel has made one rotation. The reel index includes, for example, an optical sensor having a light emitting unit and a light receiving unit, and a detection piece provided at a predetermined position on each reel and interposed between the light emitting unit and the light receiving unit by rotation of each main reel. It is detected by a provided reel position detection unit (not shown).

  Here, the management of the rotation angle of each of the reels 3L, 3C, 3L (main reel) will be specifically described. The number of pulses output to the stepping motor is counted by a pulse counter provided in the main RAM 103. The symbol counter provided in the main RAM 103 is incremented by one each time the pulse counter outputs a predetermined number of pulses required for rotation of one symbol. The symbol counter is provided for each reel. The value of the symbol counter is cleared when a reel index is detected by a reel position detector (not shown).

  That is, in the present embodiment, by managing the symbol counter, it is managed how many symbols have been rotated since the reel index was detected. Therefore, the position of each symbol on each reel is detected based on the position where the reel index is detected.

  The main ROM 102 stores various control programs executed by the main CPU 101, various data tables, data for transmitting various control commands (commands) to the sub control circuit 200, and the like. The main RAM 103 is provided with a storage area for storing various data such as an internal winning combination determined by executing the control program. The internal configuration (memory map) of the main ROM 102 and the main RAM 103 will be described later in detail with reference to FIG.

  The external bus interface 104 is used to electrically connect the microprocessor 91 to an external signal bus (not shown) to which various components (for example, respective reels) provided outside the microprocessor 91 are connected. An interface circuit. The clock circuit 105 includes, for example, a frequency divider (not shown) and the like. The clock circuit 105 receives the clock pulse signal for operating the CPU input from the clock pulse generation circuit 92 by using other components (for example, the timer circuit 113). It is converted into a clock pulse signal of the frequency to be used. Note that the clock pulse signal generated by the clock circuit 105 is also output to the reset controller 106.

  The reset controller 106 resets an IAT (Illegal Address Trap) and a WDT (watchdog timer) based on a reset signal input from the power management circuit 93. The operation circuit 107 includes a multiplication circuit and a division circuit. For example, when executing a later-described “MUL (multiplication)” instruction (see FIG. 93B described later) on the source program, the arithmetic circuit 107 executes a multiplication process based on the “MUL” instruction.

  The random number circuit 110 generates a random number in a predetermined range (for example, 0 to 65535 or 0 to 255). Although not shown, the random number circuit 110 stores a random number register 0 for obtaining a 2-byte hard latch random number, random number registers 1 to 3 for obtaining a 2-byte soft latch random number, and a 1-byte soft latch random number. It comprises random number registers 4 to 7 for obtaining. The main CPU 101 extracts one value from random numbers in a predetermined range generated by the random number circuit 110, for example, as a random number value for internal lottery. The parallel port 111 is a port (memory map I / O) for signals input / output between the microprocessor 91 and various circuits (for example, the power management circuit 93) provided outside the microprocessor 91. . The parallel port 111 is also connected to a random number circuit 110 and an interrupt controller 112. The start switch 79 is connected to one of the input ports PI0 to PI4 of the parallel port 111, and the latch signal is sent from the parallel port 111 to the random number register 0 of the random number circuit 110 at the timing when the start switch 79 is turned on (on edge). Is output. Then, in the random number circuit 110, the random number register 0 is latched by the input of the latch signal, and a 2-byte hard latch random number is obtained.

  The interrupt controller 112 performs an interrupt process by the main CPU 101 based on a power failure detection signal input from the power management circuit 93 via the parallel port 111 or a timeout signal input at a period of 1.1172 ms from the timer circuit 113. Control the execution timing. When a power interruption detection signal is input from the power management circuit 93 or a time-out signal is input from the timer circuit 113, the interrupt controller 112 sends an interrupt request signal indicating an interrupt processing start command to the main CPU 101. Output to The main CPU 101 performs an input port check process, a reel control process, a communication data transmission process, a 7-segment LED drive process, a timer, based on an interrupt request signal input from the interrupt controller 112 in response to a timeout signal from the timer circuit 103. Various interrupt processing such as update processing (see FIG. 158 described later) is performed.

  The timer circuit 113 (PTC) operates on a clock pulse signal generated by the clock circuit 105 (a clock pulse signal having a frequency obtained by dividing a clock pulse signal for operating the main CPU by a frequency divider (not shown)) ( Count elapsed time). Then, the timer circuit 113 outputs a timeout signal (trigger signal) to the interrupt controller 112 at a period of 1.1172 msec.

  The first serial communication circuit 114 is a circuit that controls a serial transmission operation when transmitting data (various control commands (commands)) from the main control board 71 to the sub control board 72. The second serial communication circuit 115 is a circuit that controls a serial transmission operation when data is transmitted from the main control board 71 to the second interface board 302 for a tester.

<Sub-control circuit>
Next, the configuration of the sub-control circuit 200 (sub-control unit) mounted on the sub-control board 72 will be described with reference to FIG. FIG. 10 is a block diagram illustrating a configuration example of the sub-control circuit 200 of the pachi-slot 1.

  The sub-control circuit 200 is electrically connected to the main control circuit 90, and performs processing such as determination and execution of effect contents based on a command transmitted from the main control circuit 90. The sub control circuit 200 basically includes a sub CPU 201, a sub RAM 202, a rendering processor 203, a drawing RAM 204, and a driver 205.

  The sub CPU 201 is connected to the ROM cartridge substrate 86. The driver 205 is connected to the liquid crystal relay board 87. That is, the driver 205 is connected to the projector mechanism 211 and the sub-display device 18 via the liquid crystal relay board 87.

  The sub CPU 201 controls output of video, sound, and light in accordance with a control program stored in the ROM cartridge substrate 86 in response to a command transmitted from the main control circuit 90. The ROM cartridge substrate 86 basically includes a program storage area and a data storage area.

  A control program executed by the sub CPU 201 is stored in the program storage area. For example, the control program includes a main board communication task for controlling communication with the main control circuit 90 and an effect registration for extracting random number values for effect, determining and registering effect contents (effect data). Various programs for executing tasks are included. Further, the control program includes a drawing control task for controlling display of an image on the display device 11 based on the determined effect contents, a lamp control task for controlling light output by a light source such as the LED group 85, and a sound from the speaker group 84. Various programs for executing a voice control task or the like for controlling the output of the program are also included.

  The data storage area includes a storage area for storing various data tables, a storage area for storing effect data constituting each effect content, and a storage area for storing animation data related to video creation. The data storage area also includes a storage area for storing sound data relating to BGM and sound effects, a storage area for storing lamp data relating to a light on / off pattern, and the like.

  The sub RAM 202 is provided with a storage area for registering the determined effect contents and effect data, and a storage area for storing various data such as a sub flag (internal winning combination) transmitted from the main control circuit 90.

  The sub CPU 201, the rendering processor 203, the drawing RAM (including the frame buffer) 204, and the driver 205 create an image according to the animation data specified by the contents of the effect, and display the created image on the display device 11 (projector mechanism 211) and / or Alternatively, it is displayed on the sub display device 18. The display device 11 (projector mechanism 211) and the sub-display device 18 are individually controlled by the sub-control board 72.

  Further, the sub CPU 201 causes the speaker group 84 to output sounds such as BGM according to the sound data designated by the effect contents. Further, the sub CPU 201 controls turning on and off of the LED group 85 according to the lamp data specified by the effect contents.

<Various registers of main CPU>
Next, various registers of the main CPU 101 will be described with reference to FIG. FIG. 11 is a schematic configuration diagram of various registers included in the main CPU 101.

  The main CPU 101 includes, as main registers, an accumulator A (hereinafter, referred to as “A register”), a flag register F (flag register), a general-purpose register B (hereinafter, referred to as “B register”), and a general-purpose register C (hereinafter, “ C register), general purpose register D (hereinafter referred to as "D register"), general purpose register E (hereinafter referred to as "E register"), general purpose register H (hereinafter referred to as "H register"), and general purpose register L (hereinafter referred to as "H register"). , "L register"). The main CPU 101 also includes, as sub registers, an accumulator A ', a flag register F', a general purpose register B ', a general purpose register C', a general purpose register D ', a general purpose register E', a general purpose register H ', and a general purpose register L'. As a general-purpose register. Each register is composed of a 1-byte register.

  In this embodiment, the B register and the C register are used as a pair register (hereinafter, referred to as a “BC register”), and the D register and the E register are used as a pair register (hereinafter, referred to as a “DE register”). Further, in the present embodiment, the H register and the L register are used as a pair register (hereinafter, referred to as “HL register”).

  As shown in FIG. 11, predetermined flag information indicating the result of the arithmetic processing and the like is set in each bit of the flag registers F and F '. For example, data (zero flag) indicating whether or not the operation result is “0” in the operation result determination process is set in bit 6 (D6). Specifically, when the operation result is “0”, data “1” is set in bit 6, and when the operation result is not “0”, data “0” is set in bit 6. Then, in the calculation result determination process, the main CPU 101 makes a determination (YES / NO) with reference to the bit 6 data “0” / “1”.

  Further, the main CPU 101 has an extension register Q (hereinafter, referred to as “Q register”). The Q register is composed of a 1-byte register. In the present embodiment, as will be described later in various processing flows, instruction codes dedicated to various main CPUs 101 for specifying addresses using the Q register are provided on the source program. , The efficiency of processing and the capacity of the main ROM 102 are reduced. In addition, in various instruction codes dedicated to the main CPU 101 for specifying an address using the Q register, the upper register address data (address value) of the address is stored in the Q register. Note that “F0H” is set in the Q register as an initial value immediately after the main CPU 101 is reset. Also, in the “LD Q, n (8-bit data)” instruction using the Q register, the value of the Q register is changed by setting an arbitrary 1-byte data in “n” and executing the instruction. be able to.

  Further, the main CPU 101 includes an interrupt page address register I and a memory refresh register R composed of 1-byte registers, and an index register IX and an index register IY composed of 2-byte registers. , A stack pointer SP and a program counter PC as dedicated registers.

<Internal Configuration of Main ROM and Main RAM (Memory Map)>
Next, an internal configuration of the main ROM 102 and the main RAM 103 included in the main control circuit 90 (microprocessor 91) (hereinafter, referred to as “memory map”) will be described with reference to FIGS. 12A to 12C. 12A is a diagram showing a memory map of the entire memory, FIG. 12B is a diagram showing a memory map of the main ROM 102, and FIG. 12C is a diagram showing a memory map of the main RAM 103.

  In the memory map of the entire memory of the main control circuit 90 (microprocessor 91), as shown in FIG. 12A, the memory area of the main ROM 102, the memory area of the main RAM 103, the internal register area, The XCS decode areas are arranged at predetermined addresses in this order with the non-use area interposed therebetween.

  In the memory map of the main ROM 102, as shown in FIG. 12B, a program area, a data area, a non-standard area, a trademark recording area, a program management area, and a security setting area are arranged from the top (0000H) of the address of the main ROM 102. In this order, they are arranged at predetermined addresses.

  In the program area, control programs for various processes executed by the main CPU 101 in various control processes related to the playability of the game performed by the player are stored. In the data area, various data used by the main CPU 101 (for example, a data table such as an internal lottery table, Data for transmitting a control command). In other words, the game ROM area (game storage area) consisting of the program area and the data area is required for the control processing (processing related to the playability) related to the playability of the game actually performed by the player in the amusement store. Various programs and various data are stored.

  Further, in the non-defined area, control programs and data of various processes not directly related to the playability of the game performed by the player (processes which do not affect the playability) are stored. For example, programs and data used in a pachislot 1 verification test (test shot test), control programs and data used in a checksum generation process at the time of power failure or a sum check process at the time of power restoration, and an anti-fraud program And the data necessary for it are stored in the non-defined area.

  In the memory map of the main RAM 103, as shown in FIG. 12C, the game RAM area (predetermined storage area, game temporary storage area) and the non-standard RAM area (non-standard temporary area) start from the top (F000H) of the address of the main RAM 103. Storage areas) are arranged at predetermined addresses in this order.

  The game RAM area is provided with a work area and a stack area for temporarily storing various data such as an internal winning combination determined by execution of a control program related to the playability of the game performed by the player. . Each of the various data is stored in a work area at a predetermined address in the game RAM area.

  In the non-defined RAM area, a non-defined work area serving as a work area for various processes not directly related to the playability of a game performed by a player and a non-defined stack are provided. In the present embodiment, various processes not directly related to the playability of the game performed by the player, such as a sum check process, are executed using the non-defined RAM area.

  As described above, in the pachislo 1 of the present embodiment, in the main ROM 102, various programs and various data (tables) used for various processes not directly related to the playability of the game performed by the player are stored in the main ROM 102. The data is stored in a non-defined ROM area (non-defined storage area) arranged at an address different from the ROM area. In addition, various processes that are not directly related to the playability of the game performed by the player are performed in the main RAM 103 by using the non-defined RAM area arranged at an address different from the game RAM area. .

  In such a configuration of the main ROM 102, programs and data that are unnecessary for the game itself to be actually played by the player are placed in a ROM area (a non-defined ROM area) in which a program or the like cannot be arranged according to the conventional rules. can do. Therefore, in the present embodiment, it is possible to avoid pressure on the capacity of the gaming ROM area.

<Game state transition flow>
Next, various game states managed by the main control circuit 90 (main CPU 101) of the pachi-slot 1 of the present embodiment and their transition flows will be described with reference to FIGS. FIG. 13A is a transition flow chart of the basic gaming state of the pachislot 1, and FIG. 13B is a table summarizing the transition conditions of the gaming state. FIG. 14A is a transition flow diagram of the gaming state in consideration of the presence / absence of the operation of the notification (ART) function, and FIG. 14B is a table summarizing the transition conditions of the gaming state.

[Basic game state transition flow]
In the pachislo 1 of the present embodiment, a big bonus (hereinafter, referred to as “BB”) is provided as a type of bonus game. BB is an accessory continuous operation device related to a regular bonus (hereinafter referred to as “RB”) called a first-class special accessory, and continuously operates RB.

  Therefore, in the present embodiment, the main control circuit 90 manages the gaming state based on the presence / absence of winning / operating (winning) of the bonus combination. More specifically, as shown in FIG. 13A, the main control circuit 90 determines whether or not a bonus combination (internal winning combination of names “F_BB1” and “F_BB2” described later) has been won / activated (winning). It manages three types of gaming states called a bonus non-winning state, an inter-flag state, and a bonus state.

  The bonus non-winning state is a state where the bonus is not won and the bonus is not activated (winning), and the bonus state is a state where the bonus is activated. Further, in the present embodiment, when the bonus combination is determined as the internal winning combination, a state occurs in which the bonus combination is carried over as the internal winning combination over a plurality of games until the bonus is won. The inter-flag state is a state in which the bonus combination is carried over as an internal winning combination, that is, a state in which the bonus combination is won and the bonus is not activated.

  The presence or absence of a bonus combination is determined by data stored in a hit request flag storage area (see FIGS. 28 to 30 described later) and a carryover combination storage area (see FIG. 31 described later) provided in the main RAM 103. It is managed based on. Whether or not a bonus operation (winning) is performed is managed based on data stored in a later-described gaming state flag storage area (see FIG. 32 described later) provided in the main RAM 103.

  In the present embodiment, as shown in FIG. 13A, in the gaming state in which the bonus is not operated (the bonus non-winning state and the state between the flags), the type of the internal winning combination related to the replay and the winning probability are different from each other. There are provided six types of states from an RT0 gaming state to an RT5 gaming state (hereinafter, referred to as “RT0 state” to “RT5 state”, respectively). The RT0 state, the RT2 state, and the RT5 state are gaming states in which the probability that the replay combination is determined as the internal winning combination is low, and the RT1 state is that the probability that the replay combination is determined as the internal winning combination is medium. Is a game state with a medium probability. The RT3 state and the RT4 state are gaming states in which the probability that the replay combination is determined as the internal winning combination is high. In the present embodiment, the RT state in the bonus non-winning state is any one of the RT0 state to the RT4 state, and the RT state in the inter-flag state is the RT5 state.

  Therefore, in the present embodiment, in the gaming state where the bonus is not operated (the bonus non-winning state and the state between the flags), the main control circuit 90 further determines the internal winning combination related to the replay and the winning probability thereof. Thus, six types of statuses, that is, the RT1 status to the RT5 status are also managed.

  The RT0 state to the RT5 state are managed based on data stored in a later-described game state flag storage area (see FIG. 32 described later) provided in the main RAM 103. Specifically, the pachislo 1 of the present embodiment is provided with flags indicating five RT states, that is, an RT1 state flag to an RT5 state flag. The on / off states of these flags are managed by the main RAM 103 so that the RT state is controlled. Is managed. Then, the main control circuit 90 specifies the RT state corresponding to the RT state flag that is in the ON state as the current RT state. When all the RT state flags are in the OFF state, the main control circuit 90 specifies that the current RT state is the RT0 state.

  As shown in FIGS. 13A and 13B, when a bonus combination (internal winning combinations of names “F_BB1” and “F_BB2” described later) is determined as an internal winning combination in the bonus non-winning state (if the transition condition (1) is satisfied). The main control circuit 90 shifts the gaming state from the bonus non-winning state to the flag state. When the bonus combination is won in the inter-flag state (when the transition condition (2) is satisfied), the main control circuit 90 transitions the gaming state from the inter-flag state to the bonus state.

  Further, when medals exceeding the specified number (216) are paid out in the bonus state and the bonus state ends (if the transition condition (3) is satisfied), the main control circuit 90 changes the gaming state from the bonus state to the RT1 state ( (Bonus non-winning state).

  In the RT1 state, when 20 games have elapsed (when the transition condition (4) is satisfied), the main control circuit 90 transitions the gaming state from the RT1 state to the RT0 state. Further, in the RT1 state, if a symbol combination (refer to FIG. 28 described later) related to the abbreviation “bell spilled eyes” is displayed on the activated line before 20 games elapse (if the transition condition (5) is satisfied). The main control circuit 90 shifts the gaming state from the RT1 state to the RT2 state.

  In the RT0 state, when the symbol combination related to the abbreviation "bell spilled eyes" is displayed on the activated line (if the transition condition (5) is satisfied), the main control circuit 90 transitions the gaming state from the RT0 state to the RT2 state. Let it. In the RT2 state, when the symbol combination (refer to FIG. 28 described later) related to the abbreviation “RT3 transition lip” is displayed on the activated line (if the transition condition (6) is satisfied), the main control circuit 90 sets the gaming state. A transition is made from the RT2 state to the RT3 state.

  In the RT3 state, when the symbol combination (refer to FIG. 28 described later) related to the abbreviation “RT4 shift lip” is displayed on the activated line (if the shift condition (7) is satisfied), the main control circuit 90 changes the game state. The state is shifted from the RT3 state to the RT4 state. Further, in the RT3 state, when a symbol combination (refer to FIG. 28 described later) relating to the abbreviation “bell spilled eyes” or “RT2 transition lip” is displayed on the activated line (if the transition condition (8) is satisfied), the main The control circuit 90 shifts the gaming state from the RT3 state to the RT2 state. Further, in the RT4 state, when the symbol combination related to the abbreviation "bell spilled eyes" or "RT2 transition lip" is displayed on the activated line (if the transition condition (8) is satisfied), the main control circuit 90 sets the game state The game state is shifted from the RT4 state to the RT2 state.

  In the symbol combination related to the abbreviation “bell spilled eyes”, an internal winning combination (small role) related to a name “F_3 choice bell_1st”, “F_3 choice bell_2nd” or “F_3 choice bell_3rd” to be described later is determined. Further, the combination of symbols is displayed when the order of the stop operation is incorrect for the pressing order determined for each type of the small combination (see FIG. 24 described later). For the symbol combination related to the abbreviation “RT2 shift lip”, an internal winning combination (replay combination) related to a name “F_maintenance lip_1st”, “F_maintenance lip_2nd” or “F_maintenance lip_3rd” to be described later is determined, and This is a combination of symbols displayed when the order of the stop operation is incorrect for the pressing order determined for each type of the replay combination.

  In the symbol combination related to the abbreviation “RT3 shift lip”, an internal winning combination (replay combination) related to a name “F_RT3 lip — 1st”, “F_RT3 lip — 213”, “F_RT3 lip — 231”, or “F_RT3 lip — 3rd” to be described later is determined. The symbol combination displayed when the order of the stop operation is correct for the pressing order determined for each type of the replay combination. The symbol combination related to the abbreviation “RT4 shift lip” has an internal winning combination (replay role) related to a name “F_RT4 lip — 123”, “F_RT4 lip — 132”, “F_RT4 lip — 2nd”, or “F_RT4 lip — 3rd” described later. This is a combination of symbols that is determined and displayed when the order of the stop operation is correct for the pressing order determined for each type of the replay combination.

[Transition flow of game state in consideration of presence / absence of notification (ART) function]
In the present embodiment, the main control circuit 90 (main CPU 101) determines whether or not a function (ART function) of notifying a stop operation advantageous to the player is activated. Therefore, in the present embodiment, the activated / inactivated state of the ART function in the bonus inactivated state is also managed as the gaming state.

  In the pachislo 1 of the present embodiment, as shown in FIG. 14A, in the non-bonus operation state, the main control circuit 90 separates the “general game state” and the “ART game state” based on the presence / absence of notification (ART). Is managed as a gaming state. That is, in the management of the game state in consideration of the presence / absence of the notification (ART), as shown in FIG. 14A, the main control circuit 90 classifies the game state into the large categories of “bonus state”, “general game state”, and “ART game state”. The three types of game states are managed.

  Note that the general game state is basically a game state (non-ART) in which information of a stop operation advantageous to the player is not notified, and is a game state disadvantageous to the player. The general gaming state is any one of the RT0 to RT4 states, and is an ART non-winning gaming state.

  On the other hand, the ART gaming state is a gaming state in which information of a stop operation advantageous to the player is notified, and is an advantageous gaming state for the player. The ART gaming state is basically an RT4 state and a gaming state in which an ART winning is performed. In this embodiment, after the ART winning, when the RT state shifts to the RT4 state, the ART game is started.

  Further, in the present embodiment, as shown in FIG. 14A, two types of states called “normal game state” and “CZ (chance zone)” are provided as the general game state.

  The normal game state is the most disadvantageous game state for the player, but in the game in the normal game state, a lottery transition to CZ is performed. Then, as shown in FIGS. 14A and 14B, in the game in the normal game state, when the transfer lottery to CZ is won (when the transfer condition (A) is satisfied), the main control circuit 90 changes the game state to the normal game state. From CZ to CZ.

  CZ is a gaming state (chance zone) in which the degree of expectation for the transition to the ART gaming state is high, and in the game in CZ, the transition to ART is performed by lottery. Then, as shown in FIGS. 14A and 14B, in the game in CZ, if the transfer lottery to ART is not won (if the transfer condition (B) is satisfied), the main control circuit 90 changes the game state. , CZ to the normal game state. On the other hand, in the game in CZ, when the lottery transition to ART is won (when the transition condition (C) is satisfied), the main control circuit 90 transitions the gaming state from CZ to the ART gaming state. At this time, although not shown in FIG. 14A, the main control circuit 90 shifts the game state from the CZ to the ART game state (normal ART or CT described later) via an ART preparation state described later.

  As described above, the ART gaming state is started when the RT state shifts to the RT4 state after the ART winning. As shown in FIG. 13A, the RT4 state shifts from the RT0 to RT2 states via the RT3 state, so that the ART gaming state is not immediately started even after the ART winning. Therefore, in the pachi-slot 1 of the present embodiment, the game state during the period from the winning of the ART to the transition of the RT state to the RT4 state is set to the ART preparation state. Then, in the game in the ART preparation state, information of a stop operation necessary for shifting the RT state to the RT4 state is notified.

  Further, in the present embodiment, as shown in FIG. 14A, two types of states called “normal ART” and “CT (additional chance)” having different game properties are provided as ART game states.

  The normal ART is a stop operation that is advantageous to the player during a predetermined number of games (for example, a stop operation for displaying a symbol combination in which a large number of medals are paid out or a stop operation necessary for maintaining the RT4 state). Is a game state to be notified. In addition, in a game during a normal ART, a lottery for transition to CT is performed.

  The CT is a game state in which a stop operation advantageous to the player is notified and a continuation period of the normal ART can be added for a specific period (a period of one set of 8 games), and functions as an addition chance zone. Is a game state. In addition, during the CT, the game is usually played without exhausting the duration of the ART. In addition, the playability during CT will be described later in detail with reference to FIGS. 52A to 52C.

  As shown in FIGS. 14A and 14B, in the game during the normal ART, when the transition lottery to the CT is won (when the transition condition (D) is satisfied), the main control circuit 90 changes the game state from the normal ART to the CT. The game state is shifted. Further, in the normal ART, when the duration of the normal ART ends (when the transition condition (E) is satisfied), the main control circuit 90 changes the gaming state from the normal ART to the general gaming state (normal gaming state or CZ). Migrate. In the present embodiment, the duration of the normal ART is managed based on the number of games. However, the present invention is not limited to this. The method of managing the duration of the normal ART is arbitrary. For example, the duration of the normal ART may be managed by the number of medals paid out during the normal ART or the difference number, or the number of times (navigation times) informing that affects the payout of medals during the normal ART. May be managed.

  As shown in FIGS. 14A and 14B, in the game during CT, when the duration of CT (eight games per set) ends (when the transition condition (F) is satisfied), the main control circuit 90 changes the game state to CT. To normal ART.

  Further, as shown in FIG. 14A, when the bonus combination is won in the normal game state (normal game state or CZ) or the ART game state (normal ART or CT), the transition condition (2) described in FIGS. 13A and 13B is used. Is established), the main control circuit 90 shifts the gaming state from the general gaming state or the ART gaming state to the bonus state.

  In the game in the bonus state, as described above, the lottery for shifting to the ART is performed. In the game in the bonus state, when the lottery for shifting to the ART is non-winning (if the transition condition (G) is satisfied). The main control circuit 90 shifts the gaming state from the bonus state to the normal gaming state (normal gaming state or CZ). However, when the game has shifted from the ART gaming state (normally ART or CT) to the bonus state, the main control circuit 90 sets the gaming state to the bonus state, even if the lottery transition to the ART is not won. The state is shifted from the bonus state to the ART game state (normally ART or CT). On the other hand, in the game in the bonus state, if the transition lottery to the ART is won (the transition condition (H) is satisfied), the main control circuit 90 changes the gaming state from the bonus state to the ART gaming state (normal ART or CT). Migrate. As described above, at the end of the bonus state, the RT state shifts to the RT1 state. Therefore, when shifting the gaming state from the bonus state to the ART gaming state, the main control circuit 90 sets the gaming state to the ART state. A transition is made to the ART gaming state via the preparation state.

<Configuration of data table stored in main ROM>
Next, the configuration of various data tables stored in the main ROM 102 will be described with reference to FIGS. It should be noted that various data tables used in various lotteries relating to the game characteristics (CZ, normal ART, CT game characteristics) in the general game state and the ART game state will be separately described later together with the description of the game characteristics. .

[Symbol arrangement table]
First, the symbol arrangement table will be described with reference to FIG. The symbol arrangement table stores the position of each symbol in the rotation direction of each of the left reel 3L, the center reel 3C, and the right reel 3R, and data (hereinafter, a symbol code (see FIG. 15) that specifies the type of the symbol arranged at each position. ) Is defined.)

  In the symbol arrangement table, when the reel index is detected, the position of the symbol located in the middle area of each reel in the frame of the reel display window 4 is defined as “0”. Then, in each reel, the order corresponding to the value of the symbol counter is determined in the order in which the symbols move in the reel rotation direction (the direction from the symbol position "19" to the symbol position "0" in FIG. 15) based on the symbol position "0". “0” to “19” are assigned to each symbol as a symbol position.

  That is, by referring to the value of the symbol counter (“0” to “19”) and the symbol arrangement table, the reels are displayed in the upper, middle, and lower areas of each reel in the frame of the reel display window 4. It is possible to specify the type of symbol that is present. In this embodiment, the symbols "white 7", "blue 7", "upper Chile 1", "upper Chile 2", "lower Chile", "replay", "hat", "cactus 1", Ten kinds of patterns of "cactus 2" and "cactus 3" are used.

  In the present embodiment, as shown in the symbol code table, "00000001" is assigned as data to the symbol "white 7" (symbol code 1), and the symbol "blue 7" (symbol code 2) is assigned to the symbol. “00000010” is assigned as data. “00000011” is assigned as data to the symbol “Chile 1” (symbol code 3), and “00000001” is assigned to the symbol “Chile 2” (symbol code 4).

  "00000101" is assigned as data to the symbol "Chile lower" (symbol code 5), and "00000110" is assigned to the symbol "Replay" (symbol code 6). "00000011" is assigned as data to the symbol "hat" (symbol code 7), and "00001000" is assigned to the symbol "cactus 1" (symbol code 8). Also, the symbol “cactus 2” (symbol code 9) is assigned data “000010001”, and the symbol “cactus 3” (symbol code 10) is assigned data “000001010”.

[Internal lottery table]
Next, with reference to FIGS. 16 and 17, an internal lottery table referred to when determining an internal winning combination will be described. FIG. 16 is an internal lottery table referred to in each of the RT0 state to the RT4 state. FIG. 17A is an internal lottery table referred to in the RT5 state, and FIG. 17B is an internal lottery table referred to in the bonus state.

  The internal lottery table is provided for each gaming state, and defines the correspondence between various internal winning combinations and a lottery value when each internal winning combination is determined. The lottery value is defined for each setting (settings 1 to 6) for adjusting an expected value of internal winning such as a bonus combination or a small combination set in advance. This setting is changed using, for example, the reset switch 76 and the setting key type switch 54 (see FIG. 7).

  In the internal lottery process of the present embodiment, first, the random number register 0 of the random number circuit 110 converts a random number value extracted from a predetermined numerical value range (for example, 0 to 65535) in correspondence with each internal winning combination. The addition is performed sequentially with the specified lottery value. Next, it is determined whether or not the lottery result (lottery value + random number value) exceeds 65535 (whether or not the lottery result overflows). If the lottery result exceeds 65535 in the predetermined internal winning combination, it is determined that the internal winning combination has been won. In the internal lottery process of the present embodiment, an example has been described in which the lottery value is added to the extracted random number value to perform the lottery. However, the present invention is not limited to this, and the lottery value is subtracted from the random number value. It may be determined whether or not the subtraction result (lottery result) is less than “0” (whether or not the lottery result has underflowed) to determine the internal lottery winning / non-winning.

  Therefore, in the internal lottery process of the present embodiment, the probability of being determined is higher for an internal winning combination having a larger numerical value defined as a lottery value. Note that the winning probability of each internal winning combination can be represented by “the lottery value specified for each winning number / the number of all random numbers that may be extracted (random number denominator: 65536)”.

  In the internal lottery tables referred to in each of the RT0 state to the RT4 state, as shown in FIG. 16, basically, the type of the replay combination determined as the internal winning combination and the winning probability are determined according to the type of the RT state. Changes. For example, the replay combination of the names “F_Chililip (No. 25)” to “F_reach-eye lip D (No. 31)” is not determined as the internal winning combination in the RT0 state to the RT3 state, and is in the RT4 state. Only the internal winning combination is determined. In the pachi-slot 1 of the present embodiment, during the RT4 state, the replay combination having the names “F_Chililip (No. 25)” to “F_reach eye lip D (No. 31)” is determined as the internal winning combination. In this case, specific control (flag conversion described later) is performed. This flag conversion will be described later in detail.

  Also, as shown in FIG. 16, in the RT0 state to the RT3 state, the internal winning combinations of the names “F_reach-eye lip A” to “F_reach-eye lip D” are related to the name “F_BB1” or “F_BB2”. Although it may be determined in duplicate with the bonus combination (see Nos. 3 to 6, 15 to 18), each internal winning combination (replay) having a name from “F_reach-eye lip A” to “F_reach-eye lip D” is performed. Is not determined as an internal winning combination by itself. Therefore, in the present embodiment, when the replay combination of the names “F_reach-eye lip A” to “F_reach-eye lip D” is determined as an internal winning combination during the RT0 state to the RT3 state (name from the player) The symbol combination corresponding to the replay combination according to “F_reach-eye lip A” to “F_reach-eye lip D” and the bonus combination (name “F_BB1” or “F_BB2”) are determined as the internal winning combination at the same time. It will be.

  The RT5 state, which is a state between flags, is a gaming state in which the bonus combination is carried over as the internal winning combination as described above. Therefore, as shown in FIG. 17A, in the internal lottery table referred to in the RT5 state, the carried-over bonus combination is always determined as the internal winning combination. Also, as shown in FIG. 17B, in the internal lottery table referred to in the bonus state, an internal winning combination with any of the names “F_RB combination 1” to “F_RB combination 4” is always won ( "Outside" will not be won).

[Correspondence table between internal winning combination and symbol combination (winning combination) (symbol combination determination table)]
Next, a correspondence table (symbol combination determination table) between an internal winning combination and a symbol combination will be described with reference to FIGS. The symbol combination determination table defines the correspondence between various internal winning combinations and the symbol combinations (combinations) that can be displayed on the activated line (center line) and are associated with each internal winning combination. That is, when the internal winning combination is determined, the type of the symbol combination that can be displayed on the activated line (the type of the display combination that can be won) is uniquely determined.

  Various data described in the symbol combination column in each symbol combination determination table are used to identify a symbol combination that is permitted to be displayed along an active line set over the left reel 3L, the middle reel 3C, and the right reel 3R. Data. Note that the relationship between each name described in the symbol combination (display combination) column and a specific symbol combination is shown in a winning operation flag storage area in FIGS. 28 to 30 described later.

  The symbol “○” described in the symbol combination determination table indicates a symbol combination (combination) that can be displayed on the activated line in the determined internal winning combination, that is, a display combination that can be awarded. For example, when the internal winning combination “F_Chilelip” is determined, as shown in FIGS. 18 and 19, the combination names “C_keeplip A_01” to “C_keeplip G_01”, “C_tillip A_01” to “C_tillip” The symbol combination related to "D_01" can be stopped and displayed. Note that the symbol combination determination table does not specify the case where the “internal winning combination” is “losing”, but this is the case for all the symbols defined by the symbol combination tables shown in FIGS. Indicates that the display of the combination is not permitted.

  In the pachislo 1 of the present embodiment, the main control circuit 90 (main CPU 101) changes the stop control according to the internal winning combination and the game state, and when the predetermined combination is determined as the internal winning combination, the main control circuit 90 (FIG. The rotation stop control of the left reel 3L, the middle reel 3C, and the right reel 3R is performed so that the symbol combination (combination) of the correspondence shown in FIG. 23 can be displayed. In the correspondence tables shown in FIGS. 18 to 23, all the symbol combinations that can be displayed for the determined internal winning combination are listed with “」 ”marks, but the symbol combinations marked with“ 」” are indicated. Even if they are combinations, they may not be displayed.

  In the present embodiment, the stop control (for example, a symbol to be preferentially drawn in) is changed according to a symbol combination that can be stopped and displayed or a current game state. Even if the symbol combination is marked, it may not be displayed. The correspondence between the type of the internal winning combination and the actually displayed symbol combination will be described with reference to FIGS. 24 and 25 described later.

[Correspondence between winning combination in non-flag state and symbol combination stopped and displayed]
Here, with reference to FIG. 24, a description will be given of the correspondence between the internal winning combination and the symbol combination stopped and displayed in the gaming state (non-flag state) excluding the state between flags. FIG. 24 shows the correspondence relationship between various internal winning combinations that can be determined in the non-flag state and the symbol combinations (abbreviations) stopped and displayed when each internal winning combination is determined (some combinations are omitted). FIG. The name of the symbol combination described in FIG. 24 is “abbreviated name” described in the content column shown in the winning operation flag storage area in FIGS. 28 to 30 described later.

  In the pachislo 1 of the present embodiment, a symbol combination displayed in accordance with a stop operation sequence (push sequence) of the player, that is, a so-called "push sequence" is provided. Note that the symbol combination associated with the “push order correct answer” described in FIG. 24 is a symbol combination that is advantageous to the player among the symbol combinations displayed according to the push order, and the “push order incorrect answer” The associated symbol combination is a symbol combination disadvantageous to the player among the symbol combinations displayed according to the pressing order. When notifying a stop operation that is advantageous to the player, a correct push order is notified, and if the stop operation is performed in accordance with the notification, a symbol combination associated with the “push order correct answer” is displayed. In addition, even in the ART gaming state, the pushing order in which the answer is incorrect may be reported, but the details will be described later.

  In the present embodiment, for some of the pressing sequences, the correct pressing sequence is shown at the end of the name. Specifically, the ending “1st” of the name of the internal winning combination means that the correct push order is that the first stop operation (first stop operation) is for the left reel 3L, The ending “2nd” of the name of the internal winning combination means that the pressing order for the correct answer is that the first stop operation is for the middle reel 3C, and the ending “3rd” of the name of the internal winning combination is the correct answer. The pressing order means that the first stop operation is for the right reel 3R. In addition, the end “123” of the name of the internal winning combination means that the correct push order is “left, middle, right”, and the end “132” of the name of the internal winning combination is the correct answer. Means that the pressing order is “left, right, middle”, and the ending “213” of the name of the internal winning combination means that the correct pressing order is “middle, left, right”. And the end “231” of the name of the internal winning combination means that the correct pressing order is “left, right, middle”.

  In the following, the stop operation order when the first stop operation is performed on the left reel 3L, specifically, the pressing order of “left, middle, right” and “left, right, middle” is referred to as “ Also referred to as "forward push". Further, in the following, a stop operation sequence when the first stop operation is performed on the middle reel 3C or the right reel 3R, specifically, “middle, left, right”, “middle, right, left”, The pressing order of “right, middle, left” and “right, left, middle” is also referred to as “irregular pressing”.

  In the present embodiment, as shown in FIG. 24, the internal winning combination "F_Chililip" is a pressing sequence in which the symbol combination displayed according to the pressing order is different, and when the pressing order is correct, the abbreviation "F_Chililip" is used. Any of the displayable symbol combinations shown in FIGS. 18 to 23 among the symbol combinations related to “Chili lip” (see FIG. 28 described later) is displayed along the activated line. On the other hand, if the pressing order is not the correct answer, any of the displayable combinations shown in FIGS. 18 to 23 among the combinations of symbols related to the abbreviation “Replay” (see FIG. 28 described later) is along the active line. Is displayed. When the internal winning combination “F_Chililip” is determined, as shown in FIGS. 18 to 23, the combination name “C_Chililip A_01”, “C_Chililip B_01” or “C_Chililip C_01” (abbreviation “single chililip”) Alternatively, a symbol combination related to a "two-piece chili lip": corresponding to an abbreviation "chili lip (no triple)" in FIG. "Triple Chililip": a symbol combination related to the abbreviation "Chililip (triple)" in FIG. 28 described later cannot be displayed. That is, the internal winning combination “F_Chililip” is a combination that cannot display the symbol combination related to the abbreviation “Triple Chililip”.

  Further, the internal winning combination “F_Probable Chililip” and the “F_1 Probable Chililip” are both different press combinations that are displayed in different symbol combinations according to the pressing order, and when the pressing order is correct, the abbreviation “Chililip” is used. Among the symbol combinations (see FIG. 28 described later) according to any one of the symbol combinations which can be displayed as shown in FIGS. 18 to 23, are displayed along the activated line. On the other hand, if the pressing order is not the correct answer, any of the displayable combinations shown in FIGS. 18 to 23 among the combinations of symbols related to the abbreviation “Replay” (see FIG. 28 described later) is along the active line. Is displayed. When the internal winning combination “F_Sure Chill Lip” or “F_1 Chill Chill Lip” is determined, as shown in FIGS. 18 to 23, the symbol combination related to the abbreviation “Triple Chill Lip” can be displayed. In other words, the internal winning combination “F_Surely Chilllip” and “F_1 Circularly Chilllip” are symbols that can display the symbol combination related to the abbreviation “Triple Chillip”.

  Further, the internal winning combinations “F_reach-eye lip A” to “F_reach-eye lip D” are push-sequence combinations in which the symbol combinations displayed according to the order of the push are different, and are abbreviated when the push order is correct. One of the displayable symbol combinations shown in FIGS. 18 to 23 among the symbol combinations (see FIGS. 28 and 29 described later) relating to the “reach eye lip” is displayed along the activated line. On the other hand, if the pressing order is not the correct answer, any of the displayable combinations shown in FIGS. 18 to 23 among the combinations of symbols related to the abbreviation “Replay” (see FIG. 28 described later) is along the active line. Is displayed.

  In the present embodiment, the order of pressing the correct answer at the time of winning the internal winning combination “F_ChiliLip”, “F_ClilipRip”, “F_1RilipLip A” to “F_ReachRipA” to “F_ReachRipD”. Performs a first stop operation on the left reel 3L. Therefore, for example, in a game in which the internal winning combination “F_reach eye lip A” is determined, when the player performs the first stop operation on the left reel 3L, the abbreviation is “reach eye lip”. The symbol combination is stopped and displayed. Note that the present invention is not limited to this, and the internal winning combination “F_ChiliLip”, “F_Probable Chililip”, “F_1Probable Chililip”, and “F_Reach eye lip A” to “F_Reach eye lip D” can be obtained. The pressing order of the correct answer can be set arbitrarily.

  Further, the internal winning combination “F_maintenance lip A” and “F_maintenance lip B” are not the pressing order, but the symbols in the symbol combination (refer to FIG. 28 described later) related to the abbreviation “Replay” regardless of the pressing order. Any of the displayable symbol combinations shown in FIGS. 18 to 23 is displayed along the activated line.

  Further, all of the internal winning combinations “F_maintenance lip_1st” to “F_maintenance lip_3rd” are symbol combinations that are displayed in different symbol combinations according to the order of pressing, and are abbreviated when the order of pressing is correct. Among the symbol combinations related to “replay” (see FIG. 28 described later), any of the displayable symbol combinations shown in FIGS. 18 to 23 is displayed along the activated line. On the other hand, when the pressing order is not the correct answer, any of the symbol combinations that can be displayed in FIGS. 18 to 23 among the symbol combinations (refer to FIG. 28 described later) related to the abbreviation “RT2 shift lip” is an active line. Is displayed along.

  In addition, all of the internal winning combinations “F_RT3 lip — 1st” to “F_RT3 lip — 3rd” have different symbol combinations displayed according to the pressing order, and when the pressing order is correct, the abbreviation “RT3 A symbol combination (see FIG. 28 described later) related to “transition lip” is displayed along the activated line. On the other hand, if the pressing order is not the correct answer, any of the displayable combinations shown in FIGS. 18 to 23 among the combinations of symbols related to the abbreviation “Replay” (see FIG. 28 described later) is along the active line. Is displayed.

  In addition, all of the internal winning combinations “F_RT4 lip — 123” to “F_RT4 lip — 3rd” have different symbol combinations displayed according to the pressing order, and if the pressing order is correct, the abbreviation “RT4 A symbol combination (see FIG. 28 described later) related to “transition lip” is displayed along the activated line. On the other hand, if the pressing order is not the correct answer, any of the displayable combinations shown in FIGS. 18 to 23 among the combinations of symbols related to the abbreviation “Replay” (see FIG. 28 described later) is along the active line. Is displayed.

  Further, all of the internal winning combinations “F_3 selection bell — 1st” to “F_3 selection bell — 3rd” are different in the symbol combination displayed according to the pressing order, and are abbreviated when the pressing order is correct. A symbol combination (see FIG. 19 described later) related to “bell” is displayed along the activated line. On the other hand, when the pressing order is not the correct answer, the symbol combination relating to the abbreviation “bell spilled eyes” (see FIG. 28 described later) or the symbol combination relating to the abbreviation “1st appearance” (refer to FIG. 30 described later) is used. Is displayed.

  Further, the internal winning combination “F_common bell” is not a pressing sequence combination, and can be displayed as shown in FIGS. 18 to 23 in a symbol combination (see FIG. 29 described later) related to the abbreviation “bell” regardless of the pressing order. One of the symbol combinations is displayed along the activated line. In addition, the internal winning combination “F_SABO1” and “F_SABO2” are not the pressing order, and FIG. 18 of the symbol combination (refer to FIG. 30 described later) related to the abbreviation “Cactus” regardless of the pressing order. 23 are displayed along the activated line.

  In addition, the internal winning combination “weak cherry” is not a pressing sequence, and can be displayed as shown in FIGS. 18 to 23 in a symbol combination (refer to FIG. 30 described later) related to the abbreviation “weak cherry” regardless of the pressing order. One of the symbol combinations is displayed along the activated line. In addition, the internal winning combination “F_Strong Chile 1” and “F_Strong Chile 2” are not the pressing sequence, and the symbol combinations related to the abbreviation “Strong Cherry” (see FIG. 30 described later) regardless of the pressing order. One of the displayable symbol combinations shown in FIGS. 18 to 23 is displayed along the activated line.

[Correspondence between the winning combination in the state between the flags and the symbol combination stopped and displayed]
Next, with reference to FIG. 25, a description will be given of the correspondence between the internal winning combination and the symbol combination stopped and displayed in the state between the flags. FIG. 25 is a diagram showing a correspondence relationship between the internal winning combination and the symbol combination stopped and displayed (a part of the combination is omitted) in the state between the flags, and particularly, the bonus combination ( It is a figure which shows whether the symbol combination (combination name "C_BB1" or "C_BB2") concerning a BB combination can be displayed.

  In the correspondence table of FIG. 25, the symbol “○” in the “BB establishment possibility” column indicates that the symbol combination relating to the BB combination can be displayed, and the symbol “X” indicates the symbol combination relating to the BB combination. Indicates that cannot be displayed. If the symbol combination relating to the BB combination cannot be displayed, the symbol combination relating to the combination determined to overlap with the bonus combination as the internal winning combination is displayed. For example, when the internal winning combination “F_BB1 + F_Chililip” is won (when the internal winning combination “F_BB1” and the internal winning combination “F_Chililip” are repeated), as shown in FIG. 25, the internal winning combination “F_BB1” Can be stopped and displayed, and the symbol combination related to the internal winning combination "F_Chirilip" is stopped and displayed.

  Further, during the inter-flag state, when the symbol combination relating to the BB combination cannot be displayed and the symbol combination relating to the combination determined to overlap with the bonus combination is displayed, the push described in FIG. Only the symbol combination at the time of the correct order may be displayed, or only the symbol combination at the time of the incorrect answer may be displayed.

  For example, when the internal winning combination “F_BB1 + F_3 selection bell_1st” is won, the symbol combination relating to the internal winning combination “F_BB1” cannot be stopped and displayed as shown in FIG. Is stopped and displayed, but at this time, only the symbol combination related to the abbreviation "bell" displayed at the time of the correct answer of the pressing order can be displayed, and the abbreviation "bell spilling eye" displayed at the time of the incorrect answer of the pressing order is displayed. Alternatively, the symbol combination relating to “1st roll” may not be displayed (see FIG. 24). Further, for example, when the internal winning combination “F_BB1 + F_RT3 lip_1st” is won, only the symbol combination related to the abbreviation “Replay” displayed when the pressing order is incorrectly displayed can be displayed, and the abbreviation “RT3” displayed when the pressing order is correct. The symbol combination related to the “transition lip” may not be displayed (see FIG. 24).

  In the inter-flag state, as shown in FIG. 25, the bonus combination (BB combination) and one of the internal winning combinations “out”, “F_special 1”, “F_special 2”, and “F_special 3” are performed. When it is determined in duplicate, the symbol combination relating to the BB combination can be stopped and displayed.

[Reel stop initial setting table]
Next, a reel stop initialization table will be described with reference to FIG. The reel stop initial setting table defines the correspondence between the internal winning combination and various data used in the reel stop control processing described later.

  The reel stop initial setting table shown in FIG. 26 defines a correspondence relationship between an internal winning combination (small winning combination number), a drawing priority table selection table number, a drawing priority table number, and a stop table number. In FIG. 26, the referred gaming state and the name of the internal winning combination are also described.

  The pull-in priority table selection table number and the pull-in priority table number are data used in the process of selecting the pull-in priority table. For example, if the pull-in priority table number corresponding to the stop table number is specified in the reel stop initial setting table, it corresponds to the pull-in priority table number specified in the pull-in priority table (see FIG. 27 described later). It is possible to acquire data on the priority of the display combination. On the other hand, if the pull-in priority table number corresponding to the stop table number is not specified in the reel stop initial setting table, the pull-in priority table selection table (not shown) is referred to, and the pull-in priority table selection table number is changed. The corresponding withdrawal priority table number is determined.

  Here, a reel stop control (a method of determining a stop symbol position) in the pachislo 1 of the present embodiment will be briefly described. In this embodiment, after the stop operation is detected by the stop switch, the stop control of the reel is performed so that the rotation of the corresponding reel stops within 190 msec. Specifically, any one of the number of sliding symbols “0” to “4” is added to the value of the symbol counter corresponding to the reel when the stop operation is detected, and the value corresponds to the obtained value. The symbol position is determined as a symbol position at which the rotation of the reel stops (hereinafter, referred to as a “scheduled stop position”). The symbol position corresponding to the value of the symbol counter corresponding to the relevant reel when the stop operation is detected is a symbol position at which the rotation of the reel starts to be stopped (hereinafter, referred to as a "stop start position").

  That is, the number of sliding pieces is the rotation amount of the reel from when the stop operation is detected by the stop switch to when the rotation of the corresponding reel stops. In other words, it is the number of symbols that pass through the middle area of the relevant reel of the reel display window 4 during the period from when the stop operation is detected by the stop switch to when the rotation of the relevant reel stops. This is grasped by the value of the symbol counter updated after the stop operation is detected by the stop switch.

  Referring to a stop table (not shown), the number of sliding pieces is obtained according to the stop start position of each reel. In the present embodiment, the number of sliding pieces is obtained based on the stop table, but this is a provisional one, and the obtained number of sliding pieces does not immediately determine the scheduled stop position of the reel. In the present embodiment, if there is a more appropriate number of sliding pieces than the number of sliding pieces obtained based on the stop table (hereinafter, referred to as “sliding piece number determination data”), a pull-in priority table described later (described later). Referring to FIG. 27), the number of sliding pieces is changed. The number-of-slide-pieces determination data is referred to in order to determine the search order when comparing the priorities of the symbols from the stop start position to the symbol position four symbols ahead, which is the maximum number of slide pieces.

[Purchase priority table]
Next, the pull-in priority order table will be described with reference to FIG. The draw-in priority table includes draw-in data (win-action flag data) for each type of a win-action flag storage area (see FIGS. 28 to 30 described later) in each of the draw-priority table numbers “00” to “05”. ) And a predetermined priority order.

  The pull-in priority table is used to search for a more appropriate number of sliding pieces in addition to the number of sliding pieces obtained based on the stop table (not shown). The priority order is data that defines the order in which symbols are preferentially stopped and displayed (pulled in) between types of symbol combinations (winning operation flags) related to winning. In FIG. 27, for convenience of explanation, the column of the pull-in data (winning operation flag data) describes the combination name of the winning operation flag, but in the actual pull-in priority table, each of the pull-in data is described later. As shown in the operation flag storage area (refer to FIGS. 28 to 30 described later), it is represented by 1-byte data, and a unique symbol combination (winning operation flag) is assigned to each bit in the 1-byte data. .

  In the reel stop control of the present embodiment, first, the number of sliding pieces is obtained based on a stop table (not shown). However, if there is a more appropriate number of sliding pieces besides the number of sliding pieces based on the priority, the number is changed to the appropriate number of sliding pieces. That is, in the present embodiment, a more appropriate number of sliding pieces is determined based on the priority of the symbol combination for which the stop display is permitted by the internal winning combination, regardless of the number of sliding pieces obtained from the stop table.

  In the present embodiment, the stop display (pull-in) of the symbol combination having the higher priority is performed in preference to the stop display of the symbol combination having the lower priority.

  Further, in the present embodiment, as shown in FIG. 27, not only the priority of the symbol combination (winning operation flag) differs according to the pull-in priority table number, but also the number of priority order divisions differs. Specifically, when the attraction priority table number is “00”, the number of divisions of the priority order is set to 5, and when the attraction priority table number is “01” or “04”, the priority order is set. Is four. Further, when the attraction priority table number is “02” or “03”, the number of priority sections is set to 2, and when the attraction priority table number is “05”, the number of priority sections is set. Is set to 3.

  Here, a description will be given of the priority when the pull-in priority table number is “00”, and a description of the priority in the other pull-in priority table numbers will be omitted. When the pull-in priority table number is “00”, the priority order “1” (the highest priority order) includes the combination names “C_9 sheets A_01”, “C_1 sure lip C_01”, “C_1 sure lip lip D_01”, Attraction-in data corresponding to “C_RT3 lip — 01” is defined.

  When the pull-in priority table number is “00”, the priority order “2” includes the combination names “C_strong 2 sheets C_01” to “C_strong 2 sheets C_09”, “C_low 2 sheets B_01” to “C_low” “2 sheets B_03”, “C_3 sheets E_01”, “C_3 sheets E_02”, “C_9 sheets F_01” to “C_9 sheets F_03”, “C_1 sure lip B_01”, “C_tillip D_01”, and “C_tillip C_01” Attraction data is specified.

  The priority “3” in the case where the pull-in priority table number is “00” includes the combination names “C_1 sure lip A_01”, “C_tillip A_01”, “C_tillip B_01”, and “C_keep lip E_01” to “ Attraction-in data corresponding to "C_maintenance lip E_04" is defined.

  When the pull-in priority table number is “00”, the combination “C_SP1 — 01”, “C_SP2 — 01”, “C_reach lip P_01”, “C_reach lip P_02”, and “C_reach” are assigned to the combination priority “4”. Eye lip O_01, C_reach eye lip O_02, C_reach eye lip N_01, C_reach eye lip N_02, C_reach eye lip M_01, C_reach eye lip M_02, C_reach eye lip “L_01” to “C_reach eye lip L_03”, “C_reach eye lip K_01” to “C_reach eye lip K_03”, “C_reach eye lip J_01”, “C_reach eye lip I_01” to “C_reach eye lip I_09” , “C_reach eye lip H_01” to “C_reach eye lip H_03”, “C_reach eye lip G_01” , “C_reach eye lip F_01”, “C_reach eye lip F_02”, “C_reach eye lip E_01”, “C_reach eye lip D_01”, “C_reach eye lip D_02”, “C_reach eye lip C_01” to “ “C_reach-eye lip C_03”, “C_reach-eye lip B_01”, “C_reach-eye lip B_02”, “C_reach-eye lip A_01”, “C_maintenance lip F_01”, “C_maintenance lip F_02”, “C_maintenance lip D_01” ”To“ C_maintenance lip D_04 ”,“ C_maintenance lip C_01 ”to“ C_maintenance lip C_03 ”,“ C_maintenance lip B_01 ”,“ C_maintenance lip B_02 ”, and“ C_maintenance lip A_01 ”are defined. Is done.

  In addition, when the withdrawal priority table number is “00”, the withdrawal data corresponding to the combination names “C_BB1” and “C_BB2” is defined in the priority order “5” (the lowest priority order).

<Configuration of storage area provided in main RAM>
Next, the configuration of various storage areas provided in the main RAM 103 will be described with reference to FIGS.

[Winning request flag storage area and winning operation flag storage area]
First, the configurations of the hit request flag storage area (internal winning combination storage area) and the winning operation flag storage area (display combination storage area) will be described with reference to FIGS. In the present embodiment, the hit request flag storage area (flag data storage area, winning flag data storage area) and the winning operation flag storage area (winning flag data storage area) have the same configuration.

  In the present embodiment, the hit request flag storage area includes hit request storage areas 0 to 11 each represented by 1-byte data, and the winning operation flag storage area includes a winning operation represented by 1-byte data. It is composed of storage areas 0-11. The data stored in each of the hit request flag storage area and the winning operation flag storage area is only 1-byte data in the “data” column in FIGS. 28 to 30, but in FIGS. 28 to 30, For convenience of explanation, symbol combinations of the respective reels (corresponding to the symbols of the left reel 3L, the symbol of the middle reel 3C, and the symbol of the right reel 3R in the drawing, respectively), The name (combination name) and abbreviation, and the number of paid out medals are also described.

  When "1" is stored in a predetermined bit in each of the hit request flag storage areas 0 to 11, it indicates that the internal winning combination corresponding to the predetermined bit has been internally won. In each of the winning operation storage areas 0 to 11, when “1” is stored in a predetermined bit, it indicates that the display combination (winning operation flag) corresponding to the predetermined bit has won. That is, when “1” is stored in the predetermined bit, it indicates that various symbol combinations of the internal winning combination corresponding to the predetermined bit are displayed on the payline.

  In the hit request flag storage area and the winning operation flag storage area, a plurality of symbol combinations (combinations) are assigned to one bit (flag) in each storage area as shown in FIGS. Some are. That is, for such a flag, it means that there are a plurality of symbol combinations that can be stopped and displayed (winning combinations).

  For example, the symbol combination “Cactus 2”-“White 7”-“Hat” (combination name “C_Maintenance Lip C_01”) and the symbol combination “Cactus 2” are stored in the bit 5 of the hit request storage area 5 and the winning operation storage area 5. -"Chile top 1"-"Hat" (combination name "C_Maintenance Lip C_02") and the symbol combination "Cactus 2"-"Cactus 2"-"Hat" (combination name "C_Maintenance Lip C_03") Three symbol combinations are assigned. Therefore, when "1" is stored in bit 5 of the hit request storage area 5, it indicates that the three symbol combinations can be stopped and displayed on the activated line. When "1" is stored in bit 5 of the winning operation storage area 5, it indicates that any of these three symbol combinations has been displayed on the activated line.

[Holdover combination storage area]
Next, the configuration of the carryover combination storage area will be described with reference to FIG. In the present embodiment, the carryover combination storage area includes a 1-byte data storage area.

  When the internal winning combination “F_BB1” or “F_BB2” is determined as a result of the internal lottery, the internal winning combination (BB combination) is stored in the carryover combination storage area as a carryover combination. The carryover combination stored in the carryover combination storage area is held without being cleared until the corresponding symbol combination is displayed on the payline. Further, while the carryover combination is stored in the carryover combination storage area, the carryover combination is stored in the hit request storage area in addition to the internal winning combination determined by the internal lottery.

[Gaming state flag storage area]
Next, the configuration of the gaming state flag storage area will be described with reference to FIG. The game state flag storage area is composed of a 1-byte data storage area. In the present embodiment, as shown in FIG. 32, a unique bonus type or RT type is assigned to each bit of the gaming state flag storage area.

  When "1" is stored in a predetermined bit in the gaming state flag storage area, it indicates that a bonus game or RT operation corresponding to the predetermined bit is being performed. For example, when “1” is stored in bit 0 of the gaming state flag storage area, the operation of the big bonus “BB” is performed, indicating that the gaming state is the BB gaming state. Further, for example, when “1” is stored in bit 3 of the gaming state flag storage area, it indicates that the gaming state is the RT3 state.

[Operation stop button storage area]
Next, the configuration of the operation stop button storage area will be described with reference to FIG. The operation stop button storage area includes a 1-byte data storage area, and stores an operation stop button flag composed of 1 byte. In the operation stop button flag, the operation state of the stop button is assigned to each bit.

  For example, when the left stop button 17L is the currently pressed stop button, that is, the operation stop button, “1” is stored in bit 0 of the operation stop button storage area. For example, when the left stop button 17L is a stop button that has not been pressed yet, that is, an effective stop button, “1” is stored in the bit 4. The main CPU 101 identifies a currently pressed stop button and a stop button that has not been pressed based on the data stored in the operation stop button storage area.

[Pressing order storage area]
Next, the configuration of the pressing order storage area will be described with reference to FIG. The pressing order storage area is composed of a 1-byte data storage area, and stores a pressing order flag composed of 1 byte.

  In the pressing order flag, the type of the pressing order of the stop button is assigned to each bit. For example, when the pressing order of the stop button is “left, middle, right”, “1” is stored in bit 0 of the pressing order storage area.

[Symbol code storage area]
Next, the configuration of the symbol code storage area will be described with reference to FIG. In the present embodiment, the symbol code storage area includes symbol code storage areas 0 to 11 each represented by 1-byte data. The symbol code storage area has the same configuration as the hit request flag storage area and the winning operation flag storage area (see FIGS. 28 to 30).

  In the symbol code storage area, “1” is stored in a bit corresponding to a symbol combination that can be stopped on an active line. After all the reels are stopped, the symbol codes corresponding to the display combination (winning operation flag) are stored in the symbol code storage areas 0 to 11.

[Relationship between internal winning combination and various sub flags]
In the general gaming state and the ART gaming state, various types of lottery by the main control circuit 90 refer to various data tables. In this embodiment, not only the internal winning combination but also the internal winning combination is used in this embodiment as a parameter used at this time. Various parameters with different names (hereinafter, referred to as “sub flag (first sub flag)”, “sub flag EX (second sub flag)”, and “sub flag D”) are also used. Therefore, in the present embodiment, the main control circuit 90 performs a process of converting an internal winning combination into various sub flags (see a sub flag conversion process, a flag conversion process, and a sub flag compression process in FIG. 104 described later). In the present embodiment, the sub flag is set in the start command as information (communication parameters) regarding the internal winning combination, and transmitted from the main control circuit 90 to the sub control circuit 200.

  Here, the correspondence between the internal winning combination and various sub flags will be described with reference to FIG. 36 and FIG. FIG. 36 is a diagram showing the correspondence between the internal winning combination (small combination winning number) and various sub flags, and FIG. 37 is a diagram showing the correspondence between the internal winning combination (special prize winning number) and the sub flags.

  In the flag conversion process of the present embodiment, first, a plurality of internal winning combinations belonging to the same type are combined into one sub flag. In the present embodiment, as shown in FIG. 36, the 32 types of internal winning combinations (small winning combinations) relating to the small combination and the replay combination are changed to 18 types of sub flags (“01” to “18”) by the flag conversion process. : Flag data). For example, the internal winning combination “F_maintained lip_1st (10: small win number)” to “F_maintained lip_3rd (12)” are collected into a sub flag “push order lip 1 (09: flag data)”. It should be noted that the sub-flag “losing (00)” is assigned to the internal winning combination “losing”.

  In the flag conversion processing of the present embodiment, as shown in FIG. 36, nineteen types of sub flags (“00” to “18”) including the sub flag “loss (00)” are replaced with nine types of sub flags EX (“00”). To “08”: flag data). Therefore, in this conversion process, the sub flag data can be further compressed. At this time, in this embodiment, the sub-flag is converted into the sub-flag EX by lottery (flag conversion lottery). Specifically, it is converted as follows.

  The sub-flag “losing (00)” is converted into the sub-flag EX “losing (00)” regardless of the result of the flag conversion lottery, and the sub-flag “two-piece chili lip (01)” is changed regardless of the result of the flag conversion lottery. It is converted into the sub flag EX “Replay (01)”.

  The sub-flag “triple chili lip A (02)” and the sub-flag “triple chili lip B (03)” indicate that the flag conversion lottery has been won (in the case of “with conversion” to be described later), the sub-flag EX “fixing hand (06)” Alternatively, the flag is converted into "triple chili lip (07)", and when the flag conversion lottery is not won (in the case of "no conversion" described later), the sub flag EX is converted into "replay (01)".

  When the flag conversion lottery is won, the sub flags “Reach eye lip 1 (04)” to “Reach eye lip 4 (07)” are converted to the sub flag EX “Determined hand (06)” or “Reach eye lip (08)”. If the flag conversion lottery is not won, the sub flag EX is converted to “Replay (01)”.

  The sub flags “Replay (08)” and “Push order Lip 1 (09)” to “Push order Lip 3 (11)” are converted into the sub flag EX “Replay (01)” regardless of the result of the flag conversion lottery. The sub-flag “push order bell (12)” and “common bell (13)” are converted to the sub-flag EX “bell (02)” regardless of the result of the flag conversion lottery.

  The sub-flags “Cactus (14)”, “Weak cherry (15)”, and “Strong cherry (16)” are sub-flags EX “Cactus (03)” and “Weak cherry (04), respectively, regardless of the result of the flag conversion lottery. "And" strong cherry (05) ". The sub-flag “reach 1 (17)” and “reach 2 (18)” are converted to the sub-flag EX “loss (00)” regardless of the result of the flag conversion lottery.

  As described above, in the present embodiment, substantially, the sub-flags “triple lip A (02)”, “triple lip B (03)”, and “reach lip 1 (04)” to “reach lip 4 (07) ) "Is the target of the flag conversion lottery. The lottery table used for the flag conversion lottery will be described later in detail.

  Further, in the flag conversion processing of the present embodiment, as shown in FIG. 36, nine types of sub-flags EX (“00” to “08”) are converted into seven types of sub-flags D (“00” to “06”). You. Therefore, in this conversion processing, the sub flag data can be further compressed. In this conversion process, the lottery is not performed, and the conversion is performed by associating the sub flag EX with the sub flag D in the following manner.

  The sub-flag EX “losing (00)”, “replay (01)”, and “bell (02)” are converted to the sub-flag D “losing (00)”. The sub flag EX “cactus (03)” is converted to the sub flag D “cactus (01)”, the sub flag EX “weak cherry (04)” is converted to the sub flag D “weak cherry (02)”, and the sub flag EX “strong” Cherry (05) "is converted to sub-flag D" strong cherry (03) ".

  Further, the sub flag EX “fixed hand (06)” is converted to the sub flag D “fixed hand (04)”, and the sub flag EX “triple lip (07)” is converted to the sub flag D “triple lip (05)”. Then, the sub flag EX “reach lip (08)” is converted to the sub flag D “reach lip (06)”.

  In the flag conversion process of the present embodiment, as shown in FIG. 37, both the internal winning combination “F_BB1 (01: special prize winning number)” and “F_BB2 (02)” are converted into the sub flag “BB”. .

[Gaming property at the time of sub flag EX conversion]
Here, a process of converting the above-described internal winning combination into a sub-flag and a sub-flag EX, and an example of the gaming property at the time of sub-flag EX conversion will be described with reference to FIGS. 38A and 38B. FIG. 38A is a diagram illustrating a flag conversion process in a case where the internal winning combination “F_Probable Chill Lip” or “F_1 Probable Chill Lip” is determined, and FIG. 38B is a diagram illustrating the internal winning combinations “F_Reach Rep A” to “F_ It is a figure which shows the flag conversion process in case any one of "reach eye lip D" is determined.

  In the pachislot 1 of the present embodiment, during the RT4 gaming state, any of the internal winning combinations “F_Clip Clip”, “F_1 Clip Clip”, and one of “F_Reach Rip A” to “F_Reach Rip D” are solely used. , The flag conversion lottery is performed. In the present embodiment, when the flag conversion lottery is won, a special privilege (for example, an increase in the number of ART games or a CT win) is given.

  For example, when the internal winning combination “F_Sure Chill Lip” or the “F_1 Sure Chill Lip” is determined, as shown in FIG. 38A, the internal winning combinations “F_Sure Chill Lip” and “F_1 Sure Chill Lip” are respectively set to the sub-flag “3 It is converted into "Chirilip A (02)" and "triple Chirilip B (03)".

  Next, when the sub-flags “triple chili lip A (02)” and “triple chili lip B (03)” win the flag conversion lottery, they become the sub-flag EX “triple chili lip (07)” or “fixed hand (06)”. Is converted. On the other hand, if the flag conversion lottery is not won, both the sub-flag “triple chili lip A (02)” and “triple chili lip B (03)” are converted to the sub-flag EX “replay (01)”. .

  As described with reference to FIG. 24, when the internal winning combination “F_Sure Chill Lip” or “F_1 Sure Chill Lip” is won, a symbol combination related to the abbreviation “Triple Chill Lip” is displayed when the push order is correct, and the push order is incorrect. At the time of correct answer, the symbol combination related to the abbreviation "Replay" is displayed. Therefore, in the present embodiment, when the internal winning combination “F_Sure Chill Lip” or the “F_1 Sure Chill Lip” is determined and the flag conversion lottery is won, the internal winning combinations “F_Sure Chill Lip” and “F_1 Sure Chill Lip”. Are treated as the role of the sub-flag EX “triple chili lip (07)” or “determined role (06)”.

  Then, when the internal winning combination “F_Sure Chill Lip” or “F_1 Chill Chill Lip” is converted to the sub-flag EX “Three Chill Lip (07)” or “Fixed Charm (06)” by the flag conversion process, the abbreviation “3 Information for displaying the symbol combination related to "Chili lip" is notified (for example, information indicating that the player is aimed at the Chile symbol by pushing in order). On the other hand, in this flag conversion process, if the flag conversion lottery becomes non-winning and the internal winning combination “F_Surely Reliable Lip” or “F_1 Surely Reliable Lip” is converted to the sub flag EX “Replay (01)”, the abbreviation is changed to “Replay”. Information for displaying such a symbol combination is notified (for example, a pressing order other than the normal pressing (irregular pressing) is notified).

  Further, for example, when any of the internal winning combinations “F_reach-eye lip A” to “F_reach-eye lip D” is determined, as shown in FIG. The F_reach eye lip D is converted into sub-flags “reach eye lip 1 (04)” to “reach eye lip 4 (07)”, respectively.

  Next, when the sub flags “Reach eye lip 1 (04)” to “Reach eye lip 4 (07)” win the flag conversion lottery, they become the sub flag EX “Reach eye lip (08)” or “determined combination (06)”. Is converted. On the other hand, if the flag conversion lottery has not been won, the sub flags “Reach eye lip 1 (04)” to “Reach eye lip 4 (07)” are converted to the sub flag EX “Replay (01)”.

  As described with reference to FIG. 24, when any of the internal winning combinations “F_reach-eye lip A” to “F_reach-eye lip D” is won, the symbol combination related to the abbreviation “reach-eye lip” is obtained when the pressing order is correct. Is displayed, and a symbol combination related to the abbreviation "Replay" is displayed when the pressing order is incorrect. Therefore, in the present embodiment, if any of the internal winning combination “F_reach-eye lip A” to “F_reach-eye lip D” is determined and the flag conversion lottery is won, the internal winning combination “F_reach- All of “Lip A” to “F_reach eye lip D” are handled as the role of the sub-flag EX “reach eye lip (08)” or “fixed hand (06)”.

  Then, when the internal winning combination “F_reach-eye lip A” to “F_reach-eye lip D” is converted into, for example, the sub-flag EX “reach-eye lip (08)” or “fixed combination (06)” by the flag conversion process. , Information for displaying the symbol combination related to the abbreviation “Reach eye lip” is notified (for example, information indicating that the player is sequentially pushed to aim at the symbol “white 7” is notified). On the other hand, in this flag conversion process, the flag conversion lottery becomes non-winning, and the internal winning combinations “F_reach-eye lip A” to “F_reach-eye lip D” are converted into the sub-flag EX “replay (01)”. Information for displaying a symbol combination related to “replay” is notified (for example, a pressing order (irregular pressing) other than the forward pressing is notified).

  Further, in the present embodiment, in the flag conversion process shown in FIG. 38A or 38B, if the player performs a stop operation in accordance with the notification after winning the flag conversion lottery, the abbreviation “triple lip” or “reach lip” is applied. The symbol combination is stopped and displayed on the activated line, and a special privilege is given. In this processing, a special privilege is given to the player in accordance with the fact that the pachislot 1 wins the flag conversion lottery in the processing. However, the abbreviation "3" is given to the player. The display of the symbol combination related to the “continuous chili lip” makes it possible to feel that a special privilege has been given.

  In order to enhance the pachislot playability, it may be preferable that the appearance frequency of the symbol combination to which the benefit is given is different depending on the state, rather than being constant. Since the stop control (displayed symbol combination) differs depending on the type of the internal winning combination, as a method of changing the appearance frequency of the symbol combination to which the privilege is given according to the state, the winning probability of the internal winning combination is changed. (In the pachislot 1, the winning probability of the internal winning combination can be made different depending on the presence or absence of the bonus and the RT state. For example, as the RT state corresponding to the ART gaming state, only the RT4 state is used. Alternatively, a method of providing another RT state such as the RT6 state or the RT7 state may be considered). However, since the timing for changing the winning probability of the internal winning combination (transition timing of the RT state) is limited, this method lacks flexibility from the viewpoint of improving the gaming performance (interest).

  On the other hand, in the pachislot 1 of the present embodiment, the flag conversion lottery and the notification based on the lottery result are performed in addition to the internal lottery for determining the internal winning combination without changing the winning probability of the internal winning combination. In addition, the appearance frequency of the symbol combination to which the privilege is given can be flexibly changed according to the state. That is, in a state where it is easy to win the flag conversion lottery, the appearance frequency of the symbol combination to which the benefit is given can be increased. On the contrary, in a state where it is difficult to win the flag conversion lottery, the appearance of the symbol combination to which the benefit is given appears Frequency can be reduced.

<Playability during the general game state>
Next, with reference to FIGS. 39A to 39C, a flow of the game in the general game state will be described. In the pachislot 1 of the present embodiment, during the general gaming state, the gaming state shifts from the normal gaming state to CZ, and then the gaming state shifts from CZ to the ART gaming state, whereby the general gaming state (non-ART gaming state) ) To the ART gaming state (see FIGS. 14A and 14B).

  FIG. 39A is a diagram showing a game flow when the game state shifts from the normal game state to CZ during the general game state. As shown in FIG. 39A, the normal game state has a low probability state and a high probability state as CZ lottery states. The low-probability state and the high-probability state are states in which the degrees of expectation of winning the CZ lottery performed during the normal game state are different from each other. The low-probability state is a state in which it is difficult to win the CZ lottery. This is a state where it is easy to win a lottery. Then, when the CZ lottery performed in the game in the normal game state is won, the game state shifts from the normal game state to CZ.

  In the pachislot 1 of the present embodiment, a plurality of chance zones “CZ1”, “CZ2” and “CZ3” are provided as CZs (chance zones). CZ1 to CZ3 are chance zones in which the expected degrees of winning in the ART lottery performed in the game in CZ are different from each other, CZ3 is a chance zone in which the ART lottery is always won, and CZ1 and CZ2 have a predetermined probability. This is a chance zone for winning the ART lottery. In the CZ lottery performed in the game in the normal gaming state, not only the winning / non-winning of the CZ, but also the type of the CZ (one of CZ1 to CZ3) to be shifted at the time of the winning is determined (see FIG. 41 described later).

  FIG. 39B is a diagram showing a flow of the game when the game state shifts from the CZ1 and CZ2 in the normal game state to the ART game state. Both CZ1 and CZ2 are composed of a first half and a second half. The first half is a period during which the rank of the degree of expectation to win the ART lottery performed in the game in CZ is promoted, and the second half is a predetermined effect (in the present embodiment, the character lottery result of the ART lottery based on the rank). This is a period in which the notification is made.

  In CZ1, six levels of modes (modes 1 to 6) are prepared as ranks, and the higher the mode, the higher the degree of expectation of winning the ART lottery. In the first half of CZ1, a game is continuously performed for a first predetermined number of games (for example, a maximum of 12 games), and a promotion of a mode is performed based on an internal winning combination. Then, in the first game of the second half of CZ1, ART lottery is performed based on the mode promoted in the first half (the mode at the end of the first half).

  In CZ2, ten levels of points are prepared as ranks, and the higher the points, the higher the degree of expectation of winning the ART lottery. In the first half of CZ2, a game is continuously performed for a second predetermined number of games (for example, a maximum of 15 games), and a point lottery is performed based on an internal winning combination. Then, in the first game of the second half of CZ2, ART lottery is performed based on points promoted in the first half (points at the end of the first half).

  In the latter half of CZ1, a battle effect in which the ally character and the enemy character A compete against each other is performed, and in the latter half of the CZ2, a battle effect in which the ally character and the enemy character B compete against each other is performed. This battle effect is performed over a game of a third predetermined number of games (for example, a maximum of four games). Further, the winning or losing of the battle effect is managed (determined) based on the result of the ART lottery. If the ART lottery is won, the ally character wins the battle effect, and if it is not won, the battle character wins. The enemy character wins in the production.

  In each second half of CZ1 and CZ2 (during a battle effect), ART random determination is performed for each game based on the internal winning combination. Then, when this ART lottery is won, the result of the battle effect is rewritten. For example, if a so-called "rare" combination is determined as an internal winning combination during a battle effect, an ART lottery is performed, and the result of the battle effect is rewritten based on the result.

  In CZ1 and CZ2, if the ART is not won, the game is defeated in the latter half of the battle effect, and the game state basically shifts to the normal game state thereafter. On the other hand, when the ART is won in CZ1 and CZ2, the battle is won in the latter half of the battle effect, and then the gaming state shifts from the CZ to the normal ART via the ART preparation state. In the present embodiment, a freeze may occur in the game in the first half of CZ1 and CZ2. In such a case, the game state is changed from CZ to the ART preparation state, and not the normal ART but the CT (additional). (Chance zone).

  FIG. 39C is a diagram illustrating a flow of a game when the game state shifts from the CZ3 in the normal game state to the ART game state. In the CZ3, a game is continuously performed for a period of a fourth predetermined number of games (for example, a maximum of 17 games). Then, in CZ3, ART random determination is performed for each game based on the internal winning combination.

  The CZ3 ends when the ART lottery is won, and the game state shifts from the CZ3 to the CT (additional chance zone) via the ART preparation state after the next game. Further, in the CZ3, a freeze may occur. In such a case, the game state shifts from the CZ3 to the CT (additional chance zone) via the ART preparation state after the next game. On the other hand, if the game period (the fourth predetermined number of games) of CZ3 has elapsed without winning the ART lottery in CZ3, the game state shifts to normal ART from CZ3 via the ART preparation state. That is, in the present embodiment, CZ3 is a chance zone in which the transition to the ART gaming state is determined.

<Various data tables used during the general game state>
Next, with reference to FIGS. 40 to 45, various data tables used in the lottery process regarding the gaming properties performed during the general gaming state will be described. The various data tables described below are stored in the main ROM 102.

  Further, in the various data tables described below, information on the lottery values is conceptually shown. “0” in the data table means that a lottery value corresponding to the winning probability “0%” is defined, and “extremely low” means a lottery value corresponding to the winning probability “0% to less than 1%”. "Very low" means that a lottery value corresponding to the winning probability "1% to less than 10%" is defined. “Low” in the data table means that a lottery value corresponding to the winning probability “10% to less than 30%” is defined, and “medium” means the winning probability “30% to less than 60%”. Means that a lottery value corresponding to "" is defined, and "high" means that a lottery value corresponding to the winning probability "60% to less than 80%" is defined. Further, “extremely high” in the data table means that a lottery value corresponding to the winning probability “80% to less than 99%” is defined, and “extremely high” indicates that the winning probability is “99% to 100%”. "Less than%" means that a lottery value is defined, and "determined" means that a lottery value corresponding to a winning probability of "100%" is defined.

  In the various data tables described below, the random number register 1 of the random number circuit 110 sequentially subtracts a random number for lottery extracted from a predetermined numerical value range (0 to 65535) by a specified lottery value. The internal lottery is performed by determining whether or not the result of the subtraction is negative (whether or not a so-called "digit" has occurred). Note that, in the present embodiment, an example has been described in which the lottery value is subtracted from the random number for lottery in the lottery processing relating to the playability performed in the general gaming state, and the winning / non-winning is determined, but the present invention is not limited to this. Instead, the lottery value is added to the extracted random number for lottery, and it is determined whether or not the addition result exceeds 65536 (whether or not so-called “digit overflow” has occurred) to determine winning / non-winning. Is also good.

[Normal middle and high probability lottery table]
First, with reference to FIGS. 40A and 40B, a description will be given of a normal medium-high probability lottery table used in the transition lottery of the CZ lottery state (low probability and high probability). In the pachislot 1 of the present embodiment, not only the shift lottery of the CZ lottery state is performed based on the internal winning combination in each game, but also in the case of, for example, the end of the bonus or the end of the CZ or ART, etc. Shifting to a lottery state is performed. FIG. 40A is a configuration diagram of a normal medium-high probability lottery table referred to in each game during the normal game state, and FIG. 40B is a normal medium-high value referred to, for example, at the time of setting change, at the end of a bonus, or at the end of CZ or ART. It is a lineblock diagram of a probability lottery table. Note that the name of the internal winning combination shown in FIG. 40A corresponds to the name of the sub flag described above.

  The normal medium-high probability lottery table shown in FIG. 40A includes, for each combination of the current CZ lottery state and the internal winning combination, the lottery result (low probability / high probability) of the CZ lottery state after transition, and each lottery result. The correspondence with the information of the associated lottery value is defined.

  As is clear from the normal medium-high probability lottery table shown in FIG. 40A, when the current CZ lottery state is low probability, when the internal winning combination is the combination corresponding to the sub-flag “weak cherry”, the CZ It becomes easy for the lottery state to shift to a high probability. On the other hand, when the current CZ lottery state has a high probability, when the internal winning combination is a combination corresponding to one of the sub flags “common bell”, “cactus”, “weak cherry”, and “strong cherry”. Then, the lottery state of CZ is maintained at a high probability.

  The normal medium-high probability lottery table shown in FIG. 40B includes various situations when the table is referred to, lottery results (low-probability / high-probability) of the CZ lottery state after transition, and lottery associated with each lottery result. Defines the correspondence between value information. As is clear from the normal medium-high probability lottery table shown in FIG. 40B, the CZ lottery state always shifts to the high probability at the end of the bonus.

[CZ lottery table]
Next, a CZ random determination table used in the CZ random determination will be described with reference to FIGS. 41A and 41B. FIG. 41A is a configuration diagram of a CZ lottery table used when performing the CZ lottery based on the internal winning combination during the normal gaming state, and FIG. 41B is a drawing back of the CZ when, for example, the CZ fails or the ART ends. FIG. 10 is a configuration diagram of a CZ lottery table used when performing the CZ lottery as to whether or not to perform. Note that the name of the internal winning combination shown in FIG. 41A corresponds to the name of the sub flag described above.

  The CZ lottery table shown in FIG. 41A includes each combination of the current CZ lottery state and the internal winning combination, CZ1, CZ2, CZ3 winning / non-winning (lottery result), and the lottery associated with each lottery result. Defines the correspondence between value information. As is clear from the CZ lottery table shown in FIG. 41A, when the current CZ lottery state is in high probability, the CZ lottery is won more than when the current CZ lottery state is in low probability. The probability increases.

  The CZ lottery table shown in FIG. 41B is a correspondence relationship between winning / non-winning (lottery result) of CZ1, CZ2, and CZ3 at the time of CZ failure or ending of ART and information of a lottery value associated with each lottery result. Is specified. When the CZ fails (when the ART lottery in CZ1 and CZ2 is not won) or when the ART gaming state ends, the CZ pull-back lottery is performed using this CZ lottery table.

[CZ1 Medium Mode Up Lottery Table]
Next, a CZ1 mode up lottery table used in the CZ1 mode up lottery performed in the first half of CZ1 will be described with reference to FIG. FIG. 42 is a configuration diagram of the CZ1 medium mode up lottery table. Note that the names of the internal winning combinations shown in FIG. 42 correspond to the names of the sub flags described above.

  The CZ1 mode-up lottery table shows the correspondence between each combination of the current mode and the internal winning combination, the result of the mode-up lottery (win / non-win), and the information of the lottery value associated with each lottery result. Is specified. As shown in FIG. 44A described later, in CZ1, the probability of winning the ART lottery increases as the mode increases (the value of the mode increases), and when the mode rises to mode 6, the ART lottery is always won.

  In addition, the lottery result “mode 1 UP” in FIG. 42 means that the mode of CZ1 is raised by one step, and the lottery result “mode 2 UP” means that the mode of CZ1 is raised by two steps. Therefore, for example, when the lottery result “mode 2 UP” is won in the situation where the current mode is mode 2, the mode of CZ1 goes up from mode 2 to mode 4. Further, for example, when the lottery result "mode 6 UP_freeze occurrence" is won, a freeze occurs, and the winning of the ART lottery and the giving of the CT are determined.

[CZ2 Medium Point Lottery Table]
Next, a CZ2 medium point lottery table used in the CZ2 point-up lottery performed in the first half of the CZ2 will be described with reference to FIG. FIG. 43 is a configuration diagram of the CZ2 middle point lottery table. The name of the internal winning combination shown in FIG. 43 corresponds to the name of the sub flag described above.

  The CZ2 medium point lottery table indicates the correspondence between each combination of the current point and the internal winning combination, the result of the point-up lottery (win / non-win), and the information of the lottery value associated with each lottery result. Stipulate. As shown in FIG. 44B to be described later, in CZ2, the probability of winning the ART lottery increases as the point increases, and when the point increases to “point 10,” the ART lottery is always won. Note that the lottery result “point 2 UP” in FIG. 43 means that “2” is added to the current CZ2 point. For example, in the situation where the current point is “2”, the lottery result “point 2 UP” When the point 2UP is won, the point of CZ2 increases from "2" to "4". Further, for example, when the lottery result is won at “point 10 UP_freeze occurrence”, a freeze occurs, and the winning of the ART lottery and the provision of the CT are determined.

[CZ Art Lottery Table]
Next, with reference to FIGS. 44A to 44C and FIG. 45, an ART random determination table during CZ used in ART random determination performed during CZ will be described. FIG. 44A is a configuration diagram of the CZ ART random determination table (for CZ1) used in the first game of the second half of CZ1, and FIG. 44B is a CZ ART ART used in the first game of the second half of CZ2. FIG. 44C is a configuration diagram of a lottery table (for CZ2), and FIG. 44C is a configuration diagram of a CZ in-ART ART lottery table (common for CZ1 and CZ2, during second-half battle) used in the second half of CZ1 and CZ2. FIG. 45 is a configuration diagram of a CZ3 ART random determination table (for CZ3) used in the ART random determination performed during CZ3. Note that the names of the internal winning combinations shown in FIGS. 44C and 45 correspond to the names of the sub flags described above.

  The CZ ART lottery table (for CZ1) shown in FIG. 44A defines the correspondence between the current mode, the ART lottery result (whether there is a winning), and information on the lottery value associated with each lottery result. . The ART random determination table during CZ (for CZ2) shown in FIG. 44B shows the correspondence between the current point, the result of the ART random determination (whether there is a winning), and the information of the random determination value associated with each random determination result. Stipulate.

  As is clear from the CZ ART lottery table (for CZ1) and the CZ ART lottery table (for CZ2), in CZ1 and CZ2, the higher the rank (mode or point) of the first half, the easier it is to win ART lottery.

  The CZ ART lottery table during CZ (common for CZ1 and CZ2 during the latter half of the battle) shown in FIG. Define the correspondence between As is clear from the ART random determination table during CZ (common for CZ1 and CZ2 during the latter half of the battle), in the latter half of CZ1 and CZ2, the role corresponding to the rare role (sub-flag “weak cherry”, “cactus” or “strong cherry”) ) Is determined as the internal winning combination, the ART lottery is won with a predetermined probability.

  The CZ3 ART lottery table (for CZ3) shown in FIG. 45 includes each combination of the number of digested games in CZ3 and the internal winning combination, the ART lottery result (whether there is a winning), and the lottery associated with each lottery result. Defines the correspondence between value information. As is apparent from the ART random determination table during CZ (for CZ3), in the present embodiment, whenever the ART random determination is performed in CZ3, the CT is also determined.

<Playability during normal ART>
Next, with reference to FIGS. 46A and 46B, a flow of a game during the game ART will be described. In the pachislot 1 of the present embodiment, as described above, the ART game state is provided with the normal ART and the CT (see FIGS. 14A and 14B), and the inside of the CT is set as an additional chance zone. Therefore, in the present embodiment, in the game during the normal ART, the player plays the game with the aim of shifting to CT.

[Transition from Normal ART to CT]
FIG. 46A is a diagram showing a mode of transition of the gaming state from normal ART to CT. In the pachislo 1 of the present embodiment, as shown in FIG. 46A, when the CT lottery performed during the normal ART is won, the gaming state shifts from the normal ART to the CT. In the pachislot 1 of the present embodiment, as shown in FIG. 46A, an ART level and a CT random determination state are provided as parameters affecting various random determinations performed during the normal ART.

  As the ART level, four levels from level 1 to level 4 are provided, and this ART level is controlled (decided) mainly based on the number of continuous (exhaustion) games during normal ART. The ART level affects the determination of the CT lottery state and the later-described flag conversion lottery during the normal ART.

  The CT lottery state includes four stages of low probability, normal, high probability, and super high probability. The CT lottery state is controlled mainly based on the ART level, the internal winning combination during the normal ART, and the like ( It is determined. The CT lottery state affects CT lottery performed during the normal ART, flag conversion lottery performed during the normal ART described later, and the like.

[Flag conversion during normal ART]
As described above, in the pachislot 1 of the present embodiment, during the RT4 state, that is, during the ART gaming state, the internal winning combinations “F_Sure Chill Lip”, “F_1 Sure Chill Lip”, and “F_Reach Eye Lip A” to “F_F_L_C” If any of the “reach eye lip D” is independently determined as the internal winning combination, a flag conversion lottery is performed, and a special privilege (for example, an increase in the number of ART games or a CT winning) is given according to the lottery result. . FIG. 46B is a diagram illustrating an outline of a technique of the flag conversion random determination performed during the normal ART.

  In the present embodiment, as shown in FIG. 46B, during normal ART, flag conversion random determination is performed with reference to the ART level and the CT random determination state. As a result, when the flag conversion lottery is won, a special privilege is given, and a symbol combination related to the abbreviation "triple lip" or a symbol combination related to the abbreviation "reach eye lip" is stopped and displayed on the activated line. Navi (for example, notification of information indicating that a predetermined symbol is aimed at by sequentially pressing) is performed. On the other hand, if the flag conversion lottery has not been won, a navigation (for example, notification of the pressing order other than the forward pressing) for stopping and displaying the symbol combination related to the abbreviation “Replay” on the activated line is performed.

  Then, when the player performs a stop operation according to the notification (navigation), a symbol combination corresponding to the notification content is stopped and displayed on the activated line. Specifically, when the flag conversion lottery is won, a symbol combination related to the abbreviation “triple lip” or a symbol combination related to the abbreviation “reach eye lip” is stopped and displayed on the activated line, and the flag combination lottery is disabled. If it is a winning, the symbol combination related to the abbreviation "Replay" is stopped and displayed on the payline.

<Various data tables used during normal ART>
Next, various data tables used in the lottery process during the normal ART will be described with reference to FIGS. The various data tables described below are stored in the main ROM 102.

[ART flag conversion lottery table]
FIGS. 47A and 47B are configuration diagrams of an ART flag conversion random determination table used in flag conversion random determination performed during normal ART.

  In the pachislo 1 according to the present embodiment, flag conversion random determination during normal ART is performed in two stages. Specifically, when the internal winning combination “F_Sure Chill Lip” or “F_1 Sure Chill Lip” is won, first, the first-stage flag conversion lottery is performed. A second stage flag conversion lottery is performed. Then, when the second-stage flag conversion lottery is won, the internal winning combination “F_Surely Reliable” or “F_1 Surely Reliable” is converted to the sub-flag EX “Three consecutive chips”. On the other hand, if the first-stage flag conversion lottery or the second-stage flag conversion lottery is non-winning, the internal winning combination “F_Sure Chill Rep” or “F_1 Sure Chill Rep” is converted to the sub flag EX “Replay”. (Treated as a regular replay). When any of the internal winning combinations “F_reach-eye lip A” to “F_reach-eye lip D” is won, only the second-stage flag conversion lottery is performed.

  FIG. 47A is a configuration diagram of an ART flag conversion lottery table used in the first-stage flag conversion lottery, and FIG. 47B is a configuration diagram of an ART flag conversion lottery table used in the second-stage flag conversion lottery. is there.

  The ART in-flag conversion lottery table shown in FIG. 47A includes an internal winning combination (“F_Sure Chill Lip” or “F_1 Certain Chill Lip”) and a lottery result of the first-stage flag conversion lottery (without conversion / with conversion (temporary)) And the information on the lottery value associated with each lottery result.

  The in-ART flag conversion lottery table shown in FIG. 47B includes each combination of an internal winning combination, an ART level, and a CT lottery state, a lottery result of the second-stage flag conversion lottery (without conversion / with conversion), and each lottery result. Is defined in correspondence with the information of the lottery value associated with. Note that in the game up to winning the CT once in the normal ART, the table in the "First time (until the CT is won once)" column of the item "ART level" in FIG. 47B is referred to.

  In the present embodiment, as shown in FIGS. 47A and 47B, in the stage and second stage flag conversion lotteries using each of the during-ART flag conversion lottery tables, a random number value (0 to 0) whose probability denominator is “256” is set. 255) is performed by lottery. Therefore, in the present embodiment, the above-described two-stage flag conversion lottery can be considered to be substantially the same as the case of performing a single lottery using a random number whose probability denominator is “65536”.

  In recent pachislot machines, a lottery (eg, an ART lottery) relating to payout that has conventionally been performed on the sub control board 72 side (hereinafter, referred to as “sub side”) is performed on the main control board 71 side (hereinafter, referred to as “main side”). It is required to do. However, since the capacity of the main storage means (main ROM 102) is limited to a small capacity, there is a need for a mechanism that enables a lottery that does not impair the game performance while suppressing an increase in the processing capacity.

  In this regard, in the pachislot 1 of the present embodiment, the lottery with the probability denominator being “65536” can be performed by performing the lottery with the probability denominator being “256” in two stages. It is possible to suppress an increase in the capacity on the side. In the second stage lottery, since the ART level, the CT lottery state, and the like are referred to, not only the internal winning combination but also the flag conversion lottery according to the current state can be performed. It is possible to carry out flag conversion random determination.

[ART level determination table]
FIGS. 48A and 48B are configuration diagrams of an ART level determination table used when determining the ART level. The processing for determining the ART level is performed at the time of the ART winning in which the transition to the ART gaming state is determined, and during the normal ART. FIG. 48A is a configuration diagram of an ART level determination table used during ART winning, and FIG. 48B is a configuration diagram of an ART level determination table used during normal ART.

  The ART level determination table shown in FIG. 48A defines the correspondence between ART levels 1 to 4 (lottery results) and information on lottery values associated with each ART level. In the present embodiment, if a freeze occurs during the ART winning, the ART level 2 is determined as the ART level.

  The ART level determination table shown in FIG. 48B includes a lottery associated with each combination of the current ART level and the number of elapsed (exhausted) games of the normal ART, various ART levels at the transition destination, and each ART level at the transition destination. Defines the correspondence between value information. The ART level determination table shown in FIG. 48B is associated with each combination of the current ART level and the number of elapsed games in the normal ART at the time of the CT entry, the various ART levels at the transition destination, and the respective ART levels at the transition destination. The corresponding relationship with the information of the obtained lottery value is defined. In other words, during the normal ART, the ART level can be shifted not only at the timing when the number of elapsed games of the normal ART (digestion) reaches the predetermined game number, but also at the timing when the CT enters the CT during the normal ART. It can be migrated.

[Normal ART medium-high probability lottery table]
FIG. 49 is a configuration diagram of the normal ART medium-high probability lottery table used when determining the CT lottery state during the normal ART.

  The normal ART medium-high probability lottery table shows a correspondence relationship between each combination of the current CT lottery state and the internal winning combination, various CT lottery states at the transition destination, and information on the lottery value associated with each CT lottery state. Stipulate. Note that the name of the internal winning combination shown in FIG. 49 corresponds to the name of the sub flag described above.

  As is clear from the normal ART medium-high probability lottery table, an internal winning combination corresponding to the sub-flag “triple lip (triple lip A and triple lip B)” or the sub-flag “reach-eye lip (reach-eye lip 1 to 4)” , It is easy to shift (fall) the CT lottery state to “low probability”. However, as shown in FIG. 50 to be described later, when the internal winning combination corresponding to the sub-flag “triple lip” or “reach eye lip” is won, even if the CT lottery state falls, the CT wins. It is configured to always win a lottery.

[CT random lottery table during ART]
FIG. 50 is a configuration diagram of a CT random determination table during ART used in CT random determination performed during normal ART.

  The ART during lottery table includes various combinations of the current CT lottery state and internal winning combinations, various lottery results of CT lottery (non-winning / normal CT / high-probability CT), and lotteries associated with each lottery result. Defines the correspondence between value information. Note that the name of the internal winning combination shown in FIG. 50 corresponds to the name of the sub flag described above.

  In the present embodiment, as internal winning combinations, sub flags “cactus”, “weak cherry”, “strong cherry”, “triple lip (triple lip A and triple lip B)”, “reach lip (reach lip) If the role corresponding to “1-4)” or “BB” is determined, in the CT lottery process using the ART during CT lottery table, the CT lottery using a random number in the range where the probability denominator is “256” Is performed. If an internal winning combination other than these combinations (for example, a combination corresponding to the sub-flag “replay”, “common bell”, “push order bell”, etc.) is determined as the internal winning combination, the CT during ART is determined. In the CT lottery process using the lottery table, the CT lottery is performed using random numbers in a range where the probability denominator is “65536”.

  In the pachislot 1 of the present embodiment, two types of CTs called “normal CT” and “high-probability CT” are provided as CTs. The normal CT and the high-probability CT have different expectations for the number of ART games added in a CT (additional chance zone), and the high-probability CT is a CT in which a larger number of ART games are easily added than the normal CT. (See FIG. 55 described later).

[Normal ART add-on lottery table]
FIG. 51 is a configuration diagram of a normal ART additional lottery table used in the additional lottery of the number of ART games performed during the normal ART. Note that the name of the internal winning combination shown in FIG. 51 corresponds to the name of the sub flag described above.

  The normal ART medium addition lottery table defines a correspondence relationship between an internal winning combination, various lottery results of the additional lottery (non-winning / additional 10G to 300G), and information of a lottery value associated with each lottery result.

<Playability during CT>
Next, the flow of a game during CT will be described with reference to FIGS. 52A to 52C. FIGS. 52A and 52B are diagrams mainly showing an outline of a game flow during CT when the sub-flag EX “Triple Chili Lip” is won, and FIG. 52C shows an outline of flag conversion processing performed during CT. FIG.

[Game content during CT]
In the pachi-slot 1 of the present embodiment, a set of eight games (eight games) is performed in CT. During the CT period, an additional lottery is performed for each game based on the internal winning combination. When the additional lottery is won, the unit game number (game number) of the CT game is not subtracted. On the other hand, when the additional lottery is not won, the unit game number of the CT game (game) is not subtracted. Number) is subtracted. Therefore, in the game in which the number of ART games is added during the CT period, the CT does not end. If the game in which the number of ART games is not added is performed eight times in the same set, the CT ends. .

  Further, in the present embodiment, as shown in FIGS. 52A and 52B, when the sub-flag EX “triple chili lip” is won during the CT period, that is, the internal winning combination “F_probable chili lip” or “F_1 probable chili lip” is won. In addition, when the flag conversion lottery is won, one set of eight CT games is reset (stocked). Then, the reset (stock) CT game set is started after the CT game set ends.

  For example, in the same set, after a unit game that is non-winning in the number of ART games is performed seven times and then a CT game in which the number of ART games is not performed is performed once, CT ends. If the sub-flag EX “triple chili lip” has been won, the CT game is reset. As a result, after the CT game is reset, the CT does not end until the unit game, which is a non-winning lottery in the number of ART games, is performed eight times. Therefore, the game period of CT becomes longer as the sub-flag EX “triple chili lip” is won.

[Conversion of flag during CT]
Next, with reference to FIG. 52C, a method of flag conversion lottery performed during CT will be described. As described above, in the present embodiment, when the sub-flag EX “Triple Chililip” is won during the CT period (the internal winning combination “F_Surelilip” or “F_1 Positive Chililip” is won, and the flag conversion lottery is won). Then, the CT is reset (stocked). Further, as shown in a CT flag conversion lottery table in FIG. 54 described later, when the internal winning combination “F_Sure Cliplip” or “F_1 Cirilip” is won during CT, the flag conversion lottery is always won (the sub flag EX “ It is always converted to "triple chili lip"). That is, in the present embodiment, when the internal winning combination “F_Sure Chill Lip” or “F_1 Sure Chill Lip” is won during CT, CT is always reset.

  Further, in the flag conversion lottery when any of the internal winning combinations “F_reach-eye lip A” to “F_reach-eye lip D” is won, the flag is determined based on three types of flag conversion tables (tables 0 to 2). The winning probability of the conversion lottery is controlled. More specifically, as shown in FIG. 52C, Table 0 is a flag conversion table having the lowest probability of being converted to the sub-flag EX “Reach eye lip”, and Table 1 is converted to the sub-flag EX “Reach eye lip”. This is the flag conversion table with the next lowest probability, and Table 2 is the flag conversion table with the highest probability of being converted into the sub-flag EX “Reach-Lip”. Note that, when the sub flag EX “Reach eye lip” is won during CT, a CT is newly given as shown in a later-described lottery table in which the number of sets during CT is added in FIG.

  In the present embodiment, in the normal CT, the flag conversion table is determined based on the ART level, as shown in FIG. 52C. On the other hand, in the high probability CT, table 0 is always determined as the flag conversion table regardless of the ART level.

<Various data tables used during CT>
Next, various data tables used in the lottery process performed during CT will be described with reference to FIGS. The various data tables described below are stored in the main ROM 102.

[CT table lottery table]
FIG. 53 is a configuration diagram of a CT table lottery table used when determining a table used for flag conversion lottery from the three-stage flag conversion tables (tables 0 to 2).

  The during-CT table lottery table shows a correspondence relationship between each state such as the ART level and the type of CT to be executed from now on, the types of the flag conversion tables (tables 0 to 2), and the information of the lottery values associated with each type. Stipulate. It should be noted that the during-CT table lottery table is referred to when it is determined to win CT lottery and shift to CT, or at the start of CT.

[CT flag conversion lottery table]
FIG. 54 is a configuration diagram of the flag conversion random determination table during CT used in the flag conversion random determination performed during CT.

  The flag conversion lottery table during CT includes an internal winning combination (any one of “F_reliable lip”, “F_1 reliable lip”, and “F_reach lip A” to “F_reach lip D”), and each flag conversion table ( The correspondence between the lottery results of the flag conversion lotteries (without conversion / with conversion) in Tables 0 to 2) and the information of the lottery values associated with the respective lottery results is defined. As is clear from the flag conversion lottery table during CT, when the internal winning combination “F_Currency Clip Rep” or “F_1 Probability Clip Rep” is won during CT, the flag conversion lottery is always won (the sub-flag EX “Triple Clip Rep” is always on). Will be converted).

[Additional lottery table during CT]
FIG. 55 is a configuration diagram of a CT add-on lottery table used in the additional lottery for the number of ART games performed during CT.

  The CT additional lottery table is associated with each combination of the current CT state and the internal winning combination, various lottery results of additional lottery (non-winning / additional 10 games /.../ additional 300 games), and each lottery result. The corresponding relationship with the information of the determined lottery value is defined. The name of the internal winning combination shown in FIG. 55 corresponds to the name of the above-described sub-flag, and when a role other than the internal winning combination (sub-flag) shown in FIG. 55 is internally won, the additional lottery during CT is won. I will not do it.

  In addition, in the additional lottery during the normal CT according to the present embodiment, the mode of providing the number of additional games changes according to the number of wins of the sub-flag “triple chili lip” (internal winning combination “F_positive chili lip” or “F_1 positive chili lip”). I do.

  Specifically, when the number of wins of the sub-flag “triple chili lip” in the same CT set is 1 to 8, the lottery results “addition — 10G” and “addition — 20G” shown in FIG. 55 are given. The number of additional games is 10 games and 20 games, respectively. Therefore, in this case, 10 games are easily determined as the number of additional games of the ART. When the number of wins of the sub-flag “triple chili lip” in the same CT set is 9 to 16, the additional game provided by the lottery results “additional_10G” and “additional_20G” shown in FIG. The number is both 20 games. That is, the number of additional games (lottery result) corresponding to the lottery value “extremely high” of the sub-flag “triple chili lip” in FIG. 55 is promoted to 20 games. Therefore, in this case, 20 games are easily determined as the number of additional games in the ART.

  If the number of wins of the sub-flag “triple chili lip” in the same CT set is 17 to 24, the additional game provided by the lottery results “additional_10G” and “additional_20G” shown in FIG. The number is both 30 games. That is, the number of additional games (lottery result) corresponding to the lottery values “extremely high” and “extremely low” of the sub-flag “triple lip” in FIG. 55 is promoted to 30 games. Therefore, in this case, “30 games” is likely to be determined as the number of additional games of ART. Furthermore, when the number of wins of the sub-flag “3 consecutive chips” in the same CT set is 25 or more, the number of additional games given in the lottery results “additional_10G” and “additional_20G” shown in FIG. Are both 50 games. That is, the number of additional games (lottery result) corresponding to the lottery values “extremely high” and “extremely low” of the sub-flag “triple lip” in FIG. 55 is promoted to 50 games. Therefore, in this case, “50 games” is easily determined as the number of additional games of ART.

  As described above, in the pachi-slot 1 of the present embodiment, it is possible to increase the number of ART games that can be added by one additional lottery in accordance with the number of winnings of the sub-flag “3 consecutive chips” during CT. In addition, as described above, in the present embodiment, as long as the number of ART games is added, the CT is not terminated, and if the sub-flag EX “Triple Chili Lip” is won, the CT is reset (stock). Is performed. Therefore, in the present embodiment, as the CT continues, the player can be expected to increase the additional amount per game, and the interest during the CT can be improved. In addition, the number of wins of the sub-flag “triple chili lip” which triggers an increase in the additional amount per game is a number of times (9 or more) larger than the number of basic games (8 times) for one CT set. Can be prevented from giving excessive profit to the player, and the profit can be balanced between the player and the game store.

  In the present embodiment, the number of wins of the above-described sub-flag “triple chili lip” (internal winning combination “F_ sure chili lip” or “F_1 certain chili lip”) is the number of times counted in the same CT set. The present invention is not limited to this. For example, a new CT that is given when the lottery performed during the CT is added to the set number may be included in the “same CT set”.

[Additional lottery table during CT set]
FIG. 56 is a configuration diagram of a CT set additional lottery table used in CT set additional lottery performed during CT.

  The number of sets during the CT addition lottery table includes each combination of the current CT state and the internal winning combination (sub-flag “reach-eye lip (reach-eye lip 1 to 4)”) and various lottery results of the additional lottery (non-winning / normal A relationship between CT winning / high-probability CT winning) and information on a lottery value associated with each lottery result is defined.

  As is clear from the CT set number addition lottery table, when any of the internal winning combinations “F_reach-eye lip A” to “F_reach-eye lip D” is won during CT, the CT set is additionally won. (CT sets are always stocked). Note that the stocked CT set is started after the currently operating CT set is completed.

<Playability during bonus state>
Next, the flow of the game in the bonus state will be described with reference to FIGS. 57A to 57C. FIG. 57A is a diagram showing a game flow when the gaming state shifts to the bonus state during the normal gaming state (ART non-winning), and FIG. 57B shows a case where the gaming state shifts to the bonus state during the normal ART. FIG. 57C is a diagram showing a game flow when the gaming state shifts to the bonus state during CT.

  In the pachislo 1 of the present embodiment, as shown in FIGS. 57A to 57C, a normal BB and a special BB are provided as bonus types in terms of amusement, and the type of the bonus is determined when shifting to the bonus state. Is done. At this time, if the special BB is determined, the game state shifts to the CT via the ART preparation state after the end of the bonus state. On the other hand, when the normal BB is determined, the transition destination gaming state differs depending on the state before transition to the bonus state.

  When the game state shifts from the normal game state to the normal BB, as shown in FIG. 57A, in the game during the normal BB, ART lottery is performed based on the internal winning combination. Then, when this ART lottery is won, after the end of the bonus state, the gaming state shifts to the normal ART via the ART preparation state. In this case, in the game in the bonus state after winning the ART lottery, an additional lottery is performed on the number of ART games.

  When the gaming state shifts from the normal ART to the normal BB, as shown in FIG. 57B, the CT lottery is performed at the end of the normal BB. The winning probability of this CT lottery is 50%, and when the winning is completed, the gaming state shifts to CT via the ART preparation state after the end of the bonus state. On the other hand, if the CT lottery is not won, after the bonus state ends, the gaming state shifts to the normal ART via the ART preparation state. In addition, in the game in the bonus state shifted from the normal ART, an additional lottery is also performed on the number of the ART games.

  When the gaming state shifts from CT to normal BB or special BB, as shown in FIG. 57C, after the bonus state ends, the gaming state shifts to CT via the ART preparation state. In the game in the bonus state shifted from CT, an additional lottery is also performed for the number of ART games.

<Various data tables used in games during the bonus state>
Next, various data tables used in the lottery processing performed in the game in the bonus state will be described with reference to FIGS. The various data tables described below are stored in the main ROM 102.

[Bonus type lottery table]
FIG. 58 is a configuration diagram of a bonus type lottery table used when determining a bonus type (normal BB, special BB).

  The bonus type lottery table includes a game state (CT and other) before shifting to the bonus state, various lottery results (bonus type: normal BB / special BB), and a lottery value associated with each lottery result. Define the correspondence with information. The process of determining the bonus type with reference to the bonus type lottery table is performed at the start of the bonus state.

[Additional lottery table for the number of ART games during bonus]
FIG. 59 is a configuration diagram of an ART lottery bonus in-game lottery table used in the ART lottery performed in the game in the bonus state and the additional lottery in the number of ART games.

  The number of lottery tables in the number of ART games during the bonus is associated with each combination of the current bonus type and the internal winning combination, various lottery results of the additional lottery (non-winning / 5 games /.../ 300 games), and each lottery result. The corresponding relationship with the information of the obtained lottery value is defined.

  In the present embodiment, in the ART non-winning state (the state until the ART lottery is won in the normal BB shifted from the general game state), the ART game number addition lottery table during the bonus is used for the ART lottery. Specifically, in the ART non-winning state, when one or more additional games (50 or more games in the example shown in FIG. 59) are determined by lottery using the additional number of ART games during bonus, the ART is determined. The lottery is won and the corresponding game number is given as the ART game number. On the other hand, in the state after the ART winning, the ART game number additional lottery table during the bonus is used only for the ART game number additional lottery.

[Bonus end CT lottery table]
FIG. 60 is a configuration diagram of a bonus end CT lottery table used in CT lottery performed at the end of the bonus state.

  The bonus lottery CT lottery table includes a combination of a bonus type (normal BB, special BB) and a gaming state (during normal CT, high probability CT) before shifting to the bonus state, and various lottery results of CT lottery ( The correspondence between non-winning / normal CT winning / high-probability CT winning) and information on a lottery value associated with each lottery result is defined. As is clear from the bonus end-time CT lottery table, for example, when the normal BB is performed during the normal ART, the CT is won with a probability of 50% at the end of the bonus state.

<Exceptional playability during general game state>
Next, with reference to FIG. 61, the flow of an exceptional game during the general game state will be described.

  In the flow of the basic gaming state in the pachislo 1 of the present embodiment, the gaming state shifts from the normal gaming state to the CZ during the general gaming state, and the gaming state shifts to the ART gaming state by winning the ART lottery in the CZ. I do. In the present embodiment, the ART gaming state is realized by performing notification in the RT4 state. In the present embodiment, as shown in FIG. 61, the transition control of the RT state is performed according to the symbol combination stopped and displayed.

  It should be noted that the symbol combination for shifting the RT state is the one that is stopped and displayed in accordance with the order of the stop operation (push order) of the player (see FIG. 24). By chance, the RT state may shift to the RT4 state. Further, in the RT4 state, there is a possibility that any of the internal winning combinations “F_reach-eye lip A” to “F_reach-eye lip D” may be determined, and therefore, even in the general gaming state (non-ART), Reach eyes (a symbol combination related to “reach eye lip”) to which a special privilege is given can be displayed.

  Therefore, in the pachislo 1 of the present embodiment, as shown in FIG. 61, the RT state accidentally shifts to the RT4 state during the general game state (non-ART), and the symbol combination related to the abbreviation “Reach eye lip” can be displayed. In this state, the game state can be shifted to the ART game state (normal ART) without passing through the CZ.

  More specifically, when any of the internal winning combinations “F_reach-eye lip A” to “F_reach-eye lip D” is determined in the general gaming state and in the RT4 state, a flag conversion lottery is performed. When this flag conversion lottery is won, a notification (navigation) for displaying a symbol combination related to the abbreviation “Reach eye lip” is performed, and an ART right is given. On the other hand, if any of the internal winning combinations “F_reach-eye lip A” to “F_reach-eye lip D” is determined in the general gaming state and in the RT4 state, if the flag conversion lottery is not won, A notification for displaying the symbol combination related to the abbreviation “Replay” is performed, and control is performed such that the symbol combination related to the abbreviation “Reach eye lip” is not displayed.

<Various data tables used in exceptional game control during the general game state>
Next, with reference to FIG. 62, a data table used in the lottery process performed in the exceptional game control in the above-described general game state will be described. The data table described below is stored in the main ROM 102.

[Non-ART flag conversion lottery table]
FIG. 62 is a configuration diagram of the non-ART flag conversion random determination table used in the flag conversion random determination performed in the game in the normal gaming state and in the RT4 state.

  The non-ART flag conversion lottery table includes an internal winning combination (“F_reach lip A” to “F_reach lip D”), a lottery result of flag conversion lottery (without conversion / with conversion), and each lottery result. The correspondence with the information of the associated lottery value is defined.

<Notification function by control on the main side>
In the conventional pachislot, information (navigation order, etc.) of reel stop operation (navigation order) is reported (navigated) by the sub (sub-control board 72) side control during ART. However, since the presence or absence of this notification affects the player's profit (so-called payout), in recent years, it is required that the main (main control board 71) that manages the player's profit perform notification. I have. Therefore, in the pachislo 1 of the present embodiment, as described above, the information display 6 controlled on the main side is provided with an instruction monitor (not shown) for notifying the information of the stop operation. A function of notifying information of a reel stop operation is provided.

  Here, FIGS. 63A to 63D show the correspondence between the notification (navi) performed on the main side and the notification (navi) performed on the sub side in the pachislo 1 of the present embodiment. FIG. 63A is a diagram showing the correspondence between the notification (navi) performed on the main side and the notification (navi) performed on the sub side in the ART preparation state, and FIG. 63B illustrates the state during the ART (normal ART or CT). FIG. 5 is a diagram showing a correspondence relationship between notification (navi) performed on the main side and notification (navi) performed on the sub side. FIG. 63C is a diagram showing the correspondence between the notification (navigating) performed on the main side and the notification (navigating) performed on the sub side during the RT5 state (between the BB1 flags). FIG. It is a figure which shows the correspondence of the notification (navigating) performed on the main side and the notification (navigating) performed on the sub side in (between BB2 flags).

  In the present embodiment, as shown in FIGS. 63A to 63D, the main (main control board 71) side notifies the information of the reel stop operation by displaying numerical values of “1” to “11” on the instruction monitor. I do. The numerical values of “1” to “11” displayed on the instruction monitor uniquely correspond to the contents of the stop operation reported by each.

  Specifically, the numerical values “1” to “3” indicate the types of the reels performing the first stop operation, respectively, and the numerical value “1” indicates that the first stop operation is performed on the left reel 3L. The numerical value "2" means that the first stop operation is performed on the middle reel 3C, and the numerical value "3" means that the first stop operation is performed on the right reel 3R.

  Numerical values “4” to “9” indicate the pressing order to be notified, respectively, and numerical value “4” means that the pressing order is “left, middle, right”, and numerical value “5”. Indicates that the pressing order is “left, right, middle”, the numerical value “6” indicates that the pressing order is “middle, left, right”, and the numerical value “7” indicates the pressing order. The order is “middle, right, left”, the numerical value “8” means that the pressing order is “right, left, middle”, and the numerical value “9” is the pressing order. It means “right, middle, left”.

  Numerical values "10" and "11" are for notifying the bonus combination, respectively, and the numerical value "10" is a symbol combination (symbol "white 7" -symbol "white 7") associated with the combination name "C_BB1". The symbol “white 7”), and the numerical value “11” means a symbol combination (symbol “blue 7” -symbol “blue 7” -symbol “blue 7”) associated with the combination name “C_BB2”.

  In addition, although the numerical values “1” to “11” notified on the main side (instruction monitor) uniquely correspond to the content of the stop operation to be notified, all the players clearly indicate based on the numerical values. It is not always possible to grasp the contents of the notification. For example, simply displaying the numerical value “6” on the instruction monitor on the main side may not be able to grasp the notification content depending on the player.

