JP2010233722A - Game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a game machine which prevents excitement and enjoyment of a game from decreasing even when shifting to a disadvantageous game state by an erroneous stop operation. <P>SOLUTION: When a stop operation different from a reported stop operation order is detected even though the stop operation order for not establishing a falling combination is reported in the case of being in a first high probability replay state and a prescribed mode, the mode is changed to a first special mode. Also, when a stop operation different from the reported stop operation order is detected even though the stop operation order for not establishing the falling combination is reported in the case of being in a second high probability replay state and the prescribed mode, the mode is changed to a second special mode. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a gaming machine.

  Conventionally, a plurality of reels on which a plurality of symbols are drawn on the peripheral surface, and a display window that is provided in correspondence with each reel and displays a part of the symbols drawn on the peripheral surface of each reel, The symbols are stopped on the display window by rotating all reels based on the player's input of game value such as medals and the start operation on the start lever, and stopping each reel based on the stop operation on the stop button by the player. A gaming machine to display (so-called “pachislot”) is known. Such a gaming machine offers a bonus to the player based on the fact that the combination of symbols related to the combination is stopped on the active line in the display window and determined as the display combination (that is, the combination is established). (E.g., medal payout).

  A mainstream gaming machine draws one or two or more roles from among a plurality of roles in advance in the gaming machine based on the start operation of the player (hereinafter referred to as “internal lottery”), Hereinafter, the reel stop control is performed based on the “internal winning combination” and the player's stop operation, and the symbol combination related to the internal winning combination is stopped and displayed on the symbol display window. In addition, as a type of a role, for example, a small role that gives a player a game value, a replay that allows a replay without input of a game value, or a game state compared to a normal game state for a player There is a bonus combination (hereinafter referred to as “BB”) for starting a BB gaming state in which an advantageous gaming state (hereinafter referred to as “RB gaming state”) is continuously operated.

  Recently, there is an RT1 gaming state with a high probability that a replay will be determined as an internal winning combination, and an RT2 gaming state with a low probability that a replay will be determined as an internal winning combination as compared to the RT1 gaming state. A gaming machine that shifts to the RT2 gaming state based on the establishment of a specific combination (for example, red cherry, blue cherry) is known (for example, Patent Document 1). In the gaming machine, whether or not to give navigation points is determined according to the result of the mini game played on the liquid crystal display device in a predetermined gaming state, the number of navigation points is equal to or greater than a predetermined number, and RT1 When a specific winning combination is determined as an internal winning combination in the gaming state, the internal winning combination information is notified. Therefore, the player can prevent the transition to the RT2 gaming state by performing a stop operation so as not to establish a specific combination based on the notified information.

JP 2008-136593 A

  However, in the above-described gaming machine, in spite of the internal winning combination information indicating that the specific winning combination is determined as the internal winning combination in the RT1 gaming state, the specific winning combination is performed by performing an erroneous stop operation. If it is established, it will shift to the RT2 gaming state, which is a disadvantageous gaming state for the player. In addition, since the player is not relieved in the RT2 gaming state after the transition, the interest in the game is significantly reduced when the RT2 gaming state is shifted by performing an erroneous stop operation. In the above-described gaming machine, a player who is not good at performing a stop operation at a timing that does not establish a specific combination (is not good at pushing) is more likely to erroneously shift to the RT2 gaming state. For this reason, such a gaming machine is avoided, resulting in a decrease in the operation of the gaming machine.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a gaming machine in which the interest in gaming does not decrease even when the gaming state is shifted to an unfavorable gaming state due to an erroneous stop operation. To do.

  In order to solve the above-described problem, a gaming machine according to the first aspect of the present invention includes a plurality of reels each having a plurality of symbols arranged on the circumferential surface thereof (for example, reels 3L, 3C, and 3R described later), A display window for displaying a part of a plurality of symbols arranged on the peripheral surfaces of the plurality of reels (for example, symbol display areas 4L, 4C, 4R described later), and one symbol of each reel in the display window. By rotating the reel based on at least one effective line (for example, a center line 8c described later) formed by connecting the unit symbol display areas to be displayed and a predetermined start condition, Based on the reel rotation means (for example, stepping motors 49L, 49C, 49R described later) for changing the symbols displayed on the display window and the predetermined start condition being satisfied, a plurality of A winning combination determining means (for example, a main CPU 31 to be described later) for determining one or a plurality of internal winning combinations with a predetermined probability, and provided for each of the reels, for stopping fluctuations of the reels A configuration symbol constituting a combination of a stop operation detecting means (for example, a stop switch 7LS, 7CS, 7RS described later) for detecting a stop operation and a symbol related to the internal winning combination when the stop operation is detected, With respect to an effective line, when the stop operation is detected and before the rotation of the reel is stopped, when the drawing is within the allowable number of drawing symbols allowed in advance, the configuration symbol is The stop control means (for example, main CPU 31 described later) for stopping the rotation of the reel so as to stop along the effective line, and the stop control means When the variation of the symbol is stopped, a display combination determining means for determining whether or not the internal winning combination is established or not based on whether or not a combination of symbols related to the internal winning combination is displayed along the effective line (for example, described later) Main CPU 31) and a re-game player (for example, a replay described later) that is permitted to start a game without being input by a game value when determined by the display combination determining means. The first high-probability replaying state (for example, RT2 gaming state described later) and the second high-probability replaying state (for example, RT4 gaming state described later) determined with a relatively high probability as a role are determined according to a predetermined condition. Compared with the high probability replay state control means (for example, a main CPU 31 described later) that starts or ends based on being satisfied, and the first high probability replay state and the second high probability replay state. Then, the re-game player starts a low-probability re-game state (for example, an RT1 game state described later) determined with a relatively low probability as the internal winning combination based on a predetermined condition being satisfied. Or, in the low probability replay state control means (for example, main CPU 31 described later) to be terminated and the display combination determination means in the second high probability replay state, a special combination (for example, RT4 operating combination described later) is established. And a navigation point providing means (for example, a sub CPU 71 described later) for providing a navigation point (for example, a G value for updating the value of a digest counter described later) and a plurality of modes (for example, described later) Mode determination means (for example, a sub CPU 71 described later) for determining one mode from among the modes “0” to “39”), and the mode determined by the mode determination means is a first mode. If the mode is a mode (for example, mode “9” described later), the first special mode changing means (for example, a sub mode described later) for changing the first mode to a first special mode (for example, mode “29” described later). When the mode determined by the CPU 71) and the mode determining means is the second mode (for example, mode “13” described later), the second mode is changed to the second special mode (for example, mode “33 described later). ”) Second special mode changing means (for example, a sub CPU 71 described later) and navigation information notification means (for example, a sub CPU 71 described later) for notifying navigation information (for example, pressing order information described later). The low-probability re-gaming state control means determines that a falling combination (for example, an RT1 working combination described later) is established in the first high-probability re-gaming state or the second high-probability re-gaming state. Based on the above, the low probability replaying state is started, and the high probability replaying state control means determines that the first combination (for example, the RT2 operating combination described later) is established in the low probability replaying state. The first high-probability re-gaming state is started based on the first high-probability re-gaming state, or a second role (for example, an RT4 operating role described later) is established in the first high-probability re-gaming state or the first high-probability re-gaming state. The second high-probability re-gaming state is started based on that, and the stop control means is detected by each stop operation detecting means when the special winning combination is determined as an internal winning combination by the winning combination determining means. In accordance with the stop operation sequence to be performed, the combination of symbols related to the special combination is not stopped or displayed along the effective line, and the falling combination is determined as an internal winning combination by the winning combination determining means. When determined, according to the stop operation sequence detected by each stop operation detecting means, the combination of symbols related to the falling combination is not stopped or displayed along the effective line, When the first winning combination is determined as the internal winning combination by the winning combination determining means, the combination of the symbols related to the first combination is selected as the effective line according to the stop operation order detected by each of the stop operation detecting means. According to the stop operation sequence detected by each of the stop operation detecting means when the second winning combination is determined as an internal winning combination by the winning combination determining means. The combination of symbols related to the second combination is not stopped or displayed along the active line, and the special combination is determined as an internal winning combination by the winning combination determination means. When the stop operation order detected by each stop operation detecting means is the stop operation order corresponding to the special combination, the combination of symbols related to the special combination is set along the effective line. And when the winning combination is determined by the winning combination determining means as an internal winning combination, the order of the stop operations detected by each of the stop operation detecting means is a specific number corresponding to the falling combination. In the case of the stop operation order, the combination of symbols related to the falling combination is stopped and displayed along the effective line, and the first special mode changing means is configured to notify the navigation information in the first high probability replaying state. Means that the stop combination is notified along the effective line by the stop operation detecting means even though the stop operation sequence for not stopping and displaying the falling combination along the effective line is notified by the means. Based on the detection of the stop operation order for the stop display, the first special mode is changed, and the second special mode change means is more than the navigation information notification means in the second high probability replay state. The stop operation sequence for stopping and displaying the fallen combination along the effective line is detected by the stop operation detecting means even though the stop operation sequence for not displaying the fallen combination along the effective line is notified. When the winning combination is determined as an internal winning combination by the winning combination determining means in the first high probability replaying state or the second high probability replaying state based on In addition, the stop operation order for preventing the falling combination from being stopped and displayed along the active line is notified, and the mode determined by the mode determination means is a specific mode. If the special combination is determined as an internal winning combination by the winning combination determination means in the second high probability replaying state, a stop operation for stopping and displaying the special combination along the active line The order is notified, and when the mode is changed to the first special mode by the mode changing means, the first winning combination is determined as an internal winning combination by the winning combination determining means in the low probability replaying state. In some cases, the stop operation sequence for stopping and displaying the first combination along the active line is notified, and the mode change means changes to the second special mode, and the low probability replay state When the second winning combination is determined as the internal winning combination by the winning combination determining means, the stop operation sequence for stopping and displaying the second winning combination along the active line The navigation information notification means is characterized in that the navigation point given by the navigation point giving means is greater than or equal to a predetermined value (for example, a value of a digestion counter to be described later is “1” or more), When the winning combination determining means determines that the falling combination is an internal winning combination in the first high probability replaying state or the second high probability replaying state, a stop operation sequence different from the specific stop operation sequence is set. When the special combination is determined as an internal winning combination by the winning combination determination means in the first high probability replaying state, the stop operation order corresponding to the special combination is indicated. The navigation information is notified.

  With this configuration, the re-game player who is permitted to start the game without being input of the game value by determining that the first high-probability re-game state has been established by the display combination determining means is an internal winning combination. The low probability replaying state control means starts or ends the first high probability replaying state and the second high probability replaying state determined with a relatively high probability based on a predetermined condition being satisfied. Compared with the first high-probability replay state and the second high-probability re-play state, the re-playing combination is a low-probability re-playing state determined with a relatively low probability as an internal winning combination. The navigation point granting means grants a navigation point by determining that the special combination has been established by the display combination determining means in the second high-probability replaying state, The decision means has a plurality of modes ( For example, mode determining means (for example, a sub CPU 71 described later) for determining one mode from modes “0” to “39” described later) is used, and the first special mode changing means is determined by the mode determining means. 1st special mode changing means for changing the first mode to the first special mode (for example, mode “29” described later) when the selected mode is the first mode (for example, mode “9” described later). (E.g., a sub CPU 71 described later), and the second special mode changing unit is configured to change the second mode when the mode determined by the mode determining unit is the second mode (e.g., mode "13" described later). The second special mode changing means (for example, a later-described sub CPU 71) for changing the mode to the second special mode (for example, a mode “33” to be described later) is used, and the navigation information notifying means provides navigation information (for example, Navigation information notification means (for example, a sub-CPU 71 described later) for notifying the later-described push order information), and the low-probability re-gaming state control means includes the first high-probability re-gaming state or the second The low-probability re-gaming state is started based on the determination that a falling combination (for example, an RT1 operating combination described later) is established in the high-probability re-gaming state, and the high-probability re-gaming state control means The first high-probability re-gaming state is started based on a determination that a first combination (for example, an RT2 operating combination described below) has been established in the probability re-gaming state, or the first high-probability re-gaming state, or The second high-probability re-gaming state is started based on the fact that a second combination (for example, an RT4 operating combination described later) is established in the first high-probability re-gaming state, and the stop control means determines the winning combination By the means When a different combination is determined as an internal winning combination, according to the stop operation sequence detected by each stop operation detecting means, the combination of symbols related to the special combination is not stopped or displayed along the effective line. In addition, when the winning combination is determined as an internal winning combination by the winning combination determining means, a combination of symbols related to the falling combination according to the stop operation order detected by each of the stop operation detecting means Is not detected or stopped along the active line, and when the first winning combination is determined as an internal winning combination by the winning combination determining means, the stop detected by each of the stop operation detecting means Depending on the operation order, the combination of symbols related to the first combination is not stopped or displayed along the effective line, and the winning combination determining means When the second winning combination is determined as an internal winning combination, the combination of symbols related to the second winning combination is displayed along the effective line in accordance with the stop operation order detected by each stop operation detecting means. The first special mode changing means is informed of a stop operation sequence for not causing the fall information to be stopped and displayed along the active line from the navigation information notifying means in the first high probability replaying state. However, the second special mode is changed to the first special mode based on the fact that the stop operation detecting means detects the stop operation sequence for stopping and displaying the falling combination along the active line. The changing means is for preventing the navigation information notification means from causing the navigation information notification means to stop and display the fallen combination along the active line in the second high probability replay state. In spite of the notification of the stop operation order, the stop operation detecting means changes to the second special mode based on the detection of the stop operation order for displaying the falling combination along the effective line. When the falling combination is determined as an internal winning combination by the winning combination determination means in the first high probability replaying state or the second high probability replaying state, the falling combination is not stopped and displayed along the active line. And when the mode determined by the mode determining unit is a specific mode, the special combination is determined to be an internal winning combination by the winning combination determining unit in the second high probability replaying state. When the combination is determined as a combination, a stop operation order for stopping and displaying the special combination along the active line is notified, and the mode changing means performs the first operation. When the mode is changed to the special mode and the first winning combination is determined as an internal winning combination by the winning combination determining means in the low probability replaying state, the first combination is stopped along the active line. The stop operation order for display is notified, and the second combination is determined by the winning combination determination unit in the low probability replay state when the mode change unit changes to the second special mode. When the internal winning combination is determined, the second combination is stopped and displayed along the active line. The navigation information notification means notifies the navigation information. The low-probability re-gaming state control means starts the low-probability re-gaming state based on the determination that the falling combination is established in the first high-probability re-gaming state or the second high-probability re-gaming state, The probability re-gaming state control means starts the first high-probability re-gaming state based on the determination that the first role is established in the low-probability re-gaming state, and the second role in the first high-probability re-gaming state. The second high-probability re-playing state is started based on the fact that is established, and the stop control means is detected by each stop operation detecting means when the special combination is determined as the internal winning combination by the winning combination determining unit When the order of the stop operation is the stop operation order corresponding to the special role, the combination of symbols related to the special role is stopped and displayed along the active line, and the winning combination is determined by the winning combination determining means. Determined as a role If the stop operation order detected by each stop operation detecting means is a specific stop operation order corresponding to the falling combination, the combination of symbols related to the falling combination is stopped along the effective line. The navigation information notifying means is a case where the navigation points given by the navigation point giving means are not less than a predetermined value, and the winning combination determining means in the first high probability replaying state or the second high probability replaying state. When the falling combination is determined as the internal winning combination, navigation information indicating a stop operation sequence different from the specific stop operation sequence is notified, and in the first high probability replaying state, the special combination is determined by the winning combination determining means. When the winning combination is determined, the navigation information indicating the stop operation order corresponding to the special combination is notified.

  Therefore, according to the gaming machine, by performing an erroneous stop operation, the low probability replay game that is disadvantageous from the first high probability replay game state or the second high probability replay game state that is an advantageous game state. Even if the state has shifted to the state, it is possible to re-transfer to the gaming state before the transition to the disadvantaged gaming state by informing the push order in the first special mode or the second special mode, Even if the game is shifted to an unfavorable game state due to an erroneous stop operation, the interest in the game is not lowered. In addition, since the role of shifting to an unfavorable gaming state is established in a predetermined pushing order, the player who is not good at stopping at a specific timing does not shy away from the game, and the operation of the gaming machine decreases There is no cause. Since the player can recognize whether or not a navigation point has been given simply by gazing at the combination of symbols displayed on the active line, the concentration on the game is reduced by keeping an eye on the liquid crystal display device. Can be prevented. Further, according to the gaming machine, navigation information is notified when the number of navigation points is equal to or greater than a predetermined number, and a stop operation according to the navigation information is performed to prevent a transition to a gaming state that is disadvantageous for the player. be able to. Further, when the special combination is determined as the internal winning combination, the special combination can be established on the active line by performing a stop operation according to the navigation information. Thereby, even if it is a player who is not good at performing stop operation at a specific timing, the interest with respect to a game does not fall.

  Therefore, according to the gaming machine, by performing an erroneous stop operation, the low probability replay game that is disadvantageous from the first high probability replay game state or the second high probability replay game state that is an advantageous game state. Even if the state has shifted to the state, it is possible to re-transfer to the gaming state before the transition to the disadvantaged gaming state by informing the push order in the first special mode or the second special mode, Even if the game is shifted to an unfavorable game state due to an erroneous stop operation, the interest in the game is not lowered. In addition, since the role of shifting to an unfavorable gaming state is established in a predetermined pushing order, the player who is not good at stopping at a specific timing does not shy away from the game, and the operation of the gaming machine decreases There is no cause.

It is a figure which shows the game machine in one Embodiment. It is a figure which shows the winning line of the game machine in one Embodiment. It is a figure which shows the symbol arrangement | positioning table of the game machine in one Embodiment. It is a figure which shows the structure of the main control circuit of the game machine in one Embodiment. It is a figure which shows the structure of the sub control circuit of the game machine in one Embodiment. It is a figure which shows the example of the internal lottery table determination table of the game machine in one Embodiment. It is a figure which shows the example of the internal lottery table for general game states of the game machine in one Embodiment. It is a figure which shows the example of the internal lottery table for RT1 gaming states of the game machine in one Embodiment. It is a figure which shows the example of the internal lottery table for RT2 gaming states of the game machine in one Embodiment. It is a figure which shows the example of the internal lottery table for RT3 game state of the game machine in one Embodiment. It is a figure which shows the example of the internal lottery table for RT4 gaming state of the game machine in one Embodiment. It is a figure which shows the example of the internal lottery table for RT5 gaming states of the gaming machine in one embodiment. It is a figure which shows the example of the RT6 gaming state internal lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the internal lottery table for RB1 game states of the game machine in one Embodiment. It is a figure which shows the example of the internal lottery table for RB2 game states of the game machine in one Embodiment. It is a figure which shows the example of the internal winning combination determination table for the small combination and replay of the gaming machine in one embodiment. It is a figure which shows the example of the internal winning combination determination table for the small combination and replay of the gaming machine in one embodiment. It is a figure which shows the example of the internal winning combination determination table for the small combination and replay of the gaming machine in one embodiment. It is a figure which shows the example of the internal winning combination determination table for bonuses of the gaming machine in one embodiment. It is a figure which shows the example of the symbol combination table of the game machine in one Embodiment. It is a figure which shows the example of the symbol combination table of the game machine in one Embodiment. It is a figure which shows the example of the symbol combination table of the game machine in one Embodiment. It is a figure which shows the example of the symbol combination table of the game machine in one Embodiment. It is a figure which shows the example of the symbol combination table of the game machine in one Embodiment. It is a figure which shows the example of a transition of the game state of the game machine in one Embodiment. It is a figure which shows the relationship between the internal winning combination and display combination of the gaming machine in one embodiment. It is a figure which shows the example of the bonus operation time table of the gaming machine in one embodiment. It is a figure which shows the example of the rotation stop initial setting table of the game machine in one Embodiment. It is a figure which shows the example of the drawing-in priority order table selection table of the gaming machine in one embodiment. It is a figure which shows the example of the priority order table of the game machine in one Embodiment. It is a figure which shows the example of the stop table of the game machine in one Embodiment. It is a figure which shows the example of the stop table of the game machine in one Embodiment. It is a figure which shows the example of the stop table of the game machine in one Embodiment. It is a figure which shows the example of the stop table of the game machine in one Embodiment. It is a figure which shows the example of the stop table of the game machine in one Embodiment. It is a figure which shows the example of the stop table of the game machine in one Embodiment. It is a figure which shows the example of the stop table of the game machine in one Embodiment. It is a figure which shows the example of the stop table of the game machine in one Embodiment. It is a figure which shows the example of the stop table of the game machine in one Embodiment. It is a figure which shows the example of the priority order table of the game machine in one Embodiment. It is a figure which shows the example of the change data table selection value determination table after the 1st stop of the game machine in one Embodiment. It is a figure which shows the example of the stop table number determination table for a change after the 1st stop of the game machine in one Embodiment. It is a figure which shows the example of the change data table selection table after the 2nd stop of the game machine in one Embodiment. It is a figure which shows the example of the stop position check data selection table of the game machine in one Embodiment. It is a figure which shows the example of the internal winning combination storing area | region of the game machine in one Embodiment. It is a figure which shows the example of the display combination storage area | region of the game machine in one Embodiment. It is a figure which shows the example of the carryover combination storage area | region of the game machine in one Embodiment. It is a figure which shows the example of the game state management flag storage area | region of the game machine in one Embodiment. It is a figure which shows the example of the stop table selection value storage area 1-4 of the game machine in one Embodiment. It is a figure which shows the example of the draw-in priority data storage area | region of the game machine in one Embodiment. It is a figure which shows the example of the symbol storage area in one Embodiment. It is a figure which shows the example of the effective stop button storage area | region of the game machine in one Embodiment. It is a figure which shows the example of the operation | movement stop button storage area | region of the game machine in one Embodiment. It is a figure which shows the example of the stop order check data storage area | region of the game machine in one Embodiment. It is a figure which shows the example of the position check data storage area | region of the game machine in one Embodiment. It is a figure which shows the outline | summary of each mode of the game machine in one Embodiment. It is a figure which shows the relationship between each mode and management data of the game machine in one Embodiment. It is a figure which shows the example of the data list for mode management of the game machine in one Embodiment. It is a figure which shows the example of the navigation display lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the navigation display lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the navigation display lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the navigation display lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the navigation display lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the navigation display lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the navigation display lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the navigation display lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the navigation display lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the navigation display lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the mode transfer lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the mode transfer lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the mode transfer lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the mode transfer lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the mode transfer lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the mode transfer lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the mode transfer lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the mode transfer lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the mode transfer lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the mode transfer lottery table of the gaming machine in one embodiment. It is a figure which shows the example of the mode transfer lottery table in BB of the game machine in one Embodiment. It is a figure which shows the example of the counter update table of the game machine in one Embodiment. It is a figure which shows the example of the counter update table of the game machine in one Embodiment. It is a figure which shows the example of the counter update table of the game machine in one Embodiment. It is a figure which shows the example of the counter update table of the game machine in one Embodiment. It is a figure which shows the example of the counter update table of the game machine in one Embodiment. It is a figure which shows the example of the counter update table of the game machine in one Embodiment. It is a figure which shows the example of the counter update table of the game machine in one Embodiment. It is a figure which shows the example of the counter update table of the game machine in one Embodiment. It is a figure which shows the example of the counter update table of the game machine in one Embodiment. It is a figure which shows the example of the step value update table at the time of BB3 action | operation of the game machine in one Embodiment. It is a figure which shows the example of the step value update table at the time of BB3 action | operation of the game machine in one Embodiment. It is a figure which shows the example of the sub setting lottery table of the game machine in one Embodiment. It is a figure which shows the example of the sub setting lottery table of the game machine in one Embodiment. It is a figure which shows the example of the sub appearance ball discharge | lottery lottery table of the game machine in one Embodiment. It is a figure which shows the example of the sub appearance ball discharge | lottery lottery table of the game machine in one Embodiment. It is a figure which shows the example of the sub appearance ball lottery table of the game machine in one Embodiment. It is a figure which shows the example of the sub appearance ball lottery table of the game machine in one Embodiment. It is a figure which shows the flowchart of the reset interruption process by the main CPU performed by the main control circuit in one Embodiment. It is a figure which shows the flowchart of the medal reception and start check process performed in the main control circuit in one Embodiment. It is a figure which shows the flowchart of the internal lottery process performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the internal lottery process performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the reel stop initial setting process performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the drawing priority order | rank storage process performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the drawing priority order table selection process performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the drawing priority order acquisition process performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the reel stop control process performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the sliding frame number determination process performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the priority drawing-in control process performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the stop data storage process performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the stop data storage process after the 1st stop performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the stop data storage process after the 2nd stop performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the winning action search process performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of a prize check and medal payout process performed in the main control circuit in one Embodiment. It is a figure which shows the flowchart of the bonus completion | finish check process performed in the main control circuit in one Embodiment. It is a figure which shows the flowchart of the bonus operation | movement check process performed in the main control circuit in one Embodiment. It is a figure which shows the flowchart of RT control processing performed with the main control circuit in one Embodiment. It is a figure which shows the flowchart of the interruption process by the main CPU performed by the main control circuit in one Embodiment. It is a figure which shows the flowchart of the process at the time of power activation performed by the sub-control circuit in one Embodiment. It is a figure which shows the flowchart of the lamp | ramp control task performed with the sub control circuit in one Embodiment. It is a figure which shows the flowchart of the sound control task performed with the sub control circuit in one Embodiment. It is a figure which shows the flowchart of the mother task performed by the sub control circuit in one Embodiment. It is a figure which shows the flowchart of the main board | substrate communication task performed with the sub control circuit in one Embodiment. It is a figure which shows the flowchart of the command analysis process performed with the sub control circuit in one Embodiment. It is a figure which shows the flowchart of the production content determination process performed with the sub control circuit in one Embodiment. It is a figure which shows the flowchart of the process at the time of the start command reception performed by the sub-control circuit in one Embodiment. It is a figure which shows the flowchart of the process at the time of the reel stop command reception performed by the sub control circuit in one Embodiment. It is a figure which shows the flowchart of the process at the time of the display command reception performed by the sub-control circuit in one Embodiment. It is a figure which shows the flowchart of the special mode rewriting process performed with the sub control circuit in one Embodiment.

  The gaming machine of the present invention will be specifically described below with reference to the drawings. In the following embodiment, as a gaming machine of the present invention, a gaming machine having three rotating reels that variably display symbols, in addition to coins, medals, tokens, etc., a card given to a player A description will be given using a game machine capable of playing using a game value such as a so-called pachislot machine. Further, in the following embodiments, a pachislot gaming machine will be described as an example, but the gaming machine of the present invention is not limited, and a pachinko machine or a slot machine may be used.

  First, an overview of the gaming machine according to the present embodiment will be described with reference to FIG. FIG. 1 is a front view of the gaming machine 1 according to the present embodiment.

  As shown in FIG. 1, the gaming machine 1 includes a cabinet that houses reels 3L, 3C, and 3R, a main control circuit 60 (see FIG. 4) described later, and the like, and a front door that is attached to the cabinet so as to be openable and closable. , Is provided.

  A symbol display area 4L, 4C, 4R as a substantially vertical surface and a liquid crystal display area 23 for displaying and displaying a predetermined image are formed in front of the central portion of the front door. Three reels 3L, 3C, and 3R are rotatably provided in a horizontal row inside the front of the central portion of the cabinet (the back of the symbol display areas 4L, 4C, and 4R). On the three reels 3L, 3C, 3R, a symbol row composed of a plurality of types of symbols is drawn on each outer peripheral surface. The symbols of the reels 3L, 3C, 3R can be seen through the symbol display areas 4L, 4C, 4R. Each reel 3L, 3C, 3R is controlled by a main control circuit 60 (see FIG. 4), which will be described later, so as to rotate at a constant speed (for example, 80 revolutions / minute). The symbols drawn on the reels 3L, 3C, 3R vary as the reels rotate. Note that the reels 3L, 3C, and 3R of the present embodiment constitute a reel of the present invention, and the symbol display areas 4L, 4C, and 4R constitute a display window of the present invention.

  A substantially horizontal pedestal is formed below the liquid crystal display area 23. On the left side of the pedestal portion, a maximum BET button 13 for betting a credited medal by a push button operation is provided. The maximum BET button 13 is inserted into three of the credited medals (that is, the maximum number that can be inserted in one game) by one press operation. By doing so, a winning line described later is validated.

  A medal slot 22 is provided on the right side of the pedestal. In accordance with the medal inserted into the medal slot 22, a pay line described later is activated.

