JP7060001B2 - Pachinko machine - Google Patents

Description

The present invention relates to a gaming machine.

Conventionally, a gaming machine is configured to control the gaming machine by a main control means and a sub control means. For example, while the main control of the game is performed by the main control means, the display control of the effect image in the image display means such as the liquid crystal display device provided in the game machine is performed by the sub control means .

In recent years, there has been a tendency for a wide variety of production images to be displayed on the image display means in order to further improve the interest of the game .

Japanese Unexamined Patent Publication No. 2006-223598

However, the conventional gaming machine has a problem that the processing may become complicated and enormous due to the diversification of the effect images.

The present invention has been made to solve the above-exemplified problems and the like, and provides a gaming machine capable of easily diversifying display modes such as effect images displayed on an image display means. The purpose is to do.

In order to achieve this object, the gaming machine according to claim 1 is transmitted from a main control means that performs main control of the game, a main display means whose display is controlled by the main control means, and the main control means. It is provided with a sub-control means that operates based on a command and an image display means that displays an image based on the control by the sub-control means, and the sub-control means causes the image display means to display 1 For an image drawing means for drawing an image for a screen, a first image storage means for storing a plurality of image information used for drawing an image by the image drawing means, and a predetermined command received from the main control means. A first display specifying means for specifying a predetermined display mode for dynamically displaying identification information on the image display means from a plurality of display modes, and drawing information indicating information necessary for drawing each display mode are provided for each screen. A first specified information storage means for storing the specified first specified information, a first specific means for specifying the first specified information corresponding to the predetermined display mode specified by the first display specifying means, and a predetermined time. One screen worth of the image drawing means based on the update means updated every time and the drawing information for one screen corresponding to the updated update means each time the update means is updated. The image drawing means includes a drawing instruction information generating means for generating drawing instruction information for instructing drawing of an image, and a measuring means capable of measuring time, and the image drawing means is the drawing generated by the drawing instruction information generating means. An image for one screen is drawn using image information based on the instruction information, and the display mode for dynamically displaying the identification information on the image display means starts the dynamic display for each display mode. When the required time elapses from the start of the display in the predetermined display mode specified by the first display specifying means, the sub-control means has a predetermined time required from the start to the end. If the command transmitted from the main control means is the predetermined command, the predetermined command is provided with the second specific means for specifying the first specified information used for the dynamic continuous display of the identification information to be continuously displayed. Is received, the sub-control means executes the dynamic display of the identification information of the time corresponding to the predetermined command in the predetermined display mode specified by the first display specifying means , and the time corresponding to the predetermined command. Is present in plurality, and even if the predetermined display mode specified by the first display specifying means is a display mode having a different required time, it is continuously displayed when the required time has elapsed. The display mode of the dynamic continuous display of the identification information is the same display mode, and the sub-control means receives a predetermined command from the main control means during the dynamic continuous display period of the identification information. Dynamic continuous display of identification information Based on the predetermined display mode specified by the first display identification means for the predetermined command received without performing the definite display of the dynamic display of the identification information that was executed before. A dynamic display control means for initiating dynamic display of identification information by the image display means is provided, and the main control means is predetermined to the main display means for a time corresponding to the predetermined command transmitted to the sub control means. The main display control means is provided for controlling the main display means to be fixedly displayed regardless of the execution of the dynamic continuous display of the identification information in the image display means when the switching display of the above is executed and the time has elapsed.

According to the gaming machine of the present invention, a main control means that performs main control of a game, a main display means whose display is controlled by the main control means, and a sub that operates based on a command transmitted from the main control means. It includes a control means and an image display means for displaying an image based on the control by the sub-control means, and the sub-control means draws an image for one screen to be displayed on the image display means. The image display means has identification information for an image drawing means, a first image storage means for storing a plurality of image information used for drawing an image by the image drawing means, and a predetermined command received from the main control means. A first display specifying means for specifying a predetermined display mode to dynamically display a predetermined display mode from a plurality of display modes, and a first specified information for defining drawing information indicating information necessary for drawing each display mode for each screen. The first specified information storage means to be stored, the first specific means to specify the first specified information corresponding to the predetermined display mode specified by the first display specifying means, and the update updated every predetermined time elapse. Every time the means and the updating means are updated, the image drawing means is instructed to draw an image for one screen based on the drawing information for one screen corresponding to the updated means for updating. The image drawing means includes a drawing instruction information generating means for generating drawing instruction information and a measuring means capable of measuring time, and the image drawing means has image information based on the drawing instruction information generated by the drawing instruction information generating means. Is used to draw an image for one screen, and the display mode for dynamically displaying the identification information on the image display means is from the start to the end of the dynamic display for each display mode. The required time is predetermined, and the sub-control means continues to display the identification information when the required time has elapsed since the display was started in the predetermined display mode specified by the first display specifying means. When the command transmitted from the main control means is the predetermined command, the sub-control means that has received the predetermined command is provided with the second specific means for specifying the first specified information used for the dynamic continuous display of the above. , The dynamic display of the identification information of the time corresponding to the predetermined command is executed in the predetermined display mode specified by the first display specifying means , and there are a plurality of times corresponding to the predetermined command. 1 Even if the predetermined display mode specified by the display specifying means is a display mode having a different required time, the dynamic continuous display of the identification information is continuously displayed when the required time has elapsed. The display mode is the same, and when the sub-control means receives a predetermined command from the main control means during the dynamic continuous display period of the identification information, the sub-control means is before the dynamic continuous display of the identification information. The dynamic display of the identification information based on the predetermined display mode specified by the first display specifying means for the received predetermined command without performing the definite display of the dynamic display of the identification information executed in the above. The main control means includes a dynamic display control means started by the image display means, and the main control means causes the main display means to execute a predetermined switching display for a time corresponding to the predetermined command transmitted to the sub control means. When the time elapses, the main display control means for controlling the main display means to be fixedly displayed regardless of the execution of the dynamic continuous display of the identification information in the image display means is provided, so that the display displayed on the image display means is provided. There is an effect that a wide variety of aspects can be easily achieved.

It is a perspective view of the slot machine in the state which the front door is closed in 1st Embodiment. It is a perspective view of the slot machine with the front door open. It is a rear view of the front door. It is a front view of a housing. It is an arrangement diagram which shows the symbol arrangement of each reel. It is explanatory drawing which shows the relationship between the design which becomes visible from a display window, and a combination line. It is explanatory drawing which shows the relationship between the winning mode, the stop symbol corresponding to the winning mode, the winning probability, and the number of medals paid out. It is a block diagram which shows the electric structure of a slot machine. (A) is a schematic diagram schematically showing an example of a three-sheet hanging lottery table, (b) is a schematic diagram schematically showing an example of a two-sheet hanging lottery table, and (c) is a schematic diagram showing one example. It is a schematic diagram which shows an example of the lottery table at the time of hanging. It is a block diagram which shows the electric structure of a display control device. It is a schematic diagram which shows typically the scanning area of the screen which the auxiliary display part has, and the display area which an image is actually displayed on the screen. It is a schematic diagram which shows an example of the display data table schematically. It is a schematic diagram which shows an example of the transfer data table schematically. It is a schematic diagram which shows an example of a drawing list schematically. It is a flowchart which shows the timer interrupt processing executed by the MPU of a main control unit. It is a flowchart which shows the normal process which is executed by MPU of a main control unit. It is a flowchart which shows the lottery process which is executed by MPU of a main control unit. It is a flowchart which shows the lottery table setting process which is executed by MPU of a main control unit. It is a flowchart which shows the reel control processing which is executed by MPU of a main control device. It is a flowchart which shows the bonus state processing which is executed by MPU of a main control unit. It is a flowchart which shows the display main processing executed by the MPU of a display control device. It is a flowchart which shows the boot process which is executed by MPU of a display control device. (A) is a flowchart showing a command interrupt process executed by the MPU of the display control device, and (b) is a flowchart showing a V interrupt process executed by the MPU of the display control device. It is a flowchart which shows the command determination process which is executed by MPU of a display control apparatus. (A) is a flowchart showing a state command process executed by the MPU of the display control device, and (b) is a flowchart showing a start command process executed by the MPU of the display control device. It is a flowchart which shows the lottery result command processing executed by MPU of a display control apparatus. (A) is a flowchart showing a payout determination result command process executed by the MPU of the display control device, and (b) is a flowchart showing an error command process executed by the MPU of the display control device. It is a flowchart which shows the display setting process which is executed by MPU of a display control device. (A) is a flowchart showing a transfer setting process executed by the MPU of the display control device, and (b) is a flowchart showing a resident image transfer setting process executed by the MPU of the display control device. It is a flowchart which shows the normal image transfer setting process which is executed by MPU of a display control apparatus. It is a flowchart which shows the drawing process which is executed by MPU of a display control apparatus. It is a block diagram which shows the electric structure of the display control device in 2nd Embodiment. It is a schematic diagram which shows an example of the synthetic data table schematically. It is a flowchart which shows the lottery result command processing executed by MPU of a display control apparatus. It is a flowchart which shows the payout determination result command processing executed by MPU of a display control apparatus. It is a flowchart which shows the display setting process which is executed by MPU of a display control device. It is a flowchart which shows the normal image transfer setting process which is executed by MPU of a display control apparatus. It is a block diagram which shows the electric structure of the display control device in 3rd Embodiment. It is a schematic diagram which shows an example of the display data table schematically. It is a flowchart which shows the lottery result command processing executed by MPU of a display control apparatus. It is a flowchart which shows the payout determination result command processing executed by MPU of a display control apparatus. It is a flowchart which shows the display setting process which is executed by MPU of a display control device. It is a flowchart which shows the normal image transfer setting process which is executed by MPU of a display control apparatus. It is a block diagram which shows the electric structure of the display control device in 4th Embodiment. It is a block diagram which shows the electric structure of the display control device in 5th Embodiment. It is a block diagram which shows the electric structure of the display control device in 6th Embodiment. It is a front view of the pachinko machine in the 7th embodiment. It is a front view of the game board of a pachinko machine. It is a rear view of a pachinko machine. (A) is a diagram schematically showing the area division setting and the effective line setting of the display screen, and (b) is a diagram illustrating an actual display screen. It is a block diagram which shows the electric structure of a pachinko machine. It is a figure which shows the outline of various counters. It is a block diagram which shows the electric structure of a display control device. (A) to (c) are explanatory views explaining the image at the time of power-on. (A) is an explanatory diagram for explaining the back surface A, and (b) is an explanatory diagram for explaining the back surface B. (A) to (c) are explanatory views explaining the back surface C. It is a schematic diagram which shows an example of the display data table for variation schematically. It is a schematic diagram which shows an example of an additional data table schematically. It is a schematic diagram which shows an example of the transfer data table schematically. It is a schematic diagram which shows an example of a drawing list schematically. It is a flowchart which shows the timer interrupt process executed by the MPU in the main control unit. It is a flowchart which shows the fluctuation processing executed by the MPU in the main control unit. It is a flowchart which showed the fluctuation start processing executed by the MPU in the main control unit. It is a flowchart which shows the start winning process executed by the MPU in the main control unit. It is a flowchart which shows the NMI interrupt process executed by MPU in the main control unit. It is a flowchart which shows the start-up process which is executed by MPU in the main control unit. It is a flowchart which shows the main process executed by MPU in a main control unit. It is a flowchart which showed the start-up process which is executed by MPU in the voice lamp control device. It is a flowchart which showed the main process executed by MPU in a voice lamp control device. It is a flowchart which showed the vibration sensor input monitoring process executed by MPU in a voice lamp control device. It is a flowchart which showed the command determination process executed by the MPU in the voice lamp control device. It is a flowchart which showed the variation display process which is executed by MPU in a voice lamp control device. It is a flowchart which showed the main process executed by MPU in a display control device. (A) is a flowchart showing the command interrupt process executed by the MPU in the display control device, and (b) is a flowchart showing the V interrupt process executed by the MPU in the display control device. be. It is a flowchart which showed the command determination process executed by the MPU in the display control device. (A) is a flowchart showing the reserved ball number command process executed by the MPU in the display control device, and (b) is a flowchart showing the confirmed command process executed by the MPU in the display control device. Yes, (c) is a flowchart showing the demo command processing executed by the MPU in the display control device. (A) is a flowchart showing the variation pattern command processing executed by the MPU in the display control device, and (b) is a flowchart showing the stop type command processing executed by the MPU in the display control device. be. (A) is a flowchart showing the continuous advance notice command processing executed by the MPU in the display control device, and (b) is a flowchart showing the rear image change command processing executed by the MPU in the display control device. Is. (A) is a flowchart showing the frame button operation command processing executed by the MPU in the display control device, and (b) is a flowchart showing the error command processing executed by the MPU in the display control device. be. It is a flowchart which showed the display setting process executed by the MPU in the display control device. It is a flowchart which showed the display setting process executed by the MPU in the display control device. (A) is a flowchart showing the hold image setting process executed by the MPU in the display control device, and (b) is a flowchart showing the warning image setting process executed by the MPU in the display control device. Yes, (c) is a flowchart showing a frame button operation process executed by the MPU in the display control device. It is a flowchart which showed the comparison process which is executed by the MPU in the display control device. It is a flowchart which showed the pointer update process executed by the MPU in the display control device. (A) is a flowchart showing the transfer setting process executed by the MPU in the display control device, and (b) is a flowchart showing the resident image transfer setting process executed by the MPU in the display control device. be. It is a flowchart which showed the normal image transfer setting process executed by MPU in a display control apparatus. It is a flowchart which showed the drawing process which is executed by MPU in the display control device. It is a block diagram which shows the electric structure of the display control device in 8th Embodiment. It is a schematic diagram which shows an example of the synthetic data table schematically. It is a flowchart which showed the demo command processing executed by the MPU in the display control device. It is a flowchart which showed the variation pattern command processing executed by MPU in a display control device. It is a flowchart which showed the continuous notice command processing executed by the MPU in the display control device. It is a flowchart which showed the display setting process executed by the MPU in the display control device. It is a flowchart which showed the display setting process executed by the MPU in the display control device. It is a flowchart which showed the comparison process which is executed by the MPU in the display control device. It is a flowchart which showed the normal image transfer setting process executed by MPU in a display control apparatus. It is a block diagram which shows the electric structure of the display control device in 9th Embodiment. It is a schematic diagram which shows an example of the display data table schematically. It is a flowchart which showed the demo command processing executed by the MPU in the display control device. It is a flowchart which showed the variation pattern command processing executed by MPU in a display control device. It is a flowchart which showed the continuous notice command processing executed by the MPU in the display control device. It is a flowchart which showed the display setting process executed by the MPU in the display control device. It is a flowchart which showed the display setting process executed by the MPU in the display control device. It is a flowchart which showed the comparison process which is executed by the MPU in the display control device. It is a flowchart which showed the normal image transfer setting process executed by MPU in a display control apparatus. It is a block diagram which shows the electric structure of the display control device in 10th Embodiment. It is a block diagram which shows the electric structure of the display control device in eleventh embodiment. It is a block diagram which shows the electric structure of the display control device in 12th Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. First, with reference to FIGS. 1 to 31, as a first embodiment, a rotating cylinder type gaming machine, which is a kind of gaming machine, specifically, an embodiment when applied to a slot machine 10 will be described. 1 is a perspective view of the slot machine 10 with the front door 12 closed, FIG. 2 is a perspective view of the slot machine 10 with the front door 12 open, FIG. 3 is a rear view of the front door 12, and FIG. 4 is a casing. It is a front view of the body 11.