  Therefore, in the pachislo 1 of the present embodiment, the information on the stop operation of the stop button is also notified on the sub side together with the notification on the main side. Specifically, using the display device 11 (the projector mechanism 211 and the display unit 212) controlled on the sub side, the information on the stop operation is notified by the control on the sub side.

  For example, when notifying the pressing order in which the first stop operation is performed on the left reel 3L, the main side displays a numerical value “1” on the instruction monitor, and the sub side displays the left reel in the display screen of the display device 11 on the sub side. A numerical value "1" is displayed above 3L to notify that the left reel 3L is the target of the first stop operation. When notifying the pressing order “middle, left, right”, the main side displays the numerical value “6” on the instruction monitor, and the sub side displays the numerical value above the middle reel 3C in the display screen of the display device 11. "1" is displayed, a numerical value "2" is displayed above the left reel 3L, and a numerical value "3" is displayed above the right reel 3R. With this display, the pressing order is "middle, left, right". Notify that When the internal winning combination “F_BB1” is determined, the numerical value “10” is displayed on the instruction monitor on the main side, and “white 7” − “white 7” is displayed on the display screen of the display device 11 on the sub side. -Display information about the symbol combination of "white 7" and notify the player of the symbol to be aimed.

  Note that the timing of performing the notification on the main side can be set to an arbitrary timing as long as it is at least a period of one game in which the notification is performed. For example, the notification of the main side may be performed at the timing when the start operation of the player is detected (accepted), the notification of the main side may be performed at the start of the rotation of the reel, or the first to third stop operations. The main side may be notified at the timing when any of the stop operations is detected. On the other hand, it is preferable that the timing of the notification on the sub side be at least the timing before the first stop operation. Therefore, in the pachislo 1 of the present embodiment, the notification (navigation) is performed on both the main side and the sub side at the timing when the start operation is detected or at the timing when the rotation of the reel is started. Thereby, before the player performs the stop operation, the information of the stop operation is notified on both the instruction monitor on the main side and the display device 11 on the sub side.

  In the ART preparation state, as shown in FIG. 63A, a notification (navigation) called “bell navigation”, “maintenance lip navigation”, “RT3 transition lip navigation” and “RT4 transition lip navigation” is performed by the control on the main side. In “Bell Navi”, when the internal winning combination “F_3 choice bell — 1st” to “F_3 choice bell — 3rd” is determined, the symbol combination (refer to FIG. 29) related to the abbreviation “bell” is stopped and displayed on the activated line. Is announced. In the “maintenance lip navi”, when the internal winning combination “F_maintenance lip_1st” to “F_maintenance lip_3rd” is determined, the symbol combination (refer to FIG. 28) related to the abbreviation “replay” is stopped and displayed on the activated line. The order of pressing is notified. In the “RT3 shift lip navigation”, when the internal winning combination “F_RT3 shift lip — 1st” to “F_RT3 shift lip — 3rd” is determined, the symbol combination (refer to FIG. 28) related to the abbreviation “RT3 shift lip” is displayed on the activated line. The pressing order for the stop display is notified. Further, in the “RT4 shift lip navigation”, when the internal winning combination “F_RT4 shift lip — 123” to “F_RT4 shift lip — 3rd” is determined, a symbol combination (refer to FIG. 28) related to the abbreviation “RT4 shift lip” is set as an active line. The pressing order for stopping display at the top is notified.

  In addition, during the ART gaming state (normally ART or CT), as shown in FIG. 63B, by the control of the main side, notification called “bell navigation”, “maintenance lip navigation”, “RT3 transition lip navigation” and “RT4 transition lip navigation”. (Navi) is performed. In the game in the ART gaming state (RT4 state), a flag conversion lottery is performed, and based on the lottery result, a symbol combination related to the abbreviation “triple lip”, “reach eye lip” or “replay” is displayed. Is notified on the sub side only, and not on the main side.

  As described above, the symbol combination related to the abbreviation "triple lip" or "reach eye lip" is related to the grant of a special privilege, so the presence or absence of the notification affects the profit (payout) of the player. Although it seems to give, in the pachislot 1 of the present embodiment, the special benefit is actually given based on the lottery result of the flag conversion lottery, so the displayed symbol combination is the given benefit. Has no effect. Therefore, for example, in the state where the flag conversion lottery is won, even if the symbol combination related to the abbreviation “Replay” is stopped and displayed, a special privilege is given. On the other hand, in a state where the flag conversion lottery has not been won, even if the symbol combination related to the abbreviation “triple lip” or “reach eye lip” can be stopped and displayed, no special privilege is given. In the pachislo 1 of the present embodiment, when the symbol combination displayed in this manner does not affect the profit (payout) of the player, the sub-side is controlled without performing notification on the main-side instruction monitor. The notification is performed only on the display device 11 that is operating.

  In the RT5 state (inter-flag state), as shown in FIGS. 63C and 63D, information indicating that the player is aimed at a symbol combination related to a bonus combination carried over as an internal winning combination is notified. For example, when the internal winning combination “F_BB1” is carried over, as shown in FIG. 63C, a notification (navigation) called “white 7 navigation” is performed by the control of the main side, and the internal winning combination “F_BB2” is performed. Is carried over, as shown in FIG. 63D, a notification (navigation) called “blue 7 navigation” is performed by the control of the main side.

  In “White 7 Navi”, a symbol combination corresponding to the internal winning combination “F_BB1”, that is, a symbol combination related to the combination name “C_BB1” (“White 7”-“White 7”-“White 7”: see FIG. 28) Of stop operation for stopping display on the active line is notified. Further, in the “blue 7 navigation”, a symbol combination corresponding to the internal winning combination “F_BB2”, that is, a symbol combination (“blue 7” − “blue 7” − “blue 7”: FIG. 28) corresponding to the combination name “C_BB2” ) On the activated line is notified of the information of the stop operation.

  In the inter-flag state, when the bonus combination and any one of the internal winning combinations “out”, “F_special 1”, “F_special 2”, and “F_special 3” are determined, as described with reference to FIG. The symbol combination relating to the bonus combination (BB combination) can be stopped and displayed on the activated line. However, when the internal winning combination other than the internal winning combination “outside”, “F_special 1”, “F_special 2” and “F_special 3” and the bonus combination have been won, the symbol combination related to the bonus combination Cannot be stopped and displayed on the activated line. Therefore, in the present embodiment, as shown in FIGS. 63C and 63D, the carried-over bonus combination and the internal winning combination “outside”, “F_special combination 1”, “F_special combination 2”, and “F_special combination” Only when any one of "3" is a winning, a notification called "white 7 navigation" or "blue 7 navigation" is performed by the control of the main side. Therefore, in the present embodiment, a notification (navi) called “white 7 navi” or “blue 7 navi” under the control of the main side can be performed at an appropriate timing at which the bonus combination can be won.

  The pachislo 1 of the present embodiment is also provided with a function of notifying a bonus by, for example, displaying a bonus confirmation screen or turning on a bonus confirmation lamp. Therefore, the main side may perform a navigation called “white 7 navigation” or “blue 7 navigation” only after notifying that the bonus combination is determined as the internal winning combination (bonus notification).

  As the bonus notification, for example, an effect is generally performed in which an effect performed over a plurality of game periods (so-called continuous effect) is performed, and a bonus confirmation screen is displayed according to the result of the continuous effect. I have. If "Main 7 Navi" or the like is performed on the main side during such a continuous production, the result of the continuous production will be known in the middle, which may detract from interest. Therefore, in the present embodiment, after the bonus notification is performed, the main control board 71 performs a notification (navi) called “white 7 navigation” or “blue 7 navigation” under the control of the main side.

  Note that a method of enabling the main side to grasp the timing at which the bonus notification is performed is arbitrary. As one method, when the bonus combination is determined as the internal winning combination, the main control board 71 determines the number of games required until the end of the bonus notification, and after the game of this number of games is consumed, “white 7 navi” or A method of performing notification (navigation) called “blue 7 navigation” is conceivable. More specifically, after determining the number of games required until the end of the bonus notification, the main control board 71 notifies the sub control board 72 of the number of games. The sub-control board 72 controls the production according to the number of games, and displays the bonus confirmation screen at the timing when the games of the number of games have been consumed, so that the main side can grasp the timing at which the bonus is notified. Can be. That is, the main control board 71 counts the number of unit games after determining the bonus combination as the internal winning combination in a state where the bonus combination has not been carried over, and after the counting result reaches the predetermined number, the bonus combination is determined. And one of the internal winning combination “outside”, “F_special combination 1”, “F_special combination 2” and “F_special combination 3” is determined as the internal winning combination, “white 7 navi” or “ Blue 7 Navi ”.

  As another method, a method of controlling the bonus notification on the main side instead of the sub side can be considered. More specifically, when determining the bonus combination as the internal winning combination in a state where the bonus combination is not carried over, the main control board 71 determines an effect to be executed on the display device 11 (at least the number of games required for the effect), The sub-control board 72 is notified. The sub-control board 72 executes the notified effect and displays the bonus confirmation screen, so that it is possible to grasp the timing at which the bonus is notified on the main side.

  It should be noted that a configuration may be adopted in which the timing at which the bonus notification is performed by a method other than the two methods described above can be grasped on the main side. In this case, since the main control board 71 cannot receive a signal from the sub control board 72 or the like, it is necessary to grasp the timing at which the bonus notification is performed based on a signal that the main control board 71 can receive. For example, since a signal accompanying a stop operation can be received by the main control board 71, when a predetermined stop operation (for example, other than the forward push) is performed in a state where the bonus combination is determined as the internal winning combination. In addition, a method of making a bonus announcement is also conceivable. Specifically, the sub-control board 72 obtains information on the internal winning combination and information on the stop operation from the main control board 71, and issues a bonus notification when the combination of these pieces of information is a predetermined combination. By adopting such a method of the bonus notification, the trigger of the bonus notification can also be grasped by the main control board 71, so that the timing at which the bonus notification is performed on the main side can be grasped.

<Description of operation of main control circuit>
Next, the contents of various processes executed by the main CPU 101 of the main control circuit 90 using a program will be described with reference to FIGS.

[Processing at power-on (reset interrupt)]
First, the processing at the time of turning on the power of the pachislot 1 (reset interrupt) performed under the control of the main CPU 101 will be described with reference to FIGS. FIG. 64 is a flowchart showing the procedure of processing at the time of power-on (reset interrupt). FIGS. 65A to 65C show the sources for executing the processing of S2, S7 and S8, and S13 in the flowchart, respectively. FIG. 6 is a diagram illustrating an example of a program. The power-on (reset interrupt) processing shown in FIG. 64 is based on the fact that when the power supply management circuit 93 detects that the supply of the power supply voltage to the microprocessor 91 has been started, a reset signal of the microprocessor 91 is output. XSRST "terminal, thereby executing based on an interrupt request signal output from the interrupt controller 112 of the microprocessor 91 to the main CPU 101.

  First, the main CPU 101 determines whether or not a power supply monitoring port (power supply monitoring means) is in an ON state (S1).

  In S1, when the main CPU 101 determines that the power monitoring port is in the ON state (if S1 is YES), the main CPU 101 repeats the processing of S1. Here, the ON state of the power supply monitoring port means a state where the power supply voltage (DC + 5V) supplied to the main CPU 101 is not stable.

  On the other hand, in S1, when the main CPU 101 determines that the power supply monitoring port is not in the ON state (if S1 is NO), the main CPU 101 performs initialization processing of the timer circuit 113 (PTC) (S2). In this process, the main CPU 101 performs initialization of the timer circuit 113. More specifically, the main CPU 101 sets the frequency division ratio in a timer prescaler register (not shown), sets an interrupt enabled state in a timer control register (not shown), and sets a timer counter (not shown). Set the initial count value.

  Next, the main CPU 101 initializes the first serial communication circuit 114 (SCU1) between the main control circuit 90 and the sub control circuit 200, and initializes the second serial communication circuit 115 (SCU2) for the second interface board. Initialization processing is performed (S3). Next, the main CPU 101 performs an initialization process of the random number circuit 110 (RDG) (S4). Next, the main CPU 101 performs a write test on the main RAM 103 (S5).

  Next, as a result of the write test, the main CPU 101 determines whether or not writing to the main RAM 103 has been normally performed (S6).

  In S6, when the main CPU 101 determines that writing to the main RAM 103 has not been performed normally (NO in S6), the main CPU 101 performs the process of S13 described later. On the other hand, in S6, when the main CPU 101 determines that the writing to the main RAM 103 has been performed normally (YES in S6), the main CPU 101 sets the state of the timer control register (not shown) of the timer circuit 113. Is acquired (S7).

  Next, the main CPU 101 determines whether or not the current state is an interrupt processing occurrence timing based on the obtained state of the timer control register (S8). Specifically, the main CPU 101 determines whether 1.1172 ms has elapsed since the start of the timer count, based on the state of the obtained timer control register.

  In the present embodiment, when the timer time of 1.1172 ms is set by the initialization processing of the timer circuit 113 in S2, the count processing of the CPU built-in timer is started. After that, the status of the timer circuit 113 can be obtained by reading information of a timer control register (not shown). In the present embodiment, a bit (discrimination bit) capable of discriminating (referencing) whether or not the current state is an interrupt processing occurrence timing (whether or not the timer is in an interrupt state) is set in the timer control register. ) Is provided.

  Therefore, in the process of S7, the main CPU 101 reads information of the timer control register (not shown), and in the process of S8, the main CPU 101 sets the ON / OFF state of the determination bit in the timer control register ( By referring to “1” / “0”), it is determined whether or not the current state is the timing at which the interrupt processing occurs. When 1.1172 ms has elapsed from the start of counting by the timer circuit 113 (if the count value of the timer circuit 113 is 0), the determination bit is turned on.

  In S8, when the main CPU 101 determines that the current state is not the timing of the occurrence of the interrupt processing (if S8 is NO), the main CPU 101 returns the processing to S7 and repeats the processing from S7.

  On the other hand, in S8, when the main CPU 101 determines that the current state is the timing of the occurrence of the interrupt processing (if S8 is YES), the main CPU 101 performs the sum check processing (not specified) (S9). . In this process, the main CPU 101 performs a sum check process of the main RAM 103, and the work of this process is performed in a non-defined work area in the main RAM 103 (see FIG. 12C). The program used in the sum check process is stored in a non-defined area in the main ROM 102 (see FIG. 12B). The details of the sum check process will be described later with reference to FIGS. 79 and 80 described later.

  Further, in S8, when the main CPU 101 determines that the current state is the timing of the occurrence of the interrupt processing (if S8 is YES), the main CPU 101 executes an interrupt processing described later before the processing of S9. (See FIG. 158 described later). Then, by this interrupt processing, a no-operation command is transmitted from the main control circuit 90 (main control board 71) to the sub-control circuit 200 (sub-control board 72).

  After the processing in S9, the main CPU 101 determines whether or not the setting key type switch 54 is in the ON state (S10).

  In S10, when the main CPU 101 determines that the setting key type switch 54 is in the ON state (if S10 is YES), the main CPU 101 performs the processing of S15 described later. On the other hand, in S10, when the main CPU 101 determines that the setting key type switch 54 is not in the ON state (NO in S10), the main CPU 101 determines the sum check based on the result of the sum check processing in S9. It is determined whether the result is normal (S11).

  In S11, when the main CPU 101 determines that the sum check determination result is not normal (NO in S11), the main CPU 101 performs the process of S13 described later. On the other hand, when the main CPU 101 determines in S11 that the sum check determination result is normal (YES in S11), the main CPU 101 performs a game return process (S12). In this process, the main CPU 101 performs a process of returning the state of the game to the state before the power interruption detection. The details of the game return process will be described later with reference to FIG. 66 described later.

  If the determination in S6 or S11 is NO, the main CPU 101 displays a character string "rr" indicating that an error has occurred on the information display 6 (7-segment LED display) (S13). After that, the main CPU 101 repeats the WDT clear processing (S14).

  Here, returning to the process of S10 again, if the determination of S10 is YES, the main CPU 101 performs a setting change confirmation process (S15). In this process, the main CPU 101 mainly performs a process of generating and storing a setting change command at the start of the setting change. The details of the setting change confirmation processing will be described later with reference to FIG.

  Next, the main CPU 101 performs a RAM initialization process (S16). In this process, the main CPU 101 sets the address of “at the time of RAM abnormality or at the start of setting change” in the gaming RAM area of the main RAM 103 shown in FIG. Information is erased (cleared) up to the last address of the use RAM area. Then, after the processing of S16, the main CPU 101 starts a main processing described later (see FIG. 82 described later).

  In the present embodiment, the process at the time of power-on (reset interrupt) is performed as described above. The processing of S2 during the above-described power-on (reset interrupt) processing is performed by the main CPU 101 sequentially executing each source code specified by the source program of FIG. 65A.

  In the source program of FIG. 65A, 10 MHz (supply clock is 20 MHz) is set as the CPU clock, 228 is set as the prescaler register setting value, and 49 is set as the initial count value. As a result, 1.1172 ms (= 1 / (10 MHz / 288) × 49) is calculated as the timer time (execution cycle) of the interrupt processing.

  The processing of S7 and S8 during the above-described power-on (reset interrupt) processing is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 65B. Specifically, the process of acquiring the state of the timer control register in S7 is executed by an “LD” instruction in FIG. 65B, and the determination process in S8 is executed by a “JBIT” instruction in FIG. 65B. The “LD” instruction in FIG. 65B and the “JBIT” instruction in FIG. 65B are repeatedly executed until 1.1172 ms elapses from the start of counting by the timer circuit 113. When 1.1172 ms elapses from the start of counting by the timer circuit 113, Then, an interrupt request signal is output from the timer circuit 113 to the main CPU 101 via the interrupt controller 112. The main CPU 101 starts the interrupt processing in the first 1.1172 ms cycle after the power is restored, triggered by the input of the interrupt request signal.

  In the interrupt processing of the first 1.1172 ms period immediately after the return of the power supply (after initialization at the time of power-on), since the command related to the game operation is not set, the main control circuit 90 sends the sub-control circuit 200 A no-operation command is sent. By permitting the interrupt processing immediately after the return of the power, the no-operation command is transmitted in the shortest time after the return of the power, and the communication connection between the main control circuit 90 and the sub-control circuit 200 can be established. The communication operation between the main control circuit 90 and the sub control circuit 200 can be stabilized.

  The communication parameters 1 to 5 constituting the no-operation command transmitted in this communication operation are set to the data stored in the L register, the H register, the E register, the D register, and the C register when the power is restored. Is done. Therefore, in the present embodiment, the data set in the communication parameters 1 to 5 of the no-operation command transmitted in the first interrupt processing after the power return is made different (undefined) each time the power is returned. Can be. That is, the sum value (BCC) of the no-operation command transmitted in the interrupt processing immediately after the power is restored (after initialization at the time of turning on the power) can be made different every time the power is restored. In this case, illegal acts such as goto can be suppressed.

  Further, the process of S13 (interrupt prohibition process) during the process of turning on the power (reset interrupt) described above is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 65C. . Then, control for displaying the error code “rr” on the 2-digit 7-segment LED in the information display 6 is executed by one source code “LDW HL, 100H * cZCHRAR + cBX_PAYSEG”, as shown in FIG. 65C. The output operation of the 7-segment common output data and the output operation of the 7-segment cathode output data to the 2-digit 7-segment LED are performed simultaneously.

  That is, in the pachislo 1 of the present embodiment, the 7-segment common output data and the 7-segment cathode output data are simultaneously output when the 2-digit 7-segment LED is dynamically turned on. In this case, the number of instruction codes required for the dynamic lighting control of the 7-segment LED on the source program can be reduced, and the capacity of the source program (used capacity of the main ROM 102) can be reduced. Therefore, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  Here, the “7-segment common output data” is LED drive data output to the common (common) terminal of the 7-segment LED when dynamically controlling the 7-segment LED, and the “7-segment cathode output data” is , LED driving data output to each cathode terminal of the 7-segment LED when the 7-segment LED is dynamically turned on.

[Game return processing]
Next, with reference to FIGS. 66 and 67, the game return process performed in S12 during the power-on (reset interrupt) process (see FIG. 64) will be described. FIG. 66 is a flowchart showing the procedure of the game return process, and FIG. 67 is a diagram showing an example of a source program for executing the processes of S25 to S32 in the flowchart.

  First, the main CPU 101 sets a stack pointer at the time of power failure in the stack pointer (SP) (S21). Next, the main CPU 101 clears (turns off) the on-edge data of the input port before the one-interrupt processing and the currently set on-edge data (S22). Next, the main CPU 101 sets the backup data of the output port to the output port (S23). Next, the main CPU 101 reads the data of the input port, and saves the data in the data storage area of the input port at present and before one interrupt processing (S24).

  Next, the main CPU 101 sets the address of the rotation control data storage area (S25). Next, the main CPU 101 sets the number of reels to be checked ("3" in the present embodiment) (S26).

  Next, the main CPU 101 acquires reel control management information (data related to display column fluctuation control at the time of power interruption) based on the set address of the rotating drum control data storage area (S27). The reel control management information (variation control management information of the display column) is information relating to the control state (rotation state) of each reel, and is backed up and stored at the time of power failure.

  Next, the main CPU 101 determines whether or not the reel control management information is information corresponding to the rotation status during the acceleration of the reel, the waiting at the constant speed, or the constant speed (S28).

  In S28, when the main CPU 101 determines that the condition of S28 is not satisfied (NO in S28), the main CPU 101 performs the process of S31 described later. On the other hand, in S28, when the main CPU 101 determines that the condition of S28 is satisfied (when S28 is YES), the main CPU 101 clears the spinning control data (reel control management information) (S29). With this process, after the game returns, the reel rotation control is started from the acceleration process. Next, the main CPU 101 sets the operation timing value of the reel (the execution start timing “1” of the turning drum control data) (S30). If "1" is set to the reel operation timing, the excitation change timing is reached in the reel control processing (see S903 in FIG. 158 described later), and thus the main CPU 101 accelerates the reel rotation control. Start with.

  After the processing of S30 or when the determination in S28 is NO, the main CPU 101 subtracts 1 from the value of the reel number (S31). Next, the main CPU 101 determines whether or not the value of the number of reels after the subtraction is “0” (S32).

  In S32, when the main CPU 101 determines that the value of the number of reels after the subtraction is not “0” (NO in S32), the main CPU 101 changes the reel to be checked and shifts the processing to the processing of S27. The process returns to step S27 and the process from step S27 is repeated.

  On the other hand, in S32, when the main CPU 101 determines that the value of the number of reels after the subtraction is “0” (if S32 is YES), the main CPU 101 performs a RAM initialization process (S33). In this process, the main CPU 101 sets the address at the time of "power recovery" in the game RAM area of the main RAM 103 shown in FIG. 12C as a start address of the initialization start, and sets the last address of the game RAM area from the start address. Delete (clear) the information up to the address.

  Next, the main CPU 101 restores the data of all the registers evacuated at the time of detecting the power interruption to all the registers (S34). Then, after the processing of S34, the main CPU 101 ends the game return processing, and returns the processing to the processing at the time of detecting the power failure.

  In the present embodiment, the game return processing is performed as described above. In the game return processing of the present embodiment, as described above, the input / output state of each port at the time of power failure occurs is secured at the time of power return, and when the reels are rotating at the time of power failure, the reel control Information is acquired and processing necessary for starting reel re-spin is also performed (see the processing of S25 to S32). Therefore, in the present embodiment, even when the power is restored from the power interruption during the rotation of the rotating drum, the reel re-rotation control can be stably performed, and the player does not feel uncomfortable.

  The processing of S25 to S32 during the above-described game return processing is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 67. As described above, in the microprocessor 91 with the security function for the gaming machine used in the pachislo 1 of the present embodiment, various instruction codes dedicated to the main CPU 101 are provided. For example, the “LDQ” command (predetermined read command) in FIG. 67 is one of the main CPU 101 dedicated command codes.

  For example, when the source code “LDQ HL, k” is executed on the source program, the address specified by the contents (storage data) of the Q register and the 1-byte integer k (direct value) is stored in the HL register. Is loaded. At this time, the content of the Q register becomes the upper address value of the designated address, and the integer k (direct value) becomes the lower address value of the designated address. Therefore, when the source code “LDQ HL, .LOW.wR1_CTRL” in FIG. 67 is executed, the contents of the Q register (the upper address value of the address of the trunk control data storage area) and the integer value “. LOW.wR1_CTRL "(the lower address value of the address of the spine control data storage area) (the address of the spine control data storage area) is loaded into the HL register. Note that “.LOW.” Is not an actual instruction but a pseudo instruction. In the function of this pseudo instruction, only the lower address of the address of the storage area defined after “.LOW.” Is validated. The pseudo instruction is not an instruction stored in an actual ROM, but an instruction that a conversion program (assembler) refers to when converting a source file into a format for storing in a ROM.

  As described above, in the present embodiment, the main ROM 101, the main RAM 103, and the memory map I / O are stored in immediate values by using the instruction code dedicated to the main CPU 101 for specifying the address using the Q register (extended register). Can be accessed. In this case, the instruction code relating to the address setting can be omitted from the source program, and the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Setting change confirmation process]
Next, with reference to FIGS. 68 and 69, a description will be given of the setting change confirmation processing performed in S15 during the power-on (reset interrupt) processing (see FIG. 64). FIG. 68 is a flowchart showing the procedure of the setting change confirmation process, FIG. 69A is a diagram showing an example of a source program for executing the processes of S44 to S47 in the flowchart, and FIG. FIG. 11 is a diagram illustrating an example of a source program for executing the process of S57 in the flowchart.

  First, the main CPU 101 performs an initialization process for a non-defined RAM area in the main RAM 103 (S41). Next, the main CPU 101 performs one interrupt wait process (S42). In this process, the main CPU 101 waits until the process of transmitting the no-operation command to the sub-control circuit 200 by the interrupt process ends.

  Next, the main CPU 101 performs a RAM initialization process (S43). In this process, the main CPU 101 sets the address of “at the time of RAM abnormality or at the start of setting change” in the gaming RAM area of the main RAM 103 shown in FIG. Information is erased (cleared) up to the last address of the use RAM area.

  Next, the main CPU 101 determines whether or not the setting key type switch 54 is on (S44). The setting key (not shown) inserted into the setting key type switch 54 is an operation key for operating the setting (settings 1 to 6) of the pachislot 1. When the setting key is turned on, the setting key (not shown) is used. The key switch 54 is turned on.

  In S44, when the main CPU 101 determines that the setting key type switch 54 is not in the ON state (when S44 is NO), the main CPU 101 ends the setting change confirmation processing, and turns on the processing (reset interruption). The process proceeds to S16 of the time process (see FIG. 64). On the other hand, in S44, when the main CPU 101 determines that the setting key-shaped switch 54 is in the ON state (if S44 is YES), the main CPU 101 performs a medal acceptance prohibition process (S45). By this processing, the solenoid of the selector 66 (see FIG. 7) is not driven, and the inserted medals are discharged from the medal payout opening 24 (see FIG. 2).

  Next, the main CPU 101 sets the setting change start or setting confirmation start information (005H: first value) in the L register, and performs a generation and storage process of a setting change command (setting change / setting check start) (S46). . In this processing, the main CPU 101 generates setting change command data (first command data) transmitted from the main control circuit 90 to the sub control circuit 200 at the start of the setting change processing or the setting confirmation processing, and converts the command data. The data is stored in a communication data storage area provided in the main RAM 103. The details of the setting change command generation and storage processing will be described later with reference to FIG. 70 described later. The setting change command (setting change / setting confirmation start) stored in the communication data storage area is transmitted from the main control circuit 90 to the sub control circuit 200 by a communication data transmission process in an interrupt process described later with reference to FIG. Sent to.

  Next, the main CPU 101 sets the error count relay to the ON state (S47). Next, the main CPU 101 determines whether setting change or setting confirmation has been performed (S48).

  In S48, when the main CPU 101 determines that the setting has not been changed (the setting has been confirmed) (if S48 is NO), the main CPU 101 performs the processing of S55 described later.

  On the other hand, in S48, when the main CPU 101 determines that the setting has been changed (the setting confirmation has not been performed) (if S48 is YES), the main CPU 101 performs a setting value update process (S49). ). Next, the main CPU 101 performs a 7-segment display setting process of the set value (S50). With this process, the updated set value can be displayed on the 7-segment LED in the information display 6.

  Next, the main CPU 101 determines whether or not the reset switch 76 is on (S51).

  In S51, when the main CPU 101 determines that the reset switch 76 is in the ON state (if S51 is YES), the main CPU 101 returns the process to S49, and repeats the processes from S49. On the other hand, in S51, when the main CPU 101 determines that the reset switch 76 is not in the ON state (when S51 is NO), the main CPU 101 determines whether the start switch 79 is in the ON state (S52). .

  In S52, when the main CPU 101 determines that the start switch 79 is not in the ON state (if S52 is NO), the main CPU 101 returns the processing to S51 and repeats the processing from S51. On the other hand, in S52, when the main CPU 101 determines that the start switch 79 is on (in the case of YES determination in S52), the main CPU 101 sets the start value in the set value storage area (not shown) provided in the main RAM 103. The value is stored (S53).

  Next, the main CPU 101 determines whether or not the setting key type switch 54 is off (S54).

  In S54, when the main CPU 101 determines that the setting key type switch 54 is not in the OFF state (NO in S54), the main CPU 101 repeats the processing of S54. On the other hand, in S54, when the main CPU 101 determines that the setting key type switch 54 is in the OFF state (if S54 is YES), the main CPU 101 performs the processing of S55 described later.

  When S48 is NO or S54 is YES, the main CPU 101 determines whether setting change or setting confirmation has been performed (S55).

  In S55, when the main CPU 101 determines that the setting has not been changed (the setting has been confirmed) (if S55 is NO), the main CPU 101 performs the process of S57 described later. On the other hand, in S55, when the main CPU 101 determines that the setting has been changed (the setting confirmation has not been performed) (if S55 is YES), the main CPU 101 performs a RAM initialization process (S56). . In this process, the main CPU 101 sets an address (the next address of the setting value storage area) (not shown) in the game RAM area of the main RAM 103 shown in FIG. Then, the information from the start address to the end address of the game RAM area is erased (cleared).

  After the processing of S56 or when the determination of S55 is NO, the main CPU 101 sets the information (004H: second value) of the end of the setting change or the end of the setting check in the L register, and sets the setting change command (the end of the setting change / setting check). ) Is performed (S57). In this processing, the main CPU 101 generates setting change command data (second command data) transmitted from the main control circuit 90 to the sub control circuit 200 at the end of the setting change processing or the setting confirmation processing, and generates the command data. The data is stored in a communication data storage area provided in the main RAM 103. The details of the setting change command generation and storage processing will be described later with reference to FIG. 70 described later. The setting change command (setting change / setting confirmation end) stored in the communication data storage area is transmitted from the main control circuit 90 to the sub control circuit 200 by a communication data transmission process in an interrupt process described later with reference to FIG. Sent to. Then, after the processing in S57, the main CPU 101 ends the setting change confirmation processing, and shifts the processing to the processing in S16 of the processing at power-on (reset interrupt) (see FIG. 64).

  In the present embodiment, the setting change confirmation processing is performed as described above. The processing of S44 to S47 during the above-described setting change confirmation processing is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 69A. Among them, for example, the state determination processing of the setting key in S44 is executed by the source code “BITQ 7, (.LOW. (WIBUF + 4))” in FIG. 69A, and the error count relay in S47 is set to the ON state. The processing is executed by the source code “SETQ 1, (.LOW.wECRREQ)” in FIG. 69A.

  The “BITQ” instruction and the “SETQ” instruction are both instruction codes dedicated to the main CPU 101 for specifying an address using a Q register (extension register).

  For example, when the source code “BITQ b, (k)” is executed on the source program, the data stored in the Q register (upper address value) and the 1-byte integer value k (direct value: lower address value) ) Is checked, and if "1" is stored in the bit b, "0" is set to the zero flag (bit 6: see FIG. 11) of the flag register F. If "0" is stored in the bit b, "1" is set in the zero flag (predetermined bit area) of the flag register F. Therefore, when the source code “BITQ 7, (.LOW. (WIBUF + 4)” in FIG. 69A is executed, the address specified by the data stored in the Q register and the integer value “.LOW. (WIBUF + 4)” Is checked, and if "1" is stored in the bit 7, "0" is set in the zero flag of the flag register F. If "0" is stored in the bit 7, , "1" is set to the zero flag of the flag register F.

  When the source code “SETQ b, (k)” is executed on the source program, for example, the data stored in the Q register (upper address value) and the 1-byte integer value k (direct value: lower "1" is set to bit b of the memory at the address specified by (address value). Therefore, when the source code “SETQ 1, (.LOW.wECRREQ)” in FIG. 69A is executed, the data stored in the Q register and the memory at the address specified by the integer value “.LOW.wECRREQ” are read. Bit 1 is set to "1".

  That is, in the setting change confirmation processing of the present embodiment, various instruction codes dedicated to the main CPU 101 using the Q register (extended register) as described above are used. Thus, the user can access the main ROM 102, the main RAM 103, and the memory map I / O. In this case, the instruction code related to the address setting can be omitted, and the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space of the main ROM 102 can be increased, and the processing speed can be increased.

  The generation and storage processing of the setting change command (initialization command) performed at the start of the setting change / setting check in S46 during the setting change check processing described above is performed by the main CPU 101 executing the “CALLF” instruction in FIG. 69A. The generation and storage processing of the setting change command (initialization command) performed at the end of the setting change / setting confirmation in S57 described above is performed by the main CPU 101 executing the “CALLF” instruction in FIG. 69B. The “CALLF” instruction is also an instruction code dedicated to the main CPU 101.

  For example, when the source code “CALLF mn” is executed on the source program, the current value (storage data) of the PC register (program counter PC: see FIG. 11) is designated by the stack pointer (SP). It is stored in the memory, the stack pointer is updated by -2, "mn" is stored in the PC register, and the processing jumps to the address specified by "mn". However, the “CALLF” instruction is a two-byte instruction, and the address range in which the jump can be performed is 0000H to 11FFH. Therefore, for example, when the source code “CALLF SB_PCINIT_00” in FIG. 69A is executed, the current value of the PC register is stored in the memory specified by the stack pointer (SP), and the stack pointer is updated by −2. , “SB_PCINIT_00” is stored in the PC register, and the process jumps to the address specified by “SB_PCINIT_00”.

  In the present embodiment, an instruction code called a “CALL” instruction is also prepared as an instruction code of the same type as the “CALLF” instruction. Then, when, for example, the source code “CALL mn” is executed on the source program, the value (stored data) of the current PC register (program counter PC: see FIG. 11) is stored in the same manner as the “CALLF” instruction. The data is stored in the memory specified by the stack pointer (SP), the stack pointer is updated by −2, “mn” is stored in the PC register, and the processing jumps to the address specified by “mn”. However, the “CALL” instruction is a three-byte instruction, and the jumpable address range is different from that of the “CALLF” instruction, and the jumpable address range is from 0000H to FFFFH. Since the “CALLF” instruction is an instruction code having a smaller number of bytes than the “CALL” instruction, the capacity of the source program (the used capacity of the main ROM 102) can be reduced and the processing efficiency can be improved. be able to.

  In the setting change confirmation process of the present embodiment, as shown in FIGS. 69A and 69B, the jump destination address “SB_PCINIT_00” specified by the “CALLF” instruction in S46 is changed to the jump destination address specified by the “CALLF” instruction in S57. Address. That is, in the present embodiment, the generation and storage processing of the setting change command (initialization command) transmitted to the sub control circuit 200 at the time of setting change (at the time of starting the gaming machine), at the start of setting check (during normal operation), and at the end of setting check Are the same as each other, and the source program of the setting change command generation and storage process used in both the processes of S46 and S57 is shared (moduleed).

  In this case, since it is not necessary to separately provide a source program for the setting change command generation and storage process in both the processes S46 and S57, the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. . As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Setting change command generation and storage processing]
Next, with reference to FIG. 70 and FIG. 71, the setting change command generation and storage processing performed in S46 and S57 during the setting change confirmation processing (see FIG. 68) will be described. FIG. 70 is a flowchart showing the procedure of the setting change command generation and storage processing, and FIG. 71 is a diagram showing an example of a source program for executing the setting change command generation and storage processing.

  First, the main CPU 101 sets information of the set values (1 to 6) in the E register (S61). Next, the main CPU 101 sets the information of the RT state in the C register (S62). Next, the main CPU 101 sets the command type information (02H) of the setting change command in the A register (S63).

  Next, the main CPU 101 performs a communication data storage process (S64). In this process, the main CPU 101 sets the information set in each register in S61 to S63 and the information set in the D register in S46 or S57 (see FIG. 68) (setting change start / setting change end / setting change (Setting confirmation start / setting confirmation end) to generate setting change command data, and save the generated command data in the communication data storage area. The details of the communication data storage processing will be described later with reference to FIG. 72 described later.

  After the processing of S64, the main CPU 101 ends the setting change command generation and storage processing. When ending the setting change command generation and storage processing performed in S46 during the setting change confirmation processing (see FIG. 68), the main CPU 101 switches the processing to the setting change confirmation processing (see FIG. 68) after the processing in S64. The process moves to S47. When ending the setting change command generation / storage processing performed in S57 during the setting change confirmation processing (see FIG. 68), the main CPU 101 ends the setting change command generation / storage processing after the processing in S64, and sets The change confirmation processing (see FIG. 68) also ends.

  In the present embodiment, the setting change command generation and storage processing is performed as described above. Note that the above-described setting change command generation and storage processing is performed by the main CPU 101 sequentially executing each source code defined in the source program of FIG. 71.

  As described above, in the setting change command generation / storage processing, the setting status is stored in the D register as the communication parameter 4 immediately before the execution of the setting change command generation / storage processing, and the setting value is set during the execution of the setting change command generation / storage processing. Is stored in the E register as the communication parameter 3, and the RT information is stored in the C register as the communication parameter 5. That is, among the communication parameters 1 to 5 constituting the setting change command (initialization command), the communication parameters 3 to 5 are communication parameters (use parameters) used (analyzed) on the sub-control circuit 200 side. New information is set in the communication parameter. On the other hand, the other communication parameters 1 and 2 that constitute the setting change command (initialization command) are communication parameters (unused parameters) that are not used (analyzed) on the sub-control circuit 200 side. In this case, the values currently stored in the L register and the H register at the present time are set. Therefore, the values of the communication parameters 1 and 2 at the time of transmitting the setting change command (initialization command) are undefined. In this case, the sum value (BCC) of the setting change command can be set to an indefinite value for each transmission, and fraudulent acts such as goto can be suppressed.

[Communication data storage processing]
Next, with reference to FIGS. 72 and 73, for example, a description will be given of the communication data storage processing performed in S64 during the setting change command generation storage processing (see FIG. 70). The communication data storage process is executed not only when a setting change command is generated but also when another command is generated. FIG. 72 is a flowchart showing the procedure of the communication data storage process, and FIG. 73 is a diagram showing an example of a source program for executing the processes of S71 to S76 during the communication data storage process.

  First, the main CPU 101 stores the data set in the A register as communication command type data in a communication data temporary storage area (not shown) in the main RAM 103 (S71). Next, the main CPU 101 stores the data set in the H register and the L register as the communication command parameters 1 and 2 in the communication data temporary storage area (predetermined storage area) in the main RAM 103 (S72). .

  Next, the main CPU 101 stores the data set in the D register and the E register as communication command parameters 3 and 4 in the communication data temporary storage area in the main RAM 103 (S73). Next, the main CPU 101 stores the data set in the B register and the C register in the communication data temporary storage area in the main RAM 103 as the communication command parameter 5 and the RT state data, respectively (S74).

  Next, the main CPU 101 generates BCC data (sum value) of the communication command from the data values set in the A register to the L register (S75). Next, the main CPU 101 stores the generated BCC data in the communication data temporary storage area in the main RAM 103 (S76).

  After the processing of S76, the main CPU 101 determines whether there is a free space in the communication data storage area in the main RAM 103 (S77). In the present embodiment, a maximum of nine pieces of command data can be stored in the communication data storage area (see FIG. 75B described later).

  In S77, when the main CPU 101 determines that there is no free space in the communication data storage area (when S77 is NO), the main CPU 101 ends the communication data storage processing and, for example, performs a setting change command generation storage processing ( 70 is also ended.

  On the other hand, in S77, when the main CPU 101 determines that there is a free space in the communication data storage area (in the case of YES determination in S77), the main CPU 101 stores the communication data in the temporary communication data storage area by the processing of S71 to S76 described above. The stored communication data is stored in the communication data storage area as communication command data (S78).

  Next, the main CPU 101 performs a communication data pointer update process (S79). In this process, the main CPU 101 mainly performs a process of updating the communication data pointer indicating the storage address of the communication data in the communication data storage area. The details of the communication data pointer updating process will be described later with reference to FIG. 74 described later.

  Then, after the process of S79, the main CPU 101 ends the communication data storage process and also ends, for example, the setting change command generation storage process (see FIG. 70).

  In the present embodiment, the communication data storage processing is performed as described above. Note that the processing of S71 to S76 during the above-described communication data storage processing is performed by the main CPU 101 sequentially executing each source code defined in the source program of FIG. 73. In this series of processing, as shown in FIG. 73, the processing for storing the type data of the communication command, the various communication parameters, the game state flag data, and the BCC data included in the command data is performed in the Q register on the source program. This is executed using an “LDQ” instruction, which is an instruction code dedicated to the main CPU 101 for specifying an address using an (extension register).

  Specifically, by executing the source code “LDQ (.LOW. (WPDT_TMP + 0)), A”, the type data of the communication command stored in the A register is changed to the stored data (upper address value) of the Q register by 1 It is stored in the communication data temporary storage area at the address specified by the byte integer value “.LOW. (WPDT_TMP + 0)” (lower address value). Also, by executing the source code “LDQ (.LOW. (WPDT_TMP + 1)), HL”, the communication parameter 1 stored in the L register becomes the data stored in the Q register and the 1-byte integer value “.LOW. (WPDT_TMP + 1)”. The communication parameter 2 stored in the communication data temporary storage area of the address designated by "." And stored in the H register is stored in the communication data temporary storage area of the next address. Also, by executing the source code “LDQ (.LOW. (WPDT_TMP + 3)), DE”, the communication parameter 3 stored in the E register changes the data stored in the Q register and the 1-byte integer value “.LOW. (WPDT_TMP + 3)”. The communication parameter 4 stored in the communication data temporary storage area of the address designated by "." And stored in the D register is stored in the communication data temporary storage area of the next address. By executing the source code “LDQ (.LOW. (WPDT_TMP + 5)), BC”, the communication parameter 5 stored in the C register is changed to the data stored in the Q register and the 1-byte integer value “.LOW. (WPDT_TMP + 5). The game state flag data stored in the communication data temporary storage area at the address designated by "." And stored in the B register is stored in the communication data temporary storage area at the next address.

  Further, BCC data, which is the sum value of the command data set in the communication data storing process, is calculated by executing a series of source codes “ADD (addition instruction code) A, H” to “ADD A, B”. Stored in a register. By executing the source code “LDQ (.LOW. (WPDT_TMP + 7)), A”, the BCC data stored in the A register is changed from the data stored in the Q register to the 1-byte integer value “.LOW. (WPDT_TMP + 7)”. Are stored in the communication data temporary storage area at the address specified by.

  As described above, in this embodiment, when one packet (8 bytes) of communication data (command data) is created, various parameters are transferred from the register and stored in the communication data temporary storage area (communication buffer). In such a method of creating command data, the data stored in each register when the command is generated is stored as it is in the communication data temporary storage area as various parameters of the command data. Therefore, when command data including an unused parameter is created, the value of the unused parameter becomes an undefined value at each creation. In this case, the sum value (BCC data) of the command data can be changed every time a command is created, even if there is command data of the same type and the values of the parameters used are the same. Further, in the present embodiment, the calculation of the sum value, which is one of the error codes, is calculated by ADD (addition instruction code), but instead of the addition instruction code, SUB (subtraction instruction code) and XOR (exclusive OR) are used. The same effect can be obtained even if an error code is calculated based on the instruction code. Further, the same effect can be obtained by calculating an error code using MUL (multiplication instruction code) or DIV (division instruction code), which are instructions dedicated to the main CPU 101.

  Therefore, in the present embodiment, it is necessary to make the analysis of the communication data difficult and suppress the fraudulent acts such as goto by setting the unused parameters to indefinite values, and it is necessary to add unnecessary goto countermeasure processing. Therefore, the compression of the program capacity of the main control circuit 90 due to the addition of the goto countermeasure processing can be suppressed.

[Communication data pointer update processing]
Next, the communication data pointer update processing performed in S79 during the communication data storage processing (see FIG. 72) will be described with reference to FIGS. 74 and 75. FIG. 74 is a flowchart showing the procedure of the communication data pointer update process, FIG. 75A is a diagram showing an example of a source program for executing the communication data pointer update process, and FIG. FIG. 14 is a diagram illustrating a configuration of a communication data storage area actually set on a source program of an update process.

  First, the main CPU 101 acquires the value of the currently set communication data pointer (S81).

  Next, the main CPU 101 adds and updates the value of the communication data pointer for one packet (8 bytes) (S82). In this process, if the updated communication data pointer value is equal to or larger than the upper limit size of the communication data storage area (see FIG. 75B), the main CPU 101 sets the updated communication data pointer value to “0”. , Thereby invalidating all the command data stored in the communication data storage area (making the same state as the discarded state).

  In this embodiment, the amount of data (one packet) transmitted in one transmission operation is 8 bytes. That is, in the present embodiment, one command data can be transmitted by one transmission operation. Further, in the present embodiment, since a maximum of nine command data can be stored in the communication data storage area (see FIG. 75B), the upper limit size of the communication data storage area is 72 bytes (= 8 bytes × 9). . Therefore, in the present embodiment, the range of the communication data pointer is set to “0” to “71”, and in the process of S82, the value of the communication data pointer after updating (when the communication data pointer is updated by +8) is “71 ( In this case, the value of the updated communication data pointer is set to “0” (the communication data storage destination address is returned to the first address), and the communication data storage is performed. Invalidate all command data stored in the area (make the same state as the discarded state). When the value of the communication data pointer is set to "0", the next time command data is stored in the communication data storage area, the command data is stored from the start address of the communication data storage area. The new command data overwrites the new command data. Therefore, in this embodiment, it is not necessary to initialize (clear) the communication data storage area when the value of the communication data pointer exceeds “71 (upper limit)”.

  Then, after the process of S82, the main CPU 101 ends the communication data pointer update process and also ends the communication data storage process (see FIG. 72).

  In the present embodiment, the communication data pointer updating process is performed as described above. The above-described communication data pointer updating process is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 75A. Among them, the update processing of the communication data pointer in S82 is executed by the “ADD” instruction and the “ICPLD” instruction (predetermined update instruction) in FIG. 75A, and this “ICPLD” instruction is also dedicated to the main CPU 101. Instruction code.

  For example, when the source code “ICPLD A, n” is executed on the source program, the content (stored data) of the A register is compared with the integer n, and when the content of the A register is smaller than the integer n, , A register is added with “1”, and if the content of the A register is an integer n or more, “0” is set in the A register.

  Therefore, when executing the communication data pointer update process of S82, the source code “ADD A, 7” is first executed on the source program of FIG. 75A, and the contents of the A register (the contents of the communication data pointer before update) are read. Value) is added to the value, and the result of the addition is stored in the A register. Next, the source code “ICPLD A, 71” is executed, and the contents of the A register (the value of the communication data pointer after adding 7) are compared with the integer “71”. In some cases, "1" is added to the contents of the A register, and when the contents of the A register are an integer "71" or more, "0" is set in the A register. That is, in the process of S82, when the value of the communication data pointer is updated by +7 and the updated communication data pointer value exceeds the upper limit value “71”, the communication data pointer is cleared to zero (communication). The process of returning the data storage address to the head address of the communication data storage area is performed. On the other hand, if the updated value of the communication data pointer does not exceed the upper limit value “71”, “1” is further added to the communication data pointer by the “ICPLD” instruction, so that the value of the communication data pointer is totally reduced. +8 is updated.

  As described above, in the present embodiment, in the communication data pointer update processing, one “ICPLD” instruction code (an instruction code in which a transmission buffer upper limit determination instruction and a determination branch instruction are integrated) is used to communicate data. The pointer update (addition of 1) process, the communication data pointer determination check process after the update, and the communication data pointer clear process can be executed together. In this case, there is no need to provide an instruction code for executing each process separately. For example, the branch instruction code for determining whether the value of the updated communication data pointer exceeds the upper limit value “71” can be omitted.

  Therefore, by using the “ICPLD” instruction code dedicated to the main CPU 101 in the communication data pointer update processing and the like, the capacity of the source program (the used capacity of the main ROM 102) can be reduced. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Power-off (external) processing]
Next, a process performed when the pachislot 1 is turned off (external) under the control of the main CPU 101 will be described with reference to FIG. FIG. 76 is a flowchart showing the procedure of the process at the time of power interruption (external). Note that the power interruption (external) processing shown in FIG. 76 is performed when the power management circuit 93 detects a decrease (power interruption) in the power supply voltage supplied to the microprocessor 91 and outputs a power interruption detection signal to the microprocessor 91. Is executed on the basis of an interrupt request signal output from the interrupt controller 112 of the microprocessor 91 to the main CPU 101.

  First, the main CPU 101 saves data set in all registers (S91). Next, the main CPU 101 reads the data set in the power interruption detection port (S92).

  Next, the main CPU 101 determines whether or not the power interruption detection port is on (S93).

  In S93, when the main CPU 101 determines that the power interruption detection port is not in the ON state (if S93 is NO), the main CPU 101 sets the interruption processing permission (S94). Then, after the processing of S94, the main CPU 101 ends the processing at the time of power failure (external). Note that these processes performed when S93 is a NO determination correspond to the process of countermeasures against momentary power failure that occurs when the power management circuit 93 instantaneously detects a power interruption.

  On the other hand, in S93, when the main CPU 101 determines that the power interruption detection port is in the ON state (if S93 is YES), the main CPU 101 sets medal insertion impossible and sets the hopper device 51 to stop. (S95).

  Next, the main CPU 101 stores the value of the currently set stack pointer (SP) in the stack area of the game RAM area in the main RAM 103 (S96).

  Next, the main CPU 101 performs a checksum generation process of the main RAM 103 (S97). This processing is performed in a non-defined work area in the main RAM 103 (see FIG. 12C). The program used in the checksum generation processing is stored in a non-defined area in the main ROM 102 (see FIG. 12B). The details of the checksum generation processing will be described later with reference to FIG. 77 described later.

  Next, the main CPU 101 sets prohibition of access to the main RAM 103 (S98). Then, after the process of S98, an infinite loop process is performed until the power supply stops (until the power supply voltage reaches a voltage at which the main CPU 101 cannot operate).

[Checksum generation processing (unspecified)]
Next, the checksum generation processing performed in S97 during the power interruption (external) processing (see FIG. 76) will be described with reference to FIGS. FIG. 77 is a flowchart showing the procedure of the checksum generation process. FIG. 78A is a diagram showing an example of a source program for executing the checksum generation process. FIG. 78B is a flowchart showing the checksum generation process. FIG. 4 is a diagram illustrating a state of an update operation of a stack pointer and an operation of reading data from a main RAM 103 to a register to be executed.

  First, the main CPU 101 stores the current value of the stack pointer (SP) (in-use address of the stack area of the game RAM area) in the non-defined stack area of the non-defined RAM area of the main RAM 103 (S101). Next, the main CPU 101 sets the address of the non-defined stack area in the stack pointer (S102). Next, the main CPU 101 sets the upper address value (F0H) of the RAM address (address of the non-defined stack area) in the Q register (S103). Next, the main CPU 101 sets a power failure occurrence flag (S104).

  Next, the main CPU 101 sets the calculation start address of the sum value in the game RAM area to the stack pointer, and sets the value obtained by dividing the number of bytes of the sum value calculation target storage area by “2” to the sum calculation counter. It is set (S105). Note that the sum calculation counter is a counter for determining an end timing of the sum value calculation, and is provided in the main RAM 103. Then, when the sum calculation counter set in S105 becomes “0”, the sum value calculation processing of the game RAM area of the main RAM 103 ends.

  Next, the main CPU 101 clears the HL register to 0 (sets the value “0”) (S106). By this processing, the initial value “0” of the sum value is set.

  Next, the main CPU 101 executes an instruction code (source code “POP DE” described in FIG. 78A) called “POP instruction” (specific instruction), and stores the main RAM 103 set in the stack pointer (SP). The data (stored value) of the 2-byte area is read from the area address to the DE register (S107).

  When the “POP” instruction is executed, the data (memory contents) stored in the 1-byte area at the address specified by the stack pointer is loaded into the lower register of the pair register and specified by the stack pointer. The data (memory contents) stored in the 1-byte area of the address obtained by updating the input address by one is loaded into the upper register of the pair register. Further, when the “POP” instruction is executed, an address update process (addition of “2” to the address) of 2 bytes is performed on the address set in the stack pointer (SP).

  Therefore, in the process of S107, the data (memory contents) stored at the address specified by the stack pointer is loaded into the E register, and stored at the address obtained by adding “1” to the address specified by the stack pointer. The loaded data (memory contents) is loaded into the D register.

  FIG. 78B shows how the operation of reading data into the DE register and the operation of updating the address set in the stack pointer when the “POP” instruction is executed. If the address set in the stack pointer (SP) is “F010h” at the start of the calculation of the sum value, the data (memory contents) stored in the address “F010h” is loaded into the E register, and The data (memory contents) stored in “F011h” is loaded into the D register. At this time, an update process of adding 2 to the address set in the stack pointer (SP) is performed, and the address set in the stack pointer (SP) is changed from “F010h” to “F012h”. Next, when the “POP” instruction is executed again, the data (memory content) stored at the address “F012h” is loaded into the E register, and the data (memory content) stored at the address “F013h” is loaded. Loaded into D register. At this time, the address set in the stack pointer (SP) is updated, and the address set in the stack pointer (SP) is changed from “F012h” to “F014h”. Thereafter, each time the “POP” instruction is executed, the above-described operation of reading data into the DE register and the operation of updating the address set in the stack pointer are repeated.

  After the process in S107, the main CPU 101 performs a sum value calculation process (S108). Specifically, the main CPU 101 adds the value stored in the DE register to the value stored in the HL register, and stores the added value as a sum value in the HL register.

  Next, the main CPU 101 subtracts 1 from the value of the sum calculation counter (S109). Next, the main CPU 101 determines whether or not the value of the updated sum calculation counter is “0” (S110).

  In S110, when the main CPU 101 determines that the value of the sum calculation counter is not “0” (NO in S110), the main CPU 101 returns the processing to S107 and repeats the processing from S107. That is, the processing of S107 to S110 is repeated until the sum value calculation processing of the game RAM area of the main RAM 103 ends.

  On the other hand, in S110, when the main CPU 101 determines that the value of the sum calculation counter is “0” (if S110 is YES), the main CPU 101 stores the value of the non-defined RAM area in the main RAM 103 in the DE register. The calculation start address of the sum value is set, and the non-specified sum count value is set in the sum calculation counter (S111). The non-standardized sum count value is the number of bytes in the non-standardized storage area. Therefore, when the sum calculation counter set in S111 becomes “0”, the sum value calculation process for the non-defined RAM area of the main RAM 103, that is, the sum value calculation process for the entire main RAM 103 ends.

  Next, the main CPU 101 reads out the data (stored value) of the 1-byte area from the address of the non-defined RAM area set in the DE register into the A register (S112).

  Next, the main CPU 101 performs a sum value calculation process (S113). Specifically, the main CPU 101 adds the value stored in the A register to the value stored in the HL register, and stores the added value as a sum value in the HL register.

  Next, the main CPU 101 adds 1 to the address stored in the DE register and subtracts 1 from the value of the sum calculation counter (S114). Next, the main CPU 101 determines whether or not the updated value of the sum calculation counter is “0” (S115).

  In S115, when the main CPU 101 determines that the value of the sum calculation counter is not “0” (NO in S115), the main CPU 101 returns the process to S112, and repeats the processes from S112. That is, the processing of S112 to S115 is repeated until the processing of adding the sum value of the non-defined RAM area of the main RAM 103 to the sum value of the gaming RAM area is completed.

  On the other hand, in S115, when the main CPU 101 determines that the value of the sum calculation counter is “0” (if S115 is YES), the main CPU 101 determines the value stored in the HL register when the power failure occurs. Is stored in a sum value storage area (not shown) in the main RAM 103 (S116). Next, the main CPU 101 sets the value of the stack pointer (SP) stored in the non-defined stack area in S101 to the stack pointer (S117). Then, after the processing in S117, the main CPU 101 ends the checksum generation processing, and shifts the processing to the processing in S98 at the time of power interruption (external) (see FIG. 76).

  In the present embodiment, the checksum generation processing is performed as described above. The above-described checksum generation processing is performed by the main CPU 101 sequentially executing each source code defined in the source program of FIG. 78A. As described above, in the present embodiment, the checksum of the main RAM 103 at the time of occurrence of a power interruption is calculated by an addition formula. At this time, in the calculation of the sum value in the game RAM area, addition processing is performed in units of 2 bytes (see source code “ADD HL, DE” in FIG. 78A), and in the non-defined RAM area, addition processing is performed in units of 1 byte. (Refer to the source code “ADDWB HL, A” in FIG. 78A).

[Sum check processing (unspecified)]
Next, the sum check process performed in S9 during the power-on process (see FIG. 64) will be described with reference to FIGS. FIGS. 79 and 80 are flowcharts showing the procedure of the sum check process, and FIG. 81 is a diagram showing an example of a source program for executing the processes of S122 to S132 during the sum check process.

  First, the main CPU 101 stores the current value of the stack pointer (SP) in the non-defined stack area (S121). Next, the main CPU 101 sets the address of the sum value storage area in the stack pointer, and sets a value obtained by dividing the number of bytes of the sum value calculation target storage area by “2” in the sum calculation counter (S122). The sum calculation counter set here is a counter for judging the end timing of the sum value calculation (sum value subtraction processing), and is provided in the main RAM 103. Next, the main CPU 101 acquires a sum value (check sum) from the sum value storage area (S123). By this processing, the checksum (initial value before subtraction) generated at the time of power failure occurrence is stored in the HL register.

  Next, the main CPU 101 executes a “POP” instruction, and reads out data (stored value) of a 2-byte area from the address of the storage area of the main RAM 103 set in the stack pointer (SP) into the DE register (S124). . At this time, by executing the “POP” instruction, the data (memory contents) stored in the 1-byte area at the address specified by the stack pointer is loaded into the E register, and the address specified by the stack pointer is stored in the E register. The data (memory contents) stored in the 1-byte area at the updated address is loaded into the D register (see FIG. 78B). Further, when the “POP” instruction is executed, an address update process for 2 bytes (a process of adding the address by 2) is performed on the address set in the stack pointer (SP).

  Next, the main CPU 101 performs a sum value calculation (subtraction) process (S125). Specifically, the main CPU 101 subtracts the value stored in the DE register from the value stored in the HL register (the initial value of the sum value or the sum value after the previous subtraction process), and The value is stored in the HL register as a sum value.

  Next, the main CPU 101 subtracts 1 from the value of the sum calculation counter (S126). Next, the main CPU 101 determines whether or not the value of the updated sum calculation counter is “0” (S127).

  In S127, when the main CPU 101 determines that the value of the sum calculation counter is not “0” (if S127 is NO), the main CPU 101 returns the process to the process of S124, and repeats the processes from S124. That is, the processing of S124 to S127 is repeated until the sum value subtraction processing is completed over the entire area of the gaming RAM area of the main RAM 103.

  On the other hand, in S127, when the main CPU 101 determines that the value of the sum calculation counter is “0” (if S127 is YES), the main CPU 101 stores the value of the non-defined RAM area in the main RAM 103 in the DE register. The calculation start address of the sum value is set, and the non-specified sum count value is set in the sum calculation counter (S128). The non-specified sum count value is the number of bytes in the non-specified RAM area.

  Next, the main CPU 101 reads out the data (stored value) of the 1-byte area from the address of the non-defined RAM area set in the DE register into the A register (S129).

  Next, the main CPU 101 performs a sum value calculation (subtraction) process (S130). Specifically, the main CPU 101 subtracts the value stored in the A register from the value stored in the HL register, and stores the subtracted value as a sum value in the HL register.

  Next, the main CPU 101 adds 1 to the address stored in the DE register and subtracts 1 from the value of the sum calculation counter (S131). Next, the main CPU 101 determines whether or not the value of the updated sum calculation counter is “0” (S132).

  In S132, when the main CPU 101 determines that the value of the sum calculation counter is not “0” (if S132 is NO), the main CPU 101 returns the processing to the processing of S129, and repeats the processing from S129. That is, the processing of S129 to S132 is repeated until the subtraction processing of the sum value is completed over the entire non-defined RAM area of the main RAM 103.

  On the other hand, in S132, when the main CPU 101 determines that the value of the sum calculation counter is “0” (if S132 is YES), the main CPU 101 sets “Sum abnormal” in the determination result of the sum check processing. (S133). Next, the main CPU 101 determines whether or not the calculated sum value is “0” (S134).

  In this process, the main CPU 101 refers to the state (1/0) of the zero flag (bit 6) of the flag register F to determine whether or not the sum value is “0”. In the present embodiment, when the value of the sum calculation counter set in S128 becomes “0”, that is, when the sum value subtraction processing is completed over the entire area of the main RAM 103, the sum value becomes “0”. , The zero flag of the flag register F is set to “1”, and if the sum value is not “0”, the zero flag of the flag register F is set to “0”. Therefore, if “1 (on state)” is set in the zero flag of the flag register F at the time of the processing of S134, the main CPU 101 determines that the sum value is “0”.

  In S134, when the main CPU 101 determines that the calculated sum value is not “0” (NO in S134), the main CPU 101 performs the processing of S139 described later. On the other hand, when the main CPU 101 determines in S134 that the calculated sum value is “0” (YES in S134), the main CPU 101 sets “power interruption abnormal” in the determination result (S135). ).

  Next, the main CPU 101 acquires a power interruption occurrence flag (S136). Next, the main CPU 101 determines whether or not the power failure occurrence flag is in a state without power failure (OFF state) (S137).

  In S137, when the main CPU 101 determines that the power failure occurrence flag is in the state without power failure (when S137 is YES), the main CPU 101 performs the processing of S139 described later. On the other hand, in S137, when the main CPU 101 determines that the power failure occurrence flag is not in the state of no power failure (NO in S137), the main CPU 101 sets “normal” in the determination result (S138).

  After the process of S138, if S134 is NO or S137 is YES, the main CPU 101 stores the determination result in the sum check determination result and clears (turns off) the power interruption occurrence flag (S139). Next, the main CPU 101 sets the value of the stack pointer (SP) stored in the non-defined stack area in S121 to the stack pointer (S140). Then, after the processing in S140, the main CPU 101 ends the sum check processing, and shifts the processing to the processing in S10 of the power-on processing (see FIG. 64).

  In the present embodiment, the sum check process is performed as described above. Then, the processing of S122 to S132 in the above-described sum check processing is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG.

  As described above, in the determination processing of the sum chock of the main RAM 103 in the present embodiment, first, the value of the checksum generated at the time of the occurrence of the power interruption is sequentially subtracted from the data stored in the main RAM 103 when the power is restored. At this time, in the game RAM area, subtraction processing is performed in units of 2 bytes (see the source code “SUBHL, DE” in FIG. 81), and in the non-defined RAM area, subtraction processing is performed in units of 1 byte (see FIG. 81). (See SUBWB HL, A). Next, whether or not an abnormality has occurred is determined based on whether or not the final subtraction result is “0” (ie, whether or not the zero flag is in the ON state). When the subtraction result is “0” (when the zero flag is on), it is determined to be normal. When the subtraction result is not “0” (when the zero flag is off), it is determined to be abnormal. Is determined.

  That is, in the present embodiment, the process of generating the checksum when a power failure occurs is performed by the addition method, and the process of determining the checksum when the power is restored is performed by the subtraction method. Then, a normal / abnormal judgment is made based on the final subtraction result of the checksum. When such a checksum generation process and a determination process are performed, it is not necessary to generate a checksum again when the power is restored, and to collate the checksum with the checksum at the time of the occurrence of power interruption. In this case, the collation instruction code can be omitted from the source program, and the capacity of the source program can be reduced. As a result, in the present embodiment, it is possible to secure a free space corresponding to the omission of the collation instruction code in the main ROM 102, and it is possible to utilize the increased free space to enhance the gaming ability. Note that the “POP” instruction executed in the above-described checksum generation processing when a power failure occurs and the checksum determination processing when the power is restored is an instruction dedicated to stack pointer (SP) operation, and the source code “ In addition to “POP DE”, there are source codes “POP HL”, “POP AF”, and the like.

[Main processing of pachislot under control of main CPU]
Next, the main processing (main operation processing) of the pachislot 1 executed under the control of the main CPU 101 will be described with reference to FIG. FIG. 82 is a flowchart (hereinafter referred to as a main flow) showing the procedure of the main processing.

  First, the main CPU 101 performs a RAM initialization process (S201). In this process, the main CPU 101 sets the address of “at the end of one game” in the game RAM area of the main RAM 103 shown in FIG. 12C as a start address of the initialization start, and sets the address of the game RAM area from the start address. Erase (clear) information up to the last address. The storage area in this range is a storage area in which data must be deleted for each unit game (game) such as an internal winning combination storage area and a display combination storage area.

  Next, the main CPU 101 performs a medal acceptance / start check process (S202). In this process, the main CPU 101 performs an input check process for a medal sensor (not shown), a start switch 79, and the like. The details of the medal acceptance / start check process will be described later with reference to FIG. 83 described later.

  Next, the main CPU 101 performs a random number acquisition process (S203). In this process, the main CPU 101 determines the random number value for internal winning combination lottery (0 to 65535: the value of the random number register 0 of the random number circuit 110 to be a hard latched random number) or the random number value for effect used in various ART-related lotteries. 0 to 65535: each value of the random number registers 1 to 3 of the random number circuit 110 that becomes a soft latch random number, and 0 to 255: each value of the random number registers 4 to 7 of the random number circuit 110 that becomes a soft latch random number). The extracted various random numbers are stored in a random value storage area (not shown) provided in the main RAM 103. The details of the random number acquisition process will be described later with reference to FIG.

  Next, the main CPU 101 performs an internal lottery process (S204). In this process, the main CPU 101 performs an internal winning combination determination process by lottery based on the random number value (hard latch random number) extracted in S203. The details of the internal lottery process will be described later with reference to FIG.

  Next, the main CPU 101 performs a symbol setting process (S205). In this process, for example, the main CPU 101 generates an internal winning combination from the hit request flag status (flag status information), expands the hit request flag data, and stores the hit request flag data in the hit request flag storage area. And so on. The details of the symbol setting process will be described later with reference to FIG. 97 described later.

  Next, the main CPU 101 performs a start command generation and storage process (S206). In this process, the main CPU 101 generates start command data to be transmitted to the sub control circuit 200, and stores the command data in a communication data storage area (see FIG. 75B) provided in the main RAM 103. The start command stored in the communication data storage area is transmitted from the main control circuit 90 to the sub-control circuit 200 by a communication data transmission process in an interrupt process described later with reference to FIG. The start command includes a parameter (such as a sub flag) for specifying an internal winning combination or the like.

  Next, the main CPU 101 performs a second interface board control process (S207). The second interface board control process is executed in the non-standard work area of the main RAM 103. Details of the second interface board control processing will be described later with reference to FIG.

  Next, the main CPU 101 performs a state-specific control process (S208). In this process, the main CPU 101 mainly performs a game start process (start process) according to the game state. The details of the state-specific control processing will be described later with reference to FIG. 104 described later.

  Next, the main CPU 101 performs a reel stop initial setting process (S209). In this process, the main CPU 101 refers to the reel stop initialization table (see FIG. 26), and based on the internal winning combination and the game state, sets the drawing priority table selection table number, the drawing priority table number, and the stop table number. For example, a process of acquiring the value, a process of storing “3” in the stop button inactivity counter, and the like are performed.

  Next, the main CPU 101 performs a reel rotation start process (S210). In this process, the main CPU 101 requests the start of rotation of all reels. When the start of rotation of all reels is requested, the drive of three stepping motors (not shown) is performed by an interrupt process (see FIG. 158 described below) executed at a constant cycle (1.1172 msec). Is controlled, and rotation of the left reel 3L, the middle reel 3C, and the right reel 3R is started. Next, each reel is controlled to accelerate until its rotation speed reaches a constant speed, and thereafter, is controlled so as to maintain the constant speed.

  Next, the main CPU 101 performs a reel rotation start command generation and storage process (S211). In this process, the main CPU 101 generates data of a reel rotation start command to be transmitted to the sub control circuit 200, and stores the command data in a communication data storage area (see FIG. 75B) provided in the main RAM 103. The reel rotation start command stored in the communication data storage area is transmitted from the main control circuit 90 to the sub-control circuit 200 by a communication data transmission process in an interrupt process described later with reference to FIG. The reel rotation start command includes a parameter indicating that the rotation start operation of the reel has started.

  Next, the main CPU 101 performs a pull-in priority storing process (S212). In this processing, the main CPU 101 acquires the attraction priority data and stores it in the attraction priority data storage area. Details of the pull-in priority storage process will be described later with reference to FIG. 126 described later.

  Next, the main CPU 101 performs a reel stop control process (S213). In this process, the main CPU 101 controls the rotation of the corresponding reel based on the timing at which the left stop button 17L, the middle stop button 17C, and the right stop button 17R are pressed, and the internal winning combination. The details of the reel stop control process will be described later with reference to FIG. 138 described later.

  Next, the main CPU 101 performs a winning search process (S214). In this process, the main CPU 101 stores the data in the symbol code storage area (see FIG. 35) in the winning operation flag storage area (see FIGS. 28 to 30). In this process, the main CPU 101 determines whether or not the display combination is displayed on the activated line, and sets the number of payout medals based on the determination result. The details of the winning search process will be described later with reference to FIG. 145 described later.

  Next, the main CPU 101 performs an illegal hit check process (S215). In this process, the main CPU 101 combines the hit request flag (internal winning combination) with the winning operation flag (display combination), and determines whether or not there is an illegal hit error based on the combination result. The details of the illegal hit check process will be described later with reference to FIG. 148 described later.

  Next, the main CPU 101 performs a winning check / medal payout process (S216). In this process, the main CPU 101 performs a process of generating a winning operation command. In this process, the main CPU 101 drives the hopper device 51 and updates the number of credits based on the number of payouts of the display combination determined in S214, and performs a medal payout process. The details of the winning check / medal payout process will be described later with reference to FIG. 150 described later.

  Next, the main CPU 101 performs a BB check process (S217). In this process, the main CPU 101 controls the operation and termination of the bonus state. The details of the BB check process will be described later with reference to FIG.

  Next, the main CPU 101 performs an RT check process (S218). In this process, the main CPU 101 performs transition control of the RT state based on the symbol combination stopped and displayed on the activated line. The details of the RT check process will be described later with reference to FIGS. 155 and 156 described later.

  Next, the main CPU 101 performs a process at the end of CZ • ART (S219). In this process, the main CPU 101 mainly performs a CZ pull-back lottery process. The details of the processing at the end of the CZ • ART will be described later with reference to FIG. 157 described later. Then, after the processing of S219 (after the end of one game), the main CPU 101 returns the processing to the processing of S201.

[Medal acceptance / start check processing]
Next, the medal acceptance / start check processing performed in S202 in the main flow (see FIG. 82) will be described with reference to FIGS. FIG. 83 is a flowchart showing the procedure of the medal acceptance / start check process. FIG. 84 is a diagram showing an example of a source program for executing the processes of S231 to S233 during the medal acceptance / start check process. is there.

  First, the main CPU 101 determines whether or not the value of the automatic insertion medal counter is “0” (whether or not there is an automatic insertion request) (S221). In this process, when the automatic insertion medal counter is equal to or more than “1”, the main CPU 101 determines that there is an automatic insertion request. The automatic insertion medal counter is data for identifying whether or not a display combination related to a replay (replay) has been established in the previous unit game. When the display combination relating to the replay is established, medals of the number inserted in the previous unit game are automatically inserted into the automatic insertion medal counter.

  In S221, when the main CPU 101 determines that the value of the automatically inserted medal counter is “0” (if S221 is YES), the main CPU 101 performs the process of S225 described later.

  On the other hand, in S221, when the main CPU 101 determines that the value of the automatic insertion medal counter is not “0” (if S221 is NO), the main CPU 101 performs a medal insertion process (S222). In this process, the main CPU 101 performs a medal insertion command generation / storage process, a medal insertion number LED lighting control process, and the like. The details of the medal insertion processing will be described later with reference to FIG. 85 described later.

  Next, the main CPU 101 subtracts 1 from the value of the automatically inserted medal counter (S223). Next, it is determined whether or not the value of the automatically inserted medal counter after the subtraction is “0” (S224).

  In S224, when the main CPU 101 determines that the value of the automatically inserted medal counter is not “0” (NO in S224), the main CPU 101 returns the process to the process of S222, and repeats the processes from S222.

  On the other hand, in S224, when the main CPU 101 determines that the value of the automatically inserted medal counter is “0” (if S224 is YES), or if S221 is YES, the main CPU 101 starts the medal auxiliary storage. A warehouse switch check process is performed (S225). In this process, the main CPU 101 detects whether or not the medal auxiliary storage 52 is full of medals based on the on / off state of the medal auxiliary storage switch 75.

  Next, the main CPU 101 performs a medal insertion state check process (S226). Next, the main CPU 101 determines whether or not a medal can be inserted based on the result of the medal insertion state check processing (S227).

  In S227, when the main CPU 101 determines that the medal insertion is not possible (when S227 is NO), the main CPU 101 performs the process of S231 described later.

  On the other hand, in S227, when the main CPU 101 determines that the medal can be inserted (in the case of YES determination in S227), the main CPU 101 performs a medal insertion check process (S228). In this process, the main CPU 101 determines, for example, whether or not the medal has passed normally, based on the medal sensor input state, or credits the medal when the medal insertion exceeds a specified number. Perform processing, etc. Details of the medal insertion check processing will be described later with reference to FIG. 87 described later.

  Next, the main CPU 101 determines whether or not a medal insertion or credit is possible based on a result of the medal insertion check processing (S229).

  In S229, when the main CPU 101 determines that a medal insertion or credit is possible (if S229 is YES), the main CPU 101 performs the process of S231 described later. On the other hand, in S229, when the main CPU 101 determines that it is not in a state where medals can be inserted or credited (if S229 is NO), the main CPU 101 performs a medal acceptance prohibition process (S230). With this processing, the solenoid of the selector 66 (see FIG. 4) is not driven, and the inserted medals are discharged from the medal payout opening 24.

  After the processing in S230, if S227 is NO or if S229 is YES, the main CPU 101 determines whether or not the current number of inserted medals is the game start number (S231). In the present embodiment, the number of playable games is three (see FIGS. 28 to 30).

  In S231, when the main CPU 101 determines that the current number of inserted medals is the game start number (if S231 is YES), the main CPU 101 performs the process of S234 described later. On the other hand, in S231, when the main CPU 101 determines that the current number of inserted medals is not the game start number (in the case of NO determination in S231), the main CPU 101 determines whether or not there is a medal inserted (S232). ).

  In S232, when the main CPU 101 determines that there is a medal insertion (YES in S232), the main CPU 101 returns the processing to S226 and repeats the processing from S226. On the other hand, in S232, when the main CPU 101 determines that there is no medal insertion (NO in S232), the main CPU 101 performs the setting change confirmation processing described in FIG. 68 (S233). In this processing, the main CPU 101 performs processing for generating and storing a setting change command at the start of setting confirmation.

  After the process of S233 or when the determination of S231 is YES, the main CPU 101 determines whether or not the start switch 79 is on (S234).

  In S234, when the main CPU 101 determines that the start switch 79 is not in the ON state (if S234 is NO), the main CPU 101 returns the process to S226, and repeats the process from S226.

  On the other hand, in S234, when the main CPU 101 determines that the start switch 79 is on (in the case of YES determination in S234), the main CPU 101 performs a medal acceptance prohibition process (S235). With this processing, the solenoid of the selector 66 (see FIG. 4) is not driven, and the inserted medals are discharged from the medal payout opening 24. After the processing of S235, the main CPU 101 ends the medal acceptance / start check processing, and moves the processing to S203 of the main flow (see FIG. 82).

  In the present embodiment, the medal acceptance / start check process is performed as described above. The processing of S231 to S233 during the medal acceptance / start check processing described above is performed by the main CPU 101 sequentially executing each source code defined by the source program in FIG. 84. Among them, in the processing of S233, the processing is jumped to the address “SB_WVSC_00” of the execution program of the setting change confirmation processing by the “CALLF” instruction which is the instruction code dedicated to the main CPU 101, and the setting change confirmation described in FIGS. 68 and 69 is performed. Perform processing.

  Then, the processing of S233 during the above-described medal reception / start check processing, that is, the setting change confirmation processing is executed regardless of the gaming state. Therefore, in this embodiment, regardless of the gaming state, that is, even if the gaming state is the bonus state (prize operation state), the set value and the hole menu (various history data (error, power cut history, etc.)) are displayed. It is possible to confirm, and it is possible to suppress illegal acts such as goto.

[Medal insertion processing]
Next, the medal insertion processing performed in S222 during the medal acceptance / start check processing (see FIG. 83) will be described with reference to FIGS. 85 and 86. FIG. 85 is a flowchart showing the procedure of the medal insertion processing, and FIG. 86 is a diagram showing an example of a source program for executing the medal insertion processing.

  First, the main CPU 101 adds “1” to the value of the medal counter (S241). The medal counter is a counter for counting (counting) the number of inserted medals, and is provided in the main RAM 103.

  Next, the main CPU 101 performs a medal shooting command generation and storage process (S242). In this process, the main CPU 101 generates data of a medal insertion command to be transmitted to the sub control circuit 200, and stores the command data in a communication data storage area (see FIG. 75B) provided in the main RAM 103. The medal insertion command stored in the communication data storage area is transmitted from the main control circuit 90 to the sub-control circuit 200 by a communication data transmission process in an interrupt process described later with reference to FIG. That is, the medal insertion command is transmitted from the main control circuit 90 to the sub control circuit 200 every time one medal is inserted. Note that the medal insertion command includes parameters for specifying the number of inserted medals and the like.

  Next, the main CPU 101 turns off the first to third LEDs for displaying the number of inserted medals included in the LEDs 82 (see FIG. 7) (S243). Next, the main CPU 101 calculates LED lighting data (lighting control data) corresponding to the medal insertion number based on the medal insertion number (medal counter value) (S244). In this processing, for example, when the number of inserted medals is one, LED lighting data for lighting only the first LED for displaying the number of inserted medals is calculated. For example, when the number of inserted medals is three , LED lighting data for lighting all of the first to third LEDs for displaying the number of inserted medals is calculated. The method of calculating the LED lighting data will be described later in detail.

  Next, using the calculated LED lighting data, the main CPU 101 turns on the corresponding LED for displaying the number of inserted medals (S245). Then, after the processing of S245, the main CPU 101 ends the medal insertion processing, and moves the processing to S223 of the medal acceptance / start check processing (see FIG. 83).

  In the present embodiment, the medal insertion processing is performed as described above. The above-described medal insertion processing is performed by the main CPU 101 sequentially executing each source code defined by the source program in FIG. Among them, in the process of S244, the LED lighting data for displaying the number of inserted medals is generated not by the loop process referring to the table but by the arithmetic process. This arithmetic processing is performed by the main CPU 101 sequentially executing the source codes "LD A, L" to "OR L" in the source program shown in FIG.

  In this calculation process, data of the number of inserted medals stored in the L register is stored in the A register by executing the source code “LD A, L”. For example, when the number of inserted medals is three, “00000011B” (decimal “3”) is stored in the A register. In the present embodiment, one-byte data is described as “******** B”, and the last character “B” is “0” or “1” indicated before the character “B”. "Means bit data.

  Next, by executing the source code “ADD A, A”, the data stored in the A register is added to the data stored in the A register, and the addition result is stored in the A register. For example, when the data stored in the A register is “00000011B” before the execution of the “ADD” instruction (when the number of inserted medals is three), the addition result is obtained by the “ADD” instruction. "00000110B" is stored in the A register.

  Next, by executing the source code “DEC A”, the data stored in the A register is subtracted by 1, and the result of the subtraction is stored in the A register. For example, if the data stored in the A register before execution of the “DEC” instruction is “00000110B”, “00000101B” as a subtraction result is stored in the A register by the “DEC” instruction. .

  Next, by executing the source code “OR L”, a logical sum operation of the data (the number of inserted medals) stored in the L register and the data stored in the A register is performed, and the calculation result is stored in the A register. Is stored. For example, when the data stored in the A register is “00000101B” and the data stored in the L register is “00000011B” before the execution of the “OR” instruction (the number of tokens inserted is three). ), The "OR" instruction causes "00000111B", which is the result of the logical sum operation of both data, to be stored in the A register. Then, the data stored in the A register by the execution of the “OR” instruction becomes the LED lighting data for displaying the number of inserted medals (data indicating the lighting state of the medal insertion LED).

  For example, when the number of inserted medals is three, as described above, the final calculation result “00000111B” is calculated by the process of calculating the LED lighting data for displaying the number of inserted medals in S244 as described above. It becomes LED lighting data. In the present embodiment, “1/0” of bit 0 of the finally calculated LED lighting data indicates “ON / OFF” of the output port to the LED (first LED) for displaying the first medal insertion number. "1/0" of bit 1 corresponds to the "on / off" state of the output port to the LED for displaying the number of inserted medals (second LED), and bit 1 of "1" / 0 "corresponds to the" on / off "state of the output port to the third medal insertion number LED (third LED). Therefore, when the number of inserted medals is three, “00000111B” is generated as the LED lighting data as described above, so that all the output ports of the first to third LEDs for displaying the number of inserted medals are set. It is set to the ON state, and the first to third LEDs for displaying the number of inserted medals are all turned on.

  When the LED lighting data for displaying the number of inserted medals is generated by the arithmetic processing as described above, the table data to be referred to when generating the LED lighting data for displaying the number of inserted medals is not required, so the table area of the main ROM 102 is not required. Free space can be increased, and an increase in program capacity can be minimized. That is, in the above-described medal insertion processing of the present embodiment, the processing of displaying the medal insertion LED can be made more efficient, the free space of the main ROM 102 is secured (increased), and the increased free area is utilized. It is possible to enhance the playability.

[Medal insertion check processing]
Next, the medal insertion check processing performed in S228 during the medal acceptance / start check processing (see FIG. 83) will be described with reference to FIGS. 87 and 88. FIG. 87 is a flowchart showing the procedure of the medal insertion check processing, and FIG. 88 is a diagram showing an example of a source program for executing the processing of S255 to S258 during the medal insertion check processing.

  First, the main CPU 101 determines whether or not a replay is being performed (S251).

  In S251, when the main CPU 101 determines that the game is being replayed (YES in S251), the main CPU 101 ends the medal insertion check processing, and executes the medal acceptance / start check processing (see FIG. 83). S229.

  On the other hand, when the main CPU 101 determines in S251 that the game is not being replayed (NO in S251), the main CPU 101 permits medal acceptance (S252). In this process, the solenoid of the selector 66 (see FIG. 4) is driven, and medals inserted from the medal insertion slot 14 are accepted. The received medals are counted and then guided to the hopper device 51.

  Next, the main CPU 101 performs a bet button check process (S253). In this process, the main CPU 101 determines whether or not the bet button (the MAX bet button 15a or the 1-bet button 15b) has been operated based on the ON / OFF state of the BET switch 77. Next, the main CPU 101 determines whether or not the betting operation has been completed based on the result of the bet button check processing in S253 (S254).

  In S254, when the main CPU 101 determines that the betting operation has been completed (YES in S254), the main CPU 101 ends the medal insertion check processing, and executes the medal acceptance / start check processing (see FIG. 83). S229.

  On the other hand, in S254, when the main CPU 101 determines that the betting operation has not been completed (NO in S254), the main CPU 101 sets the medal sensor input state (the receiving state of the game medium) in the current processing, The medal sensor input state at the time of the previous processing is acquired (S255). The input state of the medal sensor is information indicating the passing status of the medal accepted by the medal insertion slot 14 in the selector 66, and the detection result of each medal sensor (not shown) provided at the entrance and the exit of the selector 66. Generated by

  In the present embodiment, the input state of the medal sensor is represented by 1-byte (8-bit) data, and the input state of the upstream first medal sensor (not shown) provided at the exit of the selector 66 in the direction in which the medal passes. The detection result corresponds to bit 0 information (“0” or “1”), and the detection result of the second medal sensor (not shown) on the downstream side corresponds to bit 1 information (“0” or “1”). I do. Bit 1 is set to “1” when the passing of a medal is detected by the first medal sensor, and “1” is set to bit 1 when the passing of the medal is detected by the second medal sensor. Is done. Therefore, the medal sensor input state “00000000B” indicates the state before or after the medal has passed (at the time of passing), the medal sensor input state “00000001B” indicates the state at the start of the medal passing, and the medal sensor input state “ "00000011B" indicates a state during the medal passing, and a medal sensor input state "00000010B" indicates a state immediately before the completion of the medal passing.

  Next, the main CPU 101 determines whether or not the medal sensor input state during the current process has changed from the medal sensor input state during the previous process (S256).

  In S256, when the main CPU 101 determines that the medal sensor input state at the time of the current processing has not changed from the medal sensor input state at the time of the previous processing (NO at S256), the main CPU 101 proceeds to S261 described later. Perform processing.

  On the other hand, in S256, when the main CPU 101 determines that the medal sensor input state during the current process has changed from the medal sensor input state during the previous process (when S256 is YES), the main CPU 101 determines that the medal sensor input state during the previous process has not been changed. Based on the medal sensor input state, a normal value (normal change value) of the medal sensor input state obtained in the current processing is generated by arithmetic processing (S257).

  In this process, if the medal sensor input state at the time of the previous process is “000000000B” (when both the first and second medal sensors have not detected a medal), the medal sensor input state becomes a normal change value. “00000001B” (when the first medal sensor detects the medal and the second medal sensor does not detect the medal) is generated, and when the medal sensor input state in the previous processing is “00000001B”, the medal sensor is detected. “00000011B” (when both the first and second medal sensors detect medals) is generated as a normal change value of the input state. In this process, if the medal sensor input state in the previous process is “00000011B”, the normal change value of the medal sensor input state is “00000010B” (the medal sensor is not detected in the first medal sensor, When the medal sensor detects the medal), and when the medal sensor input state at the previous processing is “00000010B”, the normal change value of the medal sensor input state is “000000000B” (first and second medals). (When both sensors have not detected a medal). The method of generating (calculating) the normal change value of the medal sensor input state will be described later in detail.

  Next, the main CPU 101 determines whether or not the medal sensor input state at the time of the current process is the same as the normal change value generated in S257 (S258). In this determination processing, it is determined whether or not a medal backward error has occurred. If the determination condition of S258 is not satisfied, the main CPU 101 determines that a medal backward error has occurred.

  In S258, when the main CPU 101 determines that the medal sensor input state at the time of the current process is not the same as the normal change value generated in S257 (if S258 is NO), the main CPU 101 executes the process of S262 described later. Do.

  On the other hand, in S258, when the main CPU 101 determines that the medal sensor input state at the time of the current process is the same as the normal change value generated at S257 (if S258 is YES), the main CPU 101 proceeds to the current process. It is determined whether or not the input state of the medal sensor is the state at the time of passing the medal (“00000000B”) (S259). In S259, when the main CPU 101 determines that the medal sensor input state at the time of the current process is a state at the time of passing the medal (if S259 is YES), the main CPU 101 performs the process of S263 described later.

  In S259, when the main CPU 101 determines that the medal sensor input state at the time of the current process is not a medal passing state (if S259 is NO), the main CPU 101 sets a medal passing check timer (S260). The time set in the medal passing check timer in this process can be set to any time as long as it is possible to determine whether or not the medal has passed the selector 66. Further, the timer value set in this processing may be changed according to, for example, the medal sensor input state at the time of the current processing.

  After the process of S260 or when the determination of S256 is NO, the main CPU 101 determines whether the medal sensor input state at the time of the current process is a medal passing state (“00000011B”) and the medal passing check timer is stopped. Is determined (S261). In this determination processing, it is determined whether or not a medal passing error (inserted medal passing time error) has occurred. If the determination condition of S261 is satisfied, the main CPU 101 determines that a medal passing error has occurred.

  In S261, when the main CPU 101 determines that the determination condition of S261 is not satisfied (if S261 is NO), the main CPU 101 returns the process to the process of S253, and repeats the processes from S253.

  On the other hand, in S261, when the main CPU 101 determines that the determination condition of S261 is satisfied (when S261 is YES), or when S258 is NO, that is, a medal passing error or a medal backward error has occurred. Is determined, the main CPU 101 performs an error process (S262). In this process, the main CPU 101 performs various processes when an error occurs, such as an error command generation and storage process. The details of the error processing will be described later with reference to FIG. 89 described later. Then, after the processing of S262, the main CPU 101 returns the processing to the processing of S253, and repeats the processing of S253 and thereafter.

  Here, returning to the process of S259 again, if the determination of S259 is YES, the main CPU 101 determines whether or not the specified number (three in the present embodiment) of medals has been inserted (S263). .

  In S263, when the main CPU 101 determines that the specified number of medals has not been inserted (NO in S263), the main CPU 101 performs the medal insertion processing described in FIG. 85 (S264). Then, after the processing of S264, the main CPU 101 returns the processing to the processing of S253, and repeats the processing from S253.

  On the other hand, in S263, when the main CPU 101 determines that the specified number of medals have been inserted (if S263 is YES), the main CPU 101 adds “1” to the value of the credit counter (S265). ). Next, the main CPU 101 performs a medal insertion command generation and storage process (S266). In this process, the main CPU 101 generates data of a medal insertion command to be transmitted to the sub control circuit 200, and stores the command data in a communication data storage area (see FIG. 75B) provided in the main RAM 103. The medal insertion command stored in the communication data storage area is transmitted from the main control circuit 90 to the sub-control circuit 200 by a communication data transmission process in an interrupt process described later with reference to FIG.

  Next, the main CPU 101 determines whether or not the number of medals is equal to the upper limit (50 in the present embodiment) based on the value of the credit counter (S267).

  In S267, when the main CPU 101 determines that the number of credits of medals is not the upper limit value (if S267 is NO), the main CPU 101 returns the process to the process of S253, and repeats the processes from S253. On the other hand, in S267, when the main CPU 101 determines that the number of credits of medals is the upper limit value (if S267 is YES), the main CPU 101 ends the medal insertion check processing, and executes the medal acceptance / start check. The process moves to S229 of the process (see FIG. 83).

  In the present embodiment, the medal insertion check processing is performed as described above. The processing of S255 to S258 during the above-described medal insertion check processing is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. Among them, the process of generating the normal change value of the medal sensor input state in S257 is not performed by referring to the table but is performed by an arithmetic process. Specifically, the process of generating the normal change value is performed by the main CPU 101 executing the source codes “RLA” and “AND cBX_MDINSW” in the source program shown in FIG. 88 in this order.

  The “RLA” instruction is an instruction code that shifts one byte of data stored in the A register one time (one bit) to the left (in a direction from bit 0 to bit 7). In the example shown in FIG. 88, the 1-byte data indicating the previous medal sensor input state stored in the A register by the source code “LD A, B” executed before the “RLA” instruction is replaced with the “RLA” instruction. Shifts once to the left. At this time, the bit data newly stored in the bit 0 is determined based on the execution result of the source code “CP cBX_MDISW2” executed before the “RLA” instruction.

  The “CP” instruction is an instruction code for executing a comparison operation. “CBX_MDISW2” is 1-byte data, and is “00000010B” in the present embodiment. When the source code “CP cBX_MDISW2” is executed, 1-byte data indicating the previous medal sensor input state stored in the A register is compared with “cBX_MDISW2 (00000010B)”.

  If the result of executing the source code “CP cBX_MDISW2” indicates that the one-byte data indicating the previous medal sensor input state is less than “cBX_MDISW2 (00000010B)”, the carry of the flag register F is performed. The flag (see FIG. 11) is set to "1", and when the "RLA" instruction is executed, "1" of the carry flag of the flag register F is stored in bit 0 of the A register. On the other hand, if the result of executing the source code “CP cBX_MDISW2” indicates that the 1-byte data indicating the previous medal sensor input state is “cBX_MDISW2 (00000010B)” or more, the carry of the flag register F is performed. The flag (see FIG. 11) is set to "0", and the carry flag "0" of the flag register F is stored in bit 0 of the A register by execution of the "RLA" instruction.

  Therefore, for example, if the one-byte data indicating the previous medal sensor input state is “00000000B (state before or after (passing) medal passing)” (<“cBX_MDISW2”), the “RLA” instruction By the execution, “00000001B” is generated. If the one-byte data indicating the previous medal sensor input state is “00000001B (state at the start of medal passing)” (<“cBX_MDISW2”), the “RLA” instruction is executed. Generates “00000011B”. On the other hand, for example, if the one-byte data indicating the previous medal sensor input state is “00000011B (medal passing state)” (> “cBX_MDISW2”), “00000110B” is generated by executing the “RLA” instruction. If the one-byte data indicating the previous medal sensor input state is “00000010B (state immediately before medal passing is completed)” (= “cBX_MDISW2”), “0000100B” is generated by executing the “RLA” instruction. You.

  Next, when the source code “AND cBX_MDINSW” is executed, 1-byte data (stored data in the A register) generated by execution of the “RLA” instruction is logically ANDed with 1-byte data “cBX_MDINSW”, and the medal sensor is executed. A normal change value of the input state is calculated. The one-byte data “cBX_MDISW” is “00000011B” in the present embodiment. Therefore, if the source code “AND cBX_MDINSW” is executed, only the data of bit 0 and bit 1 in the data stored in the A register are masked, and the other bit data becomes “0”.

  As a result, for example, if the one-byte data indicating the previous medal sensor input state is “00000000B (state before medal passing)”, the normal change value of the medal sensor input state is “00000001B (state at the start of medal passing). )) Is generated, and if the one-byte data indicating the previous medal sensor input state is “00000001B (state at the start of medal passing)”, the normal change value of the medal sensor input state is “00000011B (medal passing state). State) is generated. On the other hand, for example, if the one-byte data indicating the previous medal sensor input state is “00000011B (medal passing state)”, the normal change value of the medal sensor input state is “00000010B (state immediately before medal passing completion). Is generated, and if the one-byte data indicating the previous medal sensor input state is “00000010B” (the state immediately before the completion of the medal passing), “000000000B (after the medal passing (passing) State)) is generated.

  As described above, by changing the process of detecting the change state of the medal sensor input state from the table reference process to the calculation process, the free space of the table storage area of the main ROM 102 can be increased, and the program capacity can be increased. Can be minimized. Therefore, by employing the above-described method, the efficiency of the process of detecting the state of the medal insertion sensor can be improved, and the increased vacant space in the main ROM 102 can be used to enhance the playability.

[Error processing]
Next, with reference to FIGS. 89 and 90, for example, an error process performed in S262 during the medal insertion check process (see FIG. 87) will be described. FIG. 89 is a flowchart showing the procedure of error processing, and FIG. 90 is a diagram showing an example of the configuration of an error table that is actually referred to on a source program for error processing.

  In the error table shown in FIG. 90, for each 1-byte data indicating the on / off state of the port indicating the type of the error factor (for example, 1-byte data stored in the address “dERR_HE” in FIG. 90), Error display data (for example, 1-byte data stored at addresses “dERR_HE + 1” and “dERR_HE + 2” in FIG. 90) is defined. The error display data is output to a 2-digit 7-segment LED (for both payout number display and error display) included in the information display 6.

  First, the main CPU 101 performs a process of turning off the medal solenoid (S271). Specifically, the main CPU 101 stops driving the solenoid of the selector 66 (see FIG. 7). Next, the main CPU 101 performs evacuation processing of the medal payout number display data (S272).

  Next, the main CPU 101 performs an error table setting process (S273). By this processing, the head address of the error table shown in FIG. 90 is set on the source program.

  Next, the main CPU 101 acquires an error factor (S274). Note that the error factor obtained in this process changes according to the process of reading the error process currently being processed. As shown in FIG. 90, the error factors targeted in this embodiment are “hopper empty error”, “hopper jam error”, “inserted medal passing count error”, “inserted medal passing check error”, “ An inserted medal passing check error, an inserted medal passing time error, an inserted medal reverse error, an inserted medal auxiliary storage full error, and an illegal hit error are defined. For example, if the error processing is read out after the processing of S258 during the medal insertion check processing, in this processing, “inserted medal backward error (Cr)” in FIG. 90 is acquired as an error factor. Further, for example, when the error processing is read out after the processing of S261 during the medal insertion check processing, in this processing, “inserted medal passing time error (CE)” in FIG. 90 is acquired as an error factor. .

  Next, the main CPU 101 acquires error display data from the error table and the error cause (S275). For example, when the error factor is “insertion medal backward error (Cr)”, in this processing, the error display data shown in FIG. 90 is output as error display data to be output to the upper 7-segment LED of the 2-digit 7-segment LED. The 1-byte data “001001110B” stored at the address “dERR_CR + 1” in the table is acquired, and the 1-byte data “0000001001B” stored at the address “dERR_CR + 2” is output as error display data to be output to the lower 7-segment LED. Is obtained. In this case, two characters “Cr” are displayed as error information on the 2-digit 7-segment LED.

  Next, the main CPU 101 performs an error command (occurrence) generation and storage process (S276). In this process, the main CPU 101 generates error command data to be transmitted to the sub control circuit 200 when an error occurs, and stores the command data in a communication data storage area (see FIG. 75B) provided in the main RAM 103. . The error command stored in the communication data storage area when an error occurs is transmitted from the main control circuit 90 to the sub control circuit 200 by a communication data transmission process in an interrupt process described later with reference to FIG. The error command at the time of occurrence of an error includes a parameter indicating the occurrence of the error.

  Next, the main CPU 101 performs a standby process for one interruption time (1.1172 ms) (S277). Next, the main CPU 101 determines whether or not the error has been cleared (S278).

  In S278, when the main CPU 101 determines that the error has not been cleared (NO in S278), the main CPU 101 returns the processing to S277, and repeats the processing from S277.

  On the other hand, in S278, when the main CPU 101 determines that the error has been cleared (if S278 is YES), the main CPU 101 performs an error factor clearing process (S279). This process is performed in a non-defined work area of the main RAM 103. Next, the main CPU 101 performs a process of restoring the payout number display data of the medals saved in S272 (S280).

  Next, the main CPU 101 performs an error command (release) generation and storage process (S281). In this processing, the main CPU 101 generates data of an error command at the time of error cancellation to be transmitted to the sub control circuit 200, and stores the command data in a communication data storage area (see FIG. 75B) provided in the main RAM 103. . The error command at the time of error cancellation stored in the communication data storage area is transmitted from the main control circuit 90 to the sub control circuit 200 by a communication data transmission process in an interrupt process described later with reference to FIG. The error command at the time of error cancellation includes a parameter indicating error cancellation. Then, after the processing of S281, the main CPU 101 ends the error processing, and moves the processing to, for example, S253 in the medal insertion check processing (see FIG. 87). In the error release, the error factor that has occurred is released, and the error state is released by pressing the reset switch 76.

[Random number acquisition processing]
Next, the random number acquisition process performed in S203 in the main flow (see FIG. 82) will be described with reference to FIG. FIG. 91 is a flowchart illustrating the procedure of the random number acquisition process.

  First, the main CPU 101 acquires a hard latch random number (0 to 65535) in the random number register 0 of the random number circuit, and uses the acquired random number value as a random number value for internal winning combination lottery in the random number value storage area (non- (S291).

  Next, the main CPU 101 generates soft latch random numbers (0 to 65535: random number value for effect used in ART-related lottery processing, 0 to 255: random number value in 1-byte lottery processing) of the random number registers 1 to 7 of the random number circuit. A soft latch random number acquisition register is set to perform the setting (S292). Next, the main CPU 101 sets the number of acquired soft latch random numbers (for example, 7) (S293).

  Next, the main CPU 101 collectively acquires the acquired number of soft latch random numbers and stores the acquired number of soft latch random numbers in the random number value storage area (S294). At this time, the soft latch random number (production random number value, 2-byte random number value) obtained from the random number register 1 of the random number circuit 110 is stored in the random number value storage area in the hardware random number register 0 of the random number circuit. The latch random number (the random number value for internal winning combination lottery) is stored in an area different from the area where the random number is stored. Then, after the process of S294, the main CPU 101 ends the random number acquisition process, and moves the process to S204 of the main flow (see FIG. 82). In the present embodiment, a 12-byte storage area is allocated to the main RAM 103 as a random number storage area in order to store four 2-byte random numbers and four 1-byte random numbers.

[Internal lottery processing]
Next, an internal lottery process performed in S204 in the main flow (see FIG. 82) will be described with reference to FIGS. FIG. 92 is a flowchart showing the procedure of the internal lottery process. FIG. 93A is a diagram showing an example of a source program for executing the processes of S302 to S305 during the internal lottery process. It is a figure showing an example of a source program for performing processing of S308-S309 during internal lottery processing.

  FIG. 94 is a diagram illustrating an example of the configuration of an internal lottery table (for a general game) that is actually referred to on the source program of the internal lottery process. FIG. 9 is a diagram showing an example of the configuration of a RT state-based lottery value selection table that is actually referred to. Further, FIG. 96 shows an internal lottery value table selection table, a 1-byte internal lottery value table, a 2-byte internal lottery value table, and an internal lottery value table for each 1-byte setting, which are actually referred to on the source program of the internal lottery processing. FIG. 14 is a diagram showing an example of the configuration of an internal lottery value table for each of two-byte settings. In this embodiment, an internal lottery table for RB (BB) is also provided. However, here, the configuration of the internal lottery table for RB referred to on the source program of the internal lottery process is illustrated. Omitted.

  First, the main CPU 101 performs a setting value / medal insertion number check process (S301). In this process, the main CPU 101 performs a process of checking the set value of the current game (any one of 1 to 6) and the number of inserted medals (three in the present embodiment).

  Next, the main CPU 101 sets an internal lottery table for a general game and the number of lotteries (53 in this embodiment) (S302). In this processing, the value (winning request flag status) of “special prize winning number + small win winning number” in the internal lottery table (for general gaming) shown in FIG. The value of the lottery coefficient table (judgment data: data relating to the address) is set in the A register. As shown in FIG. 94, the winning request flag status is a special prize winning number ("00H (out)", "01H (BB1)", "02H (BB2)": decimal number 0, 1, 2). “25H (hexadecimal: decimal number 37 (special prize number described later)) is multiplied by the small winning combination number (“ 00H ”to“ 24H ”: decimal number 0 to 36). .

  Next, the main CPU 101 determines whether or not the RB operation is being performed (S303). In S303, when the main CPU 101 determines that the RB operation is not being performed (NO in S303), the main CPU 101 performs the processing of S305 described later.

  On the other hand, in S303, when the main CPU 101 determines that the RB is in operation (if the determination in S303 is YES), the main CPU 101 determines the internal lottery table for the RB and the number of lotteries (five times in the present embodiment). It is set (S304). In this process, the internal lottery table and the number of times of lottery set in S302 are overwritten with the internal lottery table and the number of times of lottery set during RB.

  After the processing of S304 or when the determination of S303 is NO, the main CPU 101 acquires the determination data (data relating to the address) of the lottery target combination from the set internal lottery table, and updates the lottery table address (S305).

  Next, the main CPU 101 determines whether or not the determination data is RT state-specific data (S306). In this process, the main CPU 101 determines whether or not the currently acquired lottery target combination is an internal winning combination whose lottery value changes according to the RT state. Specifically, the main CPU 101 determines whether or not the address specified in the determination data of the currently acquired lottery target combination is an address in the RT state-based lottery value selection table shown in FIG. 95. .

  For example, in the determination data “(dRPPTR01−dRTRB_SEL) * 2 + 001H” associated with the internal winning combination “F_Chililip” in the internal lottery table of FIG. 94, the internal winning in the RT state-based lottery value selection table shown in FIG. 95 is determined. Since the address “dRPPTR01” of the combination “F_Chililip” is defined, the determination data associated with the internal winning combination “F_Chililip” corresponds to the RT state-specific data. Therefore, when the currently acquired lottery target combination is the internal winning combination “F_Chililip”, in the process of S306, the main CPU 101 determines that the determination data is the RT state-specific data.

  In S306, when the main CPU 101 determines that the determination data is not RT state-specific data (NO in S306), the main CPU 101 performs the processing of S308 described later. On the other hand, in S306, when the main CPU 101 determines that the determination data is RT state-specific data (if S306 is YES), the main CPU 101 selects the RT state lottery value shown in FIG. 95 based on the determination data. The selection data is obtained from the table, and the obtained selection data is set as the determination data (S307).

  After the processing of S307 or when the determination of S306 is NO, the main CPU 101 determines whether or not the determination data of the lottery target combination is the data according to the setting (S308). In this process, the main CPU 101 determines whether or not the currently acquired lottery target combination is an internal winning combination whose lottery value changes according to the set value. Specifically, the main CPU 101 determines that the address specified in the determination data of the currently acquired lottery target combination is within the 1-byte setting internal lottery value table or the 2-byte setting internal lottery value table shown in FIG. Is determined.

  For example, in the internal lottery table of FIG. 94, the determination data “((dNMLB00F289−dPRB_DB_WV) / 06H) * 2 + 080H” associated with the internal winning combination “F_Strong Chile 1” shown in FIG. Since the address “dNMLB00F289” of the internal winning combination “F_Strong Chile 1” in the lottery value table is defined, the determination data associated with the internal winning combination “F_Strong Chile 1” corresponds to the setting-specific data. I do. Therefore, when the currently obtained lottery target combination is the internal winning combination “F_strong dust 1”, in the process of S308, the main CPU 101 determines that the determination data is the setting-specific data.

  In S308, when the main CPU 101 determines that the determination data is not the setting-specific data (NO in S308), the main CPU 101 performs the process of S310 described later. On the other hand, when the main CPU 101 determines in S308 that the determination data is the setting-specific data (YES in S308), the main CPU 101 adds the set value data (any of 0 to 5) to the determination data. Then, the added value is set in the determination data (S309). The set value data added to the determination data in this process is data associated with the set value, but is not the value of the set value itself, and the set value data “0” to “5” are “ This is data corresponding to “Setting 1” to “Setting 6”.

  After the processing of S309 or when the determination of S308 is NO, the main CPU 101 calculates the address of the area in which the lottery value of the lottery target combination is stored based on the set determination data (address data), and The stored lottery value is obtained (S310).

  In the process of S310, for example, when the lottery target combination is the internal winning combination “F_SABO2” whose lottery value does not depend on both the RT state and the set value, the 1-byte internal lottery value table shown in FIG. , The lottery value “128” stored at the address “dNM_B00F26” is obtained. Also, for example, when the lottery target combination is an internal winning combination “F_RT3 lip_1st” whose lottery value changes according to the RT state and the RT state is the RT2 state, a 2-byte internal lottery value table shown in FIG. , The lottery value “1800” stored at the address “dRT2B00F13456” is obtained.

  In the process of S310, for example, if the lottery target combination is the internal lottery combination “F_Strong Chile 1” whose lottery value changes according to the set value, the internal lottery value table for each 1-byte setting shown in FIG. Out of the six types of lottery values “150 (setting 1), 150 (setting 2), 150 (setting 3), 150 (setting 4), 160 (setting 5), and 170 (setting 6)” defined in A lottery value corresponding to the set value is obtained. At this time, the lottery value corresponding to the setting value is obtained by adding the setting value data to the determination data (processing of S309) and specifying the address obtained. Therefore, for example, when the lottery target combination is “F_strong dust 1” and the set value is “6” (set value data is “5”), the lottery value “dNMLB00F289 + 5” stored in the address “dNMLB00F289 + 5” 170 "is obtained.

  In the present embodiment, when the lottery value is a combination that depends on both the RT state and the set value, for example, as in the internal winning combination “F_maintenance lip A”, the internal lottery value table and the internal lottery for each setting are set. The lottery value is obtained by referring to both of the value tables.

  Next, the main CPU 101 acquires the random number value (any of 0 to 65535) for internal winning combination lottery stored in the random number storage area (S311).

  Next, the main CPU 101 performs a lottery execution process (S312). In this process, the main CPU 101 adds the random number value acquired in S311 to the lottery value acquired in S310, and sets the addition result as a lottery result (winning / non-winning of the lottery target combination). In the lottery execution process, when the sum of the lottery value and the random number value exceeds 65535 (in the case of overflow), it is determined that the lottery target combination has been won (the lottery target combination has been determined as an internal winning combination). You.

  Next, the main CPU 101 stores the value obtained by adding the random number value to the random number value (the random number value after the execution of the random determination) as a new random number value in the random number storage area (S313). Next, the main CPU 101 determines whether or not the lottery has been won in the lottery execution process (whether or not an overflow has occurred) (S314).

  In S314, when the main CPU 101 determines that the lottery execution process has been won (if S314 is YES), the main CPU 101 refers to the internal lottery table to determine the winning request flag status (corresponding to the internal winning combination won) ( The value of “special prize winning number + small winning combination number” is acquired (S315). For example, during a general game, if the lottery target combination is “F_Surely Lip” and the lottery execution process is won, in the process of S315, the hit request flag status “(00H * 25H) + 02H” (special prize winning number = 0, small win number = 2) is obtained. Then, after the processing of S315, the main CPU 101 ends the internal lottery processing, and moves the processing to S205 of the main flow (see FIG. 82).

  On the other hand, in S314, when the main CPU 101 determines that the lottery is not won in the lottery execution process (if S314 is NO), the main CPU 101 updates the lottery target role to the next role in the internal lottery table, and the lottery. The number of times is subtracted by 1 (S316). Next, the main CPU 101 determines whether or not the number of lotteries after the subtraction is “0” (S317).

  In S317, when the main CPU 101 determines that the number of lotteries after the subtraction is not “0” (if S317 is NO), the main CPU 101 returns the processing to the processing of S305, and repeats the processing from S305.

  On the other hand, in S317, when the main CPU 101 determines that the number of lotteries after the subtraction is “0” (if S317 is YES), that is, when the internal winning combination is “out”, the main CPU 101 The losing status is set (S318). The “losing status” corresponds to a hit request flag status in which both the special winning number and the small winning number are “0”. Then, after the processing of S318, the main CPU 101 ends the internal lottery processing, and moves the processing to S205 of the main flow (see FIG. 82).

  In the present embodiment, the internal lottery process is performed as described above. Note that the processing of S302 to S305 during the internal lottery processing described above is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 93A. Among them, the acquisition processing of the determination data in S305 is executed by the source code “LDIN AC, (HL)” in FIG. 93A.

  For example, when the source code “LDIN ss, (HL)” is executed on the source program, the memory specified by the address set in the HL register (pair register) and the address obtained by adding “1” to the address Is loaded into the ss (BC, DE, AC, AE, or BD) pair register, and the address set in the HL register is updated by +2 (addition of 2). Therefore, when the source code “LDIN AC, (HL)” in FIG. 93A is executed, the contents of the memory specified by the address set in the HL register (pair register) and the address obtained by adding 1 to the address ( ) Is loaded into the AC register, and the address set in the HL register is updated by +2 (addition of 2). In the determination data acquisition process in S305, as described above, the determination data (the value of the "lottery value selection table or the random determination coefficient table") is stored in the A register by the "LDIN" instruction (the predetermined read instruction). The hit request flag status (the value of “special prize winning number + small win winning number”) is stored in the C register.

  As described above, in the acquisition processing of the determination data in S305 during the internal lottery processing, both the data loading processing and the address updating processing can be performed by one instruction code (“LDIN” instruction). In this case, the instruction code relating to the address setting can be omitted from the source program, and the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  Further, the processing of S308 and S309 during the above-described internal lottery processing is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 93B. Among them, in the addition processing of the set value data (any of 0 to 5) in S309, the main CPU 101 executes the source code “MUL A, 6” and “ADDQ A, (.LOW.wWAVENUM)” in FIG. 93B. It is performed by executing in this order. Note that both the “MUL” instruction and the “ADDQ” instruction are instruction codes dedicated to the main CPU 101, and the “ADDQ” instruction is an instruction code dedicated to the main CPU 101 for specifying an address using a Q register (extended register).

  For example, when the source code “MUL A, n” is executed on the source program, the data stored in the A register is multiplied by a 1-byte integer n, and the multiplication result is stored in the A register. Therefore, in the source code “MUL A, 6” in FIG. 93B, the contents (storage data) of the A register are multiplied by the 1-byte integer 6, and the multiplication result is stored in the A register. This multiplication process is executed by the arithmetic circuit 107 (see FIG. 9) included in the microprocessor 91. That is, the pachislo 1 of the present embodiment is provided with a dedicated operation circuit (arithmetic circuit 107) for executing the multiplication processing and the division processing on the source program, so that the efficiency of the multiplication processing and the division processing is improved. Can be.

  Further, for example, when the source code “ADDQ r, (k)” is executed on the source program, the data stored in the Q register (upper address value) and the 1-byte integer k (direct value: lower address value) ) Is added to the contents (stored data) of the memory at the address specified by the register (A, B, C, D, E, H or L register), and the result of the addition is stored in the r register. You. Therefore, when the source code "ADDQ A, (.LOW.wWAVENUM)" in FIG. 93B is executed, the data stored in the Q register and the memory at the address specified by the 1-byte integer value ".LOW.wWAVENUM" Is added to the content (set value data) of the A register, and the result of the addition is stored in the A register.

  That is, in the example shown in FIG. 93B, in the addition processing of the set value in S309, the lottery table selection relative value is multiplied by the coefficient “6”, and the multiplied value is added to the set value data, thereby obtaining the lottery target combination. The address of the lottery table storing the lottery value is calculated.

  As described above, in the present embodiment, in the internal lottery processing, the instruction code (“ADDQ” instruction) dedicated to the main CPU 101 using the Q register (extended register) is used. Thereby, the main ROM 102, the main RAM 103, and the memory map I / O can be accessed. Therefore, in the source program of the internal lottery process, the instruction related to the address setting can be omitted, and the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Symbol setting processing]
Next, the symbol setting process performed in S205 in the main flow (see FIG. 82) will be described with reference to FIGS.

  FIG. 97 is a flowchart showing the procedure of the symbol setting process. FIG. 98 is a correspondence table of a special prize (bonus) winning number and a small winning combination number and an internal winning combination. In FIG. 98, the illustration of the special prize winning number and the small winning combination number corresponding to “losing (00)” is omitted. FIG. 99 is a diagram showing an example of a source program for executing the processing of S324 to S330 during the symbol setting process. FIG. It is a figure showing an example of composition of a request flag table (flag data table, winning flag table data).

  First, the main CPU 101 extracts a special prize winning number and a small winning combination number based on the hit request flag status acquired in the internal lottery process, and stores the extracted special prize winning number and small combining winning number in the main RAM 103. It is stored in a winning number storage area (not shown) (S321).

  In this embodiment, as shown in FIG. 98, the internal winning combinations “F_BB1” and “F_BB2” are associated with the special prize (bonus) winning numbers “1” and “2”, respectively. Further, the internal winning combinations “F_Chililip” to “F_RB combination 4” are respectively associated with the small winning combinations “1” to “36”. As described with reference to FIG. 94, the value of the hit request flag status is obtained by multiplying a special prize winning number by a special prize number (“37 (25H in hexadecimal)” in this embodiment) and a small combination winning number. This is the value added. Therefore, in the process of S321, in order to extract the special prize winning number and the small winning combination number from the value of the hit request flag status, in the present embodiment, the main CPU 101 sets the value of the hit request flag status to the special prize number (“37”). ). As a result, the value of the quotient generated by the division process becomes the special prize winning number (any of 0 to 2 in decimal), and the remaining value is the small winning number (any of 0 to 36 in decimal). Become.