  On the left side of the front portion of the pedestal portion, a C / P button 14 for switching between credit (Credit) / payout (Pay) of medals obtained by the player in the game is provided. The payout mode or the credit mode is switched by the player's operation on the C / P button 14. In the credit mode, when a winning is established, medals for the number of payouts corresponding to the winning are credited. In the payout mode, when a winning is established, medals for the number of payouts corresponding to the winning are paid out from the medal payout port 15 at the lower front, and the medals paid out from the medal payout port 15 are sent to the medal receiving unit 16. Can be stored. Note that winning means stopping a combination of symbols relating to a small combination on an activated winning line. The small role is a role in which medals are paid out when established.

  Speakers 21 </ b> L and 21 </ b> R are provided on the left and right above the liquid crystal display region 23. The speakers 21L and 21R output game sounds such as performance sounds and notification sounds according to the game situation.

  A start lever 6 is provided on the right side of the C / P button 14. The start lever 6 rotates the reels 3L, 3C, and 3R by the player's start operation, and starts changing the symbols displayed in the symbol display areas 4L, 4C, and 4R.

  Three stop buttons 7L, 7C, and 7R for stopping the rotation of the three reels 3L, 3C, and 3R by the player's stop operation are provided on the right side of the start lever 6 at the center of the front portion of the base portion. Is provided. Here, when the three reels 3L, 3C, and 3R are rotating, the first stop of the rotation of the reels is referred to as a first stop, which is performed after the first stop and the two reels are rotated. The second stop of the rotation of the reel that is performed when the operation is performed is referred to as the second stop, which is performed after the second stop, and is performed last when the rotation of the remaining one reel is performed. Stopping the rotation of the reel is referred to as a third stop. The stop operation for the player to stop for the first time is referred to as a first stop operation. Similarly, a stop operation for the player to stop the second stop is referred to as a second stop operation, and a stop operation for the third stop is referred to as a third stop operation.

  On the left side of the symbol display areas 4L, 4C, and 4R, a WIN lamp 17, a maximum BET lamp 9a, a payout number display unit 18, and a credit display unit 19 are provided.

  The WIN lamp 17 notifies the player that the combination of symbols related to the operation of the bonus can be displayed by lighting. The maximum BET lamp 9a is turned on when the maximum BET button 13 is operated or when three medals are inserted.

  The payout number display unit 18 and the credit display unit 19 are each composed of a 7-segment LED, and display the payout number of medals at the time of winning and the number of stored medals.

  In each of the symbol display areas 4L, 4C, and 4R, one symbol is displayed in each of the upper, middle, and lower stages in each of the vertically long symbol display areas 4L, 4C, and 4R and arranged on the peripheral surface of the corresponding reel. Three symbols are displayed. That is, the symbol display areas 4L, 4C, and 4R have a function as a so-called display window.

  Next, the winning line will be described with reference to FIG. In the symbol display areas 4L, 4C, 4R, one winning line connecting the above-described symbol display areas 4L, 4C, 4R is provided. Specifically, a center line 8c is provided that connects the middle regions of the symbol display regions 4L, 4C, and 4R. When the rotation of the reels 3L, 3C, 3R is stopped, the gaming machine 1 determines whether the winning combination is established or not based on the combination of symbols displayed on the activated winning line. Hereinafter, the activated winning line is referred to as an activated line, and the activated winning line is referred to as an inactivated line.

  In addition, as shown in the lower diagram of FIG. 2, the gaming machine 1 is provided with four pseudo pay lines that connect the respective areas. Specifically, the top line 8b that connects the upper regions of the symbol display areas 4L, 4C, and 4R as the pseudo pay line, and the bottom that connects the lower regions of the symbol display areas 4L, 4C, and 4R, respectively. Line 8d, the lower part of the left symbol display area 4L, the middle part of the middle symbol display area 4C, and the upper part of the right symbol display area 4R, the cross-up line 8a and the upper part of the left symbol display area 4L, the middle symbol display area A cross-down line 8e is provided that connects the middle part of 4C and the lower part of the right symbol display area 4R. However, medals are not paid out depending on the combination of symbols displayed on the pseudo pay line.

  Next, with reference to FIG. 3, the symbol row arranged on the reels 3L, 3C, 3R will be described. FIG. 3 is a diagram illustrating an arrangement of symbols drawn on the reels 3L, 3C, and 3R of the gaming machine 1 according to the present embodiment.

  A reel sheet is mounted on the outer peripheral surface of each reel 3L, 3C, 3R, and a symbol row in which 21 types of symbols are arranged on the reel sheet is drawn. Specifically, it is composed of a red 7A symbol, a red 7B symbol, a BAR (A) symbol, a BAR (B) symbol, a bell A symbol, a bell B symbol, a watermelon symbol, a cherry symbol, a replay A symbol, and a replay B symbol. A pattern row is drawn.

  For each symbol, code numbers “00” to “20” for specifying the position of each symbol are determined in advance and stored as a data table in the ROM 32 of the main control circuit 60 described later with reference to FIG. ing.

  In each reel 3L, 3C, 3R, the maximum interval between each replay symbol is 4 symbols. This corresponds to “4” frames which is the maximum number of sliding frames. Although the number of sliding symbols will be described in detail later, the gaming machine 1 draws the symbol related to the establishment of the internal winning combination for the maximum number of sliding symbols from the time when the stop operation is detected, that is, draws four symbols on the active line. Stop reel rotation to stop.

  Next, with reference to FIG. 4, the circuit configuration of the gaming machine 1 including a peripheral device (actuator) electrically connected to the main control circuit 60, the sub control circuit 70, the main control circuit 60 or the sub control circuit 70 will be described. To do. FIG. 4 is a diagram showing a circuit configuration of the gaming machine 1.

  The main control circuit 60 controls the progress of a series of games such as determination of an internal winning combination and reel control. The main control circuit 60 includes a microcomputer 30 disposed on a circuit board as a main component, and is added to a circuit for random number sampling. The microcomputer 30 includes a main CPU 31 and ROM 32 and RAM 33 which are storage means.

  The main CPU 31 is connected to a clock pulse generation circuit 34, a frequency divider 35, a random number generator 36, and a sampling circuit 37.

  The main CPU 31 determines an internal winning combination based on the random number value and an internal lottery table described later, and stops the rotation of the reels 3L, 3C, 3R based on the detection of the internal winning combination and the stop operation. Let Further, when the main CPU 31 stops the rotation of the reels 3L, 3C, and 3R, it determines whether or not a winning combination has been established based on the combination of symbols displayed in the symbol display areas 4L, 4C, and 4R. If established, the player is given a profit such as paying out medals according to the established combination.

  Further, the main CPU 31 operates the RT2 gaming state based on the RT2 gaming role being established in the RT1 gaming state, and the RT4 gaming role is based on the RT1 gaming state or RT2 gaming status being established. Operate. Further, the main CPU 31 activates the RT1 gaming state based on the establishment of the RT1 operating combination in the RT2 gaming state or the RT4 gaming state.

  Further, when “11” is determined as the small role / replay data pointer, the main CPU 31 performs the first stop operation on the right reel 3R, the second stop operation on the left reel 3L, and the third stop operation on the middle reel 3C. Is detected, the RT4 operating combination is stopped and displayed on the active line, and the first stop operation for the left reel 3L, the second stop operation for the middle reel 3C, and the third stop operation for the right reel 3R are detected. In this case, the RT2 operating combination is stopped and displayed on the active line. Further, when “22” is determined as the small role / replay data pointer, the main CPU 31 stops and displays the RT1 operating role on the active line based on the detection of the first stop operation on the left reel. .

  The main CPU 31 of the present embodiment constitutes a winning combination determining means, a stop control means, a display combination determining means, a high probability replaying state control means, and a low probability replaying state control means of the present invention.

  The clock pulse generation circuit 34 and the frequency divider 35 generate a reference clock pulse. The random number generator 36 generates a random number ranging from “0” to “65535”. The sampling circuit 37 extracts (samples) one random number value from the random number generated by the random number generator 36.

  In the gaming machine 1, the extracted random number value is stored in a random value storage area of the RAM 33 described later. Based on the random number value stored in the random value storage area of the RAM 33 for each game, an internal winning combination is determined in an internal lottery process (see FIGS. 99 and 100) described later.

  In addition, as a means for random number sampling, you may make it the structure which performs random number sampling within the microcomputer 30, ie, on the operation program of the main CPU31. In that case, the random number generator 36 and the sampling circuit 37 can be omitted, or can be left as a backup for the random number sampling operation.

  In the ROM 32 of the microcomputer 30, a program related to the processing of the main CPU 31 (for example, see FIGS. 97 to 116 described later), various tables (for example, see FIGS. 6 to 24 and FIGS. Various control commands (commands) to be transmitted to the control circuit 70 are stored.

  Various information obtained by the processing of the main CPU 31 is set in the RAM 33. For example, information for identifying the extracted random number value, gaming state, operating state, payout number, bonus carryover status, setting value, etc., various counters and flags are set. Some of these pieces of information are transmitted to the sub-control circuit 70 by the above-described command.

  In the circuit of FIG. 4, the main actuators whose operation is controlled by the control signal from the microcomputer 30 are the maximum BET lamp 9a, the WIN lamp 17, the payout number display section 18, the credit display section 19, the hopper 40, and the stepping motor. 49L, 49C, 49R, etc. The exchange of signals between these actuators and the main CPU 31 is performed via the I / O port 38.

  In addition, each circuit for controlling the operation of each actuator described above is connected to the output unit of the microcomputer 30 in response to a control signal output from the main CPU 31. Each circuit includes a motor drive circuit 39, a lamp drive circuit 45, a display unit drive circuit 48, and a hopper drive circuit 41.

  The lamp driving circuit 45 controls driving of the maximum BET lamp 9a and the WIN lamp 17. Thereby, the maximum BET lamp 9a and the WIN lamp 17 are turned on and off.

  The display unit drive circuit 48 drives and controls the payout number display unit 18 and the credit display unit 19. As a result, various information (such as the number of credits) is displayed on the payout number display unit 18 and the credit display unit 19.

  The hopper drive circuit 41 drives and controls the hopper 40. Thereby, the medal accommodated in the hopper 40 is paid out.

  The motor drive circuit 39 drives and controls the stepping motors 49L, 49C, 49R. As a result, the reels 3L, 3C, and 3R are rotated and stopped. Note that the stepping motors 49L, 49C, and 49R of the present embodiment constitute the reel rotating means of the present invention.

  Also, each switch and each circuit for generating an input signal that triggers outputting a control signal to each circuit and each actuator described above are connected to the input section of the microcomputer 30. Each switch and each circuit includes a start switch 6S, stop switches 7LS, 7CS, 7RS, maximum BET switch 13S, C / P switch 14S, medal sensor 22S, setting value change switch 200S, reel position detection circuit 50, payout completion signal. There is a circuit 51. Note that the stop switches 7LS, 7CS, and 7RS are collectively referred to as the stop switch 7S.

  The start switch 6S detects a player's start operation on the start lever 6 and outputs a start signal instructing the start of the game to the microcomputer 30.

  The stop switches 7LS, 7CS, and 7RS detect the player's stop operation on the stop buttons 7L, 7C, and 7R, respectively, and stop the rotation of the reels 3L, 3C, and 3R corresponding to the detected stop buttons 7L, 7C, and 7R. A stop signal to be commanded is output to the microcomputer 30. Note that the stop switches 7LS, 7CS, and 7RS of the present embodiment constitute stop operation detecting means of the present invention.

  The maximum BET switch 13S detects a player's insertion operation on the BET button, and outputs a signal for instructing insertion of three medals from the credited medals to the microcomputer 30.

  The C / P switch 14S detects a player's switching operation on the C / P button 14, and outputs a signal for switching the credit mode or the payout mode to the microcomputer 30. When the credit mode is switched to the payout mode, a signal for instructing the payout of medals credited to the gaming machine 1 is output to the microcomputer 30.

  The set value change switch 200S includes a setting key type switch (not shown) linked to a power switch (not shown), a reset switch (not shown), and the like. The set value can be changed by the set value change switch 200S.

  The set values can be set in six levels from “1” to “6”, and by selecting an internal lottery table to be described later based on the set values, each of the combinations such as BB1 to BB4 can be set as an internal winning combination. The probability determined to be changed. The set values are “1”, “2”, “3”, “4”, “5”, and “6” when they are arranged in order from the disadvantage to the player. That is, the case where the set value is “6” is most advantageous for the player.

  The medal sensor 22S detects medals inserted into the medal insertion slot 22 by the player's insertion operation, and outputs a signal indicating that a medal has been inserted to the microcomputer 30.

  The reel position detection circuit 50 detects a pulse signal from the reel rotation sensor and generates a signal for detecting the position of the symbol on each reel 3L, 3C, 3R.

  The payout completion signal circuit 51 indicates that the medal payout has been completed when the number of medals detected by the medal detection unit 40S (that is, the number of medals paid out from the hopper 40) reaches the designated number. Generate a signal to indicate.

  The sub-control circuit 70 performs various processes such as determination and execution of effect contents based on various commands output from the main control circuit 60 such as a start command described later. The sub control circuit 70 does not input commands, information, or the like to the main control circuit 60, and communication is performed in one direction from the main control circuit 60 to the sub control circuit 70.

  As main actuators whose operation is controlled by a control signal from the sub-control circuit 70, there are a liquid crystal display device 5 and speakers 21L and 21R. The sub-control circuit 70 determines the image displayed on the liquid crystal display device 5 and determines and outputs the display based on the determined effect content, determines and outputs the effect sound and sound effect output from the speakers 21L and 21R, and the like. Control.

  Details of the configuration of the sub control circuit 70 in the present embodiment will be described later.

  In the gaming machine 1, when a signal for starting a game is output from the start switch 6S by a player's operation on the start lever 6 on condition that a medal is inserted, a control signal is output to the motor drive circuit 39, and the stepping motor Rotation of the reels 3L, 3C, and 3R is started by driving control of 49L, 49C, and 49R (for example, excitation to each phase). At this time, the number of pulses output to the stepping motors 49L, 49C, 49R is counted, and the counted value is set in a predetermined area of the RAM 33 as a pulse counter. In the gaming machine 1, when the “16” pulse is output, the reels 3L, 3C, and 3R move by one symbol. The number of symbols moved is counted, and the counted value is set in a predetermined area of the RAM 33 as a symbol counter. That is, every time the pulse counter counts “16”, the symbol counter is updated by “1”.

  A reel index is obtained from the reels 3L, 3C, and 3R for each rotation and is output to the main CPU 31 via the reel position detection circuit 50. With the output of the reel index, the pulse counter and the symbol counter set in the RAM 33 are cleared to “0”. In this way, the symbol position within one rotation range is specified for each reel 3L, 3C, 3R. The distance that each symbol moves by one symbol by the rotation of the reel is called one frame. That is, moving the symbol by one frame corresponds to updating the symbol counter by “1”.

  In order to associate the rotation positions of the reels 3L, 3C, and 3R with the symbols drawn on the outer peripheral surface of the reel, a symbol arrangement table (see FIG. 3) is stored in the ROM 32. This symbol arrangement table includes code numbers from “00” to “20” that are sequentially assigned at fixed rotation pitches of the reels 3L, 3C, and 3R with reference to the position where the reel index is output. A symbol code for identifying the type of symbol provided corresponding to each code number is associated with each other.

  When a start signal is output from the start switch 6S, a random number value is extracted by the random number generator 36 and the sampling circuit 37. In the gaming machine 1, when the random value is extracted, it is stored in the random value storage area of the RAM 33. Then, an internal winning combination is determined based on the random value stored in the random value storage area.

  After the reels 3L, 3C, and 3R have reached constant speed rotation, when a stop signal is output from the stop switches 7LS, 7CS, and 7RS by a stop operation, based on the output stop signal and the determined internal winning combination, A control signal for stopping and controlling the reels 3L, 3C, 3R is output to the motor drive circuit 39. The motor drive circuit 39 drives and controls the stepping motors 49L, 49C, 49R, and stops the rotation of the reels 3L, 3C, 3R.

  When the rotation of all the reels 3L, 3C, and 3R is stopped, the display combination retrieval process, that is, the determination process of the formation / non-establishment of the combination is performed based on the combination of symbols displayed on the effective line. The search for the display combination is performed based on the symbol combination table (see FIGS. 20 to 24) stored in the ROM 32. In this symbol combination table, a symbol combination related to a display combination and a corresponding payout are set.

  When it is determined by the display combination search that a combination of symbols related to winning is displayed, a control signal is output to the hopper driving circuit 41 and the hopper 40 is driven to pay out medals. At this time, the medal detection unit 40S counts the number of medals to be paid out from the hopper 40, and when the count value reaches the designated number, the payout completion signal circuit 51 outputs a signal indicating completion of the medal payout. . Thereby, a control signal is output to the hopper drive circuit 41, and the drive of the hopper 40 is stopped.

  When the credit mode is switched by the C / P switch 14S, if it is determined that the winning symbol combination is displayed, the payout amount corresponding to the winning symbol combination is stored in the credit of the RAM 33. Add to the number counter. Further, a control signal is output to the display unit driving circuit 48 and the value of the credit number counter is displayed on the credit display unit 19. Here, there are cases where the medal payout or the addition of the payout number to the credit counter, which is performed when a combination of symbols related to winning is displayed, is simply referred to as “payout”.

  Next, the circuit configuration of the sub control circuit 70 will be described with reference to FIG. FIG. 5 is a diagram showing a circuit configuration of the sub control circuit of the gaming machine 1.

  The sub-control circuit 70 performs control for performing effects related to games using video, sound, light, and the like. The sub-control circuit 70 determines the contents of effects based on various commands transmitted from the main control circuit 60 and performs various effects processes. The sub control circuit 70 includes a sub CPU 71, a sub ROM 72, a sub RAM 73, a rendering processor 74, a drawing SDRAM 75 (including a frame buffer 76), a driver 77, an A / D converter 78, and an amplifier 79. The main actuators whose operation is controlled by the sub control circuit 70 include the liquid crystal display device 5 and speakers 21L and 21R.

  The sub CPU 71 performs display control of the liquid crystal display device 5, output control of the speakers 21L, 21R, and the like based on a program stored in the sub ROM 72. Specifically, the sub CPU 71 receives a gaming state and various commands from the main control circuit 60 and stores various information in the sub RAM 73. The sub CPU 71 executes the program while referring to the game state information, the internal winning combination information, etc. stored in the sub RAM 73, thereby causing the effect devices such as the liquid crystal display device 5, the speakers 21L and 21R to perform. To decide. Further, the sub CPU 71 controls the liquid crystal display device 5 via the rendering processor 74 based on the determined contents of the effect, and also controls the sound output from the speakers 21L and 21R.

  Further, the sub CPU 71 executes a random number acquisition program stored in the sub ROM 72, thereby acquiring a random number value used when determining the production contents and the like. However, when a random number generator and a sampling circuit are provided in the sub-control circuit 70 as in the main control circuit 60, this processing is not necessary.

  Further, as will be described later, the sub CPU 71 executes a program stored in the sub ROM 72 to produce an effect based on the effect data determined by the effect content determination process described later with reference to FIG. And so on.

  Further, as will be described later, when the gaming state managed by the sub-control circuit 70 is the RT4 gaming state, the sub CPU 71 updates the value of the digest counter based on the establishment of the RT4 operating combination. Further, the sub CPU 71 determines a transfer destination mode based on the current mode and the internal winning combination with reference to a mode shift lottery table to be described later with reference to FIGS. 69 to 78. Further, the sub CPU 71 provides navigation information (push order information) for preventing the RT1 operating combination from being established when the gaming state is the RT2 gaming state or the RT4 gaming state and the value of the digest counter is “1” or more. Inform. Further, in the RT4 gaming state, when the mode when the RT4 winning combination is determined as the internal winning combination is “13”, the sub CPU 71 notifies the navigation information for establishing the RT4 operating combination.

  In addition, when the sub CPU 71 notifies the navigation information for not establishing the RT1 actuator when the RT2 gaming state and the mode is “9”, the gaming state managed by the main control circuit 60 is the same. When transitioning to the RT1 gaming state, the mode is shifted to mode “27”. In addition, when the sub CPU 71 notifies the navigation information for not establishing the RT1 actuator when the RT4 gaming state and the mode is “13”, the gaming state managed by the main control circuit 60 is the same. When transitioning to the RT1 gaming state, the mode is shifted to mode “31”.

  Further, in the RT1 gaming state, when the mode when “10” is determined as the small role / replay data pointer is “27”, the sub CPU 71 displays navigation information for establishing the RT2 operating role. Inform. Further, in the RT1 gaming state, when the mode when the RT4 winning combination is determined as the internal winning combination is “31”, the sub CPU 71 notifies the navigation information for establishing the RT4 operating combination.

  The sub CPU 71 of the present embodiment constitutes a navigation point giving means, a mode determining means, a first special mode changing means, a second special mode changing means, and a navigation information notifying means according to the present invention.

  The sub ROM 72 has a program storage area for storing programs executed by the sub CPU 71 and a data storage area for storing various tables. The program storage area is based on the operating system, the device driver, the main board communication task for controlling communication with the main control circuit 60, the sound control task for controlling the sound output from the speakers 21L and 21R, and the contents of the effects. Then, a drawing task for controlling display of images by the liquid crystal display device 5 is stored. On the other hand, the data storage area includes a table storage area for storing an effect determination table and the like, a drawing control data storage area for storing animation data such as character object data, and a sound control data storage area for storing sound data such as BGM and sound effects , Etc.

  The sub RAM 73 is used as temporary work storage means when the sub CPU 71 executes each program. For example, the sub RAM 73 stores information such as commands transmitted from the main control circuit 60, effect content information, game state information, internal winning combination information, display combination information, various counters, and various flags.

  The rendering processor 74 performs a process for displaying an image on the liquid crystal display device 5 based on an image display command or the like received from the sub CPU 71. Data necessary for processing performed by the rendering processor 74 is expanded in the drawing SDRAM 75 at the time of activation. The rendering processor 74 generates image data by superimposing the image data developed on the drawing SDRAM 75 in order from the background image located at the rear to the image located at the front, and supplies the image data to the liquid crystal display device 5 via the driver 77. To do. As a result, an image corresponding to the effect content determined by the sub CPU 71 is displayed on the liquid crystal display device 5.

  The drawing SDRAM 75 has two frame buffers 76 of a writing image data area and a display image data area. The writing image data area stores image data generated by the rendering processor 74 and displays a display image. The image data area stores image data to be displayed on the liquid crystal display device 5. The rendering processor 74 causes the liquid crystal display device 5 to sequentially display image data by alternately switching these frame buffers (that is, the banks are switched).

  The A / D converter 78 converts the sound data in the digital format selected by the sub CPU 71 based on the contents of the effect into sound data in the analog format, and transmits it to the amplifier 79. The amplifier 79 amplifies the analog-format sound data received from the A / D converter 78 based on the volume adjusted by a volume adjustment knob (not shown) provided in the gaming machine 1, and the speakers 21L and 21R. Send to. As a result, a sound corresponding to the effect content determined by the sub CPU 71 is output from the speakers 21L and 21R.

  Next, an internal lottery table determination table stored in the ROM 32 of the main control circuit 60 will be described with reference to FIG. FIG. 6 is a diagram showing an example of an internal lottery table determination table of the gaming machine 1 in the present embodiment.

  In the internal lottery table determination table, an internal lottery table used for determining an internal winning combination in the internal lottery process (see FIGS. 99 and 100) and the number of lotteries are defined for each gaming state. Specifically, based on the internal lottery table determination table, when the gaming state is the general gaming state, it is determined that the general gaming state internal lottery table is used, and the gaming state is the RT1 gaming state. In this case, it is determined that the internal lottery table for RT1 gaming state is used, and when the gaming state is the RT2 gaming state, it is determined that the internal lottery table for RT2 gaming state is used, and the gaming state When RT is in the RT3 gaming state, it is determined that the RT3 gaming state internal lottery table is used. When the gaming state is the RT4 gaming state, the RT4 gaming state internal lottery table is used. When the gaming state is the RT5 gaming state, it is determined that the RT5 gaming state internal lottery table is used, and the gaming state is the RT6 gaming state. When the game state is in the state, it is determined that the RT6 gaming state internal lottery table is used. When the gaming state is the RB1 gaming state, it is determined that the RB1 gaming state internal lottery table is used. If the gaming state is the RB2 gaming state, it is determined that the internal lottery table for the RB2 gaming state is used.

  Further, based on the internal lottery table determination table, when the gaming state is the general gaming state, the RT1 gaming state, the RT2 gaming state, the RT3 gaming state, the RT4 gaming state, or the RT5 gaming state, “53” is set as the number of lotteries. When the gaming state is the RT6 gaming state, “49” is determined as the number of lotteries, and when the gaming state is the RB1 gaming state and the RB2 gaming state, “4” is determined as the number of lotteries.

  Next, an internal lottery table stored in the ROM 32 of the main control circuit 60 will be described with reference to FIGS. FIG. 7 is a diagram showing an example of a general gaming state internal lottery table of the gaming machine 1 in the present embodiment. FIG. 8 is a diagram illustrating an example of the RT1 gaming state internal lottery table of the gaming machine 1 according to the present embodiment. FIG. 9 is a diagram illustrating an example of the RT2 gaming state internal lottery table of the gaming machine 1 according to the present embodiment. FIG. 10 is a diagram illustrating an example of the RT3 gaming state internal lottery table of the gaming machine 1 according to the present embodiment. FIG. 11 is a diagram illustrating an example of the RT4 gaming state internal lottery table of the gaming machine 1 according to the present embodiment. FIG. 12 is a diagram illustrating an example of the RT5 gaming state internal lottery table of the gaming machine 1 according to the present embodiment. FIG. 13 is a diagram illustrating an example of the RT6 gaming state internal lottery table of the gaming machine 1 according to the present embodiment. FIG. 14 is a diagram illustrating an example of the internal lottery table for the RB1 gaming state of the gaming machine 1 in the present embodiment. FIG. 15 is a diagram showing an example of the internal lottery table for RB2 gaming state of the gaming machine 1 in the present embodiment.

  The internal lottery table is a table used when performing internal lottery, that is, when determining an internal winning combination in internal lottery processing (see FIGS. 99 and 100) described later. In the internal lottery table, lottery values and data pointers (small role / replay data pointer, bonus data pointer) are defined for each winning number. The lottery value is a numerical value used to determine the data pointer.

  Each internal lottery table defines a lottery value corresponding to each winning number for each set value. The internal lottery tables shown in FIGS. 7 to 15 show lottery values corresponding to the setting values “1” and “6”, and the lottery values corresponding to the setting values “2” to “5”. Is omitted.

  Next, a method for determining a data pointer using a lottery value, that is, an internal lottery method will be described. In the internal lottery, first, a random number value is extracted from a predetermined numerical range “0 to 65535”, and a lottery value corresponding to each winning number is sequentially subtracted from the extracted random number value and a digit is performed. This is done by determining whether or not. Digit is performed when the numerical value to be subtracted is smaller, in other words, when the result of subtraction is negative. For example, when the internal lottery table for the general gaming state in FIG. 7 is determined to be the internal lottery table, when the set value is “6” and the extracted random number value is “15”, the main CPU 31 first sets “15 ”Is subtracted from the lottery value“ 10 ”corresponding to the winning number“ 53 ”. The subtraction result is “15−10 = 5”, which is positive. Next, the main CPU 31 subtracts the lottery value “10” corresponding to the winning number “52” from the subtracted value “5”. The subtraction result is “5-10 = −5”, which is negative. Therefore, the main CPU 31 determines the winning number “52” as the internal winning combination, that is, “0” as the small combination / replay data pointer and “3” as the bonus data pointer. According to this internal lottery method, the larger the numerical value defined as the lottery value, the higher the possibility that the data pointer of the corresponding winning number will be determined. The winning probability of each winning number is “the lottery value corresponding to each winning number / the number of all random values that may be extracted (“ 65536 ”)”.

  Note that various types of lottery performed using lottery values, which will be described later, are the same as those for determining the data pointer. Hereinafter, the various lottery methods based on the lottery value are the same as the internal lottery method, and thus description thereof is omitted.

  The general gaming state internal lottery table shown in FIG. 7 is a table used in the general gaming state, and lottery values and data pointers corresponding to the winning numbers “1” to “53” are defined. The internal lottery table for a general gaming state has a numerical value of any one of “5”, “34”, and “35” as a small role / replay data pointer for the winning numbers “1” to “12”. And any one of “1” to “4” is defined as the bonus data pointer. Therefore, when the winning number “1” to the winning number “12” is determined, a plurality of bonus pointers are determined. At the same time as one or more of the small combinations or replays are determined as the internal winning combination, any bonus combination (BB1 to BB4) is determined as the internal winning combination.