In the slot machine 10, the player inserts a medal, which is a game medium, from the medal insertion slot 45, and the start lever 41 is operated to rotate and drive three reels 32L, 32M, 32R having a plurality of symbols. When the player operates the stop switches 42, 43, 44 provided corresponding to the reels 32L, 32M, 32R, the corresponding reels 32L, 32M, 32R are stopped, and the reels 32L, 32M, 32R are stopped. When the combination of symbols displayed by stopping is a predetermined combination, the player is given a privilege of awarding a predetermined number of medals and a privilege of shifting to a gaming state.

As shown in FIGS. 1 to 4, the slot machine 10 includes a housing 11 that forms an outer shell thereof. The housing 11 is formed in a box shape with an open front as a whole by combining wooden panels, and is attached by nailing a so-called island facility at the time of installation in a game hall. In addition to being made of wooden panels, the housing 11 may be made of synthetic resin panels or metal panels, or may be made of synthetic resin materials or metal materials to form an integral box. May be good.

A front door 12 is attached to the front side of the housing 11 so as to be openable and closable. That is, the housing 11 is provided with a pair of upper and lower support shafts 13a and 13b on the left side portion when viewed from the front thereof, and the front door 12 is provided with bearing portions 14a at positions corresponding to the respective support shafts 13a and 13b. , 14b are provided. When the support shafts 13a and 13b are inserted into the bearing portions 14a and 14b, the front door 12 rotates around the opening / closing axis extending in the vertical direction connecting the support shafts 13a and 13b to the housing 11. It is movably supported, and the front open side of the housing 11 can be opened and closed by the rotation of the front door 12.

Further, on the opposite side of the opening / closing shaft of the front door 12, a locking device 20 is provided on the back surface thereof, and the front door 12 is in a locked state that cannot be opened by the locking device 20. A key cylinder 21 integrated with the locking device 20 is provided on the upper right end side of the front door 12, and is configured to release the locked state by a predetermined key operation on the key cylinder 21. The position where the key cylinder 20 is provided is a thin upper position in the front door 12, and as a result, a versatile key cylinder 21 having a short overall length can be adopted. In the present embodiment, the key cylinder 21 is an OMLock (registered trademark) having a high unauthorized unlocking prevention function.

A game panel 25 for notifying the player of the game state is provided near the center of the front door 12. Three vertically long display windows 26L, 26M, 26R are formed side by side on the game panel 25, and the inside of the slot machine 10 can be visually recognized through the respective display windows 26L, 26M, 26R. The display windows 26L, 26M, and 26R may be combined into one to form a common display window.

As shown in FIG. 2, the inside of the housing 11 is divided into upper and lower parts by a partition plate 30, and a reel unit 31 constituting a variable display means is attached to the upper part of the partition plate 30. The reel unit 31 includes a left reel 32L, a middle reel 32M, and a right reel 32R, which are formed in a cylindrical shape (annular shape), respectively. Each reel 32L, 32M, 32R is rotatably supported so that its central axis is the rotation axis of the reel. The rotation axes of the reels 32L, 32M, 32R are arranged on the same axis extending in a substantially horizontal direction, and the reels 32L, 32M, 32R correspond one-to-one with the display windows 26L, 26M, 26R. .. Therefore, a part of the surface of each reel 32L, 32M, 32R is visible through the corresponding display windows 26L, 26M, 26R, respectively. Further, when the reels 32L, 32M, 32R rotate in the forward direction, the surfaces of the reels 32L, 32M, 32R are projected as if they are moving from top to bottom through the display windows 26L, 26M, 26R.

Here, the configuration of the reel unit 31 will be briefly described. Each reel 32L, 32M, 32R is connected to a stepping motor, and each reel 32L, 32M, 32R can be rotationally driven individually, that is, independently by driving each stepping motor. .. The stepping motor is set to rotate once by, for example, giving a drive signal of 504 pulses (hereinafter, also referred to as an excitation pulse), and the rotation position of the stepping motor, that is, the rotation position of the reel is set by this excitation pulse. Be controlled. Further, in the reel unit 31, reel index sensors for detecting that the reel has rotated once are installed in each reel 32L, 32M, 32R. Then, when the reel index sensor detects that the reel has rotated once, a detection signal is output to the main control device 101, which will be described later, each time the detection is performed. Therefore, the main control device 101 sets the angular position of each reel 32L, 32M, 32R for each rotation based on the detection signal of the reel index sensor and the number of excitation pulses output until the detection signal is input. It can be confirmed and corrected.

On the outer peripheral surface of each reel 32L, 32M, 32R, a plurality of symbols as identification information are drawn in the long side direction (circumferential direction) thereof. Details will be described later with reference to FIG. 5, but 21 symbols are drawn at equal intervals for each reel 32L, 32M, 32R, of which 3 consecutive symbols are displayed windows 26L, 26M, It is configured to be visible at the upper, middle, and lower positions of the 26R. Therefore, in order to switch a symbol at a predetermined position to the next symbol, it is necessary to output 24 pulses (= 504 pulses ÷ 21 symbols) of excitation pulses. Further, the main control device 101 grasps a symbol that can be visually recognized from the display windows 26L, 26M, and 26R by the number of excitation pulses output after the detection signal of the reel index sensor is input, and the display window. It is possible to perform control such as stopping a predetermined symbol at a position visible from 26L, 26M, 26R.

On the lower left side of the game panel 25, a start lever 41 operated to start the rotation of each reel 32L, 32M, 32R is provided. The start lever 41 is a lever that is manually pushed (the direction in which the player is pushed) when the player starts a game (game), and is operated by the start lever 41 with a predetermined number of medals inserted. Then, the rotations of the reels 32L, 32M, and 32R are started all at once (but not necessarily at the same time).

On the right side of the start lever 41, button-shaped stop switches 42 to 44 that are operated to individually stop the rotating reels 32L, 32M, 32R are provided. The stop switches 42 to 44 are arranged directly below the display windows 26L, 26M, 26R corresponding to the reels 32L, 32M, 32R to be stopped. That is, when the left stop switch 42 is operated, the rotation of the left reel 32L is stopped, and when the middle stop switch 43 is operated, the rotation of the middle reel 32M is stopped and the right stop switch 44 is operated. In that case, the rotation of the right reel 32R is stopped.

At this time, only the stop mode in which the arrival symbol that has reached the base point position (in the present embodiment, the lower position of each of the corresponding display windows 26L, 26M, 26R) is stopped as it is when the stop switches 42 to 44 are operated. Instead, the corresponding reel is slid by one symbol and then stopped, the stop mode is stopped after sliding two symbols, the stop mode is stopped after sliding three symbols, and the four symbols are slid. Five patterns are prepared, one is a stop mode and the other is a stop mode. As a result, the display window is set so that each reel 32L, 32M, 32R stops in a predetermined stop mode from the timing when the stop switches 42 to 44 are operated until the specified time (190 msec) elapses. It is possible to give the player the impression that the symbol arrangement (hereinafter, also referred to as a stop roll) that stops within a visible range from the 26L, 26M, and 26R is determined by the player's operation. In addition, by making it possible to slide up to 4 symbols, a combination of symbols corresponding to the winning mode (see FIG. 7), which will be described later, won the lottery as much as possible within the specified time, will be described later. It is possible to stop on the effective line (see FIG. 6), and it is possible to prevent the combination of symbols corresponding to the winning modes that have not been won in the lottery from stopping on the effective line.

A medal insertion slot 45 for inserting medals is provided on the lower right side of the display windows 26L, 26M, and 26R. The medals inserted from the medal insertion slot 45 are guided to either the storage passage 47 or the discharge passage 48 by the selector 46 as a passage switching means provided on the back surface of the front door 12. More specifically, the selector 46 is provided with a medal passage switching solenoid 46a, and the medal is guided to the discharge passage 48 side when the medal passage switching solenoid 46a is not excited, and the medal is guided to the discharge passage 48 side when the medal passage switching solenoid 46a is excited. Is guided to the storage passage 47 side. The medal guided to the storage passage 47 is guided to the hopper device 51 housed inside the housing 11. On the other hand, the medal guided to the discharge passage 48 is guided to the medal tray 50 from the medal discharge port 49 provided in the lower front portion of the front door 12, and is returned to the player.

The storage passage 47 is provided with an inserted medal detection device (not shown) that detects the passage of inserted medals. The output signal of the inserted medal detection device is input to the main control device 101, and the main control device 101 counts the number of medals based on the detection result of the inserted medal detection device. Further, the movement of the inserted medal (the passing direction of the medal) is determined based on the detection result of the inserted medal detection device, and when the movement of the medal is different from the normal one, the main control device 101 may be jammed with medals or may be jammed. It is configured to notify that a sensor error has occurred from the upper lamp 63, speaker 64, auxiliary display unit 65, etc., which will be described later, by determining that there is a possibility that a medal has been pulled out or other fraudulent activity has been performed. There is.

The inserted medal detection device includes a first inserted medal detection sensor 45a and a second inserted medal detection sensor configured by a photocoupler having a pair of light emitting portions and light receiving portions (not shown) on both sides of the passing medal. It is equipped with 45b (see FIG. 8). The first inserted medal detection sensor 45a and the second inserted medal detection sensor 45b are arranged side by side on the upstream side and the downstream side, respectively, in a state close enough to detect one passing medal at the same time. The detection sensors 45a and 45b are set to output a "Lo" signal when receiving light and a "Hi" signal when blocking light.

When the medal inserted by the player is guided to the storage passage 47 side by the selector 46, the medal passes through the inserted medal detection device. At this time, first, the first inserted medal detection sensor 45a disposed on the upstream side is in a light-shielded state first to output a "Hi" signal, and then the second inserted medal detection sensor disposed on the downstream side. The 45b is in a light-shielded state, a "Hi" signal is output, and medals are detected simultaneously by the two inserted medal detection sensors 45a and 45b. Then, when the medal further advances to the downstream side in the storage passage 47, the first inserted medal detection sensor 45a arranged on the upstream side first enters the light receiving state and outputs the "Lo" signal, and then outputs the "Lo" signal. The second inserted medal detection sensor 45b arranged on the downstream side is in a light receiving state and outputs a "Lo" signal.

That is, when the medal normally passes through the inserted medal detection device, the signals output from the inserted medal detection sensors 45a and 45b are such that the first inserted medal detection sensor 45a first becomes "Hi" and then the second inserted medal. The detection sensor 45b becomes "Hi". Then, after the inserted medal detection sensors 45a and 45b are simultaneously set to "Hi", the first inserted medal detection sensor 45a is set to "Lo", and finally the second inserted medal detection sensor 45b is set to "Lo". The main control device 101 determines that the medals have been normally inserted when the signals output from the inserted medal detection sensors 45a and 45b change at such timing, and counts the number of inserted medals. Up.