  Next, the main CPU 101 determines whether or not the small combination has been won based on the extracted small combination winning number (S322). In this process, if the small combination winning number is one of 1 to 36, the main CPU 101 determines that the small combination has been won, and if the small combination winning number is 0, the main CPU 101 It is determined that the small combination has not been won.

  In S322, when the main CPU 101 determines that the small combination has not been won (if S322 is NO), the main CPU 101 performs the processing of S331 described later. On the other hand, in S322, when the main CPU 101 determines that the small win has been won (if S322 is YES), the main CPU 101 sets the small win win number as an initial value of the subtraction result (S323).

  Next, the main CPU 101 sets a hit request flag table (see FIG. 100) (S324). Next, the main CPU 101 subtracts 1 from the subtraction result and updates the subtraction result (S325). Next, the main CPU 101 determines whether or not the subtraction result is less than “0” (S326).

  In S326, when the main CPU 101 determines that the subtraction result is not less than “0” (if S326 is NO), the main CPU 101 performs a bit number calculation process (S327). In the bit number calculation processing in S327, the number of blocks in the storage area of the hit request flag data corresponding to the small winning combination number specified in the hit request flag table is obtained.

  In this embodiment, in the hit request flag storage area (internal winning combination storage area), blocks of hit request storage areas 0 to 7 and blocks of hit request storage areas 8 to 11 are provided. Therefore, the maximum value of the number of blocks in the storage area of the hit request flag data acquired in the bit number calculation processing of S327 is “2”. For example, when the internal winning combination is “F_Surely Lip”, as shown in the hit request flag table (see FIG. 100), the storage area 7 included in the blocks of the hit request storage areas 0 to 7 and the hit request Since the hit request flag data is defined in each of the storage areas 9 included in the blocks of the storage areas 8 to 11, the number of blocks of the hit request flag data storage area acquired in the bit number calculation process in S327 is “2”. Becomes

  Next, the main CPU 101 performs a bit number calculation process (S328). In the bit number calculation process of S328, the number of bytes of the hit request flag data per block specified in the hit request flag table (see FIG. 100) is calculated. For example, when the internal winning combination is “F_Surely Lip”, both the storage area 7 and the storage area 9 store 1-byte hit request flag data as shown in the hit request flag table (see FIG. 100). Therefore, the number of bytes of the request flag data per block obtained in the bit number calculation process in S328 is 1 byte. In the table shown in FIG. 100, the hit request flag data stored in the storage area 7 is described as “10000000B | 01000000B”. “10000000B” or (“|” is a logical sum symbol) means “0100000B”.

  Note that the processing of S325 to S328 described above is repeated by the number of small combination winning numbers. For example, when the internal winning combination is "F_Surely Chill Lip" (the small winning combination number is "2"), the processing of S325 to S328 described above is repeated twice. When the processing of S325 to S328 is repeated a plurality of times, the number of blocks and the number of bytes of the hit request flag data per block obtained in the bit number calculation processing of S327 and S328 are stored in separate storage areas. Is done. Further, the number of blocks and the number of bytes of the hit request flag data per block obtained by the above-described processing of S325 to S328 serve as information (on-bit information) for specifying the storage location of the hit request flag data.

  Here, returning to the process of S326 again, in S326, when the main CPU 101 determines that the subtraction result is less than “0” (if S326 is YES), the main CPU 101 returns to the hit request flag storage area ( The internal winning combination storage area is set (S329). At this time, the main CPU 101 determines the hit request flag to be checked (updated) based on the number of blocks obtained by the above-described processing of S325 to S328 and the number of bytes (on-bit information) of the hit request flag data in block units. Set only the storage area. Specifically, the address of the hit request flag storage area to be checked (updated) is stored in the DE register (see FIG. 99).

  Next, the main CPU 101 performs a compressed data storage process (S330). In this process, the main CPU 101 mainly performs a process of transferring (developing) the hit request flag data to a predetermined storage area in the hit request flag storage area to be checked (updated). Details of the compressed data storage processing will be described later with reference to FIG.

  After the process of S330 or when the determination of S322 is NO, the main CPU 101 refers to the carryover combination storage area (see FIG. 31) to determine whether there is a carryover combination (S331). In S331, when the main CPU 101 determines that there is a carryover combination (if S331 is YES), the main CPU 101 performs the process of S334 described later.

  On the other hand, in S331, when the main CPU 101 determines that there is no carryover combination (if S331 is NO), the main CPU 101 determines the bonus combination (BB1 or BB2) based on the special prize winning number extracted in the process of S321. ) Is determined (S332).

  In S332, when the main CPU 101 determines that the bonus combination has not been won (NO in S332), the main CPU 101 ends the symbol determination process, and proceeds to S206 of the main flow (see FIG. 82). Move.

  On the other hand, if the main CPU 101 determines in S332 that the bonus combination has been won (if S332 is YES), the main CPU 101 stores the won special prize winning number in the carryover combination storage area (S333).

  After the processing of S333 or when the determination of S331 is NO, the main CPU 101 sets the special prize winning number in the winning number storage area (not shown), sets the hit request flag data in the hit request flag storage area, and sets the RT state to RT5. The state is set, and the number of RT games (the number of digested games in the RT1 state) is cleared ("0") (S334). Then, after the processing of S334, the main CPU 101 ends the symbol setting processing, and moves the processing to S206 of the main flow (see FIG. 82).

  In the present embodiment, the symbol setting process is performed as described above. The processing of S324 to S330 in the above-described symbol setting processing (compression / expansion processing of winning data) is performed by the main CPU 101 sequentially executing each source code defined in the source program of FIG. . Among them, the compressed data storage processing of S330 is performed by the main CPU 101 executing the source code “CALLF SB_BTEP_00” in FIG.

  The “CALLF” instruction is a two-byte instruction code dedicated to the main CPU 101 as described above. When the source code “CALLF SB_BTEP_00” in FIG. 99 is executed, the process is executed at the address specified by “SB_BTEP_00”. A jump is made to start the compressed data storage processing. In the compressed data storage process of S330, as described above, the hit request flag data (compressed data) stored in the hit request flag table is expanded (copied) to the corresponding hit request flag storage area.

  Further, the address setting process of the hit request flag storage area in S329 during the above-described symbol setting process is performed by the main CPU 101 executing the source code “LDQ DE, .LOW. WWAVEBIT” in FIG. That is, the process of S329 during the symbol setting process is performed by an “LDQ” instruction dedicated to the main CPU 101 for specifying an address using a Q register (extension register). In this case, the instruction code relating to the address setting can be omitted in the source program of the symbol setting process, and the capacity of the source program of the symbol setting process (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  Further, in the present embodiment, the compression / decompression processing of the winning data is performed in the processing procedure described in S324 to S330 in the above-described symbol setting processing, and the main CPU 101 exclusive instruction code is executed in the processing. By using this, it is possible to increase the efficiency of the compression / decompression processing of the data related to the winning, and to effectively utilize the limited capacity of the main RAM 103.

[Compressed data storage processing]
Next, the compressed data processing performed in S330 during the symbol determination processing (see FIG. 97) will be described with reference to FIG. FIG. 101 is a flowchart illustrating the procedure of the compressed data storage process.

  The compressed data storage process shown in FIG. 101 is executed not only in S330 in the symbol determination process (see FIG. 97), but also in S649 in the symbol code acquisition process described later (see FIG. 128 described later). In the compressed data storage process executed in S330 during the symbol determination process (see FIG. 97), the flag data to be processed is the hit request flag data (the flag data relating to the winning combination), but the symbol code acquisition process described later. In the compressed data storage processing executed in S649 in (see FIG. 128 described later), the flag data to be processed is winning operation flag data (flag data relating to a winning combination). The two processes are the same except that the types of flag data to be processed are different.

  Therefore, in the flowchart of FIG. 101, the flag data to be processed is described as “processing flag data”, and the flag table to be processed is described as “processing flag table”. In accordance with this description, also in the following description of the compressed data storage processing, the hit request flag data or the winning operation flag data is referred to as “processing target flag data”, and the hit request flag table (see FIG. 100) or a later described The symbol corresponding winning operation table (for example, see FIG. 130A described later) is referred to as a “processing target flag table”.

  First, the main CPU 101 sets a storage destination check bit (S341). In this process, the storage destination check bit is stored in a register other than the A register.

  The storage destination check bit is 1-byte data for specifying a block to be a storage destination (transfer destination) of the processing target flag data. In the present embodiment, each of the hit request flag storage area and the winning operation flag storage area is composed of two blocks (blocks of storage areas 0 to 7 and blocks of storage areas 8 to 11). Then, for example, when the internal winning combination “F_Sure Chill Lip” is determined, the hit request flag data is stored in each of the storage areas 7 and 9 as shown in the hit request flag table of FIG. 100. (Because the number of storage destination blocks is "2"), in the process of S341, "00000011B" is set as the storage destination check bit. The value of bit 0 (1/0) of the 1-byte data corresponds to the presence or absence of a storage destination in the block of storage areas 0 to 7, and the value of bit 1 (1/0) corresponds to storage areas 8 to 11. Corresponds to the presence or absence of the storage destination in the block.

  Next, the main CPU 101 sets the value of the transfer counter in byte units to “8” (S342). In this embodiment, since the number of bytes in each block is “8”, “8” is set as the initial value of the transfer counter.

  Next, the value of the transfer instruction bit is extracted from the storage destination check bit (S343). Note that the transfer instruction bit corresponds to the data of bit 0 in the storage destination check bit, and in the process of S343, the storage destination check bit stored in the 1-byte register is right-shifted once (one bit). Thereby, the transfer instruction bit is extracted. Specifically, when the 1-byte register (the register other than the A register) in which the storage destination check bit is stored is right-shifted once, the data stored in bit 7 to bit 1 is changed to bit 6 to bit 0, respectively. At the same time, the data of bit 0 before the shift is output. Then, the data output by this shift processing becomes the value of the transfer instruction bit.

  Next, the main CPU 101 determines whether or not there is a transfer instruction based on the value of the extracted transfer instruction bit (S344). In this process, the main CPU 101 determines that there is a transfer instruction when the value of the extracted transfer instruction bit is “1”. For example, if “00000011B” is set as the storage destination check bit, the transfer is performed in the first (corresponding to the first block of the storage area) and the second (corresponding to the second block of the storage area) S344. Although it is determined that there is an instruction, in the third and subsequent determination processing in S344, it is determined that there is no transfer instruction.

  In S344, when the main CPU 101 determines that there is no transfer instruction (when S344 is NO), the main CPU 101 performs the processing of S354 described later.

  On the other hand, in S344, when the main CPU 101 determines that there is a transfer instruction (YES in S344), the main CPU 101 acquires the byte unit storage location designation information from the processing target flag table (S345). In this process, as the byte-unit storage destination designation information, 1 indicating the transfer destination stored in the head address of the area where the flag data of the processing target combination (winning combination or winning combination) in the processing target flag table is stored. Byte data is obtained. For example, when the internal winning combination is “F_Surely Reliable”, the storage request stored in the head address of the area in which the flag data of “F_Surely Reliable” in the hit request flag table shown in FIG. 100 is stored. One-byte data “10000000B” that specifies the area 7 as a transfer destination is obtained as byte-unit storage destination specification information.

  Next, the main CPU 101 performs an update process of the address referred to in the process target flag table (a process of adding 1 to the address) (S346). In this process, the main CPU 101 sets, as an initial address, an address designating a head storage area of a block in which the processing target flag data is stored (transferred). For example, in the processing of the first block, the address of the storage area 0 is set as the initial address in the processing of S346, and in the processing of the second block, the address of the storage area 8 is set as the initial address in the processing of S346. .

  Next, the main CPU 101 extracts the value of the transfer instruction bit from the byte unit storage location designation information (S347). Here, the transfer instruction bit corresponds to bit 0 of the byte-unit storage destination designation information. In the process of S347, the byte-unit storage destination designation information stored in the 1-byte register is right-shifted once. Extracts the value of the transfer instruction bit (outputs the data of bit 0).

  Next, the main CPU 101 determines whether or not there is a transfer instruction based on the value of the transfer instruction bit extracted in the process of S347 (S348). In this processing, when the value of the extracted transfer instruction bit is “1”, the main CPU 101 determines that there is a transfer instruction. For example, when “00000010B” is set as the byte-unit storage destination designation information, the data of bit 1 “1” in the processing of S347 for the second time (storage area 1 of the first block or storage area 9 of the second block) Is output as the value of the transfer instruction bit to determine that there is a transfer instruction. However, in the first and third to eighth S347 processes, it is determined that there is no transfer instruction.

  In S348, when the main CPU 101 determines that there is no transfer instruction (NO in S348), the main CPU 101 performs the process of S351 described later.

  On the other hand, in S348, when the main CPU 101 determines that there is a transfer instruction (if S348 is YES), the main CPU 101 sets the processing target flag stored at the address in the currently set processing target flag table. The data (win request flag data or winning operation flag data) is transferred (copied) to the designated storage area (S349).

  For example, if the internal winning combination is “F_SureClip” and the current processing is performed on the storage area of the first block (storage areas 0 to 7), the byte-unit storage destination designation information is “ 10000000B ”(data designating the storage area 7 as a storage destination), it is determined that there is a transfer instruction in the processing of the eighth S347, and in the subsequent processing of S349, the hit request flag data“ 10000000B ”,“ 01000000B ” , "00100000B" or "00010000B" is transferred (copied) to the storage area 7 of the hit request flag storage area.

  Next, the main CPU 101 performs a process of updating an address referred to in the process target flag table (a process of adding one to the address) (S350).

  After the processing of S350 or when the determination of S348 is NO, the main CPU 101 performs an update processing (processing of adding one address) of an address specifying a storage area to be a storage destination of the processing target flag data (S351). Next, the main CPU 101 decrements the value of the transfer counter by one (S352).

  Next, the main CPU 101 determines whether or not the value of the transfer counter is “0” (S353). In S353, when the main CPU 101 determines that the value of the transfer counter is not “0” (if S353 is NO), the main CPU 101 returns the process to S347, and repeats the process from S347.

  On the other hand, in S353, when the main CPU 101 determines that the value of the transfer counter is “0” (if S353 is YES), the main CPU 101 determines whether the transfer instruction target remains in the current storage destination check bit. It is determined whether or not it is (S354). In this process, the main CPU 101 determines whether or not a bit storing “1” remains in the storage destination check bit at the time of the current process. Then, when the bit storing “1” remains in the storage destination check bit, that is, when there is a block to be processed, the main CPU 101 issues a transfer instruction to the current storage destination check bit. It is determined that the target remains.

  In S354, when the main CPU 101 determines that the transfer instruction target remains in the current storage destination check bit (YES in S354), the main CPU 101 returns the processing to the processing in S342, and performs the processing in S342 and thereafter. repeat. On the other hand, in S354, when the main CPU 101 determines that the transfer instruction target does not remain in the current storage destination check bit (NO in S354), the main CPU 101 ends the compressed data storage processing, and ends the processing. For example, the process proceeds to S331 in the symbol determination process (see FIG. 97).

[Second interface board control processing (not specified)]
Next, the second interface board control processing performed in S207 in the main flow (see FIG. 82) will be described with reference to FIG. FIG. 102 is a flowchart illustrating the procedure of the second interface board control process. This processing is performed in a non-defined work area in the main RAM 103 (see FIG. 12C). The program used in the second interface board control process is stored in a non-defined area in the main ROM 102 (see FIG. 12B).

  First, the main CPU 101 saves the address data of the stack area in the main RAM 103 set in the stack pointer (SP) (S361). Next, the main CPU 101 sets the address data of the non-defined stack area in the main RAM 103 to the stack pointer (SP) (S362).

  Next, the main CPU 101 acquires navigation data (S363). Next, the main CPU 101 sets the navigation conversion table in a non-defined work area in the main RAM 103 (S364).

  Next, the main CPU 101 refers to the navigation conversion table to obtain the second interface pressing order number (S365). Next, the main CPU 101 stores the obtained second interface pressing order number in the non-standard pressing order number storage area (not shown) provided in the non-standard working area (S366). Next, the main CPU 101 sets “0” to the value of the pressed position table selection counter provided in the non-defined work area (S367).

  Next, the main CPU 101 determines whether or not the acquired navigation data is a pressing order navigation (navigation data for a pressing order small combination) (S368). In S368, when the main CPU 101 determines that the acquired navigation data is the push order navigation (if S368 is YES), the main CPU 101 performs the process of S372 described later.

  On the other hand, in S368, when the main CPU 101 determines that the acquired navigation data is not the push order navigation (if S368 is NO), the main CPU 101 determines that the acquired navigation data is the navigation data (10) for the BB1 stop operation. Is determined (S369).

  In S369, when the main CPU 101 determines that the acquired navigation data is the navigation data for the BB1 stop operation (if S369 is YES), the main CPU 101 performs the process of S371 described later. On the other hand, in S369, when the main CPU 101 determines that the acquired navigation data is not the navigation data for the BB1 stop operation (NO in S369), the main CPU 101 sets the value of the pressed position table selection counter to “1”. Is added (S370). In S370, the process of adding “1” to the value of the pressed position table selection counter is a process performed to acquire the pressed position of BB2 from the pressed position table (not shown).

  After the processing of S370 or when the determination of S369 is YES, the main CPU 101 adds “1” to the value of the pressed position table selection counter (S371). In S371, the process of adding “1” to the value of the pressed position table selection counter is a process performed to acquire the pressed position of BB1 or BB2 from the pressed position table (not shown).

  After the process of S371 or when the determination of S368 is YES, the main CPU 101 selects a pressed position table (not shown) based on the value of the pressed position table selection counter (S372). Next, the main CPU 101 acquires the pressed position data for three reels (the left reel 3L, the middle reel 3C, and the right reel 3R) with reference to the selected pressed position table (S373). Next, the main CPU 101 stores the acquired pressed position data in an undefined pressing position storage area (not shown) provided in the undefined working area (S374). By the processing of S367 to S371, the value of the pressed position table selection counter becomes “0” if the navigation data is the pressing order navigation, and if the navigation data is the navigation data for the BB1 stop operation, the value of the pressed position table selection counter is changed. The value is “1”, and if the navigation data is the navigation data for the BB2 stop operation, the value of the pressed position table selection counter is “2”. That is, the pressed position data is obtained based on the navigation data.

  Next, the main CPU 101 performs a second interface board output process (S375). The details of the second interface board output process will be described later with reference to FIG.

  Next, the main CPU 101 performs a restoration process for all registers (S376). Next, the main CPU 101 sets the address data of the stack area saved in S361 in the stack pointer (SP) (S377). After the process of S377, the main CPU 101 ends the second interface board control process, and moves the process to S208 of the main flow (see FIG. 82).

[2nd interface board output processing]
Next, the second interface board output processing performed in S375 in the second interface board control processing (see FIG. 102) will be described with reference to FIG. FIG. 103 is a flowchart showing the procedure of the second interface board output process. This second interface board output process is performed in a non-defined work area of the main RAM 103.

  First, the main CPU 101 determines whether or not a transmission operation is being performed via the second interface serial line (second serial communication circuit 115: SCU2) (S381). In S381, when the main CPU 101 determines that the transmission operation is being performed via the second interface serial line (if S381 is YES), the main CPU 101 ends the second interface board output processing, The processing moves to S376 of the second interface board control processing (see FIG. 102).

  On the other hand, in S381, when the main CPU 101 determines that the transmission operation is not performed via the second interface serial line (if S381 is NO), the main CPU 101 is provided in the non-specified work area. The value of the loop counter is set to "3" (the number of reels), and the initial value "1" is set to the serial communication sum value (S382). Next, the main CPU 101 transmits transmission start data via the second interface serial line (second serial communication circuit 115: SCU2) (S383).

  Next, the main CPU 101 refers to the non-defined pressing position storage area of the predetermined reel (turning drum) and acquires the pressing position data of the predetermined reel (S384). Next, the main CPU 101 updates the non-defined pressing position storage area to be referred to to that of the next target reel (turn drum) (S385).

  Next, the main CPU 101 acquires pulse number data corresponding to the pressed position data (symbol position) based on the pulse conversion data (not shown) and the obtained pressed position data (S386). Although details of the correspondence between the pressed position data (symbol position) and the pulse number data are omitted, for example, the acquired pressed position data (symbol position) is "3" (the symbol "white 7" on the left reel 3L). ), “38” is acquired as pulse number data, and if the pressed position data (symbol position) is “10” (symbol “replay” on the left reel 3L), “38” is acquired as pulse number data. 155 "is obtained. Also, for example, when the acquired pressed position data (symbol position) is “12” (symbol “blue 7” on the left reel 3L), “189” is acquired as pulse number data, and the pressed position data (symbol is indicated). When the position is "15" (the symbol "Replay" in the left reel 3L), "239" is acquired as the pulse number data.

  Next, the main CPU 101 transmits the acquired pulse number data via the second interface serial line (second serial communication circuit 115: SCU2) (S387). Next, the main CPU 101 adds the pulse number data to the serial communication sum value (S388). Next, the main CPU 101 subtracts 1 from the value of the loop counter (S389).

  Next, the main CPU 101 determines whether or not the value of the loop counter is “0” (S390). In S390, when the main CPU 101 determines that the value of the loop counter is not “0” (if S390 is NO), the main CPU 101 changes the target reel to the next reel and returns the processing to S384. The processing after S384 is repeated.

  On the other hand, in S390, when the main CPU 101 determines that the value of the loop counter is “0” (if S390 is YES), the main CPU 101 outputs the serial communication sum value to the second interface serial line ( The data is transmitted via the second serial communication circuit 115: SCU2) (S391). Then, after the process of S391, the main CPU 101 ends the second interface board output process, and moves the process to S376 of the second interface board control process (see FIG. 102).

[Control processing by state]
Next, the state-specific control processing performed in S208 in the main flow (see FIG. 82) will be described with reference to FIG. FIG. 104 is a flowchart illustrating the procedure of the state-specific control processing.

  First, the main CPU 101 performs a sub flag conversion process (S401). In this process, the main CPU 101 performs a process of converting an internal winning combination into a sub flag (see FIGS. 36 and 37). The details of the sub flag conversion process will be described later with reference to FIG. 105 described later.

  Next, the main CPU 101 performs a navigation set process (S402). In this process, the main CPU 101 acquires navigation data based on the RT state, the gaming state, and the small winning combination number. The details of the navigation set process will be described later with reference to FIG.

  Next, the main CPU 101 determines whether or not the current RT state is the RT4 state (S403). In S403, when the main CPU 101 determines that the current RT state is not the RT4 state (if S403 is NO), the main CPU 101 performs the processing of S406 described later.

  On the other hand, in S403, when the main CPU 101 determines that the current RT state is the RT4 state (if S403 is YES), the main CPU 101 performs a flag conversion process (S404). In this process, the main CPU 101 performs a flag conversion lottery process (compression process of the sub flag data) for converting the sub flag into the sub flag EX (see FIG. 36). By this flag conversion processing, 19 types (including loss) of sub flags are converted (compressed) into 9 types (including loss) of sub flags EX. The details of the flag conversion process will be described later with reference to FIG.

  Next, the main CPU 101 performs a sub flag compression process (S405). In this process, the main CPU 101 converts the sub-flag EX into the sub-flag D (see FIG. 36), and performs further sub-flag data compression processing. By this sub-flag compression processing, nine types (including loss) of the sub-flag EX are converted (compressed) into seven types (including loss) of the sub-flag D.

  After the processing of S405 or when the determination of S403 is NO, the main CPU 101 determines whether or not the current gaming state is the normal gaming state (S406).

  In S406, when the main CPU 101 determines that the current gaming state is the normal gaming state (if S406 is determined to be YES), the main CPU 101 performs a normal start process (S407). The details of the normal start process will be described later with reference to FIG. Then, after the processing of S407, the main CPU 101 ends the state-specific control processing, and moves the processing to S209 of the main flow (see FIG. 82).

  On the other hand, when the main CPU 101 determines in S406 that the current gaming state is not the normal gaming state (NO in S406), the main CPU 101 determines whether or not the current gaming state is CZ (S406). S408).

  In S408, when the main CPU 101 determines that the current gaming state is CZ (if S408 is YES), the main CPU 101 performs a start-time process during CZ (S409). The details of the start-time processing during CZ will be described later with reference to FIG. 113 described later. Then, after the processing of S409, the main CPU 101 ends the state-specific control processing, and moves the processing to S209 of the main flow (see FIG. 82).

  On the other hand, in S408, when the main CPU 101 determines that the current gaming state is not CZ (if S408 is NO), the main CPU 101 determines whether the current gaming state is normal ART (S410). ).

  In S410, when the main CPU 101 determines that the current gaming state is the normal ART (when the determination in S410 is YES), the main CPU 101 performs the normal ART start time process (S411). The details of the process during the normal ART start will be described later with reference to FIG. 117 described later. Then, after the process of S411, the main CPU 101 ends the state-specific control process, and moves the process to S209 of the main flow (see FIG. 82).

  On the other hand, in S410, when the main CPU 101 determines that the current gaming state is not the normal ART (NO in S410), the main CPU 101 determines whether the current gaming state is CT (S412). ).

  In S412, when the main CPU 101 determines that the current gaming state is CT (if S412 is YES), the main CPU 101 performs a process during start during CT (S413). The details of the processing during the start during CT will be described later with reference to FIG. 118 described later. Then, after the processing of S413, the main CPU 101 ends the state-specific control processing, and moves the processing to S209 of the main flow (see FIG. 82).

  On the other hand, in S412, when the main CPU 101 determines that the current gaming state is not CT (NO in S412), the main CPU 101 determines whether the current gaming state is a bonus state (S414). ).

  In S414, when the main CPU 101 determines that the current gaming state is the bonus state (if S414 is YES), the main CPU 101 performs a process during start during BB (S415). It should be noted that the details of the processing during the start during BB will be described later with reference to FIG. 125 described later. Then, after the processing of S415, the main CPU 101 ends the state-specific control processing, and moves the processing to S209 of the main flow (see FIG. 82).

  On the other hand, in S414, when the main CPU 101 determines that the current gaming state is not the bonus state (if S414 is NO), the main CPU 101 performs other processing (S416). In this process, the main CPU 101 performs a process according to a game state other than the game state targeted in the various determination processes. For example, when the current gaming state is the ART preparation state, processing corresponding to the ART preparation state is performed. Then, after the processing of S416, the main CPU 101 ends the state-specific control processing, and moves the processing to S209 of the main flow (see FIG. 82).

[Sub flag conversion processing]
Next, the sub-flag conversion processing performed in S401 in the state-specific control processing (see FIG. 104) will be described with reference to FIGS. FIG. 105 is a flowchart showing the procedure of the sub-flag changing process. FIG. 106 is a diagram illustrating an example of a source program for executing the sub-flag changing process. FIG. 107 is a diagram illustrating a sub-flag conversion table (conversion table) actually referred to in the source program for the sub-flag converting process. It is a figure showing an example of composition.

  First, the main CPU 101 acquires a small winning combination number (0 to 36) (S421). Next, the main CPU 101 determines whether or not the bonus operation is currently being performed (S422).

  When the main CPU 101 determines in S422 that the bonus operation is currently being performed (YES in S422), the main CPU 101 converts the small winning combination number into a sub flag during the bonus operation and stores it (S423). . The process of converting the small winning combination number into the sub flag during the bonus operation is performed by the main CPU 101 executing the source code “SUB (subtraction command) cNHT_RBST-c7HT1_FLA” in FIG. In the present embodiment, by executing the “SUB” command, the small winning combination number is uniformly converted into the sub-flag “cactus (14)”. After the processing of S423, the main CPU 101 ends the sub-flag conversion processing, and moves the processing to S402 of the state-specific control processing (see FIG. 104).

  On the other hand, in S422, when the main CPU 101 determines that the bonus operation is not currently being performed (NO in S422), the main CPU 101 sets the sub-flag conversion table shown in FIG. 107 (S424). In this process, the initial value of the sub-flag to be determined is set to “losing (00)” and the sub-flag “losing (00)” is set as the initial address of the block in the sub-flag conversion table shown in FIG. Is set ("dSBCVTB + 1") in which is stored.

  Next, the main CPU 101 determines whether the data of the small winning combination number specified in the block in the sub-flag conversion table currently being referred to is the data corresponding to the small winning combination number acquired in the current game. It is determined whether or not it is (S425).

  In S425, the main CPU 101 determines that the data of the small winning combination number specified in the block in the sub-flag conversion table to be referred to is not the data corresponding to the small winning combination number acquired in the current game. At this time (if S425 is NO), the main CPU 101 updates the block in the sub-flag conversion table to be referred to to the block of the next address (S426). Next, the main CPU 101 adds “1” to the value of the sub flag (S427). Then, after the process of S427, the main CPU 101 returns the process to the process of S425, and repeats the processes from S425.

  On the other hand, in S425, the main CPU 101 determines that the data of the small combination winning number specified in the block in the sub-flag conversion table to be referred to is the data corresponding to the small combination winning number acquired in the current game. Is determined (YES in S425), the main CPU 101 refers to the sub-flag conversion table shown in FIG. 107, and refers to the sub-flag conversion control data (address of the address of the The 1-byte data stored at the next address is acquired, and the sub-flag conversion control data is stored in a sub-flag conversion control data storage area (not shown) provided in the main RAM 103 (S428). In this processing, for example, when the small winning combination number acquired in the current game is “03” (internal winning combination “F_3 consecutive lip”), the sub-flag conversion table shown in FIG. The control data “0000011B” is obtained. Then, after the processing of S428, the main CPU 101 ends the sub-flag conversion processing, and moves the processing to S402 of the state-specific control processing (see FIG. 104).

  In the present embodiment, the sub-flag conversion processing is performed as described above. The above-described sub-flag conversion processing is performed by the main CPU 101 sequentially executing each source code defined by the source program in FIG. In the sub-flag conversion table shown in FIG. 107, which is actually referred to on the source program of the sub-flag conversion process, sub-flag conversion control data (control status) is associated with each sub-flag. At this time, the same subflag conversion control data (control status) is associated with the same type of subflag.

  For example, the sub-flag conversion control data (control status) “00000011B” is commonly assigned to the sub-flag “triple chip A” and “triple chip B”. Further, for example, sub-flag conversion control data (control status) “00000001B” is commonly assigned to the sub-flags “reach eye lip 1” to “reach eye lip 4”. In the flag conversion lottery process for converting the internal winning combination (sub flag) into the sub flag EX described above, the lottery is performed based on the sub flag conversion control data (control status) stored in the sub flag conversion control data storage area. .

  By providing common sub-flag conversion control data for the same type of internal winning combination (sub-flag) in a sub-flag conversion table for converting a flag (internal winning combination) managed on the main side into a flag manageable on the sub-side. Therefore, the versatility of the conversion table is improved, and a change in the conversion program accompanying a model change can be dealt with by a small change, so that an increase in development cost can be suppressed.

[Navi set processing]
Next, with reference to FIGS. 108 to 110, the navigation set processing performed in S402 in the state-specific control processing (see FIG. 104) will be described. FIG. 108 is a flowchart showing the procedure of the navigation set process. FIG. 109 is a diagram showing an example of a source program for executing the processing of S434 to S436 described later during the navigation set processing. FIG. 110 is actually referred to in the source program of the navigation set processing. FIG. 3 is a diagram showing an example of a configuration of a navigation data table.

  First, the main CPU 101 determines whether or not a navigation set flag is set in a sub-flag conversion control data storage area (not shown) (S431). Specifically, the main CPU 101 refers to the sub-flag conversion control data storage area, and the set sub-flag conversion control data is data corresponding to the small winning combination numbers (10 to 23) for generating the pressing order navigation. It is determined whether or not. In S431, when the main CPU 101 determines that the navi-set flag is not set in the sub-flag conversion control data storage area (if S431 is NO), the main CPU 101 terminates the navi-set process, and The process moves to S403 of the control process (see FIG. 104).

  On the other hand, in S431, when the main CPU 101 determines that the navigation set flag is set in the sub-flag conversion control data storage area (if S431 is YES), the main CPU 101 is in the RT0 or RT1 RT state. It is determined whether or not this is the case (S432). In S432, when the main CPU 101 determines that the RT state is not the RT0 or RT1 state (if S432 is NO), the main CPU 101 ends the navigation set processing, and executes the state-specific control processing (see FIG. 104). Move to S403.

  On the other hand, in S432, when the main CPU 101 determines that the RT state is the RT0 or RT1 state (if S432 is YES), the main CPU 101 determines whether the gaming state is the general gaming state (S432). S433). In S433, when the main CPU 101 determines that the game state is the general game state (if S433 is YES), the main CPU 101 ends the navigation set processing, and performs the state-specific control processing (see FIG. 104). Move to S403.

  On the other hand, in S433, when the main CPU 101 determines that the gaming state is not the general gaming state (if S433 is NO), the main CPU 101 obtains a small combination winning number (S434). Next, the main CPU 101 refers to the navigation data table shown in FIG. 110, and acquires navigation data (any of 1 to 9) based on the small winning combination number (S435).

  Next, the main CPU 101 stores the acquired navigation data (information on the stop operation of the variable display of the plurality of display columns) in a navigation data storage area (stop operation instruction information storage area) (not shown) in the main RAM 103 (S436). Then, after the processing of S436, the main CPU 101 ends the navigation set processing, and moves the processing to S403 of the state-specific control processing (see FIG. 104).

  In the present embodiment, the navigation set processing is performed as described above. Note that the processing of S434 to S436 during the navigation set processing described above is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 109. In this series of processing, as shown in FIG. 109, an “LDQ” instruction dedicated to the main CPU 101 for specifying an address using a Q register (extension register) is used on a source program.

  For example, when the source code “LDQ A, (k)” is executed on the source program, the data stored in the Q register (upper address value) and the 1-byte integer k (direct value: lower address value) Is loaded into the A register. Therefore, for example, when the source code “LDQ A, (wHITFRT)” in FIG. 109 is executed, the contents of the memory at the address specified by the data stored in the Q register and the integer value “wHITFRT” are stored in the A register. Is loaded.

  Further, for example, when the source code “LDQ (k), A” is executed on the source program, the data stored in the A register is changed to the data stored in the Q register (upper address value) and the 1-byte integer k. (Direct value: lower-order address value). Therefore, for example, by executing the source code “LDQ (wNAVIPTN), A” in FIG. 109, the data (navigation data) stored in the A register becomes one byte of the data stored in the Q register (upper address value). Is stored in the navigation data storage area at the address specified by the integer value “wNAVIPTN” (lower address value).

  As described above, in the present embodiment, in the navigation set processing, the instruction code dedicated to the main CPU 101 using the Q register (extended register) is used, and the main ROM 102, the main RAM 103, and the memory map I / O are accessed by the direct value. can do. In this case, the instruction related to the address setting can be omitted from the source program for the navigation set processing, and the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Flag conversion processing]
Next, the flag conversion process performed in S404 in the state-specific control process (see FIG. 104) will be described with reference to FIG. FIG. 111 is a flowchart illustrating the procedure of the flag conversion process.

  First, the main CPU 101 determines whether or not it is time to start CT (S441).

  In S441, when the main CPU 101 determines that it is not the time to start CT (NO in S441), the main CPU 101 performs the process of S443 described later. On the other hand, in S441, when the main CPU 101 determines that CT is to be started (if S441 is YES), the main CPU 101 determines the table number of the flag conversion random determination table used for the flag conversion random determination during CT by lottery. And set (S442).

  After the process of S442 or when the determination of S441 is NO, the main CPU 101 sets a flag conversion lottery table according to the current state (S443). For example, if the current state is the non-ART RT4 state, the non-ART flag conversion lottery table (see FIG. 62) is set. If the current state is the normal ART RT4 state, The during-ART flag conversion lottery table (see FIGS. 47A and 47B) is set, and if the current state is the RT4 state during CT, the during-CT flag conversion lottery table (see FIG. 54) is set.

  Next, the main CPU 101 refers to the set flag conversion lottery table and performs a flag conversion lottery process based on the internal winning combination (S444). In fact, in this process, the main CPU 101 performs the flag conversion lottery process using the sub-flag conversion control data obtained from the sub-flag conversion table shown in FIG. 107 based on the sub-flag corresponding to the internal winning combination.

  Next, the main CPU 101 determines whether or not the flag conversion lottery in S444 has been won (S445).

  In S445, when the main CPU 101 determines that the flag conversion lottery has been won (YES in S445), the main CPU 101 performs a sub-flag conversion process (S446). In this process, for example, when the internal winning combination is “F_1 probable chip lip”, that is, when the sub flag is “triple chip lip B (03)”, when the flag conversion lottery process is won, the sub flag conversion process of S446 is executed. , The sub-flag “triple lip B (03)” is converted into the sub-flag EX “fixed hand (06)” or the sub-flag EX “triple lip (07)” (see FIG. 36).

  After the process of S446, the main CPU 101 determines whether or not the current gaming state is the non-ART state (S447). In S447, when the main CPU 101 determines that the current gaming state is not the non-ART state (NO in S447), the main CPU 101 ends the flag conversion processing, and executes the state-specific control processing (see FIG. 104). Move to S405).

  On the other hand, in S447, when the main CPU 101 determines that the current gaming state is the non-ART state (YES in S447), the main CPU 101 adds “1” to the ART set number (S448). Next, the main CPU 101 sets the ART preparation state to the game state of the next game (S449). Then, after the processing of S449, the main CPU 101 ends the flag conversion processing, and moves the processing to S405 of the state-specific control processing (see FIG. 104).

  Here, returning to the process of S445 again, when the main CPU 101 determines in S445 that the flag conversion lottery has not been won (NO in S445), the main CPU 101 performs a sub-flag maintaining process (S450). . In this process, for example, when the internal winning combination is “F_1 probable chip lip”, that is, when the sub-flag is “triple chip lip B (03)”, it is determined that the flag conversion lottery is not won, and the sub-flag is maintained in S450. By the processing, the sub-flag “triple chili lip B (03)” is converted (maintained) into the sub-flag EX “replay (01)”. Then, after the processing of S450, the main CPU 101 ends the flag conversion processing, and moves the processing to S405 of the state-specific control processing (see FIG. 104).

[Processing during normal start]
Next, with reference to FIG. 112, the normal start process performed in S407 in the state-specific control process (see FIG. 104) will be described. FIG. 112 is a flowchart showing the procedure of the normal start process.

  First, the main CPU 101 refers to the CZ lottery table (see FIG. 41A) and performs CZ lottery processing based on the current CZ lottery state and the internal winning combination (sub flag) (S461). Next, the main CPU 101 determines whether or not the CZ lottery in S461 has been won (S462).

  In S462, when the main CPU 101 determines that the CZ lottery has not been won (if S462 is NO), the main CPU 101 performs the processing of S465 described later.

  On the other hand, in S462, when the main CPU 101 determines that the CZ lottery has been won (if S462 is YES), the main CPU 101 sets the CZ of the type won in the game state of the next game (S463). Next, the main CPU 101 sets the number of CZ games of the winning type in a CZ game number counter (S464). The CZ game number counter is a counter for counting the duration of CZ, and is provided in the main RAM 103. In the process of S464, for example, when CZ1 has been won, a first predetermined game number (for example, “12”) is set in the CZ game number counter (first half), and when CZ2 has been won. Is set to the second predetermined game number (for example, “15”) in the CZ game number counter (first half), and when CZ3 is won, the fourth predetermined game number is set to the CZ game number counter. (For example, “17”) is set.

  After the processing in S464 or in the case of NO determination in S462, the main CPU 101 refers to the normal medium-high probability lottery table (see FIG. 40A), and performs the CZ lottery state transition lottery based on the internal winning combination (sub flag) (S465). ). Next, the main CPU 101 updates the CZ lottery state based on the result of the shift lottery (S466). After the process of S466, the main CPU 101 ends the normal start process and also ends the state-specific control process (see FIG. 104).

[Start processing during CZ]
Next, with reference to FIG. 113, a description will be given of the start-time processing during CZ performed in S409 in the state-specific control processing (see FIG. 104). FIG. 113 is a flowchart showing the procedure of the processing at the start during CZ.

  First, the main CPU 101 determines whether or not the current gaming state is CZ1 (S471).

  In S471, when the main CPU 101 determines that the current gaming state is CZ1 (if S471 is YES), the main CPU 101 performs processing during CZ1 (CZ2) (S472). The details of the processing during CZ1 (CZ2) will be described later with reference to FIGS. 114 and 115 described later. Then, after the processing of S472, the main CPU 101 ends the processing at the time of starting during CZ, and also ends the state-specific control processing (see FIG. 104).

  On the other hand, in S471, when the main CPU 101 determines that the current gaming state is not CZ1 (if S471 is NO), the main CPU 101 determines whether the current gaming state is CZ2 (S473). .

  In S473, when the main CPU 101 determines that the current gaming state is CZ2 (if S473 is YES), the main CPU 101 performs a process during CZ1 (CZ2) (S474). Details of the processing during CZ1 (CZ2) will be described later with reference to FIGS. 114 and 115 described later. Then, after the process of S474, the main CPU 101 ends the process at the time of start during CZ, and also ends the state-specific control process (see FIG. 104). In the present embodiment, the rank (mode or point) indicating the degree of expectation to win the ART lottery is different between the CZ1 middle processing and the CZ2 middle processing, and the basic processing contents are the same. Therefore, in this embodiment, the processing during CZ1 and the processing during CZ2 will be described as one processing during CZ1 (CZ2).

  On the other hand, in S473, when the main CPU 101 determines that the current gaming state is not CZ2 (if S473 is NO), the main CPU 101 performs CZ3 middle processing (S475). The details of the CZ3 mid-process will be described later with reference to FIG. Then, after the processing of S475, the main CPU 101 ends the processing at the start during CZ, and also ends the state-specific control processing (see FIG. 104).

[CZ1 (CZ2) middle processing]
Next, the processing during CZ1 (CZ2) performed in S472 or S474 during the processing during start during CZ (see FIG. 113) will be described with reference to FIGS. 114 and 115. FIGS. 114 and 115 are flowcharts showing the procedure of the processing during CZ1 (CZ2).

  First, the main CPU 101 determines whether or not the current game is a game in the first half of CZ1 (or CZ2) (S481). In S481, when the main CPU 101 determines that the current game is not the game of the first half of CZ1 (or CZ2) (if S481 is NO), the main CPU 101 performs the process of S490 described later.

  On the other hand, in S481, when the main CPU 101 determines that the current game is a game in the first half of CZ1 (if S481 is YES), the main CPU 101 refers to the CZ1 mode up lottery table (see FIG. 42). Then, a mode up lottery process is performed based on the internal winning combination (sub flag) (S482). Also, in S481, when the main CPU 101 determines that the current game is a game in the first half of CZ2 (if S481 is YES), the main CPU 101 refers to the CZ2 midpoint lottery table (see FIG. 43). Then, a point-up lottery is performed based on the internal winning combination (sub flag) (S482).

  Next, the main CPU 101 updates the rank (mode or point) based on the lottery result of S482 (S483). Next, the main CPU 101 determines whether or not a freeze has been won in the lottery in S482 (S484).

  When the main CPU 101 determines in S484 that the freeze has been won (YES in S484), the main CPU 101 performs a freeze process for temporarily stopping the progress of the game, and sets the number of ART sets and the number of CT sets. Is added to "1" (S485). In this process, the main CPU 101 determines and sets the ART level with reference to the ART level determination table (see FIG. 48A). When a freeze occurs, "ART level 2" is determined as the ART level.

  Next, the main CPU 101 sets the ART preparation state to the game state of the next game (S486). Then, after the processing of S486, the main CPU 101 ends the processing during CZ1 (CZ2), and also ends the processing during start during CZ (see FIG. 113).

  Here, returning to the process of S484 again, when the main CPU 101 determines in S484 that the freeze has not been won (if S484 is NO), the main CPU 101 sets the value of the CZ game number counter (first half). Is subtracted by 1 (S487). Next, the main CPU 101 determines whether or not the value of the CZ game number counter (first half) is “0” (S488).

  In S488, when the main CPU 101 determines that the value of the CZ game number counter (first half) is not “0” (if S488 is NO), the main CPU 101 ends the CZ1 (CZ2) processing, The processing at the time of start during CZ (see FIG. 113) also ends.

  On the other hand, in S488, when the main CPU 101 determines that the value of the CZ game number counter (the first half) is “0” (if S488 is YES), the main CPU 101 sets the CZ1 or the next game state to the next game state. The second half of CZ2 is set (S489). Then, after the process of S489, the main CPU 101 ends the process during CZ1 (CZ2), and also ends the process at the time of start during CZ (see FIG. 113).

  Here, returning to the processing of S481 again, if the determination of S481 is NO, the main CPU 101 determines whether or not the current game is the first game in the latter half of CZ1 or CZ2 (S490). In S490, when the main CPU 101 determines that the current game is not the first game in the latter half of CZ1 or CZ2 (if S490 is NO), the main CPU 101 performs the process of S495 described later.

  On the other hand, in S490, when the main CPU 101 determines that the current game is the first game in the second half of CZ1 or CZ2 (if S490 is YES), the main CPU 101 executes the CZ ART random determination table (FIG. Referring to FIG. 44B), an ART lottery process is performed based on the rank (mode or point) of the first half (S491).

  Next, the main CPU 101 determines whether or not the ART lottery has been won (S492). In S492, when the main CPU 101 determines that the ART lottery has not been won (NO in S492), the main CPU 101 performs the processing of S494 described later.

  On the other hand, in S492, when the main CPU 101 determines that the ART lottery has been won (YES in S492), the main CPU 101 adds “1” to the number of ART sets, and sets an ART level determination table (see FIG. 48A). ), An ART level lottery is performed, and the lottery result is set (S493).

  After the process of S493 or when the determination of S492 is NO, the main CPU 101 sets a predetermined value to a CZ game number counter (second half) (S494). In the process of S494, for example, if the ART lottery has been won, “4” is set in the CZ game number counter (the latter half), and if the ART lottery has not been won, the CZ game number “3” is set in the counter (the latter half).

  After the process of S494 or when the determination of S490 is NO, the main CPU 101 refers to the ART random determination table during CZ (see FIG. 44C) and performs the ART random determination process based on the internal winning combination (sub flag) (S495).

  Next, the main CPU 101 determines whether or not the ART lottery has been won (S496). In S496, when the main CPU 101 determines that the ART lottery has not been won (if S496 is NO), the main CPU 101 performs the processing of S498 described later.

  On the other hand, in S496, when the main CPU 101 determines that the ART lottery has been won (YES in S496), the main CPU 101 adds “1” to the number of ART sets, and sets the ART level determination table (see FIG. 48A). ), The ART level lottery is performed, and the lottery result is set (S497).

  After the process of S497 or when the determination of S496 is NO, the main CPU 101 decrements the value of the CZ game number counter (the latter half) by one (S498). Next, the main CPU 101 determines whether or not the value of the CZ game number counter (second half) is “0” (S499).

  In S499, when the main CPU 101 determines that the value of the CZ game number counter (the latter half) is not “0” (if S499 is NO), the main CPU 101 ends the processing during CZ1 (CZ2), The processing at the time of start during CZ (see FIG. 113) also ends.

  On the other hand, in S499, when the main CPU 101 determines that the value of the CZ game number counter (second half) is “0” (if S499 is YES), the main CPU 101 determines that the number of ART sets is “1” or more. Is determined (S500).

  In S500, when the main CPU 101 determines that the number of ART sets is “1” or more (if S500 is YES), the main CPU 101 sets the ART preparation state to the game state of the next game (S501). Then, after the processing of S501, the main CPU 101 ends the processing during CZ1 (CZ2) and also ends the processing during start in CZ (see FIG. 113).

  On the other hand, in S500, when the main CPU 101 determines that the number of ART sets is not equal to or more than “1” (NO in S500), the main CPU 101 sets the state of the next game to the state at the time of CZ failure (step S500). S502). Then, after the processing of S502, the main CPU 101 ends the processing during CZ1 (CZ2) and also ends the processing during start during CZ (see FIG. 113).

[CZ3 middle processing]
Next, with reference to FIG. 116, the CZ3 middle process performed in S475 during the CZ start process (see FIG. 113) will be described. FIG. 116 is a flowchart showing the procedure of the CZ3 middle processing.

  First, the main CPU 101 refers to the ART random determination table during CZ (see FIG. 45) and performs the ART random determination process based on the internal winning combination (sub flag) (S511).

  Next, the main CPU 101 determines whether or not the ART lottery has been won (S512). In S512, when the main CPU 101 determines that the ART lottery has not been won (if S512 is NO), the main CPU 101 performs the processing of S518 described later.

  On the other hand, in S512, when the main CPU 101 determines that the ART lottery has been won (YES in S512), the main CPU 101 adds “1” to the number of ART sets and sets “1” to the number of CT sets. It is added (S513). Next, the main CPU 101 determines whether or not a freeze has been won in the ART lottery in S512 (S514).

  In S514, when the main CPU 101 determines that the freeze has not been won (NO in S514), the main CPU 101 performs the processing of S516 described later. On the other hand, when the main CPU 101 determines in S514 that the freeze has been won (if S514 is YES), the main CPU 101 performs a freeze process for temporarily stopping the progress of the game (S515).

  After the processing of S515 or when the determination of S514 is NO, the main CPU 101 refers to the ART level determination table (see FIG. 48A), performs the ART level lottery processing, and sets the lottery result (ART level) (S516). . Next, the main CPU 101 sets the ART preparation state to the game state of the next game (S517). Then, after the processing of S517, the main CPU 101 ends the processing during CZ3 and also ends the processing at the time of start during CZ (see FIG. 113).

  Here, returning to the process of S512 again, if the determination of S512 is NO, the main CPU 101 decrements the value of the CZ game number counter by 1 (S518). Next, the main CPU 101 determines whether or not the value of the CZ game number counter is “0” (S519).

  In S519, when the main CPU 101 determines that the value of the CZ game number counter is not “0” (if S519 is NO), the main CPU 101 ends the processing during CZ3 and performs the processing during start during CZ (FIG. 113) also ends.

  On the other hand, in S519, when the main CPU 101 determines that the value of the CZ game number counter is “0” (if S519 is YES), the main CPU 101 adds “1” to the number of ART sets, and ART An ART level lottery is performed with reference to the level determination table (see FIG. 48A), and the lottery result is set (S520). Next, the main CPU 101 sets the ART preparation state to the game state of the next game (S521). Then, after the processing of S521, the main CPU 101 ends the processing during CZ3, and also ends the processing at the time of starting during CZ (see FIG. 113).

[Processing during normal ART start]
Next, with reference to FIG. 117, a description will be given of the normal ART start-time process performed in S411 in the state-specific control process (see FIG. 104). FIG. 117 is a flowchart showing the procedure of the process at the time of the start during the normal ART.

  First, the main CPU 101 adds “1” to the value of the ART continued game counter (S531). The ART continuous game number counter is a counter that counts the number of games (the number of digested games) for which the normal ART has been continued. In this embodiment, in addition to the ART continued game number counter, an ART finished game number counter for counting the number of games for which the normal ART can be continued is also provided. In the pachislo 1 of the present embodiment, the value of the ART continuation game number counter is compared with the value of the ART ending game number counter, and when the value of the ART continuation game number counter reaches the value of the ART ending game number counter, the ART is terminated. The gaming state ends.

  Next, the main CPU 101 performs a CT lottery process based on the current CT lottery state and the internal winning combination (sub-flag) with reference to the ART during lottery table (see FIG. 50) (S532). Next, the main CPU 101 determines whether or not the CT lottery has been won (S533). In S533, when the main CPU 101 determines that the CT lottery has not been won (NO in S533), the main CPU 101 performs the processing of S536 described later.

  On the other hand, in S533, when the main CPU 101 determines that the CT lottery has been won (if S533 is YES), the main CPU 101 adds “1” to the number of CT sets and sets the value of the CT game number counter to “1”. "8" is set (S534). Next, the main CPU 101 sets the CT of the type that has won the game state of the next game (S535).

  After the processing in S535 or in the case of NO in S533, the main CPU 101 refers to the ART level determination table (see FIG. 48B), randomly determines the ART level based on the value of the ART continuous game number counter, and sets the result of the random determination. (S536). Next, the main CPU 101 refers to the normal ART medium-high-probability lottery table (see FIG. 49), lotteries the transition destination CT lottery state based on the current CT lottery state and the internal winning combination (sub-flag), and the lottery result. Is set (S537).

  Next, the main CPU 101 refers to the normal ART additional lottery table (see FIG. 51) and performs an additional lottery process of the ART game number based on the internal winning combination (sub flag) (S538). Next, the main CPU 101 determines whether or not an additional lottery has been won (S539).

  In S539, when the main CPU 101 determines that the additional lottery has not been won (if S539 is NO), the main CPU 101 performs the processing of S541 described later. On the other hand, in S539, when the main CPU 101 determines that the additional lottery has been won (if S539 is YES), the main CPU 101 adds the winning result to the ART end game number counter (S540).

  After the processing of S540 or in the case of NO determination in S539, the main CPU 101 determines whether or not the value of the ART continued game number counter has reached the value of the ART end game number counter (S541). In S541, when the main CPU 101 determines that the value of the ART continuation game number counter has not reached the value of the ART end game number counter (if NO in S541), the main CPU 101 performs the normal ART start processing. Is ended, and the state-specific control processing (see FIG. 104) is also ended.

  On the other hand, in S541, when the main CPU 101 determines that the value of the ART continuation game number counter has reached the value of the ART end game number counter (if S541 is YES), the main CPU 101 sets the ART set number to one. Subtraction is performed (S542). Next, the main CPU 101 sets the state at the time of termination of the ART (S543). Then, after the processing of S543, the main CPU 101 ends the processing during the normal ART start and ends the state-specific control processing (see FIG. 104).

[Start processing during CT]
Next, with reference to FIG. 118, a description will be given of the during-CT start process performed in S413 in the state-specific control process (see FIG. 104). FIG. 118 is a flowchart showing the procedure of the process during start during CT.

  First, the main CPU 101 refers to the CT extra lottery table (see FIG. 55) and performs an extra lottery based on the internal winning combination (sub flag) (S551). Next, the main CPU 101 determines whether or not an additional lottery has been won (S552).

  When the main CPU 101 determines in S552 that the additional lottery has not been won (NO in S552), the main CPU 101 performs the processing of S556 described later. On the other hand, if the main CPU 101 determines in S552 that the additional lottery has been won (if S552 is YES), the main CPU 101 adds the winning result to the ART end game number counter (S553). As described above, in the pachislot 1 of the present embodiment, as the number of wins for the sub-flag “triple lip (triple A or triple lip B)” increases during the same CT, one lottery Increases the amount of addition.

  After the processing in S553, the main CPU 101 determines whether or not the internal winning combination is a combination corresponding to the sub-flag EX “triple lip” (or “fixed combination”), that is, the internal winning combination “F_Sure Chill Lip” or “F_1”. It is determined whether or not the flag is "Surely lip" and the flag conversion lottery process of S444 in FIG. 111 has been won (S554).

  In S554, when the main CPU 101 determines that the internal winning combination is not the combination corresponding to the sub-flag EX “triple lip” (NO in S554), the main CPU 101 ends the CT start process and The state-specific control processing (see FIG. 104) also ends.

  On the other hand, in S554, when the main CPU 101 determines that the internal winning combination is a combination corresponding to the sub-flag EX “Three consecutive chips” (YES in S554), the main CPU 101 sets the value of the CT game number counter to “0”. "1" is added (S555). Then, after the processing of S555, the main CPU 101 ends the processing during the start during CT, and also ends the state-specific control processing (see FIG. 104).

  Here, returning to the process of S552 again, if the determination of S552 is NO, the main CPU 101 performs CT random determination process during CT (S556). In this process, the main CPU 101 mainly performs a lottery with the CT set number added. The details of the CT random determination process during CT will be described later with reference to FIG. 119 described later.

  Next, the main CPU 101 subtracts 1 from the value of the CT game number counter (S557). Next, the main CPU 101 determines whether or not the value of the CT game number counter is “0” (S558).

  In S558, when the main CPU 101 determines that the value of the CT game number counter is not “0” (NO in S558), the main CPU 101 terminates the CT start-time process and performs the state-specific control process ( 104 is also ended. On the other hand, in S558, when the main CPU 101 determines that the value of the CT game number counter is “0” (if S558 is YES), the main CPU 101 determines whether the number of CT sets is “1” or more. Is determined (S559).

  In S559, when the main CPU 101 determines that the number of CT sets is “1” or more (if S559 is YES), the main CPU 101 subtracts one from the number of CT sets (S560). Next, the main CPU 101 sets “8” to the value of the CT game number counter (S561). Then, after the processing of S561, the main CPU 101 ends the processing during the start during CT and also ends the state-specific control processing (see FIG. 104).

  On the other hand, when the main CPU 101 determines in S559 that the number of CT sets is not equal to or more than “1” (NO in S559), the main CPU 101 sets the normal ART to the game state of the next game (S562). Then, after the processing of S562, the main CPU 101 ends the processing during the start during CT, and also ends the state-specific control processing (see FIG. 104).

[CT random determination process during CT]
Next, with reference to FIG. 119, the CT random determination process during CT performed in S556 during the process during start during CT (see FIG. 118) will be described. FIG. 119 is a flowchart showing the procedure of the CT random determination process during CT.

  First, the main CPU 101 sets a CT random determination table during CT (S571). The CT random determination table during CT set here is a lottery table in which the number of sets during CT described above with reference to FIG. 56 is added. The configuration of the number addition lottery table) will be described later with reference to FIG.

  Next, the main CPU 101 performs a table data acquisition process (S572). In this process, the main CPU 101 acquires the address of the lottery table referred to in the CT random determination process during CT. The details of the table data acquisition processing will be described later with reference to FIG.

  Next, the main CPU 101 performs a 1-byte lottery process (S573). In this process, the main CPU 101 performs an additional lottery in the CT set. The details of the one-byte lottery process will be described later with reference to FIG.

  Next, the main CPU 101 determines whether or not the one-byte lottery process has been won (S574). In S574, when the main CPU 101 determines that the one-byte lottery process has not been won (if S574 is NO), the main CPU 101 ends the CT lottery process during CT and starts the process during CT (FIG. The process proceeds to S557 of FIG. 118).

  On the other hand, in S574, when the main CPU 101 determines that the 1-byte lottery process has been won (if S574 is YES), the main CPU 101 adds “1” to the number of CT sets (S575). Then, after the process of S575, the main CPU 101 ends the CT random determination process during CT, and shifts the process to S557 of the start process during CT (see FIG. 118).

[Table data acquisition processing]
Next, the table data acquisition processing performed in S572 during the CT random determination processing during CT (see FIG. 119) will be described with reference to FIGS. FIG. 120 is a flowchart illustrating the procedure of the table data acquisition process. FIG. 121 is a diagram showing an example of a source program for executing the table data acquisition processing. FIG. 122 is actually referred to in the source program for the CT random determination processing during CT and the table data acquisition processing. FIG. 57 is a diagram illustrating an example of a configuration of a CT random determination table during CT (corresponding to the number of sets during CT added in FIG. 56). Specific various lottery values stored in the CT during CT lottery table shown in FIG. 122 are examples.

  In the present embodiment, when acquiring the lottery value to be referred to in the CT random determination process during CT, the lottery value is stored through a two-stage address calculation process (first and second stage table data acquisition processes). Is calculated. First, in the first-stage table data acquisition processing (the processing of S582 and S583 to be described later), the “selection value (1 byte)” associated with the internal winning combination (actually, the sub flag D) is acquired. The selection value is provided for each type of internal winning combination, and it is possible to determine whether or not the internal winning combination is a lottery target, and to designate an arrangement destination of a lottery table associated with the internal winning combination. Values (relative values) are defined. In the present embodiment, a selection value “0” is defined in advance for an internal winning combination (actually, the sub-flag D) in which the lottery result of the CT random determination process during CT is non-winning, and the internal winning combination is set to 1 Treat as "losing" at the time of the table data acquisition processing at the stage. In the second stage of table data acquisition processing (the processing of S585 to S587 to be described later), the address at which the random determination value of the internal winning combination in which the selection value other than “0” is defined is calculated (the random determination table). An address obtained by adding a relative value (selection value) to the reference address (2 bytes) is calculated.)

  First, the main CPU 101 refers to the CT random determination selection table during CT (not shown), and calculates the address of the first- and second-stage addition selection data for calculating the address of the CT random determination table during CT, and the CT. The number of lotteries (two in the present embodiment) is obtained (S581). Next, the main CPU 101 calculates the first-stage selection address by adding the address of the first-stage addition selection data to the address of the CT random determination table during CT (S582).

  Next, the main CPU 101 acquires the selection value stored at the calculated first-stage selection address (S583). Next, the main CPU 101 determines whether or not the selected value is “0” (S584).

  In S584, when the main CPU 101 determines that the selection value is “0” (YES in S584), the main CPU 101 ends the table data acquisition processing, and performs the CT lottery processing during CT (FIG. 119). Move to S573).

  On the other hand, in S584, when the main CPU 101 determines that the selected value is not “0” (NO in S584), the main CPU 101 adds the selected value to the selected address and sets the selected address in the second stage. It is calculated (S585). Next, the main CPU 101 calculates the selected address by adding the address of the second-stage added selection data to the second-stage selected address (S586).

  Next, the main CPU 101 obtains the selection value stored at the selection address calculated in S586, adds the selection value to the selection address, and calculates an address to be referred in the CT random determination table during CT (S587). . Then, after the processing of S587, the main CPU 101 ends the table data acquisition processing, and moves the processing to S573 of the CT during CT lottery processing (see FIG. 119).

  In the present embodiment, the table data acquisition processing is performed as described above. The above-described table data acquisition processing is performed by the main CPU 101 sequentially executing each source code defined by the source program in FIG. 121.

  Among them, in the first stage of the table data acquisition processing (the processing of S581 to S584), the data is stored in the area from the address “dCTCTSTTB” to “dCTCTS_RR-1” in the CT in-CT winning lottery table shown in FIG. A table (a winning combination table selection relative table) is referred to. Further, in the winning combination-specific table selection relative table (lottery table selection table), each combination (sub-flag D “losing”, “cactus”, “weak cherry”, “strong cherry”, “fixing combination”) in which CT winning is lost , "Triple lip", "0" is stored as the selection value (relative value) described above. In the first stage of the table data acquisition process (address calculation process), if the selection value is "0", the lottery result is set to "losing" (see the determination process in S584).

  In the CT random determination lottery table during CT configured as described above, in the winning combination table selection relative table referred to in the first stage table data acquisition process, “losing” can be set only by the type of combination. There is no need to define a lottery value for the "losing" role. Therefore, in the present embodiment, it is not necessary to store the lottery value data (“0”) of “losing” in the CT winning lottery table during CT, and the capacity of the table area of the main ROM 102 can be saved.

  In the process of S587 in the table data acquisition process (the process of S585 to S587) of the second stage (when the sub-flag D “reach eye lip” is acquired), based on the calculated lottery table address, the CT shown in FIG. From the middle CT winning lottery table (corresponding to the CT set number adding lottery table in FIG. 56), a lottery table used at the time of the normal CT state (head address “dNMCTCT_SR”) or a lottery table in the high-probability CT state (head address “dSPCTCTS_RR”) ) Is selected.

  In the lottery table used in the high-probability CT state, as shown in FIG. 122, a “judgment bit” (judgment data) composed of 1-byte data is stored in the address area next to the head address “dSPCTCTS_RER”. The determination bit stores data indicating an address range in which a lottery value to be randomly selected is stored. As in the example shown in FIG. 122, when the lottery value of the lottery target (high-accuracy CT) is stored only in the next address of the storage area of the “determination bit” in the lottery table in the high probability CT state, the determination is made. In the bit storage area, 1-byte data “00000001B” in which “1” is stored only in bit 0 is stored as a determination bit. On the other hand, as in the lottery table used in the normal CT state, when the lottery value of the lottery target (high-accuracy CT and normal CT) is stored at the next address and the next address of the storage area of the determination bit, FIG. As shown in (1), 1-byte data "00000011B" in which "1" is stored only in bits 0 and 1 is stored as a determination bit in the determination bit storage area. When such a determination bit is provided, it becomes unnecessary to store lottery value data that is not a target of lottery in an area of an address where the bit data in the determination bit is “0” in the lottery table.

  Further, in the lottery table used in the high-probability CT state, as shown in FIG. 122, the lottery value of the high-probability CT win is stored in the address “dSPCTCTS_RR + 2” next to the “judgment bit”, and as the lottery value of the high-probability CT win Data specified in the address “cABS_HIT” is stored. In the present embodiment, the data specified at the address “cABS_HIT” is data indicating winning determination (100% winning) (hereinafter, referred to as “determined data”). Further, in the present embodiment, there is no need to provide the lottery value data (“0”) for the loss in the CT winning lottery lottery table during the CT. Therefore, as shown in FIG. Can be defined as "0". That is, in the CT winning lottery table during CT having the above configuration, the lottery value “0” can be used as the determination data.

  As described in the CT set number addition lottery table in FIG. 56, in the present embodiment, the “high probability CT winning” is always determined in the CT set number addition lottery in the high probability CT state. Therefore, in the present embodiment, in the source program, the confirmed data can be stored as the lottery value of the high-probability CT win in the CT win win lottery table shown in FIG.

  Like the lottery table at the second stage (when the sub-flag D “reach-eye lip” is acquired), the lottery target role of CT lottery and the role not subject to the lottery (sub-flag D) ), It is not necessary to store the lottery value data (loss data) of the winning combination that is out of the lottery target in the table. In addition, a lottery value “0” can be used as the determination data in which the winning probability of the lottery target combination is 100%. From these facts, in the present embodiment, it is possible to compress the capacity of the CT winning lottery lottery table during CT (CT number set lottery table) and secure (increase) the free capacity in the main ROM 102. By utilizing the increased free space, it is possible to enhance the gaming ability. Further, in the present embodiment, an example in which this technique is used in the CT winning process during CT has been described. However, the present invention is not limited to this. ART lottery (see FIG. 115), ART game number added lottery (see FIG. 117) ), CT lottery described later (see FIG. 154 described later), and CZ pull-back lottery described later (see FIG. 157 described later).

[1 byte lottery processing]
Next, the 1-byte random determination process performed in S573 during the CT random determination process during CT (see FIG. 119) will be described with reference to FIGS. 123 and 124. FIG. 123 is a flowchart showing the procedure of the 1-byte lottery process. FIG. 124 is a diagram showing an example of a source program for executing the one-byte lottery process.

  First, the main CPU 101 stores the 1-byte random number value for CT lottery during CT (0 to 255: soft latch random number of the random number register 4 of the random number circuit 110) stored in a random number storage area (not shown) in the main RAM 103. It is set (S591). Next, the main CPU 101 converts the lottery determination data (determination bits in the lottery table specified in the second stage in FIG. 122) from the CT random determination table during CT based on the address calculated in S587 during the table data acquisition processing. It is acquired (S592). In this process, the main CPU 101 sets the number of determination bits “8” as an initial value of the number of lotteries.

  Next, the main CPU 101 determines whether or not the lottery determination data is a lottery target (S593). In this determination process, the main CPU 101 refers to the bit data in the determination bits associated with the current number of lotteries, and if the bit data is “1”, determines that the lottery is to be performed. In the present embodiment, bits 0 to 7 in the determination bits are associated with the lottery counts “8” to “1”, respectively.

  In S593, when the main CPU 101 determines that the lottery determination data is not a lottery target (if S593 is NO), the main CPU 101 performs the processing of S599 described later. On the other hand, in S593, when the main CPU 101 determines that the lottery determination data is a lottery target (if S593 is YES), the main CPU 101 acquires a lottery value from the CT during CT lottery table (S594).

  Next, the main CPU 101 determines whether or not the lottery value is “0” (winning confirmation data) (S595).

  In S595, when the main CPU 101 determines that the lottery value is “0” (YES in S595), the main CPU 101 ends the 1-byte lottery process, and executes the CT lottery process during CT (FIG. 119). Move to S574). On the other hand, in S595, when the main CPU 101 determines that the lottery value is not “0” (NO in S595), the main CPU 101 performs CT lottery (additional lottery of the number of CT sets) (S596). Specifically, the main CPU 101 subtracts the lottery value from the random number value (1-byte random number value) and sets the subtraction result as a random number value.

  Next, the main CPU 101 determines whether or not the CT lottery in S596 has been won (S597). In the CT lottery of S596, the main CPU 101 determines that the winning has been achieved when the subtraction result of S596 is equal to or less than “0” (when a so-called “digit” occurs).

  In S597, when the main CPU 101 determines that the CT lottery has been won (S597: YES), the main CPU 101 ends the 1-byte lottery process and proceeds to the CT lottery process during CT (see FIG. 119). Move to S574. On the other hand, in S597, when the main CPU 101 determines that the CT lottery has not been won (NO in S597), the main CPU 101 stores a lottery value storage address (lottery address) referred to in the CT during CT lottery table. Is updated to the next lottery address (S598).

  After the processing of S598 or when the determination of S593 is NO, the main CPU 101 subtracts one from the number of lotteries (S599). Next, the main CPU 101 determines whether or not the number of lotteries is “0” (S600).

  In S600, when the main CPU 101 determines that the number of lotteries is not “0” (NO in S600), the main CPU 101 returns the processing to S593, and repeats the processing from S593. On the other hand, in S600, when the main CPU 101 determines that the number of lotteries is “0” (if S600 is YES), the main CPU 101 ends the 1-byte lottery process and proceeds to the CT lottery process during CT. It moves to S574 of FIG. 119).

  In the present embodiment, the one-byte lottery process is performed as described above. The one-byte lottery process described above is performed by the main CPU 101 sequentially executing each source code defined by the source program in FIG.

  In the random number acquisition process in S591 during the 1-byte lottery process, as shown in FIG. 124, on the source program, an “LDQ” instruction, which is an instruction code dedicated to the main CPU 101 for specifying an address using a Q register (extension register), is issued. Used. Therefore, in the present embodiment, even in the 1-byte lottery process, the main ROM 102, the main RAM 103, and the memory map I / O can be accessed by the direct value by using the instruction code using the Q register (extended register). Therefore, the instruction code related to the address setting can be omitted, and the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Start processing during BB]
Next, with reference to FIG. 125, a description will be given of the BB start-time processing performed in S415 in the state-specific control processing (see FIG. 104). FIG. 125 is a flowchart showing the procedure of the process at the start during BB.

  First, the main CPU 101 performs an additional lottery process for the number of ART games based on the internal winning combination with reference to the additional number of ART games during bonus (see FIG. 59) (S611). Next, the main CPU 101 determines whether or not an additional lottery has been won (S612).

  In S612, when the main CPU 101 determines that the additional lottery has not been won (if S612 is NO), the main CPU 101 ends the BB start-time process and also performs the state-specific control process (see FIG. 104). finish. On the other hand, if the main CPU 101 determines in S612 that the additional lottery has been won (if S612 is YES), the main CPU 101 adds the winning result (the number of additional games) to the ART end game number counter (S613). .

  Next, the main CPU 101 determines whether or not the number of ART sets is “0” (S614). In S614, when the main CPU 101 determines that the number of ART sets is not “0” (NO in S614), the main CPU 101 ends the BB start-time process and performs the state-specific control process (see FIG. 104). ) Also ends.

  On the other hand, in S614, when the main CPU 101 determines that the number of ART sets is “0” (if S614 is YES), the main CPU 101 adds “1” to the number of ART sets (S615). Then, after the process of S615, the main CPU 101 ends the BB start process and the state-specific control process (see FIG. 104).

[Purchase priority storage processing]
Next, with reference to FIGS. 126 and 127, a description will be given of the pull-in priority storage processing performed in S212 in the main flow (see FIG. 82). FIG. 126 is a flowchart showing the procedure of the pull-in priority storing process. FIG. 127 is a diagram illustrating an example of a source program for executing processes of S625 and S626 described later during the attraction priority order storage process.

  First, the main CPU 101 sets “3” as the number of search reels (S621). Next, the main CPU 101 performs a pull-in priority table selection process (S622). In this process, the pull-in priority table (see FIG. 27) is selected based on the internal winning combination and the operation stop button.

  Next, the main CPU 101 performs a pull-in priority order storage area selection process (S623). In this process, the pull-in priority data storage area of the reel to be searched is selected. Next, the main CPU 101 sets “20” as the number of symbol checks (number of times) (S624).

  Next, the main CPU 101 performs a symbol code acquisition process (S625). In this process, a symbol code is acquired with reference to a winning operation flag storage area and a symbol code storage area corresponding to the number of symbol checks. The details of the symbol code acquisition process will be described later with reference to FIG. 128 described later.

  Next, the main CPU 101 performs a logical product operation process (S626). In this process, the main CPU 101 performs a process of generating winning operation flag data. Details of the logical product operation processing will be described later with reference to FIG. 133 described later.

  Next, the main CPU 101 performs a pull-in priority acquisition process (S627). In this process, the main CPU 101 sets the bit to “1” in the winning operation flag (winning combination) storage area (see FIGS. 28 to 30) and sets the bit to “1” in the hit request flag storage area. With reference to the pull-in priority order table (see FIG. 27), the draw-in priority data is acquired for the combination indicated as "". Details of the pull-in priority acquisition processing will be described later with reference to FIGS. 134 and 135 described later.

  Next, the main CPU 101 stores the acquired pull-in priority data in a pull-in priority data storage area (not shown) in the main RAM 103 (S628). At this time, the attraction priority data is stored in the attraction priority data storage area such that the value of each priority corresponds to the bit of the storage area.

  It should be noted that the pull-in priority data storage area is provided with a priority data storage area for each type of main reel. In each pull-in priority data storage area, pull-in priority data determined according to each symbol position “0” to “19” of the corresponding main reel is stored. In the present embodiment, by referring to the pull-in priority data storage area, a search is made as to whether or not there is a more appropriate number of sliding pieces in addition to the number of sliding pieces determined based on the stop table.

  The contents of priority attraction data stored in the attraction priority data storage area differ depending on the type of attraction priority table number in the attraction priority table referred to when determining the attraction priority data. The attraction priority data indicates that the higher the value, the higher the priority. By referring to the pull-in priority data, it is possible to relatively evaluate the priority among the symbols arranged on the peripheral surface of the main reel. That is, the symbol for which the largest value is determined as the pull-in priority data is the symbol with the highest priority. Therefore, it can be said that the pull-in priority data indicates the order between the symbols arranged on the peripheral surface of the main reel. When there are a plurality of symbols having the same value of the pull-in priority data, one symbol is determined according to the priority order defined by the priority order table.

  Next, the main CPU 101 performs an update process of the attraction priority storage area (S629). In this process, the main CPU 101 sets the drawing priority data storage area of the next check symbol. Next, the main CPU 101 subtracts one from the symbol check number (S630). Next, the main CPU 101 determines whether or not the number of symbol checks is “0” (S631).

  In S631, when the main CPU 101 determines that the number of symbol checks is not “0” (if S631 is NO), the main CPU 101 returns the processing to S625, and repeats the processing from S625. On the other hand, in S631, when the main CPU 101 determines that the number of symbol checks is “0” (if S631 is YES), the main CPU 101 performs a search target reel changing process (S632).

  Next, the main CPU 101 subtracts 1 from the number of search reels (S633). Next, the main CPU 101 determines whether or not the number of searched reels is “0”, that is, whether or not the above-described series of processing has been performed on all the main reels (S634).

  In S634, when the main CPU 101 determines that the number of searched reels is not “0” (if S634 is NO), the main CPU 101 returns the processing to the processing of S622, and repeats the processing from S622. On the other hand, in S634, when the main CPU 101 determines that the number of searched reels is “0” (YES in S634), the main CPU 101 terminates the pull-in priority order storage process and proceeds to the main flow (FIG. 82)).

  In the present embodiment, the attraction priority storage processing is performed as described above. The processing of S625 and S626 during the above-described pull-in priority storage processing is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 127.

  Among them, the logical product operation processing in S626 is performed by the main CPU 101 executing the source code “CALLF SB_DAND_00” in FIG. 127. The “CALLF” instruction is a 2-byte instruction code dedicated to the main CPU 101 as described above. When the source code “CALLF SB_DAND_00” in FIG. 127 is executed, the process is executed at the address specified by “SB_DAND_00”. Jump is performed, and the logical product operation process is started.

[Symbol code acquisition processing]
Next, with reference to FIGS. 128 to 132, a description will be given of the symbol code acquisition process performed in S625 during the attraction priority order storage process (see FIG. 126). FIG. 128 is a flowchart showing the procedure of the symbol code acquisition process. FIG. 129 is a diagram showing an example of a source program for executing the symbol code acquisition process. FIG. 130A is a diagram showing an example of the configuration of a first reel (left reel) symbol arrangement table actually referred to on the source program of the symbol code acquisition process, and FIG. 130B is a first reel symbol arrangement table set. It is a figure showing an example of the composition of the symbol corresponding winning operation table which is sometimes referred to. FIG. 131A is a diagram showing an example of the configuration of a second reel (middle reel) symbol arrangement table actually referred to on the source program of the symbol code acquisition process, and FIG. 131B is a second reel symbol arrangement table set. It is a figure showing an example of the composition of the symbol corresponding winning operation table which is sometimes referred to. FIG. 132A is a diagram showing an example of the configuration of a third reel (right reel) symbol arrangement table actually referred to on the source program of the symbol code acquisition process, and FIG. 132B is a diagram showing the third reel symbol arrangement. It is a figure showing an example of composition of a symbol corresponding winning operation table referred at the time of table setting.

  First, the main CPU 101 performs a process of clearing the winning operation flag storage area (S641). In this process, the main CPU 101 sets “0” to all storage areas in the winning operation flag storage area (see FIGS. 28 to 30). Next, the main CPU 101 sets a first reel symbol arrangement table (see FIG. 130A) (S642).

  Next, the main CPU 101 determines whether or not the first reel (the left reel 3L) is stopped (S643).

  In S643, when the main CPU 101 determines that the first reel (the left reel 3L) is stopped (if S643 is YES), the main CPU 101 performs the process of S647 described later. On the other hand, in S643, when the main CPU 101 determines that the first reel (the left reel 3L) is not stopped (NO in S643), the main CPU 101 reads the second reel symbol arrangement table (see FIG. 131A). It is set (S644). In this process, the first reel symbol arrangement table set in the process of S642 is overwritten with the second reel symbol arrangement table.

  Next, the main CPU 101 determines whether or not the second reel (the middle reel 3C) is stopped (S645).

  In S645, when the main CPU 101 determines that the second reel (the middle reel 3C) is stopped (if S645 is YES), the main CPU 101 performs the process of S647 described later. On the other hand, in S645, when the main CPU 101 determines that the second reel (the middle reel 3C) is not stopped (NO in S645), the main CPU 101 reads the third reel symbol arrangement table (see FIG. 132A). It is set (S646). In this process, the second reel symbol arrangement table set in the process of S644 is overwritten with the third reel symbol arrangement table.

  After the processing of S646, or when the determination of S643 or S645 is YES, the main CPU 101 performs a symbol check process at the time of executing the stop operation on the reel to be stopped and controls the symbol corresponding to the symbol acquired by the symbol check process. A winning operation table is acquired (S647). For example, when the first reel (the left reel 3L) is stopped and the symbol located on the activated line at the time of the stop operation is “white 7”, the main CPU 101 proceeds from the address “dR1_SVN1” to the address “dR1_SVN2” in FIG. The start address of the symbol corresponding winning operation table defined for the block in the range of "-1" is acquired.

  Next, the main CPU 101 sets a winning operation flag storage area (S648). Next, the main CPU 101 performs the compressed data storage process described with reference to FIG. 101 (S649). In this process, the main CPU 101 mainly performs a process of transferring (developing) winning winning operation flag data stored in the symbol corresponding winning operation table to a corresponding storage area in the winning operation flag storage area.

  For example, when the first reel (the left reel 3L) is stopped, and the symbol located on the activated line at the time of the stop operation is “white 7”, the winning symbol combinations (combinations) are shown in FIGS. As shown in FIG. 30, combination names “C_2nd_A_01”, “C_2nd_A_01” and “C_SP1_01” defined in the second storage area, combination names “C_9 sheets C_01” to “C_9 sheets C_03” defined in the third storage area, “C_9 sheets C_07” to “C_9 sheets C_09” and “C_9 sheets E_01”, combination names “C_RB combination A_01”, “C_RB combination A_02”, “C_RB combination B_01” to “C_RB combination B_04” defined in the fourth storage area "," C_RB role C_01 "and" C_RB role C_02 ", and are specified in the sixth storage area. Combination names “C_reach-eye lip C_01” to “C_reach-eye lip C_03”, “C_reach-eye lip D_01”, “C_reach-eye lip D_02”, and “C_reach-eye lip E_01”, and the tenth storage area Is a combination name “C_BB1” defined in the above.

  In this case, the storage destination of the first block (the 0th to seventh storage areas) of the winning operation flag data that can be won stored in the symbol corresponding winning operation table is stored at the address “dR1_SVN1 + 1” in the table shown in FIG. 130B. This is designated by the specified 1-byte designated data “01011100B” (see the column “comment area +2, +3, +4, +6” in FIG. 130B). The storage destination of the second block (the eighth to eleventh storage areas) of the winning operation flag data that can be won stored in the symbol corresponding winning operation table is stored at the address “dR1_SVN1 + 6” in the table shown in FIG. 130B. (Refer to the comment “storage area + 10” in FIG. 130B).

  In the present embodiment, bits 0 to 7 of the designated data of the first block are bits that designate the 0th to seventh storage areas of the first block as storage destinations, respectively, and the designated data of the second block are Bits 0 to 3 are bits for specifying the eighth to eleventh storage areas of the second block as storage destinations, respectively. In the 1-byte designated data of each block, “1” is stored in a bit corresponding to a storage area in the winning operation flag storage area where the winning operation flag data is stored.

  Therefore, for example, when the first reel (the left reel 3L) is stopped and the symbol located on the activated line at the time of the stop operation is “white 7”, the address in the table shown in FIG. The winning operation flag data “00010000B” or “0000100100B” stored in “dR1_SVN1 + 2” is transferred from the symbol corresponding winning operation table to the second storage area in the winning operation flag storage area, and stored in the address “dR1_SVN1 + 3”. The winning operation flag data “00100000B” or “00000100B” is transferred from the symbol corresponding winning operation table to the third storage area in the winning operation flag storage area. In this case, in the process of S649, the winning operation flag data “10000000B”, “01000000B” or “00100000B” stored at the address “dR1_SVN1 + 4” in the table shown in FIG. 130B is obtained from the symbol corresponding winning operation table. The winning operation flag data “00100000B”, “00010000B” or “00001000B” transferred to the fourth storage area in the operation flag storing area and stored at the address “dR1_SVN1 + 5” is stored from the symbol corresponding winning operation table. The data is transferred to the sixth storage area in the area. Further, in this case, in the processing of S649, the winning operation flag data “10000000B” stored at the address “dR1_SVN1 + 8” in the table shown in FIG. Transferred to storage area.

  After the processing of S649, the main CPU 101 sets the winning operation flag storage area updated by the compressed data storage processing, sets the symbol code storage area, and sets the data length of the winning operation flag storage area (12 bytes in the present embodiment). Is set (S650). Then, after the processing of S650, the main CPU 101 ends the symbol code acquisition processing, and moves the processing to S626 of the attraction priority storage processing (see FIG. 126).

  In the present embodiment, the symbol code acquisition process is performed as described above. The above-described symbol code acquisition process is performed by the main CPU 101 sequentially executing each source code defined by the source program in FIG. Among them, the compressed data storage processing of S649 is performed by the main CPU 101 executing the source code “CALLF SB_BTEP_00” in FIG.

  The “CALLF” instruction is a two-byte instruction code dedicated to the main CPU 101 as described above. When the source code “CALLF SB_BTEP_00” in FIG. 129 is executed, the process is executed at the address specified by “SB_BTEP_00”. A jump is made to start the compressed data storage processing. In the compressed data storing process, as described above, the winning operation flag data (compressed data) stored in the symbol corresponding winning operation flag table of each reel is developed (copied) in the winning operation flag storage area.

  In the present embodiment, the compression / decompression processing of the winning data is performed in the processing procedure described in S647 to S649 during the above-described symbol code acquisition processing. By using, the compression and decompression processing of the data relating to the winning can be made more efficient, and the limited capacity of the main RAM 103 can be effectively used.

  In the present embodiment, in the compressed data storage processing in S649 during the symbol code acquisition processing, the jump destination address “SB_BTEP_00” specified by the “CALLF” instruction is used in the compression in S330 in the symbol setting processing described with reference to FIG. In the data storage processing, this is the same as the jump destination address specified by the “CALLF” instruction. That is, in the present embodiment, the source program for executing the compressed data storage process performed in the symbol code acquisition process is the same as the source program for executing the compressed data storage process performed in the symbol setting process. In both processes, the source program of the compressed data storage process is shared (moduleed). In this case, since it is not necessary to separately provide a source program for the compressed data storage process in both the processes of S649 and S330, the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[AND operation]
Next, with reference to FIG. 133, for example, the logical product operation process performed in S626 in the attraction priority order storage process (see FIG. 126) will be described. FIG. 133 is a flowchart illustrating the procedure of the logical product operation process. The logical product calculation processing shown in FIG. 133 is performed not only in S626 in the pull-in priority storage processing (see FIG. 126) but also in S687 in the pull-in priority acquisition processing (see FIGS. 134 and 135 described later). Is also executed.

  In the AND operation process executed in S626 during the pull-in priority order storage process (see FIG. 126), the two data to be ANDed are stored in the winning operation flag set in S650 during the above-described symbol code acquisition process. The area data and the symbol code storage area data. The former data corresponds to “logical product data” described later, and the latter data corresponds to “logical product data” described later. In this case, the number of bytes “12” of the data length (12 bytes) set in S650 during the above-described symbol code acquisition processing corresponds to the “number of logical products” described later.

  On the other hand, in the logical product operation process executed in S687 in the pull-in priority acquisition process described later (see FIGS. 134 and 135 described later), the two data to be logical-and-operated are a hit (pull-in) request flag storage area. And the data of the winning operation flag storage area. The former data corresponds to “logical product data” described later, and the latter data corresponds to “logical product data” described later. In this case, the number of bytes “1” of the data length (1 byte) of the RT operation combination display flag described in FIG. 136B described later corresponds to the “number of logical products” described later.

  First, the main CPU 101 acquires logical product source data (for example, data of a symbol code storage area) (S661). Next, the main CPU 101 performs a logical product operation of the logical product source data and the logical product destination data (for example, the data in the winning operation flag storage area), and stores the calculation result as logical product data (S662).

  Next, the main CPU 101 adds 1 to the address of the logical product source data to be obtained (S663). Next, the main CPU 101 adds 1 to the address of the logical product data to be referred to (S664).

  Next, the main CPU 101 subtracts 1 from the number of logical products (S665). Next, the main CPU 101 determines whether or not the logical product number is “0” (S666).

  In S666, when the main CPU 101 determines that the logical product number is not “0” (NO in S666), the main CPU 101 returns the processing to S661, and repeats the processing from S661. On the other hand, in S666, when the main CPU 101 determines that the number of logical products is “0” (if S666 is YES), the main CPU 101 ends the logical product calculation process, and executes the process, for example, by storing the priority order of attraction. The process moves to S627 of the process (see FIG. 126).

[Purchase priority acquisition processing]
Next, with reference to FIGS. 134 to 137, a description will be given of the pull-in priority acquisition processing performed in S627 during the pull-in priority storage processing (see FIG. 126). FIG. 134 and FIG. 135 are flowcharts showing the procedure of the pull-in priority acquisition process. FIG. 136A is a diagram illustrating an example of a source program for executing processes of S680 to S683 described later during the attraction priority acquisition process, and FIG. 136B illustrates a process of S686 described later during the attraction priority acquisition process. FIG. 136C is a diagram illustrating an example of a source program for executing a process of S687 described later during the pull-in priority acquisition process. FIG. 137 is a diagram illustrating an example of the configuration of a pull-in priority table that is actually referred to on the source program of the pull-in priority acquisition process.

  First, the main CPU 101 determines whether or not the right reel 3R (specific display column) is being checked (S671).

  In S671, when the main CPU 101 determines that the right reel 3R has not been checked (NO in S671), the main CPU 101 performs the process of S674 described later. On the other hand, in S671, when the main CPU 101 determines that the right reel 3R is to be checked (if S671 is YES), the main CPU 101 sets the symbol combination (winning combination) relating to the internal winning combination to “ANY combination”. It is determined whether or not (a predetermined combination of symbols) is included (S672). Note that the “ANY combination” here means a combination in which a winning is determined irrespective of at least the stopped symbol of the right reel 3R (at least a winning symbol in which the stopped symbol of the right reel 3R is an arbitrary symbol).

  In S672, when the main CPU 101 determines that the symbol combination relating to the internal winning combination does not include the “ANY combination” (in the case of NO determination in S672), the main CPU 101 performs the process of S674 described later. On the other hand, in S672, when the main CPU 101 determines that the symbol combination relating to the internal winning combination includes the “ANY combination” (in the case of YES determination in S672), the main CPU 101 sets “ANY” in the winning operation flag storage area. The storage area corresponding to the role is masked (S673). Specifically, the main CPU 101 sets “1” to the bit corresponding to “ANY combination” in the winning operation flag storage area.

  After the process of S673, or when S671 or S672 is NO, the main CPU 101 sets “1” as the address of the winning operation flag storage area (see FIGS. 28 to 30) as the address of the last storage area. The added address is set, stop prohibition data is set, and the winning operation flag data length (the data length of the winning operation flag storage area: 12 bytes in the present embodiment) is set (S674). Next, the main CPU 101 acquires the value of the stock button operation counter and the stop button operation state (S675). The stop button operation counter is a counter for managing the number of stop buttons for which a stop operation has been detected. The stop button operation state is acquired by referring to the operation stop button storage area (see FIG. 33).

  Next, the main CPU 101 decrements the address of the set winning operation flag storage area by 1 (-1 update) (S676). Next, the main CPU 101 generates hit request flag data from the set winning operation flag storage area and the corresponding hit request flag storage area (see FIGS. 28 to 30), and generates the generated hit request flag data. A prohibited prize operation position is generated based on (S677).

  Next, the main CPU 101 determines whether or not the stop operation position is the prohibited winning operation position (S678).

  In S678, when the main CPU 101 determines that the stop operation position is not the prohibited winning operation position (if S678 is NO), the main CPU 101 performs the processing of S684 described later. On the other hand, in S678, when the main CPU 101 determines that the stop operation position is the prohibited winning operation position (if S678 is YES), the main CPU 101 determines that the value of the stop button operation counter is the third stop value. It is determined whether or not it is (S679).

  In S679, when the main CPU 101 determines that the value of the stop button operation counter is the third stop value (if S679 is YES), the main CPU 101 performs the processing of S705 described later. On the other hand, in S679, when the main CPU 101 determines that the value of the stop button operation counter is not the third stop value (if S679 is NO), the main CPU 101 determines that the value of the stop button operation counter is the second stop value. It is determined whether the value is a value (S680).

  In S680, when the main CPU 101 determines that the value of the stop button operation counter is not the value of the second stop (when S680 is NO), the main CPU 101 performs the processing of S684 described later. On the other hand, in S680, when the main CPU 101 determines that the value of the stop button operation counter is the value of the second stop (if S680 is YES), the main CPU 101 determines whether or not the right reel 3R has been stopped. Is determined (S681).

  In S681, when the main CPU 101 determines that the right reel 3R has been stopped (if S681 is YES), the main CPU 101 performs the processing of S684 described later. On the other hand, in S681, when the main CPU 101 determines that the right reel 3R is not stopped (if the determination in S681 is NO), the main CPU 101 sets a flag indicating that the hit request flag may be subject to interference of “ANY role”. (S682) is determined whether the symbol combination (winning combination) related to the internal winning combination does not include “ANY combination”.

  In S682, when the main CPU 101 determines that the hit request flag is not a flag that may cause interference of “ANY role” (if S682 is YES), the main CPU 101 performs the process of S684 described later. On the other hand, in S682, when the main CPU 101 determines that the hit request flag is a flag that may cause interference of “ANY combination” (in the case of NO determination in S682), the main CPU 101 determines that the current check is “ANY”. It is determined whether or not it is time to check the hit request flag including "role" (S683).

  In S683, when the main CPU 101 determines that the current check is the check of the hit request flag including “ANY role” (if S683 is YES), the main CPU 101 performs the processing of S705 described later.

  On the other hand, in S683, when the main CPU 101 determines that the current check is not the check of the hit request flag including “ANY role” (if S683 is NO), if S678 or S680 is NO, or S681. Alternatively, if the determination in S682 is YES, the main CPU 101 subtracts one from the winning operation flag data length (S684). Next, the main CPU 101 determines whether or not the winning operation flag data length is “0” (S685).

  In S685, when the main CPU 101 determines that the winning operation flag data length is not “0” (if S685 is NO), the main CPU 101 returns the process to S676, and repeats the processes from S676.

  On the other hand, in S685, when the main CPU 101 determines that the winning operation flag data length is “0” (if S685 is YES), the main CPU 101 performs a stop control pull-in request flag setting process (S686). . This process is performed by the main CPU 101 sequentially executing each process defined in the source program of FIG. 136B. Therefore, during this processing, the logical product operation processing described with reference to FIG. 133 is performed. In the logical product operation process executed in the process of S686, as described above, the data of the hit (pull-in) request flag storage area is set to “logical product data”, and the data of the winning operation flag storage area is set. In the “logical product source data”, the number of logical products is set to the number of bytes “1” of the data length (1 byte) of the RT operation combination display flag. The RT operation combination display flag is a storage area in which a symbol combination relating to the RT transition is defined in the winning operation flag storage area. In the present embodiment, only the storage area 11 is provided as shown in FIGS. Become.

  Next, the main CPU 101 refers to the pull-in priority table address storage area and acquires a pull-in priority table (S687). This process is performed by the main CPU 101 sequentially executing each process defined in the source program of FIG. 136C. Therefore, in this processing, the initial value “1 (001H)” of the pull-in priority data is set to the currently set address, and the start address is “dPLVLTB00” to “dPLVLTB05” shown in FIG. A pull-in priority table stored in one of the blocks is acquired. The attraction priority tables stored in the blocks whose head addresses are “dPLVLTB00” to “dPLVLTB05” shown in FIG. 137 have the attraction priority table numbers “00” to “05” shown in FIG. 27, respectively. Corresponds to the pull-in priority table.

  Next, the main CPU 101 determines whether or not the data of the pull-in priority table stored at the currently set address is an end code (000H) (S688).

  In S688, when the main CPU 101 determines that the data of the pull-in priority table stored at the currently set address is an end code (if S688 is YES), the main CPU 101 proceeds to S705 described later. Is performed. On the other hand, in S688, when the main CPU 101 determines that the data of the pull-in priority table stored at the currently set address is not the end code (if S688 is NO), the main CPU 101 performs the winning operation. The flag storage area is set (S689).

  Next, the main CPU 101 acquires the attraction priority data from the attraction priority table based on the currently set address (S690). Next, the main CPU 101 sets a block counter of the pull-in priority order table (S691). In the present embodiment, in this processing, the main CPU 101 sets “2” to the value of the block counter of the pull-in priority table.

  Next, the main CPU 101 sets the number of checks in the pull-in priority table, and adds 1 (+1 updates) to the address of the pull-in priority table to be referred to (S692). In the present embodiment, in this process, the main CPU 101 sets “8” (the number of bits of the check data specified in the pull-in priority table shown in FIG. 137) as the number of checks in the pull-in priority table.

  Next, the main CPU 101 acquires check data (see FIG. 137) based on the updated address of the pull-in priority table, and extracts check bits from the check data (S693). In this embodiment, the check bits extracted here correspond to bit 0 of the check data. For example, in the process of S690, if the withdrawal priority data “03EH” is acquired from the withdrawal priority table specified for the block whose head address is “dPLVLTB00”, “10001000B” is set as the check data in the process of S693. Then, “0” is extracted as the value of the check bit.

  Next, the main CPU 101 determines whether or not the value of the extracted check bit is “1” (S694).

  In S694, when the main CPU 101 determines that the value of the extracted check bit is not “1” (if S694 is NO), the main CPU 101 performs the processing of S699 described below. On the other hand, in S694, when the main CPU 101 determines that the value of the extracted check bit is “1” (YES in S694), the main CPU 101 adds 1 to the address of the drawing priority order table to be referred to. (+1 update), and based on the updated address, obtain determination data (“flag determination data” in FIG. 137) from the pull-in priority table (S695).

  Next, the main CPU 101 determines whether or not the currently acquired winning operation flag data is a determination target based on the determination data acquired in S695 (S696). In this process, the main CPU 101 compares the currently acquired winning operation flag data with the determination data, determines whether or not the former corresponds to the latter, and the former corresponds to the latter. In this case, it is determined that the currently obtained winning operation flag data is a determination target.

  In S696, when the main CPU 101 determines that the winning operation flag data is not a determination target (when S696 is NO), the main CPU 101 performs a process of S699 described later. On the other hand, in S696, when the main CPU 101 determines that the winning operation flag data is the determination target (if S696 is YES), the main CPU 101 performs a process of updating the pull-in priority data (S697). In this process, the main CPU 101 updates (overwrites) the currently set pull-in priority data with the pull-in priority data associated with the determination data acquired in S697.

  Next, the main CPU 101 performs a check data update process (S698). In this process, the main CPU 101 shifts the check data one bit to the right (the direction from bit 7 to bit 0). In this process, "0" is set to bit 7 of the shifted check data.

  After the processing of S698, or when S694 or S696 is NO, the main CPU 101 determines whether or not the check data includes a bit to be checked (a bit in which “1” is set) (S699).

  In S699, when the main CPU 101 determines that there is no bit to be checked in the check data (if S699 is NO), the main CPU 101 performs the process of S702 described later. On the other hand, in S699, when the main CPU 101 determines that there is a bit to be checked in the check data (if S699 is YES), the main CPU 101 adds 1 to the address of the winning operation flag storage area to be checked (+1 update). ), And subtract 1 from the number of checks (S700).

  Next, the main CPU 101 determines whether or not the number of checks is “0” (S701). In S701, when the main CPU 101 determines that the number of checks is not “0” (NO in S701), the main CPU 101 returns the processing to S698, and repeats the processing from S698.

  On the other hand, in S701, when the main CPU 101 determines that the number of checks is “0” (if S701 is YES), the main CPU 101 stores the number of checks in the address of the winning operation flag storage area currently being referred to. The address of the winning operation flag storage area is updated by adding the initial value “8”, and the value of the block counter is decremented by 1 (S702). Next, the main CPU 101 determines whether or not the value of the block counter is “0” (S703).

  In S703, when the main CPU 101 determines that the value of the block counter is not “0” (NO in S703), the main CPU 101 returns the processing to S692 and repeats the processing from S692.

  On the other hand, in S703, when the main CPU 101 determines that the value of the block counter is “0” (if S703 is YES), the main CPU 101 adds 1 to the address of the reference priority table to be referred to (+1 update). ) (S704). For example, if the currently referred pull-in priority table is a pull-in priority table defined for a block whose head address is “dPLVLTB00”, the pull-in priority table to be referred to by this processing is changed to “dPLVLTB00”. dPLVLTB01 "is changed to the pull-in priority table defined for the block. Then, after the processing of S704, the main CPU 101 returns the processing to the processing of S688, and repeats the processing of S688 and thereafter.

  Here, returning to the processing of S679, S683, or S688 again, if the determination of S679, S683, or S688 is YES, the main CPU 101 sets the attraction ranking data set at this time as the final attraction priority data. It is set (S705). If the determination in S679 or S683 is YES, the main CPU 101 sets “0 (00H)” as the final pull-in priority data. In this case, since the end code is assigned to the pull-in priority data “0 (00H)”, no pull-in data (stop prohibition) is set. Then, after the processing of S705, the main CPU 101 ends the attraction priority acquisition processing, and moves the processing to S628 of the attraction priority storage processing (see FIG. 126).

  In the present embodiment, the pull-in priority order acquisition processing is performed as described above. Note that the above-described pull-in priority handling process of “ANY role” in S680 to S683 in the pull-in priority acquisition process is performed by the main CPU 101 sequentially executing each source code defined in the source program of FIG. 136A. Will be Among them, for example, the determination processing of S683 is executed by a “JCP” instruction (a predetermined determination instruction) on the source program. The “JCP” instruction is an instruction for executing an operation equivalent to a comparison instruction, and is an instruction code dedicated to the main CPU 101.

  For example, when the source code “JCP cc, A, n, e” is executed on the source program, the content (stored data) of the A register is compared with the integer n, and the comparison result is determined by the condition of cc. Then, the process jumps to the address specified by e. As the "cc condition" of the "JCP" instruction, one of the state of the carry flag and the state of the zero flag in the flag register F is specified (see FIG. 11). For example, if “C” is specified for cc, the condition of cc means that the carry flag is “1” (on state), and if “NC” is specified for cc, the condition of cc is Means that the carry flag is "0" (off state). For example, if “Z” is specified for cc, the condition of cc means that the zero flag is “1” (on state), and if “NZ” is specified for cc, the condition of cc is The condition means that the zero flag is “0” (off state).

  As shown in FIG. 136A, when the “JCP” instruction is used on the source program of the pull-in priority handling process of “ANY role”, the instruction related to the address setting can be omitted (the instruction related to the address setting is separately provided). This eliminates the need to provide), so that the processing efficiency of the pull-in priority handling process of the “ANY role” can be increased, and the capacity of the source program (used capacity of the main ROM 102) can be reduced.

  The stop control pull-in request flag setting process in S686 during the pull-in priority acquisition process described above is performed by the main CPU 101 sequentially executing each source code defined in the source program of FIG. 136B. In the stop request pull-in request flag setting process in S686, as shown in FIG. 136B, an "LDQ" instruction for specifying an address using a Q register (extended register), which is an instruction code dedicated to the main CPU 101, and a "CALLF" Instructions are used.

  Therefore, in the stop control pull-in request flag setting process in S686, the main ROM 102, the main RAM 103, and the memory map I / O are accessed with the immediate value by using the “LDQ” instruction using the Q register (extension register). can do. In this case, an instruction related to address setting can be omitted from the source program, and the capacity of the source program (used capacity of the main ROM 102) can be reduced. The “CALLF” instruction is a 2-byte instruction code as described above. Therefore, in the stop control pull-in request flag setting process, by using these instruction codes dedicated to the main CPU 101, the efficiency of the process can be improved, and the limited capacity of the main RAM 103 can be effectively utilized. .

  Further, in the present embodiment, in the stop control pull-in request flag setting process in S686 during the priority pull-in order obtaining process, the address “SB_DAND_00” of the logical product operation process of the jump destination designated by the “CALLF” instruction is the same as that in FIG. This is the same as the jump destination address specified by the "CALLF" instruction in the logical product operation process of S626 during the pull-in priority storage process described in (1) (see FIG. 127). That is, in the present embodiment, the source program for executing the logical AND operation performed in the stop control pull-in request flag setting process in S686 during the priority pull-in order obtaining process is executed by the logic executed in S626 during the pull-in priority storing process. This is the same as the source program for executing the product operation process, and the source program of the logical product operation process is shared (moduleed) in both the processes of S686 and S626. In this case, since it is not necessary to separately provide a source program for the logical product operation in both the processes S686 and S626, the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  The acquisition process of the withdrawal priority table (see FIG. 137) in S687 during the above-described withdrawal priority acquisition process is performed by the main CPU 101 sequentially executing each source code defined in the source program of FIG. 136C. Done. In the process of acquiring the pull-in priority table in S687, as shown in FIG. 136C, an “LDQ” instruction for specifying an address using a Q register (extended register), which is an instruction code dedicated to the main CPU 101, is used.

  Therefore, in the acquisition process of the pull-in priority table in S687, the use of the “LDQ” instruction can omit the instruction related to the address setting on the source program. As a result, it is possible to improve the efficiency of the process of acquiring the pull-in priority table and reduce the capacity of the source program (the capacity used by the main ROM 102).

  As described above, in the above-described various processes during the priority attraction-in order acquisition process of the present embodiment, the above-described various instruction codes dedicated to the main CPU 101 are appropriately used, thereby realizing the efficiency of the corresponding processes and the reduction of the capacity of the source program. are doing. As a result, in the present embodiment, it is possible to improve the efficiency of the program processing speed of the main control circuit 90 and reduce the capacity, and it is possible to utilize the free space corresponding to the reduced capacity and to enhance the gaming ability. Becomes

[Reel stop control processing]
Next, the reel stop control process performed in S213 in the main flow (see FIG. 82) will be described with reference to FIGS. FIG. 138 is a flowchart showing the procedure of the reel stop control process. FIG. 139 is a diagram illustrating an example of a source program for executing the processing of S711 to S716 described later during the reel stop control processing. FIG. 140 executes the processing of S726 described later during the reel stop control processing. FIG. 6 is a diagram showing an example of a source program for the above.

  First, the main CPU 101 performs a reel stop enable signal OFF process (S711). In this process, the main CPU 101 mainly performs a port output process of the reel stop enable signal OFF data. This process is performed using a non-defined work area of the main RAM 103. The details of the reel stop enable signal OFF processing will be described later with reference to FIG. 141 described later.

  Next, the main CPU 101 determines whether or not the rotation speeds of all the reels have reached a predetermined constant speed (whether or not the rotation speed has become “constant speed”) (S712). In S712, when the main CPU 101 determines that the rotation speeds of all the reels are not "constant speed" (if S712 is NO), the main CPU 101 repeats the process of S712.

  On the other hand, in S712, when the main CPU 101 determines that the rotation speeds of all the reels have become “constant speed” (YES in S712), the main CPU 101 performs a reel stop enable signal ON process (S713). In this process, the main CPU 101 mainly performs port output processing of reel stop enable signal ON data. This process is performed using a non-defined work area of the main RAM 103. The details of the reel stop enable signal ON process will be described later with reference to FIG. 142 described later.

  Next, the main CPU 101 determines whether a valid stop button has been pressed (S714).

  In S714, when the main CPU 101 determines that the effective stop button has not been pressed (NO in S714), the main CPU 101 returns the processing to S713 and repeats the processing from S713. On the other hand, in S714, when the main CPU 101 determines that the valid stop button has been pressed (YES in S714), the main CPU 101 updates the operation stop button storage area (see FIG. 33), The value of the operation counter is decremented by 1 (S715).

  Next, the main CPU 101 determines a reel to be searched from the operation stop button (S716). In this process, an address (head address) setting process of the rotation control data storage area in which the reel control management information of the search target reel is stored is also performed (source code “LDQ IX, wR1_CTRL- (wR2_CTRL) in FIG. 139). -WR1_CTRL) ").

  Next, the main CPU 101 performs a reel stop enable signal OFF process (S717). This processing is performed using a non-defined work area of the main RAM 103, as in the case of S711. The details of the reel stop enable signal OFF processing will be described later with reference to FIG. 141 described later. Next, the main CPU 101 stores the stop start position in the main RAM 103 based on the value of the symbol counter (S718).

  Next, the main CPU 101 performs a reel stop selection process (S719). Although a detailed description is omitted, in this process, the main CPU 101 performs a process of selecting the number of sliding frames.

  Next, the main CPU 101 determines the expected stop position based on the stop start position and the number of sliding pieces determined in S719, and stores the determined expected stop position in the main RAM 103 (S720). In this process, the main CPU 101 adds the number of sliding symbols to the stop start position, and sets the addition result as the expected stop position.

  Next, the main CPU 101 executes a symbol code storage process (S721). In this process, the symbol code corresponding to the expected stop position is stored in the symbol code storage area. Next, the main CPU 101 determines whether or not the reel to be controlled is the last stopped (third stopped) reel (S722). In this process, the main CPU 101 determines whether or not the reel to be controlled is the last stopped (third stop) reel based on the value of the stop button non-operation counter, and the value of the stop button non-operation counter is determined. When it is "0", it is determined that the reel to be controlled is the last stopped reel.

  In S722, when the main CPU 101 determines that the reel to be controlled is not the last stopped reel (NO in S722), the main CPU 101 performs a control change process (S723). In this process, when the vehicle is at a specific stop position, the stop information group used for stopping the reels is updated. Next, the main CPU 101 performs the attraction priority storage processing described with reference to FIG. 126 (S724).

  Next, the main CPU 101 performs a stop interval remaining time standby process (S725). In this process, the main CPU 101 performs a standby process until a preset reel stop interval time has elapsed. Then, after the processing of S725, the main CPU 101 returns the processing to the processing of S711, and repeats the processing from S711.

  Here, returning to the process of S722 again, when the main CPU 101 determines in S722 that the reel to be controlled is the last stopped reel (YES in S722), the main CPU 101 excites all the reels. It is determined whether or not is stopped (S726). In S726, when the main CPU 101 determines that the excitation of all the reels is not in the stopped state (when S726 is NO), the main CPU 101 repeats the process of S726.

  On the other hand, in S726, when the main CPU 101 determines that the excitation of all reels is in the stopped state (when S726 is YES), the main CPU 101 keeps the stop button subjected to the third stop operation in the ON state. It is determined whether or not (stop button is not released) (S727). In S727, when the main CPU 101 determines that the stop button subjected to the third stop operation is still in the ON state (if S727 is YES), the main CPU 101 repeats the process of S727. On the other hand, in S727, when the main CPU 101 determines that the stop button for which the third stop operation has been performed is not kept in the ON state (if S727 is NO), the main CPU 101 ends the reel stop control processing and executes the processing. The process moves to S214 of the main flow (see FIG. 82).

  In the present embodiment, the reel stop control processing is performed as described above. The processing of S711 to S716 in the above-described reel stop control processing is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 139. As shown in FIG. 139, in the source program of the reel stop control processing of the present embodiment, for example, an instruction code dedicated to the main CPU 101, for example, an “LDQ” instruction for specifying an address using a Q register (extension register), or a “LDQ” instruction The "CALLF" instruction is used.

  Therefore, by using such an instruction code dedicated to the main CPU 101 in the reel stop control processing, the capacity of the source program of the reel control processing can be reduced, and the processing efficiency of the reel stop control processing can be improved. it can. That is, in the present embodiment, it is possible to increase the efficiency of the program processing speed in the main control circuit 90 and to reduce the capacity, and to utilize the free space of the main ROM 102 increased in accordance with the reduced capacity to improve the playability. Can be increased.

  The determination process of S726 during the above-described reel stop control process is performed by the main CPU 101 sequentially executing each source code defined in the source program of FIG. 140. As shown in FIG. 140, this processing is executed using an “LDQ” instruction and an “ORQ” instruction (a predetermined OR operation instruction) on the source code.

  The "ORQ" instruction is an instruction code for performing a logical sum operation, and is an instruction code dedicated to the main CPU 101 for specifying an address using a Q register (extension register). Then, for example, when the source code “ORQ (k)” is executed on the source program, the data stored in the Q register (upper address value) and the 1-byte integer k (direct value: lower address value) are obtained. An OR operation is performed on the contents (stored data) of the memory at the designated address and the contents (stored data) of the A register, and the result of the OR operation is stored in the A register.

  Therefore, in the determination processing of S726 during the reel stop control processing, first, when the source code “LDQ A, (.LOW.wR1_TIM)” in FIG. 140 is executed, the data stored in the Q register and the integer value “ .LOW.wR1_TIM "is loaded into the A register at the address of the memory (the excitation timer value of the first reel). In the present embodiment, the address of the area in the main RAM 103 where the excitation timer value of the first reel is stored is “F032h”. In the above-described determination processing of S726, the upper address value “F0h” of the address “wR1_TIM (F032h)” is set in the Q register in advance when the LDQ instruction is executed, and the lower k value (direct value) is set to the value of k (the immediate value). The address value (“.LOW.wR2_TIM” = 32h) is substituted.

  Next, when the source code “ORQ (.LOW.wR2_TIM)” in FIG. 140 is executed, the stored data (F0h) of the Q register and the address “wR2_TIM () of the area where the excitation timer value of the second reel is stored. F03Dh) ”, the contents of the memory at the address specified by the lower address value (3Dh) (the excitation timer value of the second reel) and the contents of the A register (the excitation timer value of the first reel) are calculated. The calculation result (combined result of the excitation timer value of the first reel and the excitation timer value of the second reel) is stored in the A register. Next, when the source code “ORQ (.LOW.wR3_TIM)” in FIG. 140 is executed, the data “F0h” stored in the Q register and the address “wR3_TIM () of the area where the excitation timer value of the third reel is stored are stored. F048h) ”, the contents of the memory at the address specified by the lower address value (48h) (the excitation timer value of the third reel) and the contents of the A register (the excitation timer value of the first reel and the excitation timer of the second reel). The result of the OR operation with the value (combined result of the excitation timer values of the first to third reels) is stored in the A register.

  As described above, in the present embodiment, in the process of checking the stopped state of the reel (turning drum), various instruction codes dedicated to the main CPU 101 using the Q register (extension register) are used. Therefore, by using these instruction codes dedicated to the main CPU 101, it is possible to access the main ROM 102, the main RAM 103, and the memory map I / O with a direct value, and omit the instruction related to the address setting on the source program. Accordingly, the capacity of the source program (used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  As described above, in the various processes during the reel stop control process of the present embodiment, various instruction codes dedicated to the main CPU 101 described above are appropriately used, and the efficiency of the corresponding processes and the reduction of the capacity of the source program are realized. ing. As a result, in the present embodiment, it is possible to improve the efficiency of the program processing speed of the main control circuit 90 and reduce the capacity, and it is possible to utilize the free space corresponding to the reduced capacity and to enhance the gaming ability. Becomes

[Reel stop enable signal OFF processing]
Next, the reel stop enable signal OFF process performed in S711 or S717 during the reel stop control process (see FIG. 138) will be described with reference to FIG. FIG. 141 is a flowchart showing the procedure of the reel stop enable signal OFF process.

  First, the main CPU 101 saves the address of the stack area (see FIG. 12C) of the main RAM 103 set in the stack pointer (SP) (S731). Next, the main CPU 101 sets the address of the non-defined stack area in the stack pointer (SP) (S732).

  Next, the main CPU 101 saves the data set in all the registers (S733). Next, the main CPU 101 performs a set process of the reel stop enable signal OFF data (S734).

  Next, the main CPU 101 performs an undefined port output process (S735). In this process, the main CPU 101 generates and outputs OFF output data (output off mode data) to be described later based on the reel stop enable signal OFF data. This process is performed using a non-defined work area of the main RAM 103. Details of the undefined port output processing will be described later with reference to FIG. 143 described later.

  Next, the main CPU 101 restores the data of all the registers saved in S733 (S736). Next, the main CPU 101 sets the address of the stack area saved in S731 in the stack pointer (SP) (S737).

  After the processing of S737, the main CPU 101 ends the reel stop enable signal OFF processing. At this time, if the executed reel stop enable signal OFF processing is the processing of S711 in the reel stop control processing (see FIG. 138), the main CPU 101 shifts the processing to the processing of S712 in the reel stop control processing. On the other hand, when the executed reel stop enable signal OFF processing is the processing of S717 in the reel stop control processing (see FIG. 138), the main CPU 101 shifts the processing to the processing of S718 in the reel stop control processing.

[Reel stop enable signal ON processing]
Next, the reel stop enable signal ON process performed in S713 during the reel stop control process (see FIG. 138) will be described with reference to FIG. FIG. 142 is a flowchart showing the procedure of the reel stop enable signal ON process.

  First, the main CPU 101 saves the address of the stack area (see FIG. 12C) of the main RAM 103 set in the stack pointer (SP) (S741). Next, the main CPU 101 sets the address of the non-standard stack area in the stack pointer (SP) (S742).

  Next, the main CPU 101 saves the data set in all the registers (S743). Next, the main CPU 101 refers to the operation stop button storage area (see FIG. 33) and acquires the stop button state (S744). Next, the main CPU 101 performs a set process of the reel stop enable signal ON data (S745).

  Next, the main CPU 101 performs a non-defined port output process (S746). In this process, the main CPU 101 generates and outputs ON output data (output ON mode data) to be described later based on the reel stop enable signal ON data. This process is performed using a non-defined work area of the main RAM 103. Details of the undefined port output processing will be described later with reference to FIG. 143 described later.