  Further, the internal lottery table for the general gaming state defines any value from “1” to “37” as a small role / replay data pointer for the winning numbers “13” to “49”. Since the bonus data pointer is defined as “0”, when the winning number “13” to the winning number “49” is determined, one or more of a plurality of small roles or replays are determined. Only the winning combination is determined as an internal winning combination, and bonus combinations (BB1 to BB4) are not determined as internal winning combinations.

  In addition, the internal lottery table for the general gaming state defines a numerical value of “0” as the small role / replay data pointer for the winning numbers “50” to “53”, and “ Since any numerical value from “1” to “4” is defined, when the winning number “50” to the winning number “53” is determined, only one of the bonus combinations (BB1 to BB4) is given. It is determined as an internal winning combination.

  RT1 gaming state internal lottery table shown in FIG. 8, RT2 gaming state internal lottery table shown in FIG. 10, RT3 gaming state internal lottery table shown in FIG. 10, RT4 gaming state internal lottery table shown in FIG. The RT5 gaming state internal lottery table shown in FIG. 13 and the RT6 gaming state internal lottery table shown in FIG. 13 are used in the RT1 gaming state, the RT2 gaming state, the RT3 gaming state, the RT4 gaming state, the RT5 gaming state, and the RT6 gaming state, respectively. The winning number, the small role / replay data pointer, and the bonus data pointer are configured in the same manner as the general gaming state internal lottery table, and lottery numbers corresponding to the winning numbers “13” to “32” are selected. It is defined that the structure of the value is different from the internal lottery table for general gaming state. Also, the RT6 gaming state internal lottery table has a configuration in which the winning numbers “50” to “53” are removed.

  Here, attention is paid to the sum of lottery values (when the set value is “1”) corresponding to the small role / replay data pointers “1” to “20” in the internal lottery tables shown in FIGS. . First, the total value of lottery values corresponding to the small role / replay data pointers “1” to “20” in the internal lottery table for general gaming state is “8980”, and the lottery value in the internal lottery table for RT1 gaming state is The total value is “8980”, the total lottery value in the RT2 gaming state internal lottery table is “43046”, the total lottery value in the RT3 gaming state internal lottery table is “8980”, and RT4 The total value of lottery values in the internal lottery table for gaming state is “43046”, the total value of lottery values in the internal lottery table for RT5 gaming state is “8980”, and the lottery value in the internal lottery table for RT6 gaming state is The total value is “8980”.

  Since the small role / replay data pointers “1” to “20” correspond to any of the replays as described later, the general gaming state, the RT1 gaming state, the RT3 gaming state, the RT5 gaming state, and the RT6 gaming The replay winning probability in the state is “8980/65536 (about 13.70%)”, and the replay winning probability in the RT2 gaming state and the RT4 gaming state is “43046/65536 (about 65.68%)”.

  Thus, changing only the lottery value corresponding to the replay according to the game state leads to changing only the replay winning probability and not changing the winning probability of other combinations. Furthermore, changing only the replay winning probability and not changing the winning probability of other roles will change the probability (losing probability) of losing in internal lottery (no role will be determined as an internal winning combination). It leads to. Specifically, when the winning probability of a role other than replay is fixed, increasing only the replay winning probability (increasing the lottery value) leads to lowering the loss probability, and lowering only the replay winning probability. That (decreasing the lottery value) leads to an increase in the loss probability. That is, the larger the lottery value corresponding to the replay, the more advantageous for the player, and the smaller the lottery value corresponding to the replay, the more disadvantageous for the player. Therefore, when the game states are arranged in order from the player's advantage, RT2 gaming state = RT4 gaming state> general gaming state = RT1 gaming state = RT3 gaming state = RT5 gaming state = RT6 gaming state (RB1 gaming described later) State, except RB2 gaming state).

  In the RB1 gaming state internal lottery table shown in FIG. 14 and the RB2 gaming state internal lottery table shown in FIG. 15, lottery values and data pointers corresponding to the winning numbers “1” to “4” are defined. . In the RB1 gaming state or the RB2 gaming state, any one of “21”, “34”, “36”, and “37” is used as the data pointer for the small role / replay for the winning numbers “1” to “4”. Numeric values are defined, and lottery values corresponding to each winning number are defined so that the total of the lottery values is “65536”. Therefore, in the RB1 gaming state or the RB2 gaming state, the small winning combination is determined as the internal winning combination with a probability of “65536/65536 (100%)”, and the player is advantageous in the RB1 gaming state or the RB2 gaming state. You can play games.

  In the present embodiment, each internal lottery table defines a lottery value corresponding to the winning number, but the lottery value is a ratio with respect to “0 to 65535” that is a range in which random number values are extracted. Therefore, instead of the lottery value, a random number width (for example, “0 to 654”) corresponding to each winning number can be defined as the winning range. Specifically, an internal winning combination can be determined by determining which winning number corresponds to which winning number corresponds to the random number value. That is, defining each lottery value by each internal lottery table is synonymous with defining a random number width (winning range) for each combination or combination.

  Next, with reference to FIG. 16 to FIG. 19, the internal winning combination determination table for bonus combination / replay and the internal winning combination determination table for bonus stored in the ROM 32 of the main control circuit 60 will be described. 16 and 17 are diagrams showing examples of the internal winning combination determination table (replay) for the small combination / replay of the gaming machine 1 in the present embodiment. FIG. 18 is a diagram showing an example of a small winning combination / replay internal winning combination determining table (small winning combination) of the gaming machine 1 in the present embodiment. FIG. 19 is a diagram showing an example of a bonus internal winning combination determination table for the gaming machine 1 in the present embodiment. Hereinafter, the small winning combination / replay internal winning combination determining table and the bonus internal winning combination determining table are collectively referred to as an internal winning combination determining table.

  The internal winning combination determination table is a table used when determining an internal winning combination based on the data pointer in an internal lottery process (see FIGS. 99 and 100) described later. In the internal winning combination determination table, each combination that can be determined as an internal winning combination corresponding to the data pointer is defined. Each combination corresponds to each bit stored in an internal winning combination storage area described later. Therefore, it is possible to identify which combination is an internal winning combination by determining which bit in the internal winning combination storing area is “1”.

  In the small winning combination / replay internal winning combination determination table (replay) shown in FIGS. 16 and 17, internal winning combinations corresponding to the small winning combination / replay data pointers “0” to “20” are defined. Specifically, the small role / replay data pointer “0” corresponds to a loss, and the small role / replay data pointers “1” to “20” are any of the replays (7 replays (center)). 1-8, 7 replay (top) 1-16, 7 replay (bottom) 1-8, 7 replay (crossdown) 1-16, 7 replay (crossup) 1-4, replay (center) 1-8, Replay (top) 1-14, Replay (bottom) 1-8, Replay (crossdown) 1-12, Replay (crossup) 1-8, Cherry replay A (left push) 1-12, Cherry replay B (left Press) 1-12 and Cherry Replay B (RT3) 1-8). For example, the small role / replay data pointer “1” corresponds to replay (center) 1 to 8 and replay (bottom) 1 to 8.

  In the small winning combination / replay internal winning combination determining table (small winning combination) shown in FIG. 18, internal winning combinations corresponding to the small winning combination / replay data pointers “21” to “37” are defined. Specifically, the small role / replay data pointers “21” to “37” indicate any small role (cherry, watermelon (center), watermelon (cross down), bell (center) 1-8, bell ( Top) 1-12, bell (bottom) 1-16, bell (crossdown) 1-8, bell (crossup) 1-12). For example, the small character / replay data pointer “35” corresponds to watermelon (center) and watermelon (cross down). Hereinafter, the bell (center) 1 to 8, the bell (top) 1 to 12, the bell (bottom) 1 to 16, the bell (cross down) 1 to 8, and the bell (cross up) 1 to 12 are collectively referred to as a bell role. There is a case.

  In the bonus internal winning combination determination table shown in FIG. 19, internal winning combinations corresponding to bonus data pointers “0” to “4” are defined. Specifically, the bonus data pointer “0” corresponds to a loss, the bonus data pointer 1 corresponds to BB1, the bonus data pointer 2 corresponds to BB2, and the bonus The data pointer for data 3 corresponds to BB3, and the data pointer for bonus 4 corresponds to BB4.

  Next, the symbol combination table stored in the ROM 32 of the main control circuit 60 will be described with reference to FIGS. 20 to 24 are diagrams each showing a part of the symbol combination table, and FIGS. 20 and 21 are diagrams showing examples of the symbol combination table (replay) of the gaming machine 1 in the present embodiment. FIG. 22 is a diagram showing an example of the symbol combination table (small role) of the gaming machine 1 in this embodiment, and FIG. 23 is an example of the symbol combination table (bonus) of the gaming machine 1 in this embodiment. FIG.

  In the symbol combination table, a combination of symbols relating to privilege grant displayed on the active line (center line 8c), or a symbol combination relating to the transition of the gaming state / actuation state and a display corresponding to the symbol combination Data indicating a combination, storage area type, and number of payouts are defined. The data indicating the display combination is any one of a display combination storage area 1 to a display combination storage area 29 each of which will be described later (display combination storage area 1 to display combination storage area 29 are collectively referred to as a display combination storage area). Is stored in the data. Further, in which display combination storage area the data is stored is defined by the storage area type.

  In the symbol combination table, 7 replays (center) 1-8, 7 replays (top) 1-16, 7 replays (bottom) 1-8, 7 replays (crossdown) 1-16, 7 replays are displayed as display combinations. Cross up) 1-4, replay (center) 1-8, replay (top) 1-14, replay (bottom) 1-8, replay (cross down) 1-12, replay (cross up) 1-8, cherry Replay A (left push) 1-12, Cherry Replay B (left push) 1-12, Cherry Replay B (RT3) 1-8, Cherry, Watermelon (Center), Watermelon (Crossdown), Bell (Center) 1 8, bell (top) 1-12, bell (bottom) 1-16, bell (cross down) 1-8, bell (cross up) 1-12, BB1-BB4, RT operation diagram (General) 1 to 8, RT operation symbol (RT1) 1 to 32 are defined.

  7 replays (centers) 1 to 8 are displayed by displaying “red 7A symbol / red 7B symbol-red 7A symbol / red 7B symbol-red 7A symbol / red 7B symbol” on the active line (center line 8c). To establish. When any of the 7 replays (centers) 1 to 8 is established, the replay is performed in the next game (7 replays (top) 1 to 16, 7 replays (bottom) 1 to 8, 7 replays (cross down) ) 1-16, 7 Replay (cross-up) 1-4, Replay (center) 1-8, Replay (top) 1-14, Replay (bottom) 1-8, Replay (crossdown) 1-12, Replay ( Cross-up) 1-8, Cherry Replay A (Left Press) 1-12, Cherry Replay B (Left Press) 1-12, Cherry Replay B (RT3) 1-8 Replay is performed in the game). That is, the same number of medals as the number of inserted coins in a game in which any one of 7 replays (centers) 1 to 8 is established is automatically inserted in the next game without being based on the player's insertion operation. Thereby, the player can play the next game without consuming medals. Here, the above-mentioned medal payout and re-game are examples of giving game value.

  7 replays (top) 1 to 16, 7 replays (bottom) 1 to 8, 7 replays (cross down) 1 to 16, 7 replays (cross up) 1 to 4 are predetermined on the effective line (center line 8c). It is established by displaying a combination of symbols (for example, in the case of 7 replays (top) 1, a combination of “bell A symbol-bell A symbol-replay A symbol”). When a combination of symbols related to 7 replays (tops) 1 to 16 is displayed on the active line, “red 7A symbol / red 7B symbol-red 7A symbol / red 7B symbol is displayed on the top line 8b which is a pseudo winning line. -When a red 7A symbol / red 7B symbol "is displayed and a combination of symbols relating to 7 replays (bottoms) 1 to 8 is displayed on the active line, a red line 7d symbol / When the red 7B symbol-red 7A symbol / red 7B symbol-red 7A symbol / red 7B symbol "is displayed and the symbol combination relating to 7 replays (cross down) 1-16 is displayed on the active line, "Red 7A symbol / Red 7B symbol-Red 7A symbol / Red 7B symbol-Red 7A symbol / Red 7B symbol" is displayed on the cross-down line 8e which is a line, and 7 replays (cross-up) 1-4 When such a combination of symbols is displayed on the active line, “red 7A symbol / red 7B symbol-red 7A symbol / red 7B symbol-red 7A symbol / red 7B symbol” is displayed on the cross-up line 8a which is a pseudo winning line. Is displayed.

  As will be described later, the gaming state is the RT1 gaming state, the RT2 gaming state, or the RT3 gaming state, and 7 replays (center) 1 to 8, 7 replays (top) 1 to 16, 7 replays on the active line. When (bottom) 1-8, 7 replay (cross down) 1-16, 7 replay (cross up) 1-4 are displayed, it shifts to the RT4 gaming state (hereinafter 7 replay (center) 1-8. 7 replay (top) 1 to 16, 7 replay (bottom) 1 to 8, 7 replay (cross down) 1 to 16, and 7 replay (cross up) 1 to 4 may be referred to as RT4 actuators. Further, as described above, when the RT4 act is displayed on the active line, the top line 8b, the cross-down line 8e, the bottom line 8d, and the class up line 8a which are on the active line (center line 8c) or pseudo pay lines are displayed. "Red 7A symbol / Red 7B symbol-Red 7A symbol / Red 7B symbol-Red 7A symbol / Red 7B symbol" is displayed on any of the lines, so the player can easily transition to the RT4 gaming state Can be recognized.

  Replay (center) 1-8 is established by displaying “Replay A symbol / Replay B symbol-Replay A symbol / Replay B symbol-Replay A symbol / Replay B symbol” on the active line (center line 8c). To do.

  Replay (top) 1-14, Replay (bottom) 1-8, Replay (crossdown) 1-12, Replay (crossup) 1-8 are combinations of predetermined symbols on the effective line (center line 8c) ( For example, in the case of replay (top) 1, it is established by displaying “a combination of watermelon symbol-red 7A symbol-bell A symbol”). When the symbol combinations related to Replay (Top) 1 to 14 are displayed on the active line, “Replay A Symbol / Replay B Symbol—Replay A Symbol / Replay B Symbol— When the “replay A symbol / replay B symbol” is displayed and the symbol combination relating to the replay (bottom) 1 to 8 is displayed on the active line, the “replay A symbol / replay B” is displayed on the bottom line 8d which is the pseudo winning line. When the symbol-replay A symbol / replay B symbol-replay A symbol / replay B symbol "is displayed and the symbol combination relating to replay (crossdown) 1-12 is displayed on the active line, it is a pseudo winning line. In the cross down line 8e, “Replay A symbol / Replay B symbol—Replay A symbol / Replay B symbol—Replay A” When the “pattern / replay B symbol” is displayed and the symbol combination relating to the replay (cross-up) 1 to 8 is displayed on the active line, the “replay A symbol / replay B” is displayed on the cross-up line 8a which is a pseudo winning line. Symbol-Replay A symbol / Replay B symbol-Replay A symbol / Replay B symbol "is displayed.

  As will be described later, the gaming state is the RT1 gaming state, the RT4 gaming state, or the RT5 gaming state, and the replay (center) 1 to 8, the replay (bottom) 1 to 8, or the RT described later on the active line. When one of the operating roles (general) 1 to 8 is displayed, the state shifts to the general gaming state (hereinafter, replay (center) 1 to 8, replay (bottom) 1 to 8, and RT operating role (to be described later) General) 1 to 8 may be collectively referred to as a general gaming state operating combination). Further, as will be described later, when the gaming state is the RT1 gaming state or the RT4 gaming state and any one of the replays (cross-ups) 1 to 8 is established, the state shifts to the RT2 gaming state (hereinafter referred to as replay ( (Cross-up) 1-8 may be called RT2 actuators). Further, as will be described later, the gaming state is the RT1 gaming state or the RT4 gaming state, and replay (top) 1 to 14, or cherry replay A (left push) 1 to 12, which will be described later, cherry replay B (left push) ) 1 to 12, and Cherry Replay B (RT3) 1 to 8 is established, and then transitions to the RT3 gaming state (hereinafter, Replay (Top) 1 to 14, Cherry Replay A (Left Press) 1 to 12) Cherry replay B (left push) 1-12, cherry replay B (RT3) 1-8 may be referred to as RT3 actuators).

  Cherry replay A (left push) 1-12, cherry replay B (left push) 1-12, and cherry replay B (RT3) 1-8 are combinations of predetermined symbols (for example, cherry replay A (left In the case of 1), it is established by displaying “a combination of red 7A symbol-bell A symbol-replay A symbol”. When any one of cherry replay A (left push) 1 to 12, cherry replay B (left push) 1 to 12, and cherry replay B (RT3) 1 to 8 is displayed on the active line, any pseudo “Cherry symbol-ANY symbol-ANY symbol” is displayed on the winning line. “ANY” represents that any symbol may be used.

  Cherry, watermelon (center), watermelon (cross down), bell (center) 1-8, bell (top) 1-12, bell (bottom) 1-16, bell (cross down) 1-8, bell (cross up) ) 1 to 12 are established when a predetermined symbol combination (see FIG. 22) is displayed on the active line, and medals are paid out according to the established combination.

  BB1, BB2, BB3, and BB4 are established by displaying a predetermined symbol combination (see FIG. 23) on the active line. When BB1 or BB2 is established, the BB1 gaming state is subsequently established, and when BB3 or BB4 is established, the BB2 gaming state is thereafter established. The gaming machine 1 continuously operates in the RB1 gaming state or the RB2 gaming state until the payout number of medals exceeds 160 in the BB1 gaming state or the BB2 gaming state. Further, the RB1 gaming state or the RB2 gaming state is terminated when the number of games reaches eight times or when the number of winnings reaches eight. However, even if the RB1 gaming state or the RB2 gaming state end condition is not satisfied, if the BB1 gaming state or the BB2 gaming state ends because the number of medals paid out exceeds 160, RB1 The gaming state or the RB2 gaming state is also terminated accordingly.

  Next, the symbol combination table (RT operation symbol) stored in the ROM 32 of the main control circuit 60 will be described with reference to FIG. FIG. 24 is a diagram showing an example of a symbol combination table (RT operation symbol) of the gaming machine 1 in the present embodiment.

  In the symbol combination table (RT action symbol), a combination of symbols displayed on the active line (center line 8c) related to the transition of the game state / actuation state, and data indicating a display combination corresponding to the symbol combination; The storage area type and the number of payouts are defined. The data indicating the display combination is data stored in any one of the display combination storage area 30 to the RT action symbol storage area 34 each having 1 byte, which will be described later. Further, in which display combination storage area the data is stored is defined by the storage area type.

  In the symbol combination table (RT operation symbol), RT operation symbols (general) 1 to 8 and RT operation symbols (RT1) 1 to 32 are defined as display combinations.

  RT operation symbols (general) 1 to 8 are combinations of predetermined symbols on the effective line (for example, in the case of RT operation symbol (general) 1, the combination of “replay A symbol-bell A symbol-bell A symbol”) ) Is displayed. As will be described later, when the gaming state is the RT1 gaming state, the RT2 gaming state, the RT4 gaming state, or the RT5 gaming state, any one of the RT operation symbols (general) 1 to 8 is displayed on the active line. When played, the gaming state transitions to the general gaming state.

  RT action symbols (RT1) 1 to 32 are combinations of predetermined symbols on the active line (for example, in the case of RT action symbol (RT1) 1, the combination of “Replay A symbol-Replay A symbol-Red 7A symbol”) ) Is displayed. As will be described later, when the gaming state is the general gaming state, the RT3 gaming state, the RT4 gaming state, or the RT5 gaming state, any of the RT action symbols (RT1) 1 to 32 is displayed on the active line. The gaming state transitions to the RT1 gaming state. Hereinafter, the RT operation symbols (RT1) 1 to 32 may be collectively referred to as an RT1 operation combination.

  Next, with reference to FIG. 25, the transition of the gaming state in the gaming machine 1 will be described. FIG. 25 is a diagram illustrating an example of the transition of the gaming state of the gaming machine 1 in the present embodiment. The gaming state of the gaming machine 1 includes a general gaming state, an RT1 gaming state, an RT2 gaming state, an RT3 gaming state, an RT4 gaming state, an RT5 gaming state, an RT6 gaming state, a BB1 gaming state, and a BB2 gaming state (hereinafter referred to as BB1 gaming state). The BB2 gaming state is collectively referred to as the BB gaming state.) There are the RB1 gaming state and the RB2 gaming state (hereinafter, the RB1 gaming state and the RB2 gaming state are collectively referred to as the RB gaming state). These various game states are basically distinguished by the type of a role that may be determined as an internal winning combination, the winning probability of an internal winning combination, the type of a winning combination, and the like.

  First, the operating conditions in the general gaming state will be described. The general game state is a general game state actuator (RT operation symbols (general) 1 to 8, replay (center) 1 to 8, replay) in an RT1 game state, an RT2 game state, an RT4 game state, or an RT5 game state, which will be described later. The operation is performed based on the fact that (bottom) 1 to 8) is established.

  Next, the operating conditions of the RT1 gaming state will be described. The RT1 gaming state is based on the fact that an RT1 act (RT act symbol (RT1) 1-32) is established in the general gaming state, the RT2 gaming state, the RT3 gaming state, the RT4 gaming state, or the RT5 gaming state. Operated.

  Next, the operating conditions of the RT2 gaming state will be described. The RT2 gaming state is actuated based on the fact that an RT2 actuator (any one of replays (cross-ups) 1 to 8) is established in the RT1 gaming state or the RT4 gaming state.

  Next, the operating conditions of the RT3 gaming state will be described. In the RT3 gaming state, in the RT1 gaming state or the RT4 gaming state, the RT3 actuator (cherry replay A (left push) 1 to 12, cherry replay B (left push) 1 to 12, cherry replay B (RT3) 1 to 8 , Any one of the replays (top) 1 to 14) is established.

  Next, the operating conditions of the RT4 gaming state will be described. The RT4 gaming state is the RT4 gaming state (7 replay (center) 1-8, 7 replay (top) 1-16, 7 replay (bottom) 1-8, 7) in the RT1 gaming state, the RT2 gaming state, or the RT3 gaming state. It is operated based on the fact that any one of replay (cross down) 1 to 16 and 7 replay (cross up) 1 to 4 is established.

  Next, the operating conditions of the RT5 gaming state will be described. The RT5 gaming state is activated based on the completion of paying out a predetermined number (160) of medals in the BB gaming state (RB gaming state).

  Next, the operating conditions in the RT6 gaming state will be described. The RT6 gaming state is BB1, BB2, BB3, or BB4 (hereinafter collectively referred to as BB1 to BB4) in the general gaming state, the RT1 gaming state, the RT2 gaming state, the RT3 gaming state, the RT4 gaming state, or the RT5 gaming state. ) Is operated based on the determination that the internal winning combination is determined, and the process ends when the BB operating combination is established. That is, the RT6 gaming state corresponds to a state where the BB operating combination is carried over as an internal winning combination.

  In the BB gaming state (RB gaming state), the RB gaming state continuously operates until the number of medals paid out exceeds 160, and the RB gaming state reaches the number of games of 8 times, or The game ends when the number of winnings reaches eight.

  In the RT2 gaming state or the RT4 gaming state, as described above, the replay winning probability is high, the probability of falling out of the internal lottery decreases, and the probability that any replay is determined to be an internal winning combination increases. , Medal reduction rate is suppressed. Accordingly, the player can advantageously play a game by continuing to transition between the RT2 gaming state and the RT4 gaming state.

  Next, referring to FIG. 26, the stop operation sequence and establishment when the small role / replay data pointers “0” to “37” are determined by the internal lottery processing described later with reference to FIGS. 99 and 100 are established. The relationship with the winning combination (only the winning combination relating to the game state transition) will be described.

  As shown in FIG. 26, when “0” (losing) is determined as the small role / replay data pointer, there is a possibility that the general gaming state operating combination is established according to the stop operation order. Specifically, when the first stop operation is performed on a reel other than the left reel 3L, the general gaming state operating combination is established. On the other hand, when the first stop operation is performed on the left reel 3L, the winning combination relating to the transition of the gaming state is not established.

  Thus, in the present embodiment, in the RT1 gaming state to the RT4 gaming state, when “0” is determined as the small role / replay data pointer, if the first stop operation for the left reel 3L is not performed, RT4 It is recommended to perform the first stop operation on the left reel 3L because it shifts to the general gaming state that does not shift to the gaming state.

  When “1” is determined as the small combination / replay data pointer, the general gaming state operating combination is established in any stop operation order.

  In addition, when “2”, “5”, “21”, “34” to “37” are determined as the small role / replay data pointer, the transition of the gaming state is performed in any stop operation order. The role related to is not established.

  When “3” is determined as the small role / replay data pointer, either the RT2 operating role or the RT3 operating role is established according to the stop operation order. Specifically, when the first stop operation is performed on the left reel 3L, the RT3 act is established, and when the first stop operation is performed on a reel other than the left reel, RT2 working combination is established. In addition, when “4” is determined as the small role / replay data pointer, the RT3 working combination is established in any stop operation order.

  When “6” to “10” are determined as the small combination / replay data pointer, either the general gaming state operating combination or the RT2 operating combination is established according to the stop operation order. For example, when “6” is determined as the data pointer for the small role / replay, the first stop operation is performed on the left reel 3L, the second stop operation is performed on the middle reel 3C, and the third stop operation is performed. Is performed on the right reel 3R, the RT2 operating combination is established. On the other hand, when a stop operation is performed in the other stop operation order, a general gaming state operating combination is established. The relationship between the stop operation sequence when “7” to “10” are determined as the small combination / replay data pointer and the combination related to the transition of the established gaming state is as shown in FIG. .

  In addition, when “11” to “13”, “17”, “18” are determined as the small role / replay data pointers, the general gaming state operating role, the RT2 operating role, RT4 according to the stop operation order. One of the operating combinations is established. For example, when “11” is determined as the data pointer for the small role / replay, the first stop operation is performed on the left reel 3L, and the second stop operation is performed on the middle reel 3C. Is performed on the right reel 3R, the RT2 operating combination is established. Further, when the first stop operation is performed on the right reel 3R, the second stop operation is performed on the left reel 3L, and the third stop operation is performed on the middle reel 3C, the RT4 operating combination is established. On the other hand, when a stop operation is performed in the other stop operation order, a general gaming state operating combination is established. Regarding the relationship between the stop operation sequence when “12”, “13”, “17”, and “18” are determined as the small role / replay data pointers, and the role related to the transition of the established game state, see FIG. 26.

  In addition, when “14” to “16” are determined as the small role / replay data pointers, the general gaming state operating role, the RT2 operating role, the RT3 operating role, and the RT4 operating role are selected according to the stop operation order. Either actuating role is established. For example, when “14” is determined as the small role / replay data pointer, the first stop operation is performed on the left reel 3L, the second stop operation is performed on the middle reel C, and the third stop operation is performed. When performed on the right reel 3R, the RT2 operating combination is established. Further, when the first stop operation is performed on the middle reel 3C, the second stop operation is performed on the left reel 3L, and the third stop operation is performed on the right reel 3R, the RT4 operating combination is established. Further, when the first stop operation is performed on the middle reel 3C, the second stop operation is performed on the right reel 3R, and the third stop operation is performed on the left reel 3L, the RT3 operating combination is established. On the other hand, when a stop operation is performed in the other stop operation order, a general gaming state operating combination is established. The relationship between the stop operation sequence when “15” and “16” are determined as the small combination / replay data pointer and the combination related to the transition of the established gaming state is as shown in FIG.

  Further, when “19” is determined as the data pointer for the small part / replay, there is a possibility that the RT4 working part is established according to the stop operation order. Specifically, when the first stop operation is performed on the left reel 3L, the RT4 operating combination is established. On the other hand, when the first stop operation is performed on a reel other than the left reel 3L, the winning combination relating to the transition of the gaming state is not established.

  When “20” is determined as the small role / replay data pointer, any one of the general gaming state operating combination, the RT3 operating combination, and the RT4 operating combination is established according to the stop operation order. Specifically, when the first stop operation is performed on the middle reel 3C, the second stop operation is performed on the right reel 3R, and the third stop operation is performed on the left reel 3L, the RT3 actuator is To establish. Further, when the first stop operation is performed on the right reel 3R, the second stop operation is performed on the middle reel 3C, and the third stop operation is performed on the left reel 3L, the general gaming state operating combination is established. To do. On the other hand, when the stop operation is performed in the other stop operation order, the RT4 operating combination is established.

  As described above, when “11” to “20” are determined as the small role / replay data pointer, the RT4 working combination can be established by performing the stop operation in a predetermined stop operation sequence. . Hereinafter, the internal winning combination corresponding to the small combination / replay data pointers “11” to “20” may be referred to as an RT4 establishment possible combination.