On the other hand, if the medal is jammed while passing through the inserted medal sensor device or the medal is illegally pulled out, the signals output from the two inserted medal detection sensors 45a and 45b are the cases where the medal has passed normally. It changes at different timings. The main control device 101 monitors changes in the signals output from the inserted medal detection sensors 45a and 45b, and if the change is different from the change when the medal normally passes through the inserted medal detection device, the medal It is determined that there is a blockage or an error, and the occurrence of a sensor error is notified to the display control device 81 described later by an error command. In the display control device 81, when the occurrence of the sensor error is notified from the main control device 101, the occurrence of the sensor error is notified from the upper lamp 63, the speaker 64, the auxiliary display unit 65, and the like.

The hopper device 51 includes a storage tank 52 for storing medals and a payout device 53 for paying out medals to the player. The payout device 53 discharges the medal to the opening 48a provided in the discharge passage 48 by rotating a rotating plate for paying out medals (not shown), and pays out the medal to the medal tray 50 through the discharge passage 48. It has become. Further, on the right side of the hopper device 51, a spare tank 54 is provided to prevent the storage tank 52 from storing a predetermined amount or more of medals. Inside the storage tank 52 of the hopper device 51, a guide plate 52a for discharging medals from the storage tank 52 to the spare tank 54 is provided. Therefore, when medals are stored above the height at which the guide plate 52a is provided, the medals are stored in the spare tank 54.

A button-shaped return switch 55 is provided below the medal slot 45. When the return switch 55 is operated while the medals inserted in the medal slot 45 are jammed in the selector 46, the selector 46 is mechanically interlocked and the medals packed in the selector 46 are medals. It is designed to be returned from the discharge port 49.

A checkout switch 59 is provided on the left side of the start lever 41. The slot machine 10 has a credit function for storing and storing surplus inserted medals and payout medals at the time of winning as virtual medals until the predetermined maximum value (50 medals) is reached, and the virtual medals are stored and stored. When the settlement switch 59 is operated under the above-mentioned situation, the virtual medal is paid out from the medal ejection port 49 as a real medal.

On the lower left side of the display windows 26L, 26M, 26R, a first credit insertion switch 56 for inserting three credited virtual medals as a game medium at one time is provided. Further, a second credit insertion switch 57 and a third credit insertion switch 58 are provided on the left side of the first credit insertion switch 56. The second credit insertion switch 57 is for inserting two virtual medals at a time, and the third credit insertion switch 58 is for inserting one virtual medal.

Below the display windows 26L, 26M, 26R of the game panel 25, there is a credit display unit 60 that displays the number of virtual medals that are credited, and the number of remaining medals that display the number of medals remaining to be paid out by the end of the bonus state. A display unit 61 and a payout number display unit 62 for displaying the number of medals paid out at the time of winning are provided. These display units 60 to 62 are composed of a 7-segment display, but it is naturally possible to replace them with a liquid crystal display or the like.

At the upper part of the front door 12, there is an upper lamp 63 that lights up and blinks as the game progresses, and a pair of left and right lamps that sound various sound effects as the game progresses and notify the player of the game state. The speaker 64 and an auxiliary display unit 65 for giving various information to the player are provided. The auxiliary display unit 65 is for executing various display effects as the game progresses, and for notifying the state when the power is turned on or an error occurs, and the game is mainly performed by the reels 32L, 32M, 32R. Since it can be considered that it is due to the display unit, it is referred to as an auxiliary display unit 65 in the present embodiment. On the back surface of the auxiliary display unit 65, an upper lamp 63, a speaker 64, and a display control device 81 for driving the auxiliary display unit 65 are provided. The details of the display control device 81 will be described later with reference to FIG.

Above the medal tray 50, a lower plate 66 on which a model name, characters related to the game, and the like are displayed is mounted. Further, on the left side of the medal tray 50, an ashtray 69 that can be inverted is provided on the lower front side.

A power supply box 70 is provided on the left side of the hopper device 51 inside the housing 11. The power supply box 70 houses the power supply device 91 (see FIG. 8), and also includes a power supply switch 71, a reset switch 72, a setting key insertion hole 73, and the like. The power switch 71 is a start switch for supplying power to each part including the main control device 101 described later.

The reset switch 72 is a switch for resetting various states of the slot machine 10. This slot machine 10 has a backup function for various data, maintains the state at the time of power failure even in the unlikely event of a power failure, and returns to the state at the time of power failure when recovering from the power failure (recovery). You can do it. Therefore, if the power is shut off in the normal procedure, for example, when the game hall is closed, the state before the shutoff is stored and retained, but if the power switch 71 is turned on while pressing the reset switch 72, the backup data is reset ( It is supposed to be initialized). If the reset switch 72 is pressed while the power switch 71 is on, the error state is reset.

The setting key insertion hole 73 is for the hole manager or the like to adjust the medal output. That is, the hall manager or the like inserts the setting key into the setting key insertion hole 73 and rotates the slot machine 10 to change the setting state of the slot machine 10 (setting of the winning probability of each winning mode) from "setting 1" to "setting 6". Can be changed up to. Then, when the setting state is set to "setting 1", a lottery is performed so that the expected value of the number of medals to be paid out is the lowest, and when the setting state is set to "setting 6", the winning mode (combination) is drawn. The lottery of the winning mode is configured so that the expected value of the number of medals to be paid out is the highest. The reset switch 72 is operated not only when resetting the error state but also when changing the setting state of the slot machine 10.

Above the reel unit 31, a main control device 101 that comprehensively manages the game is attached to the housing 11. The details will be described later with reference to FIG. 8, but the main control device 101 has an MPU (Micro Processing Unit) 102 that controls the main control, a ROM (Read Only Memory) 105 that stores the game program, and a game progress. RAM (Random Access Memory) 106 that temporarily stores necessary data, free run counter 107 that generates random numbers, port 104 that communicates with various devices, clock used for time counting and synchronization, etc. It includes a main board including a circuit 103 and the like, and the main board is housed in a board box made of a transparent resin material or the like. The board box includes a box base having a substantially rectangular parallelepiped shape and a box cover that covers an opening of the box base. These box bases and box covers are unopenably connected by a sealing unit, thereby sealing the board box. The box base and the box cover may be connected to each other by using a key member so as not to be opened.

Next, with reference to FIG. 5, the symbols drawn on the reels 32L, 32M, 32R will be described. FIG. 5 is an array diagram showing a symbol arrangement of the left reel 32L, the middle reel 32M, and the right reel 32R. As shown in the figure, 21 symbols are arranged in a row on each reel 32L, 32M, 32R. Further, numbers 0 to 20 are assigned to each reel 32L, 32M, 32R, and these numbers are designed so that the main control device 101 can be visually recognized from the display windows 26L, 26M, 26R. It is a number for recognizing, and is not actually attached to the reels 32L, 32M, 32R. However, in the following description, the number will be used.

The symbols include a "7" symbol (for example, the 20th of the left reel 32L), a "youth" symbol (for example, the 19th of the left reel 32L), a "replay" symbol (for example, the 18th of the left reel 32L), and " "Cherry" symbol (eg 17th on the left reel 32L), "Bell" symbol (eg 16th on the left reel 32L), "Watermelon" symbol (eg 15th on the left reel 32L), "Star" symbol (eg 15th on the left reel 32L) , 19th of the middle reel 32L). And, as shown in FIG. 5, the number and arrangement order of various symbols are completely different in each reel 32L, 32M, 32R.

Each display window 26L, 26M, 26R is formed so that out of the 21 symbols attached to the corresponding reels, 3 symbols can be visually recognized as the entire symbol. Therefore, when all the reels 32L, 32M, 32R are stopped, 3 × 3 = 9 symbols can be visually recognized through the display windows 26L, 26M, 26R.

In this slot machine 10, five combination lines are set so as to connect each position where the symbol can be visually recognized. Here, with reference to FIG. 6, the combination line set in the slot machine 10 will be described. FIG. 6 is an explanatory diagram showing the relationship between the symbol visible from each display window 26L, 26M, 26R and the combination line.

As shown in FIG. 6, the upper line L1 connecting the upper symbol of the left reel 32L, the upper symbol of the middle reel 32M, and the upper symbol of the right reel 32R, the middle symbol of the left reel 32L, the middle symbol of the middle reel 32M, and the right. Middle line L2 connecting the middle design of the reel 32R, lower line L2 connecting the lower design of the left reel 32L, lower design of the middle reel 32M, lower line L3 connecting the lower design of the right reel 32R, upper design of the left reel 32L, middle reel A right-down line L4 connecting the middle design of 32M and the lower design of the right reel 32R, and a right-up line L5 connecting the lower design of the left reel 32L, the middle design of the middle reel 32M, and the upper design of the right reel 32R are set. ing. Then, when the symbols are stopped in a predetermined combination on the activated combination line, that is, the valid line, a privilege that a predetermined number of medals are paid out or a privilege that the game state is transferred is given as a winning establishment. It is designed to be granted.

The maximum number of combination lines may be 6 or more, or less than 5. For example, a V (inverted V) -shaped line or an L-shaped line may be used as an effective line. Further, the maximum number of combination lines may be changed according to a predetermined condition. For example, the number of lines may be changed according to the number of inserted medals (number of bets).

Next, with reference to FIG. 7, the winning modes that the slot machine 10 can take, the stop symbols on the effective line that wins in each winning mode, the winning probability of each winning mode in the general gaming state, and each. The number of medals to be paid out when a prize is won in the winning mode will be described. FIG. 7 is an explanatory diagram showing the relationship between the winning mode, the stop symbol, the winning probability in the general game state, and the number of medals to be paid out. In FIG. 7, the winning probability when the setting state of the slot machine 10 is set to "setting 1" will be described as an example, but when the setting state is set to "setting 2" to "setting 6". In addition, the expected value of the number of medals to be paid out per game from "Setting 1" to "Setting 6" while maintaining the magnitude relationship of each winning probability determined by each winning mode and the number of medals inserted (number of bets). Each winning probability is set so that

As shown in FIG. 7, there is a BB (Big Bonus) prize as a state transition prize that gives a player a privilege to shift the game state. If you stop alongside the "7" symbol, "7" symbol, and "7" symbol from the left on the valid line, you will be given the privilege of shifting the gaming state to the bonus state, which is a special gaming state, as a BB prize. However, even if the "7" symbol stops alongside the left, middle, and right on the valid line, the medal will not be paid out. That is, when the combination of "7" symbols is established on the valid line, only the bonus state is entered. In other words, it can be said that the "7" symbol is a state transition symbol for shifting the gaming state to the bonus state.

Here, the bonus state will be described. The bonus state is composed of a plurality of RB (Regular Bonus) states, and the RB state is composed of 12 JAC games. The JAC game is a game in which the probability of winning the watermelon prize and the bell prize, which will be described later, which are small role prizes, is extremely high as compared with the general gaming state. Then, if the winning is established 8 times during the JAC game, the RB state ends even before the JAC game is played 12 times. Further, the bonus state ends when the number of medals paid out reaches a predetermined number (250 in this embodiment). That is, when the BB winning is established, the number of medals paid out at that time is 0, but when the gaming state of the gaming machine is shifted to the bonus state with the BB winning, 250 medals are given to the player. It is guaranteed that the payout will be made with a smaller number of medals inserted than in the general gaming state. In addition, when the number of medals paid out reaches a predetermined number in the middle of the RB state, not only the bonus state but also the RB state ends. This is a device for suppressing the gambling spirit of the player and ensuring the soundness of the game by setting an upper limit on the number of medals to be paid out in the bonus state. Further, in the present embodiment, the combination of the symbols that shift to the RB state is not set, and the configuration shifts to the RB state immediately after the transition to the bonus state and immediately after the end of the RB state. Therefore, it can be said that the bonus state is a game in which the game continuously shifts to the RB state until a predetermined number of medals are paid out.

This slot machine 10 supports 1-card, 2-card, and 3-card medals (number of bets) at the start of the game, and the winning probability of BB winning in a general game state (BB winning in one game). (Probability of being established) is set differently according to the number of medals inserted (number of bets) inserted at the start of the game. Specifically, in the case of 1-card and 2-card, the winning probability of BB winning is set to 1/65536, and in the case of 3-card, it is set to 1/256. As described above, the winning probability of the BB winning in the general game state is set lower in the case of 1-card and 2-card than in the case of 3-card.

Next, there are a watermelon prize and a bell prize as small role prizes in which medals are paid out. If you stop alongside the "watermelon" symbol, "watermelon" symbol, and "watermelon" symbol on the effective line, you will win a watermelon prize, and from the left on the effective line, the "bell" symbol, "bell" symbol, and " If you stop alongside the "bell" symbol, you will win a bell. Then, when the game is executed with three medals, 12 medals are paid out if the watermelon prize is established, and 6 medals are paid out if the bell prize is established. In addition, when the game is executed with one or two medals, if the watermelon prize or the bell prize is established, three medals are paid out. In addition, the winning probability of winning a watermelon in a general game state is set to 1/65536 in the case of 1-card and 2-card, and 1/8 in the case of 3-card. On the other hand, the winning probability of the bell winning in the general game state is set to 1/65536 in the case of 1-card and 2-card, and to about 1 / 5.1 in the case of 3-card. In this way, the watermelon prize and the bell prize are set so that the prizes can be easily established in the case of three pieces, while the prizes are rarely established in the case of one piece and two pieces. It is set not to.