  Next, the main CPU 101 restores the data of all the registers saved in S743 (S747). Next, the main CPU 101 sets the address of the stack area saved in S741 in the stack pointer (SP) (S748). After the process of S748, the main CPU 101 ends the reel stop enable signal ON process, and shifts the process to the process of S714 in the reel stop control process (see FIG. 138).

[Non-standard port output processing]
Next, with reference to FIGS. 143 and 144, the non-standard port output process performed in S735 during the reel stop enable signal OFF process (see FIG. 141) and S746 during the reel stop enable signal ON process (see FIG. 142). explain. FIG. 143 is a flowchart illustrating the procedure of the undefined port output process. FIG. 144 is a diagram illustrating an example of a source program for executing the undefined port output process.

  First, the main CPU 101 determines whether or not the port output setting is the ON output mode (S751). In this processing, the main CPU 101 determines that the port output setting is the ON output mode when the reel stop enable signal ON data is set, and determines that the reel stop enable signal OFF data is set when the reel stop enable signal OFF data is set. It is determined that the port output setting is not the ON output mode.

  In S751, when the main CPU 101 determines that the port output setting is the ON output mode (if S751 is YES), the main CPU 101 performs the process of S753 described later. On the other hand, in S751, when the main CPU 101 determines that the port output setting is not the ON output mode (if S751 is NO), the main CPU 101 performs a process of generating OFF output data (output off mode data) (S752). ). In this process, among the ports (bits) that are currently in the output on state, the ports (bits) that are to be turned off are turned off, and the ports (bits) that are currently in the output off state are turned off. OFF output data for maintaining the state is generated.

  After the processing of S752 or when the determination of S751 is NO, the main CPU 101 performs a process of generating ON output data (output ON mode data) (S753). In this process, among the ports (bits) that are currently in the output off state, the ports (bits) that are to be turned on are turned on, and the ports (bits) that are currently in the output on state are turned on. ON output data for maintaining the state is generated. Next, the main CPU 101 outputs the generated output data from the designated port (S754).

  Then, after the processing of S754, the main CPU 101 ends the non-defined port output processing. At this time, if the out-of-spec port output process that has been performed is the process of S735 during the reel stop enable signal OFF process (see FIG. 141), the main CPU 101 executes the process of S736 during the reel stop enable signal OFF process. Transfer to On the other hand, if the executed out-of-spec port output process is the process of S746 during the reel stop enable signal ON process (see FIG. 142), the main CPU 101 shifts the process to the process of S747 during the reel stop enable signal ON process. Move.

  In the present embodiment, the out-of-specification port output processing is performed as described above. The above-described non-defined port output processing is performed by the main CPU 101 sequentially executing each source code defined by the source program in FIG. 144.

  Among them, in the generation processing of the OFF output data in S752 during the above-described non-standard port output processing, the source codes “XOR (HL)” and “AND (HL)” in FIG. 144 are executed in this order. Done. Further, the generation processing of the ON output data in S753 during the above-described non-defined port output processing is performed by executing the source code “OR (HL)” in FIG. 144.

  By performing such generation processing of each output data on the source program, even if the generation processing of the ON output data in S753 is performed after the generation processing of the OFF output data in S752, the OFF output data generated in S752 is generated. Does not change.

  For example, the port output setting is the OFF output mode, the output data indicating the non-specified port to be turned off in this process is “00010111” (“1” is the bit to be set to the off state), and the non-specified port is currently set. Is "01010011" ("1" is a currently ON bit), the data of bit 0, bit 1 and bit 5 of the backup data is changed from "1" to "1". OFF output data for setting to “0” is generated. In this case, first, when the source code “XOR (HL)” in FIG. 144 is executed, an exclusive OR operation of the output data “00010111” and the backup data “01010111” is performed, and the operation result is “ 01000100 "is obtained. Next, when the source code “AND (HL)” in FIG. 144 is executed, a logical product operation of the operation result “01000100” and the backup data “01010011” is performed, and the operation result “01000000” is used as OFF output data. Generated.

  Thereafter, when the ON output data generation processing in S753 is performed (source code “OR (HL)” in FIG. 144), the operation result “01000000” (OFF output data) is set to the ON state in this processing. A logical OR operation is performed with output data “00000000” (port output setting is OFF output mode, so each bit of the output data is set to “0”) indicating a non-defined port to be specified. “01000000” is obtained, and the OFF output data does not change. Qualitatively, when the port output setting is the OFF output mode, in the generation processing of the ON output data in S753, the output for maintaining the port (bit) that is in the output ON state in the OFF output data in the ON state. Since the data is generated, the OFF output data generated in S752 does not change even if the generation processing of ON output data in S753 is performed after the generation processing of OFF output data in S752.

[Winning search process]
Next, the winning search processing performed in S214 in the main flow (see FIG. 82) will be described with reference to FIGS. FIG. 145 is a flowchart showing the procedure of the winning search process. FIG. 146 is a diagram showing an example of a source program for executing a winning search process. FIG. 147 is a diagram showing an example of the structure of the payout number data table which is actually referred to on the source program of the winning search process.

  First, the main CPU 101 transfers the data of each storage area stored in the symbol code storage area (see FIG. 35) to the corresponding storage area of the winning operation flag storage area (see FIGS. 28 to 30) and stores the data. (S761). At the end of this process, the last address of the winning operation flag storage area is set in the DE register.

  Next, the main CPU 101 sets the address of the payout number data table (the leading address “dPAYNUMTB” of the payout number data table shown in FIG. 147) in the HL register (S762). Next, the main CPU 101 sets the payout number table number ("5" in the present embodiment) as the initial value of the winning search counter, and sets the initial value in the B register (S763).

  Next, the main CPU 101 sets data of the number of paid out medals (one of one, two, three and nine in the present embodiment) in the C register based on the address set in the HL register. Then, the determination target data is set in the A register, and “2” is added (+2 updated) to the address set in the HL register (S764). In the payout number data table shown in FIG. 147, the data of the payout number of medals is “payout number (1, 2, 3, or 9) * 2 + 0”, and the determination target data is the next to the payout number data. This is 1-byte data (for example, “11111000B”) stored in the address. Hereinafter, the data “0” in the data “payout number (1, 2, 3, or 9) * 2 + 0” of the payout number of medals set in the C register is referred to as a “judgment bit”. This determination bit is information indicating whether or not the block is a determination target block for a winning search.

  Next, the main CPU 101 extracts the value of the determination bit from the data of the number of payout medals set in the C register (S765). Next, the main CPU 101 determines whether or not the block is a determination target based on the value of the extracted determination bit (S766). In this process, when the value of the extracted determination bit is “1”, the main CPU 101 determines that the block is a determination target block. In the present embodiment, as shown in FIG. 147, the value of the determination bit is always “0” regardless of the number of payout medals, so the process of S766 is always a NO determination.

  In S766, when the main CPU 101 determines that the block is not the determination target block (if S766 is NO), the main CPU 101 performs the process of S768 described later. On the other hand, when the main CPU 101 determines in S766 that the block is a determination target block (YES in S766), the main CPU 101 decrements the address of the winning operation flag storage area set in the DE register by 1 (− (1 update) (S767).

  After the process of S767 or when the determination of S766 is NO, the main CPU 101 extracts the data of the storage area specified by the address of the winning operation flag storage area set in the DE register as the determination data (S768).

  Next, the main CPU 101 determines whether or not the result of the determination is a winning based on the determination target data set in the A register in S764 and the determination data extracted in S768 (S769). In this process, if the determination target data set in the A register in S764 is the same as the determination data extracted in S768, the main CPU 101 determines that the determination result is a winning.

  In S769, when the main CPU 101 determines that the result of the determination is not a winning (when S769 is NO), the main CPU 101 performs the process of S776 described later. On the other hand, when the main CPU 101 determines in S769 that the result of the determination is a winning (when the determination in S769 is YES), the main CPU 101 determines that the current game is a three-game game (a game in which the number of medals is three). ) Is determined (S770).

  In S770, when the main CPU 101 determines that the current game is a three-game game (if S770 is YES), the main CPU 101 performs the processing of S772 described later. On the other hand, when the main CPU 101 determines in S770 that the current game is not a three-game game (NO in S770), the main CPU 101 pays out a two-game game (a game in which the number of medals is two). The number (two) is set in the C register (S771).

  After the process of S771 or in the case of YES determination in S770, the main CPU 101 performs a process of updating the number of payouts (S772). Specifically, the main CPU 101 adds the payout number of medals set in the C register to the current value of the winning number counter, and sets the value after the addition as the payout number.

  Next, the main CPU 101 determines whether or not the value of the payout number is less than the maximum payout number “10” (S773).

  In S773, when the main CPU 101 determines that the value of the payout number is less than the maximum payout number “10” (if S773 is YES), the main CPU 101 performs the processing of S775 described later. On the other hand, in S773, when the main CPU 101 determines that the value of the payout number is not less than the maximum payout number “10” (if S773 is NO), the main CPU 101 sets the payout number to the maximum payout number “10”. (S774).

  After the process of S774 or in the case of YES determination in S773, the main CPU 101 stores the payout number in the winning number counter (S775).

  After the processing of S775 or when the determination of S769 is NO, the main CPU 101 determines whether or not there is another winning (S776). In S776, when the main CPU 101 determines that there is another winning (S776: YES), the main CPU 101 returns the process to S769, and repeats the processes from S769.

  On the other hand, in S776, when the main CPU 101 determines that there is no other winning (S776: NO), the main CPU 101 decrements the value of the winning search counter by 1 (-1 update) (S777). When the number of active lines is one, as in the present embodiment, a plurality of small wins do not win at the same time, so the determination process of S776 is always a NO determination.

  Next, the main CPU 101 determines whether or not the value of the winning search counter is “0” (S778).

  In S778, when the main CPU 101 determines that the value of the winning search counter is not “0” (if S778 is NO), the main CPU 101 returns the processing to S764 and repeats the processing from S764. On the other hand, in S778, when the main CPU 101 determines that the value of the winning search counter is “0” (if S778 is YES), the main CPU 101 ends the winning search process and proceeds to the main flow (FIG. 82)).

  In the present embodiment, the winning search process is performed as described above. The above-mentioned winning search process is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 146. Among them, the processing of setting the payout number and the determination target data in S764 is performed by the main CPU 101 executing the source code “LDIN AC, (HL)”.

  For example, when the source code “LDIN ss, (HL)” is executed on the source program, the contents of the memory specified by the address set in the HL register (pair register) and the address obtained by adding one to the address ( The data) is loaded into the ss (BC, DE, AC, AE or BD) pair register, and the address set in the HL register is updated by +2 (addition of 2). Therefore, when the source code “LDIN AC, (HL)” in FIG. 146 is executed, the contents of the memory designated by the address set in the HL register (pair register) and the address obtained by adding 1 to the address ( The payout number and the data to be determined) are loaded into the AC register, and the address set in the HL register is updated by +2 (addition of 2). In the process of S764, the "LDIN" instruction causes the data of the number of payouts to be stored in the A register, the determination target data to be stored in the C register, and the address set in the HL register to be updated by +2.

  As described above, in the winning search process of the present embodiment, both the data loading process and the address updating process can be performed by one “LDIN” instruction. In this case, an instruction related to address setting can be omitted in the source program, and the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  In addition, the medal counter value acquisition processing referred to in the determination processing of S770 during the above-described winning search processing, the acquisition number counter value acquisition processing referred to in the S772 processing, and the winning number counter performed in the S775 processing are performed. As shown in FIG. 146, all the save (update) processes are executed by an “LDQ” instruction (instruction code dedicated to the main CPU 101) for specifying an address using a Q register (extension register). Therefore, in the winning search processing of the present embodiment, the main ROM 102, the main RAM 103, and the memory map I / O can be accessed by the direct value by using the “LDQ” instruction. It is possible to omit a command for setting (there is no need to separately provide a command for address setting), and accordingly, it is possible to reduce the capacity of the source program (the used capacity of the main ROM 102). As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  The determination process in S769 during the winning search process described above is executed by a “JSLAA” command (a predetermined determination command) on the source program, as shown in FIG. The “JSLAA” instruction is an instruction for executing an operation equivalent to a left shift (SLA) instruction.

  For example, when the source code “JSLAA cc, e” is executed on the source program, if the condition of cc is satisfied, the processing jumps to the address specified by e. The “cc condition” defined by the “JSLAA” instruction specifies the state of the carry flag in the flag register F. For example, if “C” is specified for cc, the condition of cc means that the carry flag is “1” (on state), and if “NC” is specified for cc, the condition of cc is Means that the carry flag is "0" (off state). Therefore, in the source code “JSLAA NC, MN_CKLN_06” in FIG. 146, if the carry flag is “0” (off state), the processing jumps to the address specified by “MN_CKLN_06”.

  The determination processing in S770 and S773 during the above-described winning search processing is executed by a “JCP” instruction on the source program, as shown in FIG. As described above, the “JCP” instruction is an instruction for executing an operation corresponding to a comparison instruction, and is an instruction code dedicated to the main CPU 101.

  Therefore, when the above-described “JSLAA” instruction and “JCP” instruction are used in the source program of the winning search processing, the instruction relating to the address setting can be omitted (it is necessary to separately provide the instruction relating to the address setting). The capacity of the source program (used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Illegal hit check processing]
Next, the illegal hit check processing performed in S215 in the main flow (see FIG. 82) will be described with reference to FIGS. 148 and 149. FIG. 148 is a flowchart showing the procedure of the illegal hit check process. FIG. 149 is a diagram illustrating an example of a source program for executing the illegal hit check process. Here, the illegal hit is determined by the internal lottery process (see FIG. 92) and the BB winning number and the small role winning number (internal winning combination) stored in the winning number storage area in the symbol setting process (see FIG. 97). This is a term indicating that the left reel 3L, the middle reel 3C, and the right reel 3R have stopped on the activated line based on a symbol combination that cannot be established (a symbol combination has not been established).

  First, the main CPU 101 sets the address of the winning operation flag storage area (see FIGS. 28 to 30) (S781). Next, the main CPU 101 sets the size (the number of bytes, "12" in the present embodiment) of the winning operation flag storage area to the value of the check counter (S782).

  Next, based on the address of the currently set winning operation flag storage area, the main CPU 101 sets the internal winning combination stored in the storage area in the hit request flag storage area (internal winning combination storage area) corresponding to the address. (S783) is obtained (S783). Next, the main CPU 101 combines the winning combination data (winning operation flag data) stored at the address of the currently set winning operation flag storage area with the internal winning combination data (hit request flag data) ( S784).

  In the synthesizing process, first, the main CPU 101 obtains an exclusive OR of the data of the winning combination (winning operation flag data) and the data of the internal winning combination (winning request flag data) (the source program shown in FIG. 149). Source code "XOR (HL)" in the middle. Next, the main CPU 101 obtains the logical product of the calculated result of the exclusive OR and the winning combination data (winning operation flag data) (the source code “AND (HL)” in the source program shown in FIG. 149). ), And the calculation result of the logical product is taken as the synthesis result. If no illegal hit error has occurred, the value of the synthesis result is “0”.

  Next, the main CPU 101 determines whether or not an illegal hit error has occurred based on the result of the combining process in S784 (S785).

  In S785, when the main CPU 101 determines that no illegal hit error has occurred (NO in S785), the main CPU 101 updates the address of the winning operation flag storage area to be referenced by +1 (S786). Next, the main CPU 101 subtracts 1 from the value of the check counter (S787). Next, the main CPU 101 determines whether or not the value of the check counter is “0” (S788).

  In S788, when the main CPU 101 determines that the value of the check counter is not “0” (if S788 is NO), the main CPU 101 returns the process to S783, and repeats the processes from S783. On the other hand, in S788, when the main CPU 101 determines that the value of the check counter is “0” (if S788 is YES), the main CPU 101 ends the illegal hit check process, and proceeds to the main flow (FIG. 82)).

  Here, returning to the processing of S785 again, when the main CPU 101 determines in S785 that an illegal hit error has occurred (if S785 is YES), the main CPU 101 executes the error processing described in FIG. Is performed (S789). By this processing, two characters “EE” indicating the occurrence of an illegal hit error are displayed as error information on a 2-digit 7-segment LED (for both payout number display and error display) included in the information display 6. Error display data is output. The state of occurrence of the illegal hit error (error state) is released by pressing the reset switch 76 (see FIG. 7).

  Next, the main CPU 101 clears the value of the winning number counter and the data in the hit request flag storage area (S790). Then, after the processing of S790, the main CPU 101 ends the illegal hit check processing, and shifts the processing to the processing of S216 in the main flow (see FIG. 82).

  In the present embodiment, the illegal hit check process is performed as described above. The above-described illegal hit check processing is performed by the main CPU 101 sequentially executing each source code defined by the source program in FIG. 149.

  In the present embodiment, as shown in FIGS. 28 to 30, the configuration of the winning operation flag storage area (display combination storage area) is the same as that of the hit request flag storage area (internal winning combination storage area). The winning request flag storage area and the winning operation flag storage area arranged in the main RAM 103 at the time of the combination processing of the winning operation flag storage area combination and the internal winning combination can have the same configuration. Therefore, as described above, the calculation result of S784 (the result of combining the winning combination data and the internal winning combination data) in the illegal hit check processing of the present embodiment is the same as that of the winning combination data and the internal winning combination in the source program. It is obtained by simply performing a logical AND (executing with an “AND” instruction) with the winning combination data. As a result, in the present embodiment, the illegal hit check processing can be made more efficient and simplified, the free space of the main control program can be secured (increased), and the increased free space can be used to improve the playability. It is possible to increase.

[Winning check / medal payout process]
Next, the winning check / medal payout process performed in S216 in the main flow (see FIG. 82) will be described with reference to FIGS. FIG. 150 is a flowchart showing the procedure of the winning check / medal payout process. FIG. 151 is a diagram showing an example of a source program for executing processes of S804 to S808 described later during the winning check / medal payout process.

  First, the main CPU 101 performs a winning operation command generation process (S801). In this process, the main CPU 101 generates type data and various communication parameters included in the winning operation command transmitted to the sub control circuit 200. The winning operation command includes a parameter for specifying a winning operation flag (display combination) and the like.

  Next, the main CPU 101 performs the communication data storage processing described with reference to FIG. 72 (S802). Through this processing, the winning operation command data is stored in the communication data storage area (see FIG. 75B) provided in the main RAM 103. The winning operation command is transmitted from the main control circuit 90 to the sub-control circuit 200 by a communication data transmission process in an interruption process described later with reference to FIG.

  Next, the main CPU 101 determines whether or not the value of the winning number counter is “0” (S803). In S803, when the main CPU 101 determines that the value of the winning number counter is “0” (if S803 is YES), the main CPU 101 ends the winning check / medal payout process, and proceeds to the main flow ( The process proceeds to S217 in FIG. 82).

  On the other hand, in S803, when the main CPU 101 determines that the value of the winning number counter is not “0” (in the case of NO determination in S803), the main CPU 101 determines that the number of credits (stored number) of medals is equal to the upper limit number (number of coins). It is determined whether or not the number is equal to or more than (50 in the embodiment) (S804).

  In S804, when the main CPU 101 determines that the number of credits of medals is not equal to or more than the upper limit number (NO in S804), the main CPU 101 adds (+1 updates) the value of the credit counter (+1 update). S805). The value of the added credit counter is displayed by a 2-digit 7-segment LED (not shown) for displaying the number of stored sheets included in the information display 6. Next, the main CPU 101 performs a medal payout number check process (S806). The details of the medal payout number check process will be described later with reference to FIG. 152 described later.

  Next, the main CPU 101 determines whether or not the payout of medals has been completed (S807). When the main CPU 101 determines in S807 that the payout of medals has been completed (YES in S807), the main CPU 101 ends the prize check / medal payout process, and proceeds to the main flow (see FIG. 82). The process proceeds to S217.

  On the other hand, when the main CPU 101 determines in S807 that the payout of medals has not been completed (NO in S807), the main CPU 101 performs a payout interval waiting process (S808). In this process, the main CPU 101 continues until a predetermined medal payout interval time (60.33 msec in this embodiment: 54 cycles of an interrupt process (1.1172 msec cycle) described later with reference to FIG. 158) elapses. Weight. After the processing in S808, the main CPU 101 returns the processing to the processing in S803, and repeats the processing in S803 and thereafter.

  Here, returning to the process of S804 again, when the main CPU 101 determines in S804 that the number of credits of medals is equal to or more than the upper limit number (50) (if S804 is YES), the main CPU 101 proceeds to S804. A medal payout process is performed (S809). By this process, one medal is paid out. Then, after the processing of S809, the main CPU 101 ends the winning check / medal payout processing, and moves the processing to the processing of S217 in the main flow (see FIG. 82).

  In the present embodiment, the winning check / medal payout process is performed as described above. The processing of S804 to S808 during the above-described winning check / medal payout processing is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 151.

  In the present embodiment, when the payout operation is continued after the credit counter is updated (+1), the main CPU 101 performs a wait (payout interval waiting) process for 60.33 ms in the process of S808. On the source program, this is realized by the main CPU 101 executing the source codes “LD BC, cTM_PAYC” and “RST SB_W1BC_00” in this order. As described above, in the prize check / medal payout process, if the wait (payout interval wait) for 60.33 ms is performed when the payout operation is continued after the credit counter is updated (+1), useless waiting time is reduced. This can reduce the mental burden on the player.

[Medal payout number check process]
Next, with reference to FIGS. 152 and 153, a description will be given of the medal payout number check processing performed in S806 during the winning check / medal payout processing (see FIG. 150). FIG. 152 is a flowchart showing the procedure of the medal payout number check process. FIG. 153A is a diagram showing an example of a source program for executing processing of S811 to S814, which will be described later, during the medal payout number check processing. FIG. 153B is a view showing S816, which will be described later, during the medal payout number check processing. FIG. 14 is a diagram illustrating an example of a source program for executing the process of S817.

  First, the main CPU 101 adds (1) to the value of the medal OUT counter (+1 update) (S811). Note that the medal OUT counter is a counter for counting the number of payouts of medals. Next, the main CPU 101 adds (1) to the value of the number-of-payouts counter (+1 update) (S812). The payout number counter is a counter for counting the number of payout medals.

  Next, the main CPU 101 performs a payout number 7SEG display process (S813). In this process, the main CPU 101 performs a control process of displaying the value of the number-of-payouts counter using a 2-digit 7-segment LED (not shown) for displaying the number-of-payouts included in the information display 6.

  Next, the main CPU 101 performs an update process of the winning combination end number counter (S814). Note that the winning combination end number counter is a counter for counting the remaining number of payout numbers of medals corresponding to the winning combination. In this processing, the main CPU 101 compares the value of the winning combination end number counter with its lower limit value “0”, and when the value of the winning end number counter is larger than the lower limit value “0”, the main CPU 101 The value of the counter is decremented by one (-1 update), and if the value of the number-of-combination-end-number counter is equal to or smaller than the lower limit value “0”, the value of the combination-of-combination-end number counter is held at “0”.

  Next, the main CPU 101 decrements the value of the winning number counter by one (-1 update) (S815).

  Next, the main CPU 101 performs a credit information command generation process (S816). In this process, the main CPU 101 generates type data and various communication parameters included in the credit information command transmitted to the sub control circuit 200. Note that the credit information command is configured to include a parameter for specifying the number of credits of medals.

  Next, the main CPU 101 performs the communication data storage processing described with reference to FIG. 72 (S817). By this processing, the credit information command data is stored in the communication data storage area (see FIG. 75B) provided in the main RAM 103. The credit information command is transmitted from the main control circuit 90 to the sub-control circuit 200 by a communication data transmission process in an interruption process described later with reference to FIG. Then, after the processing of S817, the main CPU 101 ends the medal payout number check processing, and shifts the processing to the processing of S807 in the winning check / medal payout processing (see FIG. 150).

  In the present embodiment, the medal payout number check process is performed as described above. Note that the processing of S811 to S814 during the medal payout number check processing described above is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 153A. Among them, the update processing of the winning combination end number counter of S814 is executed by the “DCPLD” instruction (predetermined update instruction) in FIG. 153A. The “DCPLD” instruction is an instruction code dedicated to the main CPU 101.

  For example, when the source code “DCPLD (HL), n” is executed on the source program, the contents of the memory (stored data) at the address specified by the HL register are compared with the integer n, and the contents of the memory are compared. If the content of the memory is larger than the integer n, 1 is subtracted. If the content of the memory is smaller than the integer n, the integer n is stored in the memory at the address specified by the HL register. Therefore, when the source code “DCPLD (HL), 0” in FIG. 153A is executed, the contents of the memory at the address specified by the HL register (the value of the number-of-copies-end counter) and the integer 0 (lower limit) Are compared with each other. If the content of the memory (the value of the number-of-completion-completion counter) is greater than the integer 0, the content of the memory is decremented by 1. If the content of the memory is less than the integer 0, the content of the memory “0” is set to (the value of the number-of-combination-end number counter). In other words, if the value of the current number-of-combination end number counter is greater than "0", the update processing of the number-of-completion-end number counter is performed, and if the current value of the combination end number counter is "0" or less. Then, a process of holding the value of the winning combination end number counter at “0” is performed.

  As described above, in the processing of S814 during the medal payout number check processing, one “DCPLD” instruction (an instruction in which the lower limit determination instruction of the number management counter and the determination branch instruction are integrated) is used to finish the number of winning combinations. Both the process of updating (subtracting) the counter and the process of holding the value of the consecutive end number counter at “0” can be executed. In this case, there is no need to provide instruction codes for executing both processes separately. For example, the determination branch instruction code for determining whether the value of the consecutive end number counter is “0” can be omitted. Therefore, in the medal payout number check processing of the present embodiment, the capacity of the source program (the used capacity of the main ROM 102) can be reduced, and the free space in the main ROM 102 can be secured (increased), and the number of Utilizing the unused space, it is possible to enhance the gaming ability.

  Further, the processing of S816 and S817 during the medal payout number check processing described above is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 153B.

  Among them, in the processing of S816, as shown in FIG. 153B, the value of the number-of-payout counter is set to the communication parameter 1 of the credit information command via the L register, and the credit is set to the communication parameter 5 via the C register. The value of the counter is set. However, the values (undefined values) stored in the H register, the E register, and the D register at the present time are set in the other communication parameters 2 to 4 constituting the credit information command. Therefore, the values of the communication parameters 2 to 4 at the time of transmitting the credit information command are undefined values. As a result, in the present embodiment, the sum value (BCC) of the credit information command can be set to an indefinite value for each transmission, and fraudulent acts such as goto can be suppressed.

[BB check processing]
Next, the BB check process performed in S217 in the main flow (see FIG. 82) will be described with reference to FIG. FIG. 154 is a flowchart illustrating the procedure of the BB check process.

  First, the main CPU 101 determines whether or not the current gaming state is a bonus state (S821). In S821, when the main CPU 101 determines that the current gaming state is not the bonus state (if S821 is NO), the main CPU 101 performs the processing of S832 described later.

  On the other hand, in S821, when the main CPU 101 determines that the current game state is the bonus state (if S821 is YES), the main CPU 101 counts the number of medals that can be paid out during the bonus state. The number of medals paid out in the winning check / medal payout process is subtracted from the value of the BB medium payout number counter (S822).

  Next, the main CPU 101 determines whether or not the value of the BB payout number counter is less than “0” (S823). In S823, when the main CPU 101 determines that the value of the number-of-payout counter during BB is not less than “0” (NO in S823), the main CPU 101 ends the BB check process and proceeds to the main flow (FIG. 82)).

  On the other hand, in S823, when the main CPU 101 determines that the value of the number-of-payout counter during BB is smaller than “0” (if S823 is YES), the main CPU 101 performs bonus end processing (S824). In this process, the main CPU 101 clears various information in the bonus state and sets the RT1 state flag to the ON state.

  Next, the main CPU 101 refers to the bonus end CT lottery table (see FIG. 60) to perform the CT random determination at the end of the bonus (S825). Next, the main CPU 101 determines whether or not the CT lottery at the end of the bonus has been won (S826).

  In S826, when the main CPU 101 determines that the CT lottery has not been won (if S826 is NO), the main CPU 101 performs the process of S828 described later. On the other hand, in S826, when the main CPU 101 determines that the CT lottery has been won (if S826 is YES), the main CPU 101 adds “1” to the number of CT sets (S827). If the number of ART sets is "0" and the CT lottery is won, in the process of S827, "1" is added to the number of CT sets and "1" is also added to the number of ART sets. .

  After the processing of S827 or when S826 is NO, the main CPU 101 determines whether the number of ART sets or the number of CT sets is “1” or more (S828).

  In S828, when the main CPU 101 determines that the number of ART sets or the number of CT sets is “1” or more (if S828 is YES), the main CPU 101 sets the ART preparation state to the game state of the next game. (S829). Then, after the processing of S829, the main CPU 101 ends the BB check processing, and shifts the processing to the processing of S218 in the main flow (see FIG. 82).

  On the other hand, in S828, when the main CPU 101 determines that the number of ART sets or the number of CT sets is not “1” or more (NO in S828), the main CPU 101 sets the normal game state to the next game state. (S830). Next, the main CPU 101 refers to the normal medium-high probability lottery table (see FIG. 40B), randomly selects the CZ random determination state, and sets the random determination result (S831). Then, after the processing of S831, the main CPU 101 ends the BB check processing, and shifts the processing to the processing of S218 in the main flow (see FIG. 82).

  Here, returning to the process of S821 again, if the determination of S821 is NO, the main CPU 101 determines whether or not the symbol combination relating to the BB combination (the symbol combination of the combination “C_BB1” or “C_BB2”) is displayed. (S832). In S832, when the main CPU 101 determines that the symbol combination relating to the BB combination has not been displayed (NO in S832), the main CPU 101 ends the BB check process and proceeds to the main flow (see FIG. 82). The process proceeds to S218.

  On the other hand, in S832, when the main CPU 101 determines that the symbol combination relating to the BB combination has been displayed (YES in S832), the main CPU 101 refers to the bonus type lottery table (see FIG. 58) to determine the bonus combination. The type is determined by lottery, and the result of the lottery is set (S833). Next, the main CPU 101 sets a predetermined value (the number of payouts to be a bonus end trigger: “216” in the present embodiment) to the value of the number-of-payout counter during BB (S834).

  Next, the main CPU 101 performs a bonus start process (S835). In this process, the main CPU 101 performs various processes necessary for starting the operation of the bonus, such as setting the bonus state to the game state of the next game. Then, after the processing of S835, the main CPU 101 ends the BB check processing, and shifts the processing to the processing of S218 in the main flow (see FIG. 82).

[RT check processing]
Next, the RT check process performed in S218 in the main flow (see FIG. 82) will be described with reference to FIGS. 155 and 156. 155 and 156 are flowcharts showing the procedure of the RT check process.

  First, the main CPU 101 determines whether or not the RT state is the RT5 state (S841). In S841, when the main CPU 101 determines that the RT state is the RT5 state (if S841 is YES), the main CPU 101 ends the RT check processing, and proceeds to S219 in the main flow (see FIG. 82). Move on to

  On the other hand, in S841, when the main CPU 101 determines that the RT state is not the RT5 state (if S841 is NO), the main CPU 101 determines whether the RT state is the RT0 state (S842). In S842, when the main CPU 101 determines that the RT state is not the RT0 state (if S842 is NO), the main CPU 101 performs the processing of S845 described later.

  On the other hand, in S842, when the main CPU 101 determines that the RT state is the RT0 state (if S842 is YES), the main CPU 101 displays the symbol combination of the abbreviation “bell spilled eyes” (see FIG. 28). It is determined whether or not it has been (S843). In S843, when the main CPU 101 determines that the symbol combination of the abbreviation "bell spilled eyes" has not been displayed (NO in S843), the main CPU 101 ends the RT check process, and proceeds to the main flow (FIG. 82)).

  On the other hand, in S843, when the main CPU 101 determines that the symbol combination of the abbreviation "bell spilled eyes" is displayed (if S843 is YES), the main CPU 101 sets the RT2 state flag to the ON state (S844). . By this processing, the RT state shifts from the RT0 state to the RT2 state. Then, after the processing of S844, the main CPU 101 ends the RT check processing, and moves the processing to the processing of S219 in the main flow (see FIG. 82).

  Here, returning to the process of S842 again, if the determination of S842 is NO, the main CPU 101 determines whether or not the RT state is the RT1 state (S845). In S845, when the main CPU 101 determines that the RT state is not the RT1 state (if S845 is NO), the main CPU 101 performs the processing of S850 described later.

  On the other hand, in S845, when the main CPU 101 determines that the RT state is the RT1 state (if S845 is YES), the main CPU 101 determines whether or not the symbol combination of the abbreviation "bell spilled eyes" is displayed. (S846).

  In S846, when the main CPU 101 determines that the symbol combination of the abbreviation "bell spilled eyes" is displayed (if S846 is YES), the main CPU 101 sets the RT1 state flag to the OFF state and sets the RT2 state flag. Is set to the ON state (S847). By this processing, the RT state shifts from the RT1 state to the RT2 state. Then, after the processing of S847, the main CPU 101 ends the RT check processing, and shifts the processing to the processing of S219 in the main flow (see FIG. 82).

  On the other hand, in S846, when the main CPU 101 determines that the symbol combination of the abbreviation “bell spilled eyes” has not been displayed (NO in S846), the main CPU 101 determines whether or not 20 games have passed in the RT1 state. Is determined (S848).

  In S848, when the main CPU 101 determines that the game in the RT1 state has not passed 20 games (if S848 is NO), the main CPU 101 ends the RT check process and proceeds to the main flow (see FIG. 82). The processing moves to the processing of S219 in). On the other hand, in S848, when the main CPU 101 determines that the game in the RT1 state has elapsed 20 games (if S848 is YES), the main CPU 101 sets the RT1 state flag to an off state (S849). With this processing, the RT state shifts from the RT1 state to the RT0 state. Then, after the processing of S849, the main CPU 101 ends the RT check processing, and shifts the processing to the processing of S219 in the main flow (see FIG. 82).

  Here, returning to the process of S845 again, if the determination of S845 is NO, the main CPU 101 determines whether or not the RT state is the RT2 state (S850). In S850, when the main CPU 101 determines that the RT state is not the RT2 state (if S850 is NO), the main CPU 101 performs the processing of S853 described later.

  On the other hand, in S850, when the main CPU 101 determines that the RT state is the RT2 state (if S850 is YES), the main CPU 101 displays the symbol combination of the abbreviation “RT3 shift lip” (see FIG. 28). It is determined whether or not it has been (S851). In S851, when the main CPU 101 determines that the symbol combination of the abbreviation “RT3 shift lip” has not been displayed (NO in S851), the main CPU 101 ends the RT check processing and proceeds to the main flow (FIG. 82)).

  On the other hand, in S851, when the main CPU 101 determines that the symbol combination of the abbreviation “RT3 shift lip” has been displayed (if S851 is YES), the main CPU 101 sets the RT2 state flag to the OFF state and sets the RT3 state flag to OFF. The state flag is set to the ON state (S852). By this processing, the RT state shifts from the RT2 state to the RT3 state. Then, after the processing of S852, the main CPU 101 ends the RT check processing, and shifts the processing to the processing of S219 in the main flow (see FIG. 82).

  Here, returning to the process of S850 again, if S850 is NO, the main CPU 101 determines whether or not the RT state is the RT3 state (S853). In S853, when the main CPU 101 determines that the RT state is not the RT3 state (if S853 is NO), the main CPU 101 performs the processing of S862 described later.

  On the other hand, in S853, when the main CPU 101 determines that the RT state is the RT3 state (if S853 is YES), the main CPU 101 displays the symbol combination of the abbreviation “bell spilled eyes” or “RT2 shift lip”. It is determined whether or not it has been performed (S854).

  In S854, when the main CPU 101 determines that the symbol combination of the abbreviation "bell spilled eyes" or "RT2 shift lip" is displayed (if S854 is YES), the main CPU 101 sets the RT3 state flag to the OFF state. At the same time, the RT2 state flag is set to the ON state (S855). With this processing, the RT state shifts from the RT3 state to the RT2 state. Then, after the processing of S855, the main CPU 101 ends the RT check processing, and shifts the processing to the processing of S219 in the main flow (see FIG. 82).

  On the other hand, in S854, when the main CPU 101 determines that the symbol combination of the abbreviation "bell spilled eyes" or "RT2 transition lip" is not displayed (if S854 is NO), the main CPU 101 executes the abbreviation "RT4 transition". It is determined whether or not the symbol combination of “Rip” (see FIG. 28) is displayed (S856).

  In S856, when the main CPU 101 determines that the symbol combination of the abbreviation "RT4 shift lip" is not displayed (if S856 is NO), the main CPU 101 ends the RT check process and proceeds to the main flow ( The process proceeds to S219 in FIG. 82). On the other hand, in S856, when the main CPU 101 determines that the symbol combination of the abbreviation “RT4 shift lip” is displayed (if S856 is YES), the main CPU 101 sets the RT3 state flag to the OFF state and sets the RT4 The state flag is set to the ON state (S857). By this processing, the RT state shifts from the RT3 state to the RT4 state.

  After the process of S857, the main CPU 101 determines whether or not the gaming state is the ART preparation state (S858). In S858, when the main CPU 101 determines that the gaming state is not the ART preparation state (NO in S858), the main CPU 101 ends the RT check processing, and proceeds to S219 in the main flow (see FIG. 82). Move on to

  On the other hand, in S858, when the main CPU 101 determines that the gaming state is the ART preparation state (if S858 is YES), the main CPU 101 determines whether the number of CT sets is “1” or more. (S859).

  In S859, when the main CPU 101 determines that the number of CT sets is “1” or more (if S859 is determined to be YES), the main CPU 101 sets the CT to the game state of the next game, and sets the CT state in the CT game number counter. "8" is set (S860). Then, after the processing of S860, the main CPU 101 ends the RT check processing, and shifts the processing to the processing of S219 in the main flow (see FIG. 82).

  On the other hand, when the main CPU 101 determines in S859 that the number of CT sets is not equal to or more than “1” (NO in S859), the main CPU 101 sets the normal ART to the game state of the next game and sets the ART end game. A predetermined value is set in the number counter (S861). Then, after the process of S861, the main CPU 101 ends the RT check process, and shifts the process to the process of S219 in the main flow (see FIG. 82).

  Here, returning to the process of S853 again, if the determination of S853 is NO, the main CPU 101 determines whether or not the symbol combination of the abbreviation "bell spilled eyes" or "RT2 shift lip" is displayed (S862). In S862, when the main CPU 101 determines that the symbol combination of the abbreviation "bell spilled eyes" or "RT2 shift lip" is not displayed (if S862 is NO), the main CPU 101 ends the RT check processing. , To the processing of S219 in the main flow (see FIG. 82).

  On the other hand, in S862, when the main CPU 101 determines that the symbol combination of the abbreviation “bell spilled eyes” or “RT2 shift lip” is displayed (if S862 is YES), the main CPU 101 turns off the RT4 state flag. And the RT2 state flag is set to the ON state (S863). By this processing, the RT state shifts from the RT4 state to the RT2 state. Then, after the processing of S863, the main CPU 101 ends the RT check processing, and shifts the processing to the processing of S219 in the main flow (see FIG. 82).

[Process at the end of CZ / ART]
Next, with reference to FIG. 157, the process at the end of the CZ • ART performed in S219 in the main flow (see FIG. 82) will be described. FIG. 157 is a flowchart showing the procedure of the process at the end of CZ / ART.

  First, the main CPU 101 determines whether or not the current gaming state is either when the CZ fails or when the ART ends (S871). In S871, when the main CPU 101 determines that the current gaming state is not either CZ failure or ART termination (if S871 is NO), the main CPU 101 ends the CZ ART termination processing, The processing moves to the processing of S201 in the main flow (see FIG. 82).

  On the other hand, in S871, when the main CPU 101 determines that the current gaming state is either CZ failure or ART termination (if S871 is YES), the main CPU 101 determines whether the current game state is the CZ lottery table (see FIG. 41B). ), The CZ pull-back lottery is performed (S872). Next, the main CPU 101 determines whether or not the CZ pull-back lottery has been won (S873).

  In S873, when the main CPU 101 determines that the pull-back lottery of CZ has been won (if S873 is YES), the main CPU 101 sets the type of CZ that has been won in the game state of the next game (S874). Next, the main CPU 101 sets a value corresponding to the winning type of CZ in the CZ game number counter (S875). Then, after the processing of S875, the main CPU 101 ends the CZ / ART termination processing, and shifts the processing to the processing of S201 in the main flow (see FIG. 82).

  On the other hand, when the main CPU 101 determines in S873 that the CZ pull-back lottery has not been won (NO in S873), the main CPU 101 sets the normal gaming state to the next gaming state (S876). Next, the main CPU 101 refers to the normal medium / high-probability lottery table (see FIG. 40B), randomly selects the CZ lottery state, and sets the lottery result (S877). Then, after the process of S877, the main CPU 101 ends the CZ / ART termination process, and shifts the process to the process of S201 in the main flow (see FIG. 82).

[Interrupt processing under control of main CPU (1.1172 msec)]
Next, with reference to FIG. 158, an interruption process performed by the main CPU 101 in a period of 1.1172 msec will be described. FIG. 158 is a flowchart showing the procedure of the interrupt processing. The interrupt process repeatedly executed at a period of 1.1172 msec is generated based on the output timing of the timeout signal of the timer circuit 113 set in the initialization process of the timer circuit 113 (PTC) (see S2 in FIG. 64). This is a process executed when an interrupt request signal from the interrupt controller 112 is input to the main CPU 101.

  First, the main CPU 101 performs a register save process (S901). Next, the main CPU 101 performs an input port check process (S902). In this process, signals input from various switches such as a stop switch are checked.

  Next, the main CPU 101 performs a reel control process (S903). In this process, the main CPU 101 starts the rotation of the left reel 3L, the middle reel 3C, and the right reel 3R when the start of rotation of all the reels is requested, and then rotates the respective reels at a constant speed. Drive control of three stepping motors. When the number of sliding pieces is determined, the main CPU 101 updates the symbol counter of the corresponding reel by the number of sliding pieces. Then, the main CPU 101 waits until the updated symbol counter matches the value corresponding to the expected stop position (the symbol at the expected stop position reaches an area on the active line of the display window), and then waits for the corresponding reel. The driving of the corresponding stepping motor is controlled so that the rotation is decelerated and stopped.

  Next, the main CPU 101 performs a communication data transmission process (S904). In this process, various commands stored in the communication data storage area are mainly transmitted to the sub-control circuit 200 via the first serial communication circuit 114 of the main control circuit 90 (see FIG. 9). After transmitting the command to the sub control circuit 200, the main CPU 101 decrements and updates the communication data pointer by one packet (not shown), and clears the transmitted command data in the communication data storage area. When a plurality of command data are stored in the communication data storage area, the command data is transmitted to the sub-control circuit 200 in the order of the stored command data. If no command data is stored in the communication data storage area, that is, if the value of the communication data pointer is “0”, a no-operation command is generated and transmitted to the sub-control circuit 200. Next, the main CPU 101 performs an inserted medal passing check process (S905). In this process, the main CPU 101 checks whether or not the inserted medal has passed the selector 66 based on the detection result (medal sensor input state) of the medal sensor (not shown). Next, the main CPU 101 performs a WDT restart process (S906).

  Next, the main CPU 101 performs a 7-segment LED driving process (S907). In this process, the main CPU 101 drives and controls various 7-segment LEDs included in the information display 6 to display, for example, the number of paid-out medals, the number of credits, and the pressing order data of the stop button. The details of the 7-segment LED driving process will be described later with reference to FIG. 159 described later.

  Next, the main CPU 101 performs a timer update process (S908). In this process, the main CPU 101 performs a count (subtraction) process of the set various timers. The details of the timer update process will be described later with reference to FIG. 164 described later.

  Next, the main CPU 101 performs an error detection process (S909). Next, the main CPU 101 performs a door open / close check process (S910). In the door open / close check process, the main CPU 101 checks the open / close state of the front door 2b (see FIG. 2) by checking the ON (door closed) / OFF (door open) state of the door open / close monitoring switch 67.

  Next, the main CPU 101 performs a trial test signal control process (S911). In this process, a control process for outputting various test signals to the tester via the second interface boat or the like is performed. This process is performed using a non-defined work area of the main RAM 103 (see FIG. 12C). In the present embodiment, this processing is also performed at a time other than the time of the test firing test (after the pachislot 1 is installed in the game store), but at this time, the main control board 71 is connected via the second interface boat or the like. Since it is not connected to a tester, various test signals are generated but not output. Details of the test shooting test signal control processing will be described later with reference to FIG. 166 described later.

  Next, the main CPU 101 performs a register restoration process (S912). Then, after the processing of S912, the main CPU 101 ends the interrupt processing.

[7-segment LED drive processing]
Next, with reference to FIG. 159 and FIG. 160, the 7-segment LED driving process performed in S907 during the interrupt process (see FIG. 158) will be described. FIG. 159 is a flowchart showing the procedure of the 7-segment LED driving process. FIG. 160A is a diagram illustrating an example of a source program for executing processes of S923 to S925 described later during the 7-segment LED driving process, and FIG. 160B is a diagram illustrating an example of a source program described later during the 7-segment LED driving process. FIG. 14 is a diagram illustrating an example of a source program for executing the process of S936.

  First, the main CPU 101 adds (1) to the value of the interrupt counter (+1 update) (S921). Next, the main CPU 101 determines whether or not the value of the interrupt counter is an odd number (S922).

  In S922, when the main CPU 101 determines that the value of the interrupt counter is not an odd number (if S922 is NO), the main CPU 101 ends the 7-segment LED driving process and proceeds to the interrupt process (see FIG. 158). The processing moves to the processing of S908 in the step ()). That is, in the present embodiment, the 7-segment LED driving process is performed every two interrupt cycles. In the present embodiment, an example has been described in which the 7-segment LED driving process is executed when the value of the interrupt counter is an even number. However, the present invention is not limited to this. The LED drive processing may be executed, or the execution timing of the 7-segment LED drive processing may be determined using a quotient or remainder obtained by dividing the value of the interrupt counter by an arbitrary integer.

  On the other hand, in S922, when the main CPU 101 determines that the value of the interrupt counter is an odd number (if S922 is YES), the main CPU 101 acquires navigation data from the navigation data storage area (S923). Next, the main CPU 101 sets the address of the push order display data storage area for storing the push order display data output to each cathode of the 7-segment LED (S924).

  Next, the main CPU 101 performs a 7-segment display data generation process (S925). In this process, the main CPU 101 creates push order display data (7-segment display data) based on the navigation data, and stores the generated push order display data in the push order display data storage area. The details of the 7-segment display data generation processing will be described later with reference to FIG. 161 described later.

  Next, the main CPU 101 acquires the value of the credit counter (S926). Next, the main CPU 101 sets an address of a credit display data storage area for storing credit display data output to each cathode of the 7-segment LED (S927).

  Next, the main CPU 101 performs a 7-segment display data generation process (S928). In this process, the main CPU 101 generates credit display data (7-segment display data) based on the value of the credit counter, and stores the generated credit display data in the credit display data storage area. The details of the 7-segment display data generation processing will be described later with reference to FIG. 161 described later.

  Next, the main CPU 101 sets an address of a 7-segment common counter storage area for storing a value of a 7-segment common counter described later (S929). Next, the main CPU 101 adds (1) to the value of the 7-segment common counter (+1 update) (S930). In this process, when the updated value of the 7-segment common counter becomes “8”, the main CPU 101 sets the value of the 7-segment common counter to “0”. In the present embodiment, in order to dynamically control the 7-segment LED, the value of the 7-segment common counter is updated every eight times.

  Next, the main CPU 101 creates common selection data based on the value of the 7-segment common counter, and addresses the target cathode data storage area (the target storage area in the push order display data storage area or the credit display data storage area). Is set (S931). Next, the main CPU 101 outputs the clear data to the cathode of the 7-segment LED (S932). This process is performed to turn off the 7-segment LED once and eliminate the influence of the afterimage.

  Next, the main CPU 101 acquires and sets 7-segment cathode output data from the target cathode data storage area (S933). Next, the main CPU 101 generates 7-segment common output data from the 7-segment common backup data and the common selection data (S934).

  Next, the main CPU 101 stores the 7-segment common output data and the 7-segment cathode output data in the 7-segment common backup data and the 7-segment cathode backup data, respectively (S935). Next, the main CPU 101 outputs 7-segment cathode output data and 7-segment common output data (S936). Then, after the processing of S936, the main CPU 101 ends the 7-segment LED driving processing, and shifts the processing to the processing of S908 in the interrupt processing (see FIG. 158).

  In the present embodiment, the 7-segment LED driving process is performed as described above. The processing of S923 to S925 during the above-described 7-segment LED driving processing is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 160A. Further, the processing of S931 to S936 in the above-described 7-segment LED driving processing is performed by the main CPU 101 sequentially executing each source code defined by the source program of FIG. 160B.

  Among them, the output process of each 7-segment output data in S936 is executed by one source code “LD (cPA_SEGCOM), BC” as shown in FIG. 160B. Therefore, in the 7-segment LED driving process of the present embodiment, 7-segment common output (selection) data and 7-segment cathode output data are output simultaneously when performing dynamic lighting control of the 2-digit 7-segment LED. In other words, in the 7-segment LED dynamic lighting control when performing the push order navigation on the instruction monitor and the 7-segment LED dynamic lighting control when displaying the credit information with the 2-digit 7-segment LED, the 7-segment common output ( Selection) data and 7-segment cathode output data are output simultaneously.

  In this case, the number of instruction codes required for the dynamic lighting control of the 7-segment LED on the source program can be reduced. Therefore, in the present embodiment, the capacity of the source program (the used capacity of the main ROM 102) can be reduced, the free space in the main ROM 102 can be secured (increased), and the increased free space is utilized. As a result, it is possible to enhance the playability. Further, in the present embodiment, an example in which the 7-segment driving circuit (not shown) for performing the 7-segment LED driving process is configured by the cathode common circuit and controlled by the cathode has been described, but the present invention is not limited to this. The seg drive circuit may be configured by an anode common circuit, and the 7-segment LED may be controlled by the anode.

  As shown in FIG. 160A, both the navigation data acquisition process in S923 and the address setting process in the push display data storage area in S924 during the 7-segment LED driving process described above use the Q register (extension register). This is executed by an “LDQ” command (command code dedicated to the main CPU 101) for specifying an address. Therefore, in the 7-segment LED driving process of the present embodiment, the main ROM 102, the main RAM 103, and the memory map I / O can be accessed by a direct value by using the “LDQ” instruction. In addition, it is possible to omit the command related to the address setting (there is no need to separately provide the command related to the address setting), and accordingly, the capacity of the source program (the used capacity of the main ROM 102) can be reduced. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[7-segment display data generation processing]
Next, the 7-segment display data generation processing performed in S925 and S928 during the 7-segment LED drive processing (see FIG. 159) will be described with reference to FIGS. FIG. 161 is a flowchart illustrating the procedure of the 7-segment display data generation process. FIG. 162 is a diagram illustrating an example of a source program for executing the 7-segment display data generation process. FIG. 163 is a diagram illustrating an example of the configuration of a 7-segment cathode table that is actually referred to on a source program for 7-segment display data generation processing.

  Note that “display data” described later generated in the 7-segment display data generation processing performed in S925 during the 7-segment LED driving processing (see FIG. 159) corresponds to the pressing order display data, and the 7-segment LED driving processing (see FIG. 159). 159) during the 7-segment display data generation process performed in S928 corresponds to the credit display data.

  First, the main CPU 101 divides the display data set in the cathode data storage area by “10”, obtains the quotient value of the division result as the display data of the upper digit of the 2-digit 7-segment LED, and divides it. The remaining value of the result is acquired as the lower digit display data (S941). Next, the main CPU 101 determines whether or not to perform upper digit display based on the acquired upper digit display data (S942).

  In S942, when the main CPU 101 determines that the upper digit display is to be performed (YES in S942), the main CPU 101 performs the process of S944 described later. On the other hand, in S942, when the main CPU 101 determines that upper digit display is not to be performed (NO in S942), the main CPU 101 sets no display of upper digit (S943).

  After the process of S943 or when the determination of S942 is YES, the main CPU 101 refers to the 7-segment cathode table (refer to FIG. 163) and acquires the display data of the upper digit (S944). Next, the main CPU 101 stores the acquired upper digit display data in the upper digit display data storage area (not shown) (S945).

  Next, the main CPU 101 refers to the 7-segment cathode table (refer to FIG. 163) and acquires the display data of the lower digit (S946). Next, the main CPU 101 stores the acquired lower digit display data in a lower digit display data storage area (not shown) (S947).

  Then, after the processing of S947, the main CPU 101 ends the 7-segment display data generation processing. At this time, if the executed 7-segment display data generation processing is the processing of S925 in the 7-segment LED driving processing (see FIG. 158), the main CPU 101 replaces the processing with the processing of S926 in the 7-segment LED driving processing. Move. On the other hand, if the executed 7-segment display data generation process is the process of S928 in the 7-segment LED driving process (see FIG. 158), the main CPU 101 shifts the process to the process of S929 in the 7-segment LED driving process. .

  In the present embodiment, the 7-segment display data generation processing is performed as described above. The above-described 7-segment display data generation processing is performed by the main CPU 101 sequentially executing each source code defined by the source program in FIG.

[Timer update process]
Next, with reference to FIGS. 164 and 165, a description will be given of the timer update process performed in S908 during the interrupt process (see FIG. 158). FIG. 164 is a flowchart illustrating the procedure of the timer update process. FIG. 165 is a diagram illustrating an example of a source program for executing processes of S951 to S954 described later during the timer update process.

  First, the main CPU 101 sets the update start address of the 2-byte timer storage area (not shown) in the HL register, and sets the 2-byte timer number in the B register (S951).

  Next, the main CPU 101 compares the number of 2-byte timers with its lower limit “0”, and if the number of 2-byte timers is larger than the lower limit “0”, subtracts 1 from the number of 2-byte timers (-1 update). If the number of 2-byte timers is equal to or smaller than the lower limit “0”, the number of 2-byte timers is held at “0” (S952). Further, in the process of S952, the main CPU 101 subtracts 2 (-2 updates) from the update start address of the 2-byte timer storage area set in the HL register.

  Next, the main CPU 101 subtracts 1 (-1 update) from the 2-byte timer number set in the B register (S953). Next, the main CPU 101 determines whether or not the 2-byte timer number set in the B register is “0” (S954).

  In S954, when the main CPU 101 determines that the number of 2-byte timers set in the B register is not “0” (NO in S954), the main CPU 101 returns the process to the process of S952, and returns to S952 and subsequent steps. Repeat the process.

  On the other hand, in S954, when the main CPU 101 determines that the number of 2-byte timers set in the B register is “0” (if S954 is YES), the main CPU 101 stores the 1-byte timer storage area in the HL register. Is set, and the number of 1-byte timers is set in the B register (S955).

  Next, the main CPU 101 compares the number of 1-byte timers with its lower limit "0", and if the number of 1-byte timers is larger than the lower limit "0", subtracts 1 from the number of 1-byte timers (-1 update). If the one-byte timer number is equal to or smaller than the lower limit value “0”, the one-byte timer number is held at “0” (S956). Further, in the processing of S956, the main CPU 101 subtracts 1 (-1 update) from the update start address of the 1-byte timer storage area set in the HL register.

  Next, the main CPU 101 subtracts 1 (updates -1) from the 1-byte timer number set in the B register (S957). Next, the main CPU 101 determines whether or not the one-byte timer number set in the B register is “0” (S958).

  In S958, when the main CPU 101 determines that the number of 1-byte timers set in the B register is not “0” (if S958 is NO), the main CPU 101 returns the process to the process of S956, and returns to S956. Repeat the process.

  On the other hand, in S958, when the main CPU 101 determines that the number of 1-byte timers set in the B register is “0” (if S958 is YES), the main CPU 101 performs an electromagnetic counter control process (S959). ). In this process, an output control process for outputting a signal indicating IN / OUT of medals to the external centralized terminal board 47 is performed. Then, after the processing of S959, the main CPU 101 ends the timer update processing, and shifts the processing to the processing of S909 in the interrupt processing (see FIG. 158).

  In the present embodiment, the timer update processing is performed as described above. The processing of S951 to S954 during the timer update processing (update processing of the 2-byte timer) is performed by the main CPU 101 sequentially executing each source code defined in the source program of FIG. 165.

  Among them, the process of S952 (update process of the 2-byte timer) is executed by the “DCPWLD” command (predetermined update command) in FIG. The “DCPWLD” instruction is an instruction code dedicated to the main CPU 101.

  When, for example, the source code “DCPWLD (HL), n” is executed on the source program, the contents of the memory (storage data) of 2 bytes from the address specified by the HL register and the integer n are compared, If the contents of the 2-byte memory are larger than the integer n, the content of the 2-byte memory is decremented by 1. If the contents of the 2-byte memory are smaller than the integer n, they are designated by the HL register. The integer n is stored in a 2-byte memory from the address.

  Therefore, in the source code “DCPWLD (HL), 0” in FIG. 165, the contents of the memory of 2 bytes (the number of 2-byte timers) and the integer “0” (lower limit) from the address specified by the HL register are obtained. Is compared, if the contents of the 2-byte memory is greater than the integer "0", the content of the 2-byte memory is subtracted by 1, and if the contents of the 2-byte memory are less than or equal to the integer "0" Is set to "0" in the contents of the memory for 2 bytes. That is, if the current number of 2-byte timers is larger than “0”, the update processing of the 2-byte timer is performed. If the current number of 2-byte timers is “0” or less, the 2-byte timer number is set to “0”. Is held.

  As described above, in the timer update processing of the present embodiment, both the update (subtraction) of the number of timers and the processing of holding the number of timers at “0” are executed by the “DCPWLD” instruction which is an instruction code dedicated to the main CPU 101. can do. In this case, there is no need to provide instruction codes for executing both processes separately. Further, a judgment branch instruction code for judging whether or not the number of timers is “0” can be omitted. Therefore, in the present embodiment, the capacity of the source program (the used capacity of the main ROM 102) can be reduced, the free space in the main ROM 102 can be secured (increased), and the increased free space is utilized. As a result, it is possible to enhance the playability. In the present embodiment, an example has been described in which the “DCPWLD” instruction is used only in the update processing of the 2-byte timer. However, the present invention is not limited to this, and the “DCPWLD” instruction is also used in the update processing of the 1-byte timer. May be used.

[Testing test signal control processing (unspecified)]
Next, with reference to FIG. 166, a description will be given of the test-shot test signal control process performed in S911 during the interrupt process (see FIG. 158). FIG. 166 is a flowchart showing the procedure of the test shooting test signal control process.

  First, the main CPU 101 saves the address of the stack area of the main RAM 103 (S961). Next, the main CPU 101 sets the address of the non-defined stack area in the stack pointer (SP) (S962). Next, the main CPU 101 saves the data of all the registers (S963).

  Next, the main CPU 101 performs a torso braking signal generation process (S964). In this process, the main CPU 101 generates and outputs a rotation control signal (drive signal) for each reel, which is output to the tester via the second interface boat or the like. The details of the torso braking signal generation processing will be described later with reference to FIG. 167 described later.

  Next, the main CPU 101 performs a special prize signal control process (S965). In this process, the main CPU 101 performs a process of outputting a bonus (special award) ON / OFF signal (test signal) output to the tester. The details of the special prize signal control processing will be described later with reference to FIG. 168 described later.

  Next, the main CPU 101 performs a condition device signal control process (S966). In this process, the main CPU 101 performs a process of outputting a control signal corresponding to the state of the condition device signal control flag. The details of the condition device signal control process will be described later with reference to FIGS. 169 and 170 described later.

  Next, the main CPU 101 performs a process of restoring the data of all registers saved in the process of S963 (S967). Next, the main CPU 101 sets the address of the stack area saved in the process of S961 in the stack pointer (SP) (S968). Then, after the processing of S968, the main CPU 101 ends the test shooting test signal control processing, and shifts the processing to the processing of S912 in the interrupt processing (see FIG. 158).

[Circuit braking signal generation processing]
Next, with reference to FIG. 167, a description will be given of the turning drum braking signal generation processing performed in S964 in the trial shooting test signal control processing (see FIG. 166). FIG. 167 is a flowchart illustrating the procedure of the turning drum braking signal generation processing.

  First, the main CPU 101 sets a rotation control data storage area (not shown) in the non-defined work area (S971). Next, the main CPU 101 sets the number of reels to “3”, and clears the spinneret control signal and its generation state (1 byte data) (S972).

  Next, the main CPU 101 determines whether or not the rotation control data is data of “less than stopped” (S973). Here, the rotation control data of “less than stop” is the rotation control data other than the rotation control data for stopping the reel, that is, the rotation control data (rotation control data for rotating the reel). Preparation, accelerating, waiting at constant speed, waiting at constant speed, and waiting for stop start position).

  In S973, when the main CPU 101 determines that the spine control data is data of “less than stopped” (if S973 is YES), the main CPU 101 performs the process of S975 described later. On the other hand, in S973, when the main CPU 101 determines that the turning body control data is not data of “less than stopped” (NO in S973), the main CPU 101 determines that the turning body control data is “Static hold control end”. Is determined (S974). Here, the turning control data of “end of static set hold control” is turning control data indicating a state in which all phases of the reel are completely stopped.

  In S974, when the main CPU 101 determines that the torso control data is the data of "end of static set hold control" (if S974 is YES), the main CPU 101 performs the process of S976 described later. On the other hand, in S974, when the main CPU 101 determines that the turning body control data is not the data of “end of static set hold control” (if S974 is NO), or if S973 is YES, the main CPU 101 The bit 3 of the generation state (1 byte data) of the turning body control signal is turned on ("1") (S975).

  After the process in S975 or in the case of NO in S974, the main CPU 101 shifts the data of each bit in the generated state by one bit to the right (in the direction from bit 7 to bit 0) (S976). Next, the main CPU 101 updates the address of the rotation control data storage area to the address of the next reel to be controlled (S977).

  Next, the main CPU 101 subtracts one from the number of reels (S978). Next, the main CPU 101 determines whether or not the number of reels is “0” (S979).

  In S979, when the main CPU 101 determines that the number of reels is not “0” (if S979 is NO), the main CPU 101 returns the processing to the processing of S973, and repeats the processing from S973.

  On the other hand, in S979, when the main CPU 101 determines that the number of reels is “0” (if S979 is YES), the main CPU 101 tests the data in the generated state via the spine brake signal output port. The data is output to the first interface board for machine 301 (see FIG. 7) (S980). Then, after the processing of S980, the main CPU 101 ends the torso braking signal generation processing, and shifts the processing to the processing of S965 in the test shot test signal control processing (see FIG. 166).

[Grand prize signal control processing]
Next, with reference to FIG. 168, a description will be given of the special prize signal control processing performed in S965 in the trial test signal control processing (see FIG. 166). FIG. 168 is a flowchart showing the procedure of the special prize signal control process.

  First, the main CPU 101 acquires a game state flag with reference to the game state flag storage area (see FIG. 32) (S991). Next, the main CPU 101 determines whether or not the gaming state is the RB gaming state (S992).

  In S992, when the main CPU 101 determines that the gaming state is the RB gaming state (if S992 is YES), the main CPU 101 sends the ON signal from the RB signal port for the test signal to the first interface for the tester. The data is output to the board 301 (see FIG. 7) (S993). On the other hand, in S992, when the main CPU 101 determines that the gaming state is not the RB gaming state (if S992 is NO), the main CPU 101 outputs the OFF signal from the RB signal port for the test signal to the first tester. The data is output to the interface board 301 (see FIG. 7) (S994).

  After the processing in S993 or S994, the main CPU 101 determines whether the gaming state is the BB gaming state with reference to the gaming state flag storage area (see FIG. 32) (S995).

  In S995, when the main CPU 101 determines that the gaming state is the BB gaming state (if S995 is YES), the main CPU 101 sends the ON signal from the BB signal port for the test signal to the first interface for the tester. The data is output to the board 301 (see FIG. 7) (S996). On the other hand, in S995, when the main CPU 101 determines that the gaming state is not the BB gaming state (if S995 is NO), the main CPU 101 outputs an OFF signal from the BB signal port for the test signal to the first testing machine. The data is output to the interface board 301 (see FIG. 7) (S997).

  Then, after the processing of S996 or S997, the main CPU 101 ends the special prize signal control processing, and shifts the processing to the processing of S966 in the trial test signal control processing (see FIG. 166).

[Conditioner signal control processing]
Next, with reference to FIG. 169 and FIG. 170, the condition device signal control processing performed in S966 in the test firing test signal control processing (see FIG. 166) will be described. 169 and 170 are flowcharts illustrating the procedure of the condition device signal control process.

  First, the main CPU 101 determines whether or not the condition device signal control flag is in an initial state (S1001). In S1001, when the main CPU 101 determines that the condition device signal control flag is in the initial state (if S1001 is YES), the main CPU 101 ends the condition device signal control process, and executes the test test signal control process. The process proceeds to S967 in (see FIG. 166).

  On the other hand, when the main CPU 101 determines in S1001 that the condition device signal control flag is not in the initial state (if S1001 is NO), the main CPU 101 sets the condition device signal control flag to the ON state of the re-game state identification signal. It is determined whether or not the information is indicated (S1002).

  In S1002, when the main CPU 101 determines that the condition device signal control flag indicates the ON state of the replaying state identification signal (when S1002 is YES), the main CPU 101 plays a role in the condition device signal control state. The ON state of the object condition device signal is set (S1003). Next, the main CPU 101 outputs the information of the RT state from the condition device 1 to 6 signal ports to the first interface board 301 for test machine (see FIG. 7) (S1004). Then, after the processing of S1004, the main CPU 101 ends the condition device signal control processing, and shifts the processing to the processing of S967 in the trial test signal control processing (see FIG. 166).

  On the other hand, in S1002, when the main CPU 101 determines that the condition device signal control flag does not indicate the ON state of the replaying state identification signal (NO in S1002), the main CPU 101 determines that the condition device signal control flag is not ON. It is determined whether or not the signal indicates the off state of the re-game state identification signal (S1005).

  In S1005, when the main CPU 101 determines that the condition device signal control flag indicates the off state of the replaying state identification signal (if S1005 is YES), the main CPU 101 sets the condition device 1 to 8 signal ports. Output an OFF signal to the first interface board for a tester 301 (see FIG. 7) (S1006). Then, after the processing of S1006, the main CPU 101 ends the condition device signal control processing, and shifts the processing to the processing of S967 in the test shot test signal control processing (see FIG. 166).

  On the other hand, in S1005, when the main CPU 101 determines that the condition device signal control flag does not indicate the off state of the replaying state identification signal (NO in S1005), the main CPU 101 sets the condition device signal control state to “OFF”. It is determined whether or not the accessory condition device signal is on (S1007).

  In S1007, when the main CPU 101 determines that the condition device signal control state is the ON state of the accessory condition device signal (YES in S1007), the main CPU 101 receives a special prize from the condition device 1 to 8 signal ports. The number information is output to the first interface board 301 for test equipment (see FIG. 7), and at this time, an ON signal is output from the signal port of the conditioner 8 to the first interface board 301 for test equipment (see FIG. 7) ( S1008). Next, the main CPU 101 sets a predetermined waiting time (24.58 ms in the present embodiment) in a condition device signal output waiting timer (S1009). Next, the main CPU 101 sets a condition device signal output wait state to the condition device signal control state (S1010). Then, after the processing in S1010, the main CPU 101 ends the condition device signal control processing, and shifts the processing to the processing in S967 in the trial test signal control processing (see FIG. 166).

  On the other hand, in S1007, when the main CPU 101 determines that the condition device signal control state is not the ON state of the accessory condition device signal (NO in S1007), the main CPU 101 sets the condition device signal control state to the condition device signal. It is determined whether it is in the output waiting state (S1011).

  In S1011, when the main CPU 101 determines that the condition device signal control state is the condition device signal output waiting state (if S1011 is YES), the main CPU 101 sets the value of the condition device signal output wait timer to “0”. Is determined (S1012).

  In S1012, when the main CPU 101 determines that the value of the condition device signal output waiting timer is not “0” (if S1012 is NO), the main CPU 101 ends the condition device signal control process, and executes the test shot test. The process proceeds to S967 in the signal control process (see FIG. 166). On the other hand, in S1012, when the main CPU 101 determines that the value of the condition device signal output waiting timer is “0” (if S1012 is YES), the main CPU 101 sets the condition device signal control state to the small combination condition device. The on state of the signal or the off state of the condition device signal is set (S1013). Then, after the processing in S1013, the main CPU 101 ends the condition device signal control processing, and shifts the processing to the processing in S967 in the trial test signal control processing (see FIG. 166).

  Here, returning to the process of S1011 again, when the main CPU 101 determines in S1011 that the condition device signal control state is not the condition device signal output waiting state (in the case of NO determination in S1011), the main CPU 101 It is determined whether the device signal control state is the ON state of the small combination condition device signal (S1014).

  In S1014, when the main CPU 101 determines that the condition device signal control state is the ON state of the small combination condition device signal (YES in S1014), the main CPU 101 transmits the small combination signal from the condition device 1 to 8 signal ports. The information of the winning number is output to the first interface board 301 for the testing machine (see FIG. 7), and at this time, an ON signal is output from the signal port of the conditioner 7 to the first interface board 301 for the testing machine (see FIG. 7). (S1015). Next, a predetermined waiting time (24.58 ms in this embodiment) is set in the condition device signal output waiting timer (S1016). Next, the main CPU 101 sets a condition device signal output wait state to the condition device signal control state (S1017). Then, after the processing of S1017, the main CPU 101 ends the condition device signal control processing, and shifts the processing to the processing of S967 in the test shot test signal control processing (see FIG. 166).

  On the other hand, in S1014, when the main CPU 101 determines that the condition device signal control state is not the ON state of the small combination condition device signal (NO in S1014), the main CPU 101 turns OFF the condition device 1 to 8 signal ports. The signal is output to the tester first interface board 301 (see FIG. 7) (S1018). Then, after the processing of S1018, the main CPU 101 ends the condition device signal control processing, and shifts the processing to the processing of S967 in the test shot test signal control processing (see FIG. 166).

<Description of operation of sub-control circuit>
Next, the contents of various processes executed by the sub CPU 201 of the sub control circuit 200 using a program will be described with reference to FIGS.

[Sub side navigation control processing]
First, the sub navigation control process will be described with reference to FIG. FIG. 171 is a flowchart illustrating the procedure of the sub navigation control process.

  First, the sub CPU 201 determines whether or not navigation data has been acquired (S1101). The sub CPU 201 acquires the navigation data determined by the main control board 71 from the start command data received from the main control board 71. Therefore, in the process of S1101, the sub CPU 201 determines whether or not the received start command data includes navigation data.

  In S1101, when the sub CPU 201 determines that the navigation data has been acquired (YES in S1101), the sub CPU 201 sets the sub navigation data according to the navigation data (S1102). For example, when the sub CPU 201 acquires the navigation data “4”, as shown in FIG. 63, the navigation data for notifying the pressing order “left, middle, right” as the sub navigation data is set in this processing. You. As a result, the content of the stop operation can be notified on both the main side and the sub side. After the processing in S1102, the sub CPU 201 ends the sub navigation control processing.

  On the other hand, in S1101, when the sub CPU 201 determines that the navigation data has not been acquired (NO in S1101), the sub CPU 201 determines whether or not the navigation (notification of the stop operation) is necessary. (S1103). In the present embodiment, the sub CPU 201 needs to navigate, for example, when a flag conversion lottery is performed on the main control board 71 or when a predetermined combination is determined as an internal winning combination on the main control board 71. Is determined. The result of the flag conversion lottery and the type of the internal winning combination are included in the start command data. Therefore, in the processing of S1103, the sub CPU 201 determines whether or not the navigation is necessary based on these various information included in the start command data.

  In step S1103, when the sub CPU 201 determines that the navigation is not necessary (NO in step S1103), the sub CPU 201 ends the sub navigation control process.

  On the other hand, in S1103, when the sub CPU 201 determines that the navigation is necessary (YES in S1103), the sub CPU 201 sets the sub side navigation data according to various lottery results (S1104). For example, when the internal winning combination “F_Sure Chill Lip” has been determined and the flag conversion lottery has been won, the sub CPU 201 in this process uses the navigation for displaying the symbol combination related to the abbreviation “Triple Chill Lip”. Set data (for example, navigation data for aiming at Chilean symbols by pushing in order). In addition, for example, when the internal winning combination “F_Sure Clip Rep” is determined and the flag conversion lottery is not won, the sub CPU 201 in this process displays the symbol combination related to the abbreviation “Replay”. The navigation data (for example, navigation data indicating a pressing order other than the forward pressing) is set. By these processes, even when the main side does not report the content of the stop operation, the sub side alone can report the content of the stop operation. Then, after the processing of S1104, the sub CPU 201 ends the sub navigation control processing.

[Player registration process]
Next, the player registration processing will be described with reference to FIG. FIG. 172 is a flowchart showing the procedure of the player registration process.

  First, the sub CPU 201 determines whether a registration operation has been received (S1111). For example, when an operation of the registration button 222b is received on the menu screen 222 (see FIG. 5B) of the sub display device 18 and a predetermined operation is received on a registration screen (not shown) displayed in that case, the sub CPU 201 starts the registration operation. Is determined to be accepted.

  When the sub CPU 201 determines in S1111 that the registration operation has been received (YES in S1111), the sub CPU 201 sets a player registration state (S1112). In a situation where the player registration state is set, the sub CPU 201 controls the sub display device 18 so that the game information screens 223, 224, and 225 (see FIGS. 5C to 5E) can be displayed on the sub display device 18. Control the display screen. Then, after the processing of S1112, the sub CPU 201 ends the player registration processing.

  On the other hand, when the sub CPU 201 determines in S1111 that the registration operation has not been received (NO in S1111), the sub CPU 201 determines whether a registration deletion operation has been received (S1113). For example, when a specific operation is received on the registration screen of the sub display device 18, the sub CPU 201 determines that a registration deletion operation has been received.

  In S1113, when the sub CPU 201 determines that the registration deletion operation has not been received (NO in S1113), the sub CPU 201 ends the player registration process.

  On the other hand, in S1113, when the sub CPU 201 determines that the registration deletion operation has been received (YES in S1113), the sub CPU 201 clears the player registration state (S1114). In the situation where the player registration state is cleared, the sub CPU 201 sets the sub display device 18 so that the game information screens 223, 224, and 225 (see FIGS. 5C to 5E) cannot be displayed on the sub display device 18. To control the display screen. Then, after the processing of S1114, the sub CPU 201 ends the player registration processing.

[History management processing]
Next, the history management process will be described with reference to FIG. FIG. 173 is a flowchart illustrating the procedure of the history management process.

  First, the sub CPU 201 acquires a game result from various command data received from the main control board 71 (S1121). For example, in this processing, the sub CPU 201 can grasp the type of the combination determined as the internal winning combination from the start command data. Also, for example, in this process, the sub CPU 201 can grasp the symbol combination displayed from the winning operation command data (that is, whether or not the winning combination determined as the internal winning combination has won). Further, for example, in this process, the sub CPU 201 can grasp the current gaming state and the transition state of the gaming state from the start command data and the like.

  Next, the sub CPU 201 performs a game history update process based on the acquired game result (S1122). By this processing, the sub CPU 201, for example, based on the game results acquired from the various command data, for example, the number of bonuses, the number of ARTs, the number of games (the number of games), the number of CZs, the number of CZ successes, the number of winning combinations, and the number of winnings Various game histories such as probabilities can be managed. Then, after the processing of S1122, the sub CPU 201 ends the history management processing.

<Various effects>
In the pachislo 1 of the present embodiment, the following various effects can be obtained in the playability.

[Management of duration during CT]
In the pachislot 1 of the present embodiment, a CT is provided as an additional chance zone in which the duration of the normal ART can be extended, and the number of ART games is increased based on the internal winning combination (sub flag) during the CT. In the CT, eight games are played per set. However, if the number of ART games can be increased during the CT, the number of games is not reduced, and the number of games is reduced only when the number of games cannot be increased. Subtract. Therefore, from the viewpoint of the player, it is not known how long the CT will last, and the CT will not be terminated as long as the addition is performed, so that the interest in the game during the CT can be enhanced.

  Further, in the present embodiment, when the sub flag EX “triple lip lip” is won during CT (sub-flag conversion lottery) and added, the CT game of one set eight times is also reset (stock). Is done. In this case, for example, even if the game period of CT is just before the end, when the sub-flag EX “triple chili lip” is won, an addition is performed and the CT is restarted from the beginning. It is possible to continue the game without getting bored and to enhance the interest of the game during CT.

  Further, the addition at the time of winning the sub-flag EX “triple chili lip” is performed only when the internal winning combination “F_probable chili lip” or “F_1 probable chili lip” is determined as the internal winning combination and the flag conversion lottery is won. . Therefore, it is possible to prevent the player from giving excessive profit, and to balance the profit between the player and the game store. In the above-described embodiment, an example has been described in which the flag conversion lottery is always won when the internal winning combination “F_Probable Chililip” or “F_1 Probable Chililip” is determined during CT (see FIG. 54). The present invention is not limited to this, and the winning probability of the flag conversion lottery can be set as appropriate according to the balance of the profit between the player and the game store.

[Number of additional games at the time of winning "triple chili lip" during CT]
In the pachislot 1 of the above-described embodiment, the sub-flag “Triple Chili Lip” is won during the CT, and if the number of times of addition based on the sub-flag “Triple Chili Lip” exceeds a predetermined number, one additional lottery is performed. The number of additional games to be won is increased (see FIG. 55). As described above, as long as the number of ART games is added, the CT is not terminated, and the CT is reset when the sub-flag EX “Three consecutive chips” is won. Therefore, the player can expect that the additional amount per game (one game) increases as the CT continues, and the interest during the CT improves. Further, the number of times that the additional amount per game (one game) is increased is more (9 or more) than the number of basic games (8) for one set of CT. It is possible to prevent giving excessive profits, and to balance (maintain good) profits between the player and the game store.

[Bonus notification on the main side]
In the pachislo 1 of the above embodiment, the numerical value “10” uniquely associated with the information of the stop operation for displaying the symbol combination related to the bonus combination (BB combination) on the instruction monitor (not shown) of the information display 6. (Or "11"), a bonus notification is made on the main side (see FIG. 63). However, usually, in the pachislot, the priority of the symbol drawn (stopped) on the activated line is determined, and when the bonus combination and other combinations are determined as an internal winning combination, the priority is set. Therefore, the symbol combination related to the bonus combination may be withdrawn, or may not be withdrawn.

  For example, in the pachislot 1 of the present embodiment, the bonus combination and any one of the internal winning combination “outside”, “F_special combination 1”, “F_special combination 2” and “F_special combination 3” are determined. In this case, the symbol combination relating to the bonus combination can be drawn in. However, the bonus combination and the internal winning combination “outside”, “F_special combination 1”, “F_special combination 2”, and “F_special combination 3” If a combination other than the winning combination is determined, the symbol combination related to the bonus combination cannot be drawn. Therefore, in the present embodiment, the bonus combination and any one of the internal winning combination “outside”, “F_special combination 1”, “F_special combination 2”, and “F_special combination 3” are determined. Only in this case, a numerical value “10” (or “11”) is displayed on the instruction monitor. In this case, navigation on the main side (bonus notification) can be performed at an appropriate timing at which a bonus combination can be won.

  Further, in the pachislot 1 of the present embodiment, the bonus combination and any one of the internal winning combination “outside”, “F_special combination 1”, “F_special combination 2” and “F_special combination 3” are determined. Even if a predetermined number of games have elapsed since the first winning of the bonus combination, the numerical value “10” (or “11”) is not displayed on the instruction monitor (without navigating), and On the condition that the game has elapsed, a numerical value “10” (or “11”) is displayed on the instruction monitor.

  For example, when an effect (so-called continuous effect) that is performed over a plurality of games triggered by the winning of the bonus combination is performed, the numeric value “10” (or “ When 11)) is displayed, the meaning of the continuous production is lost, and there is a possibility that interest may be spoiled. Therefore, in the pachislo 1 of the present embodiment, the display by the instruction monitor is not performed until the predetermined number of games has elapsed, and the display by the instruction monitor is performed after the predetermined number of games has elapsed. As a result, it is possible to notify the bonus on the main side without impairing the effect of the effect.

[Notification performed on both the main and sub sides and notification performed on the sub side alone]
In the pachislo 1 of the present embodiment, a plurality of combinations with different symbol combinations displayed according to the mode of the stop operation (push order) are provided (see FIG. 24). Roles in which different benefits are provided depending on the combination and roles in which the same benefit is provided even when the displayed symbol combinations are different are included.

  For example, the number of medals to be paid out differs between the case where the symbol combination related to the abbreviation "bell" is displayed and the case where the symbol combination related to the abbreviation "bell spilled eyes" is displayed. It is a role in which different benefits are given depending on the combination. In addition, when the symbol combination according to the abbreviation “Replay” is displayed and when the symbol combination according to the abbreviation “RT2 transition lip” is displayed, whether or not the RT state transition is performed in addition to the operation of the replay. Are different, the internal winning combination “F_3 selection bell_1st” and “F_maintenance lip_1st” are also combinations where different privileges are given depending on the displayed symbol combination.

  On the other hand, when the symbol combination according to the abbreviation "Triple Chili Lip" is displayed and when the symbol combination according to the abbreviation "Replay" is displayed, only the replay operation is performed. Therefore, the internal winning combination “F_Surely Chilllip” or “F_1Surely Chilllip” is a role to which the same privilege is given even if the displayed symbol combination is different. As described above, the internal winning combination "F_Sure Chill Lip" or "F_1 Chill Chill Lip" is a combination in which the privilege to be given is different depending on the result of the flag conversion lottery, but the privilege to be given by the displayed symbol combination. It is not the role that influences.

  In the pachi-slot 1 of the present embodiment, a combination in which a different privilege is given depending on a displayed symbol combination is notified on both the main side and the sub side, but the same symbol combination is displayed even if the displayed symbol combination is different. The role to which the privilege is given is not notified on the instruction monitor on the main side, but is notified only on the display device 11 on the sub side. By providing such a notification function, the notification affecting the privilege is appropriately performed on the instruction monitor on the main side which manages the privilege, and the notification not affecting the privilege has a variety on the display device 11 on the sub side. It can be done by navigation.

[Game history display function]
In the pachislo 1 of the present embodiment, a sub-display device 18 is provided separately from the display device 11 (the projector mechanism 211 and the display unit 212), and the sub-display device 18 displays various information useful for a player. For example, as shown in FIGS. 5A to 5E, a sub-display device includes a top screen 221 showing an overview game history, a menu screen 222 on which various operations can be performed on the pachislot 1, and game information screens 223, 224, and 225 showing a detailed game history. 18 can be displayed.

  Further, the pachislo 1 of the present embodiment has a function of enabling registration of a player playing a game via the sub-display device 18 and a function of providing a unique service to the registered player. For example, in the present embodiment, when the registration of the player is not received, the game information screens 223, 224, and 225 indicating the detailed game history are disabled from being displayed on the sub display device 18, but the registration of the player is not performed. If the game has been accepted, the game information screens 223, 224, and 225 representing the detailed game history can be displayed on the sub display device 18. Since it is possible to check the more detailed game history, it is possible to improve the convenience of the player. Therefore, in the present embodiment, when the registration of the player is received, the convenience can be improved.

  Further, in the pachislo 1 of the present embodiment, the sub-display device 18 is provided separately from the display device 11 that performs an effect. The sub display device 18 is controlled by the sub control board 72 (sub CPU 201) via the liquid crystal relay board 87. The display unit 212 included in the display device 11 is controlled by the sub-control board 72 (sub-CPU 201) via the accessory relay board (not shown). Therefore, in the present embodiment, the sub display device 18 can be controlled separately from the display device 11. Specifically, the display screen of the sub display device 18 can be switched even during the game (that is, during the performance of the effect by the display device 11). Therefore, even during a game, the player can obtain various information by switching the display on the sub-display device 18 without disturbing the effect performed by the display device 11.

  Further, in the display device 11 of the pachislot 1 of the present embodiment, a plurality of screen mechanisms (display units 212) for displaying an image by irradiating the irradiation light from the projector mechanism 211 are used to use a planar image display. When performing an effect using an image display having a sense of depth (three-dimensional effect) and an effect using a curved image display, the effect of the effect can be significantly enhanced. However, such a display mode of information is not suitable for displaying information unrelated to the effect such as a game history during the effect. Therefore, in the pachi-slot 1 of the present embodiment, information irrelevant to the effect can be displayed on the sub-display device 18 provided separately from the display device 11, so that the effect of the effect can be achieved without deteriorating the effect of the game. Various information such as a history can be appropriately displayed.

  By the way, in a general pachislot, a medal insertion slot 14 is provided on the right side of the pedestal portion 13 when viewed from the player side, and bet buttons 15a and 15b and a start lever 16 are provided on the left side of the pedestal portion 13. Therefore, normally, when the player proceeds with the game, the player operates the operation unit on the right side or the left side (side) of the base 13.

  On the other hand, in the pachislot 1 of the present embodiment, the sub display device 18 is provided on the side (left side) of the surface that stands substantially perpendicularly from the pedestal portion 13, and the sub display device 18 is displayed on the screen of the sub display device 18. A touch sensor 19 for switching the display screen is provided. Therefore, in the present embodiment, the sub display device 18 and the input device (the touch sensor 19) for controlling the display thereof are provided at the place where the player's hand is located during the game, so that the operability of the player is improved. Can be improved. In particular, when the sub-display device 18 with the touch sensor 19 is provided on the surface of the pedestal portion 13 standing from the horizontal plane as in the present embodiment, the player places his or her hand on the pedestal portion 13. The user can operate the sub-display device 18. In this case, not only the operability of the player is improved, but also the fatigue of the player due to the operation can be reduced, and as a result, the operation rate can be expected to be improved.

[Non-defined ROM area and Non-defined RAM area]
In the pachislot 1 of the present embodiment, as shown in FIG. 12B, various programs and various programs used for various processes that do not directly affect the playability of the game performed by the player (various processes that do not affect the playability). The data (table) is stored in a non-defined ROM area located at an address different from the gaming ROM area in the main ROM 102.

  In such a configuration of the main ROM 102, programs and data that are unnecessary for the game itself that the player actually plays are stored in a ROM area (non-defined ROM area) where it is impossible to arrange programs and the like according to conventional rules. can do. Therefore, in the present embodiment, it is possible to avoid the compression of the capacity of the game ROM area in the main ROM 102 of the main control board 71, and to enhance the expandability of the programs and tables in the main ROM 102.

[Effect obtained by power-on (reset interrupt) processing]
In the power-on (reset interrupt) processing of the pachislot 1 of this embodiment, as shown in FIG. 64, immediately after the power is restored (before the sum check), an interrupt processing of the first 1.1172 ms cycle is performed (S7 and S8). ), A no-operation command is transmitted from the main control circuit 90 to the sub-control circuit 200. By permitting the interrupt processing immediately after the return of the power, the no-operation command is transmitted in the shortest time after the return of the power, and the communication connection between the main control circuit 90 and the sub-control circuit 200 can be established. The communication operation between the main control circuit 90 and the sub control circuit 200 can be stabilized.

  Also, the communication parameters 1 to 5, which constitute the no-operation command transmitted immediately after the power is restored, include the data stored in the L register, the H register, the E register, the D register, and the C register when the power is restored. Is done. Therefore, in the present embodiment, the sum value (BCC) of the no-operation command transmitted in the interrupt processing immediately after the return of the power supply can be made different every time the power supply returns, thereby suppressing illegal acts such as goto. it can.

  Further, the control for displaying the error code “rr” on the 2-digit 7-segment LED in the information display unit 6 performed in the process of S13 during the power-on (reset interrupt) process is performed by one “LDW”. Command (predetermined read command), the operation of outputting 7-segment common output (selection) data to the 2-digit 7-segment LED and the operation of outputting 7-segment cathode output data are performed simultaneously (see FIG. 65C). That is, in the pachislo 1 of the present embodiment, in the process of turning on the power (reset interrupt), when the 2-digit 7-segment LED is dynamically turned on, the 7-segment common output (selection) data and the 7-segment cathode output data are converted. Output at the same time.

  In this case, the number of instruction codes required for the dynamic lighting control of the 7-segment LED on the source program can be reduced. Therefore, in the present embodiment, the capacity of the source program (the used capacity of the main ROM 102) can be reduced, the free space in the main ROM 102 can be secured (increased), and the increased free space is utilized. Therefore, it is possible to enhance the playability.

[Effects obtained by game return processing]
In the game return process of the pachi-slot 1 of the present embodiment, as shown in FIG. 66, while the input / output state of each port at the time of power failure occurs is ensured at the time of power return, When the power is restored, the reel control management information is acquired, and the processing necessary to start the reel re-rotation is also performed (see S25 to S32). Therefore, in the present embodiment, it is possible to stably perform the re-rotation control of the reels even when returning from the power interruption during the rotation of the reels, and the player does not feel uncomfortable.

  As described above, the pachislo 1 of the present embodiment includes the microprocessor 91 with a security function for gaming machines. The microprocessor 91 is provided with various instruction codes (instruction codes dedicated to the main CPU 101) specific to the microprocessor 91, which can be defined on a source program, and uses the instruction codes dedicated to the main CPU 101 in various processes. This makes it possible to increase processing efficiency and reduce program capacity.

  For example, in the game return process, as shown in FIG. 67, an “LDQ” instruction, which is one of the instruction codes dedicated to the main CPU 101, is used in the source program. The “LDQ” instruction is an instruction code for specifying an address using a Q register (extension register), and as described above, can directly access the main ROM 102, the main RAM 103, and the memory map I / O. In this case, the instruction code related to the address setting can be omitted, and accordingly, the capacity of the source program for the game return processing (the used capacity of the main ROM 102) can be reduced. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Effect obtained by setting change confirmation processing]
In the setting change confirmation processing of the pachislot 1 of the present embodiment, as shown in FIG. 69A, a “BITQ” instruction and a “SETQ” instruction (predetermined instructions), which are instruction codes dedicated to the main CPU 101, are used on the source program. . The “BITQ” instruction and the “SETQ” instruction are both instruction codes for specifying an address using a Q register (extension register). When these instruction codes are used, as described above, the main RAM 103 And memory mapped I / O. In this case, the instruction code related to the address setting can be omitted, and the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space of the main ROM 102 can be increased, and the processing speed can be increased.

  69A and 69B show a process of generating and storing a setting change command (initialization command) performed at the start of setting change / setting check in S46 and at the end of setting change / setting check in S57 during the setting change checking process. In the source program, the instruction is executed by a “CALLF” instruction which is an instruction code dedicated to the main CPU 101. The jump destination address specified by the “CALLF” instruction in S46 is the same as the jump destination address specified by the “CALLF” instruction in S57. That is, in the present embodiment, the generation and storage processing of the setting change command (initialization command) transmitted to the sub control circuit 200 at the time of setting change (at the time of starting the gaming machine), at the start of setting check (during normal operation), and at the end of setting check Are the same as each other, and the source program is shared (moduleed) in both processes of S46 and S57.

  In this case, it is not necessary to separately provide a source program for generating and storing the setting change command in each of the processes S46 and S57, so that the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. it can. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Effect obtained by the setting change command generation and storage processing]
In the setting change command generation and storage processing of the pachislot 1 of this embodiment, as shown in FIG. 70, the set value is stored in the E register as the communication parameter 3, and the RT information is stored in the C register as the communication parameter 5. That is, among the communication parameters 1 to 5 constituting the setting change command (initialization command), the communication parameters 3 and 5 are communication parameters (use parameters) used (analyzed) on the sub-control circuit 200 side. New information is set in the communication parameter. On the other hand, other communication parameters 1, 2, and 4 that constitute the setting change command (initialization command) are communication parameters (unused parameters) that are not used (analyzed) on the sub-control circuit 200 side, and communication parameters 1, 2, and 3. The values currently stored in the L register, the H register, and the D register at the present time are set for and. Therefore, the values of the communication parameters 1, 2, and 4 at the time of transmitting the setting change command (initialization command) are undefined. In this case, the sum value (BCC) of the setting change command can be set to an indefinite value for each transmission, and fraudulent acts such as goto can be suppressed.

[Effect obtained by communication data storage processing]
In the communication data storing process of the pachislot 1 of this embodiment, as shown in FIG. 72, the data stored in the A register is set as the type data of the communication command, and the L register, the H register, the E register, the D register and the C register are set. The data stored in the register is set as communication parameters 1 to 5 of the communication command, and the data stored in the B register is set as game state flag data of the communication command. That is, in the present embodiment, when one packet (8 bytes) of communication data (command data) is created, various parameters are transferred from the register and stored in the communication data temporary storage area (communication buffer).

  In this case, when command data including an unused parameter is created, the value of the unused parameter becomes an indefinite value each time it is created. That is, in the command data including the unused parameter, even if there is the same type of command data and the value of the used parameter is the same, the sum value (BCC data) of the command data can be changed every time the command is created. . Therefore, in the present embodiment, it is necessary to make the analysis of the communication data difficult and suppress the fraudulent acts such as goto by setting the unused parameters to indefinite values, and it is necessary to add unnecessary goto countermeasure processing. Therefore, the compression of the program capacity of the main control circuit 90 due to the addition of the goto countermeasure processing can be suppressed.

[Effect obtained by the communication data pointer update processing]
In the communication data pointer updating process of the pachi-slot 1 according to the present embodiment, as shown in FIG. 75A, an “ICPLD” instruction, which is an instruction code dedicated to the main CPU 101, is used in a source program.

  In the communication data pointer update processing, the “ICPLD” instruction is an instruction code in which the upper limit determination instruction of the transmission buffer and the determination branch instruction are integrated, so that an instruction code for executing each instruction processing separately is used. There is no need to provide them. Therefore, by using the “ICPLD” instruction, it is possible to reduce the capacity of the source program for the communication data pointer update processing (the used capacity of the main ROM 102). As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Effect obtained by checksum generation processing and checksum processing]
In the checksum generation process (not specified) performed at the time of power failure in the pachislot 1 of the present embodiment, the checksum is calculated by sequentially adding the data of the main RAM 103 as shown in FIG. On the other hand, in the sum check process (not specified) performed when the power is turned on (when the power is restored), as shown in FIG. 79, the value of the checksum generated when the power failure occurs is stored in the main RAM 103 when the power is restored. The subtraction is sequentially performed using the obtained data, and whether or not an abnormality has occurred is determined based on whether or not the final subtraction result is “0”. That is, in the present embodiment, the process of generating the checksum when a power failure occurs is performed by the addition method, and the process of determining the checksum when the power is restored is performed by the subtraction method.

  When such a checksum generation process and a determination process are adopted, there is no need to generate a checksum again when the power is restored and to collate the checksum with the checksum at the time of power failure. In this case, the collation instruction code can be omitted from the source program, and the capacity of the source program can be reduced. As a result, in the present embodiment, it is possible to secure (increase) the free space corresponding to the omission of the collation instruction code in the main ROM 102, and it is possible to use the increased free space to enhance the playability. Become.

[Effects obtained by medal reception / start check processing]
In the medal acceptance / start check process of the pachislot 1 of the present embodiment, as shown in FIG. 83, a setting change confirmation process (the process of S233) is performed, but this process is executed regardless of the gaming state. Therefore, in this embodiment, even if the gaming state is the bonus state (the special prize operation state), the set value and the hole menu (various history data (error, power-off history, etc.)) can be confirmed, Can be suppressed.

[Effect obtained by medal insertion processing]
In the medal insertion processing of the pachislot 1 of the present embodiment, as shown in FIG. 85, in the processing of S244, the LED lighting data for displaying the number of inserted medals is generated not by the loop processing referring to the table but by the arithmetic processing. . Specifically, by sequentially executing a series of source codes “LD A, L” to “OR L” in the source program shown in FIG. 86, LED lighting data for displaying the number of inserted medals is generated.

  When the LED lighting data for displaying the number of inserted medals is generated by arithmetic processing, the free space in the table area of the main ROM 102 can be increased and the increase in the capacity of the program can be minimized. That is, in the medal insertion processing of the present embodiment, the processing of displaying the medal insertion LED can be made more efficient, the free space of the main ROM 102 is secured (increased), and the increased vacant area is utilized to improve the game performance. Can be enhanced.

[Effect obtained by medal insertion check processing]
In the medal insertion check process of the pachislo 1 of the present embodiment (see FIG. 87), the process of generating the normal change value of the medal sensor input state in S257 is performed not by a process of referring to a table but by an arithmetic process. Specifically, the medal sensor input state normal change value is calculated by sequentially executing the source code “RLA” and “AND cBX_MDINSW” in the source program shown in FIG.

  By changing the detection process of the change state of the medal sensor input state from the table reference process to the calculation process, it is possible to increase the free space in the table storage area of the main ROM 102 and minimize the increase in the program capacity. it can. Therefore, by adopting the processing method described above, it is possible to improve the efficiency of the process of detecting the change state of the medal insertion sensor state, and to enhance the game performance by utilizing the increased free space in the main ROM 102. it can.

[Effect obtained by internal lottery process]
In the internal lottery process of the pachi-slot 1 of this embodiment (see FIG. 92), the process of acquiring the determination data in S305 is executed by the source code “LDIN AC, (HL)” in FIG. 93A. By executing the “LDIN” instruction, in the process of S305, the determination data (the value of the “lottery value selection table or lottery counting table”) is stored in the A register, and the request flag status (“special prize winning number”) is hit in the C register. + Small Winning Number ”) is stored. In addition, by executing the “LDIN” instruction, the address set in the HL register is updated by +2 (addition of 2).

  That is, in the acquisition processing of the determination data in S305 during the internal lottery processing, both the data loading processing and the address updating processing can be performed by one instruction code (“LDIN” instruction). In this case, the instruction code relating to the address setting can be omitted from the source program, and the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  In addition, in the addition processing of the set value data (any of 0 to 5) in S309 of the internal lottery processing, the main CPU 101 converts the source codes “MUL A, 6” and “ADDQ A, (.LOW.wWAVENUM)” in FIG. 93B. )) In this order.

  The “MUL” instruction is an instruction code of a multiplication process dedicated to the main CPU 101, and the execution of this instruction is executed by the arithmetic circuit 107 (see FIG. 9) included in the microprocessor 91. That is, the pachislo 1 of the present embodiment is provided with a dedicated operation circuit (arithmetic circuit 107) for executing the multiplication processing and the division processing on the source program, so that the efficiency of the multiplication processing and the division processing is improved. Can be.

  The “ADDQ” instruction (predetermined addition instruction) is an instruction code dedicated to the main CPU 101, and is an instruction code for specifying an address using a Q register (extension register). Then, if this "ADDQ" instruction is used, the main ROM 102, the main RAM 103, and the memory map I / O can be accessed by a direct value. Therefore, by using the “ADDQ” instruction, it is possible to omit the instruction related to the address setting on the source program of the internal lottery process, and to reduce the capacity of the source program (the used capacity of the main ROM 102) accordingly. Can be. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Effect obtained by the pattern setting process]
In the symbol setting process of the pachislot 1 of this embodiment (see FIG. 97), the compressed data storing process of S330 is performed by the main CPU 101 executing the source code “CALLF SB_BTEP_00” in FIG. The “CALLF” instruction is a two-byte instruction code dedicated to the main CPU 101 as described above, and the source code “CALLF” in FIG.
When “SB_BTEP_00” is executed, the process jumps to the address specified by “SB_BTEP_00”, and the compressed data storage process is started.

  Further, the address setting process of the hit request flag storage area in S329 during the symbol setting process is performed by the main CPU 101 executing the source code "LDQ DE, .LOW.wWAVEBIT" in FIG. That is, the process of S329 is performed by an “LDQ” instruction dedicated to the main CPU 101 using a Q register (extension register). In this case, the instruction code relating to the address setting can be omitted in the source program of the symbol setting process, and the capacity of the source program of the symbol setting process (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  Further, in the present embodiment, the compression / decompression processing of the data related to winning is performed in the processing procedure described in S324 to S330 in the above-mentioned symbol setting processing, and the main CPU 101 dedicated instruction code is executed in the processing. By using this, it is possible to increase the efficiency of the compression / decompression processing of the data related to the winning, and to effectively utilize the limited capacity of the main RAM 103.

[Effect obtained by sub-flag conversion processing]
In the pachi-slot 1 of the present embodiment, in the sub-flag conversion table shown in FIG. 107, which is actually referred to on the source program of the sub-flag conversion processing, sub-flag conversion control data (control status) is associated with each sub-flag. . At this time, the same subflag conversion control data (control status) is associated with the same type of subflag.

  For example, the sub-flag conversion control data (control status) “00000011B” is commonly assigned to the sub-flag “triple chip A” and “triple chip B”. In the flag conversion lottery process for converting the internal winning combination (sub flag) into the sub flag EX, the lottery is performed based on the sub flag conversion control data (control status) associated with the sub flag.

  As described above, by providing common sub-flag conversion control data for the same type of internal winning combination (sub-flag) in the sub-flag conversion table managed on the main side, the versatility of the conversion table is improved, and the type of the conversion table is changed. Changes in the conversion program can be dealt with by minor changes, so that an increase in development costs can be suppressed.

[Effect obtained by navigation set processing]
In the navigation setting process of the pachislot 1 according to the present embodiment, as shown in FIG. 109, an “LDQ” instruction (instruction code dedicated to the main CPU 101) for specifying an address using a Q register (extension register) is used on the source program. Can be

  Therefore, in the navigation set processing according to the present embodiment, it is possible to omit the instruction related to the address setting on the source program, and accordingly, it is possible to reduce the capacity of the source program (the used capacity of the main ROM 102). As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Effect obtained by table data acquisition processing]
In the table data acquisition process of the pachislot 1 of this embodiment (see FIG. 120), in the first stage table data acquisition process of S581 to S584, a winning combination table selection in the CT during CT lottery random determination table (see FIG. 122) is performed. A relative table is referenced. In the winning combination-specific table selection relative table referred to in the first-stage table data acquisition process, “losing” of CT lottery is set by a selection value provided for each type of internal winning combination (sub-flag D). Therefore, it is not necessary to define the lottery value of the “losing” role in the lottery table. Therefore, in the present embodiment, it is not necessary to store the lottery value data of the “losing” role in the CT winning lottery table during CT, and the capacity of the table area of the main ROM 102 can be saved.

  Further, in the second-stage lottery table (when acquiring the sub-flag D “reach-eye lip”) in the CT-winning CT lottery lottery table, a lottery target role or a non-lottery target role is determined based on the value of each bit constituting a determination bit. This eliminates the need to store lottery value data (loss data) in a table for a role that is not a target of lottery. Further, in the CT winning lottery table during CT, a lottery value “0” can be used as the determination data in which the winning probability of the lottery target combination is 100%. From these facts, in the present embodiment, it is possible to compress the capacity of the CT winning lottery lottery table during CT (CT number set lottery table) and secure (increase) the free capacity in the main ROM 102. By using the increased free space, it is possible to enhance the gaming ability.

[Effect obtained by symbol code acquisition processing]
In the symbol code acquisition process (see FIG. 128) of the pachislot 1 according to the present embodiment, the compression / decompression process of winning data is performed according to the processing procedure described in S647 to S649, and the main CPU 101 dedicated instruction in the process is performed. By using a code (such as a “CALLF” instruction), it is possible to increase the efficiency of the data compression / decompression processing related to winning, and to effectively utilize the limited capacity of the main RAM 103.

  In the present embodiment, in the compressed data storage processing of S649 during the symbol code acquisition processing, the jump destination address specified by the “CALLF” instruction is the compressed data storage processing of S330 in the symbol setting processing (see FIG. 97). Is the same as the jump destination address specified by the "CALLF" instruction. That is, in this embodiment, in both the symbol code acquisition process and the symbol setting process, the source program for executing the compressed data storage process is shared (moduleed). In this case, since it is not necessary to separately provide a source program for the compressed data storing process in each process, the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Effects obtained by pull-in priority acquisition processing]
In the pull-in priority acquisition processing of the pachislot 1 of the present embodiment (see FIGS. 134 and 135), the determination processing of S683 during the pull-in priority processing of the “ANY role” is performed by the main CPU 101 dedicated instruction code in the source program. It is executed by a certain “JCP” command (comparison command) (see FIG. 136A).

  When the “JCP” instruction is used in the source program for the “ANY role” pull-in priority processing, as described above, the instruction related to the address setting can be omitted. The processing efficiency of the processing can be increased, and the capacity of the source program (used capacity of the main ROM 102) can be reduced.

  In addition, in the stop request pull-in request flag setting process in S686 during the pull-in priority acquisition process, as shown in FIG. 136B, a Q register (extended register), which is an instruction code dedicated to the main CPU 101, is used in the source program. An “LDQ” instruction for specifying an address and a “CALLF” instruction are used.

  Therefore, in the stop control pull-in request flag setting process in S686, by using the “LDQ” instruction, the instruction related to the address setting can be omitted in the source program, and the capacity of the source program (use of the main ROM 102 Capacity) can be reduced. The “CALLF” instruction is a 2-byte instruction code as described above. Therefore, in the stop control pull-in request flag setting process, by using these instruction codes dedicated to the main CPU 101, the efficiency of the process can be improved, and the limited capacity of the main RAM 103 can be effectively utilized. .

  Further, in the present embodiment, in the stop control pull-in request flag setting process of S686 during the priority pull-in order obtaining process, the address of the logical product operation process of the jump destination specified by the “CALLF” instruction is set in the pull-in priority storing process ( This is the same as the jump destination address specified by the “CALLF” instruction in the logical product operation processing of S626 in FIG. 126 (see FIG. 127). That is, in the present embodiment, the source program for executing the logical product operation process is shared (moduleed) in both the priority attraction order acquisition process and the attraction priority order storage process.

  In this case, it is not necessary to separately provide a source program for the logical product operation process in both the priority attraction order acquisition process and the attraction priority order storage process, and accordingly, the capacity of the source program (the used capacity of the main ROM 102) Can be reduced. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  In the process of acquiring the withdrawal priority table (see FIG. 137) in S687 during the withdrawal priority acquisition process, as shown in FIG. 136C, an “LDQ” instruction (a dedicated instruction code for the main CPU 101) is used. Therefore, in the acquisition process of the pull-in priority order table in S687, the instruction related to the address setting can be omitted on the source program. As a result, it is possible to improve the efficiency of the process of acquiring the pull-in priority table and reduce the capacity of the source program (the capacity used by the main ROM 102).

[Effect obtained by reel stop control processing]
In the reel stop control processing of the pachi-slot 1 of this embodiment (see FIG. 138), in the processing of S711 to S715, as shown in FIG. 139, address designation is performed on the source program using the Q register (extension register). An “LDQ” command and a “CALLF” command are used.

  Therefore, in this embodiment, by using these instruction codes dedicated to the main CPU 101, the capacity of the source program for the reel control processing can be reduced, and the processing efficiency of the reel stop control processing can be improved. That is, in the present embodiment, it is possible to increase the efficiency of the program processing speed in the main control circuit 90 and reduce the capacity, and to utilize the increased free space of the main ROM 102 in accordance with the reduced capacity to improve the game performance. Can be enhanced.

  As shown in FIG. 140, in the determination process of S726 during the reel stop control process (the process of checking the stopped state of the reel (turning drum)), the “LDQ” command and the “ORQ” command (Q An instruction code dedicated to the main CPU 101 for specifying an address using a register (extension register) is used.

  Therefore, in the present embodiment, the instruction related to the address setting can be omitted in the source program of the reel stop control process, and the capacity of the source program (the used capacity of the main ROM 102) can be reduced accordingly. . As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Effects obtained by winning search processing]
In the winning search process of the pachi-slot 1 of this embodiment (see FIG. 145), in the process of setting the number of payouts and the data to be determined in S764, as shown in FIG. 146, an “LDIN” command is used in the source program.

  Therefore, in the winning search processing of the present embodiment, both the data loading processing and the address updating processing can be performed by one “LDIN” instruction. In this case, it is possible to omit the instruction related to the address setting in the source program of the winning search process, and to reduce the capacity of the source program (the used capacity of the main ROM 102). As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  In addition, a medal counter value acquisition process referred to in the determination process of S770 during the winning search process, a winning coin counter value acquired process referred to in the S772 process, and a winning coin counter saved in the S775 process ( In the update) process, as shown in FIG. 146, an “LDQ” instruction for specifying an address using a Q register (extension register) is used. Therefore, in the winning search process according to the present embodiment, it is possible to omit the instruction related to the address setting in the source program, and to reduce the capacity of the source program (the used capacity of the main ROM 102). As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

  Further, in the determination processing in S769 during the winning search processing, as shown in FIG. 146, a “JSLAA” instruction is used in the source program, and in the determination processing in S770 and S773, a “JCP” instruction is used. When the “JSLAA” command and the “JCP” command are used on the source program of the winning search processing, the command related to the address setting can be omitted as described above, and the capacity of the source program (main ROM 102 Used capacity) can be reduced. As a result, in the present embodiment, the free space can be secured (increased) in the main ROM 102, and the increased free space can be utilized to enhance the gaming ability.

[Effects obtained by illegal hit check processing]
In the present embodiment, as shown in FIGS. 28 to 30, the configuration of the winning operation flag storage area (display combination storage area) is the same as that of the hit request flag storage area (internal winning combination storage area). Therefore, in the arithmetic processing of S784 in the illegal hit check processing of the present embodiment, the data of the winning combination and the data of the internal winning combination are simply logically ANDed by the “AND” instruction on the source program (see FIG. 149). By simply executing the “execute”, it is possible to obtain a result of combining the data of the winning combination and the data of the internal winning combination.

  Therefore, in the present embodiment, the efficiency of the illegal hit check process can be improved and simplified, and as a result, the free space of the main control program can be secured, and the playability is improved by using the free space. be able to.

[Effects obtained by winning check / medal payout processing]
In the prize check / medal payout process of the pachislot 1 of this embodiment (see FIG. 150), when the payout operation is continued after the credit counter is updated (+1), in the process of S808, a wait (payout interval) of 60.33 ms is performed. Wait) processing is performed. In this case, unnecessary waiting time can be reduced, and the mental burden on the player can be reduced.

[Effect obtained by medal payout number check processing]
As shown in FIG. 153A, in the updating process of the winning combination end number counter in S814 during the medal payout number check process of the pachislot 1 (see FIG. 152) according to the present embodiment, the instruction code is a dedicated instruction code for the main CPU 101 on the source program. The “DCPLD” instruction is used.

  In the processing of S814, the “DCPLD” instruction is an instruction code in which the lower limit determination instruction of the number management counter and the determination branch instruction are integrated, so that the update (subtraction) processing of the combination end number counter and the serial end number Both processes for holding the value of the counter at “0” can be executed. In this case, there is no need to provide instruction codes for executing both processes separately. Therefore, in the medal payout number check processing of the present embodiment, the capacity of the source program (the used capacity of the main ROM 102) can be reduced, and the free space in the main ROM 102 can be secured (increased), and the number of Utilizing the free space that has been used can enhance the gaming ability.

  In the process of S816 during the medal payout number check processing, as shown in FIG. 153B, the value of the payout number counter is set in the communication parameter 1 of the credit information command, and the value of the credit counter is set in the communication parameter 5. Is done. However, the values stored in the H register, the E register, and the D register at the present time are set in the other communication parameters 2 to 4 (unused parameters) constituting the credit information command. Therefore, the values of the communication parameters 2 to 4 at the time of transmitting the credit information command are undefined values. As a result, in the present embodiment, the sum value (BCC) of the credit information command can be set to an indefinite value for each transmission, and fraudulent acts such as goto can be suppressed.

[Effect obtained by 7-segment LED drive processing]
The output process of the 7-segment common output (selection) data and the 7-segment cathode output data performed in S936 during the 7-segment LED driving process (see FIG. 159) of the pachislot 1 according to the present embodiment includes one source as shown in FIG. 160B. This is executed by the code “LD (cPA_SEGCOM), BC”. That is, in the present embodiment, in the 7-segment LED driving process, when the 2-digit 7-segment LED is dynamically turned on, the 7-segment common output data and the 7-segment cathode output data are output simultaneously. This output control is also performed when the pressing order display data is displayed on the instruction monitor in the information display 6.

  In this case, the number of instruction codes required for the dynamic lighting control of the 7-segment LED can be reduced on the source program of the 7-segment LED driving process. Therefore, in the present embodiment, the capacity of the source program (the used capacity of the main ROM 102) can be reduced, the free space in the main ROM 102 can be secured (increased), and the increased free space is utilized. Therefore, it is possible to enhance the playability.

[Effect obtained by timer update processing]
In the process of S952 (update process of the 2-byte timer) in the timer update process of the pachislot 1 (refer to FIG. 164) of the present embodiment, as shown in FIG. The "DCPWLD" instruction is used.

  When the “DCPWLD” instruction is executed in the timer update process, as described above, both the update (subtraction) process of the timer number (the 2-byte timer number) and the process of holding the timer number at “0” are executed. Can be. In this case, there is no need to provide instruction codes for executing both processes separately. Therefore, in the present embodiment, the capacity of the source program (the used capacity of the main ROM 102) can be reduced, the free space in the main ROM 102 can be secured (increased), and the increased free space is utilized. Therefore, it is possible to enhance the playability.

<Various modifications>
As above, the configuration and operation of the gaming machine according to the first embodiment of the present invention have been described, including the effects thereof. However, the present invention is not limited to the embodiments described above, and includes various other embodiments and modifications without departing from the spirit of the present invention described in the claims.

[Modification Example 1: CT Audible Game During Normal ART and Notification Lottery]
In the pachislo 1 of the above-described embodiment, in order to facilitate understanding, when a player wins an advantageous state (for example, CT), the gaming state is shifted from the next game (next game) to an advantageous state. However, the present invention is not limited to this. For example, when performing a game control in an advantageous state for a player, the game control in the advantageous state may be performed after performing a predetermined number of games, which is called a so-called “precursor game”. .

  Here, with reference to FIGS. 174A and 174B, an example will be described in which the gaming state shifts from the normal ART to the CT through a predetermined number of predictive games. FIG. 174A is a diagram showing a game flow at the time of CT random determination in Modification Example 1, and FIG. 174B is a configuration diagram of a flag conversion random determination table used in flag conversion random determination performed during a precursor game.

  In the game during the normal ART of this example, first, as shown in FIG. 174A, the CT random determination based on the internal winning combination (sub-flag) using the CT random determination table during the ART (see FIG. 50), as in the above embodiment. I do. When this CT lottery is won, it is determined that the gaming state shifts to a state of CT (additional chance zone) which is advantageous for the player. Therefore, during the period until the CT is won, various lotteries for the CT lottery are made. Is performed on the main side (main control board 71). For example, the main control board 71 (main CPU 101) performs an internal lottery for determining an internal winning combination, and as an internal winning combination, an internal winning combination “F_Currency Clip”, “F_1 Circular Rep”, and “F_Reach Rep A”. When any one of ".._______________________________________________ is determined, the flag conversion lottery is performed using the ART flag conversion lottery table (see FIGS. 47A and 47B).

  Next, when the CT lottery is won in the game during the normal ART, in this example, the sign game (CT sign game) for a predetermined period is performed before the transition to the CT. In this example, in the CT precursor game, for example, a bonus for a player such as a CT lottery based on a sub-flag EX (“triple lip”, “reach eye lip”, “replay”, etc.) determined by the flag conversion lottery is provided. Is not performed. However, in this example, in the CT precursor game, for example, the flag conversion lottery using the flag conversion lottery table shown in FIG. 174B is performed on the sub side (the sub control board 72 side), and the flag conversion lottery performed on the sub side is performed. Based on the result, the content of the notification performed on the sub side is controlled (determined). For example, when the flag conversion lottery performed on the sub side is won, the display device 11 (the projector mechanism 211 and the display unit 212) notifies information for displaying the symbol combination related to the abbreviation “Reach eye lip”, When the flag conversion lottery is not won, the display device 11 notifies information for displaying the symbol combination related to the abbreviation “Replay”.