  Further, when “21” to “33” are determined as the small combination / replay data pointers, there is a possibility that the RT1 operating combination is established in accordance with the stop operation order, and the state shifts to the RT1 gaming state. For example, when any of “21” to “25” is determined as the small role / replay data pointer and the first stop operation is performed on a reel other than the left reel 3L, An RT action combination (any of RT action symbols (RT1) 1 to 32) is established, and a transition is made to the RT1 gaming state. The stop operation sequence and the transfer destination game state when “26” to “33” are determined as the small role / replay data pointers are as shown in FIG. 26 and will not be described in detail.

  Next, with reference to FIG. 27, a bonus operation time table stored in the ROM 32 of the main control circuit 60 will be described. FIG. 27 is a diagram showing an example of the bonus operation time table of the gaming machine 1 in the present embodiment.

  The bonus operating time table is a table used when setting conditions for ending the BB gaming state and the RB gaming state. In the bonus operation time table, end conditions relating to the BB1 gaming state, the BB2 gaming state, the RB1 gaming state, and the RB2 gaming state are defined. Specifically, in the bonus operation time table, “160” is defined for the value of the bonus end number counter as the end condition of the BB1 gaming state and the BB2 gaming state. Further, in the bonus operation time table, “8” and “8” are defined for the values of the number of possible games and the number of possible winnings, respectively, as termination conditions for the RB1 gaming state and the RB2 gaming state. That is, in the gaming machine 1, the BB1 gaming state and the BB2 gaming state are terminated when the number of medals paid out exceeds 160, and the RB1 gaming state and the RB2 gaming state are played eight times. Or it ends by winning 8 times.

  Next, with reference to FIG. 28, the rotating cylinder stop initial setting table stored in the ROM 32 of the main control circuit 60 will be described. FIG. 28 is a diagram showing an example of the turning stop initial setting table of the gaming machine 1 in the present embodiment.

  The reeling stop initial setting table acquires either the pulling priority order table selection number or the pulling priority order table number based on the number for turning stop in the reel stop initial setting process described later with reference to FIG. This table is also used when acquiring line data, stop table number, and change data selection number for each stop button based on the turning stop number in the reel stop initial setting process. The acquired line data and stop table number are stored for each stop button in stop table selection value storage areas 1 to 3 to be described later with reference to FIG.

  Next, the pull-in priority table selection table stored in the ROM 32 of the main control circuit 60 will be described with reference to FIG. FIG. 29 is a diagram showing an example of a pull-in priority table selection table of the gaming machine 1 in this embodiment.

  The pull-in priority table selection table is the pull-in priority table selection number for the first stop or the second / second pull-in table based on the pull-in priority table selection number in the pull-in priority table selection process to be described later with reference to FIG. 3 is a table used when acquiring a pull-in priority table number for stopping. The pull-in priority table selection table is not referred to when the pull-in priority table number is acquired based on the rotation stop initial setting table (FIG. 28).

  Next, the priority table stored in the ROM 32 of the main control circuit 60 will be described with reference to FIG. FIG. 30 (a) is a diagram showing an example of the priority table (retraction priority table number: PLVLTB00) of the gaming machine 1 in the present embodiment, and FIG. 30 (b) is a gaming machine in the present embodiment. It is a figure which shows the example of 1 priority order table (drawing priority order table number: PLVLTB01).

  The priority table is a table used when acquiring the acquisition priority data in the acquisition priority acquisition process to be described later with reference to FIG. In the present embodiment, two types of priority order tables are selectively used according to the pull-in priority order table numbers (PLVLTB00 and PLVLTB01). The priority table shows the priority for each combination that can be determined as an internal winning combination (priority 1 to priority 5 if the drawing priority table number is PLVLTB00, and priority if the drawing priority table number is PLVLTB01). Only the first rank) is prescribed. In the priority table (withdrawal priority table number: PLVLTB00), the first priority (highest priority) is the role constituting the Replay A group, and the second priority is the role constituting the Replay B group. Yes, the 3rd priority is Cherry and all bells, the 4th priority is all watermelons, and the 5th priority is a bonus combination (BB1 to BB4). On the other hand, in the priority order table (withdrawal priority order table number: PLVLTB01), there is no difference in the priority order of all the combinations, and all the combinations have the first priority.

  Although not shown in FIG. 30, in the priority order table, the pull-in data having the same configuration as that of the display combination storing area described later with reference to FIG. 46 is defined for each priority order. Accordingly, the bit corresponding to the corresponding role is “1”. For example, the pull-in data with the third priority in the priority table (pull-in priority table number: PLVLTB00) is the bit 0 of the storage area type 20 corresponding to cherry and the storage area type corresponding to bell (center) 1-8. 21 bits 0-7, bits 0-7 of storage area type 22 corresponding to bell (top) 1-12, bits 0-3 of storage area type 23, and storage corresponding to bell (bottom) 1-16 Bits 0-7 of area type 24, bits 0-7 of storage area type 25, bits 0-7 of storage area type 26 corresponding to bell (cross down) 1-8, and bell (cross up) 1-12 Bits 0 to 7 of the storage area type 27 and bits 0 to 3 of the storage area type 28 corresponding to “1” are “1”.

  Next, the stop table stored in the ROM 32 of the main control circuit 60 will be described with reference to FIGS. In addition, in FIG. 31 (a)-FIG.33 (b), the example of the stop table 101 (stop table number: 101)-stop table 110 (stop table number: 110) of the gaming machine 1 in this embodiment is shown. Moreover, in FIG.33 (c)-FIG.36 (b), the example of the stop table 201 (stop table number: 201)-stop table 212 (stop table number: 212) of the game machine 1 in this embodiment is shown, 36 (c) to 39 (b) show examples of the stop table 301 (stop table number: 301) to the stop table 312 (stop table number: 312) of the gaming machine 1 in this embodiment.

  The stop table is a table used when acquiring the sliding frame number determination data in the sliding frame number determination process described later with reference to FIG. The stop table defines the slip data number determination data corresponding to the line data and the stop start position. In FIG. 31 to FIG. 39, the stop table number is described in decimal, and the hundreds represents the type of reel. That is, stop table 101 (stop table number: 101) to stop table 110 (stop table number: 110) having hundreds of “1” is a stop table for the left reel. Similarly, stop table 201 (stop table number: 201) to stop table 212 (stop table number: 212) whose hundreds place is “2” is a stop table for the middle reel, and hundreds place is “3”. Stop table 301 (stop table number: 301) to stop table 312 (stop table number: 312) are stop tables for the right reel.

  Next, the priority order table stored in the ROM 32 of the main control circuit 60 will be described with reference to FIG. FIG. 40 is a diagram illustrating an example of a priority order table of the gaming machine 1 in the present embodiment.

  The priority order table is a table used when acquiring the number of provisional sliding frames for determining the number of sliding frames in the priority pull-in control process to be described later with reference to FIG. In the priority order table, the number of provisional sliding frames is defined according to the sliding frame determination data and the priority order. The priority order table can be applied as the number of sliding frames from a predetermined number of frames (ie, “0” frame to “4” frame), and the number of sliding frames having a higher priority is searched. It defines the order of going. For example, when the sliding frame number determination data acquired based on the stop table is “1”, first, the sliding frame number “4” having the fifth priority order is applicable as the sliding frame number. Search for. Next, the number of sliding frames “2” with the fourth priority order, the number of sliding frames “0” with the third priority order, the number of sliding frames “3” with the second priority order, and the priority order It is searched for the number of sliding frames which can be applied as the number of sliding frames in the order of the first sliding frame number “1” and which has a higher priority than the number of sliding frames searched previously. Note that the priority order table defines that the value indicated by the sliding frame number determination data corresponds to the number of sliding frames having the first priority order.

  Next, the first post-stop change data table selection value determination table stored in the ROM 32 of the main control circuit 60 will be described with reference to FIG. FIG. 41 is a diagram illustrating an example of the first post-stop change data table selection value determination table of the gaming machine 1 in the present embodiment.

  The first post-stop change data table selection value determination table is a table used when acquiring the change data table selection value in the first post-stop stop data storage process to be described later with reference to FIG. In the first post-stop change data table selection value determination table, a change data table selection value is defined according to the planned stop position and the change data selection number.

  Next, with reference to FIG. 42, the first post-stop change stop table number determination table stored in the ROM 32 of the main control circuit 60 will be described. FIG. 42 is a diagram showing an example of a first stop-after change stop table number determination table for the gaming machine 1 in the present embodiment.

  The first post-stop change stop table number determination table obtains line data and stop table numbers corresponding to the stop table selection value storage areas 1 to 4 in the first post-stop stop data storage process to be described later with reference to FIG. It is a table used at the time. The first stop stop change table number determination table defines line data and stop table numbers to be stored in each stop table selection value storage area according to the change data selection number and the change data table selection value. . Note that if the change data table selection value is not acquired based on the first post-stop change data table selection value determination table (FIG. 41), the first post-stop change stop table number determination table is not referred to. .

  Next, the second post-stop change data table selection table and the stop position check data selection table stored in the ROM 32 of the main control circuit 60 will be described with reference to FIGS. 43 and 44. FIG. 43 is a diagram showing an example of the second post-stop change data table selection table of the gaming machine 1 in the present embodiment, and FIG. 44 shows the stop position check data selection table of the gaming machine 1 in the present embodiment. It is a figure which shows an example.

  Whether or not the second post-stop change data table selection table needs to change the line data and stop table number of the stop table selection value storage area 2 in the second post-stop stop data storage process described later with reference to FIG. This is a table used when determining whether or not a change is necessary and acquiring the change contents. The second post-stop change data table selection table first defines whether or not a stop position check is necessary according to the types of the first stop reel and the second stop reel. Specifically, it is defined that the stop position check is necessary when the first stop reel is “left”, and the stop position check is not necessary when the first stop reel is not “left”. is doing.

  When the stop position check is necessary, the stop position check is performed based on the stop position check data selection table (FIG. 44) and a position check data storage area described later with reference to FIG. In the position check data storage area, “1” is set in the bit corresponding to the symbol position indicating the planned stop position in order to identify the planned stop position determined for the already stopped reel. The stop position check calculates the logical product of the position check data and the stop position check data corresponding to each stop position check data selection value for each reel that has already stopped, and data with any bit being “1”. This is performed by checking whether there is any, and a corresponding stop position check data selection value is extracted as a check target. Here, an example is given in which the first stop reel is the left reel 3L and the planned stop position is “12”, the second stop reel is the middle reel 3L, and the planned stop position is “5”. explain. First, stop position check data selection values “00” and “01” are extracted as check targets from the logical product of the position check data of the left stop button and the stop position check data. Next, stop position check data selection values “01” and “04” are extracted as check targets from the logical product of the position check data of the middle stop button and the stop position check data.

  When “00” and “01” are extracted as check targets for the first stop reel (left reel 3L) and “01” and “04” are extracted as check targets for the second stop reel (middle reel 3C), then (2) With reference to the post-stop change data table selection table (FIG. 43), it is checked whether a combination corresponding to the check target is defined. If the corresponding combination is defined as a result of the check, the corresponding line data and stop table number are acquired from the second post-stop change data table selection table, and the stop table selection value storage area 2 is updated. The Here, the combination of the first stop reel (left reel 3L) “00” and the second stop reel (middle reel 3C) “04” is defined in the second post-stop change data table selection table. The stop table selection value storage area 2 is updated based on the line data “1” and the stop table number “5”.

  Next, the internal winning combination storing area, the display winning combination storing area, and the carryover winning combination storing area in the RAM 33 of the main control circuit 60 will be described with reference to FIGS. FIG. 45 is a diagram showing an example of the internal winning combination storing area of the gaming machine 1 in the present embodiment. FIG. 46 is a diagram showing an example of the display combination storing area of the gaming machine 1 in the present embodiment. FIG. 47 is a diagram showing an example of the carryover combination storage area of the gaming machine 1 in the present embodiment.

  As shown in FIG. 45, the internal winning combination storing area is composed of 29 storing areas. Each storage area divided by area type is an 8-bit data area allocated on the RAM 33, and stores internal winning combination information. Each storage area indicates which combination is an internal winning combination by storing data of “0” or “1” in an area of bits “0” to “7”.

  As shown in FIG. 46, the display combination storage area has a configuration in which five storage areas are added to the internal winning combination storage area. Similar to the internal winning combination storage area, each storage area divided by area type is an 8-bit data area allocated on the RAM 33, and stores display combination information. Each storage area indicates which combination is a display combination by storing data of “0” or “1” in an area of bits “0” to “7”. Since the RT action symbol is not determined as an internal winning combination, an area corresponding to the internal winning combination storing area is not provided, but since it can be determined as a display winning combination, an area corresponding to the display winning combination storing area is provided. (Region types 30 to 34) are provided.

  As shown in FIG. 47, the carryover combination storage area is an 8-bit data area allocated on the RAM 33 and stores carryover combination information. The carryover combination storage area stores data “0” or “1” in each of the bits “0” to “3”, so that the BB1 carryover state, BB2 carryover state, BB3 carryover state, or BB4 carryover state respectively. Indicates whether there is.

  Here, the BB1 carryover state refers to a state where BB1 is carried over as an internal winning combination until BB1 is established when BB1 is determined as an internal winning combination. The same applies to the BB2 carryover state, the BB3 carryover state, and the BB4 carryover state. In the present embodiment, the BB1 carryover state to the BB4 carryover state correspond to the RT6 gaming state.

  Next, the gaming state management flag storage area in the RAM 33 of the main control circuit 60 will be described with reference to FIG. FIG. 48 is a diagram showing an example of the game state management flag storage area of the gaming machine 1 in the present embodiment.

  The gaming state management flag storage area is composed of two storage areas. Each storage area divided by area type is an 8-bit data area allocated on the RAM 33. Each storage area indicates which gaming state it is by storing “0” or “1” data in each of the bits “0” to “7”.

  Next, stop table selection value storage areas 1 to 4 in the RAM 33 of the main control circuit 60 will be described with reference to FIG. FIG. 49 is a diagram showing an example of data stored in the stop table selection value storage areas 1 to 4 of the gaming machine 1 according to the present embodiment according to the progress time of the game.

  Each stop table selection value storage area is composed of 8 bits, the stop table number is stored in bits 0 to 5, and the line data is stored in bits 6 and 7. Further, if the game progress time is from the start of the game to the first stop, the line data and stop table number of the left stop button acquired from the rotation stop initial setting table (FIG. 28) are stored in the stop table selection value. Stored in area 1, the line data and stop table number of the middle stop button are stored in the stop table selection value storage area 2, and the line data and stop table number of the right stop button are stored in the stop table selection value storage area 3. .

  On the other hand, if the game progress time is after the first stop, the line data and stop table number corresponding to the operation stop button stored for the first stop are stored as they are for the second and third stops. However, it may be changed to other line data and a stop table number according to the scheduled stop position such as the first stop operation. After the first stop, the stop table selection value storage area 1 and the stop table selection value storage area 4 store the second stop line data and the stop table number, and the stop table selection value storage area 2 and the stop table selection value storage area 2. The table selection value storage area 3 stores third stop line data and a stop table number.

  Further, in the rotation stop initial setting table (FIG. 28), the first post-stop change stop table number determination table (FIG. 42), and the second post-stop change data table selection table (FIG. 43), the line data and the stop table Although the numbers are described in decimal notation, when these are stored in each stop table selection value storage area, they are converted into binary notation and stored.

  Next, the pull-in priority data storage area in the RAM 33 of the main control circuit 60 will be described with reference to FIG. Note that FIG. 50 is a diagram showing a pull-in priority data storage area of the gaming machine 1 in the present embodiment.

  The pull-in priority data storage area stores pull-in priority data determined according to the symbols corresponding to the symbol positions “0” to “20” of the rotating reel. For example, when all reels are rotating, the drawing priority data is stored in the drawing priority data storage area for the left reel, the drawing priority data storage area for the middle reel, and the drawing priority data storage area for the right reel. In addition, when the rotation of the left reel is stopped and the middle reel and the right main reel are rotating, the drawing priority is set in the drawing priority data storage area for the middle reel and the drawing priority data storage area for the right reel. Data is stored.

  The pull-in priority data is data determined based on the priority defined in the priority table (FIG. 30) in the pull-in priority acquisition process described later with reference to FIG. In addition, the priority of the pull-in priority data is higher as the value is larger. By referring to the pull-in priority data, it is possible to relatively evaluate the priority among the symbols arranged on the surface of the reel. It becomes. As a result, the result of the internal lottery can be appropriately reflected in the determination of the position where the reel rotation is stopped. Of the drawing priority data corresponding to each symbol within the range of the maximum number of sliding frames “4”, the symbol corresponding to the largest drawing priority data is the symbol with the highest priority. In other words, the pull-in priority data indicates the rank between symbols arranged on the reel, and the pull-in priority data having the same value as the pull-in priority data corresponding to each symbol within the range of the number of sliding symbols is If there are a plurality of symbols, the symbol with the highest priority is determined based on the priority order defined by the priority order table described above. If the symbol is stopped on the center line and a combination not determined as an internal winning combination is established, “00000000” indicating suspension prohibition is stored as the drawing priority data. If no symbol is established even if the symbol is stopped on the center line, “00000001” indicating that the symbol can be stopped is stored as the drawing priority data.

  Next, the symbol storage area in the RAM 33 of the main control circuit 60 will be described with reference to FIG. FIG. 51 is a diagram showing a storage example of the symbol storage area of the gaming machine 1 in the present embodiment (when the symbol position data of each reel is “4”).

  The symbol storage area is an area for storing a symbol code corresponding to each area in the symbol display area 4 constituting the effective line, and is provided for each effective line. In the present embodiment, only the center line can be an effective line, and the symbol storage area includes middle and middle symbol displays in the left symbol display area 4L constituting the effective line 1 (center line 8c) corresponding to the center line. The corresponding symbol codes of the middle part of the area 4C and the middle part of the right symbol display area 4R are stored.

  The symbol storage area shown in FIG. 51 indicates the symbol storage area when the symbol code is stored when the symbol position data of each reel is “4”. When the symbol position data is “4”, the symbols at symbol position “4” of each reel 3L, 3C, 3R (left reel 3L, middle reel 3C, right reel 3R are all red 7B symbols) are displayed on the left. This corresponds to the case where the middle part of the region 4L, the middle part of the middle symbol display area 4C, and the middle part of the right symbol display area 4R are displayed. Therefore, in this case, the symbol storage area corresponding to each middle stage of the left symbol display area 4L, the middle symbol display area 4C, and the right symbol display area 4R has a symbol code indicating the symbol of the symbol position "4" (red 7B symbol). Will be stored.

  Next, the effective stop button storage area in the RAM 33 of the main control circuit 60 will be described with reference to FIG. FIG. 52 is a diagram showing an example of the effective stop button storage area of the gaming machine 1 in the present embodiment.

  The effective stop button storage area is an 8-bit data area allocated on the RAM 33. The effective stop button storage area stores the data of “0” or “1” in each of the bits “0” to “2”, thereby determining whether or not the pressing operation of the left stop button 7L is effective. It indicates whether or not the pressing operation of the stop button 7C is effective, and whether or not the pressing operation of the right stop button 7R is effective. For example, that the pressing operation of the left stop button 7L is effective means that the rotation of the left reel 3L can be stopped by pressing the left stop button 7L, that is, the left reel 3L is rotating. It shows that there is.

  Next, an operation stop button storage area in the RAM 33 of the main control circuit 60 will be described with reference to FIG. FIG. 53 is a diagram showing an example of the operation stop button storage area of the gaming machine 1 in the present embodiment.

  The operation stop button storage area is an 8-bit data area allocated on the RAM 33. In the operation stop button storage area, data “0” or “1” is stored in each of the bits “0” to “2” to determine whether the left stop button 7L is operated or not. It indicates whether or not the right stop button 7R has been operated. Note that the operation of the left stop button 7L means that the left stop button 7L has been pressed.

  The stop order check data storage area shown in FIG. 54 is an 8-bit data area allocated on the RAM 33. The stop order check data storage area indicates which reel has stopped second by storing data of “0” or “1” in the area of bits “0” to “2”. By storing the data “0” or “1” in the areas “4” to “6”, it is indicated which reel is rotating. Specifically, storing “1” in the bit “0” area constituting the stop order check data storage area indicates that the second stopped reel is the left reel 3L, and in the bit “1” area. Storing “1” indicates that the second stopped reel is the middle reel 3C, and storing “1” in the bit “2” area indicates that the second stopped reel is the right reel 3R. Indicates. Further, storing “1” in the bit “4” area indicates that the left reel 3L is rotating, and storing “1” in the bit “5” area indicates that the middle reel 3C is rotating. And storing “1” in the area of bit “6” indicates that the right reel 3R is rotating. Therefore, for example, when the data in the stop order check data storage area is “00100001”, this indicates that the second stopped reel is the left reel 3L and the middle reel 3C is rotating.

  The position check data storage area shown in FIG. 55 is a 9-byte data area allocated on the RAM 33. The position check data storage area is information for identifying the stop control position (the symbol position on the center line and the same symbol position as the planned stop position) of the reel 3 corresponding to the operation stop button for which the stop operation has already been performed. Is an area for storing In the position check data storage area, 3 bytes are allocated for each operation stop button. The 3-byte area allocated for each operation stop button is divided into a first storage area (1 byte), a second storage area (1 byte), and a third storage area (1 byte). The third storage area stores data of “0” or “1” in the areas of bits “0” to “7”, so that the symbol positions “00” to “07” are stop control positions, respectively. Indicate. The second storage area stores the data of “0” or “1” in the areas of bits “0” to “7”, so that the symbol positions “08” to “15” are stop control positions, respectively. In the first storage area, the symbol positions “16” to “20” are stopped by storing data “0” or “1” in the areas of bits “0” to “4”, respectively. Indicates whether it is a control position.

  Next, the relationship between each gaming state, each mode, and each counter (ceiling counter, extended counter, digestion counter, boss battle counter) managed by the sub-control circuit 70 will be described. When the sub CPU 71 is in a predetermined gaming state (for example, RT2 gaming state) and in a predetermined mode (for example, mode “9”), the sub CPU 71 can establish an RT4 winning combination (the above-mentioned small role / replay data pointer “11”). When the internal winning combination corresponding to “-20” is determined as the internal winning combination, the navigation information for establishing the RT4 operating combination is notified. Whether to notify the navigation information for establishing the RT4 operating combination is determined by the internal winning combination and a mode described later. At this time, when the stop operation is performed according to the navigation information and the RT4 gaming state is activated, the R value and the G value determined by lottery are added to the extended game counter and the digest counter, and each counter is updated. Further, in the RT4 gaming state, when the value of the extended game counter is “1” or more when the RT4 winning combination is determined as the internal winning combination, navigation information for establishing the RT4 operating combination is notified. The For example, when the value of the extended game counter is “3”, the navigation information for establishing the RT4 operating combination in the RT4 gaming state is notified three times. Also, in the RT4 gaming state, a lottery is performed each time the RT4 operating combination is established, based on the fact that a predetermined condition (for example, that the below-described out-game sub gaming state management data is “released”) is satisfied. The G value determined by is added to the digestion counter.

  Further, in the RT4 gaming state, even when the RT4 winning combination is determined as the internal winning combination, if the value of the extended game counter is “0”, the navigation information for establishing the RT4 operating combination is The navigation information for establishing the RT2 operating combination is notified without being notified.

  In the RT2 gaming state, if the value of the digest counter is “1” or more, the predetermined navigation information is notified, and as long as the stop operation is performed according to the navigation information, the gaming in the RT2 gaming state does not shift to another gaming state. It can be performed. On the other hand, when the digest counter value is “0”, the boss battle counter value is referred to. When the boss battle counter value is “1” or more, the boss battle counter value is “0”. Up to this point, an effect suggesting a battle between the main character and the boss character is executed, and in principle, the mode is changed based on the value of the boss battle counter being “0”. At this time, when the value of the ceiling counter is “1600” or more, when the RT4 winning combination is determined as the internal winning combination, the navigation information for establishing the RT4 operating combination is notified again. The transition is made.

  Next, each mode managed by the sub control circuit 70 will be described with reference to FIG. FIG. 56 is a diagram showing an outline of each mode of the gaming machine 1 in the present embodiment. Modes managed by the sub-control circuit 70 include modes “1” to “39” having different combinations of large items, medium items, and (small items in mode “9” to mode “39”). There are 39 modes. For example, mode “1” consists of major items: initial, middle item: setting change, and stays when the setting is changed. Mode “13” is major item: ART, middle item: release, small item: from 7 low. It is a mode that shifts based on the fact that the RT4 gaming state is activated. The sub control circuit 70 manages which mode is the current mode on the sub RAM 73 based on a command transmitted from the main control circuit 60 or the like.

  Note that the pushing order violation shown in the right column (outline) in FIG. 56 (for example, refer to the row of mode “6”) is when “0” (lost) is determined as the data pointer for the small role / replay. That is, it means that the first stop operation is performed on the reels other than the left reel 3L.

  Further, the push order mistake (see, for example, the row of mode “27” to mode “39”) shown in the right column (outline) of FIG. 56 follows the navigation information (push order information) notified by the sub CPU 71. This means that the stop operation was performed without For example, when “left middle right” is notified as the navigation information, if the player performs a stop operation in a different pressing order from the navigation information, for example, “middle left and right”, the pressing order Make a mistake.

  Further, the T value shown in the right column (outline) in FIG. 56 is a value for updating the ceiling counter, and in a predetermined mode (for example, modes “1” to “8”, “26”), When the value of the ceiling counter is 1600 or more (T value ≧ 1600), the mode shifts to “10”. The R value is a value for updating the extended game counter, and in the RT4 gaming state, when the RT4 winning combination is determined as the internal winning combination, the navigation information for establishing the RT4 working combination is notified. It is a value for determining the number of times to perform. The G value is a value for updating the digest counter, and is a value for determining the number of stay games in the RT2 gaming state. The B value is a value for updating the boss battle counter, and is a value for determining the number of games in the boss battle.

  In the mode transition lottery table, which will be described later, lottery values are defined so that the transition destination mode is determined according to the outline shown in FIG.

  Next, the relationship between each mode managed by the sub-control circuit 70 and management data will be described with reference to FIG. FIG. 57 is a diagram showing the relationship between each mode of the gaming machine 1 and management data in the present embodiment.

  As shown in FIG. 57, each mode corresponds to each sub-game state management data for playing and each sub-game state management data for counter. The sub game state management data for the game is a value for each value (T) in a sub game release lottery table which will be described later with reference to FIGS. 93 and 94 and a sub game appearance ceiling lottery table which will be described with reference to FIGS. Value, R value, G value, and B value). The counter sub gaming state management data is based on determining each value (T value, R value, G value, B value) based on a counter update table, which will be described later with reference to FIGS. It is data.

  The counter sub gaming state management data “normal (left)” corresponding to the modes “1” to “3” and “26” is management data when the first stop operation is performed on the left reel 3L. Yes, “normal (middle)” is management data when the first stop operation is performed on the middle reel 3C, and “normal (right)” is the first stop operation on the right reel 3R. Management data in the case of Similarly, the counter sub gaming state management data “for navigation (left)” corresponding to the modes “4” to “8” is management data when the first stop operation is performed on the left reel 3L. “Navigation (middle)” is management data when the first stop operation is performed on the middle reel 3C, and “Navigation (right)” is the first stop operation on the right reel 3R. Management data in the case of

  Next, mode management data managed by the sub control circuit 70 will be described with reference to FIG. FIG. 58 is a diagram showing a list of mode management data of the gaming machine 1 in the present embodiment.

  The mode management data is data serving as a basis for determining a transfer destination mode based on a mode shift lottery table which will be described later with reference to FIGS. As shown in FIG. 58, the mode management data relates to the internal winning combination (value of the small combination / replay data pointer) and the transition of the gaming state managed by the main control circuit 60 established by the player's stop operation. It corresponds to the operating combination (general gaming state operating combination, RT1 operating combination, RT2 operating combination, RT3 operating combination, RT4 operating combination).

  As described above with reference to FIG. 26, for example, when “0” is determined as the small role / replay data pointer and the first stop operation is performed on the left reel 3 </ b> L, the game state transition is performed. Since the operating combination relating to is not established, the mode management data is “00”. On the other hand, when the first stop operation is performed on the reels other than the left reel 3L, since the general gaming state operating combination is established, the mode management data becomes “01”. In addition, when “3” is determined as the small role / replay data pointer, and the RT3 operating combination is established, the mode management data is “04”. On the other hand, when the RT2 operating combination is established, the mode management data is “05”.