Further, in this slot machine 10, a special small winning combination prize is prepared that is established only when the game is executed with one or two cards, or only when the game is executed with one card. .. Special child actor prizes include cherry bell prizes and 7 bell prizes. Of these, the cherry bell prize is a special small winning combination that is established only when one or two medals are hung, and the "cherry" symbol on the left reel 32L and the "bell" symbol on the middle reel 32M are on the effective line. It is established when it stops at, and three medals are paid out. In addition, the 7-bell prize is a special small winning combination that is established only when one piece is hung, and when the "7" symbol on the left reel 32L and the "bell" symbol on the middle reel 32M stop on the effective line. It is established and two medals are paid out.

Here, for both the cherry bell winning and the 7 bell winning, the symbol that stops on the effective line of the right reel 32R may be any symbol. In addition, when the game is executed with 3 reels, the cherry bell wins even if the "watermelon" symbol or "7" symbol on the left reel 32L and the "bell" symbol on the middle reel 32M stop on the effective line. Or, it is judged as a loss without establishing a 7-bell prize. Similarly, when the game is executed with two reels, even if the "7" symbol on the reel 32L and the "bell" symbol on the middle reel 32M stop on the effective line, the 7-bell prize is not established. , Judged as off. If the game is executed with 3 reels, the "cherry" or "7" symbol on the left reel 32L and the "bell" symbol on the middle reel 32M are not stopped on the effective line at the same time, and the cherry is won. Or 7 bells may be configured so that the prize is not established. Similarly, when the game is executed with two reels, the "7" symbol on the left reel 32L and the "bell" symbol on the middle reel 32M are not stopped on the effective line at the same time, so that the cherry prize is not established. It may be configured in.

The winning probability of the cherry bell winning in the general game state is set to about 1/6.0 in the case of 1-card, and to about 1-1.8 in the case of 2-card. In addition, the winning probability of winning a 7-bell prize in a general game state is set to about 1/6.0 with respect to only one piece.

By the way, in the conventional slot machine, when the game is executed with one or two cards, the probability that various benefits are given is extremely low as compared with the case where the game is executed with three cards. There were some machines that were set up, or that couldn't play a game with one or two cards, and could only play a game with three cards. This is done as a device for increasing the operating rate of the slot machine in the hall, and aims to make the player play one game with three medals as much as possible.

However, the number of medals lent out from the hall before the game is not necessarily a multiple of 3, and is generally lent out in units of 50 medals, so there is a high probability that the number of medals will be less than 3 in the hands of the player. There was a possibility that it would remain. And if there are less than 3 medals left in hand, the game cannot be played with the remaining medals on the 3-card dedicated machine, and a slot machine that can hang 1 or 2 medals. However, since the probability that the privilege will be given is low, there is a risk that the medal may be left in the hall or the player may bring back the remaining medal. In this way, if a medal is left in the hall, the player loses by the value of the medal, and if the player brings back the remaining medal, the medal lent out in the hall cannot be collected, and further. , There is a risk that the player will play the game using the medals brought back from another hole, and there is a problem that the hole side also suffers damage.

On the other hand, in this slot machine 10, when the game is played with two cards, the cherry bell prize is established with a high probability of about 1/18, and when the game is played with one card. With a high probability of about 1/6.0, the Cherry Bell prize is established and three medals are paid out. Therefore, in the slot machine 10, even if the winning probability of the BB prize in the case of one or two medals is extremely low, if one or two medals remain in the player's hand. In addition, it is possible to have the player execute the game by playing one or two medals while giving the expectation that the cherry bell winning, in which three medals are paid out, will be established. Then, as a result of this game, if the Cherry Bell prize is established, three medals will be paid out, so that the player can use the three medals under conditions that are more advantageous than one or two medals. You can play the game with the expectation that the BB prize will be won. Further, even if the game is out of order, the game can be ended without leaving an extra medal for the player.

In addition, when the game is played with one card, a 7-bell prize is established with a high probability of about 1/6.0, and two medals are paid out. Therefore, in the slot machine 10, if one medal remains in the player's hand, three medals are paid out, and two medals are paid out with the expectation that the cherry bell winning will be established. It is possible to have the player execute the game by playing one card while giving a feeling of expectation that the 7-bell prize will be established. Then, as a result of this game, if a 7-bell prize is established, 2 medals will be paid out, so that the player can use the 2 medals to pay out 3 more medals. You can enjoy the game while having the expectation of winning.

In this way, even if one or two medals remain in the player's hand, the one or two medals are used and three medals are paid out. It is possible to have a player play a game aiming at a 7-bell prize in which medals are paid out. Therefore, the slot machine 10 can motivate the player to use up all the medals.

Here, referring to FIG. 5 again, in the reels 32L and 32M of the left reel 32L "cherry" symbol, the "7" symbol, and the middle reel 32M "bell" symbol, respectively, in which the cherry bell winning and the 7 bell winning are established. The arrangement position will be briefly described.

First, in the left reel 32L, the "cherry" symbol is arranged so that the distance between the symbol that reaches first and the symbol that reaches next in the lower row is 7 symbols. For example, the 3rd "cherry" symbol and the 10th "cherry" symbol on the left reel 32L are arranged so that the distance between them is 7 symbols. In addition, since the 0th and 20th of each reel are actually arranged adjacent to each other, the interval between the 17th "cherry" symbol and the 3rd "cherry" symbol of the left reel 32L is 7 symbols. ing. On the other hand, the "7" symbol on the left reel 32L is also arranged so that the distance between the symbol arriving first in the lower row and the symbol arriving next is 7 symbols. For example, the 6th "7" symbol on the left reel 32L and the 13th "7" symbol are arranged so that the distance between them is 7 symbols, and the 20th "7" symbol on the left reel 32L. The 6th "7" symbol is also arranged so that the interval is 7 symbols.

As described above, both the "cherry" symbol and the "7" symbol are arranged on the left reel 32L so that the spacing between the symbols of the same type is 7 symbols. As described above, each reel 32L, 32M, 32R can be stopped after sliding up to four symbols from the operated timing of the stop switches 42 to 44. Therefore, by adopting such a symbol arrangement, the "cherry" symbol or the "7" symbol is used when the cherry bell prize or the 7 bell prize is established, regardless of the timing at which the left stop switch 42 is operated. The display window 26L can be stopped at any of the upper, middle, and lower positions.

For example, if the left stop switch 42 is operated when the 3rd "cherry" symbol of the left reel 32L reaches the lower row, if the left reel 32L is stopped as it is, this "cherry" symbol can be stopped at the lower row. If the left stop switch 42 is operated when the 4th "replay" symbol of the left reel 32L reaches the lower stage, if the left reel 32L is slid by 4 symbols and then stopped, the 10th "replay" is performed. The "cherry" symbol can be stopped in the upper row, and if the left stop switch 42 is operated when the 5th "bell" symbol of the left reel 32L reaches the lower row, the left reel 32L is slid by 4 symbols. If you stop it later, you can stop the 10th "cherry" symbol in the middle.

Further, if the left stop switch 42 is operated when the 6th "7" symbol of the left reel 32L reaches the lower stage, if the left reel 32L is stopped as it is, this "7" symbol is stopped at the lower stage. If the left stop switch 42 is operated when the 7th "watermelon" symbol of the left reel 32L reaches the lower stage, if the left reel 32L is slid by 4 symbols and then stopped, the 13th "watermelon" 7 "The symbol can be stopped in the upper row, and when the left stop switch 42 is operated when the 8th" replay "symbol of the left reel 32L reaches the lower row, the left reel 32L is slid by 4 symbols. If you stop it later, you can stop the 13th "7" symbol in the middle.

On the other hand, in the middle reel 32M, the "bell" symbol is arranged so that the distance between the symbol that arrives first in the lower row and the symbol that reaches next is 5 or less. For example, the 0th "bell" symbol and the 5th "bell" symbol of the middle reel 32M are arranged so that the distance between them is 5 symbols, and the 9th "bell" symbol of the middle reel 32M is arranged. And the 12th "bell" symbol are arranged so that the distance between them is 3 symbols. In this way, the "bell" symbols are arranged on the middle reel 32M so that the distance between the symbols of the same type is 5 or less, so that the middle stop switch 43 can be operated at any timing by using such a symbol arrangement. Even if it is done, the "bell" symbol can be stopped at the middle position of the display window 26M when the cherry bell winning or the 7 bell winning is established.

For example, if the middle stop switch 43 is operated when the 11th "7" symbol of the middle reel 32M reaches the lower stage, if the middle reel 32M is stopped as it is, this "bell" symbol is stopped in the middle stage. If the middle stop switch 43 is operated when the 12th "bell" symbol of the middle reel 32M reaches the lower stage, slide the middle reel 32M by 4 symbols and then stop it to stop the 17th "bell". The "bell" symbol can be stopped in the middle.

In this way, regardless of the timing at which the stop switches 42 and 43 are operated, the "cherry" symbol or the "7" symbol can be stopped at any of the upper, middle, and lower stages of the display window 26L. Also, the "bell" pattern can be displayed in the middle of the display window 26M. Therefore, when the cherry bell prize or the 7 bell prize is won in the lottery of the winning mode, the stop symbol corresponding to the cherry bell prize or the 7 bell prize is supported regardless of the operation timing of the player's stop switches 42 to 44. Since the stop symbol can be displayed on any of the middle line L2, the right-down line L4, and the right-up line L5 (see FIG. 6), the stop symbol corresponding to the winning combination won in the lottery of the winning mode is the stop switch 42. It is possible to establish a cherry bell prize or a 7 bell prize without causing a so-called "missing" that is not displayed on the effective line depending on the operation timings of ~ 44.

Returning to FIG. 7, the explanation will be continued. As another winning mode that the slot machine 10 can take, a replay winning is provided when the slot machine 10 is stopped alongside the "replay" symbol, the "replay" symbol, and the "replay" symbol from the left on the effective line. When the replay prize is established, the player can play the next game without reducing the number of medals owned and without inserting medals, although the medals are not paid out or the state is changed. Therefore, if the replay prize is successful, the number of medals (the number of bets) inserted in the game will be paid out, that is, 1 for 1 card, 2 for 2 cards, and 3 for 2 cards. In the case of, it can be considered that three medals are paid out. The probability of winning a replay prize in a general game state is not limited to the number of medals inserted (number of bets), but is as high as about 1/7.3 in any case of 1-card, 2-card, or 3-card. It is set to probability. If this replay prize is established with a high probability, BB prize or special small role prize (cherry bell prize or 7 bell prize) will be established when the game is played with 1 or 2 cards. A lot of challenge can be given to the player.

As shown in FIG. 5, the "replay" symbols that establish the replay prize are reels 32L and 32M so that the distance between the symbol that arrives first in the lower row and the symbol that reaches next is 5 symbols or less. , 32R. For example, the 8th "replay" symbol and the 11th "replay" symbol on the left reel 32L are arranged so that the intervals are 3 symbols, and the 1st "replay" symbol and 6 on the middle reel 32M. The number "replay" symbols are arranged so that the intervals are 5 symbols. As described above, the "replay" symbols are arranged on the reels 32L, 32M, 32R so that the distance between the symbols of the same type is 5 or less. As described above, the reels 32L, 32M, 32R can be stopped after sliding up to 4 symbols from the operated timing of the stop switches 42 to 44. Therefore, by adopting such a symbol arrangement, the stop switches 42 to 44 can be stopped. Regardless of the timing of the operation, the "replay" symbol can be stopped at the middle position of the display windows 26L, 26M, 26R when the replay winning is established. For example, if the left stop switch 42 is operated when the 3rd "cherry" symbol of the left reel 32L reaches the lower row, if the left reel 32L is stopped as it is, the 4th "replay" symbol is stopped in the middle row. If the middle stop switch 43 is operated when the 1st "replay" symbol of the middle reel 32M reaches the lower stage, slide the middle reel 32M by 4 symbols and then stop it. "Replay" symbol can be stopped in the middle row. Therefore, when the replay prize is won, the "replay" symbol can be stopped at the middle line L2 (see FIG. 6) regardless of the timing at which the stop switches 42 to 44 are operated. Therefore, it is possible to establish a replay prize without so-called "missing".

In other cases, that is, if the combination of the above symbols does not stop on the valid line, no medal payout or transition of the gaming state is performed, and the game is out of order. That is, the "youth" symbol of each reel 32L, 32M, 32R, the "cherry" symbol of the middle reel 32M and the right reel 32R, and the "star" symbol of the middle reel 32M are not involved in the winning at all. In other words, it can be said that each of the above symbols is a non-privilege symbol unrelated to the privilege given to the player. That is, each reel 32L, 32M, 32R is provided with a privilege symbol related to a prize such as a "bell" symbol and a non-privilege symbol unrelated to a prize such as a "youth" symbol. In the following, the combination of each winning symbol and the corresponding symbol will also be referred to as a winning symbol combination. For example, the combination of BB symbols is a combination of symbols that wins BB, that is, a combination of "7" symbols, "7" symbols, and "7" symbols.