  As described above, in recent pachislot, the main side is required to perform a lottery that affects the profit (payout) of the player, but in the pachislot 1 of this example, the lottery result of the flag conversion lottery is A period that does not affect the profit of the player at all (a period of the CT precursor game) is provided, and only during this period, the flag conversion random determination is performed on the sub side. Therefore, in this example, for example, in a situation in which the award of the privilege during the CT precursor is determined, it is possible to increase opportunities to display a special symbol combination such as the symbol combination related to the abbreviation “Reach eye lip”, for example. At the same time, it is possible to increase the variation of how the symbol combination is shown. As a result, according to the configuration of this example, it is possible to further improve the playability.

  The lottery table shown in FIG. 174B is a flag conversion lottery table during the CT precursor used for the flag conversion lottery performed on the sub side, and is stored in the ROM cartridge substrate 86. The flag conversion lottery table during the CT precursor includes an internal winning combination “F_reach-eye lip A” to “F_reach-eye lip D”, a lottery result of flag conversion lottery performed on the sub side (non-winning / winning), and each lottery. The correspondence with the information of the lottery value associated with the result is defined.

  As is apparent from the flag conversion lottery table shown in FIG. 174B, in this example, in the CT precursor game, the internal flag combination “F_reach-eye lip A” to “F_reach-eye lip D” has a very high probability of the sub-flag EX “ (The flag conversion lottery is won). That is, when any of the internal winning combinations “F_reach-eye lip A” to “F_reach-eye lip D” is determined in the CT precursor game, the symbol combination of the abbreviation “reach-eye lip” is stopped and displayed with a high probability. This means that the player can be informed that the current game is a CT precursor game. At this time, as described above, when the flag conversion lottery performed on the sub side in the CT precursor game is won, the notification for displaying the symbol combination related to the abbreviation “Reach eye lip” is performed, but the privilege is provided. There is no.

  In this example, the flag conversion lottery during the CT precursor game may be performed on the main side. However, as in the example described with reference to FIGS. 174A and 174B, by performing the lottery on the sub side in a period in which the profit of the player is not affected at all, the data capacity and the processing load on the main side can be reduced.

[Modification Example 2: Another example of the pressing order for displaying triple lip]
In the pachislot 1 of the above embodiment, when the internal winning combination “F_Sure Chill Lip” or “F_1 Sure Chill Lip” is determined, if the stop button is pressed in the correct order, the symbol combination related to the abbreviation “Triple Chill Lip” is changed. The example in which the symbol combination related to the abbreviation “Replay” is displayed when the displayed order is incorrect is described (see FIG. 24). Further, in the above-described embodiment, an example has been described in which the pressing order of the correct answer associated with the internal winning combination “F_Surely Chilllip” and “F_1 Surely Chilllip” is “forward push”. However, the present invention is not limited to this.

  For example, in the case where the internal winning combination “F_Probable Chililip” or “F_1 Probable Chililip” is determined, the types of symbol combinations displayed when the pressing order is incorrect are increased, and the internal winning combination “F_Probable Chililip” is increased. May be made different from the order in which the internal winning combination "F_1 probable flip" is determined. One example (Modification 2) will be described with reference to FIGS. 175A and 175B. Note that FIG. 175A is a diagram showing a correspondence relationship between an internal winning combination and a symbol combination (stop symbol (abbreviation)) to be stopped and displayed in Modification Example 2, and FIG. FIG. 14 is a diagram showing a correspondence relationship between the result of the flag conversion lottery and the navigation type performed on the sub side.

  In this example, as shown in FIG. 175A, when the internal winning combination “F_Sure Chill Lip” is determined, the push order of the correct answer is “forward push (first stop of the left reel 3L)”, and the push of the incorrect answer is performed. The order is “first stop of the middle reel 3C (hereinafter referred to as“ middle push ”) or first stop of the right reel 3R (hereinafter referred to as“ reverse push ”), that is,“ irregular push ”. Then, in this example, when the internal winning combination “F_Sure Chill Lip” is determined, when the key is pressed in order, a symbol combination related to the abbreviation “Triple Chill Lip” is displayed. Is displayed, and when it is pushed backward, a symbol combination according to the abbreviation "Dual Chill Lip" is displayed.

  Further, in this example, when the internal winning combination "F_1 certainty lip" is determined, the pressing order of the correct answer is reverse pressing, and the pressing order of the incorrect answer is forward pressing and middle pressing. In this example, when the internal winning combination “F_1 probable chili lip” is determined, when the key is pressed backward, a symbol combination related to the abbreviation “triple chili lip” is displayed. Is displayed, and when pressed sequentially, a symbol combination according to the abbreviation "Dual Chill Lip" is displayed.

  In the pachislot 1 of this example, if one of the internal winning combination “F_Surely Chilllip” and “F_1 Certainly Chilllip” is determined, when the buttons are sequentially pushed, the abbreviation “3 consecutive Chilllip” or A symbol combination related to “two-piece chili lip” is displayed. In addition, when one of the internal winning combination “F_Surely Chilllip” and “F_1 Certainly Chilllip” is determined, when the button is pressed in reverse, the abbreviation “Three Chilllip” or “Dual Chilllip” depending on the type of the internal winning combination. Are displayed. Further, in this example, when one of the internal winning combination “F_Sure Chill Lip” and “F_1 Certain Chill Lip” is determined, when the middle press is performed, the symbol combination related to the abbreviation “Replay” is performed regardless of the type of the internal winning combination. Is displayed.

  When the correspondence between the internal winning combination and the symbol combination (stop symbol (abbreviation)) to be stopped and displayed is set to the relationship shown in FIG. 175A, for example, the internal winning combination “F_Sure Chill Lip” or “F_1 Sure Chill Lip” is determined. In this case, it is possible to perform various navigations (notifications) for causing the player to aim at the Chile symbol.

  For example, it is possible to perform both "navigating a Chile symbol by aiming forward" and "navigating a Chile symbol by pushing backward". When the internal winning combination "F_Sure Chili Lip" is determined, "Navi for aiming for Chile symbol by pushing forward" is a navigation for displaying a symbol combination related to abbreviation "Triple Chili Lip". "Navi for aiming for a Chile symbol by reverse pressing" is a navigation for not displaying a symbol combination for the abbreviation "Triple Chililip" (a navigation for displaying a symbol combination for the abbreviation "Dual Chililip"). On the other hand, when the internal winning combination “F_1 certain Chili Lip” is determined, “Navi for aiming for Chile symbol by pushing forward” is a navigation (abbreviation “ "Navi for displaying a symbol combination related to" two consecutive chili lip "), and" navi for aiming a chile symbol by reverse pressing "is a navigation for displaying a symbol combination relating to the abbreviation" three consecutive chili lip ".

  In this example, the determination as to whether or not to perform the above-described navigation is managed by the flag conversion random determination performed on the main side, and the navigation is executed under the control of the sub side based on the result of the flag conversion random determination on the main side. . At this time, the correspondence between the lottery result of the flag conversion lottery performed on the main side during the normal ART and the navigation type controlled on the sub side is the correspondence shown in FIG. 175B.

  Also in this example, when the internal winning combination “F_Sure Chill Lip” or “F_1 Sure Chill Lip” is determined in the game during the normal ART, the main control board 71 (main CPU 101) performs a two-stage flag conversion lottery ( See FIG. 47). On the other hand, the sub side acquires the result of the two-stage flag conversion lottery from the start command data, and determines the navigation to be performed by the display device 11 based on the result of the two-stage flag conversion lottery.

  Therefore, in this example, if the lottery result is non-winning at the time of the first-stage flag conversion lottery, the sub-control board 72 (sub CPU 201) sets “Replay Navi” as shown in FIG. 175B. Perform a so-called navigation. In the “replay navigation”, information for instructing the player to press the middle is notified. In this example, as shown in FIG. 174A, the symbol combination related to the abbreviation “Replay” will be displayed when the middle press is performed, regardless of whether the internal winning combination is “F_Surely Chilllip” or “F_1 Surely Chilllip”. .

  In this example, when the first-stage flag conversion lottery is won and the lottery result of the second-stage flag conversion lottery is non-winning, the sub-control board 72 (sub CPU 201) executes the process shown in FIG. As shown in (2), a navigation called "Chili lip fan navigation" is performed. In the case of the “Chili lip fanning navi”, when the internal winning combination “F_Sure Chili lip” is determined, the player is notified of instruction information such that the player pushes backward to aim at the Chile symbol. On the other hand, when the internal winning combination "F_1 probable chili lip" is determined in the "Chili lip fanning navigator", instruction information is displayed to instruct the player to aim at the Chile symbol by pushing forward. Then, in such a “Chili lip fan navigation”, as shown in FIG. 174A, when the internal winning is “F_Sure Chili lip”, a symbol combination related to the abbreviated name “Two consecutive Chili lip” is displayed at the time of reverse pressing, When the internal winning combination is "F_1 probable chili lip", the symbol combination related to the abbreviated name "two consecutive chili lip" is displayed at the time of forward pushing.

  In addition, in this example, when both the first-stage and second-stage flag conversion lotteries are won, the sub-control board 72 (sub-CPU 201), as shown in FIG. Perform navigation. In the case of the "Chili lip matching navigator", when the internal winning combination "F_Sure Chili lip" is determined, the player is notified of instruction information such that the player can push the player to aim at the Chilean symbol. On the other hand, when the internal winning combination "F_1 Clilip" is determined in the "Chili lip matching navigator", the player is notified of instruction information that causes the player to push in the reverse direction to aim at the Chile symbol. 174A, when the internal winning is "F_Surely Chililip", the symbol combination related to the abbreviation "3 consecutive Chililip" is displayed when the internal winning is "F_Surely Chililip", as shown in FIG. 174A. When the internal winning combination is “F_1 probable chili lip”, the symbol combination related to the abbreviation “triple chili lip” is displayed at the time of reverse pressing.

  In this example, the notification based on the lottery result of the flag conversion lottery described above does not affect the profit (the flag conversion lottery itself affects the profit, but the symbol combination displayed as a result does not affect the profit). Therefore, the above-described notification operation in this example is not performed on the main side (instruction monitor), but is performed only on the sub-side (display device 11). Further, in this example, as described above, by performing not only “Navigating in Chilelip” but also “Navigating in Chilelip”, navigation that does not affect profit can be controlled by the sub side in various modes. . As a result, the interest in the game can be improved.

[Modification 3: Another Example of Bell Navigation Mode Between Between Flags and Between Non-Flags]
In the pachislo 1 of the embodiment, as described above, the numerical value uniquely corresponding to the information of the reel stop operation is displayed on the instruction monitor (not shown), so that the notification on the main side is performed. At this time, the correspondence of the navigation data described with reference to FIGS. 63A to 63D is referred to. In the above-described embodiment, an example in which “white 7 navigation” and “blue 7 navigation” are performed during the BB flag state (RT5 state), but “bell navigation” is not performed has been described. Not limited. During the state between the BB flags (RT5), “bell navigation” may be performed in addition to “white 7 navigation” and “blue 7 navigation”.

  In this case, the numerical values displayed on the instruction monitor may be different between the state between the BB flags and the state between the non-BB flags. Here, FIGS. 176A and 176B show the correspondence between the notification (navi) performed on the main side and the notification (navi) performed on the sub side during the state between the BB flags in the third modification. FIG. 176A is a diagram showing the correspondence between the notification (navi) performed on the main side and the notification (navi) performed on the sub side during the RT5 state (between the BB1 flags), and FIG. It is a figure which shows the correspondence of the notification (navigating) performed on the main side and the notification (navigating) performed on the sub side in (between BB2 flags).

  In this example, the correspondence between the notification (navi) performed on the main side and the notification (navi) performed on the sub side during the non-BB flag state is the same as in the above embodiment (see FIGS. 63A and 63B). . Therefore, when "bell navigation" is performed in the state between the non-BB flags, numerical values of "1" to "3" (press instruction second instruction information) are displayed on the instruction monitor.

  In this example, as shown in FIGS. 176A and 176B, when “Bell Navi” is performed in the state between the BB flags, numerical values of “12” to “14” (first push instruction first instruction information) are displayed on the instruction monitor. You. Note that the present invention is not limited to this, and when "bell navigation" is performed in the state between the BB flags, the numerical value displayed on the instruction monitor can be appropriately changed. In this example, the navigation on the sub side performed by using the display device 11 may be common to both the state between the BB flags and the state between the non-BB flags.

[Variation 4: Another example of privilege provision]
In the pachislo 1 of the above embodiment, the content of the notification is controlled based on the result of the flag conversion lottery performed on the main side, so that when the stop operation is performed according to the notification, the displayed symbol combination is different. That is, in the above-described embodiment, an example has been described in which whether or not to grant a privilege is determined based on the result of the flag conversion lottery performed on the main side, but the present invention is not limited to this. For example, on the main side (main control board 71), a configuration may be such that a privilege is given based on a symbol combination actually displayed.

  In this case, the main control board 71 (main CPU 101) gives a privilege when a predetermined symbol combination is displayed according to the notification performed in accordance with the result of the flag conversion lottery, and Alternatively, the configuration may be such that no privilege is given even when a predetermined symbol combination is displayed. In the pachislot 1 of the above embodiment, the symbol combination displayed according to the pressing order is different. However, even when the player ignores the notification and performs the stop operation, the symbol combination according to the abbreviation "triple chili lip" is used. Etc. may be displayed. Therefore, in this example, even if the special symbol combination is displayed ignoring the notification, the privilege is provided without providing the privilege only when the special symbol combination is displayed according to the notification. You may.

[Modification 5: Another example of notification control that does not affect profits (privileges)]
In the pachislot 1 of the first modification (see FIGS. 174A and 174B), whether or not to perform the notification that affects the profit is determined by the notification lottery (flag conversion lottery) on the main side and does not affect the profit. An example has been described in which whether or not to perform the notification is determined by the notification lottery on the sub side. And as an example of the notification that does not affect the profit, the example of performing the notification for displaying the symbol combination related to the abbreviation “Reach eye lip” during the precursor game has been described. However, the present invention is not limited to this example.

  In recent pachislots, a transition may be made to a state in which it is easy (difficult) to lock the game in accordance with the order of the stop operation. For example, when the order of pressing “left, middle, right” is changed to a state where the game lock is easily performed, and when the order of pressing “right, middle, left” is changed, the state is changed to a state where it is difficult to perform the game lock. There is. In such a pachislot, it is possible to make a transition to a state in which the game lock can be easily performed (difficult) by notifying the pressing order. However, when whether or not to perform the game lock affects the profit, it is necessary to control this notification on the main side. In addition, when whether or not the game lock is performed does not affect the profit, the notification may be controlled on the sub side.

  In addition, as a case where whether or not the game lock is performed has an effect on the profit, for example, a case where the game lock is performed and the ART lottery is won can be considered. On the other hand, the case where whether or not the game lock is performed does not affect the profit is a case where the game lock is performed as an effect. For example, by performing a game lock frequently during a precursor game in which it is determined that a profit (privilege) is to be provided, it is possible to show in a production that a profit will be provided in a subsequent game. .

  Here, with reference to FIGS. 177A and 117B, a description will be given of a configuration example in which the pressing order and the locked state are associated with each other in the fifth modification. Note that FIG. 177A is a diagram illustrating the correspondence between the pressing order and the locked state, and FIG. 177B is a diagram illustrating the relationship between the presence / absence of the game lock on the profit and the notification mode.

  In the example shown in FIG. 177A, if the stop operation is performed in the pressing order of “left, middle, right” when the internal winning combination “F_maintenance lip A” is determined, the lock state becomes “0” (the state where it is difficult to lock). ) To “1” (a state that is easy to lock), and if a stop operation is performed in the pressing order of “left, right, middle”, “middle, left, right” or “middle, right, left”, the current Is maintained, and when the stop operation is performed in the pressing order of “right, left, middle” or “right, middle, left”, the lock state transits from “1” to “0”. Further, when the internal winning combination “F_Maintain Lip B” is determined, if the stop operation is performed in the pressing order of “middle, left, right”, the lock state changes from “0” (a state that is difficult to lock) to “1”. (In a state where locking is easy), and the stop operation is performed in the other pressing order, the current locked state is maintained.

  In the example shown in FIG. 117A, for simplicity of explanation, an example will be described in which the lock state is set to two stages of “0 (a state that is difficult to lock)” and “1 (a state that is easy to lock)”. The present invention is not limited to this. For example, three or more lock states may be provided. Further, in this case, the lock state may not be changed one step at a time, but may be changed in multiple steps at one time.

  In this example, as shown in FIG. 117B, when the game lock affects the profit, the main (main control board 71) performs the notification lottery as to whether or not to perform the notification, and the lottery result. , A predetermined pressing order is notified on both the main side and the sub side. On the other hand, if the game lock does not affect the profit, the sub (sub-control board 72) performs the notification lottery as to whether or not to perform the notification, and based on the lottery result, the sub side determines the predetermined pressing order. Notify.

  As the pachislot, there is a pachislot where the game lock affects the profit over the entire period of the game, and a pachislot where the game lock does not affect the profit over the entire period of the game. Further, as a pachislot, there is a pachislot in which a game lock affects a profit during a predetermined period of a game, but does not affect a profit during a specific period of the game. Therefore, during the period in which the game lock affects the profit, the main side performs the information lottery on whether or not to perform the notification, and notifies the predetermined pressing order on both the main side and the sub side based on the lottery result. On the other hand, during the period in which the game lock does not affect the profit, the sub-side performs the notification lottery as to whether or not to perform the notification, and the sub-side notifies the predetermined pressing order based on the lottery result. Good.

  Since the control of the game lock is usually performed on the main side (main control board 71), the function of shifting the lock state according to the pressing order shown in FIG. 117A is provided on the main control board 71. That is, the main control board 71 randomly determines whether or not to perform the game lock at a probability according to the lock state set by the lock state setting means, which sets the lock state based on the detected order of the stop operation. When the game lock determination means determines that the game lock is to be performed, the game lock determination means also functions as a lock execution means for temporarily stopping the progress of the game. Further, the main control board 71 and / or the sub control board 72 perform a notification lottery to determine whether or not to notify the pressing order when the lock state setting means sets a lock state in which the game lock is easy (difficult). It also functions as a lottery means and a notifying means for notifying a predetermined pressing order based on the lottery result of the notification lottery means.

[Modification 6: Another example of termination condition of normal ART or CT]
The termination condition of the normal ART or CT is not limited to the example described in the above embodiment, and an arbitrary termination condition can be adopted. For example, the number of medals awarded during the normal ART or CT, the number of times the unit game has been consumed during the normal ART or CT, the number of times of notification of information advantageous to the player performed during the normal ART or CT, When the predetermined number of games (for example, 50 games) is one set, end conditions such as the number of sets and the continuation rate at the end of one set can be adopted.

  Further, as a method of counting the number of medals awarded during the normal ART or CT, for example, a method of counting the number of medals paid out in the unit game may be adopted, or the number of medals paid out in the unit game may be used. A method of counting the difference number (net increase number) obtained by subtracting the bet (multiplied) number of medals used in the unit game from the obtained number of medals may be adopted. Also, as a method of counting the number of medals given during the normal ART or CT, a method of calculating based on the actually increased medals (calculation based on actual values) may be employed. Regardless of whether or not the notification is made, a method of calculating based on the number of medals to be increased when following the notification (calculation using an ideal value) may be adopted.

  Further, a configuration in which the number of awarded medals is not increased according to the type of the internal winning combination, that is, a configuration in which the number of awarded medals is not counted as the number of medals or the difference number which is a termination condition of the number of awarded medals may be adopted. . For example, even if some combinations (rare combinations) with a low probability of being determined as an internal winning combination, or a combination whose display / non-display is switched according to the timing of the stop operation, are determined as the internal winning combination. Alternatively, the number of awarded medals may not be increased or decreased (counted).

[Modification 7: Others]
The content of the notification usually performed during ART or CT is not limited to the above-described example, and is arbitrary. For example, the order (push order) of a stop operation in which a special symbol combination that is advantageous to the player may be displayed, or the timing of the stop operation required to display the symbol combination ( (A design to be aimed at) may be notified.

  As a state advantageous to the player, the winning probability of the internal winning combination related to the replay does not change (or changes within a range that does not affect the playability). A function of notifying, that is, a game state in which the AT function operates may be used. Further, as a state advantageous to the player, a replay high probability state (replay time) in which the winning probability of the internal winning combination related to the replay is increased is activated, and a mode of a stop operation advantageous to the player is reported. The function state may be activated, that is, a gaming state in which the ART function is activated.

  Further, in the pachislo 1 of the above embodiment, an example has been described in which various display screens are displayed on the sub-display device 18 provided on the left side of the reel display window 4 when viewed from the player side, but the present invention is not limited to this. . For example, another sub-display device may be provided on the right side of the reel display window 4 when viewed from the player side, and this sub-display device may be configured to display various display screens. In this case, a touch sensor is provided on the display surface of the sub display device provided on the right side of the reel display window 4, and the display screen of the sub display device is switched based on touch input information output from the touch sensor. It may be.

  Further, in the above-described embodiment and various modified examples, the pachislot has been described as an example of the gaming machine, but the present invention is not limited to this. Features other than the features specific to the pachi-slot 1, such as the features relating to the reel control and the features relating to the setting change and confirmation, can also be applied to a gaming machine called "pachinko", and the same effects can be obtained. For example, checksum generation and determination processing, various processing using an instruction code dedicated to the main CPU 101 (address specification processing using a Q register, soft timer update processing, 7-segment LED driving processing, communication data generation and storage processing, etc.) Features such as various processes using the non-standard ROM area and the non-standard RAM area can also be applied to “pachinko”.

<Various functions of main control board and sub control board>
Hereinabove, the pachislot 1 according to the first embodiment of the present invention and various modifications thereof have been described. Here, various functions of the main control board 71 (main control circuit 90, main CPU 101) and the sub control board 72 (sub control circuit 200, sub CPU 201) of the pachislo 1 according to the first embodiment of the present invention are summarized. explain.

  The main control board 71 is connected to the start switch 79 and the stop switch board 80, and controls the progress of the game shown in FIG. Therefore, the main control board 71 functions as start operation detection means, symbol variation means, internal winning combination determination means, stop operation detection means, reel stop control means (stop control means), and winning determination means.

  In addition, when the internal winning combination “F_Probable Chilllip” or “F_1 Probable Chilllip” is determined during the normal ART, the main control board 71 performs the flag conversion lottery, the result of the flag conversion lottery and other internal winning combinations. When the CT lottery based on is won, the CT for extending the duration of the normal ART is started. Therefore, the main control board 71 also functions as conversion lottery means and additional game start means.

  In addition, the main control board 71 adds (extends) the number of ART games indicating the duration of the normal ART according to the internal winning combination during CT. Specifically, when the internal winning combination corresponding to the sub-flag “cactus”, “weak cherry” or “strong cherry” is determined, the main control board 71 adds the ART game number of the normal ART by a predetermined amount, When the internal winning combination corresponding to the sub-flag “triple chip lip (triple chip lip A or triple chip lip B)” is determined, the ART game number of the normal ART is added by a specific amount. Further, the main control board 71 determines that if the number of additions of the ART game based on the sub-flag “3 consecutive chips” is 9 or more, which is more than 8 which is the basic number of games in one set of CT, the addition 1 Increase the amount added per time. Therefore, the main control board 71 also functions as an additional control unit.

  Further, the main control board 71 counts the number of games in which the number of ART games is not added during the CT using the CT game number counter, and terminates the CT when the CT game number counter counts “8”. At this time, if the sub-flag EX “Triple Chile Lip” is won (ie, the flag conversion lottery is won), the main control board 71 resets the CT game of eight sets (eight games) in one set (the number of CT games counter). Reset the value to the initial value). Therefore, the main control board 71 also functions as counting means and additional game ending means.

  Further, when the bonus combination (internal winning combination “F_BB1”, “F_BB2”) is determined as the internal winning combination, the main control board 71 shifts the gaming state to the state between the BB flags (RT5 state) and sets the BB flag. In the interim state, the bonus combination is carried over as the internal winning combination until the bonus is activated (until the bonus combination is won). Therefore, the main control board 71 also functions as bonus carryover means. Further, when the bonus combination is won in the state between the BB flags, the main control board 71 activates the bonus and shifts the gaming state to the bonus state. Therefore, the main control board 71 also functions as bonus start means and advantageous game means.

  In addition, as shown in FIG. 25, in the state between the BB flags, the main control board 71 overlaps the bonus combination with a predetermined internal winning combination combination (“losing”, “F_special 1” to “F_special 3”). If it is determined that the symbol combination (“C_BB1”, “C_BB2”) relating to the bonus combination can be displayed, an internal winning combination other than the bonus combination and the predetermined internal winning combination is performed. Is determined in an overlapping manner, stop control is performed so that the symbol combination relating to the bonus combination cannot be displayed. When the symbol combination relating to the bonus combination can be displayed during the state between the BB flags, the main control board 71 controls the instruction monitor (not shown) of the information display 6 to win the bonus combination. Is displayed, and the bonus instruction information is notified by displaying a numerical value “10” or “11” that uniquely indicates the mode of the stop operation. On the other hand, when the symbol combination relating to the bonus combination cannot be displayed during the state between the BB flags, the main control board 71 does not display (notify) the numerical values “10” and “11” on the instruction monitor. Therefore, the instruction monitor of the main control board 71 and the information display 6 functions as instruction information notification means.

  At this time, the main control board 71 notifies the numerical value “10” or “11” via the instruction monitor only after the bonus notification. Specifically, when the main control board 71 determines the bonus combination as the internal winning combination in a state where the bonus combination is not carried over, the main control board 71 counts the number of subsequent games, and after the counting result reaches the predetermined number, the bonus control is performed. When the winning combination and the predetermined internal winning combination (“outside”, “F_special 1” to “F_special 3”) are determined in an overlapping manner, a numerical value “10” or “11” is notified via the instruction monitor. . Therefore, the main control board 71 also functions as a counting means for counting the number of unit games after determining the bonus combination as the internal winning combination.

  The sub-control board 72 manages the game history based on the various command data received from the main control board 71 and, when receiving a registration operation from the player, receives registration of a player who performs the game. Therefore, the sub-control board 72 functions as a history management unit and a registration receiving unit.

  Further, the pachislot 1 according to the present invention is provided with a display device 11 that performs an effect according to the progress of a game, and a plurality of display devices that are provided separately from the display device 11 and include a top screen 221 and game information screens 223, 224, and 225. And a touch sensor 19 provided on a display unit of the sub-display device 18. The sub-control board 72 controls the operations of the display device 11 and the sub-display device 18. I do. Specifically, when the registration of the player is received, the sub control board 72 controls the sub display device 18 so that the game information screens 223, 224, and 225 can be displayed on the sub display device 18. If the registration of the player has not been received, control is performed so that the game information screens 223, 224, and 225 cannot be displayed on the sub display device 18. Therefore, the sub-control board 72 also functions as a control unit.

  In addition, the main control board 71 also functions as a privilege granting unit in order to grant various privileges according to the result of the game. Specifically, the main control board 71 gives a privilege according to the symbol combination displayed along the activated line.

  For example, in the game in which the internal winning combination “F_3 choice bell_1st” is determined, when the symbol combination related to the abbreviation “Bell” is displayed on the activated line, the main control board 71 gives nine medals, When the symbol combination related to the abbreviation “bell spilled eyes” is displayed on the activated line, the main control board 71 gives 0 medals. Further, for example, in the game in which the internal winning combination “F_Sure Chill Lip” is determined, when the symbol combination related to the abbreviation “3 consecutive Chill Lip” or the abbreviation “Replay” is displayed on the activated line, the main control board 71 The same privilege as the replay is activated. Further, the main control board 71 gives the privilege based on the result of the flag conversion lottery instead of the symbol combination displayed along the activated line. For example, the main control board 71 performs a flag conversion lottery when the internal winning combination “F_Sure Clip” is determined, and gives a benefit such as a CT lottery when the flag conversion lottery is won.

  Further, the sub-control board 72 performs an effect according to the mode of the stop operation via the display device 11. Therefore, the sub control board 72 and the display device 11 also function as an effect executing unit. At this time, when the privilege to be given is different depending on the symbol combination displayed along the activated line, the main control board 71 supplies information uniquely indicating the mode of the stop operation advantageous to the player via the instruction monitor. In the case where the notification and the award given by the symbol combination displayed along the activated line are the same, the mode of the stop operation advantageous to the player is not notified. On the other hand, the sub-control board 72 executes an effect indicating the order of the stop operation, regardless of whether the privilege to be given according to the displayed symbol combination is the same or different.

  In addition, the main control board 71 performs a CT lottery to determine whether or not to start the CT. When the CT lottery is won, the main control board 71 starts the CT after a predetermined number of foreplay games are performed after the winning. Therefore, the main control board 71 also functions as an advantageous state lottery means and an advantageous state start means. Further, at this time, when the internal winning combination “F_Sure Chill Lip” or “F_1 Sure Chill Lip” is determined during the CT precursor game, the sub control board 72 performs the flag conversion lottery on the sub side. Therefore, the sub control board 72 also functions as a notification lottery unit.

  Further, in the pachislo 1 according to the present invention, the main control board 71 gives a privilege based on the result of the flag conversion lottery, and the main control board 71 and the sub-control board 72 are connected via the instruction monitor and display device 11. Notify the pressing order. Therefore, the main control board 71 also functions as a privilege giving unit. In addition, the main control board 71, the sub control board 72, the instruction monitor and the display device 11 also function as notification means.

  Furthermore, in the pachislo 1 according to the present invention, the main control board 71 (main control circuit 90, main CPU 101) performs various control processes over the entire game operation. Therefore, the main control board 71 also functions as arithmetic control means. Further, in the pachislo 1 according to the present invention, the main control board 71 (main control circuit 90, main CPU 101) also functions as an execution unit of various processes described below.

  The main control board 71 (main control circuit 90, main CPU 101) performs a checksum generation process at the time of power failure (see FIG. 77) and a checksum process at the time of power restoration (see FIGS. 79 and 80). Therefore, the main control board 71 also functions as a sum value calculating unit, a sum value subtracting unit, and a sum value determining unit.

  The main control board 71 (main control circuit 90, main CPU 101) performs a winning search process (see FIG. 145). Therefore, the main control board 71 also functions as a privilege grant determination unit and a winning combination determination unit.

  The main control board 71 (main control circuit 90, main CPU 101) performs communication data transmission processing (S904 during the interruption processing in FIG. 158). Therefore, the main control board 71 also functions as a data transmission unit.

  The main control board 71 (main control circuit 90, main CPU 101) performs a setting change confirmation process (see FIG. 68). Therefore, the main control board 71 also functions as a setting change confirmation unit, a start command generation unit, and an end command generation unit.

  The main control board 71 (main control circuit 90, main CPU 101) performs communication data storage processing (see FIG. 72) and communication data pointer update processing (see FIG. 74). Therefore, the main control board 71 also functions as communication data generation means and communication data generation storage means.

  The main control board 71 (main control circuit 90, main CPU 101) performs a 7-segment LED driving process (see FIG. 159). Therefore, the main control board 71 also functions as a 7-segment LED drive unit and an LED drive control unit.

  The main control board 71 (main control circuit 90, main CPU 101) performs a game return process (see FIG. 68). Therefore, the main control board 71 also functions as a game return unit.

  The main control board 71 (main control circuit 90, main CPU 101) performs a medal acceptance / start check process (see FIG. 83). Therefore, the main control board 71 also functions as a game start determination unit and a setting confirmation unit (S233).

  The main control board 71 (main control circuit 90, main CPU 101) performs a medal insertion check process (see FIG. 87). Therefore, the main control board 71 also functions as a game medium reception state determination unit (S255 to S258).

  The main control board 71 (main control circuit 90, main CPU 101) repeatedly executes the interrupt process (see FIG. 158) at a period of 1.1172 msec. Therefore, the main control board 71 also functions as an interrupt processing execution unit and a periodic processing unit.

  The main control board 71 (main control circuit 90, main CPU 101) performs power-on processing (see FIG. 64). Therefore, the main control board 71 also functions as a power return process execution unit.

  The main control board 71 (main control circuit 90, main CPU 101) performs an internal lottery process (see FIG. 92). Therefore, the main control board 71 also functions as internal lottery means.

  The main control board 71 (main control circuit 90, main CPU 101) performs a symbol setting process (see FIG. 97). Therefore, the main control board 71 includes an internal winning combination generating unit (S321), a flag table expanding unit, a winning flag table expanding unit (S324), a flag storage area designating unit, a winning flag storage area designating unit (S329), and flag data. It also functions as a storage unit and a winning flag data storage unit (S330).

  The main control board 71 (main control circuit 90, main CPU 101) performs a symbol code acquisition process (see FIG. 28). Therefore, the main control board 71 also functions as a winning flag storage area designating means (S648) and a symbol code storage area setting means (S650).

  The main control board 71 (main control circuit 90, main CPU 101) performs a reel stop control process (see FIG. 139). Therefore, the main control board 71 also functions as a stop operation detection result acquisition unit (S714) and a stop control data storage area setting unit (source code “LDQ IX, wR1_CTRL- (wR2_CTRL-wR1_CTRL)” in FIG. 139). .

  The main control board 71 (main control circuit 90, main CPU 101) performs a pull-in priority acquisition process (see FIGS. 134 and 135). Therefore, the main control board 71 includes priority stop symbol determining means, optional combination processing means (S680 to S683), winning flag storage area specifying means (S686), winning flag storage area specifying means (S686), and logical product operation means (S686) and also functions as a priority data table acquisition unit (S687).

  The main control board 71 (main control circuit 90, main CPU 101) performs an illegal hit check process (see FIG. 148). Therefore, the main control board 71 also functions as an error detection unit, an error processing unit, a winning flag storage area designation unit (S781), a logical product operation unit (S784), and an error determination unit (S785).

  The main control board 71 (main control circuit 90, main CPU 101) performs a winning check / medal payout process (see FIG. 150). Therefore, the main control board 71 also functions as a game medium payout unit, a game medium addition unit (S805), a payout end determination unit (S807), and a weight generation unit (S808).

  The main control board 71 (main control circuit 90, main CPU 101) performs CT random determination processing during CT (see FIG. 119). Therefore, the main control board 71 also functions as a privilege provision determining unit.

  The main control board 71 (main control circuit 90, main CPU 101) performs a sub flag conversion process (see FIG. 105). Therefore, the main control board 71 also functions as a first sub-flag conversion unit.

  The main control board 71 (main control circuit 90, main CPU 101) performs a flag conversion process (see FIG. 111). Therefore, the main control board 71 also functions as a second sub-flag conversion unit.

2. Second Embodiment Hereinafter, a pachislot machine will be described as an example of a gaming machine according to a second embodiment of the present invention, and its configuration and operation will be described with reference to the drawings. However, the functional flow of the pachislot according to the second embodiment (FIG. 1), the external appearance and internal configuration of the gaming machine housing (FIGS. 2 to 4), and the configuration of the control system circuit and board provided in the pachislot (FIGS. 7 to 7) 10), the configuration of various registers of the main CPU (FIG. 11), and the memory map of the main control circuit (FIG. 12) are the same as the corresponding configurations of the pachislot 1 of the first embodiment. Here, these descriptions are omitted. Further, in the present embodiment, the same components as those in the first embodiment will be described with the same reference numerals.

  In the pachislot 1 of the present embodiment, within the frame of the reel display window 4, a pseudo line (cross-down) connecting the upper region of the left reel 3L, the middle region of the middle reel 3C, and the lower region of the right reel 3R. Line) is defined as an active line for determining whether or not a winning has been achieved.

<Various main game states managed by the main control circuit>
First, in the pachislo 1 of the present embodiment, an RT state and a main game state related to the presence or absence of a bonus operation, which are managed by the main control circuit 90 (main CPU 101), will be described. In the present embodiment, the number of inserted medals (the number of medals) for each unit game in each main game state is three.

[Type of main game state]
In the pachislot 1 of the present embodiment, as the RT states, five types of RT states referred to as “RT0 state” to “RT4 state”, in which combinations of a winning probability of a replay (replay) and a type of a winning replay are different from each other. Is provided. In the present embodiment, as shown in an internal lottery table to be described later (see FIGS. 188 to 195 to be described later), the RT0 and RT1 states are states in which the replay winning probability is low, and the RT2 and RT4 states are. Is a state where the winning probability of the replay is a medium probability (> low probability), and the RT3 state is a state where the winning probability of the replay is a high probability (> medium probability).

  In the present embodiment, a big bonus (BB) is provided as a type of bonus game. The BB in the present embodiment is, like the first embodiment, a RB continuous actuating device that is referred to as a first class special RB, and operates the RB continuously.

  Further, in this embodiment, three types of BBs (combination names “red BB_CD, CU”, “blue BB_CD, CU”, and “mixed color BB_CD, CU” described later) are provided. Hereinafter, the BBs of the combination names “red BB_CD, CU”, “blue BB_CD, CU”, and “mixed color BB_CD, CU” are referred to as “BB3”, “BB2”, and “BB1”, respectively. In the following, the RB that continuously operates in BB1 is referred to as “RB1”, and the RB that continuously operates in each of BB2 and BB3 is referred to as “RB2”.

  In the present embodiment, the operation of the BB, which is started when the symbol combination related to the BB is displayed, ends when the payout of the number of medals exceeding the specified number is performed. Specifically, BB2 and BB3 end when the payout of the number of medals exceeding “297” is performed, and BB1 ends when the payout of the number of medals exceeding “72” is performed. .

  In the present embodiment, the game state (BB state) during the BB operation is also managed by the main control circuit 90 (main CPU 101). In the present embodiment, a game state flag is provided for each type of BB (see FIG. 264 described later), and the presence or absence of BB operation is managed based on the on / off state of the game state flag corresponding to each BB. .

  Further, in the present embodiment, similarly to the first embodiment, the state from the time when an internal winning combination related to BB (hereinafter, referred to as “BB combination”) is won until a winning is achieved, that is, the state between the BB flags A state called a state is also managed by the main control circuit 90 (main CPU 101). In the present embodiment, the state between the BB1 and BB3 flags corresponds to the RT4 state, and the state between the BB2 flags corresponds to the RT0 state. That is, the state between the BB1 and BB3 flags is different from the state between the BB2 flags.

[Transition mode between main game states]
Next, with reference to FIG. 178, a description will be given of transition modes of the above-described various main game states managed by the main control circuit 90 (main CPU 101). FIG. 178 is a diagram showing a transition flow between the main gaming states.

  In the initial state, at the end of BB, and at the time of winning BB2, as shown in FIG. 178, the main gaming state shifts to the RT0 state. That is, the RT0 state also serves as the state between the BB2 flags. When the RT0 state is the state between the BB2 flags, the display combination is treated as invalid even if the transition combination such as a bell spill is stopped and displayed on the activated line (the transition condition to the RT1 state is satisfied). Does not shift to the RT1 state).

  In the RT0 state, when "bell spilled eyes" is displayed, the RT state shifts from the RT0 state to the RT1 state. The “bell spilled eyes” display is a symbol combination displayed when the symbol combination of the small combination relating to the symbol “bell” could not be stopped and displayed on the activated line (missed). Here, a symbol combination according to one of the combination names “RT1 transition 01” to “RT1 transition 27” in a symbol combination table shown in FIG. 181 described later.

  In the RT0 state, when the symbol combination related to BB2 is stopped and displayed on the activated line (at the time of winning BB2), the main game state shifts from the RT0 state (state between BB2 flags) to the BB state. Further, when BB1 or BB3 is won in the RT0 state, the RT state shifts from the RT0 state to the RT4 state (BB1 or BB3 inter-flag state).

  In the RT1 state, when the "RT2 lip" is won, the RT state shifts from the RT1 state to the RT2 state. The “RT2 lip” winning time is when a replay combination corresponding to any of the combination names “RT1RP_1” to “RT1RP_3” in the symbol combination table shown in FIG. 181 described later wins. In the RT1 state, when the BB1 or BB3 is won, the RT state shifts from the RT1 state to the RT4 state (a state between the BB1 or BB3 flags), and when the BB2 is won, the RT state changes from the RT1 state to the RT0 state (BB2 state). (Inter-flag state).

  In the RT2 state, when the "RT3 lip" prize is won, the RT state shifts from the RT2 state to the RT3 state. The “RT3 lip” winning time is when a replay combination corresponding to one of the combination names “RT3RP_1” to “RT3RP_3” in the symbol combination table shown in FIGS. 181 and 182 described below wins. In addition, in the RT2 state, when "bell spilled eyes" is displayed or when "RT1 lip" is won, the RT state shifts from the RT2 state to the RT1 state. Further, in the RT2 state, when the BB1 or BB3 is won, the RT state shifts from the RT2 state to the RT4 state (a state between the BB1 and BB3 flags), and when the BB2 is won, the RT state changes from the RT2 state to the RT0 state (BB2 state). (Inter-flag state).

  In the RT3 state, when "bell spilled eyes" is displayed or when "RT1 lip" is won, the RT state shifts from the RT3 state to the RT1 state. In the RT3 state, when the BB1 or BB3 is won, the RT state shifts from the RT3 state to the RT4 state (a state between the BB1 or BB3 flags), and when the BB2 is won, the RT state changes from the RT3 state to the RT0 state (BB2 state). (Inter-flag state).

  In the RT4 state (the state between the BB1 or BB3 flags), when the symbol combination corresponding to the corresponding BB type (BB1 or BB3) is stopped and displayed on the activated line (at the time of winning BB1 or BB3), the main gaming state is RT4. Transition from the state to the BB state. Also, in the BB state, when the payout of the number of medals exceeding the specified number (“72” in BB1, and “297” in BB2 or BB3) is performed, the BB ends, and the main game state is changed to the BB state. To the RT0 state.

<Various payout states managed by the main control circuit>
The pachislo 1 of the present embodiment is also a gaming machine having an ART function in which the RT function and the AT function operate simultaneously, as in the first embodiment. In this embodiment, whether the ART (AT) function is activated is determined by the main control circuit 90 (main CPU 101). That is, in the pachislo 1 of the present embodiment, the main control circuit 90 (main CPU 101) manages the activation / deactivation of the ART (AT) function that directly affects the payout performance (privilege giving performance). Therefore, the main control circuit 90 (main CPU 101) also manages, as the gaming state, a state related to the payout (medal payout) performance (payout state).

  Here, referring to FIG. 179, the types of the payout states managed by the main control circuit 90 (main CPU 101) of the pachi-slot 1 of the present embodiment, the playability in each payout state, and the various payout states (Transition mode) (game flow) will be described. FIG. 179 is a diagram showing a game flow (transition flow between various payout states) in the pachislo 1 of the present embodiment. In FIG. 179, for convenience of explanation, a bonus state (BB1 to BB3 state) managed as a main game state (not managed as a payout state) is also described.

  In the pachi-slot 1 of the present embodiment, the payout states mainly managed by the main control circuit 90 (main CPU 101) can be broadly classified into two types called "normal state" and "ART state" as shown in FIG. It is a ball-out state. In addition, in the game in the normal state and the ART state in each of the ball-out states, when the player wins the BB combination, the BB game is executed as an interrupt processing, and after the BB game is digested, the ball-out state is changed to the original ball-out state. Return to the state.

  In the normal state, two kinds of payout states called “normal during normal state” and “normal during CZ state” are managed. In the normal medium general state, three types of states "normal A", "normal B", and "normal C" having different effect contents are repeatedly executed in this order. In the “normal A”, “normal B”, and “normal C” states, it is suggested that the state is easily shifted to the normal medium CZ state (easy to win the CZ lottery).

  In the ART state, three types of payout states referred to as “general state during ART”, “state during CZ during ART”, and “state during SZ” are managed. Further, in the general state during the ART, three types of payout states called “ART during the enemy absence state”, “ART during the enemy state”, and “state during the battle B” are managed.

  The ART state shows a specific example of the “notification game state” according to the present invention. The ART-in-enemy absence state indicates a specific example of the “first notification game state” according to the present invention. The state during the battle B shows a specific example of the “second notification game state” according to the present invention. Further, the game in the enemy during ART state is a predetermined unit game according to the present invention, which is "after the end of the game period of the first notification game state and whose game state can shift to the second notification game state". "Shows a specific example. Further, the CZ middle state indicates a specific example of the “specific game state” according to the present invention. Note that BB (BB1 to BB3) is a specific example of the “special game” according to the present invention, and the BB state (BB1 state to BB3 state) is a “special game state” according to the present invention. It shows one specific example.

  Although not shown in FIG. 179, at the time of setting change, a lottery process different from these payout states is performed. Therefore, the main control circuit 90 (main CPU 101) manages the state at the time of setting change as the payout state. . The normal state is basically a ball-out state in which the RT state is mainly one of the RT0 state to RT2 state and the RT4 state and the AT function does not operate. On the other hand, the ART state is basically a payout state in which the RT state is the RT3 state and the AT function operates.

[Normal in normal state]
In the normal state, first, a game in the normal state during the normal state is performed. In the normal state during the normal state, a predetermined number of games (hereinafter, referred to as “cycle games”) are repeatedly played per cycle. In other words, the game mode in the normal medium state is a cycle management type game mode. Hereinafter, a main lottery process performed in a game in a normal medium state and a characteristic game property based on the lottery will be described.

(1) CZ Lottery Mode Cycle Game Number Lottery The number of cycle games in the normal normal state is determined at the end of the normal normal state cycle and when the payout state shifts to the normal state, except when the setting is changed. In the present embodiment, it is determined by a value in the range of “40” to “65”.

  However, when the setting is changed, the value of the quotient obtained when the random number in the range of 0 to 255 is divided by “50” to the number of cycle games determined by lottery (CZ lottery mode cycle game number lottery described later). , And the value of the quotient obtained when the random number value in the range of 0 to 255 is divided by “6”, and the value after the addition becomes the number of periodic games in the first cycle. Therefore, the initial period of the normal state at the time of setting change is longer (about twice as large) than in other cases.

  Further, in the pachislot 1 of the present embodiment, when returning from a power interruption of 4 hours or more, in the effect controlled on the sub side (sub control board 72 side), in the first cycle (the number of remaining games at the time of power interruption), A power return effect such that the normal game and the second cycle of the normal game are executed in one cycle (first cycle) is performed. For example, in the count display effect of the number of remaining cycle games in the first cycle of the normal game started after the return of the power supply, the number of remaining cycle games does not become “0” in the last game of the first cycle but in the last game of the second cycle. An effect that becomes “0” is executed as an effect for power return.

  Due to the method of determining the initial period of the normal state at the time of the setting change and the power return effect performed when returning from the power interruption of 4 hours or more, at the time of setting change and returning from the power interruption of 4 hours or more In both cases, the effect of the first cycle (for example, the display effect of the number of remaining cycle games, etc.) is longer in the effect than in other cases. As a result, it is possible to make it difficult for the player to recognize the difference between the time when the setting is changed and the time when the power is restored after a power interruption of 4 hours or more.

(2) CZ Lottery In the normal middle general state, each game (each game), a shift lottery to the normal middle CZ state (CZ lottery 1 described later) is performed. The state shifts to the normal medium CZ medium state.

  In the normal medium general state, two types of CZ random determination modes (“low accuracy” and “high accuracy”) having different winning probabilities of the shift random determination to the normal medium CZ medium state are provided. The type of the CZ lottery mode is determined by lottery (CZ lottery mode lottery described later) when the unit game in the normal general state ends and when the payout state shifts to the normal state.

  Further, in the normal medium general state, five types of modes (hereinafter, referred to as “cycle management modes”: modes A to E) having different probabilities that the CZ lottery mode is “highly accurate” are provided. The type of the cycle management mode is also determined by lottery (the later-described cycle management mode shift lottery) when the unit game in the normal normal state ends and when the payout state shifts to the normal state.

  In the game in the normal state and during the operation of BB2 or BB3, the lottery for shifting to the normal middle CZ state (CZ lottery 2 described later) is performed using a lottery table different from the CZ lottery 1.

(3) ART Direct Hit Lottery In the normal medium state, a lottery called “ART direct hit lottery” is performed as a direct lottery for each game and the ART state. When the lottery in the ART is won in the normal state during the normal state, the payout state shifts from the normal state to the ART state directly (without passing through the normal medium CZ state).

(4) Premium ART Lottery and Episode BB Lottery In the normal state during the normal state, when BB2 or BB3 wins alone, a lottery called “Premium ART lottery” is performed as a transition lottery to the ART state. When the premium ART lottery is won in the normal normal state, the payout state shifts from the normal state to the ART state (ART no enemy state) after the winning BB game is consumed. In addition, in the ART that has been transferred after winning the premium ART lottery, more benefits are provided to the player than in the ART that has been transferred through another route.

  In addition, when BB2 or BB3 wins in the normal state in the normal state, a lottery called “Episode BB lottery” is performed as a lottery for shifting to the ART state. When the episode BB lottery is won in the normal normal state, the payout state shifts from the normal state to the ART state (ART no enemy state) after the BB game called “Episode BB” is completed. In the episode BB, a special effect of displaying an episode movie of the ally character is performed. Therefore, in the game in the normal state, if the player wins the BB and an episode movie occurs, the transition to the ART is determined.

(5) P-Point Lottery The above-described winning / non-winning of the episode BB lottery is mainly based on a point called “P point” which can be obtained by each game and lottery (P-point lottery) in the normal state during the normal state. Done. Then, in the present embodiment, when the total number of acquired P points becomes larger than “250”, the episode BB lottery is always won (see FIGS. 232 and 233 to be described later). That is, in the normal state during the normal state, if BB2 or BB3 wins independently and the P point is larger than "250", the episode BB lottery is always won and the transition to ART is determined.

  The P point lottery is a game at the end of the game in the normal normal state, at the time of transition to the normal normal state, and in the normal state and the state in which the BB (RB) is operating (hereinafter, also referred to as “normal normal BB state”) Done in Then, the lottery result (“1”, “5”, “10” or “20”) of the P point lottery is added to the current P point. However, if the P point is larger than “250” when the episode BB lottery is won, the point “250” is subtracted from the current P point.

(6) Other gaming properties In the present embodiment, in the normal state, when the transition to the ART state is not determined continuously for a predetermined number of cycles (when returning from the normal middle CZ state to the normal middle general state (CZ Losing) and finalizing the transition to the ART state. That is, the pachislo 1 of the present embodiment has a so-called ceiling function. In the present embodiment, as described later, the number of cycles in the normal state is counted by the cycle number counter. When the cycle number counter reaches “17” (ceiling value), the transition to the ART state is determined.

[Normal CZ state]
In the normal middle CZ state, an ally character (hereinafter abbreviated to “ally character” for short) becomes an enemy character (hereinafter, “CZ enemy character”) in the effect (sub side) over a game period of 15 games + α. ) (A game of “Battle A” in FIG. 179). Then, if an effect in which the ally character wins the CZ enemy character is performed, the transition to the ART state is determined, and if an effect in which the ally character is defeated by the CZ enemy character is performed, the outgoing ball state is set to the normal general state. Return.

  Note that the winning or losing of “Battle A” in the normal medium CZ state is such that a predetermined hit point of the CZ enemy character (hereinafter, referred to as “enemy HP”) is “0” during the game in the normal medium CZ state. It is managed by determining in the internal processing on the main side (main control board 71 side) whether or not the following conditions are satisfied. Hereinafter, main lottery processing performed in a game in the normal medium CZ state and a characteristic playability based on the random determination will be described.

(1) Damage Lottery In the normal middle CZ state, each game (each game), a lottery (damage lottery described later) for determining a subtraction value of the enemy HP of the CZ enemy character is performed, and the damage points obtained in the lottery are determined. Is subtracted from the current enemy HP. In the present embodiment, any one of “6” to “200” is determined as a subtraction value (damage point) of the enemy HP by the damage lottery, and at this time, an effect of reducing the enemy HP on the sub side is performed. Will be If the value of the enemy HP becomes equal to or less than “0” during the period of the normal medium CZ state (15 games + α (the number of games to be continued in the later-described CZ end lottery)), the ally character wins, and the ART is won. The transition to the state is determined. On the other hand, if the value of the enemy HP does not become “0” or less during the period of the normal middle CZ state (15 games + α), the ally character is defeated, and the payout state returns to the normal middle state.

  In the present embodiment, there are three types of CZ enemy characters (CZ enemy characters A to C) set in the normal medium CZ medium state, and the maximum initial value of the enemy HP is “200”. (See FIG. 235 described below). Therefore, when “200” is determined as the damage point by the damage lottery during the normal medium CZ state, the battle A victory is determined at that time, and the transition to the ART state is determined. The type of the CZ enemy character is determined by the CZ enemy character random determination performed in the CZ random determination winning game.

  In addition, in the normal middle CZ state and in the state where BB (RB) is operating, if a hand related to a payout lottery flag B “strong rare” described later (see FIG. 220B described later) is internally won, "200" is set to the damage point. Therefore, in the game in the normal middle CZ state and the BB (RB) operation, when the role of “strong rare” is internally won, the victory of the battle A is determined at that time, and the transition to the ART state is made. Determine.

  In the present embodiment, when the damage points are determined by the damage lottery, an effect of reducing the enemy HP is performed in the game, but the present invention is not limited to this. For example, in a game in which a damage point is determined by a damage lottery, if the effect determined on the sub side does not match the notification of the damage point, the determined damage point is stocked on the sub side and the enemy is stocked. The effect of reducing the HP may not be performed. Then, in this case, the notification effect of the stocked damage points (the effect of reducing the enemy HP collectively) may be executed in a game in which the effect content applicable to the notification of the damage points is determined. At this time, a part of the stocked damage points may be notified, all the damage points may be notified, or the damage points to be notified may be determined by lottery. Further, for example, as an effect at the time of acquiring damage points, an effect may be employed in which the attack power of a friendly character is increased at the time of acquiring damage points.

(2) Special Effect Lottery and Special Effect Game Number Lottery In the game in the normal CZ state, the function of increasing the damage of the enemy character (subtraction value of the enemy HP) over a predetermined number of games ( (Hereinafter referred to as “special effects”). In the present embodiment, two kinds of effects, “strike” and “attack strength UP”, are provided as the special effects. The presence / absence and type of the special effect are determined by a special effect lottery described later (see FIG. 237 described later), and the period of action of the special effect (hereinafter referred to as “the number of special effect games”) is also determined by the number of the special effect games described later. It is determined by lottery (see FIG. 239 described later).

  The special effect “strike” operates during a relatively short number of special effect games (mainly 2 to 4 games), and during the action period of the “strike”, a relatively large number of enemy HP A subtraction value (damage point: “23” or more) is given. It should be noted that “repeated strike” is a specific example of the “special state mode” according to the present invention.

  In addition, various effects are performed by the control of the sub-side during the action period of the “continuous strike”. For example, an effect in which each of a plurality of ally characters alternately attacks a CZ enemy character while sequentially changing, an effect in which one ally character continuously attacks the CZ enemy character over several games, and an ally character is a character in which a CZ enemy character There are effects such as an effect of dodging an attack and then turning into an attack, and an effect of stunning a CZ enemy character by a predetermined game and continuing to attack the stunned CZ enemy character thereafter. In addition, as an effect during the operation period of the “continuous strike”, for example, an effect in which the attack power of the ally character is increased at the time of acquiring the damage point may be adopted.

  On the other hand, the special effect “attack strength UP” acts for a relatively long number of special effect games (mainly 5 to 7 games). Therefore, during the action period of the special effect “attack power UP”, the subtraction value (damage point) of the enemy HP that can be given in each game is relatively small as compared with that of “continuous hit”.

  In the present embodiment, the special effect lottery is performed for each game even during the special effect operation, but the result of the special effect lottery is discarded during the “continuous strike” operation period. On the other hand, during the operation period of the “attack strength UP”, when the “attack strength UP” is determined by the special effect lottery and the number of special effect games is newly determined by the special effect game number lottery, the special effect game number is determined. Is updated (overwritten) with the new value. At this time, if the new number of special effect games is smaller than the number of special effect games before updating, the update processing of the number of special effect games may not be performed.

  In addition, during the operation period of the “attack power UP”, if “strike” is determined by the special effect lottery and the number of special effect games is newly determined by the special effect game number lottery, it is newly determined. During the period of the number of special effect games, the special effect of “attack power UP” and the special effect of “strike” are simultaneously activated. Therefore, in this case, a very large damage point is obtained. Then, after the period in which these two effects simultaneously act is over, if the period of action of the “attack power UP” remains, the “attack power UP” acts alone during that period.

  The special effect lottery is also performed during a period in which the special effect of “attack power UP” and the special effect of “strike” simultaneously operate, but the result of the special effect lottery is discarded. If “non-winning” is determined by special effect random determination during the “attack power UP” operation period, the result of the random determination is discarded, and the “attack power UP” operation period is continued.

(3) CZ end lottery In the game of the fifteenth game in the normal middle CZ state, the CZ end lottery is performed. In this CZ end lottery, if "end" is determined as the lottery result, basically, the payout state returns to the normal state during normal operation. In this CZ end lottery, even if “end” is determined as the lottery result, if the CZ enemy character set in the normal CZ middle state is the CZ enemy character C, the ball is thrown out. Shifts to the ART state (ART no enemy state).

  In the CZ end lottery, if “continue” is determined as the lottery result, the normal medium CZ state is continued.

  Also, in the CZ end lottery, when “resurrection” is determined as the lottery result, it is determined that the enemy HP is set to “0” (transition to the ART state). In the CZ end lottery, in a game in which “resurrection” is determined as a lottery result, a game lock (a game lock for CZ resumption at a later time) is generated after the second stop operation, and the sub side is in the lock period. At the same time, a victory confirmation special effect is performed in which the enemy HP is set to “0” by continuous attacks of the ally characters.

(4) CZ Level Lottery In the normal middle CZ state, three levels (modes) of CZ levels 1 to 3 are provided. The type of the CZ level is determined by the CZ level random determination performed in the CZ winning game.

  In the present embodiment, when the CZ level 3 is set in the 15G game in the normal middle CZ state, the lottery result of the CZ end lottery is always “continue” (see FIG. 242 described later). . That is, in the 15G game during the normal middle CZ state, when the CZ level 3 is set, the game in the normal middle CZ state is continued until the enemy HP becomes “0”. The transition to is confirmed.

(5) Friend HP Addition Lottery When the victory of the ally character is determined in the normal middle CZ state (when it is determined that the enemy HP is set to “0”), that is, when the transition to the ART state is determined, At the end of the final game, an additional lottery is performed on the ally HP. In this team HP addition lottery, if the internal winning combination is a combination relating to a strong rare ("strong cho", "cha eyes, subbell" or "medium cho" described later), a large number of additional HP ("100" to “300”) is always determined (see FIG. 255 described later).

  Then, when the ally HP addition lottery is won, a game lock (a game lock for notifying the ally HP addition notification to be described later) occurs at the time of operating the lever of the next game, and the addition of the ally HP occurs during the lock period. The production to do is performed.

(6) Other gaming properties During the game period in the CZ middle state during traffic, in the effect controlled by the sub side, an effect of displaying the enemy HP and the damage point of the CZ enemy character on the display device 11 is performed. The enemy HP and damage points managed on the main side are displayed by multiplying by 100 without displaying them as they are. For example, when the CZ enemy character set in the normal medium CZ medium state is the CZ enemy character B, the initial value of the enemy HP is managed as “120” on the main side, but is controlled on the sub side. In this effect, it is displayed as “12000”. Further, for example, when the result (damage point) of the damage lottery in the normal middle CZ state is “11”, the damage point is managed as “11” on the main side, but is controlled on the sub side. Is displayed as "1100".

[ART state]
(1) Game Flow During the ART State Next, a transition form between various payout states in the ART state will be described with reference to FIG. In the ART state, ten types of stages (hereinafter, referred to as “ART chapters”) are provided. Then, in the ART state, the level (chapter) of the ART chapter is set to 1 each time the return state returns from the general state during ART to the general state during ART again via the state during CZ during ART and the state during SZ. Step up.

  When the payout state changes to the ART state, first, a game in the general state during the ART is performed. The game period in the general state during ART ends when the hit point of the ally character (hereinafter, referred to as “ally HP”) reaches a predetermined value (“0” in the present embodiment). That is, the end of the general state during the ART is managed based on the value of the ally HP, and the game mode in the general state during the ART is an HP management type game mode. In addition, the ally HP shows a specific example of the “parameter regarding the end timing of the notification game state” according to the present invention.

  In the general state during ART, a game in the ART-free state is performed first. In the ART no enemy state, the ART game in which the ally HP is not subtracted is performed over a period of a predetermined number of games (5 to 100 games).

  In the game in which there is no enemy during the ART, an effect is performed in which the ally character does not encounter an enemy character (hereinafter, referred to as an “ART enemy character”) in the effect controlled on the sub side. Therefore, the state in which there is no enemy during the ART is a game state in a zone that is safe for the ally character in production. The game period in the state of no enemy during ART (hereinafter, referred to as “the number of safe zone games”) is determined by lottery when the payout state shifts to the state of no enemy during ART (see FIG. 244 and FIG. (See FIG. 245).

  Next, when the game in the ART-in-enemy state is exhausted, the payout state shifts to the ART-in-enemy state. In the enemy during ART state, one game is played. In the ART during enemy presence state, an effect is performed in which an ally character encounters an ART enemy character in an effect controlled on the sub side. In this embodiment, seven types of ART enemy characters (ART enemy characters A to G) are prepared (see FIG. 246 described later). It should be noted that the game period in the ART in enemy presence state is not limited to one game, and can be set arbitrarily.

  Next, when a rare combination is internally won in a game in the ART in enemy presence state, the payout state returns to the ART in enemy absence state. At this time, in the effect controlled by the sub side, an effect is performed to avoid a battle with the ART enemy character encountered by the ally character. The rare combination indicates a specific example of the “specific internal winning combination” according to the present invention.

  On the other hand, in a game in the ART in enemy presence state, if a win other than the rare role is internally won, the payout state shifts to the battle B state. The game in the battle B state is performed over a period of two games, and in the effect, an effect is performed in which an ally HP fights against an ART enemy character (battle B). Here, the example in which the game period in the battle B state is two games has been described, but the present invention is not limited to this, and a plurality of games other than the two games may be the game period in the battle B state. . Further, a configuration may be adopted in which the game period in the battle B state is determined by lottery at the time of the transition to the battle B state.

  In the state of the battle B, the result (win / loss) of the battle B between the ally character and the ART enemy character is determined by each game and lottery (reward lottery described later).

  When the result of the battle B (reward lottery described later) is “losing” in both games in the battle B state, the ally HP is subtracted. Then, in the battle B state, if the result of the battle B is “losing” in both games and the value of the ally HP after the subtraction is larger than “0”, the ball-out state is the state in which the enemy is in the ART state. Return to At this time, in the effect controlled by the sub side, an effect is performed in which the ally character loses to the ART enemy character. Note that, in the battle B state, if the result of the battle B is “losing” in both games and the value of the ally HP after the subtraction becomes “0” or less, the ART state ends at that time. The payout state shifts to the normal state during normal operation.

  On the other hand, in the battle B state, if the result of the battle B (reward lottery described later) is not “losing” in both games (if the result of the reward lottery described later is other than “losing” in one game), the game is started. The ball state returns to the no-enemy state during ART (safety zone). At this time, in the effect controlled by the sub side, an effect is performed in which the friend character wins the ART enemy character or escapes from the ART enemy character.

  However, in the present embodiment, in the state during the battle B, the result of the battle B (reward lottery described later) is “losing” in both games, and the value of the ally HP after the subtraction is larger than “0” (“0”). When the event (which becomes 1 or more) continues three times (predetermined number of times) (in the production, when the ally character loses three consecutive battles B), when the third (predetermined number of) events occurs (when three consecutive losses are confirmed) , The ball-out state is shifted to the ART-free state (the safety zone) instead of the ART-friendly state. In the state during the battle B, the value of the ally HP after the third subtraction is equal to or less than “0” even if three events in which the result of the battle B (reward lottery described later) is “lost” continue three times in both games. If so, the ART state ends at that point, and the payout state shifts to the normal medium state.

  Further, in each of the payout states in the general state during the ART, a parameter called “CZ required point” for managing a transition to the state during the ART during CZ is provided. In the present embodiment, a subtraction process is performed. When the updated CZ required point reaches a predetermined value (“0” in the present embodiment) in the general state during ART, the payout state shifts to the state during CZ during ART.

  In the ART during CZ state, the enemy HP is basically subtracted over a game period of 15 games + α (the number of games to be continued in the CZ end lottery), similarly to the above-described game in the normal middle CZ state. Is performed. Note that the enemy HP in the ART during CZ state indicates a specific example of “specific parameters relating to stage transition trigger” according to the present invention.

  The CZ enemy character set in the ART during CZ state is only the CZ enemy character A (the initial value of the enemy HP is “200”). However, in the ART during CZ state, the image of the CZ enemy character displayed in the effect is the image of the boss character associated with the ART chapter currently staying. In other words, in the ART during CZ state, in the effect, an effect is executed in which the ally character plays against the boss character associated with the ART chapter currently staying.

  When the value of the enemy HP becomes equal to or less than “0” in the game in the ART during CZ state, the ally character wins, and the payout state shifts to the SZ state. On the other hand, when the value of the enemy HP is greater than “0” at the time of the end of the CZ during ART state, the ally character is defeated, and the ball returns to the general state during ART (the enemy-less state during ART).

  In the SZ state, if the currently staying ART chapter is any one of “Chapter 1” to “Chapter 8,” ART games of 20 games are performed, and the currently staying ART chapter is “Chapter 9” or later. In the case of, the ART game of 30 games is performed. In the SZ state, a movie display effect of a video with a story is performed over the game period in the SZ state under the control of the sub side. At this time, a movie display effect of a video with a story corresponding to the ART chapter currently staying is performed. That is, the content (story) of the movie display effect changes according to the ART chapter currently staying. Further, in the present embodiment, a movie display effect is performed in which one story is composed of the story of “Chapter 10” from the story of “Chapter 1”.

  As described above, in the ART state, the payout state has a gaming property of returning from the general state during ART to the general state during ART again via the CZ during ART state and the SZ state during ART, and the ART again. Each time the state returns to the medium general state, the ART chapter shifts to the next chapter.

  In such a game flow, for example, in the general state during the ART (the state during the battle B), on the sub-side, an effect of displaying the ally HP and its damage points on the display device 11 is performed. The ally HP and its damage points managed by are displayed 100 times without being displayed as they are. For example, the initial value of the ally HP is managed as “50” on the main side, but is displayed as “5000” in the effect controlled on the sub side. Also, for example, when the result (damage point) of a later-described battle B damage lottery in the battle B state is “11”, the damage point of the ally HP is managed as “11” on the main side, but is managed on the sub side. Is displayed as "1100". The display device 11 is a specific example of the notification unit according to the present invention, and the display device 11 may be configured by a liquid crystal display device.

  Also, for example, during the game period in the ART during CZ state, on the sub side, an effect of displaying the enemy HP of the corresponding chapter enemy character (boss character) and its damage points on the display device 11 is performed. The enemy HP and its damage points managed on the main side are displayed by multiplying by 100 without displaying them. For example, in the ART during CZ state, the initial value of the enemy HP of the CZ enemy character (boss character) is managed as “200” (the same value as the CZ enemy character A) on the main side, but is controlled on the sub side. In the effect, it is displayed as "20,000". Also, for example, when the result (damage point) of the damage lottery in the ART during CZ state is “11”, the damage point is managed as “11” on the main side, but is controlled on the sub side. Is displayed as "1100".

  Furthermore, in the present embodiment, in the effect controlled by the sub side during the ART state, when the value of the chapter of the ART chapter (story) increases (as the story progresses), the ally HP and its damage points, and the enemy HP And each value of the damage point is appropriately increased according to the value of the ART chapter during stay and displayed. For example, an effect of displaying a value obtained by integrating each of these values with the value of the ART chapter during stay (a specific example of a magnification associated with the level of the stage during stay) may be performed. In this case, for example, when the ART chapter during stay is “Chapter 3”, the initial value “50” of the ally HP is displayed as “15000” in the sub-side effect, and the initial value “200” of the enemy HP. Is displayed as "60000". Further, for example, when the damage point of the ally HP or the enemy HP is “11”, it is displayed as “3300” in the sub-side effect.

(2) ART No Enemy State Next, various lottery processes related to the main payout performance and a characteristic game property based on the lottery, which are performed in the game in the ART no enemies state, will be described.

(2-1) CZ Point Lottery In the ART-free state, every game and CZ point lottery are performed. In this lottery, an update (subtraction) point (hereinafter, referred to as a “CZ point”) of a CZ necessary point for managing a transition to an ART during CZ state is determined.

  Then, the current CZ required point is updated with the CZ point determined by the CZ point lottery, and when the updated CZ required point reaches a predetermined value, the transition to the ART during CZ state is determined. In the present embodiment, the CZ required point is subtracted from the initial value by the determined CZ point for each game, and if the subtracted CZ required point reaches “0” (if it becomes “0” or less), The transition to the CRT state during ART is determined. The technique for determining the transition to the CZ during ART state based on the CZ required points is not limited to this example, and the CZ required points are determined from the initial value (for example, “0”) for each game, The CZ required point after the addition may reach a predetermined value (if it exceeds the predetermined value), and the transition to the ART during CZ state may be determined.

(2-2) HP Recovery / Weapon Lottery In the ART-free state, every game, HP recovery / weapon lottery is performed. In this lottery, one of “non-winning”, “HP recovery”, “weapon”, and “ART set A” is determined as the lottery result (see FIGS. 250 and 251 described later). The lottery results “HP recovery”, “weapon”, and “ART set A” are specific examples of the “predetermined privilege that allows the game period in the notification game state to be extended” according to the present invention.

  When "HP recovery" is determined as a lottery result of the HP recovery / weapon random determination, a predetermined HP recovery amount is added (added) to the ally HP, and the game period in the ART state can be extended. The predetermined HP recovery amount to be added is determined by lottery from among a plurality of types of HP recovery amounts (see FIG. 254 described later).

  When the “weapon” is determined as a result of the HP recovery / weapon random determination, a predetermined “number of weapons” (number of times the weapon is used) determined by the random determination is further set. Then, in the game in the battle B state, if the number of weapons is greater than “0”, the number of weapons is decremented by 1 (weapon is used once), whereby the battle B victory is achieved without reducing the number of friendly HP. Determine. At this time, in the effect of Battle B, an effect is performed in which an ally character defeats an ART enemy character using a weapon. Note that, when the ART enemy character is defeated by using the weapon once in the game in the battle B state, a predetermined HP recovery value may be added to the ally HP depending on the ART enemy character. Therefore, even when the "weapon" is determined as the lottery result of the HP recovery / weapon lottery, the ally HP does not decrease in the battle B state, so that the game period in the ART state can be extended. Note that the predetermined number of weapons set at the time of determining the “weapon” is determined by lottery from a plurality of types of the number of weapons (“1”, “2”, or “5”) (see FIG. 256 described later).

  In addition, when “non-winning” is determined as a result of the HP recovery / weapon random determination, the above-described benefits at the time of “HP recovery” and “weapon” winning are not obtained. As described above, in the ART-less enemy state, a game mainly involving “HP recovery” and acquisition of “weapons” is performed.

  The HP recovery / weapon lottery is commonly executed in each of the payout states in the ART state. In addition, HP recovery and weapon random determination are performed even during the BB operation in each of the payout states. At this time, if the internal winning combination is a combination relating to “Strong Cho” described later, “ART SET A” other than the above “non-winning”, “HP recovery”, and “weapon” as the lottery result. May be determined. When "ART set A" is determined as a lottery result of the HP recovery / weapon random determination, "1" is added to "ART set A number" which is one of the parameters indicating the number of ART stocks. In other words, in a game in the ART state and during the BB operation, if the internal winning combination is a combination relating to “Strong Choi”, there is a possibility that one set of ART will be stocked by HP recovery and weapon random determination.

  When the premium ART has been started in the ART-free state, “1” is added to the number of ART sets A. That is, in the premium ART, at least two sets of ARTs are determined. Further, at the start of the premium ART, a value ("13" in the present embodiment) in which the number of times the weapon is used is set as compared with the other ARTs. Therefore, the premium ART is a very advantageous gaming state for the player.

(3) ART Enemy State Next, various lottery processes relating to the main payout performance, which are performed in a game in the ART enemies state, and characteristic playability based on the lottery will be described.

(3-1) CZ Point Lottery Even in the ART enemy presence state, the CZ point lottery is performed in the same manner as in the ART enemy absence state described above. Then, the current CZ required point is updated (subtracted) with the CZ point determined by the CZ point lottery in the ART in enemy presence state, and the updated CZ required point becomes a predetermined value (“0” in the present embodiment). When it has reached, the transition to the ART-in-CZ-in-state is determined.

(3-2) HP Recovery / Weapon Lottery Even in the ART enemy presence state, HP recovery / weapon lottery is performed in the same manner as in the above-mentioned ART enemy absence state. The benefits obtained by the HP recovery / weapon lottery in the ART in-enemy state are the same as those in the ART in-enemy state.

(3-3) Battle B Lottery and Special Mode Content Lottery In the game in the ART in enemy presence state, it is determined whether to shift the ball-out state to the battle B in state (whether to fight or avoid the ART enemy character). Battle B lottery is performed. As the lottery result obtained in the battle B lottery, one of “evasion”, “battle B”, and “special mode” is determined (see FIG. 248 described later).

  When "avoidance" is determined as the lottery result of the battle B lottery, the payout state is returned to the enemy-free state during the ART. In this case, the ART game can be continued without reducing the number of friendly HP. When “Battle B” is determined as a result of the battle B lottery, the payout state is shifted to the battle B state.

  When the “special mode” is determined as the result of the battle B lottery, the special mode is set as the game mode in the ART state. The state in which the special mode is set is a gaming state more advantageous to the player than the state in which these modes are not set.

  When the “special mode” is determined as a result of the battle B lottery, a special mode content lottery for determining the special contents of the special mode is performed. In this special mode content lottery, the special mode type (special mode A or special mode S) and the number of weapons (4 to 7 times) are determined as special mode privilege contents (see FIG. 249 described later). ). In this special mode content lottery, four or more weapon counts are always given.

  When the “special mode” is determined as a result of the battle B lottery and the special mode contents are determined by the special mode content lottery, the ball-out state shifts from the ART during enemies state to the battle B state. I do. In the state during the battle B, a game in which the ally HP is subtracted is mainly performed. However, when the special mode is set, the number of weapons is four or more as described above. Therefore, when the special mode is set, it is guaranteed that the friend character wins the battle B at least four times in the battle B state without reducing the friend HP.

  That is, in the ART state in which the special mode is set, the defeat of the battle B is not determined in the battle B state until the remaining number of weapons determined by the special mode content lottery becomes “0”. (Friend HP does not decrease). Further, in the present embodiment, in the ART state in which the special mode is set, if the remaining number of times of the number of weapons determined by the special mode content lottery becomes “0”, the dispensing state is unconditionally changed to the ART during CZ mode. Transition to the state.

  That is, when the "special mode" is determined as the lottery result of the battle B lottery, the transition to the ART during CZ state is determined without reducing the ally HP and without updating the required CZ point to a predetermined value. I do. Therefore, the state in which the special mode is set is a very advantageous game state for the player.

  The counter for counting the number of weapons determined by the special mode content lottery (the remaining number of times of use of the weapon) (a special mode weapon counter described later) is used when “weapon” is selected in the HP recovery / weapon lottery. It is provided separately from a counter for counting the number of obtained weapons (weapon counter described later).

(4) State during Battle B Next, various kinds of lottery processing related to payout performance, which are performed in a game in the state during battle B, and characteristic playability based on the lottery will be described.

(4-1) CZ Point Lottery Even in the state during the battle B, the CZ point lottery is performed in the same manner as in the above-mentioned ART enemy absence state. Then, the current CZ required point is updated (subtracted) with the CZ point determined by the CZ point lottery during the battle B state, and the updated CZ required point reaches a predetermined value (“0” in the present embodiment). In this case, the transition to the ART during CZ state is determined.

(4-2) Reward Lottery and Battle B Damage Lottery In the state of Battle B, each game and reward lottery are performed. In this lottery, one of “non-winning”, “losing”, “HP recovery”, “weapon”, and “ART set A” is determined as the lottery result (see FIGS. 252 and 253 described later).

  In both of the two games during the game period in the battle B state, when “losing” is determined as a result of the reward lottery, the defeat of the battle B is determined. However, even if the result of the reward lottery is “losing” over two games in the battle B state, if the number of weapons is “1” or more, the weapon is used once, and the ART enemy character who competes is used. Is added to the ally HP. However, if the result of the reward lottery is “losing” and the number of weapons is “0” over the two games in the battle B state, the damage lottery (battle B damage lottery) is performed, and the ally HP A subtraction value (damage point) is determined, and the damage point is subtracted from the current ally HP.

  Then, in the state during the battle B, if the ally HP after subtraction is larger than “0”, the payout state shifts to the enemy during ART state, and if the ally HP after subtraction reaches “0” ( If it becomes "0" or less), the ART ends, and the payout state shifts to the normal state during normal operation.

  When "HP recovery" is determined as a result of the lottery of the reward lottery, a predetermined HP recovery amount is added (added) to the ally HP, and the game period in the ART state can be extended. The predetermined HP recovery amount to be added is determined by lottery from among a plurality of types of HP recovery amounts (see FIG. 254 described later).

  When “weapon” is determined as a result of the reward lottery, a predetermined number of weapons (number of times the weapon is used) determined by the lottery is set. When the number of weapons is greater than “0” in the game in the battle B state, the number of weapons is decremented by one (weapon is used once), thereby reducing the number of friendly HP in the game. Battle B victory is decided without any. At this time, in the effect of Battle B, an effect is performed in which an ally character defeats an ART enemy character using a weapon. Note that, when the ART enemy character is defeated by using the weapon once in the game in the battle B state, a predetermined HP recovery value may be added to the ally HP depending on the ART enemy character. Therefore, even when the "weapon" is determined as a result of the lottery of the reward lottery, the number of friendly HPs does not decrease in the state of the battle B, so that the game period in the ART state can be extended. The number of weapons set at the time of "weapon" determination is determined by lottery from a plurality of types of weapon numbers ("1", "2", or "5") (see FIG. 256 described later).

  When “ART set A” is determined as a result of the reward lottery, “1” is added to ART set A. That is, when the “ART set A” is determined by the reward lottery, the number of ART stocks is increased by one.

  Further, when "non-winning" is determined as a result of the lottery of the reward lottery, the above-described processing at the time of "losing", "HP recovery", "weapon", and "ART set A" winning is not performed.

  In the various types of lottery in the above-described battle B state, lottery is performed based on the internal winning combination. In the battle B state, the role related to “bell” (see the open lottery flag C in FIG. 220C) is two. If the game is won consecutively, the winning combination (predetermined internal winning combination) relating to “Bell”, which has been won for the second time, is converted to the combination relating to “weak che” (see the payout lottery flag C in FIG. 220C). Is done. In other words, when the winning combination related to “Bell” is continuously won over the two games in the battle B state, the second winning combination is treated as a rare combination. Therefore, in the state of the battle B, even if the hand related to the “bell” which is not a rare hand is won for two games in a row, there is a possibility that an advantageous lottery result is given to the player.

  In the present embodiment, in the game in the state of the battle B, the role that can be converted to the rare role has been described by taking the small role related to “bell” as an example. However, the present invention is not limited to this. May be used as a role that can be converted to a rare role. Further, in the present embodiment, in the game in the state of the battle B, when a small role other than the rare role is won for two consecutive games, the internal winning combination of the second game (the small role other than the rare role) is set to “weak”. Although the example of changing to "Cherry" has been described, the present invention is not limited to this, and the internal winning combination (small role other than rare role) of the second game is changed to a rare role other than "weak cherry" (for example, "watermelon"). , Etc.).

(5) CZ state during ART In the game in the CZ state during the ART, basically, various lottery processes related to payout performance similar to the state during the CZ state during the normal state are performed. Specifically, the damage lottery, the special effect lottery, the special effect game number lottery, and the CZ end lottery are performed in the same manner as in the normal medium CZ state. Then, when the enemy HP becomes “0” or less (when specific conditions are satisfied) at the end of the ART-in-CZ-state, the ball-shooting state shifts to the SZ state. The state shifts to the ART general state (ART enemy-free state).

  Further, in the game in the ART during CZ state, the HP recovery and the weapon random determination are performed in each game in the same manner as in the ART during enemy presence state.

  In addition, in the CZ during ART state, when the CZ victory is determined, the lottery on the ally HP is performed in the same manner as in the CZ during normal state. However, in the ART during CZ state, a predetermined minimum guarantee value (in the present embodiment, “10”) of the ally HP is added to the ally HP even if the lottery addition to the ally HP is not won.

  Further, in the ART during CZ state, when the CZ victory is confirmed, ART set number lottery (ART stock lottery) is performed, and the lottery result (set number) is one of the parameters indicating the ART stock number. ART set B number ".

  Here, a description will be given of characteristic playability commonly provided in the normal middle CZ state and the ART middle CZ state. Specifically, a description will be given of the characteristic playability when a BB wins in the normal middle CZ state and the ART middle CZ state.

  In the present embodiment, when a bonus (BB) is won during the game period in the CZ middle state, an effect of bonus notification (game lock for bonus winning) is not generated. In this case, the game after the bonus (BB) prize is a bonus game. However, in the production, until the value of the enemy HP becomes “0” or less, the production in the CZ state (the battle) executed before the bonus prize is won. Direction) is continuously performed. Also, in the bonus game after the bonus prize, the enemy HP is subtracted, and when the value of the enemy HP becomes equal to or less than “0”, the battle effect in the CZ state is ended, and thereafter, the effect content is changed to the effect for the bonus. Switch.

  In addition, in the bonus (BB) game during the game period in the CZ state, “25” (during-prize correction value) is determined as a subtraction value (damage point) of the enemy HP for each game. Further, in the bonus (BB) game during the game period in the CZ state, if the internal winning combination is a combination relating to “strong rare”, “200” is determined as a subtraction value (damage point) of the enemy HP. Is done. That is, in the present embodiment, when the bonus (BB) game is started during the game period in the CZ state, the subtraction value (damage point) of the enemy HP is reliably determined, and depending on the type of the winning combination, The damage that surely sets the enemy HP below “0” (determines the CZ victory) is also determined.

(6) State in SZ In the game in the SZ state, a movie display effect with a story corresponding to the ART chapter during stay is performed. Therefore, in the game in the SZ state, the lottery of the privilege provision such that the game period in the SZ state is extended (added) is not performed. In the SZ state, each game, the above-described HP recovery / weapon random determination, and the HP recovery amount random determination are performed.

<Configuration of data table stored in main ROM>
Next, the configuration of various data tables stored in the main ROM 102 will be described with reference to FIGS. In the following description of the various lottery tables, parameters, sub-flags (payout lottery flags), lottery indices, and the like necessary for the description of the lottery table will be appropriately described.

[Symbol arrangement table]
First, the symbol arrangement table of the present embodiment will be described with reference to FIG. Similar to the first embodiment, the symbol arrangement table of the present embodiment includes the positions of the symbols in the respective rotating directions of the left reel 3L, the center reel 3C, and the right reel 3R, and the symbols arranged at the respective positions. The correspondence with the symbol code specifying the type (see the symbol code table in FIG. 180) is defined.

  In the symbol arrangement table, when the reel index is detected, the position of the symbol located in the middle area of each reel in the frame of the reel display window 4 is defined as “0”. Then, in each reel, the order corresponding to the value of the symbol counter is determined in the order of progressing in the reel rotation direction (the direction from the symbol position “19” in FIG. 180 toward the symbol position “0”) based on the symbol position “0”. “0” to “19” are assigned to each symbol as a symbol position.

  That is, by referring to the value of the symbol counter (“0” to “19”) and the symbol arrangement table, the reels are displayed in the upper, middle, and lower areas of each reel in the frame of the reel display window 4. It is possible to specify the type of symbol that is present. In the present embodiment, the symbols “red 7”, “blue 7”, “BAR”, “watermelon”, “bell 1”, “replay”, “cherry”, “bell 2”, and “bell 3” are used as symbols. And ten kinds of symbols called "blank".

  Further, in the present embodiment, as shown in the symbol code table, "00000001" is assigned as data to the symbol "red 7" (symbol code 1), and the symbol "blue 7" (symbol code 2) is assigned as data. “00000010” is assigned as data. The symbol “BAR” (symbol code 3) is assigned “00000011” as data, and the symbol “watermelon” (symbol code 4) is assigned data “0000100100”.

  "00000101" is assigned as data to the symbol "Bell 1" (symbol code 5), and "00000110" is assigned as data to the symbol "Replay" (symbol code 6). The symbol “Cherry” (symbol code 7) is assigned data “00000111”, and the symbol “Bell 2” (symbol code 8) is assigned data “00001000”. The symbol "bell 3" (symbol code 9) is assigned data "000010001", and the symbol "blank" (symbol code 10) is assigned data "000001010".

[Symbol combination table]
Next, the symbol combination tables (Nos. 1 to 4) will be described with reference to FIGS. Here, in order to clarify the configuration of the symbol combination table (to make it easier to see), the symbol combination table is divided into four tables shown in FIGS. 181 to 184. The four tables 184 are configured as one table.

  The symbol combination table includes a symbol combination (combination and combination name) predetermined in accordance with the type of privilege (bonus, small role, replay), the corresponding display combination code (storage area, data) and payout. The correspondence with the number of sheets is defined.

  In the present embodiment, when the symbol combination displayed by the left reel 3L, the middle reel 3C, and the right reel 3R along the activated line (cross-down line) matches the symbol combination specified in the symbol combination table, a prize is won. Is determined. Then, when it is determined that a winning is achieved, a privilege such as a medal payout, a replay (re-game) operation, and a bonus operation is given to the player. On the other hand, when the symbol combination displayed along the activated line does not match any of the symbol combinations defined in the symbol combination table, the result is a so-called "losing". That is, in the present embodiment, the symbol combination corresponding to “losing” is not defined in the symbol combination table, thereby defining the symbol combination of “losing”. Note that the present invention is not limited to this, and an item of “losing” may be provided in the symbol combination table to directly define the symbol combination of “losing”.

  In addition, the symbol combination table (part 1) shown in FIG. 181 includes the symbol combination (combination name “ RT1 transition 01 "to" RT1 transition 27 ") are also described. The symbol “ANY” in the symbol combination tables (Nos. 2 and 3) shown in FIGS. 182 and 183 indicates an arbitrary symbol drawn on the corresponding reel.

  The various data described in the display combination code column in the symbol combination table are data for identifying the symbol combination displayed along the activated line. “Data” in the display combination code column is represented by 1-byte data, and a unique symbol combination (contents of the display combination) is assigned to each bit in the data.

  In the present embodiment, one type of symbol combination (display combination) is assigned to each bit, but the present invention is not limited to this. For example, in the symbol combination table, one bit data may be assigned to a plurality of types of symbol combinations serving the same type of combination. For example, the combination names “Bell_CD_AAA” to “Bell_CD_CCC” may be combined into one combination name “Bell_CD”. In this case, one bit data is assigned to 27 kinds of symbol combinations of combination names “Bell_CD_AAA” to “Bell_CD_CCC”.

  The data of the “storage area” in the display combination code field is data for designating a symbol code storage area (see FIG. 266 described later) in which data of the corresponding symbol combination is stored. In the present embodiment, 19 symbol code storage areas are provided. In the present embodiment, display combinations having the same bit pattern (1 byte data pattern) and different contents are managed as different display combinations according to differences in “storage area”.

  The numerical value described in the payout number column in the symbol combination table indicates the number of medals to be paid out to the player. In a symbol combination in which one or more numerical values are given as data of the "number of payouts", payout of the same number of medals as the numerical value is performed. For example, in the present embodiment, when the display combination related to the combination name “Bell_CD_AAA” is determined (when the symbol combination related to “Bell_CD_AAA” is stopped and displayed on the activated line), nine medals are paid out. Done. In the present embodiment, the number of inserted medals per unit game (number of medals) is three.

  In the present embodiment, for example, when the display combination associated with the combination name “RT1RP_1” is determined (when the symbol combination associated with “RT1RP_1” is stopped and displayed on the activated line), the replay is activated. Furthermore, in the present embodiment, for example, when the display combination associated with the combination name “red BB_CD” (when the symbol combination associated with “red BB_CD” is stopped and displayed on the activated line), the bonus game (BB3) Operates.

  In the present embodiment, the combination names “JAC_watermelon chance_1” to “JAC_watermelon chance_3” are winning combinations in which the symbol of the right reel 3R is “ANY”, and some of the reels (the left reel 3L and the middle reel 3R) The winning combination is determined based on the symbols stopped on the reel 3C). Further, for example, the combination names “watermelon_CD_1” and “watermelon_CD_2” are winning combinations in which the symbol on the left reel 3L is “ANY”, and the combination symbols “watermelon_CD_1” and “watermelon_CD_2” are stopped symbols on some of the reels (the middle reel 3C and the right reel 3R). This is the role that determines the winning.

  In the present embodiment, the small combination (hereinafter, referred to as “JAC combination”) related to the combination “JAC _ ** _ **” defined in the symbol combination table (No. 2) of FIG. 182 is BB (BB1). BB3) This is a winning combination that can be achieved only in the operating state (three sheets inserted). In the present embodiment, as shown in an internal lottery table for BB (RB) described later (see FIGS. 202 and 203 described later) and a symbol combination table shown in FIGS. In the middle game, when the internal winning combination of the name “F_RB Bell”, “F_RBBAR Alignment” or “F_BAR Loss” is won, the JAC combination of the combination name “JAC_Smelt Chance_1” (the number of medals paid out is 9 ( In addition to the predetermined number of small wins), a small win of the combination name "watermelon_CD_1" (small wins with a medal payout number of 4 (specific number)) can also be won.

  Therefore, when the internal winning combination of the name “F_RB bell”, “F_RBBAR alignment” or “F_BAR loss” is won in the game during the BB operation, for example, the symbol combination “watermelon” − “watermelon” on the activated line -When "watermelon" is stopped and displayed, it means that the small part of the combination name "JAC_watermelon chance_1" and the small part of the combination name "watermelon_CD_1" have won at the same time, and the medals are paid out for both small parts. The total number (13) of the number is paid out. That is, in the present embodiment, by appropriately providing the ANY combination, a plurality of combinations can be simultaneously won without increasing the number of active lines.

  Note that the internal winning combination associated with the combination name “F_watermelon” is a specific example of the “first combination” according to the present invention, and the names “F_RB Bell”, “F_RBBAR aligned”, or “F_BAR loss”. The internal winning combination according to shows a specific example of the “second combination” according to the present invention. The symbol combination according to the combination name “watermelon_CD_1” is a specific example of “specific symbol combination” according to the present invention, and the symbol combination according to the combination name “JAC_watermelon chance_1” is the present invention. Shows a specific example of the “predetermined symbol combination” according to the above.

[Table for bonus activation]
Next, the bonus activation time table will be described with reference to FIG. The bonus operation time table stores a game state flag storage area (see FIG. 264A described later) provided in the main RAM 103, a bonus end number counter, a playable number counter, and a winning number counter when the bonus operation is performed. Data to be specified.

  The game state flag is data for identifying the type of bonus game to be operated. In the present embodiment, three types of BBs (BB1, BB2, and BB3) are provided. In the present embodiment, each BB is managed by a separate game state flag (see FIG. 264A described later).

  The bonus end number counter is data for managing whether or not the payout number of medals has exceeded a prescribed number (payout number) which triggers the end of the bonus game. In the present embodiment, the specified number (payout number) that triggers the end of BB1 is “72”, and the specified number that triggers the end of BB2 and BB3 is “297”.

  The playable number counter is data for managing the number of remaining games that can be played in the operation of the RB, that is, the so-called playable number. The operation of both RB1 and RB2 ends when six games have been played. The prize possible number counter is data for managing the number of remaining games in which the combination of symbols related to prize can be displayed in the operation of the RB, that is, the so-called prize possible number. In the present embodiment, the number of possible prizes for RB1 and RB2 is both six.

[RT transition table]
Next, the RT transition table will be described with reference to FIG. The RT transition table is a table that defines the transition conditions of the transition flow between the RT states described with reference to FIG. 178. Specifically, the RT transition table defines the activation condition and the end condition of each RT state. Then, the main control circuit 90 (main CPU 101) controls the transition operation between the RT0 state and the RT4 state with reference to the RT transition table (refer to RT control processing in FIG. 300 described later).

[Internal lottery table determination table]
Next, the internal lottery table determination table will be described with reference to FIG. The internal lottery table determination table defines the correspondence between the main gaming state, the number of inserted medals, the internal lottery table to be referred, and the number of lotteries.

  Specifically, when the main game state is a normal game state (when the BB is not operating and the non-BB flag is in the state), an internal lottery table for RT0 medium to RT3 medium (described later with reference to FIGS. 188 to 195). ) Is used, and “81” is set as the number of lotteries.

  When the main game state is the state between BB1 flags (RT4 state), an internal lottery table for BB1 flag described later (see FIGS. 200 and 201 described later) is used, and “81” is set as the number of lotteries. You. When the main game state is the state between BB2 flags (RT0 state), an internal lottery table for BB2 flag later (see FIGS. 198 and 199 to be described later) is used, and “81” is set as the number of lotteries. You. When the RT0 state is the state between the non-BB2 flags, an internal lottery table for RT0 described later (see FIGS. 188 to 189 described later) is used, and “81” is set as the number of lotteries. When the main gaming state is the state between BB3 flags (RT4 state), an internal lottery table for BB3 flag described later (see FIGS. 196 and 197 described later) is used, and “81” is set as the number of lotteries. Is set.

  When the main game state is the BB1 state, a BB1 inside lottery table (see FIG. 203 described later) is used, and “7” is set as the number of lotteries. When the main gaming state is the BB2 state or the BB3 state, the BB2 and BB3 middle internal lottery tables (see FIG. 202 described later) are used, and “7” is set as the number of lotteries.

[Internal lottery table]
Next, various internal lottery tables will be described with reference to FIGS. FIG. 188 and FIG. 189 are diagrams showing the configuration of the internal lottery table for RT0 which is referred to when the main game state is the RT0 state. FIG. 190 and FIG. 191 are diagrams showing the configuration of the internal lottery table for RT1 referred to when the main game state is the RT1 state. FIG. 192 and FIG. 193 are diagrams showing the configuration of the RT2 internal lottery table referred to when the main game state is the RT2 state. FIGS. 194 and 195 are diagrams showing the configuration of the internal lottery table for RT3 referred to when the main gaming state is the RT3 state. FIGS. 196 and 197 are diagrams illustrating the configuration of the internal lottery table for the BB3 (red BB) flag which is referred to when the main game state is the state between the BB3 flags (RT4 state). FIG. 198 and FIG. 199 are diagrams showing the configuration of the BB2 (blue BB) flag internal lottery table which is referred to when the main game state is the state between BB2 flags (RT0 state). FIGS. 200 and 201 are diagrams showing the configuration of the BB1 (mixed color BB) flag internal lottery table which is referred to when the main game state is the state between BB1 flags (RT4 state). FIG. 202 is a diagram showing the configuration of the BB2, BB3 (RB2) middle internal lottery table referred to when the main gaming state is the BB2 state or the BB3 state. FIG. 203 is a diagram showing the configuration of the BB1 (RB1) middle internal lottery table referred to when the main game state is the BB1 state. Here, in order to clarify the structure of the internal lottery table (to make it easier to see), each internal lottery table other than the BB medium internal lottery table is shown divided into two tables. The two tables are configured as one table.

  Each of the internal lottery tables (the random number denominator 65536) of the present embodiment includes, in the corresponding main gaming state, winning numbers “0” to “88” (including “losing”) associated with each internal winning combination. The correspondence relationship with the lottery value when the winning number is determined is defined. Further, in each internal lottery table, a lottery value is separately defined according to the settings 1 to 6. In the various internal lottery tables shown in FIGS. 188 to 203, the illustration of the lottery values of the settings 2 to 6 is omitted for convenience of explanation.

  In the internal lottery process using the internal lottery table of the present embodiment, similarly to the first embodiment, first, the random number register 0 of the random number circuit 110 sets a predetermined numerical value range (for example, 0 to 65535). ) Are sequentially added with a random determination value defined corresponding to each internal winning combination. Next, it is determined whether or not the lottery result (lottery value + random number value) exceeds 65535 (whether or not the lottery result overflows). If the lottery result exceeds 65535 in the predetermined internal winning combination, it is determined that the internal winning combination has been won. In the internal lottery process of the present embodiment, an example has been described in which the lottery value is added to the extracted random number value to perform the lottery. However, the present invention is not limited to this, and the lottery value is subtracted from the random number value. It may be determined whether or not the subtraction result (lottery result) is less than “0” (whether or not the lottery result has underflowed) to determine the internal lottery winning / non-winning.

  Therefore, also in the internal lottery process of the present embodiment, the probability that the data (that is, the winning number) to which the internal winning combination is determined is increased as the numerical value defined as the lottery value is larger. Note that the winning probability of each winning number can be represented by “the lottery value associated with each winning number / the number of all random numbers that may be extracted (random number denominator: 65536)”.

(1) RT0 Internal Lottery Table The RT0 internal lottery table is an internal lottery process executed for each unit game when the main game state is the RT0 state and BB2 is not carried over (between non-BB2 flags). Referenced.

  As shown in FIG. 188 and FIG. 189, the RT0 internal lottery table includes winning numbers “0” to “81” (various internal winning combinations including “losing”), and a lottery value associated with each winning number. Define the relationship.

  For example, in the internal lottery process that refers to the setting 1 of the RT0 internal lottery table, the probability that the winning number “1” (the internal winning combination with the name “F_BB3”) is won is 6/65536.

  Further, for example, in the internal lottery process with reference to the setting 1 of the internal lottery table for RT0, the probability that the winning number “31” (internal winning combination with the name “F_Rip”) is won is 8540/65536. Note that the internal winning combination that the replay combination (replaying) alone wins corresponds to the combination from the name “F_Rip” (winning number “31”) to the name “F_RT3 promotion lip_3rd” (winning number “47”). I do. Therefore, for example, in the internal lottery process with reference to the setting 1 of the RT0 internal lottery table, the probability that the replay combination (replay) is won alone is (8504 + 450) / 65536.

  Further, for example, in the internal lottery process with reference to the setting 1 of the RT0 internal lottery table, the probability that the winning number “48” (internal winning combination related to the name “F_common bell”) will be 600/65536. It should be noted that the push order small combination (hereinafter, referred to as “push order bell”) relating to “bell” having a correct answer in the push order of the stop button is from “F_left bell — 1” (winning number “55”) to “F_ This corresponds to the combination associated with “Right Bell — 9” (winning number “81”). Therefore, for example, in the internal lottery process that refers to the setting 1 of the RT0 internal lottery table, the probability of winning the pressing order bell is (543 × 27) / 65536. Note that the winning probability of each internal winning combination related to these “bells” is the same in the RT0 state to the RT3 state and the state between the BB flags, as shown in FIGS.

  Note that, in the following, the internal winning combination related to the names “F_Chance Lip”, “F_Sveribel”, “F_Weak Che”, “F_Strong Che”, “F_Medium Che”, “F_Chance Eye”, and “F_Watermelon” Are collectively referred to as “rare roles”.

(2) RT1 Internal Lottery Table The RT1 internal lottery table is referred to in the internal lottery process executed for each unit game in the RT1 state.

  As shown in FIG. 190 and FIG. 191, the internal lottery table for RT1 includes winning numbers “0” to “81” (various internal winning combinations including “losing”), a lottery value associated with each winning number, and Define the relationship.

  For example, in the internal lottery process that refers to the setting 1 of the RT1 internal lottery table, the probability that the winning number “1” (the internal winning combination with the name “F_BB3”) will be 6/65536, and the RT0 internal lottery table Has the same probability as that of

  Also, for example, in the internal lottery process with reference to the setting 1 of the RT1 internal lottery table, the probability that the winning number “31” (internal winning combination with the name “F_Rip”) will be 0/65536, and the RT1 state In the game of, the internal winning combination with the name “F_Rip” (winning number “31”) is not won. In the RT1 state, the probability that the replay combination (the internal winning combination corresponding to the name “F_Rip” (winning number “31”) to the name “F_RT3 promotion lip — 3rd” (winning number “47”)) is determined as: (450 + 1701 × 5) / 65536, which is almost the same as that of the RT0 internal lottery table.

(3) RT2 Internal Lottery Table The RT2 internal lottery table is referred to in the internal lottery processing executed for each unit game in the RT2 state.

  As shown in FIG. 192 and FIG. 193, the internal lottery table for RT2 includes winning numbers “0” to “81” (various internal winning combinations including “losing”) and a lottery value associated with each winning number. Define the relationship.

  For example, in the internal lottery process referring to the setting 1 of the internal lottery table for RT2, the probability that the winning number “1” (the internal winning combination with the name “F_BB3”) is won is 6/65536, and the internal lottery table for RT0 is Has the same probability as that of

  Also, for example, in the internal lottery process with reference to the setting 1 of the RT2 internal lottery table, the probability that the winning number “31” (internal winning combination with the name “F_Rip”) is won is 0/65536, and the RT2 state In the game of, the internal winning combination with the name “F_Rip” (winning number “31”) is not won. Note that in the RT2 state, the probability that the replay combination (the internal winning combination corresponding to the name “F_Rip” (winning number “31”) to the name “F_RT3 promotion lip — 3rd” (winning number “47”)) is determined as: (450 + 2100 × 5 + 2520 × 5) / 65536, which is higher than that of the RT0 internal lottery table.

(4) RT3 Internal Lottery Table The RT3 internal lottery table is referred to in the internal lottery process executed for each unit game in the RT3 state (mainly the ART state).

  As shown in FIG. 194 and FIG. 195, the internal lottery table for RT3 includes winning numbers “0” to “81” (various internal winning combinations including “losing”), and a lottery value associated with each winning number. Define the relationship.

  For example, in the internal lottery process that refers to the setting 1 of the RT3 internal lottery table, the probability that the winning number “1” (the internal winning combination associated with the name “F_BB3”) is won is 6/65536, and the RT0 internal lottery table Has the same probability as that of

  Further, for example, in the internal lottery processing with reference to the setting 1 of the RT3 internal lottery table, the probability of winning the winning number “31” (internal winning combination with the name “F_Rip”) is 4433/65536. In the RT3 state, the probability that the replay combination (namely, the internal winning combination corresponding to the name “F_Rip” (winning number “31”) to the name “F_RT3 promotion lip — 3rd” (winning number “47”)) is determined as: (4433 + 450 + 8736 × 5) / 65536, which is higher than that of the RT2 internal lottery table. That is, in this embodiment, the probability of winning the replay is high in the RT3 state, medium in the RT2 state, and low in the RT0 and RT1 states.

(5) BB3 Flag Internal Lottery Table The BB3 flag internal lottery table is an internal lottery table executed for each unit game when the main game state is the RT4 state and BB3 is carried over (BB3 flag state). It is referred to in the lottery process.

  As shown in FIGS. 196 and 197, the internal lottery table for the BB3 flag is a lottery number corresponding to each of the winning numbers “0” to “81” (various internal winning combinations including “losing”). Specifies the relationship with the value.

  For example, in the internal lottery process with reference to the setting 1 in the internal lottery table for the BB3 flag, the probability that the winning number “31” (internal winning combination related to the name “F_Rip”) will be 0/65536, and the BB3 flag In the game in the interim state (RT4 state), the internal winning combination with the name “F_Rip” (winning number “31”) is not won. In the state between the BB3 flags (RT4 state), the replay combination (the internal winning combination related to the name “F_Rip” (winning number “31”) to the name “F_RT3 promotion lip — 3rd” (winning number “47”)) is independent. Is (450 + 2099 × 5 + 2520 × 5) / 65536, which is almost the same as that of the RT2 internal lottery table (medium probability).

  In the internal lottery table for the BB3 flag and the internal lottery table for the other BB flags to be described later, an internal winning combination in which the role of BB is independently won, or a combination of BB and a small combination or a replay combination. In some cases, a lottery value of “1” or more is defined for an internal winning combination that is repeatedly won. However, even if these internal winning combinations are won, information on a role related to BB (game state The flag and the special prize winning number) are not overwritten, and the current carry-over gaming state flag is maintained. Therefore, in the state between the BB flags, when the hand related to BB is won alone, the same treatment as “losing” is performed, and when the hand related to BB and the small hand or the replay hand are overlapped and won, Is the same as when the small win or replay wins alone.

(6) BB2 Flag Internal Lottery Table The BB2 flag internal lottery table is an internal lottery table executed for each unit game when the main game state is the RT0 state and BB2 is carried over (BB2 flag state). It is referred to in the lottery process.

  As shown in FIG. 198 and FIG. 199, the internal lottery table for the BB2 flag includes lottery numbers “0” to “81” (various internal winning combinations including “losing”) and lottery numbers associated with the respective winning numbers. Specifies the relationship with the value.

  For example, in the internal lottery process with reference to the setting 1 of the internal lottery table for the BB2 flag, the probability that the winning number “31” (the internal winning combination related to the name “F_Rip”) is won is 8540/65536, and the RT0 is used. It is almost the same as that of the internal lottery table. In the state between the BB2 flags (RT0 state), the replay combination (internal winning combination corresponding to the name “F_Rip” (winning number “31”) to the name “F_RT3 promotion lip — 3rd” (winning number “47”)) is independent. Is (8540 + 450) / 65536, which is almost the same as that of the internal lottery table for RT0 (low probability).

(7) BB1 Flag Internal Lottery Table The BB1 flag internal lottery table is an internal lottery table executed for each unit game when the main game state is the RT4 state and BB1 is carried over (BB1 flag state). It is referred to in the lottery process.

  As shown in FIGS. 200 and 201, the internal lottery table for the BB1 flag includes lottery numbers “0” to “81” (various internal winning combinations including “losing”) and lotteries associated with the respective winning numbers. Specifies the relationship with the value.

  For example, in the internal lottery process with reference to the setting 1 in the internal lottery table for the BB1 flag, the probability that the winning number “31” (the internal winning combination related to the name “F_Rip”) will be 0/65536, and the BB1 flag In the game in the interim state (RT4 state), the internal winning combination with the name “F_Rip” (winning number “31”) is not won. In the state between the BB1 flags (RT4 state), the replay combination (name “F_Rip” (winning number “31”) to the internal winning combination related to the name “F_RT3 promotion lip — 3rd” (winning number “47”)) is single. Is (450 + 2099 × 5 + 2520 × 5) / 65536, which is almost the same as that of the RT2 internal lottery table (medium probability).

(8) BB2, BB3 Medium Internal Lottery Table The BB2, BB3 medium internal lottery table is referred to in the internal lottery processing executed for each unit game in the BB2 state or the BB3 state.

  As shown in FIG. 202, the BB2 and BB3 middle internal lottery tables are associated with the winning numbers “0” and “82” to “88” (various internal winning combinations including “losing”) and the respective winning numbers. The relationship with the determined lottery value is defined.

  In the internal lottery process with reference to the setting 1 of the BB2, BB3 intermediate internal lottery table, the names “F_RB Bell” (winning number “82”), “F_RB Sveliber” (winning number “83”), and “F_RB weak check” ( The internal winning combination relating to any one of the winning number “84”), the “F_RB strong check” (winning number “85”) and the “F_RB chance” (winning number “87”) is always won. That is, in the BB2 state or the BB3 state, the internal winning combination associated with the names “out” (winning number “0”), “F_RBBAR alignment” (winning number “86”), and “F_RBBAR loss” (winning number “88”) is Does not win.

  Also, as is clear from the BB2 and BB3 middle internal lottery tables shown in FIG. 202, in the internal lottery process referring to the setting 1 of the BB2 and BB3 middle internal lottery tables, the name “F_RB bell” (winning number “82”) ) Has the highest probability of winning the internal winning combination, and the probability is 59786/65536.

(9) BB1 Medium Internal Lottery Table The BB1 medium internal lottery table is referred to in the BB1 state in an internal lottery process executed for each unit game.

  As shown in FIG. 203, the BB1 medium internal lottery table includes, as shown in FIG. 203, the lottery numbers “0” and “82” to “88” (various internal winning combinations including “losing”), and the lottery associated with each winning number. Specifies the relationship with the value.

  In the internal lottery process with reference to the setting 1 of the BB1 medium internal lottery table, the internal winning combination related to any of the names “F_RB Bell” (winning number “82”) to “F_RBBAR Loss” (winning number “88”) , Be sure to win. That is, in the BB1 state, the internal winning combination associated with the name “losing” (winning number “0”) is not won.

  As is clear from the internal BB1 internal lottery table shown in FIG. 203, in the internal lottery processing with reference to the setting 1 of the internal BB1 internal lottery table, the name “F_RB Bell” (winning number “82”) or “F_RB” The probability of winning the internal winning combination relating to “weak che” (winning number “82”) is high, the probability of the former is 27964/65536, and the probability of the latter is 31500/65536.

[Correspondence between winning numbers, special prize winning numbers, and small winning numbers]
Also in the present embodiment, as in the first embodiment, the internal winning combination (BB combination) related to BB is associated with a special prize winning number for each type, and the small combination or the replay combination is provided. Is associated with a small winning combination number for each type.

  Here, FIG. 204 shows a correspondence table between BB internal winning combinations and special prize winning numbers, and FIGS. 205A and 205B show correspondence tables between small winning combinations or replay combinations and small winning combinations. In the present embodiment, as shown in FIG. 204, special prize winning numbers “1”, “2”, and “3” are associated with BB combinations with names “F_BB1”, “F_BB2”, and “F_BB3”, respectively. In the present embodiment, as shown in FIGS. 205A and 205B, the small wins and the replay wins with the names “F_Rip” to “F_RBBAR Loss” are respectively associated with the small win win numbers “1” to “58”. .

  In the present embodiment, a value obtained by adding a small winning combination number to a value obtained by multiplying the special prize lottery number by “59” (special prize number) is referred to as “winning request flag status”, and the corresponding request flag status is associated with the winning number. . For example, the winning request flag status “59” is associated with the winning number “1” (name “F_BB3”), and the winning request flag status “80” on the winning number “7” (name “F_BB3 + F_strong”). (= 1 × 59 + 21) ”. For example, the winning request flag status “1” is associated with the winning number “31” (name “F_lip”), and the winning request flag “48” (name “F_common bell”) is The status “18” is associated with the status.

  In the present embodiment, the special prize winning number and the small winning combination number are acquired (extracted) based on the result (winning number) of the internal lottery process. The procedure is as follows. First, when a winning number is determined by the internal lottery process, a winning request flag status associated with the winning number is obtained. Next, the obtained hit request flag status is divided by "59" (special prize number). Then, the value of the quotient obtained by the division is set as a special prize winning number, and the remaining value is set as a small combination winning number.

[Symbol combination determination table]
Next, the symbol combination (display combination) determination table will be described with reference to FIGS. Here, in order to clarify the configuration of the symbol combination determination table (to make it easier to see), the symbol combination determination table is divided into twelve tables, but actually, the twelve tables are one. Configured as a table.

  The symbol combination determination table defines the correspondence between various internal winning combinations and the symbol combinations (combinations) that can be displayed on the activated line (cross-down line) and are associated with each internal winning combination. That is, when the internal winning combination is determined, the type of the symbol combination that can be displayed on the activated line (the type of the display combination that can be won) is uniquely determined.

  The symbol “○” described in the symbol combination determination table indicates a symbol combination (combination) that can be displayed on the activated line in the determined internal winning combination, that is, a display combination that enables winning. For example, when the internal winning combination of the name “F_Rip” is determined, as shown in FIGS. 206 to 209, the combination names “maintain RP_UP_1” to “maintain RP_UP_3” and “maintain RP_CE_01” to “maintain RP_CE_12” The symbol combination can be stopped and displayed. Note that the case where the internal winning combination is “losing” is not defined in the symbol combination determination table, but this is the case of all the symbol combinations defined by the symbol combination tables shown in FIGS. 206 to 217. Indicates that display is not allowed.

  In the pachislo 1 of the present embodiment, the main control circuit 90 (main CPU 101) changes the stop control according to the internal winning combination and the gaming state, and when the predetermined combination is determined as the internal winning combination, the main control circuit 90 (FIG. The rotation stop control of the left reel 3L, the center reel 3C, and the right reel 3R is performed so that the symbol combination (combination) of the correspondence shown in FIG. 217 can be displayed.

[Symbol winning prize operation flag data table]
Next, the symbol corresponding winning operation flag data table will be described with reference to FIG. The symbol corresponding winning operation flag data table defines the correspondence between the reel type and the data of the internal winning combination that can be displayed according to the symbol of each reel displayed on the activated line. That is, by referring to the symbol corresponding winning operation flag data table, the internal winning combination that can be displayed at that time can be determined. The symbol corresponding winning operation flag data table is provided corresponding to the symbol combination table (see FIGS. 181 to 184).

  For example, when the symbol "blank" is stopped and displayed on the activated line of the left reel 3L, it can be displayed in the storage areas 0 to 18 corresponding to the symbol code "00001010" (blank) in the reel type "left". “1” is stored in the bit corresponding to the internal winning combination (for example, bits 2 to 4 of the storage area 18). The data defined in the symbol corresponding winning operation flag data table is stored by ANDing data stored in a symbol code storage area described later (see FIG. 266 described later).

[Correspondence between internal winning combination and sub-flag]
In the pachislo 1 of the present embodiment, the information regarding the internal winning combination (the information included in the start command) transmitted from the main control circuit 90 to the sub-control circuit 200 is not the information of the internal winning combination itself but the information of the internal winning combination. This is information converted into flag data called “sub-flag”.

  Here, FIGS. 219A and 219B show correspondence tables between the internal winning combination (small combination and replay combination) and the sub-flag. In addition, in the correspondence table, “outside” (winning number “0”) is described as an internal winning combination, and a subflag name and a subflag number are also described.

  In the conversion processing of the internal winning combination into the sub-flag in the present embodiment, a plurality of internal winning combinations belonging to the same type are combined into one sub-flag. By this flag conversion, in the present embodiment, as shown in FIGS. 219A and 219B, 59 internal winning combinations (winning numbers “0” to “59”) relating to the small combination and the replay combination are replaced with 12 types of sub flags (sub flags). Numbers “0” to “11”: flag data). That is, by the flag conversion, information on the internal winning combination is compressed, and the capacity of the information included in the start command can be reduced.

  For example, the internal winning combination (replay combination) for the names “F_RT2 promotion_123” to “F_RT2 promotion_3rd”, “F_maintenance_123” to “F_maintenance_3rd” and “F_RT3 promotion_123” to “F_RT3 promotion_3rd” are all included. , Is converted to a subflag “push order lip” (subflag number “3”). Also, for example, the names “F_left bell_1” to “F_left bell_9”, “F_middle bell_1” to “F_middle bell_9”, “F_right bell_1” to “F_right bell_9”, and “F_RBBAR loss” Are converted to the sub-flag “push order bell” (sub-flag number “11”).

  For example, the internal winning combination (small hand) associated with the names “F_common bell” and “F_RB bell” are both converted to the sub-flag “common bell” (sub-flag number “4”), and the names “F_sliver bell” and “F_RB” Any internal winning combination (small winning combination) related to “Sbelibel” is converted to a subflag “Sliverbel” (subflag number “5”). For example, the internal winning combination (small winning combination) relating to the names “F_weak che” and “F_RB weak che” are both converted to the sub flag “weak che” (sub flag number “6”), and the names “F_strong che” and Any internal winning combination (small win) related to “F_RB strong check” is converted to a sub flag “strong check” (sub flag number “7”). Further, the internal winning combination (small hand) related to the names “F_medium cho” and “F_RBBAR alignment” are both converted into the sub flag “medium cho” (sub flag number “8”), and the names “F_chance chance” and “ Each of the internal winning combinations (small wins) related to the “F_RB chance” is converted into a sub-flag “chance” (sub-flag number “10”).

  For other internal winning combinations, one sub-flag is associated with one internal winning combination. Specifically, the name “out” is converted to a sub flag “out” (sub-flag number “0”). The replay combination according to the name “F_Rip” is converted into a sub flag “Lip” (sub flag number “1”), and the replay combination according to the name “F_Chance Lip” is converted into a sub flag “chan lip” (sub flag number “2”). Is converted. Further, the small win associated with the name “F_watermelon” is converted to a subflag “watermelon” (subflag number “9”).