  Next, a navigation display lottery table stored in the sub ROM 72 of the sub control circuit 70 will be described with reference to FIGS. FIG. 59 is a diagram showing an example of a navigation display lottery table (modes “0” to “3”, “26”) of the gaming machine 1 in the present embodiment, and FIG. 60 is a gaming machine in the present embodiment. FIG. 61 is a diagram showing an example of one navigation display lottery table (modes “4” and “5”), and FIG. 61 is a navigation display lottery table (modes “6” and “7”) of the gaming machine 1 in the present embodiment. 62 is a diagram showing an example of a navigation display lottery table (mode “8”) of the gaming machine 1 in the present embodiment, and FIG. 63 is a diagram of the gaming machine 1 in the present embodiment. FIG. 64 is a diagram showing an example of a navigation display lottery table (modes “9” to “12”), and FIG. 64 is an example of a navigation display lottery table (modes “13” to “16”) of the gaming machine 1 in this embodiment. FIG. 65 is a diagram of the gaming machine 1 in this embodiment. It is a figure which shows the example of a display lottery table (mode "17"-"21", "23", "25"), and FIG. 66 is a navigation display lottery table (mode "22") of the gaming machine 1 in this embodiment. , “24”). FIG. 67 is a diagram showing an example of the navigation display lottery table (modes “27” to “34”) of the gaming machine 1 in this embodiment, and FIG. It is a figure which shows the example of the navigation display lottery table (mode "35"-"39") of the gaming machine 1 in this embodiment.

  The navigation display lottery table is a table used for determining navigation display data based on the gaming state and the internal winning combination managed by the sub-control circuit 70 in the start command reception process described later with reference to FIG. is there. The gaming state managed by the sub-control circuit 70 includes a general gaming state, an RT2 gaming state, an RT3 gaming state, an RT4 gaming state, an RT5 gaming state, an RT6 gaming state, and a BB gaming state. Based on the transmitted start command or the like, the gaming state is managed on the sub RAM 73.

  In the navigation display lottery table, lottery values are defined so that navigation display data is determined according to the gaming state managed by the sub-control circuit 70 and the internal winning combination. Here, the navigation display data in the figure corresponds to the first stop operation, the second stop operation, and the third stop operation from the left except for “None”. For example, the navigation display data “left middle right” Provides navigation information for instructing the player to perform the first stop operation on the left reel 3L, the second stop operation on the middle reel 3C, and the third stop operation on the right reel 3R. This is data for notification. Further, when the navigation display data “none” is determined, the navigation information is not notified. Hereinafter, the navigation display data determined according to the gaming state and the internal winning combination will be described by taking a representative mode as an example.

  First, navigation display data determined when the mode is “0” to “3”, “26” will be described with reference to FIG. As shown in FIG. 59, when the gaming state is the RT1 gaming state or the RT3 gaming state, “None” is displayed as the navigation display data regardless of which value is determined as the small role / replay data pointer. Is determined. Further, in the RT2 gaming state and the RT4 gaming state, even when the RT4 winning combination is determined as the internal winning combination, the navigation display data for establishing the RT4 operating combination is not determined, and the RT2 operating combination is established. The navigation display data for this is determined.

  Next, navigation display data determined when the mode is “9” to “12” will be described with reference to FIG. As shown in FIG. 63, when the gaming state is the RT1 gaming state and the RT2 gaming state and the RT4 winning combination is determined as the internal winning combination, the navigation display data for establishing the RT4 working combination is determined. The When the gaming state is the RT3 gaming state and “20” is determined as the small role / replay data pointer, navigation display data for establishing the RT4 operating combination is determined. If the gaming state is the RT3 gaming state and “19” is determined as the small role / replay data pointer, “None” is determined as the navigation display data, but in this embodiment, The RT4 operating combination can be established by performing the first stop operation on the left reel 3L recommended when the navigation information is not notified. That is, modes “9” to “12” are modes in which the RT4 gaming state can be activated by performing a stop operation according to the navigation information, and the transition to the next RT4 gaming state is determined. I can say that.

  In modes “9” to “12”, when the RT1 operating combination is determined as an internal winning combination, navigation display data for preventing the RT1 operating combination from being established is determined. Specifically, navigation display data for establishing a bell combination is determined. In this case, the player can establish a bell role while preventing the transition to the RT1 gaming state by performing a stop operation according to the navigation information.

  Next, navigation display data determined when the mode is “13” to “16” will be described with reference to FIG. As shown in FIG. 64, when the gaming state is the RT4 gaming state and the RT4 winning combination is determined as the internal winning combination, navigation display data for establishing the RT4 operating combination is determined. That is, in the modes “13” to “16”, the RT4 operating combination can be established during the RT4 gaming state by performing a stop operation according to the navigation information. As shown in FIG. 57, the modes “13” to “16” correspond to the sub-game state management data for “departing”, and the RT4 actuator is established in the RT4 game state as will be described later. By doing so, the values of the ceiling counter and the digest counter are updated.

  Next, navigation display data determined when the mode is “17” to “21”, “23”, “25” will be described with reference to FIG. Modes “17” to “21” are modes that shift based on the value of the consecutive resort counter being “0”, and even if the RT4 winning combination is determined as the internal winning combination, RT4 The navigation display data for establishing the operating combination is not determined, and the navigation display data for establishing the RT2 operating combination is determined.

  In addition, as shown in FIG. 66, when the gaming state is the RT2 gaming state and the mode when the RT4 winning combination is determined as the internal winning combination is “22” or “24”, the RT4 operation is performed. Navigation display data for establishing a combination is determined. On the other hand, as described above, when the gaming state is the RT2 gaming state and the mode when the RT4 winning combination is determined as the internal winning combination is “23”, “25”, the RT4 operating combination is Since the navigation display data to be established is not determined, the modes “22” and “24” are advantageous modes for the player compared with the modes “23” and “25”.

  Next, navigation display data determined when the mode is “27” to “34” will be described with reference to FIG. Note that the modes “27” to “34” (the same applies to the modes “35” to “39”) are modes that shift in principle due to a pressing order error.

  Here, with reference to FIGS. 63 and 67 and FIGS. 73 and 78B described later, the notification of the navigation information, the gaming state, and the mode transition in the mode “27” will be specifically described.

  In describing the mode “27”, first, the transition from the mode “9” to the mode “27” and the transition of the gaming state managed by the main control circuit 60 will be described. As shown in FIG. 63, for example, when the gaming state managed by the main control circuit 60 is the RT2 gaming state and “22” is determined as the small role / replay data pointer, the navigation display data is “ “Left middle right” or “Left and right middle” is determined, and the navigation information corresponding to the determined navigation display data is notified. At this time, when the player performs a stop operation based on the navigation information, the transition of the gaming state and the mode are not performed because the bell combination is established. On the other hand, when a stop operation sequence different from the navigation information (for example, the first stop operation for the middle reel 3C or the right reel 3R) is performed, the RT1 actuating role is established, and the gaming state managed by the main control circuit 60 is Transition to the RT1 gaming state. Further, the mode management data at this time is “21” (see FIG. 58), and the mode shifts to the mode “27” as shown in FIG. 78 (b).

  As described above, the RT1 gaming state is a disadvantageous gaming state for the player who has a low probability that the replay is determined as an internal winning combination as compared with the RT2 gaming state. If the managed gaming state shifts to an unfavorable gaming state, the player's interest will be reduced. Therefore, even when the gaming state managed by the main control circuit 60 shifts to an unfavorable gaming state due to a push order error, the gaming machine 1 enters the gaming state before the transition to the unfavorable gaming state. A dedicated mode (mode “27” (the same applies to modes “28” to “39”)) for performing re-migration is provided.

  In the mode “27”, in the transition RT1 gaming state, for example, when “6” is determined as the small role / replay data pointer, “left” is displayed as the navigation display data for establishing the RT2 operating role. “Middle right” is determined, and the navigation information corresponding to the determined navigation display data is notified. At this time, if the player performs a stop operation in accordance with the navigation information, the RT2 operating combination is established, and the state shifts to the RT2 gaming state. Further, the mode management data at this time is “08” (see FIG. 58), and the mode shifts to the mode “9” as shown in FIG. 78 (b).

  Thus, even if the gaming machine 1 is in a case where the gaming state managed by the main control circuit 60 has shifted to a gaming state that is disadvantageous to the player due to a pushing order error, the mode of the transition destination that has been shifted due to the pushing order error The navigation information for making a transition to the gaming state and mode before the transition to the unfavorable gaming state is notified. Accordingly, even if the game state is shifted to an unfavorable game state managed by the main control circuit 60 due to a push order error, it is possible to re-transfer to the game state and mode before the shift to the disadvantaged game state. . Therefore, the player does not reduce the interest in the game even when the gaming state managed by the main control circuit 60 shifts to an unfavorable gaming state due to a pushing order error.

  Next, the mode transition lottery table stored in the sub ROM 72 of the sub control circuit 70 will be described with reference to FIGS. FIG. 69 is a diagram showing an example of the mode transition lottery table (mode “1”) of the gaming machine 1 in the present embodiment. FIG. 70 is a diagram illustrating an example of a mode transition lottery table (mode “2”). FIG. 71 is a diagram showing an example of a mode transition lottery table (mode “4”). FIG. 72A is a diagram showing an example of the mode transition lottery table (mode “6”). FIG. 72B is a diagram showing an example of the mode transition lottery table (mode “8”). FIG. 73 is a diagram showing an example of a mode transition lottery table (mode “9”). FIG. 74 is a diagram showing an example of a mode transition lottery table (mode “13”). FIG. 75 is a diagram showing an example of a mode transition lottery table (mode “17”). FIG. 76 is a diagram showing an example of a mode transition lottery table (mode “19”). FIG. 77A shows an example of the mode transition lottery table (mode “22”). FIG. 77B is a diagram showing an example of the mode transition lottery table (mode “23”). FIG. 78A shows an example of the mode transition lottery table (mode “26”). FIG. 78B is a diagram showing an example of the mode transition lottery table (mode “27”).

  The mode transition lottery table is a table used for determining the mode of the transition destination, and the mode transition lottery table corresponds to the gaming state managed by the sub control circuit 70 and the mode management data (see FIG. 58). The lottery value is defined so that the transfer destination mode is determined.

  The mode transition lottery table (mode “1”) shown in FIG. 69 is a table used when determining the transition destination mode when the mode is “1”. In the mode transition lottery table (mode “1”), lottery values are defined so that any one of “1” to “3” is determined as the mode of the transition destination. Note that the RT game state “common” in the figure means that the game state managed by the sub-control circuit 70 is one of the general game state, the RT1 game state to the RT5 game state. For example, when the gaming state managed by the sub-control circuit 70 is the RT1 gaming state and the mode management data is “1”, the mode “2” is determined as the mode of the transfer destination. The mode “1” is a mode that is shifted when the setting is changed.

  The mode transition lottery table (mode “2”) shown in FIG. 70 is a table used when determining the transition destination mode when the mode is “2”. When the mode is “2”, the mode determined as the transfer destination differs depending on the gaming state. For example, when the gaming state is the general gaming state or the RT5 gaming state, any one of the modes “2” to “6” and “27” is determined as the transition destination mode, and the gaming state is the RT1 gaming state. In this case, any one of modes “2” to “6”, “8”, “13”, and “27” is determined as the transfer destination mode. In addition, when the gaming state is the RT3 gaming state and the mode management data is “03”, “06”, “15”, “17”, “22”, “23”, it has a predetermined probability. Mode transition to mode “9” is performed. As described above, as described above, in the mode “9”, the navigation information for establishing the RT4 operating combination is notified until the transition to the RT4 gaming state is made. Therefore, from the mode “2” to the mode “9”. Transition to is a mode transition that is advantageous to the player. Note that mode “2” is a mode in which there is a high possibility of shifting from a plurality of modes, which will be described later, and a high possibility of staying during normal times.

  Although not shown, a mode transition random determination table (mode “3”) is stored in the sub ROM 72 of the sub control circuit 70. The mode transition lottery table (mode “3”) is a table used to determine a transition destination mode when the mode is “3”. The mode transition lottery table (mode “3”) has the same configuration as the mode transition lottery table (mode “2”), and the probability of transition to mode “9” in the RT3 gaming state is compared with mode “2”. The lottery value is defined so as to be higher.

  The mode transition lottery table (mode “4”) shown in FIG. 71 is a table used for determining the mode of the transition destination when the mode is “4”. Although not shown, the sub ROM 72 of the sub control circuit 70 stores a mode transition lottery table (mode “5”). The mode transition lottery table (mode “5”) is a table used to determine the transition destination mode when the mode is “5”. The mode transition lottery table (mode “5”) has the same configuration as the mode transition lottery table (mode “4”), and the probability of transition to mode “9” is higher than that of mode “4”. The lottery value is defined as follows.

  The mode transition lottery table (mode “6”) shown in FIG. 72A is a table used for determining the mode of the transition destination when the mode is “6”. Mode “6” is a mode that may be shifted when a pressing order violation (first stop operation for a reel other than the left reel 3L) is performed in modes “2” to “4”.

  In addition, the mode transition lottery table (mode “2”), the mode transition lottery table (mode “3”), and the mode transition lottery table (mode “4”) are set to a mode with a predetermined probability when a pressing order is violated. The lottery value may be defined so as to shift to “6” or mode “7”. In such a configuration, the mode transition lottery table (mode “7”) may be stored in the sub ROM 72 of the sub control circuit 70. In addition, the lottery value may be defined in the mode transition lottery table (mode “7”) so that the probability of transition to mode “2” is higher than that of mode “6”.

  The mode transition lottery table (mode “8”) shown in FIG. 72B is a table used to determine the transition destination mode when the mode is “8”. In the mode transition lottery table (mode “8”), any one of “2”, “3”, “8”, “9”, “13” is set as the transition destination mode when the gaming state is the RT3 gaming state. The lottery value is defined so that is determined.

  The mode transition lottery table (mode “9”) shown in FIG. 73 is a table used for determining the mode of the transition destination when the mode is “9”. In mode “9”, since the navigation information for establishing the RT4 operating combination is notified, the player performs the stop operation according to the navigation information to establish the RT4 operating combination, and changes the gaming state to the RT4 gaming state. Can be transferred to. In the mode transition lottery table (mode “9”), a lottery value is defined so that the mode shifts to “13” when the gaming state shifts to the RT4 gaming state.

  In the mode transition lottery table (mode “9”), “27” is defined as the mode of the transition destination. When the mode management data is “01”, “04”, “09”, “11” to “13”, “21” in the predetermined gaming state (for example, in the RT2 gaming state, the mode management data When the data is “04”), the lottery value is defined so that the mode shifts to the mode “27” with a predetermined probability. That is, the mode “27” (the same applies to modes “28” to “39” described later) is a mode that is shifted when the gaming state shifts to an unfavorable gaming state due to a pushing order error. This is a mode for making a transition to the gaming state before the transition to the disadvantaged gaming state even when the gaming state has transitioned to the disadvantaged gaming state due to an order error.

  Although not shown, the sub ROM 72 of the sub control circuit 70 has a mode transition lottery table (mode “10”) and a mode used for determining the mode of the transition destination when the mode is “10” to “12”. A transition lottery table (mode “11”) and a mode transition lottery table (mode “12”) are stored. In each mode transition lottery table, the transition destination mode “9” in the mode transition lottery table (mode “9”) is changed to modes “10” to “12”, respectively, and the destination mode “27” is changed to mode “ 28 ”to“ 30 ”.

  The mode transition lottery table (mode “13”) shown in FIG. 74 is a table used for determining the mode of the transition destination when the mode is “13”. In the mode transfer lottery table (mode “13”), “13”, “14”, and “31” are defined as transfer destination modes. Note that the mode “13” is a mode that shifts when the RT4 gaming state is activated by performing a stop operation according to the navigation information.

  Although not shown, the sub ROM 72 of the sub control circuit 70 has a mode transition lottery table (mode “14”) and a mode used for determining the mode of the transition destination when the modes are “14” to “16”. A transition lottery table (mode “15”) and a mode transition lottery table (mode “16”) are stored. The mode transition lottery table (mode “14”) replaces the mode “13” of the transition destination in the mode transition lottery table (mode “13”) with “14”, and changes the mode “31” of the transition destination. The configuration replaced with “32” is adopted. The mode transfer lottery table (mode “15”) replaces the transfer destination modes “13” and “14” in the mode transfer lottery table (mode “13”) with “15”, and the transfer destination mode “31”. "Is replaced with" 33 ". Further, the mode transition lottery table (mode “16”) replaces the mode “13” and “14” of the transition destination in the mode transition lottery table (mode “13”) with “16”, and the mode of the transition destination The configuration is such that “31” is replaced with “34”. The mode “15” is a mode that is shifted when the BB operating combination is determined as the internal winning combination when the mode is “13”, and the mode “16” is the mode “14”. In this case, the mode shifts when the BB operating combination is determined as the internal winning combination.

  The mode transition lottery table (mode “17”) shown in FIG. 75 is a table used for determining the mode of the transition destination when the mode is “17”. In the mode transfer lottery table (mode “17”), “17”, “19”, and “35” are defined as the transfer destination modes. Note that the mode “17” is a mode to be shifted based on the fact that the value of the extended game counter is “0” in the mode “13”.

  Although not shown, a mode transition random determination table (mode “18”) is stored in the sub ROM 72 of the sub control circuit 70. The mode transfer lottery table (mode “18”) is a table used to determine the transfer destination mode when the mode is “18”, and the transfer destination in the mode transfer lottery table (mode “17”). The mode “17” is replaced with “18”. The mode “18” is a mode in which the mode is changed based on the fact that the value of the extended game counter becomes “0” in the mode “14”.

  The mode transition lottery table (mode “19”) shown in FIG. 76 is a table used for determining the mode of the transition destination when the mode is “19”. In the mode transfer lottery table (mode “19”), “19” and “37” are defined as the transfer destination modes.

  In the mode transition lottery table (mode “22”) shown in FIG. 77A and the mode transition lottery table (mode “23”) shown in FIG. 77B, the modes are “22” and “23”, respectively. This table is used to determine the mode of the transfer destination. In the mode transition lottery table (mode “22”) and the mode transition lottery table (mode “23”), “2”, “9”, “13” are the transition destination modes when the gaming state is the RT2 gaming state. , “22” and “23” are defined.

  As will be described later, in the sub CPU 71, the game state is the RT2 game state, and the mode when any of “11” to “18” is determined as the small role / replay data pointer is “22”. If so, the sub CPU 71 notifies the navigation information for establishing the RT4 operating combination (see FIG. 66). At this time, when the player performs a stop operation in accordance with the navigation information, the mode management data becomes “10” (see FIG. 58), so the mode “13” is determined as the transition destination mode. On the other hand, the sub CPU 71 is in the RT2 gaming state, the mode is “23”, and the mode when any one of “11” to “18” is determined as the small role / replay data pointer is “ If it is “23”, the navigation information for establishing the RT2 operating combination is notified (see FIG. 65). At this time, when the player performs a stop operation according to the navigation information, the mode management data becomes “11” (see FIG. 58), so the mode “9” or “22” is determined as the transition destination mode. The

  Although not shown, the sub ROM 72 of the sub control circuit 70 stores a mode transition lottery table (mode “24”) and a mode transition lottery table (mode “25”). The mode “25” is a mode for shifting based on the fact that the value of the digestion counter becomes “0” in the mode “18”. The mode transfer lottery table (mode “24”) is a table used to determine the transfer destination mode when the mode is “24”, and the transfer destination in the mode transfer lottery table (mode “22”). The mode “22” and “23” are replaced with “24” and “25”, respectively. The mode transfer lottery table (mode “25”) is a table used to determine the transfer destination mode when the mode is “25”, and the transfer destination in the mode transfer lottery table (mode “23”). The mode “22” and “23” are replaced with “24” and “25”, respectively. The mode transition lottery table (mode “24”) and the mode transition lottery table (mode “25”) are configured more than the mode transition lottery table (mode “22”) and the mode transition lottery table (mode “23”). The lottery value may be defined so that the probability of shifting to the mode “9” is increased.

  The mode transition lottery table (mode “26”) shown in FIG. 78A is a table used to determine the transition destination mode when the mode is “26”. In the mode transfer lottery table (mode “26”), “2” and “26” are defined as the transfer destination modes when the gaming state is the RT2 gaming state. Note that the mode “26” is a mode to be shifted based on the value of the boss battle counter being “0” in the modes “22” to “25”.

  The mode transition lottery table (mode “27”) shown in FIG. 78B is a table used to determine the transition destination mode when the mode is “27”. In the mode transition lottery table (mode “27”), “9”, “13”, “27” are the transition destination modes when the gaming state is the RT1 gaming state, the RT2 gaming state, the RT3 gaming state, and the RT4 gaming state. Is defined. Note that the mode “27” is a mode that shifts due to a pressing order mistake in the mode “9”.

  Although not shown, the sub ROM 72 of the sub control circuit 70 has a mode transition lottery table (mode “28”), a mode transition lottery table (mode “29”), a mode transition lottery table (mode “30”), a mode, and the like. Transition lottery table (mode “31”), mode transition lottery table (mode “32”), mode transition lottery table (mode “33”), mode transition lottery table (mode “34”), mode transition lottery table (mode “ 35 "), mode transition lottery table (mode" 36 "), mode transition lottery table (mode" 37 "), mode transition lottery table (mode" 38 "), and mode transition lottery table (mode" 39 "). ing. Note that modes “28” to “39” are modes determined as transition destinations when a pressing order is missed in modes “10” to “21”, and each mode transition lottery table. In the mode transfer lottery table (mode “27”), the transfer destination mode “9” is changed to modes “10” to “21”, and the transfer destination mode “27” is changed to modes “28” to “39”, respectively. The configuration is replaced with.

  In the table used when the modes are “27” to “39”, lottery values are defined so that the mode before the transition due to a push order error is determined as the transition destination mode. Although the details will be described later, the modes “27” to “39” are dedicated modes for returning the game state and the mode to the game state and the mode before the transfer due to a mistake in the pressing order.

  Next, with reference to FIG. 79, the BB medium mode lottery table stored in the sub ROM 72 of the sub control circuit 70 will be described. FIG. 79 is a diagram showing an example of the BB mode transition lottery table of the gaming machine 1 in the present embodiment.

  The during-BB mode transfer lottery table is a table used when determining the transfer-destination mode during the BB gaming state. A lottery value is defined in the BB mode transition lottery table so that the current mode and the mode of the transfer destination are determined according to the mode management data. For example, if the mode management data is any one of the modes “1” to “3” and the mode management data is “24” (small role / replay data pointer “36”) (see FIG. 58), the transition is made. Mode “9” is determined as the previous mode.

  Next, the counter update table stored in the sub ROM 72 of the sub control circuit 70 will be described with reference to FIGS. FIG. 80 is a diagram showing an example of a counter update table (counter sub gaming state management data: normal (left)) of the gaming machine 1 in the present embodiment, and FIG. 81 shows the gaming machine 1 in the present embodiment. FIG. 82 is a diagram showing an example of a counter update table (counter sub gaming state management data: for navigation (left)), and FIG. 82 is a counter updating table (counter sub gaming state management data for the gaming machine 1 in this embodiment). FIG. 83 is a diagram showing an example of a counter update table (counter sub game state management data: for navigation (medium)) of the gaming machine 1 in this embodiment. FIG. 84 is a diagram showing an example of a counter update table (counter sub-game state management data: normal (right)) of the gaming machine 1 in this embodiment, and FIG. 85 is a diagram in this embodiment. FIG. 86 is a diagram showing an example of a counter update table (counter sub-game state management data: for navigation (right)) of the gaming machine 1, and FIG. 86 (a) is a counter update table (counter) of the gaming machine 1 in the present embodiment. FIG. 86B is a diagram showing an example of sub-game state management data for use: sub-confirmation (common), and FIG. 86B is a counter update table (counter sub-game state management data for releasing) in the present embodiment. 87 (a) is a diagram showing an example of (common)), and FIG. 87 (a) is a diagram showing an example of a counter update table (counter sub game state management data: digesting (common)) of the gaming machine 1 in this embodiment. FIG. 87 (b) is a diagram showing an example of a counter update table (counter sub-game state management data: during boss battle (common)) of the gaming machine 1 in this embodiment, and FIG. 88 shows this embodiment. Counter update table of the gaming machine 1 in the state: is a diagram showing an example of a (sub counter gaming state management data during freezing (common)).

  The counter update table is a table used to update the values of the ceiling counter, extended game counter, digestion counter, and boss battle counter in the reel stop command reception process described later with reference to FIG. Which counter update table is used is determined based on counter sub-game state management data (see FIG. 57). For example, when the mode is “1” and the first stop operation is performed on the left reel 3L, the counter sub gaming state management data is normal (left). Sub-game state management data: normal (left)) (see FIG. 80) is referred to, and each counter is updated.

  In the counter update table, a lottery value is defined so that an update value of each counter is determined in accordance with the gaming state and the value of the small role / replay data pointer. Note that “+ X” in the updated value in the figure adds “X” to the counter, “−X” subtracts “X” from the counter, and “= X” replaces the counter value with “X”. Correspond. For example, when T value: “+1”, R value, G value, and B value: “+0” are determined, “1” is added to the ceiling counter, and the villa counter, digestion counter, and boss battle counter Does not change. Hereinafter, the update of each counter will be specifically described by taking a typical mode as an example.

  As shown in FIG. 86 (b), when the counter sub gaming state is being released (common), the gaming state is the RT2 gaming state or the RT4 gaming state, and is used as a small role / replay data pointer. Since the R value when any one of “11” to “18” is determined is “−1”, “1” is subtracted from the extended range counter. The counter sub gaming state: releasing (common) corresponds to any of the modes “13” to “16”. In the modes “13” to “16”, the counter counter The navigation information for establishing the RT4 operating combination is notified until the value becomes “0” (see FIG. 64). It should be noted that, based on the fact that the value of the consecutive resort counter has become “0”, the mode is changed to any one of the mode “17” to the mode “21” corresponding to the counter sub-game state management data: being digested (common). Transition.

  Also, as shown in FIG. 87 (a), when the counter sub gaming state is in digestion (common), the gaming state is the RT2 gaming state, and “0” is used as the small role / replay data pointer. , “2”, “6” to “18”, “21” to “35” when the G value is determined to be “−1”, the value of the digestion counter is “1”. Subtracted. Further, the counter sub-gaming state: during digestion (common) corresponds to any of the modes “17” to “21”. In the modes “17” to “21”, the value of the digest counter is used. Until RT becomes “0”, in the RT2 gaming state, navigation information for not establishing an operating role for operating other gaming states (general gaming state operating role, RT1 operating role, RT3 operating role, RT4 operating role) is notified. The Therefore, the player can continue the game in the RT2 gaming state with a high probability that the replay is determined as an internal winning combination without shifting to another gaming state by performing a stop operation according to the navigation information. It becomes. Based on the fact that the value of the digest counter is “0”, the sub-game state management data for counters is shifted to any one of modes “22” to “25” corresponding to the boss battle (common). To do.

  As shown in FIG. 87 (b), when the counter sub gaming state is in the boss battle (common), the gaming state is the RT2 gaming state, and “0”, “ Since B value is “−1” when any of “2”, “6” to “18”, “21” to “35” is determined, “1” is subtracted from the value of the boss battle counter Is done. The counter sub-game state: during boss battle (common) corresponds to any of the modes “22” to “25”. In modes “22” to “25”, the value of the boss battle counter The battle effect between the main character and the boss character is executed until “0” is reached or until a mode other than “22” to mode “25” is entered. Based on the fact that the value of the boss battle counter has become “0”, the sub game state management data for counters is shifted to mode “26” corresponding to normal (left), normal (middle), and normal (right). Then, an effect suggesting that the boss character has been defeated is executed. On the other hand, even before the value of the boss battle counter becomes “0”, when the mode is shifted to the mode “9” or the mode “13”, an effect suggesting that the boss character has been won is executed. The

  Next, the BB3 operation step value update table stored in the sub ROM 72 of the sub control circuit 70 will be described with reference to FIGS. 89 and 90. FIG. FIG. 89 is a diagram showing an example of the step value update table (setting values 1 to 3) at the time of BB3 operation of the gaming machine 1 in the present embodiment, and FIG. 90 is the operation of BB3 of the gaming machine 1 in the present embodiment. It is a figure which shows the example of a time step value update table (setting value 4-6).

  The step value update table at the time of BB3 operation is a table used to determine the step value of the transfer destination based on the current step value when BB3 is established in the display command reception processing described later with reference to FIG. is there. The step value is data serving as a basis for determining an A value and a Z value described later.

  In the BB3 operation step value update table, lottery values are defined so that the destination step value is determined according to the current step value. Specifically, when the set value is 1 to 3, as shown in FIG. 89, the lottery value is set so that the step value obtained by adding “1” to the current step value is determined as the destination step value. Defined (except when the current step value is 21). On the other hand, when the set value is 4 to 6, as shown in FIG. 90, when the current step value is “00” to “09”, it is the same as the current step value as the transition destination step value. The lottery value is defined so that the step value is determined. When the current step value is “10” to “20”, the step value obtained by adding “1” to the current step value is the destination value. A lottery value is defined so as to be determined as a step value. The determined step value is not cleared by a setting change or power interruption. In this embodiment, since “00” is set as the initial value for the step value, if the set value continues to be 4 to 6, the step value remains “00”. Therefore, when the set value is low (set values 1 to 3), the step value is likely to increase as the game progresses.