As described above, in this slot machine 10, the winning probability of BB winning when the game is played by inserting three medals is sufficiently higher than when the game is played by inserting one or two medals. Since it is set, it is possible to have the player insert three medals and play one game while expecting the player to get a lot of medals by winning the BB prize. As a result, medals are consumed quickly, and it becomes possible to increase the operating rate of slot machines in the hall.

On the other hand, when the game is played by inserting one or two medals, the cherry bell winning with three medals paid out is set as a winning combination candidate, and the winning probability is set high, so that the game is played. If one or two medals remain in the player's hand, the player is expected to pay out three medals by winning the Cherry Bell prize, and one or two medals remaining in the hand. Can be thrown in to play one game. As a result, if three medals are paid out due to the establishment of the Cherry Bell prize, the player can insert the three medals and play another game while expecting the establishment of the BB prize. , The player can enjoy the game to the end without leaving any extra medals. Further, even if the result of the game played by inserting one or two medals is off, the player can end the game without leaving any extra medals. In this way, the slot machine 10 can allow the player to enjoy the game to the end without leaving any extra medals. Then, there is a problem that the player loses by finishing the game without using the rented medal, the player cannot bring back the remaining medals and collect the rented medals, or brought them back from another hall. By using the medal by the player, it is possible to avoid the problem that the hole side suffers damage.

In addition, when the game is played by inserting one medal, a 7-bell prize with two medals paid out is also set as a winning combination candidate, and the winning probability is also set high, so that the player has a hand. If one medal remains in the game, the player is expected to pay out two medals if the 7-bell prize is established, and the remaining one medal is inserted once. You can play the game. As a result, if two medals are paid out due to the establishment of the 7-bell prize, the player inserts the two medals and expects the cherry-bell prize to be paid out with three more medals. , You can enjoy another game. Then, if the Cherry Bell prize is established, the player can play the game by inserting the three medals paid out while expecting the BB prize to be established, so that the player can play the game to the end without leaving any extra medals. You can enjoy the game, and even if you miss it, you can use up the medals. Therefore, it is possible to entertain the game to the end without leaving any extra medals while giving the player more enjoyment of the game.

In addition, in the lottery of the winning mode, when the cherry bell winning in which three medals are paid out or the seven bell winning in which two medals are paid out are won, regardless of the timing when the stop switches 42 to 44 are operated. , Since the stop symbol can be stopped on the effective line without missing, as a result of the lottery of the game started by the player with one and two medals, the cherry bell prize and the 7 bell prize were won as winning medals. In that case, those winnings can be surely established without relying on artificial operations. In addition, the player can be made to play the game in anticipation of the establishment of the cherry bell prize or the 7 bell prize while aiming at other prizes (for example, BB prize).

Here, the expected value of the number of medals to be paid out in the general game state in the case of one-card hanging and the case of two-card hanging will be described. First, in the case of one-card medals, the winning probability of the watermelon winning and the bell winning in the general game state is set to 1/65536, and if any of the winnings is established, three medals are paid out. In addition, the winning probabilities of the cherry bell winning and the 7 bell winning in the general game state are set to about 1/6.0, respectively, and if the cherry bell winning is established, 3 medals and the 7 bell winning are established. Two medals will be paid out. In addition, the winning probability of the replay winning in the general gaming state is set to about 1/7.3, and if the replay winning is established, it is equivalent to the one in which one medal is paid out as described above. I can think. On the other hand, the winning probability of the BB winning in the general gaming state is set to 1/65536, and when the BB winning is established, the gaming state shifts to the bonus state, but the number of medals paid out is 0. Here, the expected value of the number of medals to be paid out per game under the general gaming state is equal to the value obtained by multiplying the number of medals to be paid out corresponding to each of the above winning probabilities and adding these multiplication results. The expected value is about 0.96. That is, in the general game state, the ratio of the number of medals paid out to the number of bets (1) is about 96%, and it is expected that the number of medals owned by the player decreases by about 0.04 for each game played. ..

Further, in the case of two medals, the winning probability of the watermelon winning and the bell winning in the general game state is set to 1/65536, and if any of the winnings is established, three medals are paid out. In addition, the winning probability of the cherry bell winning in the general gaming state is set to about 1 / 1.8, and if the cherry bell winning is established, three medals are paid out. In addition, the winning probability of the replay winning in the general gaming state is set to about 1/7.3, and if the replay winning is established, it is equivalent to the one in which two medals are paid out as described above. I can think. On the other hand, the winning probability of the BB winning in the general gaming state is set to 1/65536, and when the BB winning is established, the gaming state shifts to the bonus state, but the number of medals paid out is 0. Therefore, the expected value of the number of medals to be paid out per game under the general gaming state in which two medals are played is about 1.94. That is, in the general game state, the ratio of the number of medals paid out to the number of bets (2) is about 97%, and it is expected that the number of medals owned by the player decreases by about 0.06 for each game played. ..

In this way, in both cases of 1-card and 2-card, the ratio of the number of medals to be paid out to the number of bets is set to a value as close to 100% as possible. If you do, the medal will be returned to the player with an expected value of almost 100%. That is, even if the game is played with one or two medals, the medals hardly decrease, so if one or two medals remain in the player's hand, the player has one remaining in the hand. Or you can be sure that you want to play a game with two medals. Therefore, it is possible to further reduce the possibility that the player will finish the game by leaving a medal.

On the other hand, if the game is played with one or two medals, it is expected that the number of medals will decrease slightly, so if the game is repeated with one or two medals, the number of medals will increase. Instead, it is decreasing. Therefore, it is possible to prevent the player from repeatedly playing the game with one or two medals and aiming for an increase in medals. Therefore, when there are three or more medals, the player can be made to play the game with three medals having a high probability of winning the BB prize.

In this embodiment, the number of medals to be paid out when the cherry bell prize is established by playing the game with one or two medals is set to three, which is the maximum number of bets, and the game is played with one medals. The number of medals to be paid out when the 7-bell prize is established is set to 2, but the number of medals to be paid out when the cherry-bell prize is established is set to a multiple of 3, and the number of medals to be paid out when the 7-bell prize is established is set to 2. It may be set to a multiple of 2. However, if the number of medals to be paid out is set to 3 or 2 when the cherry bell prize or 7 bell prize is established, even if the expected value of the number of medals to be paid out is set to less than 100%, each prize will be won. The winning probability can be set high. Therefore, it is possible to increase the possibility that a cherry bell prize or a 7 bell prize will be established, and it is possible to increase the probability that 3 or 2 medals will be given to the player, so that 1 or 2 medals will be given to the player. You can use the medals to make you want to play the game.

FIG. 7 shows the winning probability when the setting state is "setting 1", but even when the setting state is set to any of "setting 2" to "setting 6", one piece is hung and the winning probability is set. The winning probability corresponding to each winning mode in the case of two cards is set so that the ratio of the number of medals paid out to the number of bets is less than 100%. In this embodiment, the winning probability corresponding to each winning mode in the case of one-card or two-card is changed according to the setting state (“setting 1” to “setting 6”), but one card is used. The winning probability of the multiplication and the two-card multiplication may be constant regardless of the set state. That is, the winning probability may be changed according to the set state only in the case of three cards. In addition, in the case of 1-sheet and 2-sheet hanging, the winning probability of at least one of BB winning, watermelon winning, bell winning and replay winning is determined according to the setting state ("Setting 1" to "Setting 6"". Although it will be changed, the winning probabilities of the cherry bell winning and the 7 bell winning, which are special small winning combination prizes in the case of one-card and two-card winning, are not changed and may be a constant value.

In addition, in this slot machine 10, the winning mode is established only when the cherry bell winning is played with one or two cards, and when the game is played with three cards, the left reel 32L. Even if the "cherry" symbol is stopped and the "bell" symbol is stopped on the middle reel 32M, the cherry bell prize is not established and is treated as a miss, so the cherry bell prize is a special small for 1 and 2 cards. It is possible to draw the player's attention as a winning combination. Therefore, when the game is played with one or two cards, if the symbol stops at the cherry bell winning stop symbol, the player can be greatly delighted.

Similarly, the winning mode is established only when the game is played with one 7-bell prize, and when the game is played with two or three cards, the left reel 32L has a "7" symbol. Even if the "bell" symbol stops on the middle reel 32M, the 7-bell prize will not be established and will be treated as a miss. It can be noticed. Therefore, when the game is played with one card, if the symbol stops at the 7-bell winning stop symbol, the player can be greatly delighted.

Further, in the slot machine 10, even when the game is played with one or two cards, the BB winning is set so as to be established, although the winning probability is extremely low. As a result, even when the game is played with one or two cards, the player can have a sense of expectation that the BB prize will be established.

Further, in the slot machine 10, when the game is played with one or two medals, the watermelon prize or the bell prize, which is a normal small role prize other than the BB prize or the replay prize, is established. However, unlike the number of medals to be paid out when the game is played with 3 medals, 3 medals are to be paid out in the same way as when the Cherry Bell prize is established. By inserting the three medals that have been made, the player can play another game while expecting the BB prize to be established, and the player can surely enjoy the game to the end without leaving any extra medals. can. Further, in this slot machine 10, the probability of winning a watermelon prize or a bell prize is low when the game is played with one or two cards, while the probability of winning a cherry bell prize or a 7 bell prize is set high. Therefore, it is possible to further impress the player that the cherry bell winning or the 7 bell winning is a special small role winning with one or two slots, and one or two slots. When the game is played in, the player can have the expectation that the cherry bell prize or the 7 bell prize will be established.

Next, the electrical configuration of the slot machine 10 will be described with reference to FIG. FIG. 8 is a block diagram showing an electrical configuration of the slot machine 10.

The main control device 101 is equipped with a microcomputer centered on the MPU 102, which is an arithmetic processing means. In addition to the power supply device 91, a clock circuit 103 that outputs a rectangular wave having a predetermined frequency, an input / output port 104, and the like are connected to the MPU 102 via an internal bus. The main control device 101 functions as a main board built in the slot machine 10.

On the input side of the main controller 101, there is a reel unit 31 (more specifically, a reel index sensor that individually detects that each reel 32L, 32M, 32R has rotated once), and a start detection sensor that detects the operation of the start lever 41. 41a, stop detection sensors 42a to 44a for individually detecting the operation of each stop switch 42 to 44, first insertion medal detection sensor 45a and second insertion medal detection sensor 45b for detecting medals inserted from the medal insertion slot 45, A payout detection sensor 51a that detects medals paid out from the hopper device 51, credit insertion detection sensors 56a to 58a that individually detect the operation of each credit insertion switch 56 to 58, a payment detection sensor 59a that detects the operation of the payment switch 59, Various sensors such as a reset detection sensor 72a that detects the operation of the reset switch 72 and a setting key detection sensor 73a that detects that the setting key has been inserted into the setting key insertion hole 73 and turned on are connected. The signal from the sensor is output to the MPU 102 via the input / output port 104.

Further, a power supply device 91 is connected to the input side of the main control device 101 via the input / output port 104. The power supply device 91 is equipped with a power supply unit 91a that supplies drive power to each electronic device of the slot machine 10, including the main control device 101, a power failure monitoring circuit 91b, and the like.

The power failure monitoring circuit 91b monitors the power cutoff state and generates a power failure signal not only when the power is cut off but also when the power supply is cut off by the power switch 71. Therefore, the power failure monitoring circuit 91b monitors the stabilized drive voltage of DC 12 volt in this example output from the power supply unit 91a, and determines that the power supply is cut off when this drive voltage drops to less than, for example, 10 volt. It is configured to output a power failure signal. The power failure signal is supplied to each of the MPU 102 and the input / output port 104, and the MPU 102 recognizes the power failure signal to execute the power failure processing described later. Further, the power failure signal is also configured to be supplied to the display control device 81.

The power supply unit 91a is configured to output a regulated voltage of 5 volts, which is used as a drive voltage in a control system such as the main control device 101, even when the output voltage drops to less than 10 volts. As the time for outputting this regulated voltage, a sufficient time is secured for executing the power failure processing by the main control device 101.

On the output side of the main control device 101, a reel unit 31 (more specifically, a stepping motor for rotating each reel 32L, 32M, 32R), a medal passage switching solenoid 46a provided in the selector 46, a hopper device 51, and a credit An external centralized terminal board 121 or the like capable of transmitting information to a display unit 60, a remaining payout number display unit 61, a payout number display unit 62, a display control device 81, a hall management device (not shown), or the like is connected via an input / output port 104. There is.