[Correspondence between sub-flag and payout lottery flag]
In the present embodiment, the main control circuit 90 performs various lottery processes related to control of payout performance (control of the AT function (ART), etc.). A lottery value is defined not for each winning combination or sub-flag but for each flag referred to as a “ball out lottery flag” set in association with the type of sub-flag. In the present embodiment, when performing lottery processing with reference to these lottery tables, first, the internal winning combination is converted into a sub-flag, and then the sub-flag generated by the conversion is further converted into a payout lottery flag. Then, a lottery process is performed based on the payout lottery flag generated by the conversion.

  In the process of converting the sub-flag into a payout lottery flag, a plurality of subflags belonging to the same type are combined into one payout lottery flag. By performing such conversion, the data capacity of the lottery table relating to the payout performance can be reduced.

  Therefore, before describing various lottery tables used for controlling the payout performance, the correspondence between the sub-flag and the payout random determination flag will be described. In this embodiment, three types of payout random determination flags (a payout random determination flag A, a payout random determination flag B, and a payout random determination flag C) are provided.

  Here, FIGS. 220A to 220C show correspondence tables between the sub-flag and various payout lottery flags. FIG. 220A is a correspondence table between the sub-flag and the lottery lottery flag A, FIG. 220B is a correspondence table between the sub-flag and the lottery lottery flag B, and FIG. Is a correspondence table. In each correspondence table, a payout lottery flag name and a flag number are also described.

(1) Rollout lottery flag A
In the flag conversion from the sub-flag to the ball-out lottery flag A, as shown in FIG. 220A, 12 types of sub-flags (sub-flag numbers “0” to “11”) are converted into seven types of ball-out lottery flags A (flag A number “ 0 "to" 6 ": flag data).

  Specifically, the sub-flag “losing” (sub-flag number “0”) is converted into a payout lottery flag A “other” (flag A number “0”). Both the sub-flag “Rip” (sub-flag number “1”) and the sub-flag “push order lip” (sub-flag number “3”) are converted into a payout lottery flag A “replay” (flag A number “1”). The sub-flag “chan lip” (sub-flag number “2”), the sub-flag “weak che” (sub-flag number “6”) and the sub-flag “watermelon” (sub-flag number “9”) are all ball-drawing lottery flags A “weak rare role” (Flag A number “3”).

  Both the sub-flag “common bell” (sub-flag number “4”) and the sub-flag “push order bell” (sub-flag number “11”) are converted to a payout lottery flag A “bell” (flag A number “2”). . Both the sub-flag “Sveribel” (sub-flag number “5”) and the sub-flag “chance eye” (sub-flag number “10”) are converted to the payout lottery flag A “cha eye, subbel” (flag A number “5”). You. Also, the sub-flag “Strong Cho” (sub-flag number “7”) is converted into a payout lottery flag A “Strong Cho” (flag A number “4”), and the sub-flag “medium cho” (sub-flag number “8”) Is converted to a payout lottery flag A "medium cho" (flag A number "6").

(2) Outgoing lottery flag B
In the flag conversion from the sub-flag to the ball-out lottery flag B, as shown in FIG. 220B, 12 types of sub-flags (sub-flag numbers “0” to “11”) are replaced by five types of ball-out lottery flags B (flag B number “ 0 "to" 4 ": flag data).

  Specifically, the sub-flag “losing” (sub-flag number “0”) is converted into a payout lottery flag B “other” (flag B number “0”). Both the sub-flag “Rip” (sub-flag number “1”) and the sub-flag “push order lip” (sub-flag number “3”) are converted into a payout lottery flag B “replay” (flag B number “1”). The sub-flag “chan lip” (sub-flag number “2”), the sub-flag “weak che” (sub-flag number “6”), and the sub-flag “watermelon” (sub-flag number “9”) are all available lottery flags B “weak rare” ( Flag B number "3").

  Both the sub-flag “common bell” (sub-flag number “4”) and the sub-flag “push order bell” (sub-flag number “11”) are converted to the payout lottery flag B “bell” (flag B number “2”). . Subflag "Sveribel" (subflag number "5"), subflag "strong che" (subflag number "7"), subflag "medium che" (subflag number "8"), and subflag "chance eye" (subflag number "10") Are converted to the payout lottery flag B “strong rare” (flag B number “4”).

(3) Outgoing lottery flag C
In the flag conversion from the sub-flag to the ball-out lottery flag C, as shown in FIG. 220C, 12 types of sub-flags (sub-flag numbers “0” to “11”) are replaced with nine types of ball-out lottery flags C (flag C number “ 0 "to" 8 ": flag data).

  More specifically, the sub-flag “losing” (sub-flag number “0”), the sub-flag “lip” (sub-flag number “1”), and the sub-flag “push order lip” (sub-flag number “3”) are all payout lottery flags. It is converted to C "Nip Lip" (flag C number "0"). The sub flag “chan lip” (sub flag number “2”) is converted into a payout lottery flag C “chan lip” (flag C number “4”).

  Both the sub-flag “common bell” (sub-flag number “4”) and the sub-flag “push order bell” (sub-flag number “11”) are converted to a payout lottery flag C “bell” (flag C number “1”), The sub-flag "sliver bell" (sub-flag number "5") is converted to a payout lottery flag C "sliver bell" (flag C number "6"). The sub-flag “weak che” (sub-flag number “6”) is converted into a payout lottery flag C “weak che” (flag C number “3”), and the sub-flag “strong che” (sub-flag number “7”) is output. It is converted into a ball lottery flag C “Strong Cho” (flag C number “5”), and the sub flag “medium cho” (sub flag number “8”) is a payout lottery flag C “medium cho” (flag C number “8”). ).

  Also, the sub-flag “watermelon” (sub-flag number “9”) is converted to a payout lottery flag C “watermelon” (flag C number “2”), and the sub-flag “chance eye” (sub-flag number “10”) is output. It is converted into a ball lottery flag C “chance eye” (flag C number “7”).

[CZ lottery mode lottery table]
Next, the CZ random determination mode random determination table will be described with reference to FIGS. FIG. 221 is a diagram showing the configuration of the CZ lottery mode lottery table. FIG. 222 shows the correspondence between the lottery index numbers defined in the CZ lottery mode lottery table and the lottery parameters used in the CZ lottery mode lottery. FIG.

  The CZ lottery mode lottery table (random number denominator 128) is used in the CZ lottery mode lottery executed in the game in the normal state, and is a lottery table for determining the CZ lottery mode (“low certainty” or “high certainty”). is there. In the CZ lottery mode lottery table, for each lottery index number ("0" to "4") associated with a lottery parameter, a lottery result ("low" or "high") is set for each lottery result. The corresponding relationship with the determined lottery value is defined.

  In the present embodiment, the lottery parameter used in the CZ lottery mode lottery is a set value or a cycle management mode as shown in FIG. In this embodiment, five types of modes (modes A to E) are provided as cycle management modes. The setting values (setting 1 to setting 6) are used as the lottery parameters of the CZ lottery mode lottery only in the lottery at the time of changing the setting, and in the CZ lottery mode lottery performed at other timings, the cycle management is performed. The modes (modes A to E) are used as lottery parameters for the CZ lottery mode lottery. The setting values (setting 1 to setting 6) show a specific example of “setting parameters provided for adjusting the probability of giving a privilege to a player” according to the present invention.

  Each lottery parameter is associated with a predetermined lottery index. Specifically, setting 1 to setting 6 are associated with a lottery index number “0”. In addition, the lottery index number “2” is associated with the mode A, the lottery index number “3” is associated with the mode B, and the lottery index number “4” is associated with the modes C to E. Have been.

  Therefore, for example, when the CZ lottery mode lottery is performed at a timing other than when the setting is changed, and the current cycle management mode is any of the modes C to E, the lottery index number of the CZ lottery mode lottery table “ The lottery value specified in the column of "4" is referred to, and the lottery is performed. In this case, the probability that “high accuracy” is determined as the lottery result is 50%. In the present embodiment, as is clear from the CZ lottery mode lottery table shown in FIG. 221, the more the set cycle management mode shifts to the mode E (high level) side, the more “highly accurate” the CZ lottery mode becomes. Is more likely to be determined.

[CZ lottery mode cycle game number lottery table]
Next, the CZ lottery mode cycle game number random determination table will be described with reference to FIG. FIG. 223 is a diagram illustrating a configuration of the CZ random determination mode cycle game random determination table.

  The CZ lottery mode cycle game number lottery table (random number denominator 256) is used in the CZ lottery mode cycle game number lottery performed in the game in the normal state, and is a game period per cycle in the normal state in the normal state, that is, one cycle. It is a lottery table for determining the number of games per minute. In the CZ lottery mode cycle game number lottery table, a lottery result (the number of CZ lottery mode cycle games: 40, 45, 50, 40, 45, 50) is set for each type of the currently set CZ lottery mode (“low certainty” or “high certainty”). 55, 60, or 65) and a lottery value set for each lottery result. It should be noted that the number of CZ lottery mode cycle games indicates a specific example of “one cycle of the game period” according to the present invention.

  As is clear from the CZ lottery mode number game random determination table shown in FIG. 223, when the set CZ lottery mode is “high accuracy”, the number of periodic games of 40 games or more is determined as the lottery result. There is a possibility that 40 or 55 games can be easily determined as the number of periodic games. On the other hand, when the set CZ lottery mode is “low accuracy”, the number of periodic games of 50 or more may be determined as a result of the lottery, and 60 or more games are determined as the number of periodic games. It is configured to be easily operated. That is, when the set CZ lottery mode is “low accuracy”, the game period per cycle of the normal normal state can be longer than when the CZ lottery mode is “high accuracy”. The nature becomes high.

[CZ lottery 1 table]
Next, the CZ lottery 1 table will be described with reference to FIGS. 224 and 225. FIG. 224 is a diagram showing the configuration of the CZ lottery 1 table, and FIG. 225 is a diagram showing the correspondence between the lottery index numbers defined in the CZ lottery 1 table and the lottery parameters used in the CZ lottery 1. is there.

  The CZ lottery 1 table (the random number denominator 128) is used in the CZ lottery 1 performed in the game in the normal state, and is a lottery table for determining the winning / non-winning of the transition to the normal CZ medium state. In the CZ lottery 1 table, a lottery result (“winning” or “non-winning”) and a lottery result are set for each lottery index number (“0” to “13”) associated with the lottery parameter. The correspondence with the lottery value is defined.

  In this embodiment, as shown in FIG. 225, the lottery parameters used at the time of the CZ lottery 1 are a set value, a CZ lottery mode, and a payout lottery flag C (internal winning combination). In the present embodiment, a combination of the set value, the CZ lottery mode, and the payout lottery flag C is associated with a lottery index number defined in the CZ lottery 1 table.

  For example, if the setting value is setting 2, the CZ lottery mode is “low accuracy”, and the payout lottery flag C is “weak”, the lottery index number “3” is acquired. In this case, in the CZ lottery 1, the lottery value specified in the column of the lottery index number “3” of the CZ lottery 1 table is referred to, and the probability of winning the transition to the normal middle CZ state is 3/128.

  As apparent from the CZ lottery 1 table shown in FIG. 224, when the lottery index number is “13”, in the CZ lottery 1, the transition to the normal medium CZ state is determined with a probability of 100%. You. When the lottery index number is “13”, as shown in FIG. 225, it is a case where the payout lottery flag C is “medium cho” regardless of the set value and the type of the CZ lottery mode. That is, in the game in the normal middle general state, if the internal winning combination related to the payout lottery flag C “medium cho” is won, the transition to the normal middle CZ state is determined.

  Further, as is apparent from the CZ lottery 1 table shown in FIG. 224, in the CZ lottery 1, as the lottery index number increases, the winning probability of transition to the normal medium CZ state tends to increase. However, when the lottery index number is “2”, the probability of winning the transition to the normal middle CZ state is higher than in the case of the preceding and following lottery index numbers. When the lottery index number is “2”, as shown in FIG. 225, the setting value is an even number setting, the CZ lottery mode is “high accuracy”, and the payout lottery flag C is “weak”. This is the case. That is, when the even number setting is performed and the payout lottery flag C is “weak”, the probability that the transition to the normal middle CZ state is determined is increased. Therefore, in the present embodiment, whether the set value is an even number setting or an odd number setting is indicated by the frequency of transition to the normal medium CZ state when the payout lottery flag C is “weak”. Can be.

[CZ lottery 2 table]
Next, the CZ lottery 2 table will be described with reference to FIG. FIG. 226 is a diagram illustrating the configuration of the CZ lottery 2 table.

  The CZ lottery 2 table (random number denominator 128) is used in the CZ lottery 2 performed in the game in the normal state and during the operation of BB2 or BB3, and is used to determine the winning / non-winning of the transition to the normal CZ state. Is a lottery table. In the CZ lottery 2 table, the correspondence between the lottery result (“winning” or “non-winning”) and the lottery value set for each lottery result is determined for each type of payout lottery flag C (internal winning combination). Stipulate.

  As is clear from the CZ lottery 2 table shown in FIG. 226, in the CZ lottery 2, when the payout lottery flag C is any one of “weak che”, “strong che”, “slibel” and “chance eye” Only the transition to the normal middle CZ state may be won, and the other payout lottery flag C does not necessarily win the transition to the normal middle CZ state.

[Cycle control mode shift lottery table]
Next, with reference to FIG. 227 and FIG. 228, the cycle management mode shift lottery table will be described. FIG. 227 is a diagram showing the configuration of the cycle management mode transition lottery table. FIG. 228 is a diagram showing the lottery index numbers specified in the cycle management mode transition lottery table and the lottery parameters used in the cycle management mode transition lottery. It is a figure showing a correspondence.

  The cycle management mode transition lottery table (random number denominator 256) is used in the cycle management mode transition lottery executed at the time of the third stop of the game in the normal normal state or at the time of the third stop of the game transition to the normal normal state, It is a lottery table for determining the period management mode of the transfer destination. In the cycle management mode transition lottery table, the lottery results (transition destinations “Mode A” to “Mode E”) and each lottery result are provided for each lottery index number (“0” to “13”) associated with the lottery parameter. Is defined in correspondence with the lottery value set for.

  In this embodiment, the lottery parameters used at the time of the lottery transition to the cycle management mode are, as shown in FIG. 228, the lottery opportunity and the cycle management mode during stay. In the present embodiment, a combination of a chance of lottery and the cycle management mode during stay is associated with a lottery index number defined in the cycle management mode shift lottery table.

  For example, when the lottery opportunity is “at the time of winning BB” and the cycle management mode during the current stay is mode B, the lottery index number “6” is acquired. In this case, in the cycle management mode transition lottery, the lottery value in the column of the lottery index number “6” of the cycle management mode transition lottery table is referred to, and as the transition destination cycle management mode, mode B (no mode transition) is set to 230 /. Mode C (mode promotion) is determined with a probability of 26/256.

  As is clear from FIG. 227 and FIG. 228, in the lottery trigger other than “at the time of winning in the CZ1 lottery”, the cycle management mode currently in stay is not demoted due to the cycle management mode shift lottery. However, when the lottery opportunity is “at the time of winning in the CZ1 lottery”, there is a possibility that the cycle management mode during the current stay is demoted.

  For example, if the lottery opportunity is “at the time of winning in the CZ1 lottery” and the period management mode during the current stay is mode D or mode E, the lottery index number “13” is acquired. In this case, the mode C is always determined as the transition destination cycle management mode by the cycle management mode transition lottery, and the cycle management mode is always demoted. Further, for example, when the lottery opportunity is “CZ1 lottery win” and the cycle management mode during the current stay is mode B or mode C, the lottery index number “11” is acquired. In this case, by the lottery for transition to the cycle management mode, the mode A is determined as the transition destination cycle management mode with a probability of 159/256 (the cycle management mode is demoted with a probability of 159/256).

[P point lottery table]
Next, the P-point lottery table will be described with reference to FIG. FIG. 229 is a view showing the structure of the P-point lottery table.

  The P-point lottery table (random number denominator 256) is used in P-point lottery performed in a game in the normal normal state, a game in the normal BB1 state, and a transition game to the normal normal state. 0, 1, 5, 10, or 20). The P-point lottery table defines the correspondence between the lottery results (0, 1, 5, 10, or 20) and the lottery values set for each lottery result.

  In the P-point lottery of this embodiment, as is clear from FIG. 229, “0” is not determined as the added value of the P point, and the added value of the P point of “1” or more is always obtained. You. However, the probability that the added value “1” of the P point is determined is 251/256, and in most cases, the added value “1” of the P point is determined in the P point lottery. .

[P point initial value lottery table]
Next, the P-point initial value lottery table will be described with reference to FIG. FIG. 230 is a diagram showing the structure of the P-point initial value lottery table.

  The P-point initial value random determination table (random number denominator 256) is used in the P-point initial value random determination performed when the setting is changed, and the initial addition value (0, 50, 100, 180, 205, 220, 235, or 250) of the P point is used. ) Is a lottery table for determining (). The P-point initial value lottery table defines the correspondence between the lottery results (0, 50, 100, 180, 205, 220, 235, or 250) and the lottery values set for each lottery result.

  In the P-point initial value lottery of the present embodiment, as is apparent from FIG. 230, “0” is most easily determined as the initial addition value of the P point.

[ART direct hit lottery table]
Next, the ART direct hit lottery table will be described with reference to FIG. FIG. 231 is a diagram illustrating the configuration of the ART direct hit lottery table.

  The ART direct hit lottery table (random number denominator 65536) is used in the ART direct hit lottery executed in the game in the normal medium general state, and is a direct transition from the normal normal state to the ART state (ART no enemy state). / It is a lottery table for determining non-winning. The ART direct hit lottery table defines, for each set value, the correspondence between the lottery result ("winning" or "non-winning") and the lottery value set for each lottery result.

  As is clear from the ART direct hit lottery table shown in FIG. 231, in this embodiment, the ART direct hit lottery winning probability itself is extremely low regardless of the set value. Get higher.

[Episode BB / Premium ART lottery table]
Next, the episode BB / premium ART lottery table will be described with reference to FIGS. 232 and 233. FIG. 232 is a diagram showing the structure of the episode BB / premium ART lottery table. FIG. 233 is a diagram showing the lottery index number specified in the episode BB / premium ART lottery table and the episode BB lottery or premium ART lottery. It is a figure showing the correspondence with the lottery parameter used.

  The episode BB / premium ART lottery table (the random number denominator 128) is used in the episode BB lottery or the premium ART lottery performed in the BB2 or BB3 winning game in the normal normal state, and the episode BB or the premium ART is won / not won. It is a lottery table for determining. In the episode BB / premium ART lottery table, for each lottery index number (“0” to “2”) associated with the lottery parameter, the lottery result (“winning” or “non-winning”) and each lottery result The correspondence with the set lottery value is defined.

  In the present embodiment, the lottery parameter used at the time of the episode BB lottery is the value of the P point as shown in FIG. 233, and when the P point is “250” or less, the lottery index number “0” is obtained. If the P point is larger than "250", the lottery index number "1" is obtained. On the other hand, in the premium ART lottery, a lottery index number “2” is acquired.

  As is clear from FIGS. 232 and 233, when the P point at the time of the episode BB lottery is “250” or less (when the lottery index number is “0”), the winning probability of the episode BB is 2 / 128, which is a very low probability, but when the P point at the time of the episode BB lottery is larger than “250” (when the lottery index number is “1”), the episode BB always wins. On the other hand, in the premium ART lottery, the winning probability of the premium ART is constant at 5/128.

[CZ enemy character lottery table]
Next, the CZ enemy character lottery table will be described with reference to FIG. FIG. 234 is a diagram showing the configuration of the CZ enemy character lottery table.

  The CZ enemy character lottery table (random number denominator 256) is used in the CZ enemy character lottery executed when the CZ lottery 1 is won in the game in the normal normal state, and the enemy character that the ally character fights in the normal middle CZ state. It is a lottery table for determining the type of character (initial value of enemy HP). In the CZ enemy character lottery table, a lottery result (CZ enemy character type: “CZ enemy character A”, “CZ enemy character B”, or “CZ enemy character A”) is obtained for each type of cycle management mode (other than “mode E” or “mode E”). "CZ enemy character C") and a lottery value set for each lottery result are defined.

  As is clear from the CZ enemy character lottery table shown in FIG. 234, in the CZ enemy character lottery, when the cycle management mode is a mode other than mode E, the probability that the CZ enemy character A is determined is 249/256, and In this case, the CZ enemy character A is determined. On the other hand, in the CZ enemy character lottery, when the cycle management mode is the mode E, the CZ enemy character C is always determined. In this case, the transition to the ART state is determined regardless of the outcome of the battle A in the normal medium CZ state.

  When the type of the CZ enemy character is determined by the CZ enemy character lottery, the initial value of the enemy HP corresponding to the determined type of the CZ enemy character is set to the enemy HP. Here, FIG. 235 shows the initial value of the enemy HP of each CZ enemy character. The initial value of the enemy HP of the CZ enemy character A is “200”, the initial value of the enemy HP of the CZ enemy character B is “120”, and the initial value of the enemy HP of the CZ enemy character C is “200”. . Note that the CZ enemy character A is always set to the CZ enemy character that competes with the ally character in the CZ state during ART, and the initial value of the enemy HP is constant at “200”.

[CZ level lottery table]
Next, the CZ level lottery table will be described with reference to FIG. FIG. 236 is a diagram showing the configuration of the CZ level lottery table.

  The CZ level lottery table (random number denominator 256) is used in the CZ level lottery performed in the CZ winning game, and is a lottery table for determining the CZ level of the CZ game after the shift. The CZ level lottery table defines the correspondence between the lottery results (CZ level type: “CZ level 1”, “CZ level 2” or “CZ level 3”) and the lottery values set for each lottery result. I do.

  In the CZ level lottery of the present embodiment, the CZ level 1 is determined with a probability of 230/256, the CZ level 2 is determined with a probability of 14/256, and the CZ level 3 is determined with a probability of 12/256. As shown in a CZ end lottery table (see FIG. 242 described later), when the CZ level 3 is determined, “continue” is always determined in the CZ end lottery, and when the ally character is in the CZ state. The CZ state does not end until the battle victory is confirmed.

[Special effect lottery table]
Next, the special effect lottery table will be described with reference to FIGS. 237 and 238. FIG. 237 is a diagram showing the configuration of the special effect lottery table, and FIG. 238 is a diagram showing the correspondence between the lottery index numbers defined in the special effect lottery table and the lottery parameters used in the special effect lottery. is there.

  The special effect lottery table (random number denominator 256) is used in a special effect lottery executed in each game in the normal middle CZ state or the ART middle CZ state, and whether a special effect is given to a battle with an enemy character ( It is a lottery table for determining winning / non-winning. In the special effect lottery table, for each lottery index number (“0” to “8”) associated with the lottery parameter, the lottery result (“non-winning”, “strike”, “attack strength UP”) and each lottery The correspondence between the result and the set lottery value is defined.

  In this embodiment, as shown in FIG. 238, the lottery parameters used at the time of the special effect lottery are the number of remaining CZ games (6 or more games or within 5 games) and a payout lottery flag C (internal winning combination). In the present embodiment, the combination of the number of remaining CZ games and the payout lottery flag C is associated with a lottery index number defined in the special effect lottery table.

  For example, when the number of remaining CZ games is 6 or more and the payout lottery flag C is “replay”, the lottery index number “1” is acquired. In this case, in the special effect lottery, the lottery value in the column of the lottery index number “1” in the special effect lottery table is referred to, “non-winning” is determined with a probability of 229/256, and “serial” with a probability of 24/256. The "attack" is determined, and the "attack strength UP" is determined with a probability of 3/256. As apparent from FIGS. 237 and 238, when the payout lottery flag C is “strong rare”, the lottery index number “6” is obtained regardless of the number of remaining CZ games, and the special effect lottery is obtained. Is determined as a result of the lottery.

[Special Effect Game Number Lottery Table]
Next, the special effect game number lottery table will be described with reference to FIG. FIG. 239 is a diagram showing the structure of the special effect game number lottery table.

  The special effect game number lottery table (random number denominator 256) is used in the special effect game number lottery executed when the special effect lottery is won in the game in the CZ state, and the special effect (“strike” or “attack power”) is used. UP ”) is a lottery table for determining an activation period (number of activated games). In the special effect game number lottery table, the correspondence between the lottery result (2, 3, 4, 5, 6, or 7 games) and the lottery value set for each lottery result is defined for each type of special effect. .

  As is clear from the special effect game number lottery table shown in FIG. 239, when the special effect is “strike”, the number of special effect games of two or more games (special effect activation period) is determined. The two games are determined with the highest probability (210/256) as the number of special effect games. On the other hand, if the special effect is “attack strength UP”, the number of special effect games of 5 or more is determined, and among them, the number of special effect games is determined with the highest probability (242/256). You. That is, in the present embodiment, when the special effect is “continuous strike”, the activation period is relatively short, and when the special effect is “attack strength UP”, the activation period is relatively long. Become.

[Damage lottery table]
Next, the damage lottery table will be described with reference to FIG. 240 and FIG. FIG. 240 is a diagram showing the configuration of the damage lottery table, and FIG. 241 is a diagram showing the correspondence between the lottery index numbers defined in the damage lottery table and the lottery parameters used in the damage lottery.

  The damage lottery table (random number denominator 256) is used in each game and damage lottery performed in the normal medium CZ state or the ART medium CZ state, and the CZ enemy character in the battle during the CZ (battle A or battle C). It is a lottery table for determining a damage point to be given to the player (subtracted from the enemy HP). In the damage lottery table, a lottery result (damage point: 0, 6, 11, 23, 31, 50, 75 or 200) is obtained for each lottery index number (“0” to “7”) associated with the lottery parameter. The correspondence between each lottery result and the set lottery value is defined. The damage point of the enemy HP is a specific example of the “update value of a specific parameter” according to the present invention.

  In the present embodiment, as shown in FIG. 241, the lottery parameters used in the damage lottery are a lottery opportunity (game situation: during or after a continuous strike) and a payout lottery flag A (internal winning combination). In the present embodiment, a combination of a lottery opportunity (game state) and a payout lottery flag A is associated with a lottery index number defined in a damage lottery table.

  For example, when the lottery opportunity is other than the continuous fire and the payout lottery flag A is “Bell”, the lottery index number “2” is acquired. In this case, in the damage lottery, the lottery value in the column of the lottery index number “2” in the damage lottery table is referred to, the damage point “11” is determined with a probability of 192/256, and the damage point “11” with a probability of 64/256. 23 "is determined.

  As is clear from FIGS. 240 and 241, when the payout lottery flag A is “medium cho”, the lottery index number “7” is obtained regardless of the lottery trigger, and the lottery result of the damage lottery is obtained. , The damage point “200” is always determined. Note that, as described above, the maximum initial value of the enemy HP of the CZ enemy character is “200” (see FIG. 235). Therefore, in the present embodiment, when the payout lottery flag A is “medium cho” in the game in the CZ middle state, the enemy HP after the damage point is subtracted from the enemy HP of the CZ enemy character is always “0”. "And the battle victory during CZ is confirmed.

[CZ end lottery table]
Next, the CZ end lottery table will be described with reference to FIG. FIG. 242 is a diagram showing the configuration of the CZ end lottery table.

  The CZ end lottery table (random number denominator 256) is used in CZ end lottery performed in a game in which the end condition of the CZ state is satisfied, and is a lottery table for determining whether to end the CZ state. . In the CZ end lottery table, the correspondence between the lottery result (“end”, “continue” or “recovery”) and the lottery value set for each lottery result is defined for each type of the set CZ level. I do.

  For example, when the set CZ level is CZ level 1, in the CZ end lottery, “end” is determined with a probability of 154/256, “continue” is determined with a probability of 94/256, and 8 "Resurrection" is determined with a probability of / 256. Further, as is clear from the CZ end lottery table shown in FIG. 242, when the set CZ level is CZ level 3, “continue” is always determined. That is, in the state where the player is staying at the CZ level 3, the game in the CZ state is continued until the battle victory during the CZ is determined. In other words, if the set CZ level is CZ level 3 in a game in which the end condition of the CZ state is satisfied, the battle victory during CZ is determined.

[ART Set Number Lottery Table]
Next, the ART set number lottery table will be described with reference to FIG. FIG. 243 is a diagram showing the configuration of the ART set number lottery table.

  The ART set number lottery table (random number denominator 256) is used in the ART set number lottery executed in the game (ART winning game) in which the transition from the normal state to the ART state is determined, and the ART set to be stocked (added). It is a lottery table for determining the number. In the ART set number lottery table, the lottery result (the number of sets: 0, 1, 2, 3, or 4) and each lottery result are set for each lottery opportunity (when the premium ART is confirmed or when the CZ enemy character C is defeated, or otherwise). Is defined in correspondence with the lottery value set for.

  As is clear from the ART set number lottery table shown in FIG. 243, when the lottery opportunity is when the premium ART is confirmed or when the CZ enemy character C is defeated, the number of sets equal to or greater than “1” is always the lot number of the ART set number lottery. Determined as a result. Therefore, in the ART state in which the state is shifted to after the determination of the premium ART or the defeat of the CZ enemy character C, two or more sets of ART games (one set for the ART winning + the number of sets determined by the number of ART sets) are executed. On the other hand, when the lottery opportunity is other than when the premium ART is determined or when the CZ enemy character C is defeated, the probability that “0” is determined as the lottery result of the ART set number lottery (ART sets are not stocked) Probability) is 247/256, which is the highest.

[Safety zone game number lottery table]
Next, the safety zone game number random determination table will be described with reference to FIGS. FIG. 244 is a diagram showing the structure of the safety zone game number lottery table. FIG. 245 is a diagram showing the lottery index numbers defined in the safety zone game number lottery table and the lottery parameters used in the safety zone game number lottery. It is a figure showing a correspondence.

  The safety zone game number lottery table (random number denominator 256) is used in the safety zone game number lottery executed in the game in which the transition to the ART-free state is determined, and the game in the ART-free state (safe zone) is performed. It is a lottery table for determining a period (the number of games). In the safety zone game number lottery table, a lottery result (the number of safe zone games: 5, 10, 20, 30, 50, or 100) for each lottery index number (“0” to “5”) associated with the lottery parameter. And a lottery value set for each lottery result.

  In this embodiment, as shown in FIG. 245, the lottery parameters used at the time of the lottery of the safety zone game are lottery triggers (“first of each chapter”, “return from during battle B (chapters 1 to 4)”, “ Return from the middle (Chapter 5 to 10) "or" Other (CZ failure return, after bonus end) ") and the setting value. Then, in the present embodiment, a combination of a lottery opportunity and a set value is associated with a lottery index number defined in the safe zone game number lottery table.

  For example, when the lottery opportunity is “return from during battle B (Chapters 1 to 4)” and the set value is setting 1, the lottery index number “2” is acquired. In this case, in the safety zone game number lottery, the lottery value in the field of the lottery index number “2” of the safety zone game number lottery table is referred to, and the safety zone game number “10” is determined with a probability of 236/256. The number of safe zone games "20" is determined with a probability of / 256, the number of safe zone games "30" is determined with a probability of 5/256, and the number of safe zone games "50" or "100" with a probability of 1/256. Is determined.

  Further, for example, when the lottery opportunity is “first of each chapter”, the lottery index number “1” is acquired regardless of the set value. In this case, in the safety zone game number lottery, the lottery value in the field of the lottery index number “1” of the safety zone game number lottery table is referred to, and the safety zone game number “10” is always determined. That is, the period of the game in the ART-free state (safe zone) performed at the start of the ART chapter is always 10 games regardless of the ART chapter and the set value.

[ART enemy character lottery table]
Next, the ART enemy character lottery table will be described with reference to FIGS. 246 and 247. FIG. 246 is a diagram showing the configuration of the ART enemy character lottery table, and FIG. 247 is a diagram showing the correspondence between the lottery index numbers defined in the ART enemy character lottery table and the lottery parameters used in the ART enemy character lottery. FIG.

  The ART enemy character lottery table (random number denominator 256) is used in the ART enemy character lottery performed in the game in which the transition to the ART in enemy absence state is determined, and the ART enemy character encountered in the next ART in enemy in enemy state. It is a lottery table for determining the type of. In the ART enemy character lottery table, a lottery result (ART enemy character A to ART enemy character G) and a setting for each lottery result are set for each lottery index number (“0” to “11”) associated with the lottery parameter. The corresponding relationship with the determined lottery value is defined.

  In this embodiment, as shown in FIG. 247, the lottery parameters used at the time of the ART enemy character lottery are lottery triggers (game status during stay: “chapter 1” to “chapter 9”, “chapter 10 or later”, “special mode”. A "or" special mode S "). In this embodiment, the lottery opportunity is associated with a lottery index number defined in the ART enemy character lottery table.

  For example, when the lottery opportunity (game state during stay) is “chapter 1” (when the ART chapter during stay is chapter 1), the lottery index number “0” is acquired. In this case, in the ART enemy character lottery, the ART enemy character A is determined with a probability of 199/256, and the ART enemy character A is determined with a probability of 52/256 by referring to the lottery value in the column of the lottery index number “0” of the ART enemy character lottery table. The ART enemy character D is determined, the ART enemy character E is determined with a probability of 3/256, and the ART enemy character F or the ART enemy character G is determined with a probability of 1/256.

  When the special mode (special mode A or S) is set at the time of the ART enemy character lottery, the lottery index number corresponding to the special mode A or S is selected regardless of the type of the ART chapter.

[Battle B lottery table]
Next, the battle B lottery table will be described with reference to FIG. FIG. 248 is a diagram illustrating a configuration of the battle B lottery table.

  The battle B lottery table (random number denominator 256) is used in the battle B lottery executed in the game with the enemy in the ART state and determines whether or not to avoid a battle with the enemy character encountered in the ART (the battle state is changed to the battle B state). It is a lottery table for determining whether to shift to the middle state). In the battle B lottery table, the correspondence between the lottery results (“avoidance”, “battle B” or “special mode”) and the lottery values set for each lottery result is determined for each type of payout lottery flag B. Stipulate.

  As is clear from the battle B lottery table shown in FIG. 248, when the payout lottery flag B is “weak rare” or “strong rare”, “avoidance” is always determined as the result of the battle B lottery. For the other payout lottery flags B (internal winning combinations), “avoidance” is not determined. When the payout lottery flag B is “other” or “lip”, “battle B” is always determined as the lottery result of the battle B lottery.

  Also, when the payout lottery flag B is “Bell”, “Battle B” is determined with a probability of 252/256 as a lottery result of the battle B lottery, and “special mode” is determined with a probability of 4/256. It is determined. That is, in the present embodiment, the “special mode” may be won in the battle B lottery only when the payout lottery flag B is “bell”.

[Special mode content lottery table]
Next, the special mode content lottery table will be described with reference to FIG. FIG. 249 is a diagram showing the configuration of the special mode content lottery table.

  The special mode content lottery table (random number denominator 256) is used in the special mode content lottery executed when the “special mode” is determined as the result of the battle B lottery, and shows the contents of the privilege given by the special mode. It is a lottery table for determination. The special mode content lottery table defines the correspondence between the lottery results (contents of the special mode) and the lottery values set for each lottery result.

  As the content of the special mode, a combination of the type of the special mode (special mode A or S) and the number of weapons (4 to 7) is defined. For example, the lottery result “special mode A, number of weapons 5” indicates that the type of the special mode to be set is the special mode A, and the number of weapons that can be used in the battle B state is “5”. In the present embodiment, the number of weapons that can be used per unit game is “1”.

  As is clear from the special mode content lottery table shown in FIG. 249, in the present embodiment, the probability (217/256) that “special mode A, weapon count 4” is determined as the special mode content lottery result is the highest. Get higher. In the present embodiment, “special mode S, number of weapons 6” and “special mode S, number of weapons 7” are not determined as a result of the special mode content lottery. However, the present invention is not limited thereto. The present invention is not limited thereto, and a configuration may be adopted in which these lottery results can be determined according to, for example, a game situation.

[HP recovery / weapon lottery table]
Next, the HP recovery / weapon lottery table will be described with reference to FIG. 250 and FIG. FIG. 250 is a diagram showing the configuration of the HP recovery / weapon lottery table. FIG. 251 is a diagram showing the lottery index numbers defined in the HP recovery / weapon lottery table and the lottery parameters used in the HP recovery / weapon lottery. It is a figure showing a correspondence.

  The HP recovery / weapon lottery table (random number denominator 256) is used in HP recovery / weapon lottery performed in a game in the ART state other than the battle B state, and recovers allied HP and obtains a weapon (adds the number of weapons). Alternatively, it is a lottery table for determining whether or not to add an ART set. In the HP recovery / weapon lottery table, the lottery results (“non-winning”, “losing”, “HP recovery 1” to “HP” are obtained for each lottery index number (“0” to “15”) associated with the lottery parameter. Recovery 5 "," weapon "," ART set A ") and a lottery value set for each lottery result.

  In the HP recovery / weapon lottery, when any of the types “HP recovery 1” to “HP recovery 5” is determined, a predetermined HP recovery amount is added to the ally HP, and the “weapon” is determined. In this case, a predetermined number of additions is added to the current number of weapons. If "ART set A" is determined, one set of ART set is stocked and if "non-winning" is determined. Does not grant these benefits. In the HP recovery / weapon lottery table, “losing” is also specified as the lottery result, but “loss” is not determined in the HP recovery / weapon lottery. Therefore, it is not necessary to define the lottery result “losing” in the HP recovery / weapon lottery table.

  In this embodiment, as shown in FIG. 251, the lottery parameters used at the time of HP recovery / weapon random determination are, as shown in FIG. 251, a lottery opportunity (game state during stay: “in SZ, special mode A, special mode S”, “in bonus”, or "Other") and a lottery lottery flag C. The lottery opportunity “during SZ, special mode A, special mode S” means that the game status is SZ, the special mode A is set, or the special mode S is set. In the present embodiment, a combination of a lottery opportunity and a ball-out lottery flag C is associated with a lottery index number defined in the HP recovery / weapon lottery table.

  For example, when the lottery opportunity (game state during stay) is “in bonus” and the payout lottery flag C (internal winning combination) is “slip bell”, the lottery index number “5” is acquired. You. In this case, in the HP recovery / weapon lottery, the lottery value in the column of the lottery index number “5” in the HP recovery / weapon lottery table is referred to, “HP recovery 4” is determined with a probability of 2/256, and 1/256. , "HP recovery 5" is determined, and "weapon" is determined with a probability of 253/256.

  In addition, as is clear from FIGS. 250 and 251, in the present embodiment, the condition (the lottery index number “9”) in which “ART Set A” may be determined as the lottery result of the HP recovery / weapon lottery is acquired. The condition is that the lottery opportunity (game situation) is “under bonus” and the payout lottery flag C is “strong”.

[Reward lottery table]
Next, the reward lottery table will be described with reference to FIGS. 252 and 253. FIG. 252 is a diagram showing the configuration of the reward lottery table, and FIGS. 253A to 253C are diagrams showing the correspondence between the lottery index numbers defined in the reward lottery table and the lottery parameters used in the reward lottery. .

  The reward lottery table (random number denominator 256) is used in each game in the game in the state of the battle B and in the reward lottery to be executed, and defeats the battle B, recovers the friendly HP, obtains the weapon (adds the number of weapons) or ART. It is a lottery table for determining whether or not to add a set. In the reward lottery table, for each lottery index number (“0” to “15”) associated with the lottery parameter, the lottery results (“non-winning”, “losing”, “HP recovery 1” to “HP recovery 5”) , “Weapon”, “ART set A”) and a lottery value set for each lottery result. If “losing” is determined in the reward lottery, the battle defeat of the game is determined.

  In the present embodiment, as shown in FIGS. 253A to 253C, the lottery parameters used in the reward lottery are the type of the ART enemy character (ART enemy characters A to G), the payout random determination flag C, and the set value. In the present embodiment, the combination of the type of the ART enemy character, the payout lottery flag C, and the set value is associated with the lottery index number specified in the reward lottery table.

  For example, when the ART enemy character is the ART enemy character D, the payout lottery flag C is “Bell”, and the set value is one of the settings 1 to 6, the lottery index number “4” is set. Acquired (see FIG. 253B). In this case, in the reward lottery, the lottery value in the field of the lottery index number “4” of the reward lottery table is referred to, “non-winning” is determined with a probability of 156/256, and “losing” with a probability of 100/256. It is determined.

  In the present embodiment, for example, the case where the ART enemy character is the ART enemy character D, the payout random determination flag C is “Bell”, and the set value is one of the settings 1 to 6 is assumed. Also, when the present game is the second game in the battle B state, and the payout lottery flag C is “Bell” twice consecutively in the battle B state, the payout random determination flag C becomes “Bell”. "Bell" to "weak choi". Therefore, in this case, the lottery index number “7” is acquired (see FIG. 253B), and in the reward lottery, “HP recovery 1” is determined with a probability of 243/256, and “HP recovery 1” with a probability of 8/256. "Recovery 2" is determined, "HP recovery 3" is determined with a probability of 1/256, "weapon" is determined with a probability of 3/256, and "ART set A" is determined with a probability of 1/256. . That is, when "Bell" is determined as the payout lottery flag C twice consecutively in the game in the battle B state, the lottery result of the reward lottery is changed to a result that is advantageous to the player.

  As is clear from FIG. 253, when the rare combination is won regardless of the type and the set value of the ART enemy character, a value of “7” or more is obtained as the lottery index number. In this case, as is apparent from FIG. 252, “losing” is not determined as the result of the reward lottery. Therefore, in the game period (2 games) in the battle B state, if even one rare role is won, the payout state returns from the battle B state to the ART-free enemy state (safe zone).

[HP recovery amount lottery table]
Next, the HP recovery amount lottery table will be described with reference to FIG. FIG. 254 is a diagram showing the configuration of the HP recovery amount lottery table.

  The HP recovery amount lottery table (random number denominator 256) indicates the HP recovery amount lottery executed when the HP recovery / weapon lottery or reward lottery result is one of “HP recovery 1” to “HP recovery 5”. Is a lottery table for determining the HP recovery amount (addition value) of the friendly HP. In the HP recovery amount lottery table, the lottery results (HP recovery amounts: 10, 20, 30, 50, 100, 200 or 300) and the respective lottery results are given for each of “HP recovery 1” to “HP recovery 5”. The correspondence with the set lottery value is defined.

  As is clear from the HP recovery amount lottery table shown in FIG. 254, the higher the value (level) of “HP recovery” obtained in the HP recovery / weapon lottery or reward lottery, the higher the value determined as the HP recovery amount lottery result. The HP recovery amount increases. Specifically, in the “HP recovery 1”, the HP recovery amount “10” is most easily determined, in the “HP recovery 2”, the HP recovery amount “30” is most easily determined, and in the “HP recovery 3”, the HP recovery amount is determined. The quantity “50” is most easily determined. In “HP recovery 4”, the HP recovery amount “100” is most easily determined, and in “HP recovery 5”, the HP recovery amount “200” or “300” is always determined.

[Additional lottery table for friendly HP]
Next, with reference to FIG. 255, a description will be given of a lottery table in which a friend HP is added. FIG. 255 is a diagram showing the structure of the lottery table added to the ally HP.

  The friend HP addition lottery table (random number denominator 256) is used in the friend HP addition lottery executed when the CZ victory is determined in the CZ state, and is a lottery table for determining the friend HP addition HP (addition value). is there. In the friendly HP addition lottery table, the lottery result (additional HP: 0, 50, 100, 150, 200, 250 or 300) and the lottery value set for each lottery result are set for each type of payout lottery flag A. Define the correspondence between The addition of the ally HP indicates a specific example of the “additional privilege” according to the present invention.

  As is clear from the ally HP addition lottery table shown in FIG. 255, when a non-rare role is won, in the ally HP addition lottery, the lottery result (additional HP) is always “0”, and the ally HP addition is Not done. On the other hand, when the rare combination is won, a lottery result (additional HP) larger than “0” may be determined in the ally HP additional lottery, and among them, the payout lottery flag A is set to “strong”. , "Cha, Subaru" or "Medium Cho", an additional HP larger than "0" is always determined.

[Weapon frequency lottery table]
Next, the weapon number random determination table will be described with reference to FIG. FIG. 256 is a diagram showing the configuration of the weapon number random determination table.

  The weapon number lottery table (random number denominator 256) is used in the weapon number lottery executed when the HP recovery / weapon random determination or reward lottery result is “weapon”, and is a lottery table for determining the number of weapons. It is. In the weapon number lottery table, the correspondence between the lottery result (the number of weapons: 1, 2, or 5) and the lottery value set for each lottery result is defined.

  As is clear from the weapon count random determination table shown in FIG. 256, in the weapon count random determination, the number of weapons “1” is determined with a probability of 224/256, and the number of weapons “2” is determined with a probability of 26/256. The number of weapons “5” is determined with a probability of / 256.

[Battle B damage lottery table]
Next, the battle B damage random determination table will be described with reference to FIG. FIG. 257 is a diagram showing the configuration of the battle B damage lottery table.

  The battle B damage lottery table (random number denominator 256) is used in the battle B damage lottery executed when the lottery result of the reward lottery is “losing” for two consecutive games in the battle B state. It is a lottery table for determining a character's damage point (subtraction value of friendly HP). In the battle B damage lottery table, for each type of ART enemy character, the correspondence between the lottery result (damage point: 0, 5, 8, 11, 14, 17, or 20) and the lottery value set for each lottery result Define the relationship.

  As is clear from the battle B damage lottery table shown in FIG. 257, when the type of the ART enemy character is any of the ART enemy characters A to E, a damage point of “5” or more is determined. When the type of the enemy character is the ART enemy character F or G, “0” is determined as the damage point. That is, when the type of the ART enemy character is the ART enemy character F or G, even if the result of the reward lottery is “losing” for two consecutive games in the battle B state, the ally HP is not subtracted. .

[Battle B security reward table]
Next, the battle B security reward table will be described with reference to FIG. FIG. 258 is a diagram showing a configuration of the battle B guarantee reward table.

  The battle B security reward table shows that, in a game in the battle B state, when the weapon is used once (consumed) and the ART enemy character is defeated (when the number of weapons is subtracted by 1), the friend HP is given as a reward (privilege). Specifies the correspondence between the HP added value to be added to and the ART enemy character type. In the present embodiment, as shown in FIG. 258, when the ART enemy character is defeated using a weapon, the HP added value of the friendly HP added as a reward changes according to the type of the ART enemy character.

  Specifically, when the ART enemy character is the ART enemy character D or E, the HP added value of the ally HP added as a reward is “10”, and when the ART enemy character is the ART enemy character G, , The HP added value of the friend HP added as a reward is “100”. If the ART enemy character is one of the ART enemy characters A, B, C and F, even if the weapon is used to defeat the ART enemy character, a reward of adding HP to the ally HP is not obtained.

[CZ required point lottery table]
Next, the CZ required point lottery table will be described with reference to FIGS. FIG. 259 is a diagram showing the configuration of the CZ required point lottery table. FIG. 260 shows the correspondence between the lottery index numbers defined in the CZ required point lottery table and the lottery parameters used in the CZ required point lottery. FIG.

  The CZ required point lottery table (random number denominator 256) is used in the CZ required point lottery executed in the transition game to the enemy-free state during ART, and shifts the payout state from the ART general state to the ART during CZ state. It is a lottery table for determining the initial value of the CZ required point required for this. In the CZ required point lottery table, a lottery result (initial value of CZ required point: 20, 30, 50, 75, 100, 150) is determined for each lottery index number (“0” to “8”) associated with the lottery parameter. Or 200) and a lottery value set for each lottery result.

  In the present embodiment, as shown in FIG. 260, the lottery parameter used at the time of CZ required point lottery is a lottery opportunity (game situation: “chapter 1” to “chapter 10 or later” or “losing CZ battle”). In addition, the lottery opportunity (game situation) “Chapter 1” to “Chapter 10 or later” means the type of the ART chapter to be started next, and “CZ battle loss” means from the state of CZ during ART to the state of no enemy during ART. Means when transitioning to. In the present embodiment, a lottery opportunity (game situation) is associated with a lottery index number defined in the CZ required point lottery table.

  For example, when the lottery opportunity (game situation) is “Chapter 3”, the lottery index number “2” is acquired (see FIG. 260). In this case, in the CZ required point lottery, the lottery value in the field of the lottery index number “2” of the CZ required point lottery table is referred to, and with a probability of 8/256, “20” or “30” is the initial value of the CZ required point. Is determined as the initial value of the CZ required point with a probability of 112/256, and “75” is determined as the initial value of the CZ required point with a probability of 128/256.

[CZ point lottery table]
Next, the CZ point lottery table will be described with reference to FIG. FIG. 261 is a diagram showing the configuration of the CZ point lottery table.

  The CZ point lottery table (random number denominator 256) is a lottery table used for CZ point lottery performed in each game and executed in the general state during ART and for determining a subtraction value of CZ required points. In the CZ point lottery table, a lottery result (subtraction value of CZ required point: 0, 1, 2, 3, 5, 10, or 200) and each lottery result are set for each type of payout lottery flag A. The correspondence with the lottery value is defined.

  As is clear from the CZ point lottery table shown in FIG. 261, when a non-rare combination is won, there is a possibility that “0” is determined as the lottery result (subtraction value of CZ required points) in the CZ point lottery. is there. On the other hand, when the rare combination is won, in the CZ point lottery, a lottery result larger than “0” (a subtraction value of the required CZ point) is always determined.

<Configuration of storage area provided in main RAM>
Next, the configuration of various storage areas provided in the main RAM 103 will be described with reference to FIGS. Note that the configurations of the operation stop button storage area and the pressing order storage area in the present embodiment are the same as those of the first embodiment (see FIGS. 33 and 34). Is omitted.

[Display combination storage area and internal winning combination storage area]
First, the configuration of the display combination storage area in the present embodiment will be described with reference to FIG. In the present embodiment, the display combination storage area includes display combination storage areas 0 to 18 each represented by 1-byte data.

  When "1" is stored in a predetermined bit in each of the display combination storage areas 0 to 18, it indicates that the symbol combination corresponding to the predetermined bit has been displayed on the activated line. On the other hand, when all the bits are “0”, it indicates that the symbol combination relating to the winning (including the symbol combination relating to bell spilling in the present embodiment) is not displayed on the activated line.

  In the main RAM 103, an internal winning combination storing area is provided. The internal winning combination storage area is configured similarly to the display combination storage area shown in FIG. When “1” is stored in a plurality of bits in the internal winning combination storing areas 0 to 18, display of a symbol combination corresponding to each bit is permitted. When all the bits are “0”, the content of the internal winning combination is “out”.

[Holdover combination storage area]
Next, the configuration of the carryover combination storage area according to the present embodiment will be described with reference to FIG. In the present embodiment, the carryover combination storage area is composed of carryover combination storage areas 0 each represented by 1-byte data.

  As a result of the internal lottery, for example, when the internal winning combination corresponding to the symbol combination (displaying combination) with the name “red BB_CD” is determined as the internal winning combination, the internal winning combination is set as the carryover combination in the carryover combination storage area. Is stored in a predetermined area (area of bit 0). For the carryover combination stored in the carryover combination storage area, the corresponding symbol combination (for example, the symbol combination “red 7”-“red 7”-“red 7” with the name “red BB_CD”) is displayed on the activated line. Until cleared. Then, while the carryover combination is stored in the carryover combination storage area, the carryover combination is also stored in the internal win combination storage area in addition to the internal winning combination determined by the internal lottery.

[Gaming state flag storage area]
Next, the configuration of the gaming state flag storage area will be described with reference to FIGS. 264A and 264B. FIG. 264A is a diagram showing the configuration of the game state flag storage area, and FIG. 264B is a correspondence table between the main game state and the name of the game management flag.

  The game state flag storage area includes a 1-byte data storage area (game state flag storage area 0). In the present embodiment, as shown in FIG. 264A, a unique bonus type or RT type is assigned to each bit of the gaming state flag storage area.

  When "1" is stored in a predetermined bit in the gaming state flag storage area, it indicates that a bonus game or RT operation corresponding to the predetermined bit is being performed. For example, when “1” is stored in bit 0 of the gaming state flag storage area, it indicates that the main gaming state is the RT1 state. For example, when “1” is stored in bit 6 of the gaming state flag storage area, it indicates that BB3 is operating. If “1” is not stored in all the bits in the gaming state flag storage area, it indicates that the main gaming state is the RT0 state.

[Eject status flag storage area]
Next, the configuration of the payout flag storage area will be described with reference to FIGS. 265A and 265B. FIG. 265A is a diagram showing a configuration of a payout state flag storage area, and FIG. 265B is a correspondence table of payout game states and payout management flag names.

  The payout state flag storage area includes a 1-byte data storage area (payout state flag storage area 0). In the present embodiment, as shown in FIG. 265A, a unique payout state type is assigned to each bit of the payout state flag storage area.

  For example, when the payout state is the normal medium state, “1” is stored only in bit 0 of the payout state flag storage area (only the normal medium flag is turned on). However, when the payout state is the normal medium CZ state, “1” is stored in both the bit 0 and the bit 1 of the payout state flag storage area (the normal medium flag and the CZ medium flag are in the ON state). Becomes).

  Further, for example, when the ball-out state is the ART-in-enemy state, “1” is stored in both the bit 2 and the bit 3 of the ball-out state flag storage area (the ART-in-flight state and the enemy-in-flight state flag). Is turned on). When the ball-out state is the enemy-at-enemy state, “1” is stored in both the bit 2 and the bit 4 of the ball-out state flag storage area (the ART state and the enemy state flag are set to the ON state). Become). When the ball-out state is the battle B state, “1” is stored in both the bit 2 and the bit 5 of the ball-out state flag storage area (the ART flag and the battle B flag are turned on). ). When the ball-out state is the ART-in-CZ-in state, “1” is stored in both the bit 1 and the bit 2 of the ball-out state flag storage area (the CZ-in flag and the ART-in-flag are turned on). ). When the ball-out state is the SZ state, “1” is stored in both the bit 2 and the bit 6 of the ball-out state flag storage area (the ART flag and the SZ flag are turned on). ).

[Symbol code storage area]
Next, the configuration of the symbol code storage area will be described with reference to FIG. The symbol code storage area stores, for each activated line, a symbol code (symbol code storage area 0) of the symbol of the reel that has been stopped most recently, and a displayable symbol (symbol code storage areas 1 to 19). You. After all the reels are stopped, the symbol codes corresponding to the display combinations are stored in the symbol code storage areas (symbol code storage areas 1 to 19) in which the displayable combinations are stored.

  In the present embodiment, when the stop control position is determined, the winning operation flag data corresponding to the symbol (code) of the stop control position is read from the symbol corresponding winning operation flag data table (see FIG. 218), and the winning operation flag is determined. The data is ANDed with the data already stored in the symbol code storage area. Then, the ANDed data is stored in the symbol code storage area shown in FIG.

[Instruction flag storage area]
Next, the configuration of the instruction (navigation) flag storage area will be described with reference to FIG. In the present embodiment, the instruction flag storage area includes an instruction flag storage area 0 represented by 1-byte data. Each bit is assigned a type of navigation of the pressing order of the stop button. The instruction flag number described in FIG. 267 corresponds to the instruction monitor number described in FIG. 270 described later.

  In the instruction flag storage area 0, when “1” is stored in a predetermined bit, the target role of the push order navigation corresponding to the predetermined bit (push order role: small push order role or push order replay role) Indicates that the game has been won. On the other hand, when all the bits are “0”, it indicates that the pressing order has not been won.

  For example, when any of the names “F_left bell_1” to “F_left bell_5” is internally won in the ART state, that is, the pressing sequence in which the correct pressing order of the stop button is “left center right” is the internal When a win is made, “1” is stored in bit 0 of the instruction flag storage area 0. In this case, under the control of the main control circuit 90, information on the correct pressing order of the stop button (instruction monitor number 1) is reported on the instruction monitor (not shown) provided in the information display 6 described above. At the same time, under the control of the sub control circuit 200, a push order navigation (left middle right navigation) using the display device 11 is performed.

<Correspondence table of internal winning combination, pressing order of stop button, and symbol combination (display combination)>
Next, with reference to FIG. 268 and FIG. 269, the correspondence between the internal winning combination, the symbol combination (display combination), and the pressing order of the stop button will be described. 268 and 269 are correspondence tables of the internal winning combination, the symbol combination (display combination), and the pressing order of the stop button.

  In the correspondence table, "left center right" corresponds to the stop button pressing order "left → middle → right", and "left right center" indicates the stop button pressing order "left → right → middle" In this order. In the correspondence table, "middle left and right" corresponds to the stop button pressing order of "middle → left → right", and "middle right left" indicates the stop button pressing order of "middle → right → left" Corresponding. In the correspondence table, "Right-Left-Middle" corresponds to the stop button pressing order of "Right-Left-Middle", and "Right-Middle-Left" indicates the stop button pressing order of "Right-Middle-Left" In this order.

  In the present embodiment, the replay combination having the correct answer in the pushing order is the names “F_RT2 promotion_123” to “F_RT2 promotion_3rd”, “F_maintenance_123” to “F_maintenance_3rd”, and “F_RT3 promotion_123” to “F_RT3 promotion_3rd”. Is an internal winning combination.

  For example, for the internal winning combination associated with the name “F_RT2 promotion_123”, the correct answer in the pressing order is “left center right”. Therefore, when the internal winning combination with the name “F_RT2 promotion_123” is won, if the pressing order is correct, the symbol combination with any of the combination names “RT1RP_1” to “RT1RP_3” stops on the active line. This is displayed ("RT2 lip winning" in FIG. 268), and the RT state shifts to the RT2 state. However, when the internal winning combination with the name “F_RT2 promotion_123” is won, if the pressing order is incorrect (the pressing order is other than “right and left”), the symbols related to the combination names “RT1RP_1” to “RT1RP_3” The combination is not stopped and displayed on the active line, and the RT state does not shift ("RT state maintenance" in FIG. 268).

  In the present embodiment, the small winning combinations having the correct answer in the order of pressing include the names “F_left bell_1” to “F_left bell_9”, “F_middle bell_1” to “F_middle bell_9”, and “F_right bell_1”. ”To“ F_Right Bell — 9 ”.

  For example, in the internal winning combination related to any of the names “F_middle bell_1” to “F_middle bell_9”, the correct answer in the pressing order is “middle left / right” or “middle right / left” (first stop of the middle reel 3C. Push order). Therefore, when an internal winning combination related to any of the names “F_medium_bell_1” to “F_medium_bell_9” is won, if the pressing order is correct, the combination names “bell_CE_1” to “bell_CE_3” Are stopped and displayed on the activated line ("9-bell (middle-stage) winning" in FIG. 269), and 9 medals are paid out. However, when the internal winning combination related to any of “F_medium bell_1” to “F_medium bell_9” is won, the pressing order is incorrect (when the left reel 3L or the right reel 3R is first stopped). In this case, the small combination in which nine medals are paid out with a probability of 1/9 wins, and the symbol combination (RT1 transition 01) to any one of the combination names “RT1 transition 01” to “RT1 transition 27” with a probability of 8/9. The spilled bell is stopped and displayed on the activated line, and the RT state shifts to the RT1 state ("9 sheets at 1/9, RT1 shift at 8/9" in FIG. 269).

  In the game in the BB state, as shown in FIG. 269, a symbol combination relating to the JAC combination (small combination) for which nine medals are paid out is stopped and displayed on the activated line regardless of the type of the internal winning combination and the pressing order. ("JAC role (9 pieces) winning" in FIG. 269). However, in the game in the BB state, when the internal winning combination of the name “F_RB bell”, “F_RBBAR alignment” or “F_BAR loss” is won, for example, a symbol combination “watermelon” − “watermelon” − “ When "watermelon" is stopped and displayed, the small part (9-piece combination) associated with the combination name "JAC_watermelon chance_1" and the small combination (4 piece combination) associated with the combination name "watermelon_CD_1" win simultaneously, and the medal is obtained. The payout number is 13.

<Correspondence relationship between internal winning combination and instruction monitor number (navigation type)>
In the conventional pachislot, information (navigation order, etc.) of reel stop operation (navigation order) is reported (navigated) by the sub (sub-control board 72) side control during ART. However, since the presence or absence of this notification affects the profit (payout) of the player, in recent years, it is required that the main (main control board 71) that manages the profit of the player perform the notification. In view of this, in the pachislo 1 of the present embodiment, as described above, the information display 6 controlled on the main side is provided with an instruction monitor (not shown) for notifying the information of the stop operation and the like, and is controlled by the main side. In addition, a function (AT function) of notifying the information of the reel stop operation according to the internal winning combination is provided.

  In the pachislot 1 of the present embodiment, when the AT (ART) function is activated, when an internal winning combination (small combination and replay combination) with a correct answer is won in the order of pressing the stop button, the order of pressing the correct internal winning combination is the same. The associated instruction monitor number is displayed on the instruction monitor. The “instruction monitor number” is a numerical value displayed (notified) on the instruction display unit when a navigation occurs, and uniquely corresponds to the notification content (navigation type).

  Here, the correspondence between the internal winning combination and the designated monitor number (navigation type) will be described with reference to FIGS. FIG. 270 is a diagram showing the correspondence between the instruction monitor number and the navigation type. 271 and 272 are diagrams illustrating the correspondence between the internal winning combination relating to the small combination and the replay combination and the instruction monitor number (navigation type). In the present embodiment, no navigation is generated in the non-ART state. Further, even in the ART state, no navigation is performed for an internal winning combination for which a numerical value is not defined in FIGS. 271 and 272. Further, even if the small combination corresponding to "Bell" having a correct answer in the pushing order is won, if the RT state during stay is the RT0 state, no navigation occurs.

  In the present embodiment, as shown in FIG. 270, the indication monitor number “1” is associated with the notification of the pressing order “left middle right” (“left middle right navigation”), and the indication monitor number “2” is assigned. The notification of the pressing order “left and right middle” (“left and right middle navigation”) is associated. The instruction monitor number "3" is associated with the notification of the pressing order "middle left and right" ("middle left and right navigation"), and the instruction monitor number "4" is notified of the pressing order "middle right and left" ("middle right left navigation"). )). The instruction monitor number “5” is associated with the notification of the pressing order “middle right and left” (“middle right left”), and the instruction monitor number “6” is notified of the pressing order “middle right and left” (“middle right”). Left navigation)). Also, the instruction monitor number “7” is associated with a pressing order “right center left” (“reverse pressing”). Note that the instruction monitor number “7” is generated only in a game in the normal state and in which BB2 or BB3 is operating.

  Hereinafter, the correspondence between the internal winning combination relating to the small combination and the replay combination and the designated monitor number (navigation type) set in the present embodiment will be specifically described.

  In the ART state (when the BB is not operating), as shown in FIGS. 271 and 272, the names “F_RT2 promotion_123”, “F_maintenance_123”, “F_RT3 promotion_123”, and “F_left bell_1” to “F_left bell” The internal winning combination relating to “_5” is associated with the instruction monitor number “1” (left middle right navigation). Therefore, in the ART state (when the BB is not activated), it relates to any of the names “F_RT2 promotion_123”, “F_maintenance_123”, “F_RT3 promotion_123”, and “F_left bell_1” to “F_left bell_5”. When the internal winning combination is won, "left center right navigation" is generated, and the instruction monitor displays the instruction monitor number "1".

  In the ART state (when the BB is not activated), the internal winning combinations related to the names “F_RT2 promotion_132”, “F_maintenance_132”, “F_RT3 promotion_132”, and “F_left bell_6” to “F_left bell_9” are instructed. It is associated with the monitor number “2” (left and right middle navigation). Therefore, in the ART state (when the BB is not activated), the names “F_RT2 promotion_132”, “F_maintenance_132”, “F_RT3 promotion_132”, and any one of “F_left bell_6” to “F_left bell_9” are related. When the internal winning combination is won, “left and right middle navigation” is generated, and the indication monitor number “2” is displayed on the indication monitor.

  In the ART state (when the BB is not operating), the internal winning combinations related to the names “F_RT2 promotion — 213”, “F_maintenance — 213”, “F_RT3 promotion — 213”, and “F_medium_bell_1” to “F_medium_bell_5” are instructed. It is associated with the monitor number “3” (middle left / right navigation). Therefore, in the ART state (when the BB is not operating), any of the names “F_RT2 promotion — 213”, “F_maintenance — 213”, “F_RT3 promotion — 213”, and “F_medium_bell_1” to “F_medium_bell_5” When the internal winning combination is won, "middle left / right navigation" is generated, and the instruction monitor number "3" is displayed on the instruction monitor.

  In the ART state (when the BB is not activated), the internal winning combinations related to the names “F_RT2 promotion — 231”, “F_maintenance — 231”, “F_RT3 promotion — 231”, and “F_medium_bell_6” to “F_medium_bell_9” are instructed. It is associated with the monitor number “4” (middle right left navigation). Therefore, in the ART state (when the BB is not operated), the names “F_RT2 promotion — 231”, “F_maintenance — 231”, “F_RT3 promotion — 231”, and any of the “F_medium bell — 6” to “F_medium bell — 9” When the internal winning combination is won, "middle right left navigation" is generated, and the instruction monitor number "4" is displayed on the instruction monitor.

  In the ART state (when the BB is not activated), the internal winning combinations related to the names “F_RT2 promotion_3rd”, “F_maintenance_3rd”, “F_RT3 promotion_3rd”, and “F_right_bell_1” to “F_right_bell_4” are instructed. It is associated with the monitor number "5" (right-left middle navigation). Therefore, in the ART state (when the BB is not operating), any of the names “F_RT2 promotion_3rd”, “F_maintenance_3rd”, “F_RT3 promotion_3rd”, and any of “F_right_bell_1” to “F_right_bell_4” is used. When the internal winning combination is won, “right-left center navigation” is generated, and the instruction monitor displays the instruction monitor number “5”.

  In the ART state (when the BB is not operating), the internal winning combination associated with the names “F_right bell_5” to “F_right bell_9” is associated with the instruction monitor number “6” (right middle left navigation). Therefore, in the ART state (when the BB is not operating), when the internal winning combination of any of the names “F_Right Bell_5” to “F_Right Bell_9” is won, “Right Middle Left Navigation” occurs. Then, the indication monitor number "6" is displayed on the indication monitor.

  In the ART state (BB operation), as shown in FIGS. 271 and 272, the names “F_RT2 promotion_123”, “F_maintenance_123”, “F_RT3 promotion_123”, “F_left bell_1”, and “F_left” The internal winning combination related to “bell — 5” is associated with the instruction monitor number “1” (left middle right navigation). Therefore, in the ART state (during BB operation), the internals related to any of the names “F_RT2 promotion_123”, “F_maintenance_123”, “F_RT3 promotion_123”, “F_left bell_1”, and “F_left bell_5” When the winning combination is won, "left center right navigation" is generated, and the instruction monitor number "1" is displayed on the instruction monitor.

  In the ART state (BB operation), the internal winning combination related to the names “F_RT2 promotion_132”, “F_maintenance_132”, “F_RT3 promotion_132”, and “F_left bell_9” is indicated by the instruction monitor number “2” (left and right middle). Navi). Therefore, when the internal winning combination related to any of the names “F_RT2 promotion_132”, “F_maintenance_132”, “F_RT3 promotion_132”, and “F_left bell_9” is won in the ART state (BB operation). Indicates that "navigation in left and right" is generated, and the indication monitor number "2" is displayed on the indication monitor.

  In the ART state (while the BB is operating), the internal winning combination for the names “F_RT2 promotion — 213”, “F_maintenance — 213”, “F_RT3 promotion — 213”, “F_medium_bell_2”, and “F_medium_bell_5” is indicated by the instruction monitor. It is associated with the number “3” (middle left / right navigation). Therefore, in the ART state (while BB is operating), the internals related to any of the names “F_RT2 promotion — 213”, “F_maintenance — 213”, “F_RT3 promotion — 213”, “F_medium_bell_2”, and “F_medium_bell_5” When the winning combination is won, "middle left / right navigation" occurs, and the instruction monitor number "3" is displayed on the instruction monitor.

  In the ART state (BB operation), the internal winning combination related to the names “F_RT2 promotion_231”, “F_maintenance_231”, “F_RT3 promotion_231”, and “F_medium_bell_8” is indicated by the instruction monitor number “4” (middle right left Navi). Therefore, when the internal winning combination related to any of the names “F_RT2 promotion_231”, “F_RT3 promotion_231”, “F_RT3 promotion_231” and “F_medium_bell_8” is won in the ART state (BB operation). Indicates that "middle right left navigation" occurs, and the indication monitor number "4" is displayed on the indication monitor.

  In the ART state (while the BB is operating), the internal winning combination related to the names “F_RT2 promotion_3rd”, “F_maintenance_3rd”, “F_RT3 promotion_3rd”, and “F_right-bell_3” is indicated by the instruction monitor number “5” (the middle right and left). Navi). Therefore, in the ART state (during BB operation), when an internal winning combination related to any of the names “F_RT2 promotion_3rd”, “F_maintenance_3rd”, “F_RT3 promotion_3rd”, and “F_right-bell_3” is won. Indicates that "right-left center navigation" occurs, and the indication monitor number "5" is displayed on the indication monitor.

  In the ART state (BB operation), the internal winning combination associated with the names “F_right bell_7” and “F_right bell_8” is associated with the instruction monitor number “6” (right middle left navigation). Therefore, when the internal winning combination with the name “F_Right Bell — 7” or “F_Right Bell — 8” is won in the ART state (BB operation), “Right Middle Left Navigation” occurs and the instruction monitor Indicates the instruction monitor number "6".

  Further, in the normal state (during BB operation), the names “F_RB bell”, “F_RB bellibel”, “F_RB weak check”, “F_RB strong check”, “F_RBBAR alignment”, “F_RB chance” and “F_BAR loss” are displayed. Such an internal winning combination is associated with the instruction monitor number “7” (reverse navigation). Therefore, in the normal state (BB operation), the names “F_RB Bell”, “F_RB Sveribel”, “F_RB Weak Che”, “F_RB Strong Che”, “F_RBBAR Alignment”, “F_RB Chance Ch” and “F_BAR Lost” In the case where the internal winning combination according to any one of the above is won, a "reverse push navigation" is generated, and the indication monitor number "7" is displayed on the indication monitor.

<Game lock type>
In the pachislo 1 of the present embodiment, when a specific condition is satisfied, a game lock for invalidating a game operation by a player for a predetermined period is generated, and various effects are performed during the game lock period. Here, with reference to FIGS. 273A to 273D, an example of the game lock executed in the pachislo 1 of the present embodiment will be described.

(1) Game Lock at Bonus Winning FIG. 273A is a diagram summarizing the contents of a game lock executed at the time of winning a bonus (BB) (hereinafter, referred to as “game lock at bonus win”). As shown in FIG. 273A, the content of the game lock at the time of the bonus prize changes according to the type of the BB that has won, and the gaming state (ball-out state) at the time of the BB prize. The bonus winning game lock is a specific example of the “first lock” according to the present invention.

  More specifically, when the payout state is a state other than the CZ state, and when BB2 or BB3 is won, after the medal payout processing is completed, a bonus prize game lock with a lock time of “8 seconds” is generated. In addition, when the payout state is a state other than the CZ state, and when the BB1 is won, after the medal payout processing is completed, a bonus prize game lock with a lock time of “3 seconds” is generated. In addition, during these game lock periods, a notification effect at the time of a bonus prize is performed on the sub side.

  On the other hand, when the payout state is the CZ state and the BB2 or BB3 prize is won, a bonus prize game lock with a lock time of “0 second” is generated after the medal payout processing is completed. In other words, when the payout state is in the CZ state and when BB2 or BB3 is won, the game lock is not generated at the time of bonus winning. In this case, the sub-side does not perform the notification effect at the time of winning the bonus. In addition, when the payout state is the CZ state and the BB1 is won, after the medal payout processing is completed, a bonus prize game lock with a lock time of “0 seconds” is generated. That is, the payout state is the CZ state, and even when the BB1 is won, the game lock at the time of the bonus prize is not generated. Also in this case, the notification effect at the time of the bonus prize is not performed on the sub side.

  That is, in the present embodiment, even if a BB wins while the payout state is the CZ state, the game lock is not generated at the time of the bonus winning, and the notification effect at the time of the bonus winning is not performed on the sub side ( A notification effect similar to the notification effect at the time of the bonus prize performed in a state other than the CZ state is not performed.) This is because the battle effect is given priority over the bonus effect in the CZ state. The present invention is not limited to this. When the BB wins in the CZ state, an effect that does not require a game lock such as lamp lighting may be performed to indicate the BB prize.

  Here, the flow of the effect when the bonus (BB) is won during the game period in the CZ state will be described. When the bonus (BB) is won during the game period in the CZ state, the bonus notification effect (game lock for bonus prize) is not executed.

  Next, after winning the bonus (BB), the bonus game processing is performed in the internal processing on the main side, but the effect for the bonus is not performed in the effect until the value of the enemy HP becomes “0” or less. The effect (battle effect) in the CZ state, which has been executed before the winning of the bonus, is continuously performed. Note that the enemy HP is also subtracted during the bonus game. At this time, “25” (correction value during the special prize) is determined as the subtraction value (damage point) of the enemy HP in each game, and the “strong rare” is determined. Is determined, “200” is determined as the subtraction value (damage point) of the enemy HP (the enemy HP ≦ 0 is determined).

  Next, when the value of the enemy HP after the subtraction becomes equal to or less than “0”, the battle effect in the CZ state is ended, and thereafter, a later-described CZ end game lock and a corresponding CZ end effect are performed. Then, after the end of the game lock at the end of the CZ, the effect contents are switched to the effect for the bonus, and thereafter, the effect for the bonus is performed until the end of the bonus.

(2) CZ end game lock FIG. 273B is a diagram summarizing the contents of a game lock (hereinafter referred to as “CZ end game lock”) executed when the game period in the CZ state ends. In the present embodiment, in the end game of the game period in the CZ state, a game lock at the end of the CZ for a lock time of “8 seconds” occurs after the medal payout process is completed. During the game lock period, an effect for ending the CZ is performed on the sub side. Note that the game lock at the end of the CZ is a specific example of the “second lock” according to the present invention.

  For example, when a CZ battle (battle A or C) is won, during the game lock at the end of the CZ, an effect for battle victory of a friendly character is performed by the control of the sub side, and the CZ battle (battle A) is performed. Or, when the player loses C), during the game lock period at the end of the CZ, an effect for the battle losing of the friendly character is performed by the control of the sub side. In the CZ end lottery performed when the end condition of the CZ state is satisfied, if “resurrection” is determined as the lottery result, the game lock at the end of the CZ is not generated.

(3) CZ Resurrection Game Lock FIG. 273C shows a game lock executed when “resurrection” is determined as a lottery result in the CZ end lottery performed when the end condition of the CZ state is satisfied (hereinafter, “CZ resurrection”). It is a diagram summarizing the contents of “time game lock”).

  In the present embodiment, when “resurrection” is determined as a lottery result in the CZ end lottery, a CZ resumption game lock for a lock time of “16 seconds” occurs after the second stop of the reel in the game. Then, during the game lock period, a resurrection effect of the ally character is performed on the sub side.

(4) Game Lock for Reporting Allies HP Addition FIG. 273D shows a game lock (hereinafter, referred to as “ally allies”) executed when the ally HP additional lottery performed when the victory of the CZ battle (battle A or C) is confirmed is determined. HP addition notification game lock "). In addition, the game lock for notification of addition to the ally HP is executed when the lever is turned on (when the start lever 16 is operated by the player) of the game next to the game (final game of the CZ game) in which the lottery is added to the ally HP.

  As shown in FIG. 273A, the content of the game lock at the time of the bonus prize changes according to the addition HP of the ally HP determined by the lottery addition to the ally HP.

  Specifically, when the additional HP is “150”, a gaming lock for notification of the additional HP of the ally HP having a lock time of “45 seconds” occurs, and when the additional HP is “200”, the lock time “ For 57 seconds, a game lock for reporting information on the ally HP is generated. When the additional HP is “250”, a friendly HP additional notification game lock with a lock time of “69 seconds” is generated, and when the additional HP is “300”, the lock time is “81 seconds”. A game lock for notification of addition to the ally HP is generated. In other words, as the added HP of the ally HP is larger, the lock time of the game lock for notifying the added ally HP is longer.

  Then, during the period of the game lock for notifying the addition of the friendly HP, an effect of notifying the added HP of the friendly HP is performed by the control of the sub side. When the additional HP is “50” or “100”, the game lock for notifying the additional HP of the ally is not generated.

<Description of operation of main control circuit>
Next, with reference to FIGS. 274 to 322, the contents of various processes executed by the main CPU 101 of the main control circuit 90 using a program in the present embodiment will be described. Although not described below, in the present embodiment, a Q register (extension register) is used in a source program used when the main CPU 101 executes various processes, similarly to the pachislo 1 of the first embodiment. Various instruction codes (for example, an “LDQ” instruction, an “ORQ” instruction, etc.) dedicated to the main CPU 101 are used. In the following description and flowcharts of various processes, illustrations and descriptions of the processes executed in the same manner as in the first embodiment are omitted as appropriate.

[Processing at power-on (reset interrupt)]
First, in the present embodiment, a process at the time of turning on the power of the pachislot 1 (reset interrupt) performed under the control of the main CPU 101 will be described with reference to FIG.

  First, the main CPU 101 determines whether or not a power supply monitoring port (power supply monitoring means) is on (S2001).

  In S2001, when the main CPU 101 determines that the power supply monitoring port is in the ON state (if S2001 is YES), the main CPU 101 repeats the process of S2001. Here, the ON state of the power supply monitoring port means a state where the power supply voltage (DC + 5V) supplied to the main CPU 101 is not stable.

  On the other hand, in S2001, when the main CPU 101 determines that the power supply monitoring port is not on (when S2001 is NO), the main CPU 101 determines whether the setting key type switch 54 is on. (S2002).

  In S2002, when the main CPU 101 determines that the setting key type switch 54 is not in the ON state (when S2002 is NO), the main CPU 101 performs a power return process (S2003). In this process, the main CPU 101 performs a process of returning the state of the game to the state before the power interruption detection. The details of the power return process will be described later with reference to FIG. 275 described later.

  Next, the main CPU 101 performs an initialization command generation and storage process (S2004). In this process, the main CPU 101 generates initialization command data transmitted from the main control circuit 90 to the sub control circuit 200 at the end of the power restoration process, and stores the command data in a communication data storage area provided in the main RAM 103. save. The initialization command stored in the communication data storage area is transmitted from the main control circuit 90 to the sub control circuit 200 by the communication data transmission process in the interrupt process described with reference to FIG. 158, as in the first embodiment. Sent to. After the process in S2004, the main CPU 101 starts a main process described later (see FIG. 277 described later).

  Here, returning to the process of S2002 again, in S2002, when the main CPU 101 determines that the setting key type switch 54 is in the ON state (if S2002 is YES), the main CPU 101 executes the setting change process. Is performed (S2005). In this process, the main CPU 101 initializes (clears) various information related to a game (payout performance) and resets various information related to the cleared game. The details of the setting change process will be described later with reference to FIG. 276 described later.

  Next, the main CPU 101 performs an initialization command generation and storage process (S2006). In this process, the main CPU 101 generates initialization command data transmitted from the main control circuit 90 to the sub control circuit 200 at the end of the setting change process, and stores the command data in a communication data storage area provided in the main RAM 103. To save. The initialization command stored in the communication data storage area is transmitted from the main control circuit 90 to the sub control circuit 200 by the communication data transmission process in the interrupt process described with reference to FIG. 158, as in the first embodiment. Sent to. Then, after the process of S2006, the main CPU 101 starts a main process described later (see FIG. 277 described later).

[Power return process]
Next, with reference to FIG. 275, the power return process performed in S2003 during the power-on (reset interrupt) process (see FIG. 274) will be described. FIG. 275 is a flowchart showing the procedure of the power return process.

  First, the main CPU 101 determines whether or not the backup is normal (S2011). In this determination processing, the main CPU 101 determines whether or not the backup is normal by performing error detection using the checksum value.

  In S2011, when the main CPU 101 determines that the backup is normal (YES in S2011), the main CPU 101 returns various states related to the game to the state before the power cut based on the backup data (S2012). ). Then, after the processing of S2012, the main CPU 101 ends the power interruption recovery processing, and moves the processing to S2004 of the power-on processing (see FIG. 274).

  On the other hand, in S2011, when the main CPU 101 determines that the backup is not normal (NO in S2011), the main CPU 101 performs power-on error processing (S2013). In this process, the main CPU 101 notifies that the backup is not normal by displaying an error or the like.

[Process when setting is changed]
Next, with reference to FIG. 276, a description will be given of the setting change process performed in S2005 during the power-on (reset interrupt) process (see FIG. 274).

  First, the main CPU 101 performs a RAM initialization process (S2021). In this process, the main CPU 101 performs a process of clearing (initializing) various information (counter value, flag, etc.) related to the game. For example, the CZ lottery mode described later, the value of the cycle number counter, the value of the game number counter, the P point, the friend HP, etc. are cleared. In this process, the main CPU 101 sets, for example, a main game state, a payout state, and the like to an initial state.

  Next, the main CPU 101 performs a process of acquiring a random number for lottery at the time of changing the setting (S2022). Next, the main CPU 101 sets a lottery parameter at the time of setting change (S2023). In this process, the main CPU 101 determines the lottery index number corresponding to the setting value after the setting change (any one of the settings 1 to 6) based on the list of the CZ lottery mode lottery index numbers shown in FIG. Set to. In the present embodiment, as shown in FIG. 222, the lottery index number corresponding to the setting value after the setting change is “0” regardless of the setting value.

  Next, the main CPU 101 performs a CZ lottery mode lottery process (when setting is changed) (S2024). In this process, the main CPU 101 refers to the CZ lottery mode lottery table (see FIG. 221), and based on the lottery index number (“0” in this embodiment) associated with the set value, performs the CZ lottery mode lottery. I do. Next, the main CPU 101 sets the lottery result (low or high certainty) of the CZ lottery mode lottery (when setting is changed) to the CZ lottery mode (S2025).

  Next, the main CPU 101 adds “1” to the value of the cycle counter (S2026). Next, the main CPU 101 sets the current CZ lottery mode (low or high accuracy) as a lottery parameter (S2027).

  Next, the main CPU 101 performs a CZ random determination mode cycle game random determination process (S2028). In this process, the main CPU 101 refers to the CZ lottery mode cycle game number lottery table (see FIG. 223) and performs the CZ lottery mode cycle game number lottery based on the lottery parameter (CZ lottery mode). Next, the main CPU 101 sets the lottery result (40, 45, 50, 55, 60 or 65 games) of the CZ lottery mode cycle game number lottery in the game number counter (S2029).

  Next, the main CPU 101 acquires a random number value in the range of 0 to 255, and adds a quotient value obtained by dividing the random number value by “50” to the game number counter (S2030). Next, the main CPU 101 acquires a random number value in the range of 0 to 255, and adds a quotient value obtained by dividing the random number value by “6” to the game number counter (S2031). By the processing in S2030 and S2031, the game period (the number of games) in the first cycle of the normal normal state performed after the setting change is longer than in other cases.

  Next, the main CPU 101 performs a cycle management mode shift lottery (when setting is changed) process (S2032). In this process, the main CPU 101 refers to the cycle management mode transition lottery table (see FIG. 227), and selects a lottery index number (“0” in the present embodiment: The lottery for shifting to the cycle management mode is performed based on FIG. 228). Next, the main CPU 101 sets the lottery result (any one of modes A to E) of the cycle management mode shift lottery to the cycle management mode (S2033).

  Next, the main CPU 101 performs a P-point initial value lottery process (S2034). In this process, the main CPU 101 refers to the P-point initial value lottery table (see FIG. 230) and performs P-point initial value random determination. Next, the main CPU 101 sets the lottery result (0, 50, 100, 180, 205, 220, 235 or 250) of the P point initial value lottery to the P point (S2035).

  Next, the main CPU 101 sets “50” to the initial value of the friend HP (S2036). Then, after the processing of S2036, the main CPU 101 ends the processing at the time of setting change, and shifts the processing to S2006 of the processing at power-on (reset interrupt) (see FIG. 274).

[Main processing of pachislot under control of main CPU]
Next, the main processing (main operation processing) of the pachislot 1 executed under the control of the main CPU 101 will be described with reference to FIG. FIG. 277 is a flowchart (hereinafter, referred to as a main flow) showing a procedure of a main process.

  First, the main CPU 101 performs a RAM initialization process (S2041). In this process, the main CPU 101 sets the address of “at the end of one game” in the game RAM area of the main RAM 103 shown in FIG. 12C as a start address of the initialization start, and sets the address of the game RAM area from the start address. Erase (clear) information up to the last address. The storage area in this range is a storage area in which data must be deleted for each unit game (game) such as an internal winning combination storage area and a display combination storage area.

  Next, the main CPU 101 performs a medal acceptance / start check process (S2042). In this process, the main CPU 101 performs an input check process for a medal sensor (not shown), a start switch 79, and the like. Note that the medal acceptance / start check process of the present embodiment is performed in the same manner as the medal acceptance / start check process of the first embodiment described with reference to FIG.

  Next, the main CPU 101 performs a random number acquisition process (S2043). In this process, the main CPU 101 determines the random number value for internal winning combination lottery (0 to 65535: the value of the random number register 0 of the random number circuit 110 to be a hard latched random number) or the random number value for effect used in various ART-related lotteries. 0 to 65535: each value of the random number registers 1 to 3 of the random number circuit 110 that becomes a soft latch random number, and 0 to 255: each value of the random number registers 4 to 7 of the random number circuit 110 that becomes a soft latch random number). The extracted various random numbers are stored in a random value storage area (not shown) provided in the main RAM 103. Note that the random number acquisition processing according to the present embodiment is performed in the same manner as the random number acquisition processing according to the first embodiment described with reference to FIG.

  Next, the main CPU 101 performs an internal lottery process (S2044). In this process, the main CPU 101 performs an internal winning combination determination process by lottery based on the random number value (hard latch random number) extracted in S2043. The details of the internal lottery process will be described later with reference to FIG. 278 described later.

  Next, the main CPU 101 performs a process of acquiring a special prize winning number and a small winning combination number (S2045). In this process, the main CPU 101 generates (extracts) a special prize winning number and a small winning combination number based on a hit request flag status (flag status information) corresponding to the determined internal winning combination. The details of the process of acquiring the special prize winning number and the small winning combination number will be described later with reference to FIG. 279 described later.

  Next, the main CPU 101 performs a lottery process when the lever is turned on (S2046). In this process, the main CPU 101 mainly performs various random determination processes related to ART (AT) based on the random number values for various effects extracted in S2043 and the internal winning combination determined in S2044. The details of the lottery process when the lever is on will be described later with reference to FIG. 280 described later.

  Next, the main CPU 101 sets the push order navigation (S2047). In this process, the main CPU 101 performs a process of setting an instruction monitor number (a numerical value indicating a navigation type) to be displayed (notified) on an instruction monitor (not shown) based on, for example, a gaming state, an internal winning combination, and the like.

  Next, the main CPU 101 performs a reel stop initial setting process (S2048). In this process, the main CPU 101 refers to the reel stop initialization table (not shown) of the present embodiment, and based on the internal winning combination (small combination winning number) and the game state, the drawing priority table selection table number, the drawing-in Processing for acquiring the priority table number and the stop table number, processing for storing “3” in the stop button inactivity counter, and the like are performed.

  Next, the main CPU 101 performs a start command generation and storage process (S2049). In this process, the main CPU 101 generates start command data to be transmitted to the sub control circuit 200, and stores the command data in a communication data storage area (see FIG. 75B) provided in the main RAM 103. The start command stored in the communication data storage area is transmitted from the main control circuit 90 to the sub control circuit 200 by the communication data transmission process in the interrupt process described with reference to FIG. 158, as in the first embodiment. You. The start command includes a parameter (such as a sub flag) for specifying an internal winning combination or the like.

  Next, the main CPU 101 performs a game weight digestion process (S2050). In this process, if a predetermined wait time (for example, 4.1 seconds) has not elapsed since the start of the previous game (unit game), the main CPU 101 performs a standby process until the predetermined wait time has elapsed.

  Next, the main CPU 101 performs a reel rotation start process (S2051). In this process, the main CPU 101 requests the start of rotation of all reels. When the start of rotation of all reels is requested, the drive of three stepping motors (not shown) is controlled by an interrupt process (see FIG. 158) executed at a constant cycle (1.1172 msec), The rotation of the reel 3L, the middle reel 3C, and the right reel 3R is started. Next, each reel is controlled to accelerate until its rotation speed reaches a constant speed, and thereafter, is controlled so as to maintain the constant speed.

  Next, the main CPU 101 performs a reel rotation start command generation and storage process (S2052). In this process, the main CPU 101 generates data of a reel rotation start command to be transmitted to the sub control circuit 200, and stores the command data in a communication data storage area (see FIG. 75B) provided in the main RAM 103. The reel rotation start command stored in the communication data storage area is transmitted from the main control circuit 90 to the sub-control circuit 200 by the communication data transmission process in the interrupt process described with reference to FIG. 158, as in the first embodiment. Sent. The reel rotation start command includes a parameter indicating that the rotation start operation of the reel has started.

  Next, the main CPU 101 performs a pull-in priority storing process (S2053). In this processing, the main CPU 101 acquires the attraction priority data and stores it in the attraction priority data storage area. It should be noted that the attraction priority storage processing of this embodiment is performed in the same manner as the attraction priority storage processing of the first embodiment described with reference to FIG. 126.

  Next, the main CPU 101 performs a reel stop control process (S2054). In this process, the main CPU 101 controls the rotation of the corresponding reel based on the timing at which the left stop button 17L, the middle stop button 17C, and the right stop button 17R are pressed, and the internal winning combination. The reel stop control processing of this embodiment is performed in the same manner as the reel stop control processing of the first embodiment described with reference to FIG.

  Next, the main CPU 101 performs a winning search process (S2055). In this process, the main CPU 101 stores the data in the symbol code storage area (see FIG. 266) in the display combination storage area (see FIG. 262). In this process, the main CPU 101 determines whether or not the display combination is displayed on the activated line, and sets the number of payout medals based on the determination result. The prize search process of this embodiment is performed in the same manner as the prize search process of the first embodiment described with reference to FIG. However, in the winning search process, the maximum payout number of medals is set to 13 during the BB operation and to 9 during the non-BB operation.

  Next, the main CPU 101 performs an RT state control process (S2056). In this process, the main CPU 101 performs RT state transition control based on the display combination determined in S2055. The details of the RT state control process will be described later with reference to FIG.

  Next, the main CPU 101 performs a winning check / medal payout process (S2057). In this process, the main CPU 101 performs a process of generating a winning operation command. In this process, the main CPU 101 drives the hopper device 51 and updates the number of credits based on the number of payouts of the display combination determined in S2055, and performs a medal payout process. The prize check / medal payout process of this embodiment is performed in the same manner as the prize check / medal payout process of the first embodiment described with reference to FIG.

  Next, the main CPU 101 performs an effect lottery process at the end of the game (S2058). In this process, the main CPU 101 performs various ART-related lottery processes at the time of the end of the game. Further, in this process, the main CPU 101 controls the transition of the payout state as necessary. The details of the game end lottery process at the end of the game will be described later with reference to FIG.

  Next, the main CPU 101 performs a bonus end check process (S2059). In this processing, the main CPU 101 refers to various counters (not shown) for managing the end of the bonus (BB (RB)) game provided in the main RAM 103, and determines whether or not to end the operation of the bonus game. Check if. The details of the bonus end check processing will be described later with reference to FIG.

  Next, the main CPU 101 performs a bonus operation check process (S2060). In this process, the main CPU 101 checks whether or not to start the operation of the bonus (BB (RB)) game and whether or not to replay the game. The details of the bonus operation check process will be described later with reference to FIG. 322 described later. Then, after the processing of S2060, the main CPU 101 returns the processing to S2041, and repeats the processing of S2041 and thereafter.

[Internal lottery processing]
Next, the internal lottery process performed in S2044 in the main flow (see FIG. 277) will be described with reference to FIG. FIG. 278 is a flowchart showing the procedure of the internal lottery process.

  First, the main CPU 101 performs a setting value / medal insertion number check process (S2071). In this process, the main CPU 101 performs a process of checking the set value of the current game (any one of 1 to 6) and the number of inserted medals (three in the present embodiment).

  Next, the main CPU 101 sets the internal lottery table and the number of lotteries based on the current main game state (S2072). In this process, for example, when the current main game state is the RT0 state, the main CPU 101 sets the internal lottery table for RT0 shown in FIGS. 188 and 189, and sets 81 as the number of lotteries. In this process, for example, when the current main game state is the state between BB3 flags, the main CPU 101 sets the internal BB3 flag lottery table shown in FIGS. 196 and 197 and sets the number of lotteries to 81. Set the times. Further, in this processing, for example, when the current main game state is the BB2 or BB3 state, the main CPU 101 sets the BB2 and BB3 middle internal lottery tables shown in FIG. 202 and sets the number of times of lottery to seven. set.

  Next, the main CPU 101 acquires the lottery value of the lottery target combination from the set internal lottery table (S2073). Next, the main CPU 101 acquires the random number value (any one of 0 to 65535) for internal winning combination lottery stored in the random number storage area (S2074).

  Next, the main CPU 101 performs a lottery execution process (S2075). In this process, the main CPU 101 adds the random number value acquired in S2074 to the lottery value acquired in S2073, and sets the addition result as a lottery result (winning / non-winning of the lottery target combination). In the lottery execution process, when the sum of the lottery value and the random number value exceeds 65535 (in the case of overflow), it is determined that the lottery target combination has been won (the lottery target combination has been determined as an internal winning combination). You.

  Next, the main CPU 101 stores a value obtained by adding the random number value to the random number value (the random number value after the execution of the random determination) as a new random number value in the random number storage area (S2076). Next, the main CPU 101 determines whether or not the lottery has been won in the lottery execution process (whether or not an overflow has occurred) (S2077).

  In S2077, when the main CPU 101 determines that the lottery execution process has been won (if S2077 is YES), the main CPU 101 determines the hit request flag status corresponding to the won internal winning combination (special prize winning number × 59 + small winning combination). (S2078). For example, during the non-BB game, when the lottery target combination is “F_BB3 + F_chance lip” (special prize number = 3, small combination winning number = 2: see FIGS. 204 and 205), when the lottery is won, S2078 In the processing of (1), the hit request flag status “179 (= 3 × 59 + 2)” is obtained. Then, after the processing of S2078, the main CPU 101 ends the internal lottery processing, and moves the processing to S2045 of the main flow (see FIG. 277).

  On the other hand, in S2077, when the main CPU 101 determines that the lottery has not been won in the lottery execution process (NO in S2077), the main CPU 101 updates the lottery target role to the next role in the internal lottery table, and the lottery. The number of times is subtracted by 1 (S2079). Next, the main CPU 101 determines whether or not the number of lotteries after the subtraction is “0” (S2080).

  In S2080, when the main CPU 101 determines that the number of lotteries after the subtraction is not “0” (if S2080 is NO), the main CPU 101 returns the processing to S2073 and repeats the processing from S2073.

  On the other hand, in S2080, when the main CPU 101 determines that the number of lotteries after the subtraction is “0” (if S2080 is YES), that is, when the internal winning combination is “out”, the main CPU 101 The losing status is set (S2081). The “losing status” corresponds to the hit request flag status (“0”) in which both the special winning number and the small winning number are “0”. Then, after the process of S2081, the main CPU 101 ends the internal lottery process, and moves the process to S2045 of the main flow (see FIG. 277).

[Acquisition processing of a special winning number and a small winning number]
Next, with reference to FIG. 279, the process of acquiring the special prize winning number and the small winning combination number performed in S2045 in the main flow (see FIG. 277) will be described. FIG. 279 is a flowchart showing the procedure of a process for obtaining a special prize winning number and a small winning combination number.

  First, the main CPU 101 generates (extracts) a special winning number and a small winning number based on the hit request flag status acquired in the internal lottery process (S2091). In this process, the main CPU 101 divides the value of the hit request flag status by “59”, sets the quotient value generated by this division process as the special prize winning number (any of 0 to 3), Is the small winning combination number (any of 0 to 58) (see FIGS. 204 and 205). The special prize winning number and the small winning combination number extracted in this process are stored in a winning number storage area (not shown) in the main RAM 103.

  Next, the main CPU 101 determines whether or not the main game state is a state between BB flags (S2092). In this process, the main CPU 101 refers to the on / off state of each flag stored in the carryover combination storage area to determine whether or not the main game state is the state between the BB flags. In S2092, when the main CPU 101 determines that the main game state is the state between the BB flags (if S2092 is YES), the main CPU 101 ends the acquisition processing of the special prize winning number and the small combination winning number, and To S2046 of the main flow (see FIG. 277).

  On the other hand, in S2092, when the main CPU 101 determines that the main gaming state is not the state between the BB flags (NO in S2092), the main CPU 101 determines whether or not BB has been won (S2093). In S2093, when the main CPU 101 determines that BB has not been won (if S2093 is NO), the main CPU 101 ends the process of acquiring the special prize winning number and the small winning combination number, and proceeds to the main flow ( The process moves to S2046 in FIG. 277).

  On the other hand, in S2093, when the main CPU 101 determines that the BB has been won (if S2093 is YES), the main CPU 101 performs a process of updating the number of games counter and freezing (S2094). In this embodiment, the number-of-games counter is composed of one byte, and the information stored in the bit 7 is information indicating the presence or absence of a frozen state. Then, in the process of S2094, "1" is stored in bit 7 of the game number counter, whereby the update of the game number counter is frozen.

  Next, the main CPU 101 clears the value of the cycle counter (S2095). That is, in the BB winning game, the update freezing of the game number counter is set, and the value of the cycle number counter is set to “0”. Then, after the processing of S2095, the main CPU 101 ends the processing of acquiring the special prize winning number and the small winning combination number, and shifts the processing to S2046 of the main flow (see FIG. 277).

[Lottery at Lever ON]
Next, with reference to FIG. 280, a description will be given of the lever-on lottery process performed in S2046 in the main flow (see FIG. 277). FIG. 280 is a flowchart showing the procedure of the lottery process when the lever is turned on.

  First, the main CPU 101 performs a sub flag conversion process (S2101). In this process, the main CPU 101 performs a process of converting the internal winning combination into a sub flag (see FIGS. 219A and 219B). Further, in this process, the main CPU 101 also performs a process of converting the sub-flag into payout lottery flags A to C (see FIGS. 220A to 220C).

  Next, the main CPU 101 determines whether or not the main gaming state is a state between BB flags (S2102). In S2102, when the main CPU 101 determines that the main gaming state is the state between the BB flags (if S2102 is YES), the main CPU 101 ends the lever-on lottery process and proceeds to the main flow (see FIG. 277). Move to S2047).

  On the other hand, in S2102, when the main CPU 101 determines that the main game state is not the state between the BB flags (if S2102 is NO), the main CPU 101 performs a friend HP addition process (S2103). In this process, the main CPU 101 determines the on / off state of the friend HP addition flag, and appropriately performs a process according to the determination result. The details of the ally HP addition processing will be described later with reference to FIG. 281 described later.

  Next, the main CPU 101 determines whether or not the main game state is the BB state (S2104). In this process, the main CPU 101 determines whether the main game state is the BB state based on the on / off state of the BB1 to BB3 flags and the RB flag stored in the game state flag storage area (see FIG. 264A). It is determined whether or not.

  In S2104, when the main CPU 101 determines that the main game state is the BB state (if S2104 is YES), the main CPU 101 performs a process during start during BB (S2105). In this process, the main CPU 101 mainly executes various lottery processes at the start of the game in the BB state. The details of the start-time BB processing will be described later with reference to FIG. 282 described later. Then, after the process of S2105, the main CPU 101 ends the lever-on lottery process, and shifts the process to S2047 of the main flow (see FIG. 277).

  On the other hand, in S2104, when the main CPU 101 determines that the main game state is not the BB state (if S2104 is NO), the main CPU 101 decrements the value of the game number counter by 1 (S2106). In this process, when the value of the game number counter after the subtraction is smaller than the lower limit value “0”, the main CPU 101 maintains the value of the game number counter at “0”.

  Next, the main CPU 101 determines whether or not the payout state is the CZ state (S2107). In this process, the main CPU 101 determines whether or not the payout state is the CZ state based on the ON / OFF state of the CZ state flag stored in the payout state flag storage area (see FIG. 265A). Is determined.

  In S2107, when the main CPU 101 determines that the payout state is in the CZ state (when S2107 is YES), the main CPU 101 performs a start-time processing in CZ (S2108). In this process, the main CPU 101 mainly executes various lottery processes at the start of the game in the CZ state. The details of the start-time processing during CZ will be described later with reference to FIGS. 283 and 284 described later. Then, after the processing of S2108, the main CPU 101 ends the lever-on lottery processing, and shifts the processing to S2047 of the main flow (see FIG. 277).

  On the other hand, in S2107, when the main CPU 101 determines that the payout state is not in the CZ state (if S2107 is NO), the main CPU 101 determines whether the payout state is the ART state (S2109). ). In this processing, the main CPU 101 determines whether or not the payout state is the ART state based on the ON / OFF state of the ART flag stored in the payout state flag storage area (see FIG. 265A). Determine.

  In S2109, when the main CPU 101 determines that the payout state is the ART state (if S2109 is YES), the main CPU 101 performs the processing during the start during ART (S2110). In this process, the main CPU 101 mainly executes various lottery processes at the start of the game in the ART state. It should be noted that the details of the processing at the start during ART will be described later with reference to FIGS. 290 and 291 described later. Then, after the process of S2110, the main CPU 101 ends the lever-on lottery process, and shifts the process to S2047 of the main flow (see FIG. 277).

  On the other hand, in S2109, when the main CPU 101 determines that the payout state is not the ART state (if S2109 is NO), the main CPU 101 performs a normal start process (S2111). In this process, the main CPU 101 mainly executes various lottery processes at the start of the game in the normal state. The details of the normal start process will be described later with reference to FIG. 298 described later. Then, after the process of S2111, the main CPU 101 ends the lever-on lottery process, and moves the process to S2047 of the main flow (see FIG. 277).

[Additional processing for friendly HP]
Next, with reference to FIG. 281, the ally HP addition processing performed in S2103 during the lever-on lottery processing (see FIG. 280) will be described. FIG. 281 is a flowchart illustrating the procedure of the friend HP addition processing.

  First, the main CPU 101 determines whether or not the friend HP addition flag is on (S2121). The friendly HP addition flag is provided in the main RAM 103, and is set to an on state when a later-described friendly HP addition lottery (see FIG. 285 described later) is won. In S2121, when the main CPU 101 determines that the ally HP addition flag is not in the ON state (if S2121 is NO), the main CPU 101 ends the ally HP addition processing, and proceeds to the lever-on lottery processing (see FIG. 280). Move to S2104).

  On the other hand, in S2121, when the main CPU 101 determines that the ally HP addition flag is on (when S2121 is YES), the main CPU 101 sets the ally HP addition flag to an off state (S2122). Next, the main CPU 101 sets a lock time (see FIG. 273D) for adding to the ally HP (S2123).

  Next, the main CPU 101 determines whether or not the lock time for adding to the ally HP has elapsed (S2124). In S2124, when the main CPU 101 determines that the lock time for adding to the ally HP has not elapsed (if S2124 is NO), the main CPU 101 repeats the process of S2124. On the other hand, in S2124, when the main CPU 101 determines that the lock time for addition to the ally HP has elapsed (if S2124 is YES), the main CPU 101 ends the addition HP ally process, and proceeds to the lottery process when the lever is on. The process moves to S2104 (see FIG. 280).

[Start processing during BB]
Next, with reference to FIG. 282, a description will be given of the BB start process performed in S2105 during the lever ON lottery process (see FIG. 280). FIG. 282 is a flowchart showing the procedure of the process during start during BB.

  First, the main CPU 101 determines whether or not the payout state is the CZ state (S2131).

  In S2131, when the main CPU 101 determines that the payout state is in the CZ state (when S2131 is YES), the main CPU 101 performs a start time processing in CZ (S2132). In this process, the main CPU 101 mainly executes various lottery processes at the start of the game in the CZ state. The details of the start-time processing during CZ will be described later with reference to FIGS. 283 and 284 described later. Then, after the process of S2132, the main CPU 101 ends the BB start process and the lever ON lottery process (see FIG. 280).

  On the other hand, in S2131, when the main CPU 101 determines that the payout state is not in the CZ state (if S2131 is NO), the main CPU 101 determines whether or not the payout state is the ART state (S2133). ).

  In S2133, when the main CPU 101 determines that the payout state is the ART state (if S2133 is YES), the main CPU 101 performs an ART general lottery process (S2134). In this process, the main CPU 101 mainly executes a lottery process of various benefits that can be given in the BB game during the ART. The details of the ART total lottery process will be described later with reference to FIGS. 288 and 289 described later. Then, after the process of S2134, the main CPU 101 ends the BB start process and the lever ON lottery process (see FIG. 280).

  On the other hand, in S2133, when the main CPU 101 determines that the payout state is not the ART state (if S2133 is NO), the main CPU 101 determines whether the main game state is the BB1 state (S2135). . In this process, the main CPU 101 determines whether or not the main game state is the BB1 state based on the on / off state of the BB1 flag stored in the game state flag storage area (see FIG. 264A). . In S2135, when the main CPU 101 determines that the main gaming state is not the BB1 state (if S2135 is NO), the main CPU 101 performs the processing of S2142 described later.

  On the other hand, in S2135, when the main CPU 101 determines that the main game state is the BB1 state (if S2135 is YES), the main CPU 101 performs a P-point lottery process (S2136). In this process, the main CPU 101 refers to the P-point lottery table (see FIG. 229) and performs P-point lottery. Next, the main CPU 101 sets the lottery result (0, 1, 5, 10, or 20) of the P point lottery to a P point candidate value (S2137). The P point candidate value is a P point that is added when a correct answer (success) is given in a specific pressing order in the normal BB1 game (see FIG. 304 described later).

  Next, the main CPU 101 determines whether or not the internal winning combination with the name “F_RBBAR alignment” has been won (S2138).

  In S2138, when the main CPU 101 determines that the internal winning combination associated with the name “F_RBBAR alignment” has not been won (NO in S2138), the main CPU 101 ends the BB start process and turns on the lever. The time lottery process (see FIG. 280) also ends. On the other hand, in S2138, when the main CPU 101 determines that the internal winning combination with the name “F_RBBAR alignment” has been won (if S2138 is YES), the main CPU 101 sets the premium flag to the ON state (S2139). .

  Note that the premium flag is a flag that indicates whether or not a premium ART has been won (transfer confirmation), and is provided in the main RAM 103. In this embodiment, not only when the premium ART lottery performed in the game in the normal normal state is won, but also when the internal winning combination with the name “F_RBBAR aligned” is won in the normal middle BB1 game, The transition to ART is determined.

  Next, the main CPU 101 performs an ART set number lottery process (S2140). In this process, the main CPU 101 refers to the ART set number random determination table (see FIG. 243) and performs the ART set number random determination. Next, the main CPU 101 sets the lottery result of the ART set number lottery to the ART set B number (S2141). At this point, since the transition to the premium ART has been determined, the lottery result of the ART set number lottery is one of “1” to “4”, and the number of ART sets is always stocked. (See FIG. 243). In the present embodiment, the upper limit of the number of ART sets B is “255”. Then, after the process of S2141, the main CPU 101 ends the BB start process and the lever ON lottery process (see FIG. 280).

  Here, returning to the process of S2135 again, if S2135 is determined to be NO, that is, if the main game state is the BB2 or BB3 state, the main CPU 101 performs the CZ random determination 2 process (S2142). In this process, the main CPU 101 refers to the CZ lottery 2 table (see FIG. 226) and performs the CZ lottery based on the payout lottery flag C (internal winning combination).

  Next, the main CPU 101 determines whether or not the CZ lottery 2 has been won (S2143). In S2143, when the main CPU 101 determines that the CZ lottery 2 has not been won (if S2143 is NO), the main CPU 101 ends the BB start process and the lever ON lottery process (see FIG. 280). Also ends.

  On the other hand, in S2143, when the main CPU 101 determines that the CZ lottery 2 has been won (if S2143 is YES), the main CPU 101 performs CZ enemy character lottery processing (S2144). In this process, the main CPU 101 refers to the CZ enemy character random determination table (see FIG. 234) and performs the CZ enemy character random determination based on the cycle management mode. Next, the main CPU 101 sets the lottery result of the CZ enemy character lottery (CZ enemy character A, CZ enemy character B or CZ enemy character C) as the CZ enemy character (S2145). Then, after the process of S2145, the main CPU 101 ends the BB start process and the lever ON lottery process (see FIG. 280).

[Start processing during CZ]
Next, with reference to FIG. 283 and FIG. 284, a description will be given of the start-time processing during CZ performed in S2108 during the lottery processing at the time of lever ON (see FIG. 280) or S2132 during the start-time processing during BB (see FIG. 282). I do. FIG. 283 and FIG. 284 are flowcharts showing the procedure of the process at the time of start during CZ.

  First, the main CPU 101 performs a special effect lottery process (S2151). In this process, the main CPU 101 refers to the special effect lottery table (see FIG. 237), and determines the special effect lottery index number (see FIG. 238) associated with the combination of the number of remaining CZ games and the payout lottery flag B. ), A special effect lottery is performed.

  Next, the main CPU 101 determines whether or not the special effect lottery has been won (S2152). In this process, the main CPU 101 determines whether or not “strike” or “attack strength UP” is determined as a result of the special effect lottery. In S2152, when the main CPU 101 determines that the special effect lottery has not been won (NO in S2152), the main CPU 101 performs the processing of S2155 described later.

  On the other hand, in S2152, when the main CPU 101 determines that the special effect lottery has been won (if S2152 is YES), the main CPU 101 performs a special effect game number lottery process (S2153). In this process, the main CPU 101 refers to the special effect game number lottery table (see FIG. 239), and based on the special effect lottery result (“strike” or “attack strength UP”), the special effect game number lottery. I do.

  Next, the main CPU 101 sets the lottery result (any of 2 games to 7 games) of the special effect game number lottery to the number of special effect games (S2154). In addition, when the lottery result of the special effect lottery is “strike”, the number of special effect games set in this process becomes the initial value of the “number of remaining striking games”, and the lottery result of the special effect lottery is “ In the case of "attack strength UP", the number of special effect games set in this process becomes the initial value of "attack strength UP remaining games".

  After the processing of S2154 or when S2152 is determined to be NO, the main CPU 101 performs a damage lottery process (S2155). In this process, the main CPU 101 refers to the damage lottery table (see FIG. 240), and determines the lottery index number of the damage lottery (see FIG. 241) associated with the combination of the lottery opportunity (game situation) and the payout lottery flag A. ), A damage lottery is performed.

  Next, the main CPU 101 determines whether or not the lottery result (damage point) of the damage lottery is larger than “0” (S2156).

  In S2156, when the main CPU 101 determines that the lottery result (damage point) of the damage lottery is not larger than “0” (if S2156 is NO), the main CPU 101 performs the process of S2160 described later. On the other hand, in S2156, when the main CPU 101 determines that the lottery result (damage point) of the damage lottery is larger than “0” (if S2156 is YES), the main CPU 101 sets the lottery result (damage point) to damage. It is added (S2157).

  Next, the main CPU 101 determines whether or not the remaining game number of the attack power UP is greater than “0” (whether or not the attack power UP effect is being applied) (S2158).

  In S2158, when the main CPU 101 determines that the remaining game number of the attack power UP is not greater than “0” (if S2158 is NO), the main CPU 101 performs the process of S2160 described later. On the other hand, in S2158, when the main CPU 101 determines that the remaining game number of the attack power UP is larger than “0” (if S2158 is YES), the main CPU 101 performs a process of reflecting the attack power UP effect on the damage. (S2159). Specifically, the main CPU 101 further adds a damage point of “15” to the damage.

  After the processing of S2159, or when S2156 or S2158 is NO, the main CPU 101 determines whether or not the main game state is the BB state (S2160).

  In S2160, when the main CPU 101 determines that the main gaming state is not the BB state (if S2160 is NO), the main CPU 101 performs the processing of S2164 described later. On the other hand, in S2160, when the main CPU 101 determines that the main game state is the BB state (if S2160 is YES), the main CPU 101 damages the in-prize prize correction value (“25” in the present embodiment). It is added (S2161).

  Next, the main CPU 101 determines whether or not the hand associated with the payout lottery flag B “strong rare” has been won (S2162).

  In S2162, when the main CPU 101 determines that the winning combination relating to the payout lottery flag B “strong rare” has not been won (NO in S2162), the main CPU 101 performs the processing of S2164 described later. On the other hand, in S2162, when the main CPU 101 determines that the hand associated with the payout lottery flag B “strong rare” has been won (if S2162 is YES), the main CPU 101 sets “200” as the damage (overwrite). ) (S2163). When this process is performed, the maximum value of the initial value of the enemy HP of the CZ enemy character is “200” (see FIG. 235), so that the battle victory in CZ (transition to ART) is determined.

  After the processing of S2163, or when S2160 or S2162 is NO, the main CPU 101 subtracts damage from the enemy HP (S2164). Next, the main CPU 101 determines whether or not the value of the enemy HP after the subtraction is larger than “0” (S2165).

  In S2165, when the main CPU 101 determines that the value of the enemy HP after the subtraction is not larger than “0” (NO in S2165), the main CPU 101 performs a CZ victory process (S2166). In this process, the main CPU 101 performs various lottery processes at the time of CZ victory. The details of the CZ victory process will be described later with reference to FIG. 285 described later. Then, after the process of S2166, the main CPU 101 ends the start-time process during CZ, and also ends the lottery process at lever-on (see FIG. 280) or the start-time process during BB (see FIG. 282).

  On the other hand, in S2165, when the main CPU 101 determines that the value of the enemy HP after the subtraction is larger than “0” (in the case of YES determination in S2165), the main CPU 101 determines the number of special effect games (the number of consecutive hit games or The attack power UP remaining game number is subtracted by 1 (S2167). Next, the main CPU 101 determines whether or not the number of special effect games after subtraction (the number of remaining consecutively-played games or the number of remaining attack power UP games) is greater than “1” (S2168).

  In S2168, when the main CPU 101 determines that the number of special effect games after the subtraction is larger than “1” (if S2168 is YES), the main CPU 101 performs the process of S2175 described later. On the other hand, in S2168, when the main CPU 101 determines that the number of special effect games after the subtraction is not greater than “1” (NO in S2168), the main CPU 101 determines that the value of the game number counter is “0”. It is determined whether or not there is (S2169).

  In S2169, when the main CPU 101 determines that the value of the game number counter is not “0” (if S2169 is NO), the main CPU 101 performs the processing of S2175 described later. On the other hand, in S2169, when the main CPU 101 determines that the value of the game number counter is “0” (when S2169 is YES), that is, when the gaming state is the CZ end waiting state, the main CPU 101 It is determined whether or not "losing" has been won (S2170).

  In S2170, when the main CPU 101 determines that "losing" has been won (if S2170 is YES), the main CPU 101 performs the processing of S2173 described later. On the other hand, in S2170, when the main CPU 101 determines that the "losing" has not been won (S2170: NO), the main CPU 101 determines whether the payout state is the ART state (S2171). .

  In S2171, when the main CPU 101 determines that the payout state is not the ART state (when S2171 is NO), the main CPU 101 ends the processing during the start during CZ and the lottery processing when the lever is on (see FIG. 280). Alternatively, the start-time processing during BB (see FIG. 282) also ends. On the other hand, when the main CPU 101 determines in S2171 that the payout state is the ART state (if S2171 is determined to be YES), the main CPU 101 determines whether or not the combination according to the sub flag “push order lip” has been won. It is determined (S2172).

  In S2172, when the main CPU 101 determines that the winning combination relating to the sub-flag “push order lip” has not been won (if S2172 is NO), the main CPU 101 performs the processing of S2175 described later.

  On the other hand, in S2172, when the main CPU 101 determines that the hand associated with the sub-flag “push order rip” has been won (if S2172 is YES), or when S2170 is YES, the main CPU 101 determines whether or not to end the CZ. Processing is performed (S2173). In this process, the main CPU 101 refers to the CZ end lottery table (see FIG. 242) and performs the CZ end lottery based on the CZ level.