  Note that the update of the step value is not limited to the present embodiment, and the step value may be updated when another BB operating combination is established. Moreover, it is good also as prescribing | lotting a lot value so that the step value of a transfer destination may differ according to the classification of BB action combination.

  Next, the sub setting lottery table stored in the sub ROM 72 of the sub control circuit 70 will be described with reference to FIGS. 91 and 92. FIG. FIG. 91 is a diagram showing an example of the sub setting lottery table (setting value 1) of the gaming machine 1 in this embodiment, and FIG. 92 is the sub setting lottery table (setting value) of the gaming machine 1 in this embodiment. It is a figure which shows the example of 6).

  The sub-setting lottery table is a table used for determining the A value and the Z value in the display command reception process described later with reference to FIG. In the sub setting lottery table, lottery values are defined so that the A value and the Z value are determined according to the current step value. In addition, A value is the data used as the basis for updating a ceiling counter, a retreat counter, a digestion counter, and a boss battle counter in the sub-outlet release lottery table described later with reference to FIGS. 93 and 94. The Z value is data that serves as a basis for updating the ceiling counter, the villa counter, the digest counter, and the boss battle counter in the sub-outlet ceiling lottery table, which will be described later with reference to FIGS. 95 and 96.

  As shown in the figure, lottery values are defined in the sub-setting lottery table so that the A value and the Z value increase as the step value increases. Further, the lottery value is defined such that the higher the set value, the higher the A value and the Z value.

  Next, with reference to FIG. 93 and FIG. 94, the sub-outlet releasing lottery table stored in the sub-ROM 72 of the sub-control circuit 70 will be described. FIG. 93 is a diagram showing an example of a sub-ball exiting lottery table (A value: 1) of the gaming machine 1 in the present embodiment, and FIG. 94 is a sub-ball ejecting of the gaming machine 1 in the present embodiment. It is a figure which shows the example of a lottery table (A value: 6).

  The sub-ball release lottery table is a table used to update the values of the ceiling counter, the villa counter, the digest counter, and the boss battle counter in the display command reception process described later with reference to FIG. As described above, the T value, the R value, the G value, and the B value are values that are added to or replaced by the ceiling counter, the villa counter, the digestion counter, and the boss battle counter, respectively, and “+ X” indicates “ "X" means adding, and "= X" means replacing the counter value with "X". In addition, “RT4 start” in the figure is referred to when an RT4 actuator is established in a gaming state other than the RT4 gaming state (RT1 gaming state, RT2 gaming state, RT3 gaming state), and “RT4 in progress” Means that it is referred to when the RT4 operating combination is established in the RT4 gaming state.

  The lottery value is determined so that the updated value of each counter is determined according to the sub game state management data (see FIG. 57) and “RT4 start” or “RT4 in progress”. It is prescribed. For example, when the A value is “1” and the sub game state management data for the game is “basic”, “RT4 start”, R values added to the extended game counter are “+1” to “+1”. “+12”, “+33” as the G value to be added to the digestion counter, and “8” as the B value to replace the boss battle counter. Also, as a general rule, if the value of the extended game counter is “1” or more in the RT4 gaming state shifted by performing a stop operation according to the navigation information, the navigation information for establishing the RT4 operating combination is notified. Then, the RT4 operating combination is established by performing a stop operation according to the navigation information. In addition, every time an RT4 operating combination is established in the RT4 gaming state, a G value is determined by lottery, and the determined G value is added to the digestion counter. For example, when the value of the extended counter is “3” and “+33” is determined as the G value every time when the RT4 operating combination is established, “99” (3 × 33 = 99) is added.

  Further, as the A value is higher, “+99” is determined as a G value to be added to the digestion counter with a higher probability when the sub-game state management data for outgoing ball is “released”. As described above, the RT2 gaming state continues until the value of the digestion counter becomes “0”. Therefore, when “+99” is determined as the G value, the player has a long number of games in the RT2 gaming state. It becomes possible to stay. Further, as described above, the A value is determined based on the current step value, and the higher the step value, the higher the A value is likely to be determined. Further, even when the set value is low (set values 1 to 3), since the high A value is determined when the step value reaches “21”, the player is in a case where the set value is low. In addition, it can be expected to stay for a long number of games in the RT2 gaming state, and a decrease in the operation of the gaming machine that may occur when the set value is low can be prevented.

  Next, with reference to FIG. 95 and FIG. 96, the sub-outlet releasing lottery table stored in the sub-ROM 72 of the sub-control circuit 70 will be described. FIG. 95 is a diagram showing an example of a sub-outlet ceiling lottery table (Z value: 1) of the gaming machine 1 in this embodiment, and FIG. 96 is a sub-outside ceiling of the gaming machine 1 in this embodiment. It is a figure which shows the example of a lottery table (Z value: 6).

  The sub appearance ball ceiling lottery table is a table used for updating the values of the ceiling counter, the villa counter, the digestion counter, and the boss battle counter in the display command reception process described later with reference to FIG.

  The lottery value is determined in the sub-outlet ceiling lottery table so that the updated value of each counter is determined in accordance with the sub-game state management data (see FIG. 57) and the “RT4 start” or “RT4 in progress”. It is prescribed. For example, when the Z value is “1” and the sub game state management data for the game is “released” and “RT4 start”, T values to be added to the ceiling counter are “+1344” to “+1”. +1600 "is determined. If the value of the ceiling counter is “1600” or more, the mode is “0” to “8” or “26” in the special mode rewriting process of the display command reception process described later with reference to FIG. In some cases, rewriting (transition) to mode “10” is performed. As described above, in the mode “10”, the navigation information for establishing the RT4 operating combination is notified until the RT4 operating state is activated, so the player has a ceiling counter value of “1600” or more. This makes it possible to play a game advantageously.

  In the sub-outlet ceiling lottery table, the lottery value is defined such that the higher the Z value, the higher the T value added to the ceiling counter. As described above, the Z value is determined based on the current step value, and the higher the step value, the higher the Z value is likely to be determined. Even if the set value is low (the set value is 1 to 3), a high Z value is determined when the step value reaches “21”. However, expectation can be expected for the transition to the mode “10”, and a decrease in the operation of the gaming machine that may occur when the set value is low can be prevented.

  Next, the control operation of the main CPU 31 of the main control circuit 60 will be described with reference to the flowcharts shown in FIGS.

  First, with reference to FIG. 97, the reset interrupt processing by the main CPU 31 of the main control circuit 60 will be described. FIG. 97 is a diagram showing a flowchart of reset interrupt processing by the main CPU 31 performed in the main control circuit 60 of the present embodiment. Further, the main CPU 31 generates a reset interrupt when power is turned on and a voltage is applied to the reset terminal, and the reset interrupt process stored in the ROM 32 is sequentially performed based on the occurrence of the interrupt. It is configured as follows.

  First, the main CPU 31 performs designated storage area initialization processing (step S1). Specifically, the main CPU 31 clears the designated storage area of the RAM 33 at the end of the previous game. More specifically, the main CPU 31 erases data in the writable area in the RAM 33 used in the previous game, writes parameters necessary for the current game in the writable area in the RAM 33, and a sequence program in the current game. Specify the start address to

  Next, the main CPU 31 performs medal acceptance / start check processing, which will be described later with reference to FIG. 98 (step S2). In the medal acceptance / start check process, the insertion number counter is updated by checking the medal sensor 22S, the maximum BET switch 13S, and the like, and the input of the start switch 6S is checked. The main CPU 31 validates the center line 8c, which is a winning line, by medal acceptance / start check processing.

  Next, the main CPU 31 performs random value extraction processing (step S3). Specifically, the main CPU 31 extracts a random value from the range of “0” to “65535” by the random number generator 36 and the sampling circuit 37 and stores the extracted random value in the random value storage area of the RAM 33.

  Next, the main CPU 31 performs an internal lottery process which will be described later with reference to FIGS. 99 and 100 (step S4). Specifically, the main CPU 31 refers to the internal lottery table determination table (see FIG. 6), the internal lottery table (see FIGS. 7 to 15), and the internal winning combination determination table (see FIGS. 16 to 19). To determine the internal winning role.

  Next, the main CPU 31 performs a reel stop initial setting process which will be described later with reference to FIG. 101 (step S5).

  Next, the main CPU 31 stores start command data in the communication data storage area (step S6). The start command includes information such as game state information, internal winning combination information (data pointer for small role / replay, bonus data pointer and internal winning combination storage area), and carryover state information indicating whether or not a bonus carryover state exists. It is included. The command data stored in the communication data storage area is transmitted to the sub-control circuit 70 in the communication data transmission process (step S444) of an interrupt process which will be described later with reference to FIG.

  Next, the main CPU 31 determines whether or not the game time management timer is “0” (step S7). At this time, when the main CPU 31 determines that the game time management timer is “0”, the main CPU 31 proceeds to the process of step S9. On the other hand, when the main CPU 31 determines that the gaming time management timer is not “0”, the main CPU 31 digests the waiting time until the gaming time management timer becomes “0” (step S8), and proceeds to the processing of step S9. . Next, the main CPU 31 sets an initial value in the game time management timer (step S9).

  Next, the main CPU 31 requests the start of rotation of all reels (step S10). When the start of rotation of all reels is requested, rotation start processing and acceleration control processing of the reels 3L, 3C, and 3R are performed.

  Next, the main CPU 31 stores a reel rotation start command in the communication data storage area (step S11).

  Next, the main CPU 31 performs a pull-in priority storage process described later with reference to FIG. 102 (step S12), and then performs a reel stop control process described later with reference to FIG. 105 (step S13). In the reel stop control process, the main CPU 31 stops the rotation of the reels 3L, 3C, and 3R based on a stop signal transmitted from the stop switches 7LS, 7CS, and 7RS by the stop operation of the player.

  Next, the main CPU 31 performs a winning action search process which will be described later with reference to FIG. 111 (step S14). In the winning action search process, the main CPU 31 determines the display combination and the number of payouts based on the combination of symbols displayed on the effective line as a result of stopping the rotation of all the reels 3L, 3C, 3R.

  Next, the main CPU 31 performs a winning check / medal payout process, which will be described later with reference to FIG. 112 (step S15).

  Next, the main CPU 31 determines whether or not the BB1 gaming state flag, the BB2 gaming state flag, the RB1 gaming state flag, or the RB2 gaming state flag is on (step S16). At this time, when the main CPU 31 determines that the BB1 gaming state flag, the BB2 gaming state flag, the RB1 gaming state flag, or the RB2 gaming state flag is on, the main CPU 31 performs a bonus end check process described later with reference to FIG. The process proceeds to step S17) and step S18. On the other hand, when the main CPU 31 determines that the BB1 gaming state flag, the BB2 gaming state flag, the RB1 gaming state flag, or the RB2 gaming state flag is not on, or after the processing of step S17 is completed, the process proceeds to FIG. Is used to perform a bonus operation check process to be described later (step S18), and the process proceeds to step S19.

  Finally, the main CPU 31 performs RT control processing which will be described later with reference to FIG. 115 (step S19). When this process ends, the main CPU 31 proceeds to the process of step S1.

  In this way, the main CPU 31 executes the processing from step S1 to step S19 as processing in one game (one game), and when the processing in step S19 ends, the processing in step S1 is executed to execute processing in the next game. Migrate to

  Next, with reference to FIG. 98, the medal acceptance / start check process will be described. FIG. 98 is a diagram showing a flowchart of medal acceptance / start check processing performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 determines whether or not the value of the automatic insertion counter is “0” (step S41). At this time, when the main CPU 31 determines that the value of the automatic insertion counter is not “0”, the main CPU 31 copies the automatic insertion counter to the insertion number counter, clears the automatic insertion counter (step S42), and performs the process of step S44. Migrate to The inserted number counter is data for counting the inserted number. On the other hand, when the main CPU 31 determines that the value of the automatic insertion counter is “0”, the main CPU 31 then permits passage of medals (step S43), and proceeds to the processing of step S44. The automatic insertion counter is data for identifying whether or not a replay has been established in the previous game and for determining the number of medals inserted in the previous game.

  Next, the main CPU 31 sets “3” as the maximum value of the insertion number counter (step S44).

  Next, the main CPU 31 determines whether or not a medal has passed (step S45). At this time, when the main CPU 31 determines that no medal has passed, the process proceeds to step S51. On the other hand, when determining that the medal has passed, the main CPU 31 determines whether or not the value of the inserted number counter is equal to the maximum value (step S46).

  When the main CPU 31 determines in the process of step S46 that the value of the inserted number counter is not equal to the maximum value, the main CPU 31 adds “1” to the value of the inserted number counter (step S47) and sets “1” to the effective line counter. While storing (step S48), medal insertion command data is stored in the communication data storage area (step S49), and the process proceeds to step S51. The valid line counter is data for specifying the number of valid lines, and the display combination is searched based on the valid line counter. Note that the number of effective lines in this embodiment is defined as “1”. On the other hand, when the main CPU 31 determines that the value of the inserted number counter is equal to the maximum value, “1” is added to the value of the credit counter (step S50), and the process proceeds to step S51. Here, the credit counter is data for counting the number of credited medals.

  Next, when the main CPU 31 determines that the medal has not passed in the process of step S45, or after performing the process of step S50, it next checks the maximum BET switch 13S (step S51). Specifically, when the maximum BET switch 13S is on, the main CPU 31 calculates a value to be added to the insertion number counter based on the maximum values of the insertion number counter, the credit counter, and the insertion number counter. Update the number counter.

  Next, the main CPU 31 determines whether or not the value of the insertion number counter is equal to the maximum value (step S52). At this time, when the main CPU 31 determines that the value of the insertion number counter is not equal to the maximum value, the main CPU 31 proceeds to the processing of step S45. On the other hand, when the main CPU 31 determines that the value of the insertion number counter is equal to the maximum value, it next determines whether or not the start switch 6S is on (step S53).

  When the main CPU 31 determines in the process of step S53 that the start switch 6S is not on, the main CPU 31 proceeds to the process of step S45. On the other hand, when determining that the start switch 6S is on, the main CPU 31 prohibits the passage of medals (step S54) and ends the medal acceptance / start check process. When the main CPU 31 finishes the medal acceptance / start check process, the main CPU 31 proceeds to the process of step S3 in FIG.

  Next, with reference to FIGS. 99 and 100, the internal lottery process will be described. 99 and 100 are flowcharts showing the internal lottery process performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 refers to the internal lottery table determination table (see FIG. 6) and determines the type of the internal lottery table and the number of lotteries based on the game state flag (step S61).

  Next, the main CPU 31 acquires a random value from the random value storage area and sets it as a random number for determination (step S62).

  Next, the main CPU 31 sets the number of lotteries as the initial value of the winning number (step S63).

  Next, the main CPU 31 refers to the internal lottery table and acquires a lottery value based on the winning number (step S64).

  Next, the main CPU 31 subtracts the lottery value from the determination random number value, and sets the subtraction result as the determination random number value (step S65). Specifically, the main CPU 31 subtracts the lottery value acquired in the process of step S64 from the random number value for determination stored in the random number value storage area for determination, and updates the random number value storage area for determination with the subtraction result. .

  Next, the main CPU 31 determines whether or not a digit has been performed in the subtraction process of step S65, that is, whether or not the subtraction result has become a negative value (step S66). At this time, when the main CPU 31 determines that a digit has been made, the main CPU 31 determines the small role / replay data pointer and the bonus data pointer based on the winning number (step S71), and proceeds to the processing of step S72. On the other hand, when the main CPU 31 determines that no digit has been set, it subtracts “1” from the winning number (step S67) and subtracts “1” from the number of lotteries (step S68). Next, the main CPU 31 determines whether or not the number of lotteries is “0” (step S69).

  When determining that the number of lotteries is “0” in the process of step S69, the main CPU 31 determines the small role / replay data pointer and the bonus data pointer to be “0” (step S70). Transition to processing. On the other hand, when determining that the number of lotteries is not “0”, the main CPU 31 proceeds to the process of step S64. Thereafter, the main CPU 31 repeats the processing from step S64 to step S69 until the number of lotteries becomes “0” or a digit is obtained.

  After completing the processing of step S70 or step S71, the main CPU 31 refers to the small winning combination / replay internal winning combination determination table shown in FIGS. 16 to 18 and based on the small winning combination / replay data pointer. An internal winning combination is acquired (step S72).

  Next, the main CPU 31 stores the acquired internal winning combination in the corresponding internal winning combination storing area (step S73).

  Next, the main CPU 31 determines whether or not the carryover combination storage area is “00000000” (step S74). At this time, when the main CPU 31 determines that the carryover combination storage area is not “00000000”, the main CPU 31 proceeds to the process of step S81. On the other hand, when the main CPU 31 determines that the carryover combination storage area is “00000000”, the main CPU 31 refers to the bonus internal winning combination determination table shown in FIG. 19 and acquires the internal winning combination based on the bonus data pointer ( Step S75). Next, the main CPU 31 stores the acquired internal winning combination in the carryover combination storage area (step S76).

  Next, the main CPU 31 determines whether or not the carryover combination storage area is “00000000” (step S77). At this time, when the main CPU 31 determines that the carryover combination storage area is “00000000”, the main CPU 31 proceeds to the process of step S81. On the other hand, when the main CPU 31 determines that the carryover combination storage area is not “00000000”, the main CPU 31 turns on the RT6 gaming state flag (step S80), and proceeds to the processing of step S81.

  Next, the main CPU 31 stores the logical sum of the carryover combination storage area and the internal winning combination storage area 29 in the internal winning combination storage area 29 (step S81), and ends the internal lottery process.

  When the main CPU 31 finishes the internal lottery process, the main CPU 31 proceeds to step S5 in the reset interrupt process (FIG. 97).

  The main CPU 31 performs lottery of an internal winning combination by repeatedly executing the processes of steps S64 to S69 in the internal lottery process. Specifically, the main CPU 31 sequentially subtracts the lottery value from the extracted random number value, thereby obtaining the small role / replay data pointer and bonus data pointer corresponding to the winning number when the digit is placed. The internal winning combination is determined based on the determined data pointers and the internal winning combination determination table.

  Next, the reel stop initial setting process will be described with reference to FIG. In addition, FIG. 101 is a diagram showing a flowchart of the reel stop initial setting process performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 determines the same value as the value of the small role / replay data pointer as the rotation stop number (step S101). Next, the main CPU 31 refers to the rotation stop initial setting table (FIG. 28), and acquires the pull-in priority table selection number or the pull-in priority table number based on the rotation stop number (step S102).

  Next, the main CPU 31 refers to the rotation stop initial setting table (FIG. 28), and acquires line data, stop table number, and change data selection number for each stop button based on the rotation stop number (see FIG. 28). Step S103). Next, the main CPU 31 stores the acquired line data and stop table number of each stop button in the stop table selection value 1 storage area to the stop table selection value 3 storage area (step S104). Specifically, the main CPU 31 stores the line data and stop table number of the left stop button in the stop table selection value 1 storage area, and the line data and stop table number of the middle stop button in the stop table selection value 2 storage area. Store the line data and stop table number of the right stop button in the stop table selection value 3 storage area.

  Next, the main CPU 31 stores a rotating identifier (bit string “11111111”) indicating that it is rotating in all symbol storage areas (FIG. 51) (step S105). Next, the main CPU 31 stores “3” in the stop button non-operating counter (step S106), and ends the reel stop initial setting process.

  Next, with reference to FIG. 102, the pull-in priority storage process will be described. FIG. 102 is a diagram showing a flowchart of the pull-in priority storage process performed in the main control circuit 60 of the present embodiment.

  First, the main CPU 31 sets the value of the stop button non-operating counter in the search number counter (step S111).

  Next, the main CPU 31 determines a search target reel (step S112). Specifically, the main CPU 31 determines a reel on the left side as a search target reel among reels corresponding to a stop button for which a stop operation is not performed. Next, the main CPU 31 determines the storage area type of the drawing priority data storage area (FIG. 50) corresponding to the determined reel to be searched (step S113).

  Next, the main CPU 31 performs a pull-in priority table selection process which will be described later with reference to FIG. 103 (step S114).

  Next, the main CPU 31 determines “0” as the symbol position data and “21” as the symbol check number (step S115).

  Next, the main CPU 31 clears the display combination storing area (FIG. 46) and designates the head address of the symbol storing area (FIG. 51) according to the number of valid lines (step S116). In the present embodiment, since there is only one center line, the area corresponding to the center line is designated as the head address.

  Next, the main CPU 31 refers to the symbol arrangement table (FIG. 3), and stores the symbol code in the symbol storage area (FIG. 51) of the search target reel based on the symbol position data (step S117). For example, when the search target reel is the left reel 3L and the symbol position data is “3”, the main CPU 31 sets the symbol code “00000101” (bell) in the area corresponding to the middle stage of the left reel of the effective line 1. A design) is stored.

  Next, the main CPU 31 generates symbol corresponding winning action flag data based on the symbol combination table (FIGS. 20 to 24) and the symbol code stored in the symbol storage area (FIG. 51) (step S118). Specifically, the symbol corresponding winning action flag data is temporary work data having the same data configuration as the display combination storage area (FIG. 46), and the main CPU 31 excludes the rotating reel (rotating). In the symbol storage area corresponding to the reel, the identifier “11111111” indicating that it is rotating is stored), and the symbol code stored in the symbol storage area is compared with the symbol combination table. For each matching combination, “1” is set to the bit in the symbol corresponding winning action flag data. That is, “1” is set to the bit corresponding to the combination of symbols that can be displayed (or displayed) on the active line. Next, the main CPU 31 overwrites and updates the display combination storage area (FIG. 46) based on the generated symbol corresponding winning action flag data (step S119).

  Next, the main CPU 31 performs an acquisition priority acquisition process, which will be described later with reference to FIG. 104 (step S120).

  Next, the main CPU 31 stores the pull-in priority data acquired in the process of step S120 in the area corresponding to the symbol position data in the pull-in priority data storage area (FIG. 50) indicated by the storage area type determined in the process of step S113. Is stored (step S121). Next, the main CPU 31 subtracts “1” from the number of symbol checks and adds “1” to symbol position data (step S122).

  Next, the main CPU 31 determines whether or not the number of symbol checks is “0” (step S123). At this time, when the main CPU 31 determines that the number of symbol checks is not “0”, the main CPU 31 proceeds to the processing of step S116. That is, the main CPU 31 repeats the processing from step S116 to step S123 until the drawing priority data is stored in the area corresponding to all the symbol positions of the search target reel in the drawing priority data storage area (FIG. 50). On the other hand, when the main CPU 31 determines that the number of symbol checks is “0”, it subtracts “1” from the value of the search number counter (step S124).

  Next, the main CPU 31 determines whether or not the value of the search number counter is “0” (step S125). At this time, when the main CPU 31 determines that the value of the search number counter is not “0”, the main CPU 31 proceeds to the process of step S112. On the other hand, when the main CPU 31 determines that the value of the search number counter is “0”, the main CPU 31 ends the pull-in priority storage process.

  Next, the pull-in priority table selection process will be described with reference to FIG. FIG. 103 is a diagram showing a flowchart of the pull-in priority table selection process performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 determines whether or not a pull-in priority table number has been acquired from the spinning cylinder stop initial setting table in the process of step S102 (FIG. 101) (step S141). At this time, when the main CPU 31 determines that the pull-in priority table number has been acquired from the spinning cylinder stop initial setting table, the main CPU 31 ends the pull-in priority table selection process. On the other hand, if the main CPU 31 determines that the pull-in priority table number has not been acquired from the spinning cylinder stop initial setting table, then the stop button non-operating counter is “3” (that is, before the first stop). It is determined whether or not (step S142).

  When the main CPU 31 determines that the stop button non-operating counter is “3” in the process of step S142, the main CPU 31 refers to the pull-in priority table selection table (FIG. 29) and acquires it by the process of step S102 (FIG. 101). Based on the drawn priority order table selection number, the first priority order drawing priority table number corresponding to the search target reel is acquired (step S143). On the other hand, when the main CPU 31 determines that the stop button non-operating counter is not “3”, it next determines whether or not the stop button non-operating counter is “2” (that is, before the second stop) ( Step S144).

  When the main CPU 31 determines in the process of step S144 that the stop button non-operation counter is “2”, the main CPU 31 refers to the pull-in priority table selection table (FIG. 29) and acquires it by the process of step S102 (FIG. 101). Based on the selected pull-in priority table selection number, the pull-in priority table number for the second and third stops according to the type of the ineffective stop button and the reel to be searched is acquired (step S145), and the pull-in priority table The selection process ends. On the other hand, when the main CPU 31 determines that the stop button non-operating counter is not “2”, the main CPU 31 ends the pull-in priority table selection process.

  Next, with reference to FIG. 104, the drawing priority order acquisition processing will be described. Note that FIG. 104 is a diagram showing a flowchart of the acquisition priority order acquisition process performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 sets “0” in the target bit of the display combination storing area (FIG. 46) corresponding to the combination including “ANY” in accordance with the search target reel (step S161). Note that the target bit in this embodiment is only bit 0 of the storage area type “20” of the display combination storage area.

  Next, the main CPU 31 calculates the logical product of the internal winning combination storage areas 1 to 29 (FIG. 45) and the display combination storage areas 1 to 29 (FIG. 46) and stores them in the display combination storage areas 1 to 29 ( Step S162). Specifically, the main CPU 31 calculates a logical product of the area having the storage area type 1 to 29 in the internal winning combination storage area and the area having the storage area type 1 to 29 in the display combination storage area, and displays the display combination. The storage area type in the storage area is stored in an area of 1 to 29.

  Next, the main CPU 31 determines whether or not it is a prohibited winning action position (step S163). That is, the symbol position data (the initial value is determined in the process of step S115 and incremented by “1” in the process of step S122) in the search target reel (the reel determined in the process of step S112). .) Is stopped on the center line, and it is determined whether or not a combination not determined as an internal winning combination may be established. The formation of a combination that has not been determined as an internal winning combination is referred to as “prohibited winning action”. At this time, when the main CPU 31 determines that the position is not the prohibited winning operation position, the process proceeds to step S167. On the other hand, when determining that the main CPU 31 is in the prohibited winning operation position, the main CPU 31 then determines whether or not the value of the stop button non-operation counter is “1” (that is, before the third stop) (step S164). .

  When the main CPU 31 determines in the process of step S164 that the value of the stop button non-operation counter is “1”, the main CPU 31 proceeds to the process of step S166. On the other hand, when the main CPU 31 determines that the value of the stop button non-operating counter is not “1”, the main CPU 31 then determines whether or not a combination including “ANY” interferes (step S165). Specifically, in the process of step S165, the symbol corresponding to the symbol position data in the search target reel stops on the center line, and a combination including “ANY” that is not determined as the internal winning combination is established. It is determined whether or not there is a problem. In the present embodiment, since the role including “ANY” is only the cherry (cherry symbol-ANY symbol-ANY symbol), the search target reel is the left reel 3L and the symbol position data is “0” or It is determined whether or not “12”.

  When the main CPU 31 determines in the process of step S165 that the combination including “ANY” interferes, the main CPU 31 proceeds to the process of step S166. On the other hand, when the main CPU 31 determines that the combination including “ANY” does not interfere, the main CPU 31 proceeds to the process of step S167.

  When the main CPU 31 determines that the value of the stop button non-operating counter is “1” in the process of step S164 or when it is determined that the combination including “ANY” interferes in the process of step S165, then the main CPU 31 “00000000” indicating prohibition of stoppage is acquired as the priority order data (step S166), and the drawing priority order acquisition process is terminated.

  When the main CPU 31 determines that it is not the prohibited winning operation position in the process of step S163, or when it is determined that the combination including “ANY” does not interfere in the process of step S165, then, based on the drawing priority table number. Then, the number of checks is determined and the initial value of the priority order counter is set (step S167). Specifically, when the pull-in priority table number acquired in the process of step S102 (FIG. 101), step S143 (FIG. 103) or step S145 (FIG. 103) is “PLVLTB00”, the number of checks is set to “5”. And the initial value of the priority order counter is set to “5”. On the other hand, when the pull-in priority table number is “PLVLTB01”, the number of checks is determined as “1” and the initial value of the priority counter is set to “1”. Next, the main CPU 31 saves the pull-in priority data in which “00000001” indicating stoppage is set as an initial value (step S168).

  Next, the main CPU 31 acquires the pull-in data corresponding to the value of the priority counter in the priority table (FIGS. 30A and 30B) corresponding to the pull-in priority table number (step S169).