The display control device 81 is a control device for driving the upper lamp 63, the speaker 64, and the auxiliary display unit 65. The details will be described later with reference to FIG. 10, but the board is provided with an integrated MPU181, an image controller 188, various memories, and the like, and display control is performed after receiving a signal from the main control device 101. The device 81 independently drives and controls the upper lamp 63, the speaker 64, and the auxiliary display unit 65. Therefore, the display control device 81 is a sub-board that executes auxiliary control in relation to the main control device 101, which is the main board that controls and manages the game. The various display units 60 to 62 may also be configured to be driven and controlled by the display control device 81.

Further, in the display control device 81, the character ROM 187 for storing various image data to be displayed on the auxiliary display unit 65 is configured by a NAND flash memory which can obtain a large storage capacity in a small area and is an inexpensive memory. .. As a result, the capacity of the character ROM 187 can be easily increased, and many images can be prepared as images to be displayed on the auxiliary display unit 65. Therefore, in order to further enhance the interest of the player, the auxiliary display unit can be used. The images displayed in can be diversified and complicated. The NAND flash memory makes it easy to increase the capacity of the ROM, but when reading data by random access, the read speed related to the reading is higher than that of other ROMs (mask ROM, EEPROM, etc.). It's slow. Therefore, the display control device 81 has been invented to display an image at a desired time without any problem even if a memory having a slow read speed is used as a storage means for image data. The details will be described later with reference to FIG.

The above-mentioned MPU 102 includes a ROM 105 that stores various control programs and fixed value data executed by the MPU 102, and a work area that temporarily stores various data when executing the control program stored in the ROM 105. It has a built-in RAM 106 for securing and a free run counter 107 for generating random numbers. Further, although not shown, the MPU 102 also includes various processing circuits such as an interrupt circuit, a timer circuit, a data transmission / reception circuit, etc. required for the slot machine 10, and various counters such as a credit counter for counting the number of credits. It is built-in.

The free run counter 107 is a counter configured by hardware that generates and updates random numbers from 0 to 65535 in a short cycle. After confirming the operation of the start lever 41 based on the output signal of the start detection sensor 41a, the MPU 102 latches the value of the free run counter 107 by a hard circuit, and stores the latched value in the RAM 106. With such a configuration, it is possible to quickly acquire random numbers at the timing when the start lever 41 is operated, and it is possible to avoid problems such as synchronization. The hard circuit of the slot machine 10 is configured to latch the value of the free run counter 107 each time the start lever 41 is operated. Further, the value of the free run counter latched and stored in the RAM 106 is used to draw a winning mode (combination) of the game started by the operation of the start lever 41.

The ROM 105 and the RAM 106 constitute a main memory as a storage means, and a program for executing various processes shown in the flowcharts shown in FIGS. 15 and 15 is stored in the ROM 105 as a part of a control program. Further, the ROM 105 is provided with at least a lottery table storage area 105a for storing a lottery table used for the lottery of the winning mode.

Here, the lottery table will be described with reference to FIG. FIG. 9 is a schematic diagram schematically showing a lottery table selected in the general game state when the setting state is set to “setting 1”, and FIG. 9A is a schematic diagram showing the number of medals inserted in 3 pieces. The three-card lottery table used when (three-card hanging) is used, (b) is the two-card hanging lottery table used when the number of inserted medals is two (two-card hanging), and (c) is. The one-card hanging lottery table used when the number of inserted medals is one (one-hanging) is shown.

An index value IV is set in each lottery table, and each index value IV is uniquely associated with a winning mode, and a point value corresponding to the winning probability corresponding to the winning mode. PV is set for each lottery table. Specifically, IV = 1 is associated with BB winning as a winning mode, IV = 2 is associated with watermelon winning, IV = 3 is associated with bell winning, and IV = 4. Is associated with a cherry bell winning, IV = 5 is associated with a 7 bell winning, and IV = 6 is associated with a replay winning.

Further, in the three-sheet lottery table, as shown in FIG. 9A, PV = 256 is associated with IV = 1 (BB prize), and PV = 2 (watermelon prize). 8192 is associated, PV = 12850 is associated with IV = 3 (bell winning), PV = 0 is associated with IV = 4 (cherry bell winning), IV = 5 (7 bell winning). ) Is associated with PV = 0, and IV = 6 (replay winning) is associated with PV = 8980.

Here, the lottery method of the winning mode will be briefly described. When the random number value of the free run counter 107 is latched by the operation of the start lever 41 and stored in the RAM 106, first, the value of the point value PV associated with IV = 1 (BB winning) (FIG. 9A). In the lottery table shown in (1), 256) is added to the value of the latched random number and used as the determination value DV (see S304 in FIG. 17). Then, when the determination value DV is larger than 65535, the BB winning combination is determined as the winning combination of the game (see S305 and S306 in FIG. 17), and the lottery ends. That is, when a lottery is performed using the three-sheet lottery table shown in FIG. 9A, the BB prize is determined as a winning combination when the value of the latched random number is in the range of 655280 to 65535. .. Therefore, the winning probability is set to 1/256 as shown in FIG.

On the other hand, when the determination value DV is 65535 or less, the index value IV is incremented by 1 (see S307 in FIG. 17), and the value of the point value PV corresponding to the index value IV after the advance is added to the determination value DV. Then, the determination value DV is updated (see S304 in FIG. 17). Then, when the determined determination value DV after the update is a value larger than 65535, the winning mode corresponding to the index value IV after the advance is determined as a winning combination, and the lottery is completed. Further, the index value IV is incremented by 1, and the determination value DV is updated (addition of the point value PV corresponding to the IV after the advance) and the determination value DV after the update (whether the determination value DV is larger than 65535 or not). ) Is repeated until the winning combination is determined or the determination combination disappears (until the IV exceeds the maximum value) (see S304 to S308 in FIG. 17).

As a result, when a lottery is performed using the three-sheet lottery table shown in FIG. 9A, the watermelon prize is determined as a winning combination when the value of the latched random number is in the range of 57088 to 655279. When the value of the latched random number is in the range of 44238 to 57087, the bell winning combination is determined as the winning combination, and when the value of the latched random number is in the range of 35258 to 44237, the replay winning combination is determined as the winning combination. .. Therefore, as shown in FIG. 7, the winning probability of each winning mode is set to 1/8 for the watermelon winning, about 1 / 5.1 for the bell winning, and about 1 / for the replay winning. It will be set to 1/3.

In addition, in the three-sheet hanging lottery table shown in FIG. 9A, the value of the point value PV corresponding to IV = 4 (cherry bell winning) and IV = 5 (7 bell winning) is set to 0. Therefore, even if the determination value DV is updated using this value, the value does not change between before and after the update. Then, when the point value PV corresponding to IV = 4 and IV = 5 is added to the determination value DV, it is when the determination value DV is 65535 or less, so when IV = 4 and IV = 5. Even if the determination value after the update is determined, it is not determined to be larger than 65535. Therefore, by setting the point value PV corresponding to IV = 4 (cherry bell prize) and IV = 5 (7 bell prize) to 0, the cherry bell prize and the 7 bell prize will not be selected as winners. It has become.

In the two-sheet lottery table shown in FIG. 9B, PV = 1 is associated with IV = 1 (BB winning), and PV = 1 is associated with IV = 2 (watermelon winning). , PV = 1 is associated with IV = 3 (bell winning), PV = 36400 is associated with IV = 4 (cherry bell winning), and PV is associated with IV = 5 (7 bell winning). = 0 is associated, and PV = 8980 is associated with IV = 6 (replay winning). Therefore, when a lottery is performed using the two-sheet lottery table shown in FIG. 9B, the BB prize is determined as a winning combination when the value of the latched random number is 65535, and the latched random number is used. When the value is 65534, the watermelon winning combination is determined as a winning combination, and when the value of the latched random number is 65533, the bell winning combination is determined as a winning combination, and the value of the latched random number is in the range of 29133 to 65532. At one point, the cherry bell winning combination is determined as the winning combination, and when the value of the latched random number is in the range of 20153 to 29132, the replay winning combination is determined as the winning combination. Therefore, as shown in FIG. 7, the winning probabilities of each winning mode are set to 1/65536 for BB winning, watermelon winning, and bell winning, respectively, and to about 1 / 1.8 for cherry bell winning. It will be set, and the replay prize will be set to about 1/3. Since the point value PV corresponding to IV = 5 (7 bell winning) is set to 0, as described above, the 7 bell winning is not set as a winning combination.

Further, in the one-sheet lottery table shown in FIG. 9 (c), PV = 1 is associated with IV = 1 (BB winning), and PV = 1 corresponds to IV = 2 (watermelon winning). Attached, PV = 1 is associated with IV = 3 (bell winning), PV = 10880 is associated with IV = 4 (cherry bell winning), and IV = 5 (7 bell winning). PV = 10880 is associated with this, and PV = 8980 is associated with IV = 6 (replay winning). Therefore, when a lottery is performed using the one-sheet lottery table shown in FIG. 9C, the BB winning combination is determined as a winning combination when the value of the latched random number is 65535, and the latched random number is used. When the value is 65534, the watermelon winning combination is determined as a winning combination, and when the value of the latched random number is 65533, the bell winning combination is determined as a winning combination, and the value of the latched random number is in the range of 54653 to 65532. At one point, the Cherry Bell prize is determined as a winner, and when the value of the latched random number is in the range of 43773 to 54652, the 7 bell prize is determined as a winner, and the value of the latched random number is 34793 to 43772. When it is in the range, the replay prize is judged as the winning combination. Therefore, as shown in FIG. 7, the winning probability of each winning mode is set to 1/65536 for BB winning, watermelon winning, and bell winning, respectively, and about 6.0 for cherry bell winning and 7 bell winning. It will be set to 1/13, and the replay prize will be set to about 1/3.

In the lottery table storage area 105a, a lottery table for one-sheet hanging, a lottery table for two-sheet hanging, and a lottery table for three-sheet hanging for general gaming states are stored for each of "setting 1" to "setting 6". There is. Further, a lottery table in the bonus state, which is used when the slot machine 10 is in the bonus state, is prepared for each of "setting 1" to "setting 6". Then, a lottery table used for the lottery of the winning mode (combination) is set according to the setting state and the gaming state of the slot machine 10 and the number of inserted medals (number of bets). That is, in the general game state, when the number of bets is 3, a lottery table for playing 3 cards corresponding to the setting state of the slot machine 10 is set, and when the number of bets is 2, the slot machine 10 is set. A two-card lottery table corresponding to the set state is set, and when the number of bets is one, a one-card lottery table corresponding to the set state of the slot machine 10 is set. When the gaming state of the slot machine 10 is in the bonus state, a lottery table in the bonus state corresponding to the setting state of the slot machine 10 is set (see FIG. 18). Then, the lottery of the winning mode is performed using the set lottery table.

As a lottery table used when the gaming state of the slot machine 10 is in the bonus state, a lottery table different depending on the number of bets (1 to 3) is not provided, but this is a bonus in this embodiment. This is because the game is played by limiting the number of bets to three when the player is in the state. Therefore, in the case of the bonus state, the corresponding bonus state lottery table is simply set according to the setting state (“setting 1” to “setting 6”) of the slot machine 10.

In the slot machine 10, when the game is in a general gaming state, the three-card lottery table shown in FIGS. 9 (a) to 9 (c), the two-card lottery table, and the one-card lottery table are set according to the number of bets. By switching the game, the winning probability of BB winning when the game is played by inserting three medals can be set sufficiently higher than when the game is played by inserting one or two medals. .. Therefore, as described above, it is possible to insert three medals and play one game while expecting the player to pay out a large number of medals by establishing the BB prize. As a result, medals are consumed quickly, and it becomes possible to increase the operating rate of slot machines in the hall.

Further, when the game is played by inserting one or two medals, the cherry bell winning with three medals paid out can be set as a winning combination candidate, and the winning probability can be set high. Therefore, if one or two medals remain in the player's hand, the player is expected to pay out three medals by winning the Cherry Bell prize, and the remaining one or two medals are left in the player's hand. You can insert one medal to play one game. As a result, if three medals are paid out due to the establishment of the Cherry Bell prize, the player can insert the three medals and play another game while expecting the establishment of the BB prize. , The player can enjoy the game to the end without leaving any extra medals. Further, even if the result of the game played by inserting one or two medals is off, the player can end the game without leaving any extra medals.

In addition, when the game is played by inserting one medal, a 7-bell prize with two medals paid out can be set as a winning combination candidate, and the winning probability can be set high, so that the game can be played. If one medal remains in the player's hand, the player is expected to pay out two medals if the 7-bell prize is established, and the remaining one medal is inserted. You can play one game. As a result, if two medals are paid out due to the establishment of the 7-bell prize, the player inserts the two medals and expects the cherry-bell prize to be paid out with three more medals. , You can enjoy another game. Then, if the Cherry Bell prize is established, the player can play the game by inserting the three medals paid out while expecting the BB prize to be established, so that the player can play the game to the end without leaving any extra medals. You can enjoy the game, and even if you miss it, you can use up the medals. Therefore, it is possible to entertain the game to the end without leaving any extra medals while giving the player more enjoyment of the game.

In this way, the slot machine 10 can allow the player to enjoy the game to the end without leaving any extra medals.