  Next, the main CPU 101 performs CZ end lottery result processing (S2174). In this process, the main CPU 101 performs various lottery processes according to the lottery result of the CZ end lottery. The details of the CZ end lottery result processing will be described later with reference to FIG. 286 described later. Then, after the processing of S2174, the main CPU 101 ends the start-time processing during CZ, and also ends the lottery processing during lever-on (see FIG. 280) or the start processing during BB (see FIG. 282).

  Here, returning again to the processing of S2168, S2169 or S2172, if S2168 is YES, or if S2169 or S2172 is NO, the main CPU 101 performs CZ continuation processing (S2175). In this process, the main CPU 101 performs various lottery processes when CZ is continued. The details of the CZ continuation process will be described later with reference to FIG. 287 described later. Then, after the process of S2175, the main CPU 101 ends the start-time process during CZ, and also ends the lottery process at lever-on (see FIG. 280) or the start process during BB (see FIG. 282).

[CZ victory processing]
Next, the CZ victory process performed in S2166 during the CZ start process (see FIGS. 283 and 284) will be described with reference to FIG. FIG. 285 is a flowchart showing the procedure of the CZ winning process.

  First, the main CPU 101 clears the enemy HP (sets it to “0”) and sets “0” to the game number counter (S2181). Next, the main CPU 101 performs a lottery process on the ally HP (S2182). In this processing, the main CPU 101 refers to the friendly HP addition lottery table (see FIG. 255) and performs the friendly HP additional lottery based on the payout random determination flag A.

  Next, the main CPU 101 determines whether or not the lottery is added to the ally HP (whether or not the ally HP addition is greater than “0”) (S2183).

  In S2183, when the main CPU 101 determines that the ally HP addition lottery has been won (if S2183 is YES), the main CPU 101 sets the ally HP addition flag to the ON state (S2184). Next, the main CPU 101 adds the lottery result (additional HP) to the ally HP (S2185). In the present embodiment, the upper limit of the ally HP is set to “65535”. Then, after the processing of S2185, the main CPU 101 performs the processing of S2188 described later.

  On the other hand, in S2183, when the main CPU 101 determines that the lottery on the ally HP has not been won (S2183 is NO), the main CPU 101 determines whether or not the payout state is the ART state (S2186). ).

  In S2186, when the main CPU 101 determines that the payout state is not the ART state (when S2186 is NO), the main CPU 101 performs the processing of S2188 described later. On the other hand, when the main CPU 101 determines in S2186 that the payout state is the ART state (if S2186 is YES), the main CPU 101 adds the friend HP to the minimum guaranteed value (“10” in the present embodiment). Is added to the friend HP (S2187).

  After the processing of S2185 or S2187, or if S2186 is NO, the main CPU 101 determines whether or not the payout state is the ART state (S2188). In S2188, when the main CPU 101 determines that the payout state is the ART state (if S2188 is YES), the main CPU 101 ends the CZ victory process and starts the CZ start process (FIG. 283 and FIG. 283). (See FIG. 284).

  On the other hand, in S2188, when the main CPU 101 determines that the payout state is not the ART state (if S2188 is NO), the main CPU 101 performs an ART set number random determination process (S2189). In this process, the main CPU 101 refers to the ART set number random determination table (see FIG. 243) and performs the ART set number random determination. Next, the main CPU 101 sets the lottery result (any one of “0” to “4”) of the ART set number lottery to the ART set B number (S2190). After the process in S2190, the main CPU 101 ends the CZ victory process and also ends the CZ start process (see FIGS. 283 and 284).

[CZ end lottery result processing]
Next, with reference to FIG. 286, a description will be given of the CZ end lottery result processing performed in S2174 during the CZ start processing (see FIGS. 283 and 284). FIG. 286 is a flowchart showing the procedure of the CZ end lottery result processing.

  First, the main CPU 101 determines whether or not the lottery result of the CZ end lottery is “Resurrection” (S2201). In S2201, when the main CPU 101 determines that the lottery result of the CZ end lottery is not “Resurrection” (if S2201 is NO), the main CPU 101 performs the process of S2204 described later.

  On the other hand, in S2201, when the main CPU 101 determines that the lottery result of the CZ end lottery is “Resurrection” (if S2201 is YES), the main CPU 101 sets (reserves) a resurrection effect (S2202). By this processing, after the second stop of the reel of the game, a game lock at the time of CZ rebirth (see FIG. 273C) is generated, and on the sub side, a resurrection effect is performed during the game lock period. Note that, in the resurrection effect, in the CZ battle, an effect is performed in which the ally character is resurrected from defeat and wins the battle.

  Next, the main CPU 101 performs the CZ victory processing described in FIG. 285 (S2203). Then, after the processing of S2203, the main CPU 101 ends the CZ end lottery result processing, and also ends the processing at the start during CZ (see FIGS. 283 and 284).

  Here, returning to the process of S2201 again, if the determination of S2201 is NO, the main CPU 101 determines whether or not the lottery result of the CZ end lottery is “end” (S2204). In S2204, when the main CPU 101 determines that the lottery result of the CZ end lottery is not “end” (if S2204 is NO), the main CPU 101 performs the process of S2208 described later.

  On the other hand, in S2204, when the main CPU 101 determines that the lottery result of the CZ end lottery is “end” (YES in S2204), that is, when the gaming state is the CZ defeat waiting state, the main CPU 101 It is determined whether or not the CZ enemy character is the CZ enemy character C (S2205).

  In S2205, when the main CPU 101 determines that the CZ enemy character is not the CZ enemy character C (NO in S2205), the main CPU 101 performs the process of S2208 described later. On the other hand, in S2205, when the main CPU 101 determines that the CZ enemy character is the CZ enemy character C (YES in S2205), the main CPU 101 performs an ART set number lottery process (S2206). In this process, the main CPU 101 refers to the ART set number random determination table (see FIG. 243) and performs the ART set number random determination. Next, the main CPU 101 sets the lottery result (any of “0” to “4”) of the ART set number lottery to the ART set B number (S2207).

  After the process of S2207, or when S2204 or S2205 is NO, the main CPU 101 performs a CZ continuation process (S2208). The details of the CZ continuation process will be described later with reference to FIG. 287 described later. Then, after the processing of S2208, the main CPU 101 ends the CZ end lottery result processing, and also ends the processing during CZ start (see FIGS. 283 and 284).

[CZ continuation processing]
Next, with reference to FIG. 287, the CZ continuation process performed in S2175 during the CZ start process (see FIGS. 283 and 284) or S2208 during the CZ end lottery result process (see FIG. 286) will be described. I do. FIG. 287 is a flowchart illustrating the procedure of the CZ continuation process.

  First, the main CPU 101 determines whether or not the payout state is the ART state (S2211). In S2211, when the main CPU 101 determines that the payout state is not the ART state (if S2211 is NO), the main CPU 101 ends the CZ continuation processing and the CZ start processing (FIG. 283 and FIG. 283). 284) or CZ end lottery result processing (see FIG. 286).

  On the other hand, in S2211, when the main CPU 101 determines that the payout state is the ART state (when S2211 is determined to be YES), the main CPU 101 performs an ART general lottery process (S2212). The details of the ART total lottery process will be described later with reference to FIGS. 288 and 289 described later. Then, after the processing of S2212, the main CPU 101 ends the CZ continuation processing, and also ends the CZ start processing (see FIGS. 283 and 284) or the CZ end lottery result processing (see FIG. 286).

[ART Total Lottery Processing]
Next, with reference to FIGS. 288 and 289, the ART total lottery process performed in S2134 during the BB start process (see FIG. 282) or the S2212 in the CZ continuation process (see FIG. 287) will be described. . FIGS. 288 and 289 are flowcharts showing the procedure of the ART total lottery process.

  First, the main CPU 101 obtains a payout lottery flag C (S2221). Next, the main CPU 101 determines whether or not the payout state is the battle B state (S2222). In this process, the main CPU 101 determines whether or not the payout state is the battle B state based on the on / off state of the battle B flag stored in the payout state flag storage area (see FIG. 265A). It is determined whether or not.

  When the main CPU 101 determines in S2222 that the payout state is not the battle B state (NO in S2222), the main CPU 101 performs HP recovery / weapon random determination processing (S2223). In this processing, the main CPU 101 refers to the HP recovery / weapon lottery table (see FIG. 250), and performs the HP recovery / weapon lottery lottery associated with the combination of the lottery trigger (game situation) and the payout lottery flag C. HP recovery / weapon random determination is performed based on the index number (see FIG. 251). Then, after the processing of S2223, the main CPU 101 performs the processing of S2232 described later.

  On the other hand, in S2222, when the main CPU 101 determines that the payout state is the battle B state (if S2222 is YES), the main CPU 101 determines whether the main game state is the state between the BB flags. It is determined (S2224). In S2224, when the main CPU 101 determines that the main gaming state is not the state between the BB flags (if S2224 is NO), the main CPU 101 performs the processing of S2226 described later.

  On the other hand, in S2224, when the main CPU 101 determines that the main gaming state is the state between the BB flags (if S2224 is YES), the main CPU 101 wins the role related to the payout lottery flag C “should lip”. It is determined whether or not it has been performed (S2225). In S2225, when the main CPU 101 determines that the winning combination related to the payout lottery flag C “should rip” has been won (if S2225 is determined to be YES), the main CPU 101 performs the process of S2229 described later.

  On the other hand, in S2225, when the main CPU 101 determines that the winning combination relating to the payout lottery flag C “should not be ripped” has not been won (when S2225 is NO), or when S2224 is NO, the main CPU 101 Then, it is determined whether or not a winning combination relating to the payout lottery flag C “bell” has been won (S2226). In S2226, when the main CPU 101 determines that the winning combination relating to the payout lottery flag C “Bell” has not been won (if S2226 is NO), the main CPU 101 performs the process of S2230 described later.

  On the other hand, in S2226, when the main CPU 101 determines that the combination related to the payout lottery flag C “Bell” has been won (if S2226 is YES), the main CPU 101 adds “1” to the value of the bell counter. (S2227). Note that the bell counter is a counter for counting the number of consecutive winnings of the hand related to the payout lottery flag C “bell” during the game period in the battle B state, and is provided in the main RAM 103.

  Next, the main CPU 101 determines whether or not the value of the bell counter is “2” (S2228). In S2228, when the main CPU 101 determines that the value of the bell counter is not “2” (if S2228 is NO), the main CPU 101 performs the process of S2230 described later.

  On the other hand, in S2228, when the main CPU 101 determines that the value of the bell counter is “2” (when S2228 is YES) or when S2225 is YES, the main CPU 101 sets the payout lottery flag C Is set to "weak" (S2229). That is, in the present embodiment, not only the case where the hand related to the payout lottery flag C “Bell” is won twice consecutively during the game period in the state of the battle B, but also the state of Also, in the case of a game in which a winning combination lottery flag C of "was a lip" is won, the payout lottery flag C is rewritten to "weak".

  After the processing of S2229, or in the case of NO determination in S2226 or S2228, the main CPU 101 determines the lottery index number of the reward lottery associated with the combination of the enemy character type, the payout lottery flag C, and the set value (FIGS. 253A to 253C). (See S2230). Next, the main CPU 101 refers to the reward lottery table (see FIG. 252) and performs a reward lottery process based on the lottery index number acquired in S2230 (S2231).

  After the processing of S2223 or S2231, the main CPU 101 determines whether or not the lottery result is any one of “HP recovery 1” to “HP recovery 5” (S2322).

  In S2232, when the main CPU 101 determines that the lottery result is one of “HP recovery 1” to “HP recovery 5” (YES in S2232), the main CPU 101 performs the HP recovery amount lottery process. (S2233). In this process, the main CPU 101 refers to the HP recovery amount lottery table (see FIG. 254) and performs the HP recovery amount random determination based on the lottery results (“HP recovery 1” to “HP recovery 5”). Next, the main CPU 101 adds the lottery result (HP recovery amount) to the ally HP (S2234). Then, after the process of S2234, the main CPU 101 ends the ART total lottery process, and also ends the BB start process (see FIG. 282) or the CZ continuation process (see FIG. 287).

  On the other hand, in S2232, when the main CPU 101 determines that the lottery result is not “HP recovery 1” to “HP recovery 5” (NO in S2232), the main CPU 101 determines whether the lottery result is “weapon”. It is determined whether or not it is (S2235).

  In S2235, when the main CPU 101 determines that the lottery result is “weapon” (if S2235 is YES), the main CPU 101 performs a weapon number lottery process (S2236). In this process, the main CPU 101 refers to the weapon number random determination table (see FIG. 256) and performs the weapon number random determination. Next, the main CPU 101 adds the lottery result (the number of weapons) to the value of the weapon counter (S2237). The weapon counter is a counter for counting the number of usable weapons in the game during the battle B, and is provided in the main RAM 103. In the present embodiment, the upper limit of the value of the weapon counter is set to “255”. Then, after the process of S2237, the main CPU 101 ends the ART total lottery process and also ends the BB start process (see FIG. 282) or the CZ continuation process (see FIG. 287).

  On the other hand, in S2235, when the main CPU 101 determines that the lottery result is not “weapon” (NO in S2235), the main CPU 101 determines whether the lottery result is “ART set A” (S2235). S2238).

  In S2238, when the main CPU 101 determines that the lottery result is “ART set A” (if S2238 is YES), the main CPU 101 adds “1” to the ART set A number (S2239). In the present embodiment, the upper limit of the number of ART sets A is “255”. Then, after the process of S2239, the main CPU 101 ends the ART total lottery process and also ends the BB start process (see FIG. 282) or the CZ continuation process (see FIG. 287).

  On the other hand, in S2238, when the main CPU 101 determines that the lottery result is not “ART set A” (if S2238 is NO), the main CPU 101 ends the ART total lottery process and starts during BB ( The processing at the time of CZ continuation (see FIG. 287) is also ended.

[Start processing during ART]
Next, with reference to FIGS. 290 and 291, a description will be given of the processing at the start during ART performed in S2110 during the lottery processing at the time of lever ON (see FIG. 280). 290 and 291 are flowcharts showing the procedure of the processing at the time of starting during ART.

  First, the main CPU 101 determines whether or not the payout state is the SZ state (S2241). In this process, the main CPU 101 determines whether or not the payout state is the SZ state based on the ON / OFF state of the SZ state flag stored in the payout state flag storage area (see FIG. 265A). Is determined.

  In S2241, when the main CPU 101 determines that the payout state is in the SZ state (when S2241 is YES), the main CPU 101 performs the processing of S2246 described later.

  On the other hand, in S2241, when the main CPU 101 determines that the payout state is not in the SZ state (when S2241 is NO), the main CPU 101 performs a CZ point acquisition process (S2242). In this process, the main CPU 101 mainly performs a process of updating the required CZ points. The details of the CZ point acquisition processing will be described later with reference to FIG. 292 described later. Next, the main CPU 101 determines whether or not the main game state is a state between the BB flags (S2243).

  In S2243, when the main CPU 101 determines that the main game state is not the state between the BB flags (if S2243 is NO), the main CPU 101 performs the process of S2246 described later. On the other hand, in S2243, when the main CPU 101 determines that the main game state is the state between the BB flags (if S2243 is YES), the main CPU 101 determines whether the special mode is set (S2244). ).

  In S2244, when the main CPU 101 determines that the special mode is not set (if S2244 is NO), the main CPU 101 performs the process of S2246 described later. On the other hand, in S2244, when the main CPU 101 determines that the special mode is set (S2244 is YES), the main CPU 101 adds 1 to the value of the special mode weapon counter (S2245). In this embodiment, the upper limit of the value of the special mode weapon counter is set to “255”.

  After the processing of S2245, if S2241 is determined as YES, or if S2243 or S2244 is determined as NO, the main CPU 101 performs the ART general lottery processing described with reference to FIGS. 288 and 289 (S2246). Next, the main CPU 101 determines whether or not the RT state is the RT3 state (S2247). In this processing, the main CPU 101 determines whether the RT state (main gaming state) is the RT3 state based on the on / off state of the RT3 flag stored in the gaming state flag storage area (see FIG. 264A). Is determined.

  In S2247, when the main CPU 101 determines that the RT state is not the RT3 state (if S2247 is NO), the main CPU 101 ends the processing during the start during the ART and also performs the lottery processing when the lever is on (see FIG. 280). finish.

  On the other hand, in S2247, when the main CPU 101 determines that the RT state is the RT3 state (if S2247 is YES), the main CPU 101 determines whether or not the ball emergence state is the ART enemy presence state. (S2248). In this processing, the main CPU 101 sets the ball-out state to the ART-enemy-present state based on the on / off state of the enemy-in-progress flag stored in the ball-out state flag storage area (see FIG. 265A). It is determined whether or not.

  In S2248, when the main CPU 101 determines that the payout state is not the enemy presence state in the ART state (if S2248 is NO), the main CPU 101 performs the process of S2251 described later. On the other hand, in S2248, when the main CPU 101 determines that the payout state is the enemy presence state in the ART state (if S2248 is YES), the main CPU 101 determines whether the main game state is the state between the BB flags. Is determined (S2249).

  In S2249, when the main CPU 101 determines that the main game state is the state between the BB flags (when S2249 is YES), the main CPU 101 ends the ART start-time process and the lever-on lottery process (FIG. 280).

  On the other hand, in S2249, when the main CPU 101 determines that the main gaming state is not the state between the BB flags (NO in S2249), the main CPU 101 performs a battle B transition process (S2250). The details of the battle B transfer process will be described later with reference to FIGS. 294 and 295 described later. Then, after the processing of S2250, the main CPU 101 ends the ART start-time processing and also ends the lever-on lottery processing (see FIG. 280).

  Here, returning to the process of S2248 again, if S2248 is NO, the main CPU 101 determines whether or not the payout state is in the battle B state (S2251). In S2251, when the main CPU 101 determines that the payout state is not the battle B state (NO in S2251), the main CPU 101 performs the processing of S2258 described later. On the other hand, in S2251, when the main CPU 101 determines that the payout state is the battle B state (if S2251 is YES), the main CPU 101 determines whether or not the result of the reward lottery is “losing”. It is determined (S2252).

  In S2252, when the main CPU 101 determines that the result of the reward lottery is “losing” (YES in S2252), the main CPU 101 performs the processing of S2254 described later. On the other hand, in S2252, when the main CPU 101 determines that the result of the reward lottery is not “losing” (NO in S2252), the main CPU 101 sets the battle B win flag to an on state (S2253).

  After the processing of S2253 or when the determination of S2252 is YES, the main CPU 101 determines whether or not the main gaming state is the state between the BB flags (S2254).

  In S2254, when the main CPU 101 determines that the main game state is the state between the BB flags (if S2254 is YES), the main CPU 101 performs the processing of S2260 described later. On the other hand, in S2254, when the main CPU 101 determines that the main gaming state is not the state between the BB flags (NO in S2254), the main CPU 101 determines whether or not the value of the game number counter is “0”. It is determined (S2255).

  In S2255, when the main CPU 101 determines that the value of the game number counter is not “0” (NO in S2255), the main CPU 101 ends the processing during the start during ART and performs the lottery processing during the lever-on (FIG. 280). On the other hand, in S2255, when the main CPU 101 determines that the value of the game number counter is “0” (if S2255 is YES), the main CPU 101 determines whether or not the battle B win flag is on. It is determined (S2256).

  In S2256, when the main CPU 101 determines that the battle B win flag is on (in the case of YES determination in S2256), the main CPU 101 terminates the processing during the start during ART and performs the lottery processing when the lever is on (FIG. 280). End). On the other hand, in S2256, when the main CPU 101 determines that the battle B win flag is not in the ON state (if S2256 is NO), the main CPU 101 performs battle B damage reflection processing (S2257). The details of the battle B damage reflection process will be described later with reference to FIGS. 296 and 297 described later. Then, after the processing of S2257, the processing during the start during ART is finished, and the lottery processing at the time of lever on (see FIG. 280) also ends.

  Here, returning to the process of S2251 again, if the determination of S2251 is NO, the main CPU 101 determines whether or not the payout state is the enemy-free state during ART (S2258). In this process, the main CPU 101 sets the ball-out state to the ART-free enemy state based on the on / off state of the enemy-absence-in-progress flag stored in the ball-out state flag storage area (see FIG. 265A). It is determined whether or not.

  In S2258, when the main CPU 101 determines that the ball-out state is not the enemy-free state during the ART (NO in S2258), the main CPU 101 terminates the processing during the start during the ART and performs the lottery processing during the lever-on (see FIG. 280). On the other hand, in S2258, when the main CPU 101 determines that the payout state is the enemy-free state during the ART (if S2258 is YES), the main CPU 101 determines whether or not the CZ required point is “0”. It is determined (S2259).

  In S2259, when the main CPU 101 determines that the CZ required point is not “0” (if S2259 is NO), the main CPU 101 ends the ART start process and the lever ON lottery process (see FIG. 280). ) Also ends.

  On the other hand, in S2259, when the main CPU 101 determines that the CZ required point is “0” (when S2259 is YES), or when S2254 is YES, the main CPU 101 sets the game number counter to “0”. Is set (S2260). Then, after the process of S2260, the main CPU 101 ends the ART start process and the lever ON lottery process (see FIG. 280).

[CZ point acquisition processing]
Next, with reference to FIG. 292, a description will be given of the CZ point acquisition processing performed in S2242 during the processing during ART start (see FIGS. 290 and 291). FIG. 292 is a flowchart illustrating the procedure of the CZ point acquisition process.

  First, the main CPU 101 performs a CZ point lottery process (S2271). In this process, the main CPU 101 refers to the CZ point lottery table (see FIG. 261) and performs the CZ point lottery based on the payout lottery flag A. Next, the main CPU 101 determines whether or not the current CZ required point is “0” (S2272).

  In S2272, when the main CPU 101 determines that the current CZ required point is “0” (if S2272 is YES), the main CPU 101 ends the CZ point acquisition processing, and starts the processing during ART. The process moves to S2243 of (see FIGS. 290 and 291). On the other hand, in S2272, when the main CPU 101 determines that the current CZ required point is not “0” (if S2272 is NO), the main CPU 101 determines the lottery result of the CZ point random determination from the CZ required point (CZ point). Is subtracted (S2273).

  Next, the main CPU 101 determines whether or not the CZ required point after the subtraction is equal to or less than “0” (S2274).

  In S2274, when the main CPU 101 determines that the CZ required point after the subtraction is not “0” or less (NO in S2274), the main CPU 101 ends the CZ point acquisition processing and starts the processing during ART. It moves to S2243 of the processing (see FIGS. 290 and 291). On the other hand, in S2274, when the main CPU 101 determines that the CZ required point after the subtraction is equal to or less than “0” (if S2274 is YES), the main CPU 101 is in the ART-free state in the ball-out state. It is determined whether or not this is the case (S2275).

  In S2275, when the main CPU 101 determines that the ball-out state is not the enemy-free state during the ART (if S2275 is NO), the main CPU 101 ends the CZ point acquisition processing and starts the processing during the ART ( The process moves to S2243 in FIGS. 290 and 291). On the other hand, in S2275, when the main CPU 101 determines that the payout state is the enemy-free state in the ART state (if S2275 is YES), the main CPU 101 sets the current value of the game number counter to the input parameter. (S2276). The input parameters are used in a later-described safe zone game number saving process.

  Next, the main CPU 101 performs a safe zone game number saving process (S2277). In this process, a process of storing the number of safe zone games in the backup area is performed. The details of the safe zone game number saving process will be described later with reference to FIG. 293 described later. Then, after the processing of S2277, the main CPU 101 ends the CZ point acquisition processing, and moves the processing to S2243 of the processing during the start during ART (see FIGS. 290 and 291).

[Safety zone game number saving process]
Next, with reference to FIG. 293, a description will be given of the safe zone game number saving process performed in S2277 during the CZ point acquisition process (see FIG. 292). FIG. 293 is a flowchart showing the procedure of the safe zone game number saving process.

  First, the main CPU 101 clears bit 7 of the input parameter (S2281). Next, the main CPU 101 adds the input parameter to the value stored in the safe zone backup area, and stores the added value as the number of safe zone games in the safe zone backup area (S2282).

  Next, the main CPU 101 sets the value of the safety zone backup area as an output parameter (S2283). Then, after the processing of S2283, the main CPU 101 ends the safe zone game number saving processing and also ends the CZ point acquisition processing (see FIG. 292).

[Battle B shift processing]
Next, with reference to FIG. 294 and FIG. 295, a description will be given of the battle B transition processing performed in S2250 in the processing during the start during ART (see FIG. 290 and FIG. 291). 294 and FIG. 295 are flowcharts showing the procedure of the battle B transition processing.

  First, the main CPU 101 performs a battle B lottery process (S2291). In this process, the main CPU 101 refers to the battle B lottery table (see FIG. 248) and performs the battle B lottery based on the payout lottery flag B. Next, the main CPU 101 determines whether or not the lottery result of the battle B lottery is “avoidance” (S2292).

  In S2292, when the main CPU 101 determines that the lottery result of the battle B lottery is “avoidance” (if S2292 is YES), the main CPU 101 sets a battle B avoidance flag to an on state (S2293). Then, after the processing of S2293, the main CPU 101 ends the battle B transition processing, and also ends the during-ART processing (see FIGS. 290 and 291).

  On the other hand, in S2292, when the main CPU 101 determines that the lottery result of the battle B lottery is not “avoid” (NO in S2292), the main CPU 101 determines that the lottery result of the battle B lottery is “special mode”. It is determined whether or not this is the case (S2294). In S2294, when the main CPU 101 determines that the lottery result of the battle B lottery is not the “special mode” (if S2294 is NO), the main CPU 101 performs the process of S2300 described later.

  On the other hand, in S2294, when the main CPU 101 determines that the lottery result of the battle B lottery is “special mode” (if S2294 is YES), the main CPU 101 sets the special mode flag to the ON state (S2295). ). The special mode flag is a flag for determining whether or not the special mode is activated in the ART state, and is provided in the main RAM 103.

  Next, the main CPU 101 performs a special mode content lottery process (S2296). In this process, the main CPU 101 refers to the special mode content lottery table (see FIG. 249), performs special mode content lottery, and determines the type of special mode (special mode level) and the number of weapons. Next, the main CPU 101 adds the random number result (any of “4” to “7”) of the number of weapons to the special mode weapon counter (S2297).

  Next, the main CPU 101 determines whether or not the lottery result of the special mode level is larger than the current special mode level (S2298). The “special mode level” here is “0” in the non-special mode, “1” in “special mode A”, and “2” in “special mode S”. Therefore, for example, in the special mode content lottery, if “special mode S” is selected as the special mode and the current mode is “special mode A”, the determination in S2298 is YES.

  In S2298, when the main CPU 101 determines that the special mode level lottery result is not higher than the current special mode level (NO in S2298), the main CPU 101 performs the process of S2300 described later. On the other hand, in S2298, when the main CPU 101 determines that the lottery result of the special mode level is larger than the current special mode level (if S2298 is YES), the main CPU 101 determines the lottery result (special mode level) as the current lottery result. The special mode level is set (S2299).

  After the processing of S2299, or when S2294 or S2298 is NO, the main CPU 101 sets the battle B win flag to an off state (S2300). Next, the main CPU 101 clears the bell counter (S2301).

  Next, the main CPU 101 determines whether or not the special mode level is larger than “0” (S2302).

  In S2302, when the main CPU 101 determines that the special mode level is not larger than “0” (in the case of NO determination in S2302), the main CPU 101 performs the process of S2310 described later. On the other hand, in S2302, when the main CPU 101 determines that the special mode level is larger than “0” (if S2302 is YES), the main CPU 101 determines whether the value of the weapon counter is “0”. (S2303).

  In S2303, when the main CPU 101 determines that the value of the weapon counter is not “0” (if S2303 is NO), the main CPU 101 performs the process of S2310 described later. On the other hand, in S2303, when the main CPU 101 determines that the value of the weapon counter is “0” (if S2303 is YES), the main CPU 101 sets “0” to the special mode level (S2304).

  After the processing of S2304, the main CPU 101 sets “0” to the CZ required point (S2305). Next, the main CPU 101 sets the special mode flag to the off state (S2306).

  Next, the main CPU 101 sets the CZ winning flag to the ON state (S2307). The CZ winning flag is a flag for determining whether or not the payout state has changed from the state during the ART during the enemy presence state to the state during the special mode to the state during the ART during CZ, and is provided in the main RAM 103. When the CZ winning flag is on, the CZ level is set to “3” in the ART during CZ state after the transition, as described later. In this case, since “continue” is always determined in the CZ end lottery, the battle is always won in the CZ state, and the payout state shifts from the ART in CZ state to the SZ in state.

  Next, the main CPU 101 sets the CZ enemy character A to the CZ enemy character (S2308). Next, the main CPU 101 sets the state during ART to the state during CZ as the payout state (S2309). Specifically, the main CPU 101 sets both the ART flag and the CZ flag to the ON state, and sets the other payout management flags to the OFF state. With this process, the CZ game is started as an interrupt process in the ART state. Then, after the processing of S2309, the main CPU 101 ends the battle B transition processing, and also ends the during-ART start processing (see FIGS. 290 and 291).

  Here, returning to the processing of S2302 and S2303 again, if the determination of S2302 or S2303 is NO, the main CPU 101 sets the state of the battle B to the payout state (S2310). Specifically, the main CPU 101 sets both the ART flag and the battle B flag to the ON state, and sets the other payout management flags to the OFF state. Next, the main CPU 101 sets “2” to the game number counter (S2311). Then, after the process of S2311, the main CPU 101 ends the battle B transition process and also ends the ART start process (see FIGS. 290 and 291).

[Battle B damage reflection processing]
Next, with reference to FIGS. 296 and 297, a description will be given of the battle B damage reflection processing performed in S2257 in the processing during the start during ART (see FIGS. 290 and 291). 296 and 297 are flowcharts showing the procedure of the battle B damage reflection processing.

  First, the main CPU 101 determines whether or not the special mode is operating (S2321).

  In S2321, when the main CPU 101 determines that the special mode is being operated (YES in S2321), the main CPU 101 decrements the value of the special mode weapon counter by 1 (S2322). Next, the main CPU 101 adds the HP recovery value at the time of weapon consumption (see FIG. 258) set for each ART enemy character to the friendly HP (S2323). Then, after the process of S2323, the main CPU 101 ends the battle B damage reflection process and also ends the ART start process (see FIGS. 290 and 291).

  On the other hand, when the main CPU 101 determines in S2321 that the special mode is not operating (NO in S2321), the main CPU 101 determines whether the value of the weapon counter is greater than “0” (S2324). .

  In S2324, when the main CPU 101 determines that the value of the weapon counter is greater than “0” (if S2324 is YES), the main CPU 101 subtracts 1 from the value of the weapon counter (S2325). Next, the main CPU 101 adds the weapon recovery HP consumption value (see FIG. 258) set for each ART enemy character to the friendly HP (S2326). Then, after the process of S2326, the main CPU 101 ends the battle B damage reflection process, and also ends the ART start process (see FIGS. 290 and 291).

  On the other hand, in S2324, when the main CPU 101 determines that the value of the weapon counter is not larger than “0” (if S2324 is NO), the main CPU 101 performs battle B damage random determination processing (S2327). In this process, the main CPU 101 refers to the battle B damage random determination table (see FIG. 257) and performs battle B damage random determination based on the type of the ART enemy character (ART enemy characters A to G).

  Next, the main CPU 101 determines whether or not the determined damage point (lottery result) is “0” (S2328). In S2328, when the main CPU 101 determines that the determined damage point is “0” (if S2328 is YES), the main CPU 101 ends the battle B damage reflection processing and starts the processing during ART. (See FIGS. 290 and 291).

  On the other hand, in S2328, when the main CPU 101 determines that the determined damage point is not “0” (if S2328 is NO), the main CPU 101 adds “1” to the value of the consecutive loss counter (S2329). . Note that the consecutive loss counter is a counter for counting the number of consecutive defeats of the ally character in the battle B state, and is provided in the main RAM 103. Next, the main CPU 101 sets the damage flag to the ON state (S2330).

  Next, the main CPU 101 subtracts a damage point from the ally HP (S2331). Next, the main CPU 101 determines whether or not the value of the friend HP after the subtraction is larger than “0” (S2332).

  In S2332, when the main CPU 101 determines that the value of the ally HP after the subtraction is larger than “0” (if S2332 is YES), the main CPU 101 ends the battle B damage reflection process and starts during the ART. The time processing (see FIGS. 290 and 291) also ends. On the other hand, in S2332, when the main CPU 101 determines that the value of the friend HP after the subtraction is not larger than “0” (if S2332 is NO), the main CPU 101 sets “0” to the friend HP ( S2333).

  Next, the main CPU 101 determines whether or not the CZ required point is “0” (S2334).

  In S2334, when the main CPU 101 determines that the CZ required point is “0” (if S2334 is YES), the main CPU 101 performs the process of S2336 described later. On the other hand, in S2334, when the main CPU 101 determines that the CZ required point is not “0” (NO in S2334), the main CPU 101 determines whether the value of the ally HP before being damaged is “10” or more. It is determined whether or not it is (S2335).

  In S2335, when the main CPU 101 determines that the value of the ally HP before receiving the damage is “10” or more (when S2335 is YES), or when S2334 is YES, the main CPU 101 “1” is added to HP (S2336). Then, after the process of S2336, the main CPU 101 ends the battle B damage reflection process, and also ends the ART start-time process (see FIGS. 290 and 291).

  On the other hand, in S2335, when the main CPU 101 determines that the value of the ally HP before receiving the damage is not “10” or more (if S2335 is NO), the main CPU 101 sets the ART end waiting flag to the ON state. It is set (S2337). Then, after the process of S2337, the main CPU 101 ends the battle B damage reflection process and also ends the ART start-time process (see FIGS. 290 and 291).

[Processing during normal start]
Next, with reference to FIG. 298, the normal start process performed in S2111 during the lever-on lottery process (see FIG. 280) will be described. FIG. 298 is a flowchart showing the procedure of the normal start process.

  First, the main CPU 101 sets high-precision lottery parameters (S2331). The high-precision lottery parameter set here is a lottery index number for CZ lottery 1 (see FIGS. 225A and 225B) that is associated with a combination of a set value, a high-precision (CZ lottery mode), and a payout lottery flag C. ). Next, the main CPU 101 determines whether or not the CZ lottery mode is “high accuracy” (S2342).

  In S2342, when the main CPU 101 determines that the CZ lottery mode is “high accuracy” (if S2342 is YES), the main CPU 101 performs the processing of S2344 described later. On the other hand, in S2342, when the main CPU 101 determines that the CZ lottery mode is not “high accuracy” (if S2342 is NO), the main CPU 101 sets a low accuracy lottery parameter (S2343). The low-probability lottery parameter set here is a lottery index number for CZ lottery 1 (see FIGS. 225A and 225B) which is associated with a combination of a set value, a low probabilities (CZ lottery mode), and a payout lottery flag C. ).

  After the processing in S2343 or in the case of YES determination in S2342, the main CPU 101 performs the CZ lottery 1 processing (S2344). In this process, the main CPU 101 refers to the CZ lottery 1 table (see FIG. 224) and performs the CZ lottery 1 based on the set lottery index number (lottery parameter).

  Next, the main CPU 101 determines whether or not the CZ lottery 1 has been won (S2345). In S2345, when the main CPU 101 determines that the CZ lottery 1 has not been won (if S2345 is NO), the main CPU 101 performs the processing of S2348 described later.

  On the other hand, in S2345, when the main CPU 101 determines that the CZ lottery 1 has been won (if S2345 is YES), the main CPU 101 performs a CZ enemy character lottery process (S2346). In this process, the main CPU 101 refers to the CZ enemy character random determination table (see FIG. 234) and performs the CZ enemy character random determination based on the cycle management mode. Next, the main CPU 101 sets the lottery result of the CZ enemy character lottery to the CZ enemy character (S2347).

  After the processing in S2347 or in the case where the determination in S2345 is NO, the main CPU 101 performs the normal medium ART lottery processing (S2348). In this process, the main CPU 101 performs various ART random determinations during a normal game. Note that details of the normal medium ART lottery process will be described later with reference to FIG. 299 described later. After the process of S2348, the main CPU 101 ends the normal start process and the lever ON lottery process (see FIG. 280).

[Normal Medium ART Lottery Processing]
Next, with reference to FIG. 299, a description will be given of the normal ART random determination process performed in S2348 during the normal start process (refer to FIG. 298). FIG. 299 is a flowchart illustrating the procedure of the normal medium ART lottery process.

  First, the main CPU 101 determines whether or not “BB2” or “BB3” has been won (S2361).

  In S2361, when the main CPU 101 determines that “BB2” or “BB3” has not been won (if S2361 is NO), the main CPU 101 performs the processing of S2371 described later. On the other hand, in S2361, when the main CPU 101 determines that “BB2” or “BB3” has been won (if S2361 is YES), the main CPU 101 determines whether or not the winning small combination is “losing”. It is determined (S2362).

  In S2362, when the main CPU 101 determines that the winning small combination is not “losing” (if S2362 is NO), the main CPU 101 performs the processing of S2366 described later. On the other hand, in S2362, when the main CPU 101 determines that the winning small combination is “losing” (YES in S2362), the main CPU 101 performs a premium ART lottery process (S2363). In this process, the main CPU 101 refers to the episode BB / premium ART random determination table (see FIG. 232) and performs the premium ART random determination.

  Next, the main CPU 101 determines whether or not the premium ART lottery has been won (S2364).

  In S2364, when the main CPU 101 determines that the premium ART lottery has been won (YES in S2364), the main CPU 101 sets the premium flag to the ON state (S2365). Then, after the processing of S2365, the main CPU 101 performs the processing of S2373 described later.

  On the other hand, in S2364, when the main CPU 101 determines that the premium ART lottery has not been won (NO in S2364) or when S2362 is NO, the main CPU 101 performs an episode BB lottery process (S2366). ). In this process, the main CPU 101 refers to the episode BB / premium ART random determination table (see FIG. 232) and performs the episode BB random determination based on the random number of the episode BB random determination associated with the P point.

  Next, the main CPU 101 determines whether or not the episode BB lottery has been won (S2367).

  When the main CPU 101 determines in S267 that the lottery of the episode BB has been won (YES in S2367), the main CPU 101 sets the episode flag to the ON state (S2368). The episode flag is a flag indicating whether the episode BB is activated or not, and is provided in the main RAM 103.

  After the processing in S2368, the main CPU 101 determines whether or not the P point is larger than “250” (S2369).

  In S2369, when the main CPU 101 determines that the P point is not larger than “250” (if S2369 is NO), the main CPU 101 performs the processing of S2373 described later. On the other hand, in S2369, when the main CPU 101 determines that the P point is larger than “250” (if S2369 is YES), the main CPU 101 subtracts “250” from the P point and sets the subtraction result to the P point. It is set (S2370). Then, after the processing of S2370, the main CPU 101 performs the processing of S2373 described later.

  Here, returning to the processing of S2361 and S267 again, if the determination of S2361 or S2367 is NO, the main CPU 101 performs the ART direct hit lottery processing (S2371). In this process, the main CPU 101 refers to the ART direct hit lottery table (see FIG. 231) and performs the ART direct hit lottery based on the set value (any of settings 1 to 6).

  Next, the main CPU 101 determines whether or not the ART direct hit has been won (S2372). In S2372, when the main CPU 101 determines that the ART direct hit lottery has not been won (NO in S2372), the main CPU 101 ends the normal lottery process and starts the normal lottery process (FIG. 298) also ends.

  On the other hand, in S2372, when the main CPU 101 determines that the ART direct hit has been won (if S2372 is YES), after the processing of S2365 or S2370, or when S2369 is NO, the main CPU 101 executes ART The precursor flag is set to the ON state (S2373).

  Next, the main CPU 101 performs an ART set number lottery process (S2374). In this process, the main CPU 101 refers to the ART set number random determination table (see FIG. 243) and performs the ART set number random determination. Next, the main CPU 101 sets the lottery result of the ART set number lottery to the ART set B number (S2375). Then, after the process of S2375, the main CPU 101 ends the normal lottery process during normal operation and also ends the normal start lottery process (see FIG. 298).

[RT state control processing]
Next, the RT state control process performed in S2056 in the main flow (see FIG. 277) will be described with reference to FIG. FIG. 300 is a flowchart showing the procedure of the RT state control process.

  First, the main CPU 101 refers to the RT transition table (see FIG. 186), and checks RT state transition conditions (RT state end conditions and activation conditions) that can be satisfied in the current (transfer source) RT state (S2381). ).

  Next, the main CPU 101 determines whether or not the condition for shifting to the RT state is satisfied (S2382). In S2382, when the main CPU 101 determines that the transition condition of the RT state is not satisfied (if S2382 is NO), the main CPU 101 ends the RT state control processing, and proceeds to the main flow (see FIG. 277). )).

  On the other hand, in S2382, when the main CPU 101 determines that the transition condition of the RT state is satisfied (if S2382 is YES), the main CPU 101 refers to the RT transition table (see FIG. 186), and executes the transition condition. , The RT state flag of the transfer destination is set to a predetermined bit of the game state flag storage area (see FIG. 264A), and the game state flag storage area is updated (S2383). Then, after the processing of S2383, the main CPU 101 ends the RT state control processing, and moves the processing to S2057 of the main flow (see FIG. 277).

[Effect rendering at the end of the game]
Next, with reference to FIG. 301, the game end effect lottery process performed in S2058 in the main flow (see FIG. 277) will be described. FIG. 301 is a flowchart showing the procedure of the game effect lottery process at the end of the game.

  First, the main CPU 101 determines whether or not the main game state is a state between BB flags (S2391). In S2391, when the main CPU 101 determines that the main game state is the state between the BB flags (if S2391 is determined to be YES), the main CPU 101 ends the game end effect lottery process and proceeds to the main flow (FIG. 277)).

  On the other hand, in S2391, when the main CPU 101 determines that the main game state is not the state between the BB flags (if S2391 is NO), the main CPU 101 determines whether or not the payout state is the normal state ( S2392). In this process, the main CPU 101 determines whether or not the payout state is the normal state based on the on / off state of the normal medium flag stored in the payout state flag storage area (see FIG. 265A). Determine.

  In S2392, when the main CPU 101 determines that the payout state is the normal state (if S2392 is determined to be YES), the main CPU 101 performs a normal medium game end effect lottery process (S2393). The details of the normal game end-of-game effect lottery process will be described later with reference to FIGS. 302 and 303 described later. Then, after the processing of S2393, the main CPU 101 ends the game end effect lottery processing, and moves the processing to S2059 of the main flow (see FIG. 277).

  On the other hand, in S2392, when the main CPU 101 determines that the payout state is not the normal state (if S2392 is NO), the main CPU 101 determines whether the payout state is the CZ state (S2394). ).

  In S2394, when the main CPU 101 determines that the payout state is in the CZ state (if S2394 is YES), the main CPU 101 performs an effect lottery process at the end of the CZ game (S2395). Note that details of the CZ mid-game end effect lottery process will be described later with reference to FIGS. 310 and 311 described below. Then, after the processing of S2395, the main CPU 101 ends the game end lottery processing at the end of the game, and moves the processing to S2059 of the main flow (see FIG. 277).

  On the other hand, in S2394, when the main CPU 101 determines that the payout state is not in the CZ state (NO in S2394), the main CPU 101 performs an at-game end lottery process in ART (S2396). In addition, the details of the effect lottery process at the end of the game during the ART will be described later with reference to FIGS. 314 to 316 described later. Then, after the process of S2396, the main CPU 101 ends the game end effect lottery process, and moves the process to S2059 of the main flow (see FIG. 277).

[Regular lottery process at the end of normal game]
Next, with reference to FIG. 302 and FIG. 303, the normal game end effect lottery process performed in S2393 during the game end effect lottery process (see FIG. 301) will be described. FIG. 302 and FIG. 303 are flowcharts showing the procedure of the normal game end-of-production effect lottery process.

  First, the main CPU 101 determines whether or not the BB operation is being performed (S2401).

  In S2401, when the main CPU 101 determines that the BB is operating (if S2401 is YES), the main CPU 101 determines whether the BB1 is operating (S2402). In S2402, when the main CPU 101 determines that the BB1 is not in operation (NO in S2402), the main CPU 101 ends the normal game end-of-game lottery process and the game end-of-game lottery process (FIG. 301). End).

  On the other hand, in S2402, when the main CPU 101 determines that the BB1 is being operated (YES in S2402), the main CPU 101 performs the BB1 mid-game end effect lottery process (S2403). The details of the BB1 middle game end effect lottery process will be described later with reference to FIG. 304 described later. Then, after the processing of S2403, the main CPU 101 ends the normal game end-of-game effect lottery process and also ends the game-end effect lottery process (see FIG. 301).

  Here, returning to the process of S2401 again, in S2401, when the main CPU 101 determines that the BB operation is not being performed (NO in S2401), the main CPU 101 determines whether or not the ART transition is determined. (S2404).

  In S2404, when the main CPU 101 determines that the ART transition has been determined (YES in S2404), the main CPU 101 performs an ART initial setting process (S2405). The details of the ART initial setting process will be described later with reference to FIG. 305 described later. Then, after the processing of S2405, the main CPU 101 ends the normal game end-of-game effect lottery process and also ends the game-end effect lottery process (see FIG. 301).

  On the other hand, in S2404, when the main CPU 101 determines that the ART transition has not been determined (NO in S2404), the main CPU 101 determines whether or not it is a CZ winning game (S2406).

  In S2406, when the main CPU 101 determines that the game is a CZ winning game (S2406 is YES), the main CPU 101 performs a cycle management mode shift lottery (CZ winning) process (S2407). In this process, the main CPU 101 refers to the cycle management mode transition lottery table (see FIG. 227), and determines the lottery index number of the cycle management mode transition lottery (FIG. 228)), a lottery for transition to the cycle management mode is performed. Next, the main CPU 101 sets the lottery result of the cycle management mode shift lottery (shift destination cycle management mode) to the cycle management mode (S2408).

  After the processing in S2408, the main CPU 101 sets the payout state to the CZ in-state (S2409). Specifically, the main CPU 101 sets the normal flag and the CZ flag to the ON state, and sets the other payout management flags to the OFF state. Next, the main CPU 101 sets the number of CZ games (15 games) in a game number counter (S2410).

  After the process in S2410, the main CPU 101 performs a CZ level setting process (S2411). The details of the CZ level setting process will be described later with reference to FIG. Next, the main CPU 101 sets an initial value (see FIG. 235) to the enemy HP of the CZ enemy character (S2412). Then, after the process of S2412, the main CPU 101 ends the normal game end-of-game effect lottery process and also ends the game-end effect lottery process (see FIG. 301).

  Here, returning to the process of S2406 again, in S2406, when the main CPU 101 determines that the game is not a CZ winning game (if S2406 is NO), the main CPU 101 determines whether the game is a BB winning game. (S2413).

  In S2413, when the main CPU 101 determines that the game is a BB winning game (if S2413 is YES), the main CPU 101 performs a cycle management mode shift lottery (at the time of BB winning) (S2414). In this process, the main CPU 101 refers to the cycle management mode transition lottery table (see FIG. 227), and determines the lottery index number (see FIG. 227) of the cycle management mode transition lottery associated with the combination of the lottery opportunity and the current cycle management mode. 228)), a lottery for transition to the cycle management mode is performed. Next, the main CPU 101 sets the lottery result of the cycle management mode shift lottery (shift destination cycle management mode) to the cycle management mode (S2415). Then, after the process of S2415, the main CPU 101 ends the normal game end-of-game effect lottery process and also ends the game-end effect lottery process (see FIG. 301).

  On the other hand, when the main CPU 101 determines in S2413 that the game is not a BB winning game (S2413 is NO), the main CPU 101 determines whether or not the value of the game number counter is “0” (S2416). . In S2416, when the main CPU 101 determines that the value of the game number counter is not “0” (if S2416 is NO), the main CPU 101 ends the normal medium game end effect lottery process and the game end. The effect lottery process (see FIG. 301) also ends.

  On the other hand, in S2416, when the main CPU 101 determines that the value of the game number counter is “0” (if S2416 is YES), the main CPU 101 executes the CZ lottery mode lottery process (when the CZ lottery cycle has elapsed). This is performed (S2417). The details of the CZ lottery mode lottery process (when the CZ lottery cycle has elapsed) will be described later with reference to FIG. Next, the main CPU 101 sets the lottery result of the CZ lottery mode lottery to the CZ lottery mode (S2418).

  Next, the main CPU 101 performs a cycle management mode shift lottery (at the time of BB winning) processing (S2419). In this process, the main CPU 101 refers to the cycle management mode transition lottery table (see FIG. 227), and determines the lottery index number (see FIG. 227) of the cycle management mode transition lottery associated with the combination of the lottery opportunity and the current cycle management mode. 228)), a lottery for transition to the cycle management mode is performed. Next, the main CPU 101 sets the lottery result of the cycle management mode shift lottery (shift destination cycle management mode) to the cycle management mode (S2420).

  Next, the main CPU 101 performs a P-point lottery process (S2421). In this process, the main CPU 101 performs P-point random determination with reference to the P-point random determination table (see FIG. 229). Next, the main CPU 101 adds the lottery result of the P point lottery to the P point (S2422). Then, after the processing of S2422, the main CPU 101 ends the normal game end-of-game effect lottery process, and also ends the game-end effect lottery process (see FIG. 301).

[Drawing process at the end of game during BB1]
Next, with reference to FIG. 304, the BB1 middle game end effect lottery process performed in S2403 during the normal middle game end effect lottery process (see FIGS. 302 and 303) will be described. Note that FIG. 304 is a flowchart showing the procedure of the BB1 middle game end effect lottery process.

  First, the main CPU 101 determines whether or not the first stop operation has been performed on the right reel 3R (S2431). This determination process is performed based on information stored in each bit of the pressing order storage area (see FIG. 34).

  In S2431, when the main CPU 101 determines that the first stop operation has not been performed on the right reel 3R (NO in S2431), the main CPU 101 performs the process of S2436 described later. On the other hand, in S2431, when the main CPU 101 determines that the first stop operation has been performed on the right reel 3R (if S2431 is YES), the main CPU 101 determines whether the left reel 3L has been stopped for the third time. Is determined (S2432). This determination process is performed based on information stored in each bit of the pressing order storage area (see FIG. 34).

  In S2432, when the main CPU 101 determines that the left reel 3L has not been stopped for the third time (if S2432 is NO), the main CPU 101 performs the processing of S2436 described later. On the other hand, in S2432, when the main CPU 101 determines that the left reel 3L has been stopped for the third time (YES in S2432), the main CPU 101 determines whether the P-point acquisition completed flag is on. (S2433). The P point acquired flag is a flag for determining whether or not the P point candidate value to be added when a specific pushing order is successful in the game in the normal BB1 state is already added to the P point. And is provided in the main RAM 103.

  In S2433, when the main CPU 101 determines that the P point acquisition completed flag is in the ON state (if S2433 is YES), the main CPU 101 performs the process of S2436 described later. On the other hand, in S2433, when the main CPU 101 determines that the P point acquisition completed flag is not in the on state (if S2433 is NO), the main CPU 101 sets the P point acquisition completed flag to the on state (S2434). Next, the main CPU 101 adds the P point candidate value set in S2137 to the P point (S2435).

  After S2435, if S2431 or S2432 is NO, or if S2433 is YES, the main CPU 101 determines whether or not the premium flag is on (S2436). In S2436, when the main CPU 101 determines that the premium flag is not in the ON state (if S2436 is NO), the main CPU 101 ends the BB1 middle game end lottery process, and ends the normal middle game end lottery process. The processing (see FIGS. 302 and 303) also ends.

  On the other hand, in S2436, when the main CPU 101 determines that the premium flag is in the ON state (if S2436 is YES), the main CPU 101 performs an ART initial setting process (S2437). The details of the ART initial setting process will be described later with reference to FIG. 305 described later. Then, after the processing of S2437, the main CPU 101 ends the BB1 middle game end effect lottery process, and also ends the normal middle game end effect lottery process (see FIGS. 302 and 303).

[ART Initial Setting Process]
Next, referring to FIG. 305, the process is performed in S2405 during the normal game end-of-game effect lottery processing (see FIGS. 302 and 303) or in S2437 during the BB1 game-end effect at random lottery process (see FIG. 304). The ART initialization process will be described. FIG. 305 is a flowchart illustrating the procedure of the ART initial setting process.

  First, the main CPU 101 sets “0” to the special mode level (S2441). Next, the main CPU 101 sets “10” as the input parameter (S2442). The value of the input parameter set here is set in the game number counter in the later-described safety zone G number storage processing. That is, in the present embodiment, at the time of the ART first hit, “10” is set as the initial value of the number of safe zone games.

  Next, the main CPU 101 performs a safe zone game number storing process (S2443). In this process, the main CPU 101 performs an initial setting process of various parameters (such as the number of safe zone games) managed in the ART-free state during ART. The details of the safe zone game number storage processing will be described later with reference to FIG. Next, the main CPU 101 sets “Chapter 1” as the ART chapter (S2444).

  Next, the main CPU 101 determines whether or not the ART to be activated is a premium ART (S2445). Specifically, the main CPU 101 determines whether or not the premium flag is on.

  In S2445, when the main CPU 101 determines that the ART to be operated is not the premium ART (NO in S2445), the main CPU 101 performs the process of S2449 described later.

  On the other hand, in S2445, when the main CPU 101 determines that the ART to be operated is the premium ART (YES in S2445), the main CPU 101 sets the premium flag to the off state (S2446). Next, the main CPU 101 adds “1” to the ART set A number (S2247). Next, the main CPU 101 sets “12” to the value of the weapon counter (S2448).

  After the processing of S2448 or when S2445 is NO, the main CPU 101 adds “1” to the value of the weapon counter (S2449). If the ART to be activated is the premium ART, "13" (12 + 1) is set as the initial value of the weapon counter by this processing. Next, the main CPU 101 sets the ART flag to the ON state (S2450).

  Next, the main CPU 101 performs an ART chapter start process (S2451). In this process, the main CPU 101 determines an initial value of a CZ required point (a point for managing the presence or absence of transition to the CZ during ART). Details of the ART chapter start processing will be described later with reference to FIG. 307 described later.

  Next, the main CPU 101 performs an ART enemy character lottery process (S2452). In this process, the main CPU 101 refers to the ART enemy character lottery table (see FIG. 246), and adds the ART enemy character random determination index number (see FIG. 247) associated with the current ART chapter or the special mode type. ART enemy character lottery is performed based on the random number. Next, the main CPU 101 sets the lottery result of the ART enemy character lottery (any of the ART enemy characters A to G) to the ART enemy character (S2453). Then, after the processing of S2453, the main CPU 101 ends the ART initial setting processing and ends the normal middle game end effect lottery processing (see FIGS. 302 and 303) or the BB1 middle game end lottery processing (see FIG. 304). Also ends.

[Safety zone game number storage processing]
Next, with reference to FIG. 306, a description will be given of the safe zone game number storage processing performed in S2443 during the ART initial setting processing (see FIG. 305). FIG. 306 is a flowchart showing the procedure of the safe zone game number storage processing.

  First, the main CPU 101 sets the value of the input parameter as the output parameter (S2461). Next, the main CPU 101 clears the value of the consecutive loss counter (S2462).

  Next, the main CPU 101 sets the output parameter in the game number counter (S2463). Next, the main CPU 101 sets the state in which there is no enemy during the ART in the payout state (S2464). Specifically, the main CPU 101 sets the ART flag and the enemy absence flag to the ON state, and sets the other payout management flags to the OFF state. Then, after the processing of S2464, the main CPU 101 ends the safe zone game number storage processing, and moves the processing to S2444 of the ART initial setting processing (see FIG. 305).

[ART Chapter Start Process]
Next, with reference to FIG. 307, a description will be given of the ART chapter start processing performed in S2451 during the ART initialization processing (see FIG. 305). FIG. 307 is a flowchart showing the procedure of the ART chapter start process.

  First, the main CPU 101 sets “0” to the special mode level (S2471). Next, the main CPU 101 performs a CZ required point lottery process (S2472). In this process, the main CPU 101 refers to the CZ required point lottery table (refer to FIG. 259) and determines the CZ required point random determination index number (refer to FIG. 260) associated with the current ART chapter or CZ battle defeat. Then, the CZ required point lottery is performed.

  Next, the main CPU 101 sets the lottery result of the CZ required point lottery to the P required point (S2473). Then, after the processing of S2473, the main CPU 101 ends the ART chapter start processing, and moves the processing to S2452 of the ART initial setting processing (see FIG. 305).

[CZ level setting processing]
Next, with reference to FIG. 308, a description will be given of the CZ level setting process performed in S2411 during the normal medium game end effect lottery process (see FIGS. 302 and 303). FIG. 308 is a flowchart illustrating the procedure of the CZ level setting process.

  First, the main CPU 101 sets “3” to the CZ level (S2481). Next, the main CPU 101 determines whether or not the CZ winning flag is on (S2482).

  In S2482, when the main CPU 101 determines that the CZ winning flag is on (if S2482 is YES), the main CPU 101 sets the CZ winning flag to off (S2483). After the process of S2483, the main CPU 101 ends the CZ level setting process, and shifts the process to S2412 of the normal game end-of-game effect lottery process (see FIGS. 302 and 303).

  On the other hand, in S2482, when the main CPU 101 determines that the CZ winning flag is not on (in the case of NO determination in S2482), the main CPU 101 determines whether the ART chapter is “Chapter 5” (S2484). ). In S2484, when the main CPU 101 determines that the ART chapter is “chapter 5” (if S2484 is YES), the main CPU 101 ends the CZ level setting process, and ends the normal game end-of-game effect lottery. The process moves to S2412 of the process (see FIGS. 302 and 303).

  On the other hand, in S2484, when the main CPU 101 determines that the ART chapter is not “Chapter 5” (NO in S2484), the main CPU 101 performs a CZ level lottery process (S2485). In this process, the main CPU 101 performs CZ level random determination with reference to the CZ level random determination table (see FIG. 236).

  Next, the main CPU 101 sets the lottery result of the CZ level lottery to the CZ level (S2486). Then, after the processing of S2486, the main CPU 101 ends the CZ level setting processing, and shifts the processing to S2412 of the normal medium game end effect lottery processing (see FIGS. 302 and 303).

[CZ lottery mode lottery processing (at normal transition, when CZ lottery cycle has elapsed)]
Next, with reference to FIG. 309, a description will be given of the CZ lottery mode lottery processing (at the time of transition to the normal state, when the CZ lottery cycle elapses) performed in S2417 during the normal middle game end effect lottery processing (see FIGS. 302 and 303). . FIG. 309 is a flowchart showing the procedure of the CZ lottery mode lottery process (at the time of normal transition, at the time of elapse of the CZ lottery cycle).

  First, the main CPU 101 sets the current cycle management mode (any of modes A to E) as a lottery parameter (S2491). Next, the main CPU 101 performs a CZ lottery mode lottery process (S2492). In this process, the main CPU 101 refers to the CZ lottery mode lottery table (see FIG. 221) and determines the lottery index number of the CZ lottery mode lottery (FIG. 222) associated with the lottery parameter (cycle management mode) set in S2491. ), The CZ lottery mode lottery is performed.

  Next, the main CPU 101 sets the lottery result (low accuracy / high accuracy) of the CZ lottery mode lottery to the CZ lottery mode (S2493). Next, the main CPU 101 adds “1” to the value of the cycle counter (S2494).

  Next, the main CPU 101 determines whether or not the value of the cycle number counter is the ceiling value (“16”) (S2495).

  In S2495, when the main CPU 101 determines that the value of the cycle number counter is the ceiling value (in the case of YES determination in S2495), that is, when the shift to the ART is determined, the main CPU 101 determines the value of the cycle number counter. Clear (set "0") (S2496).

  Next, the main CPU 101 performs an ART set number lottery process (S2497). In this process, the main CPU 101 refers to the ART set number random determination table (see FIG. 243) and performs the ART set number random determination. Next, the main CPU 101 sets the lottery result of the ART set number lottery to the ART set B number (S2498). Then, after the process of S249, the main CPU 101 ends the CZ lottery mode lottery process (at the time of normal transition, when the CZ lottery cycle has elapsed), and ends the process of the normal game end-of-game effect lottery process (see FIGS. 302 and 303). It moves to S2418.

  Here, returning to the process of S2495 again, in S2495, when the main CPU 101 determines that the value of the cycle number counter is not the ceiling value (if S2495 is NO), the main CPU 101 executes the current CZ random determination mode (low). Is set as a lottery parameter (S2499).

  Next, the main CPU 101 performs a CZ random determination mode cycle game random determination process (S2500). In this process, the main CPU 101 refers to the CZ lottery mode cycle game number lottery table (see FIG. 223) and performs the CZ lottery mode cycle game number lottery based on the lottery parameter (CZ lottery mode) set in S2499. .

  Next, the main CPU 101 sets the lottery result of the CZ lottery mode period game number lottery in the game number counter (S2501). Then, after the process of S2501, the main CPU 101 ends the CZ lottery mode lottery process (at the time of normal transition, when the CZ lottery cycle has elapsed), and ends the process of the normal game end effect lottery process (see FIGS. 302 and 303). It moves to S2418.

[Currency production lottery processing at the end of CZ game]
Next, with reference to FIG. 310 and FIG. 311, a description will be given of the CZ game end effect lottery process performed in S2395 during the game end effect lottery process (see FIG. 301). FIG. 310 and FIG. 311 are flowcharts showing the procedure of the effect lottery process at the end of the CZ game.

  First, the main CPU 101 determines whether or not the value of the game number counter is “0” (S2511). In S2511, when the main CPU 101 determines that the value of the number-of-games counter is not “0” (NO in S2511), the main CPU 101 ends the CZ-based game end effect lottery process and ends the game. The effect lottery process (see FIG. 301) also ends.

  On the other hand, in S2511, when the main CPU 101 determines that the value of the game number counter is “0” (if S2511 is YES), the main CPU 101 determines whether or not a CZ battle (battle A or C) is won. It is determined (S2512). When the main CPU 101 determines in step S2512 that the CZ battle has not been won (NO in step S2512), the main CPU 101 performs the process of step S2521 described below.

  On the other hand, in S2512, when the main CPU 101 determines that the CZ battle has been won (if S2512 is YES), the main CPU 101 sets a lock time for CZ end (see FIG. 273B) (S2513). Next, the main CPU 101 determines whether or not the CZ end lock time has elapsed (S2514).

  In S2514, when the main CPU 101 determines that the lock time for CZ termination has not elapsed (if S2514 is NO), the main CPU 101 repeats the processing of S2514. On the other hand, in S2514, when the main CPU 101 determines that the lock time for ending CZ has elapsed (if S2514 is YES), the main CPU 101 determines whether or not the payout state is the ART state ( S2515).

  If the main CPU 101 determines in S2515 that the payout state is not the ART state (NO in S2515), the main CPU 101 performs the ART initial setting process described with reference to FIG. 305 (S2516). Then, after the process of S2516, the main CPU 101 ends the CZ game end effect lottery process and the game end effect lottery process (see FIG. 301).

  On the other hand, in S2515, when the main CPU 101 determines that the payout state is the ART state (when S2515 is YES), the main CPU 101 sets the SZ state to the payout state (S2517). Specifically, the main CPU 101 sets the during-ART flag and the during-SZ flag to the ON state, and sets the other payout management flags to the OFF state. Next, the main CPU 101 determines whether or not the ART chapter is “Chapter 9” or later (S2518).

  In S2518, when the main CPU 101 determines that the ART chapter is after “Chapter 9” (if S2518 is YES), the main CPU 101 sets “30” to the value of the game number counter (S2519). Then, after the processing of S2519, the main CPU 101 ends the CZ game end effect lottery process and the game end effect lottery process (see FIG. 301).

  On the other hand, in S2518, when the main CPU 101 determines that the ART chapter is not after “Chapter 9” (NO in S2518), the main CPU 101 sets “20” to the value of the game number counter (S2520). . Then, after the processing of S2520, the main CPU 101 ends the CZ-based game end effect lottery process and also ends the game end effect lottery process (see FIG. 301).

  Here, returning to the process of S2512 again, if the determination in S2512 is NO, the main CPU 101 determines whether or not the CZ has ended (S2521).

  In S2521, when the main CPU 101 determines that the CZ is not over (when S2521 is NO), the main CPU 101 ends the CZ-in-game end-of-game lottery process and the game-end-stage effect lottery process (see FIG. 301). ) Also ends. On the other hand, when the main CPU 101 determines in S2521 that the CZ has been completed (YES in S2521), the main CPU 101 determines whether or not the payout state is the ART state (S2522).

  In S2522, when the main CPU 101 determines that the payout state is the ART state (if S2522 is YES), the main CPU 101 performs the ART chapter start processing described in FIG. 307 (S2523). Next, the main CPU 101 sets “5” to the input parameter (S2524). Note that the value of the input parameter set here is set in the game number counter in the safety zone game number lottery post-processing described later. That is, in the present embodiment, when the CZ during ART ends, “5” is set as the initial value of the number of safe zone games.

  Next, the main CPU 101 performs post-lottery processing for the number of safe zone games (S2525). In this processing, the main CPU 101 performs various parameter setting processing at the time of transition to the ART-free state. The details of the post-safety zone game lottery process will be described later with reference to FIG. 312 described later. Then, after the processing of S2525, the main CPU 101 ends the CZ game end effect lottery process, and also ends the game end effect lottery process (see FIG. 301).

  Here, returning to the process of S2522 again, and in S2522, when the main CPU 101 determines that the payout state is not the ART state (in the case of NO determination in S2522), the main CPU 101 clears the CZ enemy character information ( S2526). Next, the main CPU 101 determines whether or not the CZ enemy character is the CZ enemy character C (S2527).

  In S2527, when the main CPU 101 determines that the CZ enemy character is the CZ enemy character C (if S2527 is YES), the main CPU 101 performs the ART initial setting process described with reference to FIG. 305 (S2528). In other words, in the normal middle CZ state, even if the CZ battle defeat is determined, if the CZ enemy character that has competed is the CZ enemy character C, the ART transition is determined. Then, after the processing of S2528, the main CPU 101 ends the CZ game end-time effect lottery process and also ends the game-end effect lottery process (see FIG. 301).

  On the other hand, in S2527, when the main CPU 101 determines that the CZ enemy character is not the CZ enemy character C (if S2527 is NO), the main CPU 101 performs a normal time transition process (S2529). In this process, the main CPU 101 performs various parameter setting processes at the time of transition to the normal state. The details of the normal transition process will be described later with reference to FIG. Then, after the processing of S2529, the main CPU 101 ends the CZ-based game end effect lottery process and also ends the game end effect lottery process (see FIG. 301).

[Safety zone game number lottery post-processing]
Next, with reference to FIG. 312, a description will be given of the post-lottery-safe-zone-game-number-lottery process performed in S2525 during the CZ-in-game end-of-game effect lottery process (see FIGS. 310 and 311). FIG. 312 is a flowchart showing the procedure of the post-lottery-safe-zone game lottery process.

  First, the main CPU 101 sets an input parameter (“5” or “10” in the present embodiment) to “result” (S2531). Next, the main CPU 101 determines whether or not the special mode is set (S2532).

  In S2532, when the main CPU 101 determines that the special mode is not set (if S2532 is NO), the main CPU 101 performs the process of S2534 described later. On the other hand, in S2532, when the main CPU 101 determines that the special mode is set (if S2532 is YES), the main CPU 101 sets “1” in “Result” (S2533). By this processing, the value ("5" or "10") of the "result" set in S2531 is rewritten (overwritten) to "1".

  After the processing in S2533 or in the case of NO determination in S2532, the main CPU 101 sets “result” as an input parameter (S2534). Next, the main CPU 101 performs the safe zone game number saving process described in FIG. 293 (S2535). Next, the main CPU 101 clears the safety zone backup area (S2536).

  Next, the main CPU 101 clears the value of the consecutive loss counter (S2537). Next, the main CPU 101 sets the value of the output parameter set in S2535 in the game number counter (S2538). In the present embodiment, “1”, “5”, or “10” is set as the output parameter according to the gaming state.

  Next, the main CPU 101 sets the state in which there is no enemy during the ART as the ball-out state (S2539). Specifically, the main CPU 101 sets the ART flag and the enemy absence flag to the ON state, and sets the other payout management flags to the OFF state. Then, after the processing of S2539, the main CPU 101 ends the safety zone game number lottery post-processing, and also ends the CZ game end-of-game effect lottery processing (see FIGS. 310 and 311).

[Normal transition process]
Next, with reference to FIG. 313, a description will be given of the normal shift processing performed in S2529 during the CZ game end effect lottery processing (see FIGS. 310 and 311). FIG. 313 is a flowchart illustrating the procedure of the normal transition process.

  First, the main CPU 101 clears the ART chapter (S2541). Next, the main CPU 101 sets the normal state to the payout state (S2542). Specifically, the main CPU 101 sets the normal flag to the on state, and sets the other payout management flags to the off state. Next, the main CPU 101 performs the CZ lottery mode lottery process (at the time of normal transition) described in FIG. 309 (S2543).

  Next, the main CPU 101 performs a cycle management mode shift lottery (at the time of CZ lottery mode lottery) processing (S2544). In this process, the main CPU 101 refers to the cycle management mode transition lottery table (see FIG. 227), and determines the lottery index number (see FIG. 227) of the cycle management mode transition lottery associated with the combination of the lottery opportunity and the current cycle management mode. 228)), a lottery for transition to the cycle management mode is performed. Next, the main CPU 101 sets the lottery result of the cycle management mode shift lottery (shift destination cycle management mode) to the cycle management mode (S2545).

  Next, the main CPU 101 performs a P-point lottery process (S2546). In this process, the main CPU 101 performs P-point random determination with reference to the P-point random determination table (see FIG. 229). Next, the main CPU 101 adds the lottery result of the P point lottery to the P point (S2547). Then, after the processing of S2547, the main CPU 101 ends the normal shift processing, and also ends the CZ game end effect lottery processing (see FIGS. 310 and 311).

[At-game effect end lottery processing during ART]
Next, with reference to FIGS. 314 to 316, the ART game end effect lottery process performed in S2396 during the game end effect lottery process (see FIG. 301) will be described. FIG. 314 to FIG. 316 are flowcharts showing the procedure of the effect lottery process at the time of the end of the game during ART.

  First, the main CPU 101 determines whether or not the BB operation is being performed (S2551).

  In S2551, when the main CPU 101 determines that the BB operation is being performed (YES in S2551), the main CPU 101 ends the at-game end-effect lottery processing during the ART and ends the at-game effect lottery processing (FIG. 301) also ends. On the other hand, when the main CPU 101 determines in S2551 that the BB operation is not being performed (NO in S2551), the main CPU 101 determines whether or not the value of the game number counter is “0” (S2552). .

  In S2552, when the main CPU 101 determines that the value of the number-of-games counter is not “0” (NO in S2552), the main CPU 101 terminates the at-game-during-end-of-art-effect lottery process and ends the game. The effect lottery process (see FIG. 301) also ends. On the other hand, in S2552, when the main CPU 101 determines that the value of the game number counter is “0” (if S2552 is YES), the main CPU 101 determines whether or not the payout state is the SZ state. It is determined (S2553).

  In S2553, when the main CPU 101 determines that the payout state is the SZ state (S2553 is YES), the main CPU 101 adds “1” to the value of the ART chapter (S2554). Next, the main CPU 101 sets “10” as the input parameter (S2555). Next, the main CPU 101 performs the post-lottery-for-safe-zone-games lottery process described with reference to FIG. 312 (S2556). Next, the main CPU 101 performs the ART chapter start processing described in FIG. 307 (S2557). Then, after the processing of S2557, the main CPU 101 ends the at-game end-of-game effect lottery process and ends the at-game-end effect lottery process (see FIG. 301).

  On the other hand, in S2553, when the main CPU 101 determines that the payout state is not the SZ state (when S2553 is NO), the main CPU 101 determines whether or not the payout state shifts to the CZ state. (S2558).

  In S2558, when the main CPU 101 determines that the payout state shifts to the CZ state (when S2558 is YES), the main CPU 101 sets the ART during CZ state to the gaming state (S2559). Specifically, the main CPU 101 sets the ART flag and the CZ flag to the ON state, and sets other payout management flags to the OFF state.

  Next, the main CPU 101 sets the number of CZ games (15 games) in the number-of-games counter (S2560). Next, the main CPU 101 performs the CZ level setting processing described with reference to FIG. 308 (S2561). Next, the main CPU 101 sets the enemy HP (initial value) of the CZ enemy character (S2562). Then, after the processing of S2562, the main CPU 101 ends the at-game end-of-game effect lottery process and also ends the at-game-end effect lottery process (see FIG. 301).

  On the other hand, in S2558, when the main CPU 101 determines that the payout state does not shift to the CZ in-state (NO in S2558), the main CPU 101 determines whether or not the battle B avoidance flag is on. (S2563).

  In S2563, when the main CPU 101 determines that the battle B avoidance flag is on (when S2563 is YES), the main CPU 101 sets the battle B avoidance flag to off (S2564). Next, the main CPU 101 performs a safety zone game number setting process (S2565). The details of the safety zone game number setting process will be described later with reference to FIG. 317 described later. Next, the main CPU 101 performs a CZ required point confirmation process (S2566). The details of the CZ required point confirmation processing will be described later with reference to FIG. Then, after the processing of S2566, the main CPU 101 ends the at-game end-game effect lottery process and also ends the at-game effect lottery process (see FIG. 301).

  On the other hand, in S2563, when the main CPU 101 determines that the battle B avoidance flag is not in the ON state (if S2563 is NO), the main CPU 101 determines whether or not the payout state is in the battle B state. (S2567). When the main CPU 101 determines in S2567 that the payout state is not the battle B state (NO in S2567), the main CPU 101 performs the processing of S2576 described later.

  On the other hand, in S2567, when the main CPU 101 determines that the payout state is in the battle B state (if S2567 is YES), the main CPU 101 performs an ART enemy character lottery process (S2568). In this process, the main CPU 101 refers to the ART enemy character lottery table (see FIG. 246), and adds the ART enemy character random determination index number (see FIG. 247) associated with the current ART chapter or the special mode type. ART enemy character lottery is performed based on the random number. Next, the main CPU 101 sets the lottery result of the ART enemy character lottery (any of the ART enemy characters A to G) to the ART enemy character (S2569).

  Next, the main CPU 101 determines whether or not the damage flag is in the on state (battle defeat state) (S2570).

  In S2570, when the main CPU 101 determines that the damage flag is not on (S2570 is NO), the main CPU 101 performs the process of S2573 described later. On the other hand, in S2570, when the main CPU 101 determines that the damage flag is on (S2570 is YES), the main CPU 101 sets the damage flag to off (S2571).

  Next, the main CPU 101 determines whether or not the value of the consecutive loss counter is “1” or “2” (S2572).

  In S2572, when the main CPU 101 determines that the value of the consecutive losing counter is not “1” or “2” (the value of the consecutive losing counter is “3”) (if S2572 is NO), or if S2570 is NO In the case of determination, the main CPU 101 performs a safety zone game number setting process (S2573). The details of the safety zone game number setting process will be described later with reference to FIG. 317 described later. On the other hand, in S2572, when the main CPU 101 determines that the value of the consecutive losing counter is “1” or “2” (in the case of YES determination in S2572), the main CPU 101 sets the ball-out state to the ART enemy presence state. It is set (S2574). More specifically, the main CPU 101 sets the ART flag and the enemy flag to the ON state, and sets the other payout management flags to the OFF state.

  After the processing of S2573 or S2574, the main CPU 101 performs CZ required point confirmation processing (S2575). The details of the CZ request point confirmation process will be described later with reference to FIG. Then, after the processing of S2575, the main CPU 101 ends the at-game end-game effect lottery process and ends the at-game game end lottery process (see FIG. 301).

  Here, returning to the process of S2567 again, if the determination of S2567 is NO, the main CPU 101 determines whether or not the payout state is the enemy-free state during ART (S2576).

  In S2576, when the main CPU 101 determines that the ball-out state is the state without the enemy during the ART (if S2576 is YES), the main CPU 101 sets the state with the enemy during the ART in the ball-out state (S2577). . More specifically, the main CPU 101 sets the ART flag and the enemy flag to the ON state, and sets the other payout management flags to the OFF state. Next, the main CPU 101 performs a CZ required point confirmation process (S2578). The details of the CZ required point confirmation processing will be described later with reference to FIG. Then, after the processing of S2578, the main CPU 101 ends the at-game end-of-game effect lottery process, and also ends the at-game-end effect lottery process (see FIG. 301).

  On the other hand, in S2576, when the main CPU 101 determines that the payout state is not the enemy-free state in the ART state (NO in S2576), the main CPU 101 sets the ART end wait flag to the off state (S2579). Next, the main CPU 101 sets “50” (initial value) as the friend HP (S2580). Next, the main CPU 101 determines whether or not both the number of ART sets A and the number of ART sets B are “0” (S2581).

  In S2581, when the main CPU 101 determines that both the number of ART sets A and the number of ART sets B are “0” (YES in S2581), the main CPU 101 executes the normal time transition processing described with reference to FIG. Performed (S2582). Then, after the processing of S2582, the main CPU 101 ends the at-game end-effect rendering lottery process, and also ends the at-game effect rendering random determination process (see FIG. 301).

  On the other hand, in S2581, when the main CPU 101 determines that both the number of ART sets A and the number of ART sets B are not “0” (if S2581 is NO), the main CPU 101 determines that the number of ART sets A is “0”. It is determined whether or not there is (S2583).

  In S2583, when the main CPU 101 determines that the number of ART sets A is not “0” (NO in S2583), the main CPU 101 subtracts 1 from the value of the number of ART sets A (S2584). Next, the main CPU 101 sets “30” as the friend HP (S2585). Then, after the processing of S2585, the main CPU 101 performs the processing of S2588 described later.

  On the other hand, in S2583, when the main CPU 101 determines that the number of ART sets A is “0” (if S2583 is YES), the main CPU 101 subtracts 1 from the value of the number of ART sets B (S2586). Next, the main CPU 101 adds “1” to the value of the weapon counter (S2587).

  After the processing of S2585 or S2587, ART enemy character lottery processing is performed (S2588). In this process, the main CPU 101 refers to the ART enemy character lottery table (see FIG. 246), and adds the ART enemy character random determination index number (see FIG. 247) associated with the current ART chapter or the special mode type. ART enemy character lottery is performed based on the random number. Next, the main CPU 101 sets the lottery result of the ART enemy character lottery (any of the ART enemy characters A to G) to the ART enemy character (S2589).

  Next, the main CPU 101 adds “10” to the input parameter (S2590). Note that the value of the input parameter set here is set in the game number counter in the safety zone game number lottery post-processing described later. That is, in the present embodiment, when the stock ART is released, “10” is set as the initial value of the number of safe zone games.

  Next, the main CPU 101 performs the post-lottery-of-safety-zone games lottery process described with reference to FIG. 312 (S2591). Then, after the process of S2591, the main CPU 101 ends the at-game end-game effect lottery process and ends the at-game game end lottery process (see FIG. 301).

[Safe zone game number setting process]
Next, with reference to FIG. 317, a description will be given of the number-of-safe-zones-games setting process performed in S2565 or S2573 during the effect lottery process at the end of the ART game (see FIGS. 314 to 316). FIG. 317 is a flowchart showing the procedure of the safety zone game number setting process.

  First, the main CPU 101 sets a lottery parameter according to the ART chapter and the set value (S2601). Next, the main CPU 101 performs a safety zone game number lottery process (S2602). In this process, the main CPU 101 refers to the safety zone game number lottery table (see FIG. 244), and determines the lottery index number of the safety zone game number random determination (see FIG. 245) associated with the lottery parameter (ART chapter and setting value). ), A lottery for the number of safe zone games is performed. Next, the main CPU 101 sets the lottery result (any of 5, 10, 20, 30, 50, and 100 games) of the number of safe zone games to the number of safe zone games (S2603).

  Next, the main CPU 101 determines whether or not the special mode is set (S2604).

  In S2604, when the main CPU 101 determines that the special mode is not set (if S2604 is NO), the main CPU 101 performs the process of S2606 described later. On the other hand, in S2604, when the main CPU 101 determines that the special mode is set (if S2604 is YES), the main CPU 101 sets “1” to the lottery result (S2605).

  After the processing of S2605 or when the determination of S2604 is NO, the main CPU 101 sets the lottery result as an input parameter (S2606). Next, the main CPU 101 performs the safe zone game number saving process described in FIG. 293 (S2607). Next, the main CPU 101 clears the safety zone backup area (S2608).

  Next, the main CPU 101 clears the value of the consecutive loss counter (S2609). Next, the main CPU 101 sets the value of the output parameter set in S2607 in the game number counter (S2610).

  Next, the main CPU 101 sets the state in which there is no enemy during the ART in the payout state (S2611). Specifically, the main CPU 101 sets the ART flag and the enemy absence flag to the ON state, and sets the other payout management flags to the OFF state. Then, after the process of S2611, the main CPU 101 ends the safety zone game number setting process, and proceeds to S2566 or S2575 of the effect lottery process at the time of the end of the game during ART (see FIGS. 314 to 316).

[CZ required point confirmation processing]
Next, with reference to FIG. 318, the CZ request point confirmation process performed in S2566, S2575, or S2578 during the at-game end-of-game effect lottery process (see FIGS. 314 to 316) will be described. FIG. 318 is a flowchart showing the procedure of CZ required point confirmation processing.

  First, the main CPU 101 determines whether or not the required CZ point is “0” (S2621). In S2621, when the main CPU 101 determines that the CZ required point is not “0” (if S2621 is NO), the main CPU 101 terminates the CZ required point confirmation process and ends the game during the ART during the game. (See FIGS. 314 to 316).

  On the other hand, in S2621, when the main CPU 101 determines that the CZ required point is “0” (if S2621 is YES), the main CPU 101 determines whether or not the special mode is set (S2622). ).

  In S2622, when the main CPU 101 determines that the special mode is set (if S2622 is determined to be YES), the main CPU 101 ends the CZ required point confirmation process, and performs the at-game end lottery process during the ART. 314 to 316) also ends. On the other hand, in S2622, when the main CPU 101 determines that the special mode has not been set (NO in S2622), the main CPU 101 stores the value of the input parameter (“1”, “5” or “5”) in the game number counter. "10") is set (S2623).

  Next, the main CPU 101 performs the safe zone game number saving process described in FIG. 293 (S2624). Next, the main CPU 101 sets the CZ enemy character A to the CZ enemy character (S2625).

  Next, the main CPU 101 sets the state during ART to the state during CZ as the payout state (S2626). Specifically, the main CPU 101 sets the ART flag and the CZ flag to the ON state, and sets other payout management flags to the OFF state. Then, after the processing of S2626, the main CPU 101 ends the CZ required point confirmation processing, and also ends the at-game during-game effect lottery processing (see FIGS. 314 to 316).

[Bonus end check process]
Next, the bonus end check processing performed in S2059 in the main flow (see FIG. 277) will be described with reference to FIG. FIG. 319 is a flowchart showing the procedure of bonus end check processing.

  First, the main CPU 101 refers to the gaming state flag storage area (see FIG. 264A) and determines whether or not the bonus (BB) is operating (S2631). When the main CPU 101 determines in S2631 that the bonus is not in operation (NO in S2631), the main CPU 101 ends the bonus end check processing, and shifts the processing to S2060 of the main flow (see FIG. 277). .

  On the other hand, in S2631, when the main CPU 101 determines that the bonus is being operated (YES in S2631), the main CPU 101 determines whether the value of the bonus end number counter is less than “0”. (S2632).

  In S2632, when the main CPU 101 determines that the value of the bonus end number counter is not less than “0” (NO in S2632), the main CPU 101 performs the process of S2637 described later.

  On the other hand, in S2632, when the main CPU 101 determines that the value of the bonus end number counter is less than “0” (if S2632 is YES), the main CPU 101 performs a bonus end command generation and storage process (S2633). . In this process, the main CPU 101 generates bonus end command data to be transmitted to the sub control circuit 200, and stores the command data in a communication data storage area (see FIG. 75B) provided in the main RAM 103. The bonus end command stored in the communication data storage area is transmitted from the main control circuit 90 to the sub-control circuit 200 by the communication data transmission processing in the interrupt processing described with reference to FIG. 158, as in the first embodiment. Is done. The bonus end command includes information indicating that the bonus game has ended.

  Next, the main CPU 101 performs a bonus end process (S2634). In this processing, the main CPU 1010 clears the bonus end number counter and sets the gaming state flag relating to the bonus (BB) in operation to the off state. If the value of the bonus end number counter of BB1 is less than “0”, it means that the payout of medals has exceeded a predetermined number (72) during the BB1 state, and the bonus end number of BB2 or BB3 If the value of the counter is less than “0”, it means that the payout of medals has exceeded a specific number (297) during the state BB2 or BB3.

  Next, the main CPU 101 performs a bonus lottery effect lottery process (S2635). In this process, the main CPU 101 performs various lotteries relating to the payout performance at the end of the bonus. The details of the bonus end effect lottery process will be described later with reference to FIG.

  Next, the main CPU 101 performs an initialization process at the end of the bonus (S2636). Then, after the processing of S2636, the main CPU 101 ends the bonus end check processing, and moves the processing to S2060 of the main flow (see FIG. 277).

  Here, returning to the process of S2632 again, if the determination of S2632 is NO, the main CPU 101 updates the respective values of the winning number counter and the number-of-games counter (S2637). The value of the possible prize counter is decremented by "1" when a small role (a role with a medal payout) is displayed, and the value of the possible game counter is one game (unit game) regardless of the stop symbol. When digested, "1" is subtracted.

  Next, the main CPU 101 determines whether or not the value of the winning number counter or the number of possible games counter is “0” (S2638). In S2638, when the main CPU 101 determines that the value of the winning number counter or the number of playable times counter is not “0” (if S2638 is NO), the main CPU 101 ends the bonus end check processing. , And moves the process to S2060 of the main flow (see FIG. 277).

  On the other hand, in S2638, when the main CPU 101 determines that the value of the winning number counter or the number of playable times counter is “0” (in the case of YES determination in S2638), the main CPU 101 determines whether the RB ends. The process is performed (S2639). Specifically, the main CPU 101 performs processing such as setting the RB state flag to an off state, and clearing the values of the possible winning number counter and the possible number of games counter. Then, after the processing of S2636, the main CPU 101 ends the bonus end check processing, and moves the processing to S2060 of the main flow (see FIG. 277).

[Bonus end effect lottery process]
Next, the bonus end effect lottery process performed in S2635 during the bonus end check process (see FIG. 319) will be described with reference to FIG. FIG. 320 is a flowchart showing the procedure of the bonus lottery effect lottery process.

  First, the main CPU 101 sets the episode flag to the off state (S2641). Next, the main CPU 101 releases the freeze of the game number counter (S2642). Specifically, the main CPU 101 stores “0” in bit 7 of the game number counter.

  Next, the main CPU 101 determines whether or not the payout state is the ART state (S2643).

  In S2643, when the main CPU 101 determines that the payout state is the ART state (if S2643 is YES), the main CPU 101 determines whether the payout state is the SZ state (S2644). . When the main CPU 101 determines in S2644 that the payout state is not the SZ state (NO in S2644), the main CPU 101 ends the bonus end effect lottery process, and executes the bonus end check process (FIG. 319).

  On the other hand, in S2644, when the main CPU 101 determines that the payout state is the SZ in-progress state (if S2644 is YES), the main CPU 101 stores the value of the game number counter in the safety zone backup area (S2645). ). Next, the main CPU 101 sets “5” as the input parameter (S2646). Next, the main CPU 101 performs the post-lottery-for-safe-zone-games lottery process described with reference to FIG. 312 (S2647). After the processing of S2647, the main CPU 101 ends the bonus lottery effect lottery processing, and moves the processing to S2636 of the bonus end check processing (see FIG. 319).

  Here, returning to the process of S2643 again, in S2643, when the main CPU 101 determines that the payout state is not the ART state (when S2643 is NO), the main CPU 101 determines whether the CZ enemy character is set. It is determined whether or not it is (S2648). In S2648, when the main CPU 101 determines that the CZ enemy character is set (if S2648 is YES), the main CPU 101 sets the normal CZ middle state to the payout state (S2649). Specifically, the main CPU 101 sets the normal flag and the CZ flag to the ON state, and sets the other payout management flags to the OFF state.

  Next, the main CPU 101 sets the number of CZ games (15 games) in the number-of-games counter (S2650). Next, the main CPU 101 performs the CZ level setting processing described with reference to FIG. 308 (S2651). Next, the main CPU 101 sets the enemy HP (initial value) of the CZ enemy character (S2652). After the processing of S2652, the main CPU 101 ends the bonus lottery effect lottery processing, and moves the processing to S2636 of the bonus end check processing (see FIG. 319).

  Here, returning to the process of S2648 again, in S2648, when the main CPU 101 determines that the CZ enemy character is not set (if S2648 is NO), the main CPU 101 changes the normal state to the payout state. It is set (S2653). Specifically, the main CPU 101 sets the normal flag to the on state, and sets the other payout management flags to the off state.

  Next, the main CPU 101 performs a CZ lottery mode lottery process (at the end of the bonus) (S2654). The details of the CZ lottery mode lottery process (at the end of the bonus) will be described later with reference to FIG. 321 described later.

  Next, the main CPU 101 performs a cycle management mode shift lottery (at the time of CZ lottery mode lottery) processing (S2655). In this process, the main CPU 101 refers to the cycle management mode shift lottery table (see FIG. 227) and shifts to the cycle management mode associated with the combination of the lottery trigger (at the time of the CZ lottery mode lottery) and the current cycle management mode. Based on the lottery index number of the lottery (see FIG. 228), the lottery to shift to the cycle management mode is performed. Next, the main CPU 101 sets the lottery result of the cycle management mode shift lottery (shift destination cycle management mode) to the cycle management mode (S2656).

  Next, the main CPU 101 performs a P-point lottery process (S2657). In this process, the main CPU 101 performs P-point random determination with reference to the P-point random determination table (see FIG. 229). Next, the main CPU 101 adds the lottery result of the P point lottery to the P point (S2658). After the processing of S2658, the main CPU 101 ends the bonus lottery effect lottery processing, and moves the processing to S2636 of the bonus end check processing (see FIG. 319).

[CZ lottery mode lottery processing (at the end of bonus)]
Next, with reference to FIG. 321, the CZ lottery mode lottery processing (at the time of bonus end) performed in S2654 during the bonus end effect lottery processing (see FIG. 320) will be described. FIG. 321 is a flowchart showing the procedure of the CZ lottery mode lottery process (at the end of the bonus).

  First, the main CPU 101 determines whether or not the current CZ lottery mode is “low accuracy” (S2661).

  If the main CPU 101 determines in step S2661 that the current CZ lottery mode is not “low accuracy” (NO in step S2661), the main CPU 101 performs the process in step S2664 described below. On the other hand, in S2661, when the main CPU 101 determines that the current CZ lottery mode is “low accuracy” (if S2661 is YES), the main CPU 101 performs a CZ lottery mode lottery process (S2662). In this processing, the main CPU 101 refers to the CZ lottery mode lottery table (see FIG. 221), and based on the CZ lottery index number (see FIG. 222) of the CZ lottery mode lottery associated with the current cycle management mode. Lottery mode Lottery is performed. Next, the main CPU 101 sets the lottery result to the CZ lottery mode (S2663).

  After the process of S2663 or in the case of NO in S2661, the main CPU 101 adds “1” to the value of the cycle counter (S2664). Next, the main CPU 101 determines whether or not the value of the cycle counter after the addition is the ceiling value (“16” in the present embodiment) (S2665).

  In S2665, when the main CPU 101 determines that the value of the cycle counter after addition is the ceiling value (if S2665 is YES), the main CPU 101 clears the value of the cycle counter (S2666). Next, the main CPU 101 performs an ART set number lottery process (S2667). In this process, the main CPU 101 refers to the ART set number random determination table (see FIG. 243) and performs the ART set number random determination. Next, the main CPU 101 sets the lottery result of the ART set number lottery to the ART set B number (S2668). Then, after the processing of S2668, the main CPU 101 ends the CZ lottery mode lottery processing (at the end of the bonus), and moves the processing to S2655 of the effect lottery processing at the time of the bonus end (see FIG. 320).

  On the other hand, in S2665, when the main CPU 101 determines that the value of the cycle counter after addition is not the ceiling value (if S2665 is NO), the main CPU 101 sets the CZ lottery mode to the lottery parameter (S2669). Next, the main CPU 101 performs a CZ random determination mode cycle game random determination process (S2670). In this processing, the main CPU 101 refers to the CZ lottery mode cycle game number lottery table (see FIG. 223) and performs the CZ lottery mode cycle game number lottery based on the lottery parameter (CZ lottery mode) set in S2669. .

  Next, the main CPU 101 sets the lottery result of the CZ lottery mode period game number lottery in the game number counter (S2671). After the process of S2671, the main CPU 101 ends the CZ lottery mode lottery process (at the end of the bonus), and shifts the process to S2655 of the effect lottery process at the time of the bonus end (see FIG. 320).

[Bonus operation check process]
Next, the bonus operation check processing performed in S2060 in the main flow (see FIG. 277) will be described with reference to FIG. FIG. 322 is a flowchart showing the procedure of the bonus operation check process.

  First, the main CPU 101 determines whether or not the bonus (BB) is in operation (S2681). In S2681, when the main CPU 101 determines that the bonus is not in operation (if S2681 is NO), the main CPU 101 performs the processing of S2684 described later.

  On the other hand, in S2681, when the main CPU 101 determines that the bonus is operating (if S2681 is YES), the main CPU 101 determines whether the RB is operating (S2682). In S2682, when the main CPU 101 determines that the RB is operating (if S2682 is determined to be YES), the main CPU 101 ends the bonus operation check processing, and shifts the processing to S2041 of the main flow (see FIG. 277). Move.

  On the other hand, in S2682, when the main CPU 101 determines that the RB is not operating (if S2682 is NO), the main CPU 101 performs the RB operation processing based on the bonus operation table (see FIG. 185). Performed (S2683). In this process, the main CPU 101 refers to the bonus operation time table (see FIG. 185) and appropriately sets the value corresponding to the bonus type in the winning number counter and the number of possible games counter. Then, after the processing of S2683, the main CPU 101 ends the bonus operation check processing, and moves the processing to S2041 of the main flow (see FIG. 277).

  Here, returning to the process of S2681 again, if the determination of S2681 is NO, the main CPU 101 determines whether or not a bonus game has been won (S2684). In the present embodiment, when the symbol combination relating to the BB combination (see FIG. 181) is stopped and displayed on the activated line, the bonus game is won. When the main CPU 101 determines in S2684 that the bonus game has not been won (S2684 is NO), the main CPU 101 performs the processing of S2694 described later.

  On the other hand, in S2684, when the main CPU 101 determines that a bonus game has been won (if S2684 is YES), the main CPU 101 determines whether or not the ART precursor flag is on (S2685).

  When the main CPU 101 determines in step S2685 that the ART precursor flag is not in the ON state (NO in step S2685), the main CPU 101 performs the process of step S2689 described later. On the other hand, when the main CPU 101 determines in step S2685 that the ART precursor flag is in the on state (if S2685 is determined to be YES), the main CPU 101 sets the ART precursor flag to the off state (S2687). Next, the main CPU 101 performs the ART initial setting process described with reference to FIG. 305 (S2688).

  After the processing of S2688 or in the case of NO in S2885, the main CPU 101 clears the value of the carryover combination storage area (S2689). Next, the main CPU 101 performs a bonus operation process (BB operation process) corresponding to the winning bonus game based on the bonus operation table (see FIG. 185) (S2690). In this process, the main CPU 101 refers to the bonus operation time table (see FIG. 185), sets “1” to the corresponding bit in the game state flag storage area (see FIG. 264A), and sets the bonus end number counter. The numerical value is set to a predetermined value (“72” when winning BB1 and “297” when winning BB2 or BB3). Further, in this process, the process at the time of RB operation described in S2683 is also performed.

  Next, the main CPU 101 performs a bonus start command generation and storage process (S2691). In this process, the main CPU 101 generates data of a bonus start command to be transmitted to the sub control circuit 200, and stores the command data in a communication data storage area (see FIG. 75B) provided in the main RAM 103. The bonus start command stored in the communication data storage area is transmitted from the main control circuit 90 to the sub control circuit 200 by the communication data transmission processing in the interrupt processing described with reference to FIG. 158, as in the first embodiment. Is done. The bonus start command includes information indicating that the bonus game has started.

  Next, the main CPU 101 sets a lock time for bonus winning (see FIG. 273A) corresponding to the type of winning BB and the current payout state (S2692). In this process, when the present payout state is the CZ state, “0 sec” is set as the lock time for bonus prize, and the game lock for bonus prize is not generated. Next, the main CPU 101 determines whether or not the lock time for bonus prize has elapsed (S2693).

  In S2693, when the main CPU 101 determines that the lock time for bonus prize has not elapsed (if S2693 is NO), the main CPU 101 repeats the process of S2693. On the other hand, in S2693, when the main CPU 101 determines that the lock time for bonus prize has elapsed (if S2693 is determined to be YES), the main CPU 101 ends the bonus operation check processing and proceeds to the main flow (FIG. 277). Move to S2041).

  Here, returning to the process of S2684 again, if the determination of S2684 is NO, the main CPU 101 determines whether or not the hand associated with the replay (replay) is a winning (S2694). In S2694, when the main CPU 101 determines that the combination relating to the replay is not a winning (S2694 is NO), the main CPU 101 ends the bonus operation check process, and proceeds to the main flow (see FIG. 277). Move to S2041.

  On the other hand, in S2694, when the main CPU 101 determines that the combination relating to the replay is a prize (if S2694 is YES), the main CPU 101 requests automatic insertion of medals (S2695). That is, the main CPU 101 copies the insertion number counter to the automatic insertion number counter. After the processing of S2695, the main CPU 101 ends the bonus operation check processing, and moves the processing to S2041 of the main flow (see FIG. 277).

<Description of operation of sub-control circuit>
Next, the contents of various processes (tasks) executed by the sub CPU 201 of the sub control circuit 200 using a program will be described with reference to FIGS.

[Main board communication task]
First, a main board communication task performed by the sub CPU 201 will be described with reference to FIG. FIG. 323 is a flowchart showing the procedure of the main board communication task.

  First, the sub CPU 201 checks the reception of the command transmitted from the main control circuit 90 (S3001). Next, when receiving the command, the sub CPU 201 extracts the type of the received command (S3002).

  Next, the sub CPU 201 determines whether or not the command type is normal (S3003). In the present embodiment, the command type is associated with one of a plurality of types of codes, and when the game is operating normally, the command type is one of the plurality of types of codes. Therefore, in the process of S3003, if the received command type code is one of a plurality of types of codes, the sub CPU 201 determines that the command type is a normal command type. On the other hand, when the command type code is other than the plural types of codes, the sub CPU 201 determines that some abnormality (including improper behavior) has occurred during the game and determines that the command type is not a normal command type.

  When the sub CPU 201 determines in S3003 that the command type is not a normal command type (NO in S3003), the sub CPU 201 returns the process to S3001, and repeats the processes from S3001.

  On the other hand, when the sub CPU 201 determines in S3003 that the command type is normal (YES in S3003), the sub CPU 201 stores a message in the message queue based on the received command (S3004). . The message queue is a mechanism for exchanging information between processes. Then, after the processing in S3004, the sub CPU 201 returns the processing to S3001, and repeats the processing in S3001 and thereafter.

[Direction registration task]
Next, the effect registration task performed by the sub CPU 201 will be described with reference to FIG. FIG. 324 is a flowchart showing the procedure of the effect registration task.

  First, the sub CPU 201 extracts a message from the message queue (S3011). Next, the sub CPU 201 determines whether or not there is a message in the message queue (S3012). In S3012, when the sub CPU 201 determines that there is no message in the message queue (NO in S3012), the sub CPU 201 performs the process of S3015 described later.

  On the other hand, when the sub CPU 201 determines in S3012 that there is a message in the message queue (YES in S3012), the sub CPU 201 copies game information from the message (S3013). In this processing, for example, various data such as information on the internal winning combination (main lottery flag) specified by the parameter, the type of the reel stopped rotating, the display combination, and the game state flag are stored in the storage area provided in the sub RAM 202. (Not shown).

  Next, the sub CPU 201 performs an effect content determination process (S3014). In this process, the sub CPU 201 determines the effect contents, registers effect data, and the like according to the type of the received command. The details of the effect content determination processing will be described later with reference to FIG. 325 described later.

  Next, the sub CPU 201 registers the animation data (S3015). Next, the sub CPU 201 registers sound data (S3016). Next, the sub CPU 201 registers the lamp data (S3017). Note that these registration processes are performed based on the effect data registered in the effect content determination process in S3014. After the processing in S3017, the sub CPU 201 returns the processing to S3011 and repeats the processing from S3011.

[Direction content decision processing]
Next, with reference to FIG. 325, the effect content determination processing performed in S3014 in the flowchart of the effect registration task (see FIG. 324) will be described. FIG. 325 is a flowchart showing the procedure of the effect content determination process.

  First, the sub CPU 201 determines whether or not it is time to receive an initialization command (S3021).

  In S3021, when the sub CPU 201 determines that it is not the time of receiving the initialization command (when S3021 is NO), the sub CPU 201 performs the process of S3024 described later. On the other hand, when the sub CPU 201 determines in S3021 that the initialization command has been received (YES in S3021), the sub CPU 201 determines whether or not a power interruption for 4 hours or more has occurred (S3022). ). In the present embodiment, the power-off period is counted by a timer (not shown) provided in the sub control circuit 200.

  In S3022, when the sub CPU 201 determines that the power interruption for 4 hours or more has not occurred (NO in S3022), the sub CPU 201 performs the process of S3024 described later. On the other hand, in S3022, when the sub CPU 201 determines that the power interruption for four hours or more has occurred (when S3022 is determined to be YES), the sub CPU 201 sets “2” as the number of cycles after restoration from the power interruption (S3023). ). Then, after the processing of S3023, the sub CPU 201 ends the effect content determination processing, and moves the processing to S3015 of the effect registration task (see FIG. 324).

  In the pachislot 1 of the present embodiment, as described above, when returning from a power cut of four hours or more, in the production, the first game (the number of remaining games at the time of the power cut) in the normal game and the second game in the second cycle A power-return effect such that a normal game is executed in one cycle is performed. The number of cycles after power failure recovery is a parameter for counting the cycle period in which the power-return effect is executed. When the number of cycles after power failure recovery is “1” or “2”, the number of cycles after power recovery is used. An effect is performed.

  Here, returning to the processing of S3021 or S3022 again, if the determination of S3021 or S3022 is NO, the sub CPU 201 determines whether or not the number of cycles after the recovery from power interruption is greater than “0” (S3024).

  In S3024, when the sub CPU 201 determines that the number of cycles after power recovery is larger than “0” (if S3024 is YES), the sub CPU 201 determines a power-return effect according to the received command type. (S3025). Next, the sub CPU 201 subtracts 1 from the number of cycles after the recovery from power interruption (S3026). Then, after the processing in S3026, the sub CPU 201 ends the effect content determination processing, and moves the processing to S3015 of the effect registration task (see FIG. 324).

  On the other hand, in S3024, when the sub CPU 201 determines that the number of cycles after power recovery is not larger than “0” (in the case of NO determination in S3024), the sub CPU 201 performs the normal (power recovery) according to the received command type. The effect content is determined (other than the direct effect) (S3027). Then, after the processing of S3027, the sub CPU 201 ends the effect content determination processing, and moves the processing to S3015 of the effect registration task (see FIG. 324).

<Various effects>
Here, a description will be given of various effects obtained by the various game properties and functions of the pachislo 1 of the present embodiment.

[Effect of Continuous Lottery Function in ART State]
In the pachislot 1 of the present embodiment, as described with reference to FIG. 179, in the general state during the ART, the ball-out state transitions between the no-enemy state during the ART and the state during the battle B, and the game in the state during the battle B is performed. When the ally HP becomes “0” or less, the game period in the ART state ends.

  Further, as described above, during the game period (two games) in the battle B state, a reward lottery is performed for each game, and if “losing” is not determined as a result of the reward lottery for both games, the payout state Returns from the state during battle B to the state without enemy during ART (safe zone). On the other hand, when “losing” is determined as a result of the reward lottery in both games over the game period (two games) in the battle B state, the ally HP is updated (subtracted) and updated (subtracted) If the friend HP of “)” is “1” or more, basically, the payout state returns to the battle B state again via the ART in enemy presence state. Note that over the game period (two games) in the state of the battle B, “loss” is determined as a result of the reward lottery in both games, and if the updated HP (after subtraction) is equal to or less than “0”, The ART state ends.

  In other words, in the pachislot 1 of the present embodiment, during the game period (two games) in the state of the battle B, the continuous lottery of the state of the battle B is performed by reward lottery for each game. If the continuous lottery is won in at least one game in the game period (two games) (when "losing" is not determined in at least one game), the ball-out state changes from the battle B state to the ART state. Return to enemy-free state (safe zone). On the other hand, in the two games in the battle B state, if the continuous lottery is non-winning ("losing" is determined in both games) and if the updated HP (after subtraction) is equal to or greater than "1", the basic condition is satisfied. Specifically, the payout state returns to the battle B state again via the enemy during ART state.

  Further, in the present embodiment, in the game in the battle B state, if a rare combination is won, “losing” is not determined as a result of the reward lottery (see FIGS. 252 and 253). Therefore, if a rare combination is won in the game in the battle B state, the payout state returns from the battle B state to the enemy-free state during ART (safe zone) after the end of the game period in the battle B state. On the other hand, when a role other than the rare role (bell or the like) is won in the state of the battle B, if a result other than “losing” is determined as a result of the reward lottery (if the continuous lottery is won). After the end of the game period in the battle B state, the payout state returns from the battle B state to the ART-free enemy state (safe zone).

  By providing the above-described ART state continuation lottery function, the player can be expected to continue the ART state (notification period), and the interest of the game in the ART state (notification period) can be increased. The decrease can be suppressed.

[Effect of guarantee (ceiling) function when battle B loses consecutively]
In the pachislo 1 of the present embodiment, the transition cycle of the ball-out state changes from the ART-in-enemy state to the battle-in-state in the ART state, and then returns again to the ART-in-enemy state. If the teammate character loses three consecutive battles in battle B: the consecutive loss counter = 3, and if the teammate HP at that time is equal to or greater than "1", the battle state is changed to the battle state. The state is changed from the state during battle B to the state without enemy during ART without shifting from the state during B to the state during enemies during ART.

  By providing such a guarantee (ceiling) function at the time of battle B consecutive loss, the player can be expected to continue the ART state (notification period) and a game in the ART state (notification period). It is possible to suppress a decrease in the interest of the user.

  In the present embodiment, an example has been described in which, when the above-described transition state of the ball-out state is repeated three times in succession, the ball-out state is shifted from the battle B state to the ART-free state in the ART state. However, the present invention is not limited to this. When the transition cycle of the ball-out state described above is continuously repeated a plurality of times other than three times, the ball-out state may be changed from the state during the battle B to the state without enemy during the ART.

[Effect of Reward Function in Battle B State]
In the pachislot 1 of the present embodiment, when the rare combination is won in the game in the battle B state, the transition to the enemy-less state during the ART (safe zone) (continuous lottery winning) is determined and the reward lottery is determined. Thus, for example, rewards (privileges) such as recovery of an allied HP (addition of an allied HP), acquisition of a “weapon” that can set the enemy HP to “0”, and stock of an ART set (“ART set A”) are provided. It may be given to a player (see FIG. 252).

  By providing such a reward function in the battle B state, the player can be expected to continue the ART state (notification period), and the interest of the game in the ART state (notification period) can be increased. The decrease can be suppressed.

  Further, in the present embodiment, in the game in the battle B state, if the role related to “Bell” is won for two consecutive games, the role related to “Bell” is changed to “Weak Cherry” in the second game. , Ie, a rare role. Therefore, in the present embodiment, in a game in the state of the battle B, even if a small role other than the rare role is won for two consecutive games, the transition to the ART in-enemy state (safe zone) (continuous lottery) is also performed. Is determined, and the various rewards (privileges) described above may be given to the player.

  By providing such a winning combination conversion function in the game in the battle B state, even if an event occurs in which the continuous lottery in the ART state becomes non-winning in the game period (two games) in the battle B state. For example, depending on the internal winning combination, there is a possibility that the ball-out state returns from the battle B state to the ART-free enemy state (safety zone) and the ART state continues. Therefore, by providing such a winning combination conversion function in the game in the battle B state, it is possible to further increase the player's expectation of the continuation of the ART state (notification period) and to increase the ART state (notification period). ) Can improve the interest of the game.

[Effects of the battle B avoidance function]
In the pachi-slot 1 of the present embodiment, in the general state during the ART, when the ball-out state transitions to the state during the battle B, the ball-out state changes from the state without the enemy during the ART to the state during the battle B via the state with the enemy during the ART. Transition. Then, when the rare role is won in the game in the ART in enemy presence state, the ball advance state does not shift to the battle B state (avoids battle B) but shifts to the ART in enemy absence state. .

  That is, if the rare role is won at a timing when there is a possibility of shifting to the battle B state (after the end of the safety zone), the ball-out state does not shift to the battle B state, and the ART is not enemies state. Move to Therefore, by providing a ball-out state such as the ART during enemy presence state, even at a timing when there is a possibility of transition to the battle B state, it is possible to eliminate the possibility that the number of friendly HP is reduced. Can be given to a person.

  Therefore, by providing the above-mentioned battle B avoiding function in the ART enemy presence state, the player can be expected to continue the ART state (reporting period) and the ART state (reporting period). Can be suppressed from decreasing the interest in the game.

[Effect of HP display production function in ART state]
In the pachislot 1 of the present embodiment, in the effect performed during the game period in the ART state, when the value of the chapter of the ART chapter (story) increases (as the story progresses), the ally HP and its damage points, and the enemy HP And a function of appropriately increasing the damage point according to the value of the ART chapter during stay (the duration of the ART) and displaying the damage point. For example, an effect of displaying a value obtained by integrating the values of the ART chapter during stay on each of the friendly HP and its damage points, and the enemy HP and its damage points is performed.

  By providing such an HP display effect function, it is possible to express that the ally character is growing in accordance with the progress of the ART chapter (continuation of the ART) in the effect, and the enemy character becomes stronger. Can also be expressed. Therefore, in the present embodiment, the content of the effect can be changed according to the progress (continuation period) of the game during the game period in the ART state, and the interest of the player in the game in the ART state can be further enhanced. it can.

[Effects of production style at bonus winning in CZ state]
As described above, the pachislo 1 of the present embodiment has the effect function of generating a game lock (game lock at the time of bonus prize) at the time of winning a bonus (BB) and notifying that the bonus (BB) has been won. In the present embodiment, as described with reference to FIG. 273A, when a bonus (BB) is won in a ball-out state other than the CZ state, a bonus-locking game lock is generated and the bonus (BB) is won. Perform an effect to inform

  However, when the payout state is the CZ state, the bonus (BB) winning game lock is not generated when the bonus (BB) is won, and an effect (CZ state) that informs that the bonus (BB) has been won. The same notification effect as in the ball-out state other than the above is not performed. When such an effect function is provided, if there is an effect (for example, a battle effect in the CZ state) that is to be prioritized over the bonus prize notification, the effect contents can be effectively expressed, and The interest of the state game can be enhanced.

[Effect of subtracting enemy HP after bonus prize in CZ state]
In the pachislo 1 of the present embodiment, as described above, during the game period in the CZ middle state, the enemy HP of the CZ enemy character is subtracted, and if the enemy HP becomes equal to or less than “0”, the bonus (normal medium A transition to the ART state during the CZ state and a transition to the SZ state during the ART CZ state are given. In the present embodiment, when a bonus (BB) is won during the game period in the CZ state, the effect of bonus notification (game lock for bonus prize) is not generated.

  Further, in the game period in the CZ state, the game after the bonus (BB) winning is a bonus game, but in the production, the CZ during the CZ executed before the bonus winning until the enemy HP becomes “0” or less. The state effect (battle effect) is continuously performed. The enemy HP is also subtracted in the bonus game after the bonus prize winning, and when the enemy HP becomes “0” or less, the battle effect in the CZ state is ended, and thereafter, the effect content is switched to the effect for the bonus.

  Also, in the above-described sequence of effects at the time of winning a bonus (BB) in the CZ state, in the bonus (BB) game during the game period in the CZ state, the subtraction value of the enemy HP (damage point ) Is determined as “25” (correction value during special prize). Furthermore, if the internal winning combination is a combination relating to “strong rare” in the bonus (BB) game during the game period in the CZ state, “200” is determined as the subtraction value (damage) of the enemy HP. That is, in the present embodiment, when the bonus (BB) game is started during the game period in the CZ state, the subtraction value (damage point) of the enemy HP is reliably determined, and depending on the type of the winning combination, The subtraction value of the enemy HP that surely makes the enemy HP equal to or less than “0” (determines the CZ victory) can also be determined.

  Therefore, by providing the subtraction function of the enemy HP after the bonus prize in the above-mentioned CZ state, when the bonus (BB) game is started during the game period in the CZ state, the enemy HP is set to “0” or less. This makes it easier to defeat a CZ enemy character, so that the interest in the game in the CZ state can be enhanced.

  Note that, in the present embodiment, an example in which the enemy HP is subtracted and the enemy HP approaches “0” during the game period in the CZ middle state is described, but the present invention is not limited to this. For example, in the game period in the CZ middle state, the enemy HP may be added and the gambling ability to bring the enemy HP closer to a predetermined value may be adopted. Further, for example, in the game period in the CZ middle state, a gaming property in which the friend HP is updated (subtracted or added) and the friend HP approaches a predetermined value may be adopted. Further, for example, in the game period in the CZ middle state, a gaming property in which both the enemy HP and the ally HP are updated (subtracted or added) and each HP approaches a predetermined value may be adopted.

[Effects from the function of adding HP to the ally]
As described above, the pachislot 1 of the present embodiment is a game in which the transition to the ART is determined in the normal middle CZ state, or a game in which the transition to the SZ state is determined in the ART during CZ state, that is, the CZ. In the game in which the victory of the CZ battle (Battle A or C) is determined in the middle state, the game further has a function of enabling the addition of a friend HP according to the internal winning combination as a privilege. That is, in the pachislot 1 of the present embodiment, when it is determined that the enemy HP becomes “0” or less in the CZ middle state (timing), an additional HP is added according to the internal winning combination (additional privilege). Is provided (a lottery added to a friend's HP).

  When this function is provided, the reward given to the player can be changed according to the internal winning combination when the ally character defeats the CZ enemy character in the effect. For example, when the internal winning combination when the ally character defeats the CZ enemy character is a rare combination, as shown in FIG. 255, there is a possibility that an additional ally HP may be obtained, and among them, the internal winning combination may be obtained. In the case of a strong rare ("strong che", "cha eyes, subbell" or "medium che"), a value of "100" or more is always determined as an additional point of the ally HP.

  Therefore, by providing such an additional function of the ally HP, it is possible to enhance the interest of the player in the game in the CZ state, and further, when the bonus game is started during the game period in the CZ state, Since the possibility that a good reward (easily reducing the enemy HP to “0” or less) can be obtained increases, the interest of the player can be further increased.

[Effect by special effect "strike"]
As described above, the pachislot 1 of the present embodiment has a lottery function for updating (subtracting or adding) the enemy HP during the game period in the CZ state. Specifically, in the game in the CZ middle state, a damage lottery for determining a damage point of the enemy HP is performed. The present embodiment also has a lottery function for determining whether or not to apply a special effect to the damage point of the enemy HP determined by the damage lottery. Specifically, in the game in the CZ middle state, the above-described special effect lottery is performed, and when the special effect “strike” is determined by this lottery, the damage point of the enemy HP determined by the damage lottery is determined. Changes.

  As described in the damage lottery table in FIG. 240, in the situation where the special effect “shot” is set, a damage point of “23” or more is always determined, and a larger value is set than in the other situations. It is configured so that damage points can be easily obtained. Therefore, in the present embodiment, the mode of updating (subtraction or addition) of the enemy HP during the game period in the CZ state can be diversified, and the interest of the player in the game in the CZ state can be enhanced.