  Next, the main CPU 31 obtains the logical product of the acquired pull-in data and the display combination storage area (step S170), and determines whether or not all the bits are “0” (step S171). At this time, when the main CPU 31 determines that all the bits are “0”, the main CPU 31 proceeds to the process of step S173. On the other hand, when the main CPU 31 determines that all the bits are not “0” (that is, at least one bit is “1”), the main CPU 31 corresponds the saved pull-in priority data to the pull-in priority table number. Overwrite update is performed with the pull-in priority data corresponding to the value of the priority counter in the priority table (FIGS. 30A and 30B) (step S172), and the process proceeds to step S173.

  Next, the main CPU 31 subtracts “1” from the number of checks, and adds “1” to the value of the priority order counter (step S173). Next, the main CPU 31 determines whether or not the number of checks is “0” (step S174). At this time, when the main CPU 31 determines that the number of checks is not “0”, the main CPU 31 proceeds to the processing of step S169. On the other hand, when determining that the number of checks is “0”, the main CPU 31 acquires the saved priority order data (step S175), and ends the priority order acquisition process.

  Next, the reel stop control process will be described with reference to FIG. FIG. 105 is a diagram showing a flowchart of the reel stop control process performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 determines whether or not a stop operation has been detected by a stop switch corresponding to a valid stop button (step S191). At this time, when the main CPU 31 determines that the stop operation is not detected by the stop switch corresponding to the valid stop button, the main CPU 31 executes the process of step S191 again. That is, the main CPU 31 repeats the process of step S191 until a stop operation is performed on an effective stop button. On the other hand, when the main CPU 31 determines that the stop operation is detected by the stop switch corresponding to the valid stop button, the main CPU 31 determines the stop button as the operation stop button (step S192).

  Next, the main CPU 31 sets the corresponding bit in the effective stop button storage area (FIG. 52) to “0” based on the determined operation stop button (step S193). For example, when the stop signal indicating that the stop operation for the left stop button 7L has been performed is transmitted from the reel position detection circuit 50, the main CPU 31 sets bit 0 of the effective stop button storage area from “1” to “1”. Update to "0". Next, the main CPU 31 subtracts “1” from the value of the stop button non-operating counter (step S194).

  Next, the main CPU 31 performs a sliding frame number determination process which will be described later with reference to FIG. 106 (step S195).

  Next, the main CPU 31 determines a planned stop position based on the value of the symbol counter and the number of sliding symbols (step S196). Next, the main CPU 31 stores a reel stop command in the communication data storage area (step S197). Next, the main CPU 31 refers to the symbol arrangement table (FIG. 3), acquires the symbol code corresponding to the scheduled stop position, and stores it in the symbol storage area (FIG. 51) corresponding to the operation stop button (step S198). It should be noted that the symbol code stored in the symbol storage area in the process of step S198 remains stored until the game being played at that time ends.

  Next, the main CPU 31 determines whether or not the value of the stop button non-operating counter is “0” (step S199). At this time, when the main CPU 31 determines that the value of the stop button non-operating counter is “0”, the reel stop control process ends. On the other hand, when the main CPU 31 determines that the value of the stop button non-operating counter is not “0”, the main CPU 31 performs the drawing priority order obtaining process shown in FIG. 102 (step S200), and proceeds to the process of step S191.

  Next, the sliding frame number determination process will be described with reference to FIG. FIG. 106 is a flowchart of the sliding frame number determination process performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 determines whether or not the stop button non-operation counter is “2” (that is, at the time of the first stop) (step S221). At this time, when the main CPU 31 determines that the stop button non-operation counter is “2”, the main CPU 31 sets the line data and stop table number stored in the stop table selection value storage area (FIG. 49) corresponding to the operation stop button. Obtain (step S222), the process proceeds to step S229. On the other hand, when the main CPU 31 determines that the stop button non-operating counter is not “2”, it next determines whether or not the stop button non-operating counter is “0” (that is, at the time of the third stop) ( Step S223).

  When the main CPU 31 determines in the process of step S223 that the stop button non-operating counter is “0”, the main CPU 31 acquires the line data and stop table number stored in the stop table selection value storage area 2 (step S223). S224), the process proceeds to step S229. On the other hand, when the main CPU 31 determines that the stop button non-operation counter is not “0”, it next determines whether or not the right stop button 7R is an effective stop button (step S225).

  When the main CPU 31 determines in the process of step S225 that the right stop button 7R is an effective stop button, the main CPU 31 proceeds to the process of step S228. On the other hand, when the main CPU 31 determines that the right stop button 7R is not an effective stop button, the main CPU 31 then determines whether or not the operation stop button is the left stop button 7L (step S226).

  When determining that the operation stop button is the left stop button 7L in the process of step S226, the main CPU 31 proceeds to the process of step S228. On the other hand, when the main CPU 31 determines that the operation stop button is not the left stop button 7L, the main CPU 31 then stores the line data and stop table number stored in the stop table selection value storage area 4 in the stop table selection value storage area 1. The line data stored in the stop table selection value storage area 3 and the stop table number are stored in the stop table selection value storage area 2 (step S227).

  In the stage where the process of step S227 is executed, the stop table selection value storage area 1 to the stop table selection value storage area 4 are stored in the stop data storage process after the first stop, which will be described later with reference to FIG. A stop table and line data for second and third stops are stored. For example, when the first stop operation is the right stop button 7R, each data (line data and second data) when the second stop operation is performed with the left stop button 7L is stored in the stop table selection value storage area 1. Stop table number for stop) is stored, and the stop table selection value storage area 2 stores each data (line data and third stop table for stop) when the third stop operation is performed with the middle stop button 7L. In the stop table selection value storage area 3, each data when the third stop operation is performed with the left stop button 7L is stored. In the stop table selection value storage area 4, Each data when the second stop operation is performed with the middle stop button 7C is stored.

  The main CPU 31 determines that the right stop button 7R is an effective stop button in the process of step S225, determines that the operation stop button is the left stop button 7L in the process of step S226, or performs the process of step S227. After the execution, the line data and stop table number stored in the stop table selection value storage area 1 are acquired (step S228), and the process proceeds to step S229.

  After performing the processing of step S222, step S224, and step S228, the main CPU 31 updates the acquired stop table number according to the operation stop button (step S229). Here, the main CPU 31 converts the stop table number stored in the bit 0 to bit 5 of each stop table selection value storage area into the decimal system, and then adds the value according to the operation stop button. To do. Specifically, “100” is added when the operation stop button is the left stop button 7L, and “200” is added when the operation stop button is the middle stop button 7C, and the operation stop button When the is the right stop button 7R, “300” is added.

  Next, the main CPU 31 designates the address “00” of the pull-in priority data storage area (FIG. 50) corresponding to the operation stop button (step S230). Next, the main CPU 31 adds the address of the pull-in priority order data storage area based on the stop start position, and obtains it as an expected stop start address (step S231). For example, if the stop start position is “05”, “05” is added to the current address “00” of the pull-in priority data storage area, and the expected stop start address “05” is acquired.

  Next, the main CPU 31 refers to the stop table (FIGS. 31 to 39) corresponding to the stop table number, and acquires the sliding frame number determination data based on the line data and the stop start position (step S232).

  Next, the main CPU 31 performs a priority pull-in control process, which will be described later with reference to FIG. 107 (step S233), and ends the sliding frame number determination process. In the priority pull-in control process, a predetermined range (that is, the maximum slip) is determined from the symbol of the stop start position of the corresponding reel based on the pull-in priority data determined for each symbol of the corresponding reel and the priority order table. The symbol with the highest priority among the symbols up to the symbol having the number of frames “4”) is determined.

  Next, the priority pull-in control process will be described with reference to FIG. FIG. 107 is a flowchart of the priority pull-in control process performed by the main control circuit 60 of this embodiment.

  Next, the main CPU 31 sets “5” as the number of checks and “5” as the initial value of the priority order counter (step S251). Next, the main CPU 31 saves the number of sliding frames set with the number of pieces of sliding frame determination as an initial value (step S252).

  Next, the main CPU 31 refers to the priority order table (FIG. 40), and acquires the sliding frame number determination data and the number of provisional sliding frames corresponding to the value of the priority order counter (step S253). Next, the main CPU 31 adds the acquired number of temporary sliding frames to the expected stop start address in the pull-in priority data storage area (FIG. 50), and acquires pull-in priority data (step S254).

  Next, the main CPU 31 compares the previously acquired drawing priority data with the currently acquired drawing priority data, and whether or not the currently acquired drawing priority data is equal to or higher than the previously acquired drawing priority data. Is determined (step S255). At this time, when the main CPU 31 determines that the data is not higher than the previously acquired pull-in priority data, the process proceeds to step S257. On the other hand, when the main CPU 31 determines that it is greater than or equal to the previously acquired pull-in priority data (including when there is no previously acquired pull-in priority data), the number of evacuated slip frames is acquired this time. Overwriting is updated with the number of frames (step S256), and the process proceeds to step S257.

  The main CPU 31 subtracts “1” from the number of checks and determines from the priority order counter when it is determined in the process of step S255 that it is not equal to or higher than the acquisition priority order data acquired previously or after the process of step S256. “1” is subtracted (step S257).

  Next, the main CPU 31 determines whether or not the number of checks is “0” (step S258). At this time, when the main CPU 31 determines that the number of checks is “0”, the main CPU 31 restores the number of evacuated sliding frames (step S259) and ends the priority pull-in control process. On the other hand, when determining that the number of checks is not “0”, the main CPU 31 proceeds to the process of step S253. The main CPU 31 repeats the processing from step S253 to step S258 as many times as the number of checks, so that the symbol having the highest priority among the symbols within “4” frames defined as the maximum number of sliding frames from the stop start position. The number of sliding symbols for stopping the symbol according to the above on the active line is determined.

  Next, stop data storage processing will be described with reference to FIG. FIG. 108 is a diagram illustrating a flowchart of stop data storage processing performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 determines whether or not the stop button non-operation counter is “2” (step S271). At this time, when the main CPU 31 determines that the stop button non-operating counter is “2”, the main CPU 31 performs stop data storage processing after first stop, which will be described later with reference to FIG. 109, and ends the stop data storage processing. On the other hand, when the main CPU 31 determines that the stop button non-operating counter is not “2”, the main CPU 31 performs a second post-stop stop data storage process to be described later with reference to FIG. 110 and ends the stop data storage process.

  Next, stop data storage processing after the first stop will be described with reference to FIG. FIG. 109 is a diagram showing a flowchart of the first post-stop stop data storage process performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 saves the line data and stop table number stored in the stop table selection value storage area corresponding to the operation stop button (step S291). Next, the main CPU 31 initializes the stop table selection value storage areas 1 to 4 (step S292). Next, the main CPU 31 stores the saved line data and stop table number in the stop table selection value storage areas 1 to 4 (step S293).

  Next, the main CPU 31 refers to the first post-stop change data table selection value determination table (FIG. 41), and based on the planned stop position and the change data selection number obtained in step S103 (FIG. 101). Then, the change data table selection value is acquired (step S294). Next, the main CPU 31 determines whether or not the change data table selection value has been acquired (that is, a value (including “00”) has been acquired instead of “−”) (step S295). At this time, when the main CPU 31 determines that the changed data table selection value cannot be acquired, the main CPU 31 ends the stop data storage process after the first stop. On the other hand, when the main CPU 31 determines that the change data table selection value has been acquired, the main CPU 31 then refers to the first stop post-stop change table number determination table (FIG. 42) and acquires it in the process of step S103 (FIG. 101). The line data and stop table number corresponding to the stop table selection value storage areas 1 to 4 are acquired based on the changed data selection number and the change data table selection value acquired in step S294 (step S296). Next, the main CPU 31 overwrites and updates the stop table selection value storage areas 1 to 4 with the acquired line data and stop table number (step S297), and ends the stop data storage process after the first stop.

  Next, stop data storage processing after the second stop will be described with reference to FIG. FIG. 110 is a diagram showing a flowchart of the second post-stop stop data storage process performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 refers to the stop order check data (FIG. 54), and acquires the first stop reel and the second stop reel (step S311). That is, information indicating which reel 3 was the first stop reel and the second stop reel is acquired. Next, the main CPU 31 refers to the second post-stop change data table selection table (FIG. 43) and determines whether a stop position check is necessary from the acquired first stop reel and second stop reel (steps S312 and S313). ). When determining that the stop position check is not necessary, the main CPU 31 ends the stop data storage process after the second stop. On the other hand, when the main CPU 31 determines that the stop position check is necessary, the main CPU 31 then determines the position check data storage area (FIG. 55) and the stop position check for each stop reel (first stop reel, second stop reel). A logical product with the stop position check data corresponding to each stop position check data selection value in the data selection table (FIG. 44) is calculated (step S314).

  Next, the main CPU 31 determines whether or not there is a combination in which any bit in the logical product is “1” in both the first stop reel and the second stop reel (step S315). At this time, when the main CPU 31 determines that there is no combination in which any bit in the logical product is “1” in both the first stop reel and the second stop reel, the main CPU 31 ends the stop data storage process after the second stop. On the other hand, when the main CPU 31 determines that there is a combination in which any bit in the logical product is “1” for both the first stop reel and the second stop reel, the type and stop of the first stop reel constituting the combination The position check data selection value, the type of the second stop reel and the stop position check data selection value are checked with reference to the second post-stop change data table selection table (FIG. 43) (step S316).

  Next, the main CPU 31 determines whether or not there is a corresponding combination as a result of the check in the process of step S316 (step S317). At this time, when determining that there is no corresponding combination, the main CPU 31 ends the stop data storage process after the second stop. On the other hand, when the main CPU 31 determines that there is a corresponding combination, the main CPU 31 refers to the second post-stop change data table selection table (FIG. 43) and stores it in the stop table selection value storage area 2 based on the corresponding combination. Line data and a stop table number are acquired (step S318). Next, the main CPU 31 overwrites and updates the stop table selection value 2 storage area with the acquired line data and stop table number (step S319), and ends the stop data storage process after the second stop.

  Next, the display combination retrieval process will be described with reference to FIG. FIG. 111 is a diagram showing a flowchart of the display combination search process performed by the main control circuit 60 of the present embodiment. The display combination retrieval process is a process called from the process of step S14 of the reset interrupt process (see FIG. 97) by the main CPU 31.

  First, the main CPU 31 clears the display combination storage area and sets the address of the symbol storage area (step S331). Specifically, the main CPU 31 sets an address corresponding to the center line 8c.

  Next, the main CPU 31 designates the head address of the symbol combination table shown in FIGS. 20 to 24 (step S332). Specifically, the main CPU 31 designates an address corresponding to 7 replays (center) 1 as a head address.

  Next, the main CPU 31 compares each symbol code defined in the symbol combination table with each symbol code stored in the symbol storage area (step S333).

  Next, as a result of comparison in the process of step S333, the main CPU 31 determines whether or not the symbol codes match except for the area in which the rotating identifier is stored (step S334). At this time, when the main CPU 31 determines that the symbol combination corresponding to the current address in the symbol combination table does not match the symbol combination stored in the area corresponding to the current address in the symbol storage area, When the process proceeds to S337 and it is determined that they match, the winning action flag is stored in the corresponding display combination storing area (step S335). Specifically, the main CPU 31 calculates the logical sum of the 8-bit data indicating the display combination in the symbol combination table and the 8-bit corresponding area of the display combination storage area indicated by the storage area type, and calculates the calculated logic. The corresponding area is overwritten and updated with the sum.

  Next, the main CPU 31 acquires the number of payouts from the symbol combination table, adds it to the payout number counter (step S336), and ends the winning action search process.

  When the main CPU 31 determines in the process of step S334 that the symbol codes do not match even if the area where the identifier during rotation is stored, the main CPU 31 next updates the address of the symbol combination table (step S337). Specifically, the main CPU 31 designates an address corresponding to the next combination in the symbol combination table.

  Next, the main CPU 31 determines whether or not an end code is stored in the address updated in the process of step S337 (step S338). At this time, when the main CPU 31 determines that the end code is not stored, the main CPU 31 proceeds to the process of step S333. On the other hand, when determining that the end code is stored, the main CPU 31 ends the winning operation search process.

  When the main CPU 31 ends the winning action search process, the main CPU 31 proceeds to the process of step S15 of the reset interrupt process (FIG. 97).

  Next, with reference to FIG. 112, a winning check / medal payout process will be described. FIG. 112 is a diagram showing a flowchart of a winning check / medal payout process performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 obtains the type of the winning operation flag stored in the display combination storing area and the value of the payout number counter (step S351).

  Next, the main CPU 31 determines whether or not the value of the payout number counter is “0” (step S352). At this time, when the main CPU 31 determines that the value of the payout number counter is “0”, the main CPU 31 proceeds to the process of step S359. On the other hand, when it is determined that the value of the payout number counter is not “0”, it is then determined whether or not the value of the payout number counter is equal to or greater than the upper limit number (step S353).

  At this time, when the main CPU 31 determines that the value of the payout number counter is less than the upper limit number, the process proceeds to step S355. On the other hand, when it is determined that the value of the payout number counter is equal to or greater than the upper limit number, the value of the payout number counter is corrected to the upper limit value (step S354), and the process proceeds to step S355. In the present embodiment, “8” is defined as the upper limit number of sheets.

  Next, the main CPU 31 determines whether or not the BB1 gaming state flag or the BB2 gaming state flag is on (step S356). At this time, when the main CPU 31 determines that the BB1 gaming state flag or the BB2 gaming state flag is not on, the main CPU 31 proceeds to the process of step S357. On the other hand, when it is determined that the BB1 gaming state flag or the BB2 gaming state flag is on, the bonus end number counter is updated based on the payout number counter (step S356), and the process proceeds to step S357. Specifically, the main CPU 31 subtracts the value of the payout number counter from the value of the bonus end number counter.

  Next, the main CPU 31 performs a credit addition process (step S357) and a medal payout process (step S358), and proceeds to the process of step S359. Specifically, in the payout mode, the main CPU 31 controls the hopper 40 by driving the hopper 40 based on the payout number to pay out medals, and in the credit mode, the RAM 33 based on the payout number. The credit counter set in is updated.

  Next, the main CPU 31 stores the display command data in the communication data storage area (step S359), and ends the winning check / medal payout process. The display command includes information such as display combination information indicating a display combination and payout number information indicating a payout number.

  When the main CPU 31 ends the winning check / medal payout process, the main CPU 31 proceeds to the process of step S16 in the reset interrupt process (FIG. 97).

  Next, with reference to FIG. 113, the bonus end check process will be described. FIG. 113 is a flowchart of the bonus end check process performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 determines whether or not the value of the bonus end number counter is “0” (step S371). At this time, when the main CPU 31 determines that the value of the bonus end number counter is not “0”, the main CPU 31 proceeds to the process of step S376. On the other hand, when determining that the value of the bonus end number counter is “0”, the main CPU 31 proceeds to the process of step S372.

  Next, the main CPU 31 determines whether or not the BB1 gaming state flag or the BB2 gaming state flag is on (step S372). At this time, when the main CPU 31 determines that the BB1 gaming state flag or the BB2 gaming state flag is not on, the main CPU 31 proceeds to the process of step S376. On the other hand, when the main CPU 31 determines that the BB1 gaming state flag or the BB2 gaming state flag is on, the main CPU 31 performs processing at the end of BB (step S373), and proceeds to the processing of step S374. Specifically, the main CPU 31 turns off the BB1 gaming state flag or the BB2 gaming state flag that is turned on in the BB end time process, and turns it off when the RB gaming state flag is turned on. To do.

  Next, the main CPU 31 updates the gaming state to the RT5 gaming state by turning on the RT5 gaming state flag (step S374), and then stores the bonus end command data in the communication data storage area (step S375). End the bonus end check process.

  On the other hand, the main CPU 31 determines that the value of the bonus end number counter is not “0” in the process of step S371 or that the BB1 gaming state flag or the BB2 gaming state flag is not on in the process of step S372. In some cases, “1” is subtracted from the value of the winning count counter (step S376), and “1” is subtracted from the game count counter (step S377).

  Next, the main CPU 31 determines whether or not the value of the winning possible number counter and the value of the possible gaming number counter are “0” (step S378). At this time, when the main CPU 31 determines that the value of the winable number counter and the value of the possible game number counter are not “0”, the main CPU 31 ends the bonus end check process. On the other hand, when the main CPU 31 determines that the value of the winning possible number counter and the value of the possible gaming number counter are “0”, the main CPU 31 then performs RB end time processing (step S379), and ends the bonus end check processing. . Specifically, the main CPU 31 performs processing such as turning off an RB gaming state flag that is on in the RB end time processing.

  When the main CPU 31 ends the bonus end check process, the main CPU 31 proceeds to the process of step S17 of the reset interrupt process (see FIG. 97).

  Next, with reference to FIG. 114, the bonus operation check process will be described. FIG. 114 is a flowchart of the bonus operation check process performed by the main control circuit 60 of the present embodiment.

  First, the main CPU 31 determines whether or not the BB1 gaming state flag or the BB2 gaming state flag is on (step S391). At this time, when the main CPU 31 determines that the BB1 gaming state flag or the BB2 gaming state flag is not on, the main CPU 31 proceeds to the process of step S394. On the other hand, when the main CPU 31 determines that the BB1 gaming state flag or the BB2 gaming state flag is on, the main CPU 31 then determines whether or not the RB1 gaming state flag or the RB2 gaming state flag is on (step S392).

  When determining that the RB1 gaming state flag or the RB2 gaming state flag is on in the process of step S392, the main CPU 31 ends the bonus operation check process. On the other hand, when the main CPU 31 determines that the RB1 gaming state flag or the RB2 gaming state flag is not on, the main CPU 31 performs an RB operation process based on the bonus operation table (step S393), and ends the bonus operation check process. . Specifically, the main CPU 31 sets “8” in the possible game number counter and the possible winning number counter and turns on the RB gaming state flag corresponding to the BB gaming state flag in the RB operation time process.

  On the other hand, when the main CPU 31 determines in the process of step S391 that the BB1 gaming state flag or the BB2 gaming state flag is not on, it then determines whether or not the display combination is any one of BB1 to BB4 (step). S394). At this time, when the main CPU 31 determines that the display combination is any one of BB1 to BB4, the main CPU 31 performs the BB operation process based on the bonus operation table (step S395), and proceeds to the process of step S396. Specifically, when the display combination is BB1 to BB4, the main CPU 31 sets “160” in the bonus end number counter based on the bonus operation time table, and sets the BB1 gaming state flag or the BB2 gaming state flag. Turn on.

  Next, the main CPU 31 turns off the RT6 gaming state flag (step S396), clears the carryover combination storage area (step S397), and then stores bonus start command data in the communication data storage area (step S398). ), The bonus operation check process is terminated.

  On the other hand, when the main CPU 31 determines that the display combination is not any of BB1 to BB4 in the process of step S324, then the display combination is one of the replays (7 replays (center) 1 to 8, 7 replays (top)). 1-16, 7 replay (bottom) 1-8, 7 replay (crossdown) 1-16, 7 replay (crossup) 1-8, replay (center) 1-8, replay (top) 1-14, replay (Bottom) 1-8, replay (crossdown) 1-12, 7 replay (crossup) 1-8, cherry replay A (left push) 1-12, cherry replay B (left push) 1-12, cherry replay It is determined whether or not (RT3) 1-8 replay) (step S399). At this time, when the main CPU 31 determines that the display combination is any replay, the main CPU 31 copies the insertion number counter to the automatic insertion counter (step S400) and ends the bonus operation check process. On the other hand, when the main CPU 31 determines that the display combination is not any replay, the main CPU 31 ends the bonus operation check process.

  When the main CPU 31 ends the bonus operation check process, the main CPU 31 proceeds to the process of step S18 of the reset interrupt process (see FIG. 97).

  Next, the RT control process will be described with reference to FIG. FIG. 115 is a diagram showing a flowchart of the RT control process performed in the main control circuit 60 of the present embodiment.

  First, the main CPU 31 determines whether or not the RT6 gaming state flag is on (step S411). At this time, when the main CPU 31 determines that the RT6 gaming state flag is on, the main CPU 31 ends the RT control process. On the other hand, when the main CPU 31 determines that the RT6 gaming state flag is not on, the main CPU 31 proceeds to the processing of step S412.

  Next, the main CPU 31 determines whether the display combination is a general game state operation combination (RT operation symbols (general) 1 to 8, replay (center) 1 to 8, replay (bottom) 1 to 8). Is discriminated (step S412). At this time, when the main CPU 31 determines that the display combination is the general gaming state operating combination, the main CPU 31 updates the gaming state to the general gaming state by turning off the gaming state flag that is turned on (step S413). Then, the RT control process is terminated. On the other hand, when the main CPU 31 determines that the display combination is not the general gaming state operating combination, the main CPU 31 proceeds to the process of step S414.

  Next, the main CPU 31 determines whether or not the display combination is an RT1 operation combination (any of RT operation symbols (RT1) 1 to 32) (step S414). At this time, when the main CPU 31 determines that the display combination is the RT1 operating combination, the main CPU 31 updates the gaming state to the RT1 gaming state by turning on the RT1 gaming state flag (step S415), and ends the RT control process. Let On the other hand, when the main CPU 31 determines that the display combination is not the RT1 operation combination, the main CPU 31 proceeds to the process of step S416.

  Next, the main CPU 31 determines whether or not the display combination is an RT2 operation combination (any of replays (cross-up) 1 to 8) (step S416). At this time, when the main CPU 31 determines that the display combination is the RT2 operating combination, the main CPU 31 updates the gaming state to the RT2 gaming state by turning on the RT2 gaming state flag (step S417), and ends the RT control process. Let On the other hand, when the main CPU 31 determines that the display combination is not the RT2 operation combination, the main CPU 31 proceeds to the process of step S418.

  Next, the main CPU 31 displays RT3 actuators (replay (top) 1-8, cherry replay A (left push) 1-12, cherry replay B (left push) 1-12, cherry replay (RT3) 1 It is discriminated whether or not (any one of ˜8) (step S418). At this time, when the main CPU 31 determines that the display combination is the RT3 operating combination, the main CPU 31 updates the gaming state to the RT3 gaming state by turning on the RT3 gaming state flag (step S419), and ends the RT control process. Let On the other hand, when the main CPU 31 determines that the display combination is not the RT3 operation combination, the main CPU 31 proceeds to the process of step S420.

  Next, the main CPU 31 displays RT4 actuators (7 replay (center) 1-8, 7 replay (top) 1-16, 7 replay (bottom) 1-8, 7 replay (crossdown) 1-16. , 7 replays (cross-up) 1 to 8) (step S420). At this time, when the main CPU 31 determines that the display combination is the RT4 operating combination, the main CPU 31 updates the gaming state to the RT4 gaming state by turning on the RT4 gaming state flag (step S421), and ends the RT control process. Let On the other hand, when the main CPU 31 determines that the display combination is not the general gaming state operating combination, the main CPU 31 ends the RT control process.

  When the main CPU 31 ends the RT control process, the main CPU 31 proceeds to the process of step S1 of the reset interrupt process (see FIG. 97).

  Next, with reference to FIG. 116, an interrupt process controlled by the main CPU will be described. Note that FIG. 116 is a diagram illustrating a flowchart of an interrupt process under the control of the main CPU performed by the main control circuit 60 of the present embodiment. Further, the interrupt process under the control of the main CPU is an interrupt process that occurs every predetermined cycle (1.1173 milliseconds in this embodiment).

  First, the main CPU 31 interrupts the program being executed before calling the interrupt process under the control of the main CPU, and saves the address indicating the interrupted position and the values of various registers in a predetermined area of the RAM 33. (Step S431). This is because when the interrupt process under the control of the main CPU is completed, the address indicating the interrupted position of the saved program and the values of various registers are restored, and the program is continuously executed from the point of interruption. It is.

  Next, the main CPU 31 performs input port check processing (step S432). Specifically, the main CPU 31 checks a signal from each switch such as the maximum bet switch 13S.

  Next, the main CPU 31 performs timer update processing (step S433). Specifically, the main CPU 31 subtracts “1” from various timers such as a game time management timer.

  Next, the main CPU 31 performs communication data transmission processing (step S434). Specifically, the main CPU 31 transmits command data stored in the communication data storage area to the sub control circuit 70. That is, since the interrupt process is a process executed every 1.1173 milliseconds, unless the contents of the command data stored in the communication data storage area are updated, the command data having the same contents is 1.1173 milliseconds. It is transmitted to the sub control circuit 70 every second.