Further, by using the one-card lottery table and the two-card lottery table stored in the lottery table storage area 105a, the winning probability of each winning mode can be set to the value shown in FIG. 7. As described above with reference to FIG. 7, the ratio of the number of medals to be paid out to the number of bets can be set to a value of less than 100% and as close to 100% as possible in both cases of 1-card and 2-card. can. Therefore, even if the game is played with one or two medals, the medals hardly decrease. Therefore, if one or two medals remain in the player's hand, the player has one remaining in the hand. Alternatively, it is possible to make sure that the player wants to play the game using two medals, and it is possible to further reduce the possibility that the player finishes the game by leaving the medals. On the other hand, if the game is repeated with one or two medals, the number of medals will decrease. Therefore, if the player repeatedly plays the game with one or two medals, the number of medals will increase. Can be prevented from aiming at. Therefore, if there are three or more medals, the player can be directed to play the game with three medals, which have a high probability of winning the BB prize.

In addition, by switching and using each lottery table according to the number of bets, the winning mode is established only when the game is played with one or two cherry bells, and the game is played with three. If it is done, it can be treated as a miss without establishing a cherry bell prize, so pay attention to the player as the cherry bell prize is a special small role prize dedicated to 1-card and 2-card prizes. Can be made to. Similarly, if the 7-bell prize is played only when the game is played with 1 card, and the game is played with 2 or 3 cards, the 7-bell prize is not established. Since it is treated as an outlier, the player can be noticed that the 7-bell prize is a special small role prize dedicated to one piece. Therefore, when the game is played with one or two cards, if the symbol stops at the stop symbol of the cherry bell winning or the 7 bell winning, the player can be greatly delighted.

Also, even when the game is played with one or two cards, although the winning probability is extremely low, it can be set so that the BB prize is established, so one or two cards can be played. Even when the game is played in, the player can have a sense of expectation that the BB prize will be established.

Further, in this slot machine 10, the probability of winning a watermelon prize or a bell prize is low when the game is played with one or two cards, while the probability of winning a cherry bell prize or a 7 bell prize is set high. Therefore, it is possible to further impress the player that the cherry bell winning or the 7 bell winning is a special small winning combination winning with one or two slots, and one or two slots. When the game is played by hanging, it is possible to give the player a sense of expectation that a cherry bell prize or a 7 bell prize will be established.

In this embodiment, the point value PV corresponding to IV = 5 (7 bell winning) is set to 0 in the two-card hanging lottery table, and IV = 4 (cherry bell winning) in the three-card hanging lottery table. ) And IV = 5 (7 bells) by setting the point value PV to 0, the lottery of those winning modes is performed, but the winning mode is not won, but the winning mode is won. By not setting the index value IV to be, and not drawing lots for those winning modes, the winning mode may not be won.

Returning to FIG. 8, the explanation will be continued. The RAM 106 has a configuration in which a backup voltage is supplied from the power supply device 91 to hold (back up) data even after the power supply of the slot machine 10 is cut off. The RAM 106 has a memory for temporarily storing various data, a winning flag storage area 106a for storing the lottery result of the winning combination, and a slide table used for stop control of each reel 32L, 32M, 32R. In addition to the slide table storage area 106b for storing the data, the state information storage area 106c for storing the game state such as the bonus state, and the like, at least a backup area is provided.

The backup area is an area for storing the value of the stack pointer when the power is cut off due to a power failure or the like (including the power cutoff by operating the power switch 71. The same applies hereinafter). When the power failure is resolved (including turning on the power by operating the power switch 71, the same applies hereinafter), the state of the slot machine 10 can be restored to the state before the power was cut off based on the information in the backup area. .. Writing to the backup area is executed when the power is cut off by the power failure process (see S103 in FIG. 15), and restoration of each value written in the backup area is executed in the main process when the power is turned on.

Further, the NMI terminal (non-maskable interrupt terminal) of the MPU 102 is configured to input a power failure signal from the power failure monitoring circuit 91b when the power is cut off due to the occurrence of a power failure or the like. When the power is cut off, the NMI interrupt process as the power failure flag generation process is immediately executed.

Next, with reference to FIG. 10, the electrical configuration of the display control device 81 of the slot machine 10 will be described. FIG. 10 is a block diagram showing an electrical configuration of the display control device 81. In the description of FIG. 10, the detailed description of the portion described in the electrical configuration of the slot machine 10 of FIG. 8 will be omitted.

As shown in FIG. 10, the display control device 81 is a control device for driving an upper lamp 63, a speaker 64, and an auxiliary display unit 65, and is a microcomputer centered on an MPU 181 which is an arithmetic processing means, and an image. An image controller 188 that draws and displays the drawn image on the auxiliary display unit 65 at a predetermined timing, a character ROM 187 that stores image data displayed on the auxiliary display unit 65, and the like are mounted.

An input / output port 186, a character ROM 187, and an image controller 188 are connected to the MPU 181 via an internal bus, and a signal latch circuit 182 that latches control signals such as commands transmitted from the main control device 101, and a predetermined value. A clock circuit 183 that outputs a rectangular wave of frequency, and a work RAM 185 for storing a control program executed by the MPU 181 and securing a work area for temporarily storing various data when executing this control program. Is connected.

Further, the power supply device 91, the upper lamp 63, the speaker 64, and the auxiliary display unit 65 are connected to the MPU 181 via the input / output port 186. The power supply device 91 is configured to input a power failure signal that is output when the drive voltage drops to less than, for example, 10 volts. The MPU 181 performs various control processes based on various commands transmitted from the main control device 101, and executes drive control of the upper lamp 63, the speaker 64, and the auxiliary display unit 65 via the input / output port 186. Hereinafter, the upper lamp 63, the speaker 64, and the auxiliary display unit 65 are collectively referred to as an auxiliary effect unit.

In the display control device 81, a one-chip microcomputer in which the work RAM 185, the signal latch circuit 182, the clock circuit 183, and the like described above are built in the MPU may be used. Further, the work RAM 185 may be configured by being connected to an internal bus connecting the MPU 181, the input / output port 186, the character ROM 187, and the image controller 188.

In the following, the MPU 181, the character ROM 187, the image controller 188, the resident video RAM 189, and the normal video RAM 190 will be described first, and then the work RAM 187 will be described.

The MPU 181 has a built-in instruction pointer 181a, reads and fetches an instruction code stored at the address indicated by the instruction pointer 181a, and executes various processes according to the instruction code. The MPU 181 is configured to receive a system reset from the power supply device 91 immediately after the power is turned on (including recovery from a power failure; the same applies hereinafter), and when the system reset is released, the hardware in the MPU 181 is released. The instruction pointer 181a is automatically set to "0000H" by the hardware. Then, the value of the instruction pointer 181a is incremented by 1 each time the instruction code is fetched. When the MPU 181 executes the instruction pointer setting instruction, the value of the pointer instructed by the setting instruction is set in the instruction pointer 181a.

Although details will be described later, in the present embodiment, the fixed value data for driving the control program executed by the MPU 181 and the upper lamp 63 and the like is a dedicated program ROM (for example, a dedicated program ROM like a conventional gaming machine). The ROM 22) of Patent Document 1 described above is not provided and stored, but is stored in the character ROM 187 provided for storing the image data to be displayed on the auxiliary display unit 64. As described above, since the character ROM 187 is composed of a NAND flash memory 187a capable of increasing the capacity in a small area, it is possible to sufficiently store not only the image data but also the control program and the like. can. If the control program or the like is stored in the character ROM 187, it is not necessary to provide a dedicated program ROM for storing the control program or the like. Therefore, the number of parts in the display control device 81 can be reduced, the manufacturing cost can be reduced, and the increase in the failure occurrence rate due to the increase in the number of parts can be suppressed.

On the other hand, the NAND flash memory has a problem that the read speed becomes slow, especially when performing random access. For example, when reading data that is continuously arranged on a plurality of pages, high-speed reading is possible for the data on the second and subsequent pages, but an address is specified for reading the data on the first page. It takes a long time to output the data. Further, when reading non-consecutive data, it takes a long time to read the data. As described above, since the speed of reading the NAND flash memory is slow, if the MPU 181 is configured to directly read the control program from the character ROM 187 and execute various processes, it takes time to read the instructions constituting the control program. Even if a high-performance processor is used as the MPU181, the processing performance of the display control device 81 may be deteriorated.

Therefore, in the present embodiment, when power is supplied from the power supply device 91 to the display control device 81 and the system reset is released, first, various data are stored in the NAND flash memory 187a of the character ROM 187. It is transferred to and stored in the work RAM 185 provided for temporary storage. Then, the MPU 181 executes various processes according to the control program stored in the work RAM 185. Since the work RAM 185 is composed of a DRAM (Dynamic RAM) and data is read / written at high speed, the MPU 181 can read out the instructions constituting the control program without delay. Therefore, high processing performance can be maintained in the display control device 81, and diversified and complicated effects can be easily executed by using the auxiliary effect unit.

As described above, the character ROM 187 is a memory that stores the control program executed in the MPU 181 and the image data displayed on the auxiliary display unit 65, and is connected to the MPU 181 via the internal bus. After the system reset is released, the MPU 181 directly accesses the character ROM 187 via the internal bus, and stores the control program stored in the first program storage area 187d1 and the second program storage area 187a1 described later in the character ROM 187 as a program of the work RAM 185. Transfer to area 185c. An image controller 188 is also connected to the internal bus, and the image controller 188 reads out the image data stored in the character storage area 187a2 described later of the character ROM 187, and the resident video RAM 189 connected to the image controller 188. And transfer to the normal video RAM 190.

The character ROM 187 is configured by modularizing a NAND flash memory 187a, a ROM controller 187b, a buffer RAM 187c, and a NOR flash memory 187d.

The NAND flash memory 187a is a non-volatile memory provided as a main storage unit in the character ROM 187, and is fixed for driving most of the control programs executed by the MPU 181 and the upper lamp 63, the auxiliary display unit 65, and the like. It has at least a second program storage area 187a1 for storing value data and a character storage area 187a2 for storing data of an image (character or the like) to be displayed on the auxiliary display unit 65.

Here, the NAND flash memory has a feature that a large storage capacity can be obtained in a small area, and the character ROM 187 can be easily increased in capacity. Thereby, in this slot machine, for example, by using the NAND type flash memory 187a having a capacity of 2 gigabytes, many images can be stored in the character storage area 187a2 as the images to be displayed on the auxiliary display unit 65. Therefore, in order to further enhance the interest of the player, the image displayed on the auxiliary display unit 65 can be diversified and complicated.

Further, the NAND flash memory 187a can store a large amount of image data in the character storage area 187a2, and further, the control program and fixed value data can be stored in the second program storage area 187a1. In this way, the image in which the control program and the fixed value data are displayed on the auxiliary display unit 64 without providing and storing a dedicated program ROM (for example, ROM 22 of Patent Document 1 described above) as in a conventional gaming machine. Since it can be stored in the character ROM 187 provided for storing the data, the number of parts in the display control device 81 can be reduced, the manufacturing cost can be reduced, and the failure rate increases due to the increase in the number of parts. Can be suppressed.

The ROM controller 187b is a controller for controlling the operation of the character ROM 187. For example, the corresponding data is input from the NAND flash memory 187a or the like based on the address transmitted from the MPU 181 or the image controller 188 via the internal bus. It is read out and output to the MPU 181 and the image controller 188 via the internal bus.

Here, due to the nature of the NAND flash memory 187a, a relatively large number of error bits (bits in which erroneous data is written) are generated when writing data, or a defective data block in which data cannot be written occurs. Or something. Therefore, the ROM controller 187b is known to perform known error correction on the data read from the NAND flash memory 187a, and to read and write the data to and from the NAND flash memory 187a while avoiding defective data blocks. Data address conversion (see, for example, Patent Document 1) is performed.

Since the ROM controller 187b performs error correction on the data read from the NAND flash memory 187a including the error bit, even if the NAND flash memory 187a is used as the character ROM 187, it is based on the erroneous data. It is possible to prevent the MPU 181 from performing processing and the image controller 188 from generating various images.

Further, since the defective data block of the NAND flash memory 187a is analyzed by the ROM controller 187b and access to the defective data block is avoided, the MPU 181 and the image controller 188 have different defective data in each NAND flash memory 187a. Access to the character ROM 187 can be easily performed without considering the address position of the block. Therefore, even if the NAND flash memory 187a is used for the character ROM 187, it is possible to suppress the complicated access control to the character ROM 187.

The buffer RAM 187c is a memory used as a buffer for temporarily storing data read from the NAND flash memory 187a. When an address assigned to the character ROM 187 from the MPU 181 or the image controller 188 via the internal bus is specified, the ROM controller 187b has one page (for example, 2 kilobytes) containing the data corresponding to the specified address. It is determined whether or not the data is set in the buffer RAM 187c. If it is not set, one page (for example, 2 kilobytes) of data including the data corresponding to the specified address is read from the NAND flash memory 187a (or NOR flash 187d) and temporarily set in the buffer RAM 187c. do. Then, the ROM controller 187b performs known error correction processing, and then outputs the data corresponding to the designated address to the MPU 181 and the image controller 188 via the internal bus.