  Also, in the game in the CZ middle state, in a situation where the special effect “continuous hit” is set, various effects for notifying that the special effect is set are provided. For example, an effect in which each of a plurality of ally characters alternately attacks a CZ enemy character while sequentially changing, an effect in which one ally character continuously attacks the CZ enemy character over several games, and an ally character is a character in which a CZ enemy character There are effects such as an effect of dodging an attack and then turning into an attack, and an effect of stunning a CZ enemy character by a predetermined game and continuing to attack the stunned CZ enemy character thereafter.

  That is, in the game in which the "strike" is activated, the types of attack effects of the ally characters are increased as compared with the game in which the "strike" is not set. Therefore, in the game in which the “shooting” operation is being performed, the content of the attack effect of the ally character is diversified, and the interest of the player in the game in the CZ state can be enhanced.

  Note that, in the present embodiment, an example has been described in which the damage lottery table is switched to a table in which damage points that can be obtained are preferentially treated in a situation (special state) in which the special effect “shot” is set. The present invention is not limited to this. For example, in a special state, a damage lottery table used in other states may be used to determine a damage point, and a predetermined additional damage point may be added to the determined damage point.

[Effect of the cycle counting function of the first cycle when the setting is changed and when power is cut off for 4 hours or more]
In the pachislo 1 of the present embodiment, as described above, when the setting is changed, the game period of the first cycle in the normal state is longer (about twice as long) as in other cases. Further, in the present embodiment, when returning from a power interruption of 4 hours or more, in the effect controlled by the sub side, the normal game in the first cycle (the number of remaining games at the time of power interruption) and the normal game in the second cycle Is performed in one cycle, a power return effect is executed.

  Therefore, in the present embodiment, the game period of the first cycle is longer than the other cases in the effect, both at the time of the setting change and at the time of return from the power interruption for 4 hours or more, and at the time of the setting change, 4 hours. It is possible to make it difficult for the player to recognize the difference from the above-mentioned return from the power interruption (at the time of stationary operation). That is, in the present embodiment, it is possible to prevent the fact that the RAM is cleared from being changed due to a setting change or the like.

[Overlapping winning function in BB]
In the pachi-slot 1 of the present embodiment, as described above, a plurality of types of so-called “ANY roles” are provided in which a winning is determined by stopping symbols on some reels. In the present embodiment, in the game in the BB state, the internal winning combination of the name “F_RB Bell”, “F_RBBAR Alignment” or “F_BAR Loss” is won, and the symbol combination “watermelon” − “watermelon” is displayed on the activated line. When "watermelon" is stopped and displayed, the small role (9-piece role) related to the combination name "JAC_watermelon chance_1" and the small role (4-piece role) related to the combination name "watermelon_CD_1", which are ANY roles ) Is awarded in duplicate, and the total number of medals paid out by both small roles (13) is paid out.

  On the other hand, in a game other than the BB state, the small combination associated with the combination name “JAC_watermelon chance_1” is not won (winned). Therefore, in a game other than the BB state, when the internal winning combination of the name "F_watermelon" is won and the symbol combination "watermelon"-"watermelon"-"watermelon" is stopped and displayed on the activated line, ANY Only the small role (four-piece role) associated with the combination name “watermelon_CD_1” as a role will win, and the number of paid-out medals will be four.

  As described above, in the present embodiment, by appropriately providing the ANY combination, a plurality of combinations can be simultaneously won according to the game state without increasing the number of activated lines. In the present embodiment, the number of inserted medals (number of medals) in the BB state is the same as that in the non-BB state, and the effective line in the BB state is the same as that in the non-BB state.

  Therefore, in the present embodiment, it is possible to change the number of game media to be paid out when a specific symbol combination (combination) is stopped and displayed according to the game situation. Further, in the present embodiment, it is only necessary to increase the combinations (symbol combinations) defined as winning combinations according to the gaming state without changing the combinations of the symbols displayed on the activated lines. , And the storage capacity of the symbol combination can be reduced.

<Various modifications>
As above, the configuration and operation of the gaming machine according to the second embodiment of the present invention have been described, including the effects thereof. However, the present invention is not limited to the embodiments described above, and includes various other embodiments and modifications without departing from the spirit of the present invention described in the claims.

[Modification 8]
In the present embodiment, there has been described an example of an effect in which the friendly HP and its damage point, and the enemy HP and its damage point are displayed as appropriately enlarged according to the value of the ART chapter during stay. The invention is not limited to this. For example, the following modifications may be adopted.

  In the pachislot 1 of the present embodiment, in the ART during CZ state, if the ally character defeats the CZ enemy character (boss character) in the ART chapter being stayed, the process proceeds to the story (level) of the next chapter and the ally character is staying. If the player loses a CZ enemy character (boss character) in the ART chapter, the game in the same chapter is continued. That is, the stage (level) transition state of the ART state in the present embodiment is such that when a friend character defeats a CZ enemy character (boss character) in the staying stage, the stage proceeds to the next stage (the level is promoted), and the friend character is in the staying stage. When the CZ enemy character (boss character) loses, the same stage is maintained. However, the playability in the ART state is not limited to this example.

  For example, the level of the ally character is raised in accordance with the game history in the ART state such as the number of games staying in the ART chapter (stage), the number of matches with the CZ enemy character (boss character) in the ART chapter (stay stage) during the stay. A configuration may be further provided in which the value (damage point of the enemy character) when attacking is increased according to the level. When such a configuration is provided, a new table may be provided in which the correspondence between the level of the friendly character and the damage point of the enemy character is defined. In addition, when such a configuration is provided, the initial value of the required CZ point is further reduced in accordance with the level of the friendly character, thereby reducing the number of games until the match with the CZ enemy character (boss character). A configuration may be provided.

  In the case where such an ART state gaming property is employed, for example, the attacking power of a friendly character is increased, or it is easier to shift to the CZ intermediate state during the ART (e.g., it is easier to play against a CZ enemy character (boss character)). Therefore, even if the stay period in the same ART chapter (stage) becomes longer, the possibility that the friend character will defeat the CZ enemy character (boss character) and progress to the story (level) in the next chapter increases. Therefore, in this example, the player's interest in the game in the ART state can be further increased.

[Modification 9]
Modification Example 9 describes a configuration in which the pachislo 1 of the above-described second embodiment includes a ratio display connected to the main control board 71. The present invention is not limited to this, and the ratio display of this example described below may be applied to the pachislot 1 of the first embodiment described above.

  326A and 326B show configuration examples of the ratio display. Note that FIG. 326A is a diagram illustrating an example of attachment of the ratio display, and FIG. 326B is a diagram illustrating the content of information displayed on the ratio display.

(1) Configuration of Ratio Display As shown in FIG. 326A, the ratio display is configured by a 4-digit 7-segment LED, the upper 2 digits indicate the type of display content (ratio), and the lower 2 digits indicate Indicates the value (%) of the ratio of the display content. The percentage indicator is provided inside the pachislot because it is used when an administrator (such as a clerk of an amusement store) checks whether or not the pachislot has been tampered with. At this time, it is preferable that the ratio indicator be provided inside a main control board case that covers the main control board 71 in order to prevent improper manipulation of the ratio indicator itself.

  As a specific example of attachment, for example, as shown in FIG. 326 (A-1), a ratio indicator may be mounted on the main control board 71, or as shown in FIG. 326 (A-2). Alternatively, it may be mounted on another board (ratio display board) connected to the main control board 71. Further, as shown in FIG. 326 (A-3), a 7-segment LED unit as a ratio indicator may be connected to the main control board 71 to attach the ratio indicator. In any case, as shown in FIG. 326A, it is preferable to provide the ratio indicator together with the main control board 71 inside the main control board case.

  By the way, usually, a recording paper or a seal is affixed to the main control board case. However, when a rate indicator is provided in the main control board case, the visibility of the rate indicator is impaired by the seal or the like. It is preferable to attach a sealing seal or the like so as not to occur. The sealing seal is for leaving a trace of opening the main control board case, and is a seal that has been specially processed so that a trace remains when the main control board case is peeled off. The recording paper is a paper for recording when the main control board case is attached / detached or opened in a regular procedure. The recording paper is printed with an identification number of the main control board 71, and further provided with an entry column for entering the date and time when the detachment / opening was performed and the person in charge at that time. Here, the “regular procedure” includes manufacture of the gaming machine (when the gaming machine is fixed), on-site inspection after the gaming machine is installed in the gaming shop, and the like.

(2) Display Contents of Ratio Display Next, display examples of the ratio display will be described. As shown in FIG. 326B, the ratio display device displays the total specific section ratio, the continuous bonus ratio and the bonus ratio between the latest 6000 games, and the cumulative continuous bonus ratio and the bonus ratio. You. When displaying the cumulative specific section ratio on the ratio display, "AU" is displayed in the upper two digits of the 4-digit 7-segment LED, and when displaying the continuous character ratio between the latest 6,000 games, In the upper two digits, “= r” is displayed, and when displaying the ratio of bonuses between the latest 6000 games, in the upper two digits, “= b” is displayed, and the total continuous bonus ratio is displayed. In this case, “Ar” is displayed in the upper two digits, and “Ab” is displayed in the upper two digits when displaying the cumulative accessory ratio. In addition, in the lower two digits of the 4-digit 7-segment LED, the corresponding ratio is displayed in percentage.

  Here, the “specific section ratio” refers to a ratio of the number of games in the gaming state advantageous to the player to the number of games in all the gaming states (ie, the total number of games). In this case, the game state advantageous to the player includes not only a notification state (AT or ART game state) for notifying information advantageous to the player, but also a CZ middle state having a high degree of expectation of transition to the notification state. May be included. Further, the bonus state started during the notification state may be included in the advantageous gaming state in this case.

The main control board 71 counts, by a predetermined counter provided in the main RAM 103, the total number of games indicating the number of games in all game states and the specific number of games indicating the number of games in the game state advantageous to the player. In advance, the specific section ratio is calculated by the following equation.
Specific section ratio = Specific number of games / Total number of games × 100

  In addition, the “continuous bonus ratio” refers to the total number of medals paid out in all game states (that is, the total number of paid out medals) as a first-class special bonus or a first-class special bonus. It refers to the ratio of the total number of medals paid out in the gaming state in which the accessory continuous operation device is operating.

The main control board 71 uses a predetermined counter provided in the main RAM 103 to display the total number of payouts indicating the total number of medals paid out in all game states, a first-class special accessory, or a first-class special combination. The number of payouts during the first specific game, which indicates the total number of medals paid out during the operation of the accessory continuous operation device for the object, is counted, and the ratio of the continuous bonuses is calculated by the following formula.
Consecutive bonuses ratio = number of payouts during the first specific game / total number of payouts x 100

  Also, the “principal ratio” refers to the total number of medals paid out during the operation of any one of the medals with respect to the total number of medals paid out in all gaming states (ie, the total number of paid out medals). It means the ratio. In addition, "any one of the special items" means a special type of special type, a continuous operation device for the type 1 special special item, a type 2 special special item, and a type 2 special special item. Refers to a continuous actuating device or a normal accessory. Further, the ART state, the CZ state, and the like are also advantageous states for the player. Therefore, these states may be included in the state in which “any accessory” is operating.

The main control board 71, at a predetermined counter provided in the main RAM 103, indicates the total number of payouts indicating the total number of medals paid out in all game states, and the medals paid out during the operation of any of the accessories. The number of payouts during the second specific game, which indicates the total number of payouts, is counted, and the accessory ratio is calculated by the following equation.
Consecutive bonus ratio = Payout number during the second specific game / Total payout number × 100

  In addition, “total” refers to the entire period from the installation of the pachislot to the present, and “the most recent 6,000 games” refers to the period from the game preceding the 6,000 games to the present. When calculating the ratio of “total”, the main control board 71 may calculate the ratio using the counting result counted in all periods, and when calculating the ratio of “between the latest 6000 games”, The main control board 71 may calculate the ratio by using the counting result counted in the period from the game before the 6000 game to the present.

  The predetermined counter provided in the main RAM 103 is provided in an area that is not cleared (initialized) even when the power is turned ON / OFF or the setting is changed. That is, the data relating to the ratio display stored in the main RAM 103 is configured not to be erased (not cleared) even when the power is turned on / off or the setting is changed. Further, a predetermined counter provided in the main RAM 103 counts data relating to the ratio display with 400 games as one set. For example, when calculating the ratio between 6000 games, the ratio is calculated using the counting result of the total of 15 sets.

(3) Display contents of the ratio display (switch display)
The ratio display switches and displays various ratios calculated by the main control board 71. The method of switching the content to be displayed on the ratio display is arbitrary.For example, the display of various ratios may be automatically switched at a predetermined interval, or may be manually changed in response to the operation of a dedicated switch. The display of the ratios may be switched, or the display of various ratios may be switched by a combination of automatic switching and manual switching.

(4) Modification Example of Ratio Display Since existing pachislots do not have a ratio display, it is necessary to make a large modification to the existing pachislot in the installation example of the ratio display shown in FIG. 326A. is there. Therefore, when incorporating the configuration of the ratio indicator into the existing pachislot, the indicator provided in the existing pachislot may be used as a ratio indicator for displaying various ratios. For example, an existing pachislot is provided with a display (information display 6) for displaying the number of stored medals (the number of credits) and the number of medals paid out in this game (payout number). Therefore, this indicator may be used as a ratio indicator.

  In this case, for example, when a special operation is performed on the pachi-slot, the type of display content (ratio) is displayed on a credit number display unit (credit lamp: not shown), and the payout number display unit ( The display of the display unit may be switchable so that the value of the ratio of the display content is displayed on the payout number lamp (not shown). The special operation performed at this time is optional, but is preferably an operation using a switch provided inside the pachislot. Thereby, it is possible to prevent the player from accidentally performing a special operation.

[Other various modifications]
The configuration of the enemy-less state during the ART is not limited to the example of the second embodiment. For example, the game period in the ART-free state may be a fixed value, or the game period in the ART-free state may be one or more arbitrary games. In addition, a mode other than the number-of-games management (for example, the number of times of navigation, the number of differences, the lottery, etc.) may be used as the management mode for the end of the enemy-less state during the ART. Further, in the present embodiment, it is not necessary to provide the enemy-free state during the ART.

  The configuration in the ART enemy presence state is not limited to the example of the second embodiment. For example, the game period in the enemy during ART state may be set to one or more arbitrary games. Further, the game period in the ART in enemy presence state may be variable (for example, it may be determined by lottery from a plurality of games). In addition, a management mode other than the management of the number of games (for example, the number of times of navigation, the number of difference, the lottery, etc.) may be used as the management mode of the end of the enemy with ART state. Further, in the present embodiment, the enemy presence state during the ART may not be provided.

  The configuration in the battle state is not limited to the example of the second embodiment. For example, the game period in the battle state may be set to one or more arbitrary games. Further, the game period of the enemy during the battle may be variable (for example, it may be determined by lottery from a plurality of games). When the game period in the battle state is made variable, the longer the number of games in the battle state (game period), the more advantageous to the player. Therefore, the number of games continued in the battle B state is determined by the player. Interest can be raised, and the interest of the game can be improved. In addition, a management mode other than the number-of-games management (for example, the number of times of navigation, a difference number, a lottery, etc.) may be used as the management mode of the end trigger of the battle state. Further, in the present embodiment, the in-battle state may not be provided. In other words, in a game in the ART-in-enemy absence state and / or the ART-in-enemy presence state, a configuration for determining the termination or continuation of the ART state may be adopted.

  In the second embodiment, in the configuration of the battle state, the battle state is continued when the continuous lottery is not won over two games (when “losing” is not determined in the reward lottery). When the continuous lottery is won even in one game during the battle state, a configuration is adopted in which the transition to the enemy-free state during ART (safe zone) is determined, but the present invention is not limited to this. For example, if a continuous lottery is won even in one game during the battle state, it is possible to shift to the enemy-free state during the ART (safe zone), and if the continuous lottery is not won over two games, the battle is in progress. The configuration may be such that the continuation of the state is determined. Furthermore, if the continuous lottery is not won even in one game during the battle state, the battle state may be continued. In addition, the game state of the transfer destination is determined according to the pattern of the result of the continuous lottery performed over the two games (a pattern in which the first game is continuous and a second game is not continuous, and the reverse pattern). It may be configured.

  In the second embodiment, an example in which the value of the enemy HP (initial value) is changed according to the type of the CZ enemy character has been described. However, the present invention is not limited to this. On the other hand, a common enemy HP value (initial value) may be set. Further, for example, the enemy HP may be fixed or variable (for example, determined by lottery from a plurality of values) for each type of CZ enemy character. Also, for example, one type of CZ enemy character during ART may be used, and the enemy HP of the CZ enemy character may be changed according to the value of the ART chapter.

  In the second embodiment, the initial value of the ally HP may be fixed as in the second embodiment, or may be variable (for example, randomly determined from a plurality of values). . In addition, a plurality of types of friendly characters may be provided. In this case, the ART may be terminated when the ally HP of all the ally characters reaches “0”. In this case, the initial value of the ally HP of all the ally characters may be common, or may be changed for each type of the ally character. Further, in this case, for example, the ally HP may be fixed or variable (for example, determined by lottery from a plurality of values) for each type of ally character.

  Furthermore, in the second embodiment, various parameters (such as special effects, damage points, the number of weapons, and the amount of HP recovery) related to the game period in the ART state are also fixed or variable (for example, randomly determined from a plurality of values). ). Also, various parameters (for example, the number of CZ lottery mode period games, CZ required points, P points, and the like) set in the normal state may be fixed or variable (for example, randomly determined from a plurality of values).

  In the second embodiment, the effect of counting the number of remaining cycle games is performed in the normal normal state, but the present invention is not limited to this, and the effect of counting the number of remaining cycle games may not be performed. . Even in this case, in the normal middle general state, the effect is performed in one cycle of “Normal A”, “Normal B” and “Normal C”. It is possible to get a rough idea of the number.

  In the second embodiment, in the effect performed during the game period in the ART state, when the value of the chapter of the ART chapter (story) increases (as the story progresses), the ally HP and its damage points, and the enemy HP The example has been described in which the damage points and the damage points are appropriately enlarged according to the value of the ART chapter during stay (the duration of the ART) and displayed, but the present invention is not limited to this. The friendly HP and its damage point, and the enemy HP and its damage point may be appropriately reduced as the value of the ART chapter (story) increases (as the story progresses). In the second embodiment, an example in which the friendly HP and its damage points, and the enemy HP and its damage points are displayed as a value (100 times) larger than the numerical value managed on the main side in the effect. Although described, the present invention is not limited to this, and the friendly HP and its damage points, and the enemy HP and its damage points may be displayed with a value smaller than the numerical value managed on the main side in the effect. .

  Further, in the second embodiment, an example in which the damage point (update value of the parameter) is changed mainly based on the internal winning combination has been described, but the present invention is not limited to this, and other conditions (for example, , The presence or absence of a game lock).

  Although the detailed description is omitted in the second embodiment, the transition to the advantageous section (AT or ART state) may be determined by lottery (the transition by the ceiling function in the normal cycle or the transition via the normal CZ). May be omitted.) In this case, it is preferable that there is no setting difference in the lottery winning probability. In the second embodiment, the advantageous section (AT or ART state) is forcibly terminated in 1500 games. Therefore, if the advantageous section ends suddenly without notice when the 1500 game is reached, the interest of the gaming company may be reduced. Therefore, in the second embodiment, it is preferable to make an effect such that the ally HP becomes “0” in the 1500 game. For example, it is preferable to adjust (subtract) the value of the friendly HP stepwise so that the friendly HP becomes “0” at 1500 G without any discomfort, for example, by setting the friendly HP to a certain value or less in the 1400 game.

<Various functions of main control board and sub control board>
Hereinabove, the pachislot 1 according to the second embodiment of the present invention and various modifications thereof have been described. Here, various functions of the main control board 71 (main control circuit 90, main CPU 101) and sub-control board 72 (sub-control circuit 200, sub-CPU 201) of the pachi-slot according to the second embodiment of the present invention will be summarized. I do.

  The main control board 71 is connected to the start switch 79 and the stop switch board 80, and controls the progress of the game shown in FIG. Therefore, the main control board 71 functions as start operation detection means, symbol variation means, internal winning combination determination means, stop operation detection means, reel stop control means (stop control means), and winning determination means.

  The main control board 71 controls a game in an ART state (a notification game state). Therefore, the main control board 71 also functions as a notification game control unit. In addition, the main control board 71 also controls an update process (S2331 and S2332 during the battle B damage reflection process) of the ally HP (a parameter relating to the end timing of the notification game state) for managing the end timing of the ART state. Therefore, the main control board 71 also functions as a parameter updating unit.

  Further, the main control board 71 controls a game in the CZ middle state (specific game state). Therefore, the main control board 71 also functions as a specific game control unit. Further, the main control board 71 controls a game lock performed at a predetermined timing in the unit game. Therefore, the main control board 71 also functions as lock execution means.

  Further, the main control board 71 performs update control of the enemy HP (specific parameter) in the game in the CZ state (for example, S2164 during the start process during the CZ). Therefore, the main control board 71 also functions as a specific parameter updating unit. Further, in the game in the normal state, the main control board 71 controls a process of determining a game period for one cycle of the normal game when a predetermined condition is satisfied (for example, a CZ lottery mode cycle game number random determination process). Therefore, the main control board 71 also functions as a game period determination unit.

  In the ART state, the sub-control board 72 controls an effect of displaying on the display device 11 the friend HP and the enemy HP, and numerical values related to the respective damage points. At this time, these numerical values displayed on the display device 11 are changed according to the level (chapter value) of the ART chapter during stay. Therefore, the sub control board 72 also functions as a parameter display unit. Note that the friend HP and the enemy HP, and their respective damage points, indicate a specific example of “parameters relating to the game in the notification game state” according to the present invention.

The sub control board 72 controls a predetermined effect that is executed according to the game state.
Therefore, the sub-control board 72 also functions as an effect executing unit.

<Supplementary note (Summary of the present invention)>
[First gaming machine]
2. Description of the Related Art Conventionally, there has been known a gaming machine having the above-described configuration, in which a checksum of data stored in a RAM is obtained at the time of a power failure, and a determination process of the checksum obtained at the time of the power failure is performed at the time of power recovery. For example, see JP-A-2009-011375). In the gaming machine disclosed in Japanese Patent Application Laid-Open No. 2009-011375, an error is notified in the checksum determination process at the time of power recovery when the checksum obtained at the time of power recovery does not match the checksum obtained at the time of power interruption.

  By the way, conventionally, as a limitation peculiar to the above-described gaming machine, the program capacity of the main control circuit is limited to a small capacity according to rules. Furthermore, in recent years, the ROM capacity of the main control circuit has been squeezed due to the complexity of the game, and the capacity of processing programs and tables other than the game, managed by the main control circuit, has been required to be reduced.

  SUMMARY OF THE INVENTION The present invention has been made to solve the first problem, and a first object of the present invention is to reduce the capacity of a processing program or a table other than the game property managed by the main control circuit. It is an object of the present invention to provide a gaming machine capable of increasing the free space of a ROM of a main control circuit and using the free space of the ROM for the increased capacity to enhance the gaming ability.

  In order to solve the first problem, the present invention provides a first gaming machine having the following configuration.

Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
Power supply means for supplying a power supply voltage (for example, a power supply board 53b and a switching regulator 94);
Activating means (for example, output processing of a reset signal of the power management circuit 93) for outputting a activating signal to the arithmetic processing means when the power supply voltage exceeds a predetermined activating voltage value (for example, 10V);
A power failure means for outputting a power failure signal to the arithmetic processing means when the power supply voltage falls below a predetermined power failure voltage value (for example, 10.5 V); Processing), and
The arithmetic processing means,
A flag register (eg, a flag register F) for storing data corresponding to a result of the arithmetic processing;
When the power failure means outputs the power failure signal, a sum value is calculated by accumulatively adding all information stored in a predetermined storage area (for example, a game RAM area) in the second storage means. Sum value calculation means (for example, checksum generation processing);
A sum value for sequentially subtracting information stored in the predetermined storage area from the sum value generated by the sum value calculation unit at the time of the most recent power failure, triggered by the activation unit outputting the activation signal. Subtraction means (for example, S122 to S131 during the sum check process);
When the subtraction processing by the sum value subtracting means is completed for all the information stored in the predetermined storage area, the subtraction result set in a predetermined bit area (for example, a zero flag) in the flag register is used. A gaming machine comprising: a sum value determination unit (for example, S134 during a sum check process) that determines whether an abnormality has occurred based on corresponding data.

Further, in the first gaming machine of the present invention, the sum value calculating means executes a specific command (for example, a POP command) when adding the information stored in the predetermined storage area, Acquiring and adding information of 2 bytes continuously stored and updating information of a read start address of the information by 2 bytes,
The sum value subtracting means executes the specific instruction when subtracting the information stored in the predetermined storage area from the sum value generated at the time of the occurrence of the power interruption, so that the two consecutively stored two values are stored. The information of the read start address of the information may be updated by 2 bytes while obtaining and subtracting the information of the byte.

Further, in the first gaming machine of the present invention, the arithmetic processing means has a stack pointer capable of setting an address of the predetermined storage area of the second storage means,
The specific instruction executed when the sum value calculating means adds the information stored in the predetermined storage area may be a dedicated instruction (for example, a POP instruction) for operating the stack pointer. Good.

  According to the first gaming machine of the present invention having the above-described configuration, the capacity of the processing program and tables other than the gaming property is reduced, and the free space of the ROM (first storage means) of the main control circuit is increased. The gaming ability can be enhanced by using the free space of the ROM for the capacity.

[Second to fifth gaming machines]
Conventionally, in the gaming machine having the above-described configuration, there has been proposed a gaming machine equipped with a main controller that processes numerical data by using a stack pointer in an operation instruction (for example, see Japanese Patent Application Laid-Open No. 2005-237737). ).

  By the way, conventionally, as a limitation peculiar to the above-described gaming machine, the program capacity of the main control circuit is limited to a small capacity according to rules. Further, in recent years, the capacity of the ROM of the main control circuit has been squeezed due to the complexity of gaming, and there has been a demand for a reduction in the capacity of processing programs and tables managed by the main control circuit.

  The present invention has been made to solve the second problem, and a second object of the present invention is to reduce the capacity of a main control circuit by reducing the capacity of a processing program and a table managed by the main control circuit. It is an object of the present invention to provide a gaming machine capable of increasing the free space in a ROM and using the free space in the ROM for the increased capacity to enhance the gaming ability.

  In order to solve the second problem, the present invention provides a second gaming machine having the following configuration.

Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
A dedicated register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
An expansion register (for example, a Q register) that stores data when the arithmetic processing is performed by the arithmetic processing means and that can specify a part of an address in the first storage means or the second storage means by the stored data. ) And
The arithmetic processing means executes a predetermined instruction (for example, a “BITQ” instruction, a “SETQ” instruction, an “LDQ” instruction, etc.) capable of specifying an address in the second storage means using the extension register. A gaming machine characterized in that it is possible.

  Further, in the second gaming machine of the present invention, a part of the address that can be specified by the extension register may be an upper address value constituting the address.

  Further, in order to solve the second problem, the present invention provides a third gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the stop operation of the display column by the stop control means;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
A dedicated register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
An expansion register (for example, a Q register) that stores data when the arithmetic processing is performed by the arithmetic processing means and that can specify a part of an address in the first storage means or the second storage means by the stored data. ) And
The arithmetic processing means,
In the process of checking the stop state of the display column,
A predetermined read command (for example, an “LDQ” command) capable of specifying an address in the second storage means is executed by using the extension register, and a predetermined read command stored in the second storage means is executed. Read information indicating the state of the variable display of the display column,
Next, a predetermined OR operation instruction (for example, an “ORQ” instruction) capable of specifying an address in the second storage means is executed by using the extension register, and is stored in the second storage means. While reading the information indicating the state of the variable display of the other one display column, and performing a logical OR operation of the information and the information indicating the state of the variable display of the predetermined display column,
Thereafter, the execution of the predetermined OR operation instruction is repeated, and the OR operation of the result of the OR operation and the information indicating the state of the variable display of each of the remaining display columns is repeated. A gaming machine, comprising: determining whether or not all display columns are in a stopped state, based on a result of a calculation sum calculation obtained when a calculation is completed.

  Further, in the third gaming machine of the present invention, a part of the address that can be specified by the extension register may be an upper address value constituting the address.

  Further, in order to solve the second problem, the present invention provides a fourth gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the operation of determining the internal winning combination by the internal winning combination determining means;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
A dedicated register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
An expansion register (for example, a Q register) that stores data when the arithmetic processing is performed by the arithmetic processing means and that can specify a part of an address in the first storage means or the second storage means by the stored data. ) And
The internal winning combination determined by the internal winning combination determining means includes a setting-dependent internal winning combination in which a winning probability is changed according to a setting value for adjusting an expected value at which an internal winning combination related to a privilege is determined. Is provided,
The arithmetic processing means,
In the process of determining the internal winning combination,
By executing a predetermined addition instruction (for example, an “ADDQ” instruction) that can specify an address in the second storage means using the extension register, the setting of the internal winning combination according to the setting as a lottery target is performed. The current setting value is added to the start address of the area where the lottery value for each value is stored, and the address at which the lottery value of the internal winning combination by setting corresponding to the current setting value is stored is specified. A gaming machine characterized by acquiring the lottery value.

  In the fourth gaming machine of the present invention, a part of the address that can be specified by the extension register may be an upper address value constituting the address.

  In order to solve the second problem, the present invention provides a fifth gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
When the variable display of the plurality of display columns is stopped by the stop control means, a symbol corresponding to an internal winning combination related to the payout of the game medium, on a determination line set across the plurality of display columns. A privilege grant determination means (for example, a winning search process) for determining whether or not the combination of
An arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the judging operation by the privilege granting judging means;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
The arithmetic processing means,
In the process of determining whether or not a combination of symbols corresponding to the internal winning combination related to the payout of the game medium is stopped and displayed on the determination line,
A predetermined read command (for example, an “LDIN” command) is executed, and the game which can be given when the symbol combination corresponding to the internal winning combination related to the payout of the game medium is stopped and displayed on the determination line. The data of the number of payouts of the medium and the determination data indicating the type of combination of symbols corresponding to the internal winning combination related to the payout of the game medium, which are associated with the data of the number of payouts, are simultaneously obtained. Gaming machine to do.

Further, in the fifth gaming machine of the present invention, the arithmetic processing means includes:
In the process of determining whether or not a combination of symbols corresponding to the internal winning combination related to the payout of the game medium is stopped and displayed on the determination line,
A predetermined instruction (e.g., a "JSLAA" instruction) that can execute a determination instruction, a designation instruction of a jump destination address of a process, and a jump operation instruction of a process by one instruction is executed, and an internal device related to payout of the game medium is executed. It may be determined whether or not the symbol combination corresponding to the winning combination is stopped and displayed.

  According to the second to fifth gaming machines of the present invention having the above-described structure, the capacity of the processing program and tables managed by the main control circuit is reduced, and the free space of the ROM (first storage means) of the main control circuit is reduced. It is possible to increase the playability by utilizing the ROM free space corresponding to the increased capacity.

[Sixth and seventh gaming machines]
Conventionally, in a gaming machine having the above-described configuration, when an abnormality occurs in data stored in the RAM of the main control unit, the RAM is controlled to a RAM abnormality error state, the progress of the game is disabled, and the setting change mode is set. When a setting value is newly selected and set based on a setting change operation, a gaming machine that cancels the state in which the progress of the game is disabled and sets the state in which the game can be advanced has been proposed ( For example, see JP-A-2007-209810).

  By the way, conventionally, as a limitation peculiar to the above-described gaming machine, the program capacity of the main control circuit is limited to a small capacity according to rules. Further, in recent years, the capacity of the ROM of the main control circuit has been squeezed due to the complexity of gaming, and there has been a demand for a reduction in the capacity of processing programs and tables managed by the main control circuit.

  The present invention has been made to solve the third problem, and a third object of the present invention is to reduce the capacity of a processing program or a table managed by the main control circuit and reduce the capacity of the main control circuit. It is an object of the present invention to provide a gaming machine capable of increasing the free space in a ROM and using the free space in the ROM for the increased capacity to enhance the gaming ability.

  In order to solve the third problem, the present invention provides a sixth gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
Data transmission means for transmitting command data relating to the game operation (for example, S904 (communication data transmission processing) during interrupt processing);
A setting change confirming means (for example, a setting change confirming process) capable of executing a setting value changing process and a setting value confirming process for adjusting an expected value at which an internal winning combination related to awarding is determined;
An arithmetic processing unit (for example, main CPU 101) for performing an arithmetic process for controlling a setting value change operation or a confirmation operation by the setting change confirmation unit;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
At the start of the setting value change processing or the setting value confirmation processing, start command generation means for generating first command data (for example, S43 during the setting change confirmation processing);
At the end of the setting value change processing or the setting value confirmation processing, an end-time command generating means (for example, S57 during the setting change confirmation processing) for generating second command data,
The first command data generation process executed by the start command generation unit and the second command data generation process executed by the end command generation unit are shared. A gaming machine characterized by:

In the sixth gaming machine of the present invention, the arithmetic processing means has a general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means,
The arithmetic processing means,
When generating the first command data, a first value (for example, “005H”) is set in a predetermined register (for example, an L register) of the general-purpose register, and the generation process is executed.
When generating the second command data, a second value (for example, “004H”) may be set in a predetermined register of the general-purpose register, and the generation processing may be executed.

  In order to solve the third problem, the present invention provides a seventh gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
Data transmission means for transmitting command data relating to the game operation (for example, S904 (communication data transmission processing) during interrupt processing);
Communication data generation means for generating the command data (for example, setting change command generation storage processing and communication data storage processing);
A setting change confirming means (for example, a setting change confirming process) capable of executing a setting value changing process and a setting value confirming process for adjusting an expected value at which an internal winning combination related to awarding is determined;
An arithmetic processing unit (for example, a main CPU 101) for performing an operation for controlling the operation of generating the command data by the communication data generating unit and the operation of changing or confirming the setting value by the setting change checking unit;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
At the start of the setting value change processing or the setting value confirmation processing, start command generation means (for example, S43 during the setting change confirmation processing) for generating start command data;
At the end of the setting value change process or the set value confirmation process, an end command generation means (for example, S57 during the setting change confirmation process) for generating an end command data,
The start-time command data generation process executed by the start-time command generation unit and the end-time command data generation process executed by the end-time command generation unit are shared.
The arithmetic processing means has a plurality of general-purpose registers in which a plurality of types of data are stored when the arithmetic processing is performed by the arithmetic processing means,
The arithmetic processing means,
In the command data generation process,
Among a plurality of types of communication parameters constituting the command data, a communication parameter to be used is set in a corresponding general-purpose register among the plurality of general-purpose registers,
Storing a communication parameter used in the general-purpose register in a predetermined storage area (for example, a communication data temporary storage area) in the second storage means;
When there is an unused communication parameter among the plurality of types of communication parameters, data stored in a general-purpose register associated with the unused communication parameter when the command data is generated is used as the communication parameter as the predetermined communication parameter. In the storage area of
A gaming machine, wherein a sum value of the command data is generated based on data stored in the general-purpose register associated with a communication parameter.

  In the seventh game machine of the present invention, in the command data generation processing, a value stored in the general-purpose register associated with a communication parameter is added to a value stored in an accumulator of the general-purpose register. Then, a sum value of the command data may be generated, and the generated sum value may be stored in the predetermined storage area.

  According to the sixth and seventh gaming machines of the present invention having the above configuration, the capacity of the ROM and the like in the main control circuit is increased by reducing the capacity of the processing programs and tables managed by the main control circuit. The gaming ability can be enhanced by utilizing the free area of the ROM for the minutes.

[Eighth and Ninth Game Machines]
Conventionally, in the gaming machine having the above-described configuration, a gaming machine that transmits a command from a game control board (main control circuit) to an effect control board (sub-control circuit) is known (for example, see Japanese Patent Application Laid-Open No. 2002-360766). ).

  By the way, conventionally, as a limitation peculiar to the above-described gaming machine, the program capacity of the main control circuit is limited to a small capacity according to rules. Further, in recent years, the capacity of the ROM of the main control circuit has been squeezed due to the complexity of gaming, and there has been a demand for a reduction in the capacity of processing programs and tables managed by the main control circuit.

  The present invention has been made to solve the fourth problem, and a fourth object of the present invention is to reduce the capacity of a processing program and a table managed by the main control circuit to reduce the capacity of the main control circuit. It is an object of the present invention to provide a gaming machine capable of increasing the free space in a ROM and using the free space in the ROM for the increased capacity to enhance the gaming ability.

  In order to solve the fourth problem, the present invention provides an eighth gaming machine having the following configuration.

Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
Data transmission means for transmitting communication data relating to the game operation (for example, S904 (communication data transmission processing) during interrupt processing);
A communication data generation / storage unit that creates the communication data and stores the generated communication data in a communication data storage area provided in a predetermined address range in the second storage unit; Data pointer update processing), and
The communication data generation and storage means,
When storing the communication data in the communication data storage area sequentially from the storage area of the first address to the storage area of the last address in the predetermined address range, an update instruction, an upper limit determination instruction, and a determination branch instruction are sequentially stored. By executing a predetermined update instruction (for example, an “ICPLD” instruction) that can be executed by one instruction, the current value of the communication data pointer, which is a parameter related to addressing in the communication data storage area, and the last address Is compared with the upper limit value of the communication data pointer corresponding to, and if the current communication data pointer is less than the upper limit value, the communication data pointer is added and updated, and the current communication data pointer is updated to the upper limit value. If so, the communication data pointer is located below the communication data pointer corresponding to the head address. Gaming machine and changing the value.

  Further, in the eighth gaming machine of the present invention, the communication data generation and storage means, when changing the communication data pointer to a lower limit value of the communication data pointer corresponding to the start address, the communication data storage area May be invalidated.

  In order to solve the fourth problem, the present invention provides a ninth gaming machine having the following configuration.

Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
In a process of counting predetermined data values related to the progress of the game operation (for example, a medal payout number check process),
When updating the value of the predetermined data, a predetermined update instruction (for example, a “DCPLD” instruction) capable of executing an update instruction, a lower limit determination instruction, and a decision branch instruction with one instruction is executed, thereby updating the current value. Comparing the value of the predetermined data with the lower limit of the value of the predetermined data, and if the current value of the predetermined data is larger than the lower limit of the value of the predetermined data, the value of the predetermined data , And if the current value of the predetermined data is equal to or less than the lower limit of the value of the predetermined data, the value of the predetermined data is held at the lower limit.

  Further, in the ninth gaming machine of the present invention, the predetermined data may be a payout number of the gaming medium.

  According to the eighth and ninth gaming machines of the present invention having the above configuration, the capacity of the processing programs and tables managed by the main control circuit is reduced to reduce the free space of the ROM (first storage means) of the main control circuit. It is possible to increase the playability by utilizing the ROM free space corresponding to the increased capacity.

[10th gaming machine]
Conventionally, in the gaming machine having the above-described configuration, a gaming machine controlled by a timer subtraction process by software is known (for example, see Japanese Patent Application Laid-Open No. 2004-041261).

  By the way, conventionally, as a limitation peculiar to the above-described gaming machine, the program capacity of the main control circuit is limited to a small capacity according to rules. Further, in recent years, the capacity of the ROM of the main control circuit has been squeezed due to the complexity of gaming, and there has been a demand for a reduction in the capacity of processing programs and tables managed by the main control circuit.

  The present invention has been made to solve the fifth problem, and a fifth object of the present invention is to reduce the capacity of a processing program and a table managed by the main control circuit to reduce the capacity of the main control circuit. It is an object of the present invention to provide a gaming machine capable of increasing the free space in a ROM and using the free space in the ROM for the increased capacity to enhance the gaming ability.

  In order to solve the fifth problem, the present invention provides a tenth gaming machine having the following configuration.

Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
In the counting process of the timer number of the soft timer (for example, the timer updating process),
By executing a predetermined update instruction (for example, a “DCPWLD” instruction) that can execute the update instruction, the lower limit determination instruction, and the determination branch instruction with one instruction, the current timer number of the soft timer and the lower limit of the timer number are determined. While comparing the value, the timer number of the soft timer is subtracted and updated if the current timer number of the soft timer is larger than the lower limit, and if the current timer number of the soft timer is equal to or less than the lower limit value. A gaming machine, wherein the number of timers of the soft timer is held at the lower limit.

  In the tenth gaming machine of the present invention, the soft timer may be a 2-byte soft timer.

Further, in the tenth gaming machine of the present invention, the arithmetic processing means has a fixed cycle processing means (for example, an interrupt process repeatedly executed at a period of 1.1172 msec) which performs a process at a fixed cycle,
The counting process of the number of timers by the soft timer is executed by the periodic processing unit,
The elapsed time of the soft timer may be determined based on a cycle at which the fixed cycle processing unit performs processing and the number of timers.

  Further, in the tenth gaming machine of the present invention, the processing by the fixed-period processing means is executed based on an interrupt signal generated by a timer function (for example, the timer circuit 113) built in the arithmetic processing means. You may make it.

  According to the tenth gaming machine of the present invention having the above configuration, the capacity of the processing program and tables managed by the main control circuit is reduced to increase the free capacity of the ROM (first storage means) of the main control circuit. It is possible to provide a gaming machine capable of improving the gaming performance by using the ROM free space corresponding to the increased capacity.

[Eleventh and twelfth gaming machines]
2. Description of the Related Art Conventionally, among gaming machines having the above-described configuration, a gaming machine that displays an internal lottery result by a 7-segment LED under the control of a main control circuit is known (for example, see Japanese Patent Application Laid-Open No. 2008-237337).

  By the way, conventionally, as a limitation peculiar to the above-described gaming machine, the program capacity of the main control circuit is limited to a small capacity according to rules. Further, in recent years, the capacity of the ROM of the main control circuit has been squeezed due to the complexity of gaming, and there has been a demand for a reduction in the capacity of processing programs and tables managed by the main control circuit.

  The present invention has been made to solve the sixth problem, and a sixth object of the present invention is to reduce the capacity of a main control circuit by reducing the capacity of a processing program and a table managed by the main control circuit. It is an object of the present invention to provide a gaming machine capable of increasing the free space in a ROM and using the free space in the ROM for the increased capacity to enhance the gaming ability.

  In order to solve the sixth problem, the present invention provides an eleventh gaming machine having the following configuration.

Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
A plurality of 7-segment LEDs for notifying specific information related to the game,
7-segment LED driving means (for example, 7-segment LED driving processing) for driving the plurality of 7-segment LEDs;
LED drive control means for controlling the drive operation of the plurality of 7-segment LEDs by the 7-segment LED drive means,
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The LED drive control means includes:
A dynamic drive control is performed on the plurality of 7-segment LEDs, a predetermined read command (for example, an “LDW” command) is executed, and common selection data and cathode data are simultaneously output to the plurality of 7-segment LEDs. A gaming machine characterized by:

Also, in the eleventh gaming machine of the present invention, the arithmetic processing means has a fixed cycle processing means (for example, an interrupt processing repeatedly executed at a period of 1.1172 msec) which performs a process at a fixed cycle,
The fixed-period processing means counts the number of executions of the processing by the fixed-period processing means,
When the counted value is an even number, control processing by the LED drive control means may be executed.

  In order to solve the sixth problem, the present invention provides a twelfth gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
An instruction display (for example, an instruction monitor) including a plurality of 7-segment LEDs for notifying information on a stop operation of the variable display of the plurality of display columns;
7-segment LED driving means (for example, 7-segment LED driving processing) for driving the plurality of 7-segment LEDs;
An arithmetic processing unit (for example, main CPU 101) for performing an arithmetic process for controlling the driving operation of the plurality of 7-segment LEDs by the 7-segment LED driving unit;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A dynamic drive control is performed on the plurality of 7-segment LEDs, a predetermined read command (for example, an “LDW” command) is executed, and common selection data and cathode data are simultaneously output to the plurality of 7-segment LEDs. A gaming machine characterized by:

Further, in the twelfth gaming machine of the present invention, the arithmetic processing means includes:
A general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
An extension register (for example, a Q register) that stores data when the arithmetic processing is performed by the arithmetic processing means and that can specify a part of an address in the second storage means by the stored data;
The arithmetic processing unit executes a predetermined read instruction (for example, an “LDQ” instruction) capable of specifying an address in the second storage unit by using the extension register, so that the second storage unit can execute the read operation. And an address of a stop operation instruction information storage area (for example, a navigation data storage area) for storing information relating to a stop operation of the variable display of the plurality of display columns, and a display of the variable display of the plurality of display columns. Information regarding a stop operation may be stored in the stop operation instruction information storage area.

  According to the eleventh and twelfth gaming machines of the present invention having the above structure, the capacity of the processing program and tables managed by the main control circuit is reduced to reduce the free space of the ROM (first storage means) of the main control circuit. It is possible to increase the playability by utilizing the ROM free space corresponding to the increased capacity.

[13th gaming machine]
Conventionally, in a gaming machine having the above-described configuration, a gaming machine in which a game control board (main control board) controls a reel unit is known (for example, see Japanese Patent Application Laid-Open No. 2012-034914).

  By the way, in the rotation control of the reel (rotating body), the lack of a sense of stability in the rotation operation of the reel gives a player (especially a skilled person) a discomfort, and the interest of the game may be reduced from the discomfort. There is. In this case, the game store is disadvantaged, and the sale of the game machine itself may be affected.

  The present invention has been made in order to solve the seventh problem, and a seventh object of the present invention is to suppress the lack of stability in the rotation operation of the reel and not to give a player uncomfortable feeling. It is an object of the present invention to provide a gaming machine capable of doing so.

  In order to solve the seventh problem, the present invention provides a thirteenth gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
A setting switch (for example, a setting key type switch 54) for initializing a predetermined area of the second storage means,
The arithmetic processing means,
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
When the power is restored, the input state of the input port and the output state of the output port at the time of power failure are set, and when the display column was fluctuating at the time of power failure, it was stored in the second storage means. Clearing the fluctuation control management information (for example, reel control management information) of the display column at the time of power interruption and setting the information instructing the start of the fluctuation of the display column in the fluctuation control management information of the display column. (For example, game return processing).

Further, in the thirteenth gaming machine of the present invention, the arithmetic processing means includes:
When the setting switch is in the off state, the processing by the game return means is executed,
When the setting switch is in an on state, a predetermined area of the second storage means may be initialized without executing the processing by the game return means.

  According to the thirteenth gaming machine of the present invention having the above-described configuration, it is possible to suppress the lack of stability in the rotation operation of the reel (variable display operation of the display column) and prevent the player from feeling uncomfortable. .

[14th gaming machine]
Conventionally, in a gaming machine having the above-described configuration, a gaming machine capable of displaying a set value (1 to 6) by operating a setting change switch is known (for example, JP 2008-245704 A and JP 2008-245704 A). 2013-042870 gazette).

  By the way, conventionally, a gaming machine in which a set value cannot be confirmed while a game is being played in a gaming state advantageous to the player, for example, during a bonus game, during an ART game, or the like, is mainly used. In such a gaming machine, if a bonus game or an ART game is started immediately after a fraudulent act called “goto”, the fraudulent act cannot be confirmed, and there is a possibility that the game store will be disadvantaged. is there.

  The present invention has been made in order to solve the eighth problem, and an eighth object of the present invention is to provide a game apparatus in which a game is performed in a game state advantageous to a player. It is an object of the present invention to provide a gaming machine capable of confirming information such as a set value and suppressing illegal acts such as goto.

  In order to solve the eighth problem, the present invention provides a fourteenth gaming machine having the following configuration.

A setting switch arranged at a predetermined position inside the gaming machine body,
Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
Advantageous gaming means (for example, a bonus game described later) for executing a gaming state advantageous to the player based on the internal winning combination determined by the internal winning combination determining means;
A setting change confirming means (for example, S233 during medal reception / start check processing) capable of changing or confirming a setting value relating to a probability that an internal winning combination is determined according to an operation of the setting switch;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
Game start determination means (for example, medal reception / start check processing) for determining whether or not a game can be started,
The setting change confirmation unit can change a setting value related to a probability that an internal winning combination is determined according to an operation of the setting switch when power is turned on,
If the game start determining means determines that the game can be started and the setting switch is operated, the setting value relating to the probability that the internal winning combination is determined regardless of the game state is confirmed by the setting change. A gaming machine characterized in that it can be confirmed by processing by means.

  Further, in the fourteenth gaming machine of the present invention, when the gaming machine is powered on in a state where the setting switch is operated, the setting change confirmation means may be a predetermined storage area of the second storage means. May be initialized, the set value may be changed, and the changed set value may be stored in the second storage means.

  According to the fourteenth gaming machine of the present invention having the above configuration, for example, during a bonus game, during an ART game, or the like, even during a game being played in a game state advantageous to the player, the set value and the like can be changed. Information can be confirmed, and illegal acts such as goto can be suppressed.

[15th and 16th gaming machines]
Conventionally, in the gaming machine having the above-described configuration, there is known a gaming machine including a display device for displaying the number of inserted medals (for example, see Japanese Patent Application Laid-Open No. 1999-178983).

  By the way, conventionally, as a limitation peculiar to the above-described gaming machine, the program capacity of the main control circuit is limited to a small capacity according to rules. Further, in recent years, the capacity of the ROM of the main control circuit has been squeezed due to the complexity of gaming, and there has been a demand for a reduction in the capacity of processing programs and tables managed by the main control circuit.

  The present invention has been made to solve the ninth problem, and a ninth object of the present invention is to reduce the capacity of a processing program or a table managed by the main control circuit to reduce the capacity of the main control circuit. It is an object of the present invention to provide a gaming machine capable of increasing the free space in a ROM and using the free space in the ROM for the increased capacity to enhance the gaming ability.

  In order to solve the ninth problem, the present invention provides a fifteenth gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
Game medium detection means (for example, a medal sensor) for detecting a reception state of the game medium (for example, a medal sensor input state);
Whether or not the change state of the current reception state of the game medium detected by the game medium detection means is normal is determined by arithmetic processing based on the reception state of the game medium detected in the previous processing. (For example, S255 to S258 during a medal insertion check process).

  In the fifteenth gaming machine according to the present invention, the game medium receiving state determining means determines a normal value of the game medium receiving state that can be detected in a current process based on the game medium receiving state detected in a previous process. May be calculated by a logical operation, and the normal value may be compared with the current reception state of the game medium to determine whether or not the change state of the reception state of the game medium is normal. .

  Further, in the fifteenth gaming machine of the present invention, the game medium reception state determining means determines whether or not the change state of the reception state of the game medium is normal based on two bits in the 1-byte information. You may do so.

  In order to solve the ninth problem, the present invention provides a sixteenth gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
Display means (for example, a first LED to a third LED) for notifying information indicating the number of game media inserted in a display mode corresponding to the number of game media inserted;
Arithmetic processing means (for example, main CPU 101, medal insertion processing) for performing arithmetic processing for controlling the notification operation by the display means;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
Lighting control data for notifying information indicating the number of game media inserted in a display mode corresponding to the number of game media inserted is generated by a logical operation process based on the number of game media inserted. Gaming machine to do.

  Further, in the sixteenth gaming machine of the present invention, in the logical operation processing, the lighting control data of the gaming medium may be generated from 3-bit data of information in one byte.

  According to the fifteenth and sixteenth gaming machines of the present invention having the above structure, the capacity of the processing programs and tables managed by the main control circuit is reduced to increase the free space of the ROM of the main control circuit, and the increased capacity The gaming ability can be enhanced by utilizing the free space of the ROM.

[17th and 18th gaming machines]
Conventionally, in the gaming machine having the above-described configuration, there is known a gaming machine in which a main board (main control board) and a sub board (sub control board) are connected by communication, and a command is transmitted from the main board to the sub board. (See, for example, Japanese Patent No. 5725590).

  By the way, conventionally, communication between the main control board that controls the game and the sub control board that controls the performance is one-way communication from the main control board to the sub control board. There is a large gap between the startup time of the main control board and that of the sub control board. Therefore, there is a possibility that communication connection between the main control board and the sub-control board when the power is turned on becomes unstable.

  The present invention has been made to solve the above-described tenth problem, and a tenth object of the present invention is to provide a main control board (main control means) and a sub-control board (sub-control means) at power-on. It is an object of the present invention to provide a gaming machine capable of stably performing communication between the gaming machines.

  In order to solve the tenth problem, the present invention provides a seventeenth gaming machine having the following configuration.

A main control unit (for example, a main control circuit 90) for transmitting communication data relating to the game operation;
The main control means includes:
During the control process by the main control unit, an interrupt process is executed at a predetermined cycle, and when there is no communication data related to the game operation at the time of the execution of the interrupt process, an interrupt process execution unit that transmits a no-operation command (for example, , Interrupt processing),
Power recovery processing execution means (for example, power-on processing) for performing a predetermined power recovery processing at the time of power recovery,
The power-return processing executing means performs processing (for example, S7 and S8 during power-on processing) of waiting after the power-return processing is started until the interrupt processing can be executed by the interrupt processing executing means. Do
The gaming machine, wherein the interruption processing execution means executes the interruption processing and transmits the no-operation command to the sub control means when the standby by the power return processing execution means ends.

Further, in the seventeenth gaming machine of the present invention, the main control means:
A timer circuit (for example, timer circuit 113) for measuring the predetermined period;
An interrupt circuit (for example, an interrupt controller 112) for generating an interrupt signal for executing the interrupt processing based on a timeout signal of the timer circuit;
The power supply return processing execution means,
After setting an initial setting for generating the time-out signal in the predetermined period in the timer circuit, perform a process of waiting until the interrupt process can be performed by the interrupt process executing means,
The end of the standby may be determined based on whether or not the timer circuit generates the timeout signal.

  In order to solve the tenth problem, the present invention provides an eighteenth gaming machine having the following configuration.

Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
Communication data generation means (for example, setting change command generation storage processing and communication data storage processing) for generating command data related to a game operation;
Interrupt processing is executed at a predetermined cycle during the control processing by the arithmetic processing means, and when there is no command data related to the game operation at the time of executing the interrupt processing, interrupt processing executing means for transmitting a no-operation command (for example, , Interrupt processing),
Power-return processing executing means (for example, power-on processing) for executing a predetermined power-return processing when the power is returned;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The power-return processing executing means performs processing (for example, S7 and S8 during power-on processing) of waiting after the power-return processing is started until the interrupt processing can be executed by the interrupt processing executing means. Do
The interrupt processing execution means, at the end of the standby by the power return processing execution means, executes the interrupt processing and transmits the no-operation command,
The arithmetic processing means,
A plurality of general-purpose registers in which a plurality of types of data are stored when the arithmetic processing is performed by the arithmetic processing unit,
The command data includes a command type, a plurality of communication parameters, and a sum value,
The plurality of communication parameters are respectively assigned to the plurality of general-purpose registers,
The communication data generating means,
After setting a communication parameter in the general-purpose register assigned to the communication parameter according to the command type of the command data, the communication parameter set in the general-purpose register is stored in a predetermined storage in the second storage means. Area (for example, a temporary storage area for communication data),
Even if there is a communication parameter that is not used based on the command type of the command data among the plurality of communication parameters, the data stored in the general-purpose register associated with the unused communication parameter is used as the communication parameter. Stored in the predetermined storage area as
A gaming machine, wherein a sum value of the command data is generated based on the command type and data stored in the general-purpose register assigned to a communication parameter.

Further, the eighteenth gaming machine of the present invention includes a power supply monitoring means (for example, a power supply monitoring port) for monitoring a state of a power supply voltage,
The arithmetic processing means,
If the state of the power supply voltage is not stable, wait until the state of the power supply voltage is stabilized,
Under the condition that the state of the power supply voltage is stable, the timer circuit, the serial communication circuit, and the random number circuit of the arithmetic processing unit are initialized, and then the second memory unit is initialized using a predetermined area. 2 Check whether the storage means is normal,
The no-operation command may be transmitted on condition that the second storage unit is normal.

  According to the seventeenth and eighteenth gaming machines of the present invention having the above configuration, communication between the main control board and the sub control board at the time of turning on the power can be stably performed.

[19th and 20th gaming machines]
Conventionally, in the gaming machine having the above-described configuration, for example, a gaming machine that performs control called pull-in control of a winning symbol on a reel or control called kicking control of a winning symbol on a reel based on a lottery result is known. (See, for example, JP-A-2002-219213).

  By the way, conventionally, as a limitation peculiar to the above-described gaming machine, the program capacity of the main control circuit is limited to a small capacity according to rules. Furthermore, in recent years, as the playability has become complicated and the symbol combination patterns of winning combinations (winning combinations) have increased, the RAM capacity of the main control circuit has been reduced, and the efficiency of the processing executed by the main control circuit has been improved. There is a need to develop a technology that can effectively utilize the limited RAM capacity of the main control circuit.

  The present invention has been made to solve the above-described eleventh problem, and an eleventh object of the present invention is to improve the efficiency of processing executed by the main control circuit and to make the RAM capacity of the main control circuit effective. It is to provide a gaming machine that can be utilized.

  In order to solve the eleventh problem, the present invention provides a nineteenth gaming machine having the following configuration.

Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
An internal lottery means (for example, an internal lottery process) for determining flag status information (for example, a hit request flag status) relating to an internal winning combination with a predetermined probability;
An internal winning combination generating unit (for example, S321 during a symbol setting process) for generating an internal winning combination from the flag status information acquired by the internal lottery unit;
The internal winning combination, the flag data corresponding to the internal winning combination, and the storage relationship data specifying the storage location of the flag data in the second storage device are defined, and the flag stored in the first storage device is defined. Flag table developing means (for example, S324 during the symbol setting process) for developing a data table (for example, a hit request flag table) in the second storage means;
A flag storage area designating means (for example, S329 during symbol setting processing) which is arranged in the second storage means and designates an address of a flag data storage area (for example, a hit request flag storage area) for storing the flag data; ,
Flag data for transferring and storing the flag data corresponding to the internal winning combination generated by the internal winning combination generating means from the flag table to the flag data storage area based on the corresponding storage destination data Storage means (for example, S330 during the symbol setting process).

  In the nineteenth gaming machine of the present invention, the arithmetic processing means calculates on-bit information indicating the storage destination data of the flag data table, and sets the on-bit information as the transfer target on-bit information. The flag data may be transferred to the flag data storage area.

  In order to solve the eleventh problem, the present invention provides a twentieth gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
An expansion register (for example, a Q register) that stores data when the arithmetic processing is performed by the arithmetic processing means and that can specify a part of an address in the first storage means or the second storage means by the stored data. )When,
An internal lottery means (for example, an internal lottery process) for determining flag status information (for example, a hit request flag status) relating to an internal winning combination with a predetermined probability;
An internal winning combination generating unit (for example, S321 during a symbol setting process) for generating an internal winning combination from the flag status information acquired by the internal lottery unit;
A winning flag data table (e.g., a hit request request) that defines the correspondence between the internal winning combination, the corresponding winning flag data, and the storage location data that specifies the storage location of the winning flag data in the second storage means. A winning flag table developing means (for example, S324 during the symbol setting process) for developing the flag table) in the second storage means;
By executing a predetermined read command (for example, an “LDQ” command) capable of specifying an address in the second storage means using the extension register, the predetermined arrangement is performed in the second storage means and the winning is performed. Winning flag storage area designating means (for example, S329 during symbol setting processing) for designating an address of a winning flag data storage area (for example, a hit request flag storage area) for storing flag data;
The winning flag data corresponding to the internal winning combination generated by the internal winning combination generating means is transferred from the winning flag table to the winning flag data storage area based on the corresponding storage location data and stored. Winning flag data storage means (for example, S330 during the symbol setting process),
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal lottery unit and detection of a stop operation by the stop operation detection unit;
When the variable display of the plurality of display columns is stopped by the stop control means, a combination of symbols corresponding to the internal winning combination is stopped and displayed on a determination line set across the plurality of display columns. Winning combination determination means (for example, a winning search process) for determining whether or not
By executing the predetermined read command, a prize flag data storage area (e.g., a prize flag data storage area for storing prize flag data corresponding to the combination of the symbols stopped and displayed on the determination line and arranged in the second storage means) Winning flag storage area designating means (for example, S648 during symbol code acquisition processing) for designating an address of a winning operation flag storage area;
By executing the predetermined read command, an address of a symbol code storage area for storing symbol code data corresponding to a symbol combination arranged in the second storage means and stopped and displayed on the determination line is designated. And a symbol code storage area setting means (for example, S650 during a symbol code acquisition process).

  Further, in the twentieth gaming machine of the present invention, a part of the address that can be specified by the extension register may be an upper address value constituting the address.

  According to the nineteenth and twentieth gaming machines of the present invention having the above configuration, the efficiency of the processing executed by the main control circuit can be increased, and the RAM (second storage means) capacity of the main control circuit can be effectively utilized. .

[21st and 22nd gaming machines]
Conventionally, in a gaming machine having the above-described configuration, stop control of variable display of a reel symbol is performed based on an internal winning combination and a player's stop operation, a winning determination is performed based on a combination of symbols, and a hopper is determined based on a result of the winning determination. A gaming machine that controls a medal payout device to perform a payout control of a medal is known (for example, see Japanese Patent Application Laid-Open No. 2008-119498).

  By the way, conventionally, as a limitation peculiar to the above-described gaming machine, the program capacity of the main control circuit is limited to a small capacity according to rules. Further, in recent years, the capacity of the ROM of the main control circuit has been squeezed due to the complexity of gaming, and there has been a demand for a reduction in the capacity of processing programs and tables managed by the main control circuit.

  The present invention has been made to solve the twelfth problem, and a twelfth object of the present invention is to reduce the capacity of a processing program and a table managed by the main control circuit to reduce the capacity of the main control circuit. It is an object of the present invention to provide a gaming machine capable of increasing the free space in a ROM and using the free space in the ROM for the increased capacity to enhance the gaming ability.

  In order to solve the twelfth problem, the present invention provides a twenty-first gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the stop operation of the display column by the stop control means;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
An extension register (for example, a Q register) which stores data when the arithmetic processing is performed by the arithmetic processing means and which can designate a part of an address in the second storage means by the stored data;
By executing a predetermined read instruction (for example, an “LDQ” instruction) capable of specifying an address in the second storage unit using the extension register, the detection result of the stop operation by the stop operation detecting unit is obtained. A stop operation detection result obtaining unit to obtain (for example, S714 during a reel stop control process);
When the stop operation detecting means detects a player's stop operation on a predetermined display row, the predetermined read command is executed, whereby the predetermined read row is arranged in the second storage means and A stop control data storage area setting means (for example, a source code “LDQ IX, wR1_CTRL- (wR2_CTRL-wR1_CTRL)” in FIG. 139) that specifies an address of a stop control data storage area that stores stop control data for variable display. A gaming machine comprising:

  In the twenty-first gaming machine of the present invention, a part of the address that can be specified by the extension register may be an upper address value constituting the address.

  In order to solve the twelfth problem, the present invention provides a twenty-second gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
When a plurality of types of internal winning combinations are determined by the internal winning combination determining means, if a plurality of types of symbols corresponding to the plurality of types of internal winning combinations are respectively set, the setting is performed across the plurality of display columns. Priority stop symbol determination means (for example, a pull-in priority acquisition process) for determining a combination of symbols to be preferentially stopped and displayed on the determined determination line;
Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the operation of stopping the display column by the stop control means and the operation of determining the combination of symbols to be stopped and displayed by the priority stop symbol determining means;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
An extension register (for example, a Q register) which stores data when the arithmetic processing is performed by the arithmetic processing means and which can designate a part of an address in the second storage means by the stored data;
By executing a predetermined read instruction (for example, an “LDQ” instruction) capable of specifying an address in the second storage unit using the extension register, the detection result of the stop operation by the stop operation detecting unit is obtained. A stop operation detection result obtaining unit to obtain (for example, S714 during a reel stop control process);
When the stop operation detecting means detects a player's stop operation on a predetermined display row, the predetermined read command is executed, whereby the predetermined read row is arranged in the second storage means and the predetermined display row is displayed. A stop control data storage area setting means (for example, a source code “LDQ IX, wR1_CTRL- (wR2_CTRL-wR1_CTRL)” in FIG. 139) that specifies an address of a stop control data storage area that stores stop control data for variable display.
In the process of determining a combination of symbols to be stopped and displayed on the determination line by the priority stop symbol determination means, a comparison determination instruction, a designation instruction of a jump destination address of the process, and a jump operation instruction of the process are one. By executing a predetermined determination instruction (for example, a “JCP” instruction) that can be executed by the instruction, a specific combination of symbols corresponding to the internal winning combination to be determined is displayed in a specific display column (for example, It is determined whether the stop symbol on the determination line on the right reel 3R) includes an arbitrary predetermined symbol combination (for example, an “ANY” symbol), and the internal symbol combination to be determined is determined. When it is determined that the predetermined symbol combination is included in the corresponding symbol combination, a stop display of the symbol combination corresponding to the internal winning combination to be determined is displayed. Gaming machine, characterized in that it comprises any combination corresponding processing means for locking (e.g., S683 in attraction priority acquisition processing), the.

  Also, in the twenty-second gaming machine of the present invention, a part of the address that can be specified by the extension register may be an upper address value constituting the address.

  According to the twenty-first and twenty-second gaming machines of the present invention having the above structure, the capacity of the ROM and the like in the main control circuit is increased by reducing the capacity of the processing programs and tables managed by the main control circuit. The gaming ability can be enhanced by utilizing the free space of the ROM.

[23rd to 25th gaming machines]
2. Description of the Related Art Conventionally, in a gaming machine having the above-described configuration, there has been known a gaming machine that performs a symbol stop control using a pull-in priority table at the time of symbol stop control (see, for example, JP-A-2007-175450).

  By the way, conventionally, as a limitation peculiar to the above-described gaming machine, the program capacity of the main control circuit is limited to a small capacity according to rules. Further, in recent years, the capacity of the ROM of the main control circuit has been squeezed due to the complexity of gaming, and there has been a demand for a reduction in the capacity of processing programs and tables managed by the main control circuit.

  The present invention has been made in order to solve the thirteenth problem, and a thirteenth object of the present invention is to reduce the capacity of a processing program and a table managed by the main control circuit to reduce the capacity of the main control circuit. It is an object of the present invention to provide a gaming machine capable of increasing the free space in a ROM and using the free space in the ROM for the increased capacity to enhance the gaming ability.

  In order to solve the thirteenth problem, the present invention provides a twenty-third gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
When a plurality of types of internal winning combinations are determined by the internal winning combination determining means, if a plurality of types of symbols corresponding to the plurality of types of internal winning combinations are respectively set, the setting is performed across the plurality of display columns. Priority stop symbol determination means (for example, a pull-in priority acquisition process) for determining a combination of symbols to be preferentially stopped and displayed on the determined determination line;
An arithmetic processing unit (for example, the main CPU 101) for performing an arithmetic process for controlling an operation of determining a symbol combination to be preferentially stopped and displayed by the priority stop symbol determining unit;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
An extension register (for example, a Q register) that stores data when the arithmetic processing is performed by the arithmetic processing means and that can specify a part of an address in the second storage means by the stored data. ,
In the process of determining a combination of symbols to be preferentially stopped and displayed by the priority stop symbol determination means,
The arithmetic processing means,
By executing a predetermined read instruction (for example, an “LDQ” instruction) capable of specifying an address in the second storage means using the extension register, the read instruction is arranged in the second storage means and Winning flag storage area designating means (for example, S686 during a pull-in priority acquisition process) for designating an address of a winning flag data storage area (for example, a hit request flag storage area) for storing winning flag data corresponding to a winning combination;
By executing the predetermined read command, a prize flag data storage area (e.g., a prize flag data storage area for storing prize flag data corresponding to the combination of the symbols stopped and displayed on the determination line and arranged in the second storage means) Winning flag storage area designating means (for example, S686 during a pull-in priority acquisition process) for designating an address of a winning operation flag storage area;
A gaming machine comprising: a logical product calculating means (for example, S686 during a pull-in priority acquisition process) for performing a logical product operation of the winning flag data and the corresponding winning flag data.

In the twenty-third gaming machine of the present invention, in the processing for determining a symbol combination to be preferentially stopped and displayed by the priority stop symbol determining means, a symbol combination corresponding to the internal winning combination to be determined is determined. When a predetermined symbol combination (for example, the role of “ANY”) in which the stop symbol on the determination line in the specific display column (for example, the right reel 3R) currently being determined is arbitrary is included,
The arithmetic processing means includes an address specifying process of the winning flag data storing area by the winning flag storing area specifying means, an address specifying process of the winning flag data storing area by the winning flag storing area specifying means, and the logical product operation. The logical product operation processing by the means may not be executed.

  In order to solve the thirteenth problem, the present invention provides a twenty-fourth gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
When a plurality of types of internal winning combinations are determined by the internal winning combination determining means, if a plurality of types of symbols corresponding to the plurality of types of internal winning combinations are respectively set, the setting is performed across the plurality of display columns. Priority stop symbol determination means (for example, a pull-in priority acquisition process) for determining a combination of symbols to be preferentially stopped and displayed on the determined determination line;
An arithmetic processing unit (for example, the main CPU 101) for performing an arithmetic process for controlling an operation of determining a symbol combination to be preferentially stopped and displayed by the priority stop symbol determining unit;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
An expansion register (for example, a Q register) that stores data when the arithmetic processing is performed by the arithmetic processing means and that can specify a part of an address in the first storage means or the second storage means by the stored data. ) And
In the process of determining a combination of symbols to be preferentially stopped and displayed by the priority stop symbol determination means,
The arithmetic processing means,
By executing a predetermined read instruction (for example, an “LDQ” instruction) capable of specifying an address in the second storage means using the extension register, the read instruction is arranged in the second storage means and Winning flag storage area designating means (for example, S686 during a pull-in priority acquisition process) for designating an address of a winning flag data storage area (for example, a hit request flag storage area) for storing winning flag data corresponding to a winning combination;
By executing the predetermined read command, a prize flag data storage area (e.g., a prize flag data storage area for storing prize flag data corresponding to the combination of the symbols stopped and displayed on the determination line and arranged in the second storage means) Winning flag storage area designating means (for example, S686 during a pull-in priority acquisition process) for designating an address of a winning operation flag storage area;
AND operation means for performing an AND operation of the winning flag data and the corresponding winning flag data (for example, S686 during a pull-in priority acquisition process);
By executing the predetermined read command, a priority data table obtaining means (for example, a pull-in priority) that obtains a data table defining the priority of the symbol combination to be stopped and displayed among the plurality of types of symbol combinations (S687 during acquisition processing).

Further, in the twenty-fourth gaming machine of the present invention, in the process of determining a symbol combination to be preferentially stopped and displayed by the priority stop symbol determining means, a symbol combination corresponding to the internal winning combination to be determined is determined. When a predetermined symbol combination (for example, the role of “ANY”) in which the stop symbol on the determination line in the specific display column (for example, the right reel 3R) currently being determined is arbitrary is included,
The arithmetic processing means includes an address specifying process of the winning flag data storing area by the winning flag storing area specifying means, an address specifying process of the winning flag data storing area by the winning flag storing area specifying means, and the logical product operation. The logical product operation processing by the means may not be executed.

  In order to solve the thirteenth problem, the present invention provides a twenty-fifth gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
Error detecting means for determining whether an illegal hit error has occurred (eg, illegal hit check processing);
An arithmetic processing unit (for example, main CPU 101) for performing arithmetic processing for controlling a determination operation by the error detection unit;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A general-purpose register in which data is stored when the arithmetic processing is performed by the arithmetic processing means;
An extension register (for example, a Q register) that stores data when the arithmetic processing is performed by the arithmetic processing means and that can specify a part of an address in the second storage means by the stored data. ,
In the error detection means, in the determination processing whether the occurrence of an illegal hit error,
The arithmetic processing means,
By executing a predetermined read instruction (for example, an “LDQ” instruction) capable of specifying an address in the second storage means using the extension register, the plurality of read instructions are arranged in the second storage means and A prize flag for specifying an address of a prize flag data storage area (for example, a prize operation flag storage area) for storing prize flag data corresponding to a combination of symbols stopped and displayed on the determination line set across the display column of Storage area designating means (for example, S781 during illegal hit check processing);
AND operation means for performing an AND operation of the winning flag data stored in the winning flag data storage area and the corresponding winning flag data indicating the internal winning combination (for example, S784 during illegal hit check processing) When,
Error determining means for determining whether or not an illegal hit error has occurred based on the operation result of the AND operation means (for example, S785 during the illegal hit check process);
A gaming machine, wherein a configuration of a winning flag data storage area (for example, a hit request flag storage area) in which the winning flag data is stored is the same as a configuration of the winning flag data storage area.

  In the twenty-fifth gaming machine of the present invention, a part of the address that can be specified by the extension register may be an upper address value constituting the address.

Further, in the twenty-fifth gaming machine of the present invention, the arithmetic processing means has an error processing means for performing error processing when the error detection means determines that there is an illegal hit error,
The error processing means may visually notify the illegal hit error and stop the game until the illegal hit error is released.

  According to the twenty-third to twenty-fifth gaming machines of the present invention having the above-described configuration, the capacity of the ROM and the like in the main control circuit is increased by reducing the capacity of the processing programs and tables managed by the main control circuit. The gaming ability can be enhanced by utilizing the free space of the ROM.

[26th gaming machine]
Conventionally, in a gaming machine having the above-described configuration, a gaming machine that transmits command data from a game control board (main control board) to an effect control board (sub-control board) is known (for example, Japanese Patent Application Laid-Open No. 2013-027655). And JP-A-2014-033751).

  By the way, in recent years, with the diversification of playability, there is a tendency that processing related to playability in the effect control by the sub-control circuit increases. As a result, fraudulent acts called "goto", which falsify communication data transmitted from the main control circuit to the sub-control circuit, have occurred, and have caused damage to game shops. On the other hand, conventionally, as proposed in, for example, JP-A-2014-033751 or the like, a countermeasure for performing goto prevention processing on transmission data in a main control circuit is also implemented. However, the problem that the program capacity of the main control circuit is squeezed due to the addition of the goto prevention processing occurs.

  The present invention has been made in order to solve the fourteenth problem, and a fourteenth object of the present invention is to provide a transmission data without performing a fraud (goto) prevention process and suppress fraudulent acts. An object of the present invention is to provide a gaming machine capable of eliminating pressure on a program capacity of a main control circuit due to fraud prevention processing.

  In order to solve the fourteenth problem, the present invention provides a twenty-sixth gaming machine having the following configuration.

A data transmitting unit (for example, a main control circuit 90) for transmitting communication data relating to the gaming operation;
Communication data generation means for generating the communication data (for example, communication data storage processing);
An arithmetic processing unit (for example, a main CPU 101) for performing an arithmetic process for controlling an operation of generating communication data by the communication data generating unit;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The arithmetic processing means,
A plurality of general-purpose registers in which a plurality of types of data are stored when the arithmetic processing is performed by the arithmetic processing unit,
The arithmetic processing means,
In the communication data generation processing by the communication data generation means,
Allocating a plurality of types of communication parameters constituting the communication data to the plurality of general-purpose registers,
Of the plurality of types of communication parameters constituting the communication data, a communication parameter based on the type of the communication data is set in a corresponding general-purpose register among the plurality of general-purpose registers,
Storing the communication parameters set in the general-purpose register in a predetermined storage area (temporary communication data storage area) in the second storage means;
Among the plurality of types of communication parameters, data stored in a general-purpose register associated with an unused communication parameter at the time of generating communication data is stored in the predetermined storage area as a communication parameter,
A gaming machine, wherein a sum value of the communication data is generated based on data set in the plurality of general-purpose registers according to the plurality of types of communication parameters.

  Further, in the twenty-sixth gaming machine of the present invention, the communication data generation means, when there is no free space in a predetermined storage area in the second storage means, sets the communication data set in the plurality of general-purpose registers. The communication data generation process may be terminated without storing the parameters in a predetermined storage area in the second storage means.

  According to the twenty-sixth gaming machine of the present invention having the above-described structure, it is possible to suppress improper acts without performing improper prevention processing on transmission data (communication data), and to reduce the program capacity of the main control circuit by the improper prevention processing. Pressure can be eliminated.

[27th gaming machine]
Conventionally, in a gaming machine having the above-described configuration, a gaming machine having a function of updating the number of credits according to the number of medals paid out under the control of a main control circuit has been known (for example, JP-A-2009-2009). No. 077977).

  By the way, conventionally, in a game during an ART or a bonus, the frequency of payout of medals increases, but at this time, the payout interval of one medal unit is often controlled uniformly (constantly). In this case, useless waiting time occurs in the medal payout period. Therefore, for example, in a long game such as ART, the game period becomes uselessly long, which may be a mental burden for the player.

  The present invention has been made to solve the fifteenth problem, and a fifteenth object of the present invention is to reduce unnecessary waiting time and reduce a mental burden on a player during a medal payout period. It is to provide a gaming machine capable of.

  In order to solve the fifteenth problem, the present invention provides a twenty-seventh gaming machine having the following configuration.

A loading operation detecting means (for example, a BET switch 77) for detecting a loading operation of a game medium;
A start operation detecting means (for example, a start switch 79) for detecting a start operation by a player after the input operation is detected by the input operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
A variable display unit (for example, three reels 3L, 3C, 3R) that includes a plurality of display columns and that variably displays symbols provided in each display column based on detection of a start operation by the start operation detection unit;
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
A stop control unit (for example, a reel stop control process) for stopping the fluctuation display of the symbol based on a determination result of the internal winning combination determination unit and detection of a stop operation by the stop operation detection unit;
When the variable display of the plurality of display columns is stopped by the stop control means, a symbol corresponding to an internal winning combination related to the payout of the game medium, on a determination line set across the plurality of display columns. A privilege grant determination means (for example, a winning search process) for determining whether or not the combination of
A game medium payout unit that pays out the game medium when it is determined that the combination of the symbols corresponding to the internal winning combination related to the payout of the game medium is stopped and displayed on the determination line by the privilege provision determination unit (for example, , Winning check / medal payout processing),
A game medium storing means (for example, a credit function) for storing the game medium,
Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the payout operation of the game medium by the game medium payout means,
The arithmetic processing means,
It is determined that the combination of symbols corresponding to the internal winning combination related to the payout of the game medium is stopped and displayed on the determination line by the privilege provision determination means, and the game medium stored in the game medium storage means If the stored number of the game media is less than the upper limit value, a game medium adding means (for example, S805 during a prize check / medal payout process) for adding 1 to the stored number of the game media;
After the game medium is added by 1 to the number of stored game media by the game medium addition means, the symbol is added when a symbol combination corresponding to an internal winning combination related to the payout of the game medium is stopped and displayed. Payout completion determination means (for example, S807 during a prize check / medal payout process) for determining whether or not the payout of the total payout number of the game media has been completed;
When the payout completion determining means determines that the payout of all the payout numbers of the game media has not been completed, a weight generating means (for example, a prize check and a prize check) for generating a weight for invalidating a game-related operation for a predetermined period of time. S808) during a medal payout process.

Further, in the twenty-seventh gaming machine of the present invention, the arithmetic processing means has an interrupt processing executing means for executing an interrupt processing at a predetermined cycle,
In the weight where the operation related to the game by the weight generating means is invalidated, the interrupt processing by the interrupt processing executing means may be executed a predetermined number of times.

  According to the twenty-seventh gaming machine of the present invention having the above-described configuration, in the medal (game medium) payout period, useless waiting time can be reduced, and the mental burden on the player can be reduced.

[28th and 29th gaming machines]
Conventionally, in the gaming machine having the above-described configuration, a gaming machine in which a lottery table for determining an internal winning combination and an AT game is stored in a ROM has been known (for example, see Japanese Patent Application Laid-Open No. 2009-125559).

  By the way, in the gaming machine described in JP-A-2009-125559, the lottery table and the lottery processing program of the AT game are stored in the ROM provided on the sub-control board having a sufficient storage capacity. However, for the reasons specific to the gaming machine industry in recent years, it is necessary to store a table and a program relating to the lottery of the AT game in the ROM provided on the main control board. For this reason, the ROM capacity of the main control board, which is limited to a small capacity, is squeezed.

  The present invention has been made to solve the sixteenth problem, and a sixteenth object of the present invention is to reduce the amount of data used in the processing of the main control circuit and to reduce the free space in the ROM of the main control circuit. An object of the present invention is to provide a gaming machine capable of increasing the capacity.

  In order to solve the sixteenth problem, the present invention provides a twenty-eighth gaming machine having the following configuration.

Start operation detecting means (for example, a start switch 79) for detecting a start operation by the player;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
Privilege grant determining means (for example, CT during CT lottery processing) that determines, by lottery, whether or not to grant a gaming state advantageous to the player as a privilege based on the internal winning combination determined by the internal winning combination determining means. When,
A lottery table (for example, a CT winning lottery table during CT) referred to by the privilege provision determining means,
In the lottery table,
Determination data (for example, a determination bit) for specifying a type of the internal winning combination to be a lottery target, and a lottery value of the internal winning combination to be determined by the determination data are specified;
The lottery value of the internal winning combination which is out of the lottery target is not defined,
A value other than 0 is defined as a lottery value of the internal winning combination of the lottery target having a winning probability of less than 100%, and 0 is specified as a lottery value of the internal winning combination of the lottery target having a winning probability of 100%. A gaming machine characterized by being performed.

Further, in the twenty-eighth gaming machine of the present invention, the privilege provision determining means may include:
Get 1 byte random value from soft latch random number,
A lottery using the obtained random number value and the lottery value may be performed to determine whether or not to provide a gaming state advantageous to the player as a privilege.

  In order to solve the sixteenth problem, the present invention provides a twenty-ninth gaming machine having the following configuration.

Start operation detecting means (for example, a start switch 79) for detecting a start operation by the player;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
Privilege grant determining means (for example, CT during CT lottery processing) that determines, by lottery, whether or not to grant a gaming state advantageous to the player as a privilege based on the internal winning combination determined by the internal winning combination determining means. When,
A lottery table (for example, a CT winning CT lottery table) which is referred to by the privilege granting determination means and provided for each type of the internal winning combination;
A lottery table selection table (for example, a winning combination table selection relative table) for selecting the lottery table associated with the currently determined internal winning combination,
In the lottery table selection table,
For each type of the internal winning combination, it is possible to determine whether or not the internal winning combination of the type is a lottery target, and to designate an arrangement destination of the lottery table associated with the internal winning combination of the type. The selection value is specified,
The selection value of the internal winning combination that is not to be subjected to the lottery is defined as 0 in which the lottery result by the privilege provision determining means is treated as a loss,
A game machine characterized in that data other than 0 is defined in the selection value of the internal winning combination to be a lottery target.

  In the twenty-ninth gaming machine of the present invention, the selection value in the lottery table selection table may be a relative value up to the selected lottery table, and the relative value may be a one-byte value. Good.

  According to the twenty-eighth and twenty-ninth gaming machines of the present invention having the above-described configuration, it is possible to reduce the amount of data used in the processing of the main control circuit and increase the free space of the ROM of the main control circuit.

[30th gaming machine]
Conventionally, in a gaming machine having the above-described configuration, a program and a table are respectively arranged in fixed areas in a ROM mounted on a main control board (see, for example, JP-A-2012-110635).

  By the way, as in the gaming machine described in JP-A-2012-110635, programs and tables that can be arranged in the ROM of the main control board are restricted by rules of the gaming machine industry, and the ROM of the main control board is limited. The extensibility of programs and tables within the system is significantly poor.

  The present invention has been made to solve the seventeenth problem, and a seventeenth object of the present invention is to provide a gaming machine capable of enhancing the expandability of programs and tables in a ROM of a main control board. It is to provide.

  In order to solve the seventeenth problem, the present invention provides a thirtieth gaming machine having the following configuration.

Arithmetic processing means (for example, main CPU 101) for performing arithmetic processing for controlling the game operation;
First storage means (for example, main ROM 102) in which information necessary for the execution of the arithmetic processing by the arithmetic processing means is stored;
A second storage unit (for example, a main RAM 103) in which information necessary for execution of the arithmetic processing by the arithmetic processing unit is stored;
The first storage means includes a game storage area (for example, a game ROM area) in which information necessary for executing processing related to the playability of a game performed by a player is stored; A non-specified storage area (for example, a non-specified ROM area) which is arranged in an area different from the area and stores information necessary for executing processing not related to the playability of the game performed by the player; A gaming machine characterized by the following.

  In the thirtieth gaming machine of the present invention, the second storage means temporarily stores information necessary for executing a process related to the playability of a game performed by a player. A game temporary storage area (for example, a game RAM area) including a work area and a game stack area, and a playability of a game which is arranged in an area different from the game temporary storage area and executed by a player. And a non-standard temporary storage area (eg, a non-standard RAM area) including a non-standard work area and a non-standard stack area for temporarily storing information necessary for execution of processing not related to Is also good.

Further, in the thirtieth gaming machine of the present invention, the arithmetic processing means has a stack pointer as a dedicated register,
The arithmetic processing means,
When executing a program stored in the non-defined storage area of the first storage means, an address of a non-defined stack area of the second storage means is set to the stack pointer;
When ending the program stored in the non-defined storage area of the first storage means, the game storage of the second storage means saved when the program stored in the non-defined storage area is executed. An address of a stack area may be set in the stack pointer to return to a program stored in the game storage area of the first storage area.

  According to the thirtieth gaming machine of the present invention having the above configuration, the expandability of the programs and tables in the ROM of the main control board can be improved.

[The 31st gaming machine]
Conventionally, in the gaming machine having the above-described configuration, in order to use the information of the internal winning combination determined by the main control circuit in the effect control of the sub-control circuit, the internal winning combination is converted into a sub-flag that categorizes the type in a group unit. A gaming machine having a function is known (for example, see Japanese Patent Application Laid-Open No. 2010-051471).

  In the gaming machine described in JP-A-2010-051471, the conversion table and the conversion processing program for converting the internal winning combination into the sub-flag are stored in the ROM provided on the sub-control board having a sufficient storage capacity. Have been. However, for the reasons specific to the gaming machine industry in recent years, information on the internal winning combination determined by the main control circuit cannot be transmitted to the sub control circuit, and a conversion table and a conversion processing program related to the sub flag are also provided on the main control board. Must be stored in the ROM. In this case, the ROM capacity of the main control board, which is limited to a small capacity, is pressed down by these tables and programs. Therefore, there is a need for the development of a technology capable of suppressing the pressure on the ROM capacity of the main control board by the conversion table and the conversion processing program related to the sub-flag and efficiently responding to changes in the model, plan, specifications, etc. of the gaming machine. ing.

  The present invention has been made in order to solve the eighteenth problem, and an eighteenth object of the present invention is to suppress the pressure on the ROM capacity of the main control board, and to reduce the model, plan, and specifications of the gaming machine. It is an object of the present invention to provide a gaming machine capable of efficiently responding to changes such as the above.

  In order to solve the eighteenth problem, the present invention provides a thirty-first gaming machine having the following configuration.

Start operation detecting means (for example, a start switch 79) for detecting a start operation by the player;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
First sub-flag conversion means (for example, sub-flag conversion processing) for converting the internal winning combination determined by the internal winning combination determination means into a first sub-flag (for example, sub-flag) with reference to a conversion table;
The first sub-flag obtained by the conversion process by the first sub-flag conversion means is converted to a second sub-flag (for example, sub-flag EX) by lottery with reference to a lottery table (for example, various flag conversion lottery tables). Second flag conversion means (for example, flag conversion processing)
In the conversion table, a correspondence relationship between the internal winning combination, control status data associated with the internal winning combination, and the first sub-flag is defined, and for the first sub-flag of the same type, The control status data of the same value is allocated,
A gaming machine wherein the lottery by the second sub-flag conversion means is performed based on the control status data.

Further, in the gaming machine of the present invention, the game machine further includes a data transmitting unit for transmitting command data relating to the gaming operation,
The data transmitting unit may transmit the first sub-flag as a communication parameter of command data when the start operation detecting unit detects the start operation.

  According to the thirty-first game machine of the present invention having the above-described configuration, it is possible to suppress the pressure on the ROM capacity of the main control board and efficiently respond to changes in the model, plan, specifications, and the like of the game machine.

[32nd to 35th gaming machines]
Conventionally, as a gaming machine having the above-described AT function, in order to win a small role (a so-called pressing order small role) in which the stop order of the stop button is correct, a push corresponding to the pressing order small role won by the player is performed. A gaming machine that notifies the order is known (for example, refer to JP-A-2002-85629). According to such a gaming machine, the number of game media can be easily increased even if the player does not have a special gaming technique such as eye-catching, and the interest of the game can be enhanced.

  However, in the above-described gaming machine, the notification period (the operation period of the AT function) is predetermined (150 games (times) in Japanese Patent Application Laid-Open No. 2002-85629). Could not give the player the expectation of the continuation of the notification period. Further, even if the notification period (the number of notification games) can be set to be long in advance, the game during the notification period becomes monotonous (mere work) only by the notification for winning the small push order, and Interest may decrease.

  The present invention has been made in order to solve the nineteenth problem, and a nineteenth object of the present invention is to provide a gaming machine having an AT function to expect a player to continue the notification period. And suppressing a decrease in interest in the game during the notification period.

  In order to solve the nineteenth problem, the present invention provides a thirty-second gaming machine having the following configuration.

A notifying unit (for example, the display device 11) for notifying information about the game;
A notification game control means (for example, a main control circuit 90) for controlling a game in a notification game state (for example, an ART state) in which information advantageous to the player can be reported by the notification means;
Parameter updating means (for example, S2331 and S2332 during the battle B damage reflection process) for updating a parameter (for example, a friend HP) related to the end trigger of the notification game state,
The notification game state can be a first notification game state in which the parameter update unit does not update the parameter (for example, an enemy-free state during ART) and the parameter update unit can update the parameter. And a second notification game state (for example, a battle B state) in which whether or not to continue the notification game state is determined for each unit game.
When it is determined that the notification game state is to be continued in at least one unit game in the game period of the second notification game state, the parameter update unit does not update the parameter, and the notification game After the end of the gaming period of the second gaming machine state, the control means shifts the gaming state from the second notification gaming state to the first notification gaming state,
If it is not determined to continue the notification game state in all the unit games in the game period of the second notification game state, the parameter updating unit updates the parameter,
As a result of updating the parameter by the parameter updating unit, when the updated parameter value reaches a predetermined value, the notification game control unit ends the notification game state, and updates the parameter value. If the game does not reach the predetermined value, the notification game control means enables the game in the second notification game state to be executed again.

Further, in the thirty-second gaming machine of the present invention, an internal winning combination determining means (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability when a game start operation is detected. Prepared,
In the game in the second notification gaming state, when a specific internal winning combination (for example, a rare combination) is determined by the internal winning combination determination means, the first notification is performed from the second notification gaming state. When the transition to the gaming state is determined and the internal winning combination other than the specific internal winning combination is determined by the internal winning combination determining means, if it is determined to continue the notification gaming state, The transition from the second notification game state to the first notification game state may be determined.

  Further, in the thirty-second gaming machine of the present invention, the parameter updating means may update the parameter in a direction approaching the end of the notification gaming state.

  In order to solve the nineteenth problem, the present invention provides a thirty-third gaming machine having the following configuration.

A notifying unit (for example, the display device 11) for notifying information about the game;
A notification game control means (for example, a main control circuit 90) for controlling a game in a notification game state (for example, an ART state) in which information advantageous to the player can be reported by the notification means;
Parameter updating means (for example, S2331 and S2332 during the battle B damage reflection process) for updating a parameter (for example, a friend HP) related to the end trigger of the notification game state,
The notification game state can be a first notification game state in which the parameter update unit does not update the parameter (for example, an enemy-free state during ART) and the parameter update unit can update the parameter. And a second notification game state (for example, a battle B state) in which whether or not to continue the notification game state is determined for each unit game.
When it is determined that the notification game state is to be continued in at least one unit game in the game period of the second notification game state, the parameter update unit does not update the parameter, and the notification game After the end of the game period of the second notification game state, the control means shifts the game state from the second notification game state to the first notification game state,
If it is not determined to continue the notification game state in all the unit games in the game period of the second notification game state, the parameter updating unit updates the parameter,
As a result of updating the parameter by the parameter updating unit, when the updated parameter value reaches a predetermined value, the notification game control unit ends the notification game state, and updates the parameter value. If has not reached the predetermined value, the notification game control means again enables the execution of the game in the second notification game state,
A predetermined number of consecutive occurrences in which the parameter updating means updates the parameter without determining to continue the informative game state in all unit games in the game period of the second informative game state occurs. And, if the value of the parameter after the predetermined number of updates has not reached the predetermined value, the notification game control means may execute the predetermined number of times after the end of the game period of the second notification game state. A game machine for shifting a game state from the second notification game state to the first notification game state.

  Further, in the thirty-third gaming machine of the present invention, the parameter updating means may update the parameter in a direction approaching the end of the notification gaming state.

  In order to solve the nineteenth problem, the present invention provides a thirty-fourth gaming machine having the following configuration.

Internal winning combination determining means (for example, internal lottery processing) for determining an internal winning combination with a predetermined probability when a game start operation is detected;
A notifying unit (for example, the display device 11) for notifying information about the game;
A notification game control means (for example, a main control circuit 90) for controlling a game in a notification game state (for example, an ART state) in which information advantageous to the player can be reported by the notification means;
Parameter updating means (for example, S2331 and S2332 during the battle B damage reflection process) for updating a parameter (for example, a friend HP) related to the end trigger of the notification game state,
The notification game state can be a first notification game state in which the parameter update unit does not update the parameter (for example, an enemy-free state during ART) and the parameter update unit can update the parameter. And a second notification game state (for example, a battle B state) in which whether or not to continue the notification game state is determined for each unit game.
When it is determined that the notification game state is to be continued in at least one unit game in the game period of the second notification game state, the parameter update unit does not update the parameter, and the notification game After the end of the game period of the second notification game state, the control means shifts the game state from the second notification game state to the first notification game state,
If it is not determined to continue the notification game state in all the unit games in the game period of the second notification game state, the parameter updating unit updates the parameter,
As a result of updating the parameter by the parameter updating unit, when the updated parameter value reaches a predetermined value, the notification game control unit ends the notification game state, and updates the parameter value. If has not reached the predetermined value, the notification game control means again enables the execution of the game in the second notification game state,
In the game in the second notification gaming state, when a specific internal winning combination (for example, a rare combination) is determined by the internal winning combination determining means, it is determined to continue the notification gaming state. A gaming machine, wherein a predetermined privilege (for example, “HP recovery” or “weapon”) that allows the game period in the notification gaming state to be extended is provided.

  Further, in the thirty-fourth gaming machine of the present invention, in the gaming period in the second notification gaming state, the internal winning combination determining means determines a predetermined internal winning combination other than the specific internal winning combination (for example, “bell”). ) Is determined a specified number of times in succession, the continuation of the game period in the notification game state may be determined, and the predetermined privilege may be given.

  In the thirty-fourth gaming machine of the present invention, the predetermined privilege may be a continuation of a game period in the notification game state.

  Further, in the thirty-fourth gaming machine of the present invention, the parameter updating means may update the parameter in a direction approaching the end of the notification gaming state.

  In order to solve the nineteenth problem, the present invention provides a thirty-fifth gaming machine having the following configuration.

Internal winning combination determining means (for example, internal lottery processing) for determining an internal winning combination with a predetermined probability when a game start operation is detected;
A notifying unit (for example, the display device 11) for notifying information about the game;
A notification game control means (for example, a main control circuit 90) for controlling a game in a notification game state (for example, an ART state) in which information advantageous to the player can be reported by the notification means;
Parameter updating means (for example, S2331 and S2332 during the battle B damage reflection process) for updating a parameter (for example, a friend HP) related to the end trigger of the notification game state,
The notification game state can be a first notification game state in which the parameter update unit does not update the parameter (for example, an enemy-free state during ART) and the parameter update unit can update the parameter. And a second notification game state (for example, a battle B state) in which whether or not to continue the notification game state is determined for each unit game.
When it is determined that the notification game state is to be continued in at least one unit game in the game period of the second notification game state, the parameter update unit does not update the parameter, and the notification game After the end of the game period of the second notification game state, the control means shifts the game state from the second notification game state to the first notification game state,
If it is not determined to continue the notification game state in all the unit games in the game period of the second notification game state, the parameter updating unit updates the parameter,
As a result of updating the parameter by the parameter updating unit, when the updated parameter value reaches a predetermined value, the notification game control unit ends the notification game state, and updates the parameter value. If has not reached the predetermined value, the notification game control means again enables the execution of the game in the second notification game state,
The internal winning combination determination is performed in a predetermined unit game (for example, ART enemy presence state) in which a game period of the first notification game state has ended and the game state can be shifted to the second notification game state. When a specific internal winning combination (for example, rare combination) is determined by the means, the notification game control means shifts the game state to the first notification game state.

  In the thirty-fifth gaming machine of the present invention, the parameter updating means may update the parameter in a direction approaching the end of the notification gaming state.

  According to the thirty-second to thirty-fifth gaming machines of the present invention having the above-described configuration, in a gaming machine having an AT function, it is possible to give a player an expectation of the continuation of the notification period, It is possible to suppress a decrease in interest in the game.

[The 36th and 37th gaming machines]
2. Description of the Related Art Conventionally, in a gaming machine having an ART function, after an ART game (notifying game) for a predetermined period (a predetermined number of games) has been consumed, a gaming machine that performs a continuous lottery as to whether or not to perform an ART game for a predetermined period is used. It is known (see, for example, JP-A-2014-42658). Then, in this gaming machine, when the continuous lottery is won, the ART game of the next set is started after the ART game of the set (predetermined period) ends.

  As described above, gaming machines capable of continuing to set a notification game have been known. Therefore, in recent years, in such a gaming machine, there has been a demand for the development of a technology capable of enhancing the interest of the game in accordance with the progress of the game during the notification game period (including the continuation period).

  The present invention has been made to solve the twentieth problem, and a twentieth object of the present invention is to increase the interest of a game according to the progress of the game during a notification game period. It is to provide a possible gaming machine.

  In order to solve the twentieth problem, the present invention provides a thirty-sixth gaming machine having the following configuration.

A notifying unit (for example, the display device 11) for notifying information about the game;
A game in an informed gaming state (for example, an ART state) in which information that is advantageous to a player can be informed by the informing means is changed to a value of a parameter (for example, an ally HP, an enemy HP, a damage point) relating to the game in the informed gaming state. Notification game control means (for example, main control circuit 90) for controlling based on the
Parameter display means (for example, a sub-control circuit 200) for displaying a numerical value related to the value of the parameter by the notification means in the notification game state;
In the notification game state, a plurality of types of stages are provided,
When a specific condition (for example, CZ victory during ART) is satisfied in the notification game state, the notification control means shifts the stage to a different stage from the staying stage,
The gaming machine, wherein the parameter display means changes the numerical value displayed by the notification means according to a stage during stay.

  Further, in the thirty-sixth gaming machine of the present invention, the numerical value related to the value of the parameter displayed by the parameter display means includes a value associated with the stage during stay (for example, an ART chapter). May be integrated.

  In order to solve the twentieth problem, the present invention provides a thirty-seventh gaming machine having the following configuration.

A notifying unit (for example, the display device 11) for notifying information about the game;
A notification game control means (for example, a main control circuit 90) for controlling a game in a notification game state (for example, an ART state) in which information that is advantageous to the player can be reported by the notification means;
In the notification game state, a plurality of types of stages (for example, ART chapters) are provided,
The notification game control means shifts the stage to a different stage from the staying stage when a specific condition (for example, CZ victory during ART) is satisfied in each stage, and when the specific condition is not satisfied, Continue the stage during your stay,
Each stage is provided with a plurality of levels indicating the ease with which the specific condition is satisfied.
The level changes according to the game history in the same stage,
The notification game control means can update a specific parameter (for example, an enemy HP) relating to the timing of the stage transition, and when the value of the specific parameter after the update reaches a predetermined value, the specific game Judge that the condition is satisfied,
A gaming machine, wherein the update amount of the specific parameter at the time of updating the specific parameter by the notification game control means increases as the level increases.

  According to the thirty-sixth and thirty-seventh gaming machines of the present invention having the above-described configuration, it is possible to further enhance the interest of the game according to the progress of the game during the notification game period.

[38th to 41st gaming machines]
2. Description of the Related Art Conventionally, in a gaming machine having an ART function, a gaming machine in which a gaming state shifts to an ART state via a specific gaming state called a chance zone (CZ) has been known (for example, JP-A-2014-42658). Gazette). In this gaming machine, a lottery is performed to determine whether or not to shift the gaming state to the ART state in a specific gaming state (CZ). The gaming machine also has a function of giving a bonus game called a big bonus (BB) to the player as a privilege in each game state.

  As described above, conventionally, a gaming machine in which a gaming state shifts to an ART state via a specific gaming state (CZ) is known. Therefore, in recent years, in such a gaming machine, there has been a demand for the development of a technology capable of further enhancing the interest of the game in a specific gaming state (CZ).

  The present invention has been made to solve the above-mentioned twenty-first problem, and a twenty-first object of the present invention is to provide a gaming machine capable of further enhancing the interest of a game in a specific game state (CZ). It is to provide.

  In order to solve the above-mentioned twenty-first problem, the present invention provides a thirty-eighth gaming machine having the following configuration.

A notifying unit (for example, the display device 11) for notifying information about the game;
Controlling a game in a specific game state (for example, a CZ state) in which it is possible to determine whether or not to provide a notification game state (for example, an ART state) in which information advantageous to the player can be provided by the notification means as a privilege. Specific game control means (for example, main control circuit 90),
Lock execution means (for example, game lock) for generating a lock for disabling a game operation by a player for a predetermined period at a predetermined timing in a unit game when a predetermined condition is satisfied;
Effect execution means (for example, a sub-control circuit 200) capable of executing a predetermined effect according to a game situation,
In a game state other than the specific game state, when a specific condition is established and a start of a special game (for example, BB) is determined, a first lock (for example, a bonus winning game lock) by the lock executing means is performed. ) Occurs, and during the first lock period, a special game start effect for notifying the start of the special game is executed by the effect execution means,
In the specific game state, when the specific condition is satisfied and the start of the special game is determined, the first lock by the lock execution unit does not occur, and the special game start by the effect execution unit is not performed. A gaming machine characterized in that the same effect as the effect is not executed.

Further, in the thirty-eighth gaming machine of the present invention, when the start of the special game is determined in the specific game state, even after the start of the special game, the effect execution means keeps executing the special game. Continue to perform the effect of the specific gaming state that was being executed before the start,
After the special game is started in the specific game state, when an end condition of the specific game state (for example, CZ battle victory) is satisfied, the effect execution means executes the effect of the specific game state. Finished,
After the end of the performance of the specific game state, a second lock (for example, a game lock at the end of CZ) by the lock execution unit is generated, and the specific game state is released during the second lock. A specific game end effect to notify the end is executed by the effect execution means,
After the end of the specific game end effect, the effect executing means may start an effect corresponding to the special game being executed.

  In order to solve the twenty-first problem, the present invention provides a thirty-ninth gaming machine having the following configuration.

A specific game control means (for controlling a game in a specific game state (for example, a CZ state) in which it is possible to determine whether or not to give a bonus to a player based on a value of a specific parameter (for example, an enemy HP)) For example, the main control circuit 90)
A specific parameter updating unit (for example, S2164 during start processing during CZ) that can update the value of the specific parameter in the specific game state;
Effect execution means (for example, a sub-control circuit 200) capable of executing a predetermined effect according to a game situation,
The specific game control means, in the specific game state, if the value of the specific parameter after the update processing by the specific parameter update means reaches a predetermined value, determines the grant of the privilege,
In the specific game state, when a specific condition is satisfied and a start of a special game (for example, BB) is determined in the specific game state, the value of the specific parameter is changed from the start of the special game. A gaming machine, characterized in that the effect of the specific game state, which has been executed before the start of the special game, is continuously executed until a predetermined value is reached.

In the thirty-ninth gaming machine of the present invention, an internal winning combination determining means (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability when a game start operation is detected is further provided. Prepared,
An update value (for example, damage point) of the specific parameter at the time of updating the specific parameter by the specific parameter updating means can be changed according to a type of the internal winning combination determined by the internal winning combination determining means. Yes,
In the special game, the internal winning combination in which the update of the specific parameter by the specific parameter updating unit is superior to the player is easily determined by the internal winning combination determining unit as compared with other game states. Is also good.

  In order to solve the twenty-first problem, the present invention provides a fortieth gaming machine having the following configuration.

Internal winning combination determining means (for example, internal lottery processing) for determining an internal winning combination with a predetermined probability when a game start operation is detected;
A specific game control means (for controlling a game in a specific game state (for example, a CZ state) in which it is possible to determine whether or not to give a bonus to a player based on a value of a specific parameter (for example, an enemy HP)) For example, the main control circuit 90)
Specific parameter updating means (for example, S2164 during start processing during CZ) which can update the value of the specific parameter in the specific game state,
The specific game control means,
In the specific game state, if the value of the specific parameter reaches a predetermined value after the update processing by the specific parameter updating unit is performed, determine the grant of the privilege,
In the unit game in which the value of the specific parameter has reached a predetermined value, it is possible to further provide an additional privilege (for example, adding an ally HP) according to the internal winning combination determined by the internal winning combination determining means. A gaming machine characterized by the following.

Further, in the fortieth gaming machine of the present invention, further provided is an effect executing means (for example, a sub-control circuit 200) capable of executing a predetermined effect according to a game situation,
In a unit game in which the value of the specific parameter has reached a predetermined value, when the provision of the additional privilege is determined, the effect execution means notifies the provision of the additional privilege at the start of the next unit game. May be performed.

  In order to solve the twenty-first problem, the present invention provides a forty-first gaming machine having the following configuration.

A specific game control means (for controlling a game in a specific game state (for example, a CZ state) in which it is possible to determine whether or not to give a bonus to a player based on a value of a specific parameter (for example, an enemy HP)) For example, the main control circuit 90)
Specific parameter updating means (for example, S2164 during start processing during CZ) which can update the value of the specific parameter in the specific game state,
The specific game control means, in the specific game state, if the value of the specific parameter after the update processing by the specific parameter update means reaches a predetermined value, determines the grant of the privilege,
In the specific game state, when a special state mode (for example, “hitting”) is set, an update value of the specific parameter at the time of updating the specific parameter by the specific parameter updating unit (for example, , A damage point) is more likely to be larger than an update value of the specific parameter when the special state mode is not set.

Further, the forty-first gaming machine of the present invention further comprises an effect executing means (for example, a sub-control circuit 200) capable of executing a predetermined effect according to a game situation,
When the special state mode is set in the specific game state, compared to when the special state mode is not set in the specific game state, the specific state executed by the effect execution unit is The types of parameter update effects may be increased.

  According to the thirty-eighth to forty-first gaming machines of the present invention having the above configuration, it is possible to further enhance the interest of the game in a specific game state.

[The 42nd gaming machine]
Conventionally, in the gaming machine having the above configuration, each time a cycle period of a predetermined number of games elapses, a gaming machine that determines whether or not to shift to an advantageous state according to a result determined in a game during the cycle period is provided. It is known (for example, refer to Japanese Patent Application Laid-Open Publication No. 2014-208056). In this gaming machine, the number of executions of the specific effect in the game during the cycle period is determined by lottery. Then, after the end of the cycle period, the game state is shifted to the advantageous state in accordance with the execution of the specific effect a predetermined number of times.

  However, in the gaming machine described in Japanese Patent Application Laid-Open No. 2014-08056, when the RAM is cleared due to a setting change or the like, the information on the cycle up to that point is erased, so the information is initialized. The game is started from the state. In this case, it becomes clear that the setting change or the like has been executed (it becomes possible for the player to recognize), and there has been a problem that the game is not suitable for business in a game store.

  The present invention has been made to solve the above-mentioned twenty-second problem, and a twenty-second object of the present invention is to prevent the fact that the RAM has been cleared due to a setting change or the like from being revealed. Is to provide a simple gaming machine.

  In order to solve the above-mentioned twenty-second problem, the present invention provides a forty-second gaming machine having the following configuration.

Game period determining means (for example, CZ lottery mode cycle game number lottery processing) for determining a game period for one cycle (for example, CZ lottery mode cycle game number) when predetermined conditions are satisfied;
Effect execution means (for example, a sub-control circuit 200) capable of executing a predetermined effect according to a game situation,
The predetermined effect by the effect executing means includes an effect of notifying the remaining period of the one-cycle game period,
When a setting parameter (for example, setting 1 to setting 6) provided for adjusting the probability of granting a privilege to a player is changed, the setting parameter determined by the game period determining means after the change of the setting parameter is changed. The game period for the first cycle is longer than the game period for the first cycle determined by the game period determining means at the time of power return after the occurrence of power interruption for a predetermined time or more,
When returning from the power interruption for the predetermined time or longer, the effect execution means includes a game period of the first cycle after the return and a game period of the next cycle determined by the game period determining means after the end of the game cycle of the first cycle. A game machine that performs an effect of notifying the user as a game period for one cycle.

Further, in the forty-second gaming machine of the present invention, at the time of power return after the occurrence of a power interruption for the predetermined time or more, the gaming period determination means determines one period of the gaming period by lottery,
When the setting parameters are changed, the game period determining means adds an additional game period determined based on a random number value to the game period determined by the lottery, and sets the game period after the addition for one cycle of the game period. It may be a period.

  According to the forty-second gaming machine of the present invention having the above configuration, it is possible to prevent the fact that the RAM has been cleared from being changed due to a setting change or the like.

[The 43rd gaming machine]
Conventionally, in a gaming machine having the above-described configuration, as a method of changing the number of payouts of game media according to a specific symbol combination (combination) in accordance with the situation, a method of changing the number of game media inserted (number of multiplications) or a specific combination is used. There has been proposed a method of changing the line to be stopped and displayed (for example, see Japanese Patent Application Laid-Open No. 2015-073810). In the gaming machine disclosed in Japanese Patent Application Laid-Open No. 2015-073810, for example, when the number of medals is three, the combination of the symbol “Yellow 7”, the symbol “Yellow 7”, and the symbol “Yellow 7” is an effective line (center line). 15) When the stop is displayed above, 15 medals are paid out, and when the number of medals is two, when this combination is stopped and displayed on the activated line, two medals are paid out. Also, in the gaming machine disclosed in JP-A-2015-073810, for example, when the number of medals is three, the combination of the symbol “Yellow 7”, the symbol “Yellow 7”, and the symbol “Yellow 7” is on the active line. When the combination is stopped and displayed, 15 medals are paid out, for example, the number of medals multiplied is the same, and when this combination is stopped and displayed on the top line (inactive line), 3 medals are paid out. Will be paid out.

  However, according to the technique described in JP-A-2015-073810, the degree of freedom in the symbol arrangement mode of each reel is reduced. Further, in the method described in JP-A-2015-073810, for example, in order to display a specific combination on an inactive line, the type of the combination displayed on the active line (that is, the type of the winning combination) And may be a factor in squeezing the amount of data that can be stored.

  The present invention has been made in order to solve the twenty-third problem, and the twenty-third object of the present invention is to provide the above-described conventional method (a method of changing the number of inserted game media (number of game media), a method of specifying (A method of changing the line at which the combination is stopped and displayed), and changing the payout number of the game medium to be given when the specific symbol combination (combination) is stopped and displayed according to the game state without using the game state. It is to provide a gaming machine capable of.

  In order to solve the twenty-third problem, the present invention provides a forty-third gaming machine having the following configuration.

Insertion operation detecting means (for example, a medal sensor) for detecting an insertion operation of a game medium;
Starting operation detecting means (for example, a start switch 79) for detecting a starting operation by the player based on detection of the inserting operation by the inserting operation detecting means;
An internal winning combination determining unit (for example, an internal lottery process) for determining an internal winning combination with a predetermined probability based on the detection of the start operation by the start operation detecting unit;
Variation display means including a plurality of display columns provided with a plurality of symbols required for the game, and circulating and displaying the plurality of symbols based on the detection of the start operation by the start operation detection means (for example, three Reels 3L, 3C, 3R),
A stop operation detecting means (for example, a stop switch board 80) for detecting a stop operation by the player;
Stop control means (for example, reel stop control processing) for stopping the variable display of the symbol based on a result of the determination by the internal winning combination determination means and detection of a stop operation by the stop operation detection means,
In a special game state (for example, BB state), when a specific symbol combination (for example, “watermelon_CD_1”) is stopped and displayed on a specific determination line set across the plurality of display columns, a specific number is displayed. A first combination (for example, “F_watermelon”) from which the game media of (for example, 4) are paid out and a predetermined symbol combination (for example, “JAC_watermelon chance_1”) on the specific determination line are stopped. When displayed, a predetermined number (for example, nine) of the game media is paid out and a second role (for example, “F_RB bell”, “F_RBBAR alignment” or “F_BAR loss”) overlaps with the internal winning. Can be determined as a role,
The symbol of the part of the display columns that constitute the specific symbol combination is an arbitrary symbol, and the symbol of the other part of the display column that is different from the partial display column that constitutes the predetermined symbol combination is optional. And the symbols in the display columns other than the partial display columns and the other partial display columns that constitute the specific symbol combination are the part of the symbols that constitute the predetermined symbol combination. It is the same as the pattern of the display column other than the display column and the other display columns,
In the special game state, the first combination and the second combination are repeatedly won, and the specific symbol combination and the predetermined symbol combination are stopped and displayed on the specific determination line. When, the game media of the sum of the specific number and the predetermined number is paid out,
In a gaming state other than the special gaming state, the first combination can be determined as the internal winning combination, but the second combination is not determined as the internal winning combination,
In a gaming state other than the special gaming state, the first combination is won, and the specific symbol combination and the predetermined symbol combination overlap on a predetermined determination line set across the plurality of display columns. When the game is stopped and displayed, the specified number of the game media is paid out.

In the forty-third gaming machine of the present invention, the number of the game media inserted for each unit game in the special game state is inserted for each unit game in a game state other than the special game state. The same as the number of the game media,
The specific determination line may be the same as the predetermined determination line.

  According to the forty-third gaming machine of the present invention having the above structure, without using the above-described conventional technique, the number of game mediums to be paid out when a specific symbol combination (combination) is stopped and displayed according to the gaming situation. Can be changed according to the situation.

  DESCRIPTION OF SYMBOLS 1 ... Pachislot, 3L, 3C, 3R ... Reel, 4 ... Reel display window, 6 ... Information display, 11 ... Display device, 17L, 17C, 17R ... Stop button, 18 ... Sub display device, 71 ... Main control board, 72: sub-control board, 90: main control circuit, 91: microprocessor, 101: main CPU, 102: main ROM, 103: main RAM, 107: arithmetic circuit, 114: first serial communication circuit, 115: second serial Communication circuit, 200: sub control circuit, 201: sub CPU 201, 301: first interface board, 302: second interface board

Claims (2)

A notifying means for notifying information about the game;
A specific game control means for controlling a game in a specific game state capable of determining whether or not to provide a notification game state capable of notifying information advantageous to a player by the notification means as a privilege;
Lock execution means for generating a lock for disabling a game operation by a player for a predetermined period at a predetermined timing in a unit game when a predetermined condition is satisfied;
Effect performing means capable of executing a predetermined effect according to the game situation,
In a game state other than the specific game state, when a specific condition is satisfied and the start of the special game is determined, a first lock is generated by the lock execution unit, and during the period of the first lock, A special game start effect that notifies the start of the special game is executed by the effect execution means,
In the specific game state, when the specific condition is satisfied and the start of the special game is determined, the first lock by the lock execution unit does not occur, and the special game start by the effect execution unit is not performed. A gaming machine characterized in that the same effect as the effect is not executed. If the start of the special game is determined in the specific game state, even after the start of the special game, the effect execution means, the start of the specific game state of the specific game that was executed before the start of the special game Continue to perform the production,
After the special game is started in the specific game state, when the end condition of the specific game state is satisfied, the effect execution means ends the effect of the specific game state,
After the end of the effect of the specific game state, a second lock by the lock executing means is generated, and a specific game end effect for notifying the end of the specific game state during the period of the second lock is provided. Executed by the effect execution means,
The gaming machine according to claim 1, wherein, after the end of the specific game end effect, the effect execution means starts an effect corresponding to the special game being executed.

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