  Next, the main CPU 31 performs a reel control process (step S435). Specifically, the main CPU 31 starts rotation of the reels 3L, 3C, and 3R and rotates them at a constant speed when there is a reel rotation start request in the reset interrupt process (see FIG. 97). Take control. Further, when the planned stop position is determined by determining the number of sliding frames in the reel stop control process (see FIG. 105), the main CPU 31 indicates the value of the symbol counter of the corresponding reel indicating the planned stop position. When the value becomes the same as the value, control is performed to stop the reel. For example, when the value indicating the planned stop position is “4”, the main CPU 31 performs control for stopping the corresponding reel when the value of the symbol counter becomes “4”.

  Next, the main CPU 31 performs a lamp drive control process (step S436). Next, the main CPU 31 refers to the value saved in the RAM 33 in the process of step S431 and restores the register (step S437). When this process ends, the interrupt process under the control of the main CPU is ended, and the program interrupted by the occurrence of the interrupt process under the control of the main CPU is continuously executed.

  Next, the operation of the sub control circuit 70 will be described with reference to the flowcharts shown in FIGS. 117 to 127.

  In the processing described below, a multi-thread multi-task operation system is employed as an OS (operation system) that executes processing. That is, a certain task group and another task group execute processing while preemption (interpretation) of the effective right.

  First, with reference to FIG. 117, the power-on process by the sub CPU 71 will be described. FIG. 117 is a diagram showing a flowchart of power-on processing by the sub CPU 71 of this embodiment.

  First, the sub CPU 71 performs an initialization process (step S501). Specifically, error check of the sub RAM 73, initialization of the task system, and the like are performed.

  Next, the sub CPU 71 starts a lamp control task (step S502), starts a sound control task (step S503), and starts a mother task (step S504). The ramp control task and the sound control task are timer interrupt synchronization task groups that perform interrupt processing every time a predetermined time elapses by a timer. The mother task and the drawing task described later are VSYNC interrupt synchronization task groups. It is.

  Next, with reference to FIG. 118, the lamp control task activated in the process of step S502 will be described. FIG. 118 is a diagram illustrating a flowchart of a lamp control task by the sub CPU 71 of the present embodiment.

  First, the sub CPU 71 performs lamp related data initialization processing (step S521).

  Next, the sub CPU 71 waits for an event of 2 ms (step S522). Specifically, the sub CPU 71 executes other tasks until receiving a 2 ms interrupt event message.

  Next, the sub CPU 71 performs a sound control task execution process (step S523). Specifically, a sound control task, which will be described later with reference to FIG. 119, is executed. After the sound control task is executed, the process returns to the lamp control task, and the process proceeds to step S524.

  Next, the sub CPU 71 acquires lamp data from the lamp storage area (step S524). The lamp data is effect data for causing each lamp to light up and blink as an effect.

  Next, the sub CPU 71 performs lamp data analysis processing (step S525), performs lamp lighting control processing for lighting each lamp for production (step S526), and proceeds to processing of step S522.

  Next, with reference to FIG. 119, the sound control task activated in the process of step S503 will be described. FIG. 119 is a diagram showing a flowchart of a sound control task by the sub CPU 71 of this embodiment.

  First, the sub CPU 71 performs a sound related data initialization process (step S531). Specifically, a predetermined initialization process is performed on sound-related data output from the speakers 21L and 21R.

  Next, the sub CPU 71 executes a lamp control task (step S532). Specifically, the lamp control task shown in FIG. 118 is executed, and after the lamp control task is executed, the process returns to the sound control task and the process proceeds to step S533.

  Next, the sub CPU 71 acquires sound data from the sound storage area (step S533). The sound data is effect data for outputting sound from the speakers 21 </ b> L and 21 </ b> R, and the sound data is stored in the sub ROM 72.

  Next, the sub CPU 71 performs sound data analysis processing (step S534), performs sound output control processing for outputting sound from the speakers 21L and 21R (step S535), and proceeds to processing of step S532.

  Next, with reference to FIG. 120, the mother task activated in the process of step S504 will be described. FIG. 120 is a diagram showing a flowchart of the mother task performed by the sub CPU 71 of this embodiment.

  First, the sub CPU 71 activates a drawing task (step S551). The drawing task is a task group for VSYNC interrupt synchronization.

  Next, the sub CPU 71 activates the main board communication task (step S552). The main board communication task is a task group that performs an interrupt process when a command is received from the main control circuit 60.

  Next, the sub CPU 71 performs a drawing task execution process (step S553). Specifically, the sub CPU 71 performs processing such as message queue initialization processing, event message registration, and scene playback initialization processing. A message queue is a mechanism for exchanging information between processes.

  Next, with reference to FIG. 121, the main board communication task activated in the process of step S552 will be described. FIG. 121 is a diagram showing a flowchart of the main board communication task by the sub CPU 71 of this embodiment.

  First, the sub CPU 71 initializes the transmission message queue (step S561).

  Next, the sub CPU 71 receives a command (step S562), and extracts type information from the received command (step S563).

  Next, the sub CPU 71 determines whether or not a command of a type different from the previously received command has been received (step S564). At this time, if the sub CPU 71 determines that a command of the same type as the previously received command has been received, the sub CPU 71 proceeds to the process of step S562. In other words, the sub CPU 71 repeats the processes of steps S562 to S563 until it is determined in the process of step S564 that a command of a type different from the previously received command is received. On the other hand, when the sub CPU 71 determines that a command of a type different from the previously received command is received, the sub CPU 71 creates game information based on the received command (step S565).

  Next, the sub CPU 71 stores the game information created in the process of step S565 in the message queue (step S566), performs a command analysis process described later with reference to FIG. 122 (step S567), and performs the process of step S562. Return to.

  Next, command analysis processing will be described with reference to FIG. Note that FIG. 122 is a diagram showing a flowchart of command analysis processing by the sub CPU 71 of this embodiment.

  First, the sub CPU 71 performs an effect content determination process which will be described later with reference to FIG. 123 (step S571).

  Next, the sub CPU 71 performs lamp data determination processing (step S572) and sound data determination processing (step S573), and ends the command analysis processing.

  Next, with reference to FIG. 123, an effect content determination process by the sub CPU 71 will be described. FIG. 123 is a diagram showing a flowchart of effect content determination processing by the sub CPU 71 of this embodiment.

  First, the sub CPU 71 determines whether or not an initialization command has been received (step S581). At this time, when determining that the initialization command has been received, the sub CPU 71 performs the initialization command reception process (step S582), and ends the effect content determination process. On the other hand, when the sub CPU 71 determines that the initialization command has not been received, the sub CPU 71 proceeds to the process of step S583.

  Next, the sub CPU 71 determines whether or not a medal insertion command has been received (step S583). At this time, when determining that the initialization command has been received, the sub CPU 71 performs a medal insertion command reception process (step S584), and ends the effect content determination process. On the other hand, when determining that the medal insertion command has not been received, the sub CPU 71 proceeds to the process of step S585.

  Next, the sub CPU 71 determines whether or not a start command has been received (step S585). At this time, if the sub CPU 71 determines that a start command has been received, it performs a start command reception process described later with reference to FIG. 124 (step S586), and ends the effect content determination process. On the other hand, when determining that the start command has not been received, the sub CPU 71 proceeds to the process of step S587.

  Next, the sub CPU 71 determines whether or not a reel rotation start command has been received (step S587). At this time, if the sub CPU 71 determines that a reel rotation start command has been received, it performs a reel rotation start command reception process (step S588) and ends the effect content determination process. On the other hand, when determining that the reel rotation start command has not been received, the sub CPU 71 proceeds to the process of step S589.

  Next, the sub CPU 71 determines whether or not a reel stop command has been received (step S589). At this time, when the sub CPU 71 determines that the reel stop command has been received, the reel stop command reception process described later with reference to FIG. 125 is performed (step S590), and the effect content determination process is terminated. On the other hand, when determining that the reel stop command has not been received, the sub CPU 71 proceeds to the process of step S591.

  Next, the sub CPU 71 determines whether or not a display command has been received (step S591). At this time, when determining that the display command has been received, the sub CPU 71 performs a display command reception process described later with reference to FIG. 126 (step S592), and ends the effect content determination process. On the other hand, when determining that the display command has not been received, the sub CPU 71 proceeds to the process of step S593.

  Next, the sub CPU 71 determines whether or not a bonus start command has been received (step S593). At this time, if the sub CPU 71 determines that a bonus start command has been received, the sub CPU 71 performs a bonus start command reception process (step S594), and ends the effect content determination process. On the other hand, when determining that the bonus start command has not been received, the sub CPU 71 then determines whether or not a bonus end command has been received (step S595).

  When the sub CPU 71 determines that a bonus end command has been received in the process of step S595, the sub CPU 71 performs a bonus end command reception process (step S596), and ends the effect content determination process. On the other hand, when determining that the bonus end command has not been received, the sub CPU 71 determines whether or not an input state command has been received (step S597).

  When the sub CPU 71 determines that an input state command has been received in the process of step S597, the sub CPU 71 performs an input state command reception process (step S598), and ends the effect content determination process. On the other hand, when determining that the input state command has not been received, the sub CPU 71 ends the effect content determination process.

  When the sub CPU 71 ends the effect content determination process, the sub CPU 71 proceeds to the process of step S572 of the command analysis process (see FIG. 122).

  Next, with reference to FIG. 124, a process at the time of start command reception by the sub CPU 71 will be described. FIG. 124 is a diagram showing a flowchart of processing at the time of start command reception by the sub CPU 71 of this embodiment.

  First, the sub CPU 71 refers to the navigation display lottery table (see FIGS. 59 to 68) corresponding to the current mode, and determines the navigation display data based on the internal winning combination and the gaming state (step S611).

  Next, the sub CPU 71 determines effect data based on the determined navigation display data and the internal winning combination (step S612), and ends the start command reception process.

  When the sub CPU 71 finishes the start command reception process, the sub CPU 71 proceeds to the process of step S572 of the command reception process (FIG. 122) via the effect content determination process (see FIG. 123).

  Next, with reference to FIG. 125, the reel stop command reception process by the sub CPU 71 will be described. FIG. 125 is a diagram showing a flowchart of the reel stop command reception process by the sub CPU 71 of this embodiment.

  First, the sub CPU 71 determines whether or not it is the first stop time (step S621). At this time, if the sub CPU 71 determines that it is not at the time of the first stop, the sub CPU 71 proceeds to the process of step S624. On the other hand, when the sub CPU 71 determines that the time is the first stop, the sub CPU 71 proceeds to the process of step S622.

  Next, when the sub CPU 71 determines in the processing of step S621 that it is the first stop time, the counter sub gaming state management data (see FIG. 57) based on the current mode and the type of the pressed stop button. Is acquired (step S622).

  Next, the sub CPU 71 refers to the counter update table (see FIGS. 80 to 88) corresponding to the counter sub gaming state management data acquired in the process of step S622, and updates it based on the gaming state and the internal winning combination. Value data (T value, R value, G value, B value) is acquired, and the values of the ceiling counter, extended game counter, digestion counter, and boss battle counter are updated (step S623). Specifically, the value of each counter is added, subtracted or replaced based on the update value data.

  When the sub CPU 71 determines that it is not at the time of the first stop in the process of step S621, or after finishing the process of step S623, the sub CPU 71 determines the effect data based on the determined update value data, the internal winning combination, and the like. (Step S624), the reel stop command reception process is terminated.

  When the sub-CPU 71 ends the reel command reception process, the sub-CPU 71 proceeds to the process of step S572 of the command reception process (FIG. 122) via the effect content determination process (see FIG. 123).

  Next, with reference to FIG. 126, a display command reception process by the sub CPU 71 will be described. FIG. 126 is a diagram showing a flowchart of processing at the time of display command reception by the sub CPU 71 of this embodiment.

  First, the sub CPU 71 acquires mode management data based on the internal winning combination and display combination (the game state of the transfer destination) according to the mode management data list shown in FIG. 58 (step S641).

  Next, the sub CPU 71 determines whether or not the BB1 gaming state or the BB2 gaming state is set (step S642). At this time, when the sub CPU 71 determines that it is not in the BB1 gaming state or the BB2 gaming state, the sub CPU 71 shifts to the processing of step S644. On the other hand, when the sub CPU 71 determines that the game state is the BB1 gaming state or the BB2 gaming state, the sub CPU 71 refers to the mode transition lottery table (see FIG. 79) during the BB and determines the transition destination based on the current mode and mode management data. The mode is determined (step S643), and the process proceeds to step S644.

  Next, the sub CPU 71 determines whether or not the display combination is BB3 (step S644). At this time, when the sub CPU 71 determines that the display combination is not BB3, the sub CPU 71 shifts to the processing of step S646. On the other hand, when the sub CPU 71 determines that the display combination is BB3, the sub CPU 71 refers to the step value update table (see FIGS. 89 and 90) according to the set value according to the set value, and sets the step value based on the current step value. Is updated (step S645), and the process proceeds to step S646. The step value is managed on the sub RAM 73, and the updated step value is stored in the sub RAM 73.

  Next, the sub CPU 71 refers to the sub setting lottery table (FIG. 90, FIG. 91) according to the setting value, acquires update value data based on the current step value, and updates the A value and the Z value. (Step S646). The A value and the Z value are managed on the sub RAM 73, and the updated A value and Z value are stored in the sub RAM 73.

  Next, the sub CPU 71 determines whether or not the display combination is an RT4 operation combination (step S647). At this time, when the sub CPU 71 determines that the display combination is not the RT4 operation combination, the sub CPU 71 proceeds to the process of step S651. On the other hand, when the sub CPU 71 determines that the display combination is the RT4 operation combination, the sub CPU 71 proceeds to the process of step S648.

  When the sub CPU 71 determines that the display combination is the RT4 operation combination in the process of step S647, the sub game state management data for the outgoing ball is based on the current mode according to the relationship between the mode and the management data shown in FIG. Is acquired (step S648), and the process proceeds to step S649.

  Next, the sub CPU 71 refers to the sub-ball release lottery table (see FIGS. 93 and 94) corresponding to the A value stored in the sub-RAM 73, and based on the game state and the sub-game state management data for the game. The update value data is acquired, and the values of the ceiling counter, extended game counter, digestion counter, and boss battle counter are updated (step S649), and the process proceeds to step S650. At this time, if the gaming state managed by the sub-control circuit 70 is a gaming state other than the RT4 gaming state, the “RT4 start” column is referred to, and the gaming state managed by the sub-control circuit 70 is the RT4 gaming state. In this case, the column “RT4 in progress” is referred to.

  Next, the sub CPU 71 refers to the sub appearance ball drawing table (see FIGS. 95 and 96) corresponding to the Z value stored in the sub RAM 73, and based on the game state and the sub game state management data for the appearance. The update value data is acquired, and the values of the ceiling counter, extended game counter, digestion counter, and boss battle counter are updated (step S650), and the process proceeds to step S651.

  When the sub CPU 71 determines in the process of step S647 that the display combination is not an RT4 operating combination, or after the process of step S650 is completed, the sub CPU 71 refers to the mode transition lottery table corresponding to the current mode, and Based on the mode management data, the transfer destination mode is determined (step S651), and the process proceeds to step S652.

  Next, the sub CPU 71 performs special mode rewriting processing to be described later with reference to FIG. 127 (step S652). Next, the presentation data is determined based on the display combination or the like (step S653), and the display command reception processing is terminated. Let

  When the sub-CPU 71 ends the display command reception process, the sub-CPU 71 proceeds to the process in step S572 of the command reception process (FIG. 122) via the effect content determination process (see FIG. 123).

  Next, the special mode rewriting process by the sub CPU 71 will be described with reference to FIG. FIG. 127 is a diagram showing a flowchart of special mode rewriting processing by the sub CPU 71 of this embodiment.

  First, the sub CPU 71 determines whether or not the value of the ceiling counter is “1600” or more (step S671). At this time, when the sub CPU 71 determines that the value of the ceiling counter is not equal to or greater than “1600”, the sub CPU 71 proceeds to the process of step S673. On the other hand, when determining that the value of the ceiling counter is “1600” or more, the sub CPU 71 rewrites the modes “1” to “8” and “26” to the mode “10” (step S672). As a result of this processing, when the value of the ceiling counter is “1600” or more and the current mode is any one of “1” to “8”, “26”, the rewritten mode “10”. The transition to will be made. Note that when the mode before rewriting (current mode) is a mode other than the above, the mode is not rewritten.

  When the sub CPU 71 determines in the process of step S671 that the value of the ceiling counter is not equal to or greater than “1600”, or after the process of step S672 is completed, the sub CPU 71 determines whether or not the value of the extended counter is “0”. Is determined (step S673). At this time, if the sub CPU 71 determines that the value of the extended game counter is not “0”, the process proceeds to step S675. On the other hand, when the sub CPU 71 determines that the value of the extended game counter is “0”, the modes “13” to “16” and “31” to “34” are changed to modes “17”, “18”, “20”. ”,“ 21 ”,“ 35 ”,“ 36 ”,“ 38 ”, and“ 39 ”, respectively (step S674). As a result of this processing, if the value of the extended game counter is “0” and the current mode is any one of “13” to “16” and “31” to “34”, the mode after rewriting The transition to will be made. When the mode before rewriting is a mode other than the above, the mode is not rewritten.

  When the sub CPU 71 determines in the process of step S673 that the value of the extended game counter is not “0”, or after the process of step S674 is ended, whether or not the value of the digest counter is “0”. Is determined (step S675). At this time, when the sub CPU 71 determines that the value of the digest counter is not “0”, the process proceeds to step S677. On the other hand, when the sub CPU 71 determines that the value of the digest counter is “0”, the mode “17” to “21” is changed to the modes “23”, “25”, “9”, “11”, “12”. (Step S676). If the digest counter value is “0” and the current mode is any one of “17” to “21”, the process shifts to the rewritten mode. When the mode before rewriting is a mode other than the above, the mode is not rewritten.

  When the sub CPU 71 determines in the process of step S675 that the value of the digest counter is not “0”, or after the process of step S676 is completed, the sub CPU 71 determines whether or not the value of the boss battle counter is “0”. Is determined (step S677). At this time, if the sub CPU 71 determines that the value of the boss battle counter is not “0”, the sub CPU 71 proceeds to the process of step S679. On the other hand, when determining that the value of the boss battle counter is “0”, the sub CPU 71 rewrites the modes “22” to “25” to the mode “26” (step S678). With this process, when the value of the boss battle counter is “0” and the current mode is any one of “22” to “25”, the mode is changed to “26” after rewriting. When the mode before rewriting is a mode other than the above, the mode is not rewritten.

  When the sub CPU 71 determines in the process of step S677 that the value of the boss battle counter is not “0” or after the process of step S678 is completed, is the internal winning combination BB1 to BB4? It is determined whether or not (step S679). At this time, when the sub CPU 71 determines that the internal winning combination is not any of BB1 to BB4, the special mode rewriting process is ended. On the other hand, when determining that the internal winning combination is any one of BB1 to BB4, the sub CPU 71 rewrites the modes “13” and “14” to the modes “15” and “16”, respectively (step S680), The mode rewriting process is terminated. If the internal winning combination is any one of BB1 to BB4 and the current mode is “13” or “14”, the process shifts to the rewritten modes “15” and “16”, respectively. . When the mode before rewriting is a mode other than the above, the mode is not rewritten.

  In the gaming machine 1 described above, the main CPU 31 operates the RT2 gaming state based on the establishment of the RT2 operating combination in the RT1 gaming state, and the RT4 operating combination is established in the RT1 gaming state or the RT2 gaming state. Based on this, the RT4 actuator is activated. Further, the main CPU 31 activates the RT1 gaming state based on the establishment of the RT1 operating combination in the RT2 gaming state or the RT4 gaming state. Further, when “11” is determined as the small role / replay data pointer, the main CPU 31 performs the first stop operation on the right reel 3R, the second stop operation on the left reel 3L, and the third stop operation on the middle reel 3C. Is detected, the RT4 operating combination is stopped and displayed on the active line, and the first stop operation for the left reel 3L, the second stop operation for the middle reel 3C, and the third stop operation for the right reel 3R are detected. In the case of the failure, the RT2 operating combination is stopped and displayed on the active line. Further, when “22” is determined as the small role / replay data pointer, the main CPU 31 stops and displays the RT1 operating role on the active line based on the detection of the first stop operation on the left reel. . In addition, when the gaming state managed by the sub-control circuit 70 is the RT4 gaming state, the sub CPU 71 updates the value of the digest counter based on the establishment of the RT4 operating combination. Further, the sub CPU 71 refers to a mode transition lottery table to be described later, and determines a transition destination mode based on the current mode and the internal winning combination. In addition, when the gaming state is the RT2 gaming state or the RT4 gaming state and the value of the digestion counter is “1” or more, the sub CPU 71 determines the navigation information for not establishing the RT1 actuating role (the push order for each reel). Information). Further, in the RT4 gaming state, when the mode when the RT4 winning combination is determined as the internal winning combination is “13”, the sub CPU 71 determines navigation information for establishing the RT4 operating combination (for each reel). Press order information). In addition, when the sub CPU 71 notifies the navigation information for not establishing the RT1 actuator when the RT2 gaming state and the mode is “9”, the gaming state managed by the main control circuit 60 is the same. When transitioning to the RT1 gaming state, the mode is shifted to mode “27”. In addition, when the sub CPU 71 notifies the navigation information for not establishing the RT1 actuator when the RT4 gaming state and the mode is “13”, the gaming state managed by the main control circuit 60 is the same. When transitioning to the RT1 gaming state, the mode is shifted to mode “31”. Further, in the RT1 gaming state, when the mode when “10” is determined as the small role / replay data pointer is “27”, the sub CPU 71 displays navigation information for establishing the RT2 operating role. Inform. Further, in the RT1 gaming state, when the mode when the RT4 winning combination is determined as the internal winning combination is “31”, the sub CPU 71 notifies the navigation information for establishing the RT4 operating combination.

  Therefore, according to the gaming machine 1, the RT1 actuating role is established by performing a stop operation different from the navigation information, and the RT1 gaming state which is a disadvantageous gaming state from the RT2 gaming state which is an advantageous gaming state or the RT4 gaming state. Even if the game has shifted to the game state, it is possible to re-transfer to the gaming state before shifting to an unfavorable gaming state by notifying the push order in a dedicated mode (modes “27”, “31”, etc.) Can do. Thereby, even if it is a case where it transfers to an unfavorable game state by performing stop operation different from navigation information, the interest with respect to a game does not fall. In addition, since the RT1 actuator can prevent the establishment by performing a stop operation according to the navigation information, even a player who is not good at performing a stop operation at a specific timing may refrain from playing the game. And there will be no decrease in the operation of the gaming machine.

  In the present embodiment, in the RT2 gaming state, when the mode when the RT4 winning combination is determined as the internal winning combination is a predetermined mode (for example, modes “9” to “12”), RT4 The navigation information for establishing the operating combination is notified, but instead, in the RT2 gaming state, when the RT4 winning combination is determined as the internal winning combination, the RT4 operating combination is set regardless of the mode. It is good also as alerting | reporting the navigation information for establishing.

  Also, in this embodiment, the RT4 operating role is an operating role that activates the RT4 gaming state and a role that updates the value of the digestion counter by being established in the RT4 gaming state, but instead of this, the RT gaming state It is also possible to make the combination that activates the different from the combination that updates the value of the digestion counter by being established in the RT4 gaming state.

  Further, in this embodiment, the pachislot gaming machine is exemplified, but the present invention is not limited to this, and the present invention can be applied to other gaming machines.

  In addition, a game can be executed by applying the present invention to a game program in which the operation on the gaming machine 1 is executed in a pseudo manner for a home game machine. Also in this case, the same effect as the gaming machine 1 described above can be obtained.

DESCRIPTION OF SYMBOLS 1 ... Game machine 3L, 3C, 3R ... Reel 4L, 4C, 4R ... Symbol display area 5 ... Liquid crystal display device 21L, 21R ... Speaker 100, 102 ... LED
60 ... Main control circuit 31 ... Main CPU
32 ... ROM
33 ... RAM
70 ... Sub control circuit 71 ... Sub CPU
72 ... Sub ROM
73 ... Sub RAM

Claims (1)

A plurality of reels each having a plurality of symbols arranged on the circumferential surface;
A display window for displaying a part of a plurality of symbols arranged on the peripheral surfaces of the plurality of reels;
At least one effective line formed by connecting unit symbol display areas for displaying one symbol of each reel in the display window;
Reel rotating means for changing the symbol displayed on the display window by rotating the reel based on the establishment of a predetermined start condition;
A winning combination determining means for determining one or more internal winning combinations from a plurality of combinations with a predetermined probability based on the establishment of the predetermined start condition;
A stop operation detecting means provided corresponding to each of the reels for detecting a stop operation for stopping fluctuation of the reel;
When the stop operation is detected, a configuration symbol that forms a combination of symbols related to the internal winning combination is based on the effective line, and from when the stop operation is detected to when the rotation of the reel is stopped. A stop control means for stopping the rotation of the reel so that the configuration symbol stops along the effective line when the drawing is within the number of drawing allowable symbols permitted in advance to the effective line;
Display combination determination that determines whether an internal winning combination is established or not, depending on whether a combination of symbols related to an internal winning combination is displayed along the effective line when the variation of the symbol is stopped by the stop control means Means,
A re-gamer who is permitted to start a game regardless of game value input by determining that the display combination determination unit has been established is determined with a relatively high probability as the internal winning combination. A high-probability re-gaming state control means for starting or ending the high-probability re-gaming state and the second high-probability re-gaming state when a predetermined condition is satisfied;
Compared with the first high probability replay state and the second high probability replay state, a low probability replay state in which the replay combination is determined with a relatively low probability as the internal winning combination is predetermined. Low probability replay state control means for starting or ending on the basis that the condition of is satisfied,
In the second high-probability re-playing state, a navigation point providing unit that provides a navigation point by determining that a special combination has been established by the display combination determining unit;
Mode determining means for determining one mode from a plurality of modes;
First special mode changing means for changing the first mode to the first special mode when the mode determined by the mode determining means is the first mode;
Second special mode changing means for changing the second mode to the second special mode when the mode determined by the mode determining means is the second mode;
Navigation information notification means for notifying navigation information;
With
The low-probability re-gaming state control means starts the low-probability re-gaming state based on the determination that a falling combination has been established in the first high-probability re-gaming state or the second high-probability re-gaming state. ,
The high-probability re-gaming state control means starts the first high-probability re-gaming state based on the determination that the first combination is established in the low-probability re-gaming state, and , Starting the second high-probability re-gaming state based on the second combination being established in the first high-probability re-gaming state,
The stop control means includes
When the special winning combination is determined as an internal winning combination by the winning combination determining means, the combination of symbols related to the special combination is added to the effective line according to the stop operation order detected by the respective stop operation detecting means. Do not stop display along, or stop display,
In addition, when the winning combination is determined as an internal winning combination by the winning combination determining means, the combination of symbols related to the falling combination is determined in accordance with the stop operation order detected by each stop operation detecting unit. Do not stop display along the line, or stop display,
Further, when the first winning combination is determined as an internal winning combination by the winning combination determining means, the combination of symbols related to the first combination is determined according to the stop operation order detected by each of the stop operation detecting means. Do not stop display along the active line, or stop display,
In addition, when the second winning combination is determined as an internal winning combination by the winning combination determining means, a combination of symbols related to the second combination is determined according to the stop operation order detected by each of the stop operation detecting means. Do not stop display along the active line, or stop display,
Even though the first special mode changing means is informed of a stop operation order for not causing the fall information to be stopped and displayed along the effective line from the navigation information notifying means in the first high probability replaying state. Change to the first special mode based on the detection of the stop operation order for the stop operation detection means to stop and display the falling combination along the active line,
Even though the second special mode changing means is informed of a stop operation order for not causing the fall information to be stopped and displayed along the effective line from the navigation information notifying means in the second high probability replaying state. Change to the second special mode based on the detection of the stop operation order for the stop operation detection means to stop and display the falling combination along the active line,
The navigation information notifying means is configured such that the navigation points given by the navigation point giving means are greater than or equal to a predetermined value, and the winning combination determining means in the first high probability replaying state or the second high probability replaying state When the falling combination is determined as an internal winning combination, a stop operation order for not to stop and display the falling combination along the active line is notified,
Further, when the mode determined by the mode determining means is a specific mode, when the special winning combination is determined as an internal winning combination by the winning combination determining means in the second high probability replaying state, the special winning combination is determined. Informing the stop operation order to stop and display the role along the active line,
Further, when the mode change means is changed to the first special mode and the first winning combination is determined as an internal winning combination by the winning combination determining means in the low probability replaying state, Announce the stop operation order to stop and display one role along the active line,
In addition, when the mode is changed to the second special mode by the mode changing means, and the second winning combination is determined as the internal winning combination by the winning combination determining means in the low probability replaying state, A gaming machine characterized by notifying a stop operation sequence for stopping and displaying two roles along an active line.

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