The buffer RAM 187c is composed of two banks, and data for one page of the NAND flash memory 187a can be set in one bank. As a result, the ROM controller 187b can output the data of the NAND flash memory 187a to the outside by using the other bank while the data is set in one bank, or can be designated by the MPU 181 or the image controller 188. The process of transferring one page of data including the data corresponding to the assigned address from the NAND flash memory 187a to one bank and setting the data, and the data corresponding to the address specified by the MPU 181 or the image controller 188 to the other bank. The process of reading from the bank and outputting to the MPU 181 or the image controller 188 can be processed in parallel. Therefore, it is possible to improve the responsiveness in reading the character ROM 187.

The NOR type ROM 187d is a non-volatile memory provided as a sub storage unit in the character ROM 187, and has an extremely smaller capacity (for example, 2 kilobytes) than the NAND type flash memory 187a for the purpose of complementing the NAND type flash memory 187a. ). Among the control programs stored in the character ROM 187, the NOR type ROM 187d is the first program not stored in the second program storage area 187a1 of the NAND flash memory 187a, specifically, the MPU181 after the system reset is released. At least a first program storage area 187d1 is provided to store a part of the boot program to be executed.

The boot program is a control program for activating the display control device 81 so that various controls for the auxiliary effect unit can be executed, and the MPU 181 first executes this boot program after the system reset is released. As a result, various controls can be executed in the display control device 81. The first program storage area 187d1 should be processed first by the MPU 181 after the system reset is released within the capacity range of one bank of the buffer RAM 187c (that is, one page of the NAND flash memory 187a) in this boot program. A predetermined number of instructions (for example, if the capacity of one page is 2 kilobytes, 1024 words (1 word = 2 bytes) worth of instructions) are stored from the instructions. The number of boot program instructions stored in the first program storage area 187d1 may be less than or equal to the capacity of one bank of the buffer RAM 187c, and is appropriately set according to the specifications of the display control device 81. There may be. Further, as long as the entire boot program is equal to or less than the capacity of the buffer RAM 187c, the entire boot program may be stored in the buffer RAM 187c.

When the system reset is released, the MPU 181 is configured to set the value of the instruction pointer 181a to "0000H" by hardware and to specify the address "0000H" indicated by the instruction pointer 181a to the internal bus. Has been done. On the other hand, when the ROM controller 187b of the character ROM 187 detects that the address "0000H" is specified in the internal bus, the boot program stored in the first program storage area 187d1 of the NOR type ROM 187d is stored in one bank of the buffer RAM 187c. Set and output the corresponding data (command code) to MPU181.

When the MPU181 fetches the instruction code received from the character ROM 187, it executes various processes according to the fetched instruction code, adds only one instruction pointer 181a, and assigns the address indicated by the instruction pointer 181a to the internal bus. specify. Then, while the address specified by the internal bus is the address indicating the program stored in the NOR type ROM 187d, the ROM controller 187b of the character ROM 187 is selected from the programs previously set in the buffer RAM 187c from the NOR type ROM 187d. The instruction code of the corresponding address is read from the buffer RAM 187c and output to the MPU 181.

Here, in the present embodiment, instead of storing all the control programs in the NAND flash memory 187a, among the boot programs, a predetermined number of instructions from the instructions to be processed first by the MPU 181 after the system reset is released are NOR type ROM 187d. It is stored in for the following reasons. That is, as described above, the NAND flash memory 187a is peculiar to the NAND flash memory that it takes a long time from the designation of the address to the output of the data in reading the data on the first page. There's a problem.

When all the control programs are stored in such a NAND flash memory 187a, the address "0000H" is specified from the MPU 181 via the internal bus in order to fetch the instruction code to be executed first by the MPU 181 after the system reset is released. In this case, the character ROM 187 must read the data for one page including the data (instruction code) corresponding to the address "0000H" from the NAND flash memory 187a and set it in the buffer RAM 187c. Due to the nature of the NAND flash memory 187a, it takes a lot of time to set the buffer RAM 187c from the read, so the MPU181 specifies the address "0000H" and then the instruction corresponding to the address "0000H". It consumes a lot of waiting time to receive the code. Therefore, it takes a long time to start the MPU 181. As a result, there is a problem that the control of the auxiliary effect unit in the display control device 81 may not be started immediately.

On the other hand, since the NOR type ROM is a memory capable of reading data at high speed, a predetermined number of instructions from the instruction to be processed first by the MPU 181 after the system reset is released are stored in the NOR type ROM 187d among the boot programs. By doing so, when the address "0000H" is specified from the MPU181 via the internal bus after the system reset is released, the character ROM 187 immediately transfers the boot program stored in the first program storage area 187d1 of the NOR type ROM 187d to the buffer RAM 187c. It can be set and the corresponding data (instruction code) can be output to the MPU181. Therefore, the MPU 181 can receive the instruction code corresponding to the address "0000H" in a short time after designating the address "0000H", and can start the MPU 181 in a short time. Therefore, even if the control program is stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the control of the auxiliary effect unit in the display control device 81 can be started immediately.

The boot program includes a control program stored in the second program storage area 187a1 of the NAND flash memory 187a, that is, a control program excluding the boot program stored in the first program storage area 187d1 of the NOR type ROM 187d. , A predetermined amount of fixed value data (for example, a display data table, a transfer data table, etc., which will be described later) for driving the upper lamp 63, the auxiliary display unit 65, etc. (for example, the capacity for one page of the NAND flash memory 187a). ) Are programmed to be transferred to the program storage area 185c of the work RAM 185 one by one. Then, in the MPU181, first, the boot program in the first program storage area 187d1 sets the control program stored in the second program storage area 187a1 according to the boot program read from the first program storage area 187d1 after the system reset is released. While using a bank different from the bank of the buffer RAM 187c, a predetermined amount is transferred to and stored in the program storage area 185c.

Here, since the boot program stored in the first program storage area 187d1 has a capacity corresponding to one bank of the buffer RAM 187c as described above, the address of the internal bus is designated as "0000H". When the boot program of the first program storage area 187d1 is set in the buffer RAM 187c in response to the above, the boot program is set in only one bank of the buffer RAM 187c. Therefore, when transferring the control program stored in the second program storage area 187a1 to the program storage area 185c according to the boot program of the first program storage area 187d1, the first program set in one bank of the buffer RAM 187c. The transfer process can be executed using the other bank while leaving the boot program in the storage area 187d1. Therefore, since it is not necessary to reset the boot program in the first program storage area 187d1 to the buffer RAM 434c after the transfer process, the time required for the boot process can be shortened.

When the boot program stored in the first program storage area 187d1 transfers the control program stored in the second program storage area 187a1 to the program storage area 185c by a predetermined amount, the instruction pointer 181a is transferred to the program storage area 185c. It is programmed to set to the first predetermined address. As a result, after the system reset is released, when the control program stored in the second program storage area 187a1 is transferred to the program storage area 185c by a predetermined amount by the MPU 181, the instruction pointer 181a is transferred to the first predetermined program storage area 185c. Set to the address.

Therefore, when a predetermined amount of the control programs stored in the second program storage area 187a1 are stored in the program storage area 185c, the MPU 181 reads the control program stored in the program storage area 185c and reads the control program. Various processes can be executed. That is, the MPU 181 does not read the control program from the NAND flash memory 187a having the second program storage area 187a1 and fetch the instructions, but reads the control program transferred to the work RAM 185 having the program storage area 185c and fetches the instructions. Then, various processes will be executed. As described above, since the work RAM 185 is composed of the DRAM, the read operation is performed at high speed. Therefore, even when the control program is stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the MPU 181 can fetch the instruction at high speed and execute the processing for the instruction.

Here, the control program stored in the second program storage area 187a1 includes the remaining boot programs that are not stored in the first program storage area 187d1. On the other hand, the boot program stored in the first program storage area 187d1 has the remaining boot programs in the control program transferred from the second program storage area 187a1 by a predetermined amount to the program storage area 185c of the work RAM 185. It is programmed to be included, and the instruction pointer 181a is programmed so that the start address of the remaining boot program stored in the program storage area 185c is set as the first predetermined address.

As a result, the MPU 181 transfers the control program stored in the second program storage area 187a1 to the program storage area 185c by a predetermined amount by the boot program stored in the first program storage area 187d1, and then transfers the control program. Run the rest of the boot program contained in the control program.

In this remaining boot program, the remaining control programs that have not been transferred to the program storage area 185c and the fixed value data for driving the upper lamp 63, the auxiliary display unit 65, etc. are all located from the second program storage area 187a1. The process of transferring the fixed amount to the program storage area 185c is executed. Further, at the end of the boot program, the instruction pointer 181a is set to the second predetermined address in the program storage area 185c. Specifically, as this second predetermined address, the initialization process (see S702 in FIG. 21) stored in the program storage area 185c and executed after the boot process by the boot program (see S701 in FIG. 21) is completed. Set the start address of the program corresponding to.

By executing the remaining boot program, the MPU181 transfers all the control programs and fixed value data stored in the second program storage area 187a1 to the program storage area 185c. Then, when the boot program is executed to the end by the MPU181, the instruction pointer 181a is set to the second predetermined address, and thereafter, the MPU181 is transferred to the program storage area 185c without referring to the NAND flash memory 187a. Various processes are executed using the control program.

Therefore, even when the control program is stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the control program can be transferred to the program storage area 185c of the work RAM 185 after the system reset is released. , MPU181 can read a control program from a work RAM composed of a DRAM having a high read speed and perform various controls, so that high processing performance can be maintained in the display control device 81, and an auxiliary effect unit is used. Therefore, it is possible to easily carry out diversified and complicated productions.

Further, as described above, instead of storing all the boot programs in the NOR type ROM 187d, a predetermined number of instructions are stored from the instruction to be processed first by the MPU 181 after the system reset is released, and the remaining boot programs are stored. Even if the program is stored in the second program storage area 187a2 of the NAND flash memory 187a, the control program stored in the second program storage area 187a1 can be reliably transferred to the program storage area 185c. Therefore, the character ROM 187 can start the MPU 181 in a short time only by adding an extremely small capacity NOR type ROM 187d, so that the cost increase of the character ROM 187 due to the shortening of the time can be suppressed. Can be done.

The image controller 188 is a digital signal processor (DSP) that draws an image and displays the drawn image on the auxiliary display unit 65 at a predetermined timing, and is connected to the MPU 181 via an internal bus. The image controller 188 draws an image for one frame based on the drawing list (see FIG. 14) described later transmitted from the MPU 181, and draws one frame of the first frame buffer 190b and the second frame buffer 190c described later. The image drawn in the buffer is expanded, and the image information for one frame previously expanded in the other frame buffer is output to the auxiliary display unit 65, so that the auxiliary display unit 65 displays the image. The image controller 188 performs the image drawing process for one frame and the image display process for one frame within the image display time for one frame (20 milliseconds in this embodiment) in the auxiliary display unit 65. Process in parallel with.

The image controller 188 transmits a vertical synchronization interrupt signal (hereinafter referred to as “V interrupt signal”) to the MPU 181 every 20 milliseconds when the image drawing process for one frame is completed. Each time the MPU181 detects this V interrupt signal, it executes a V interrupt process (see FIG. 23A) and instructs the image controller 188 to draw an image for the next frame. In response to this instruction, the image controller 188 executes a process of drawing an image for the next frame, and also executes a process of displaying the image previously developed by drawing on the auxiliary display unit 65.

In this way, the MPU 181 executes the V interrupt process in accordance with the V interrupt signal from the image controller 188, and gives a drawing instruction to the image controller 188. Therefore, the image controller 188 draws and displays an image. An image drawing instruction can be received from the MPU 181 at each processing interval (20 milliseconds). Therefore, in the image controller 188, since the drawing instruction of the next image is not received at the stage where the drawing processing and the display processing of the image are not completed, the drawing of a new image may be started in the middle of drawing the image. It is possible to prevent the image from being expanded in accordance with a new drawing instruction in the frame buffer in which the image information being displayed is stored.

The image controller 188 also executes a process of transferring image data from the character ROM 187 to the resident video RAM 189 or the normal video RAM 190 based on the transfer instruction from the MPU 181 and the transfer data information included in the drawing list. The image is drawn using the image data stored in the resident video RAM 189 and the normal video RAM 190. That is, the image data required for drawing is transferred from the character ROM 187 to the resident video RAM 189 or the normal video RAM 190 based on the instruction from the MPU 181 before the drawing is performed.

Here, the NAND flash memory facilitates a large capacity of the ROM, but the read speed is slower than that of other ROMs (mask ROM, EEPROM, etc.). On the other hand, in the display control device 81, the MPU 181 instructs the image controller 188 to transfer a part of the image data stored in the character ROM 187 to the resident video RAM 189 after the power is turned on. It is configured to do. Then, as will be described later, the image data stored in the resident video RAM 189 is controlled so as to be resident without being overwritten.

As a result, after the transfer of the image data to be resident in the resident video RAM 189 is completed after the power is turned on, the image is drawn by the image controller 188 while using the image data resident in the resident video RAM 189. Processing can be performed. Therefore, if the image data used for the drawing process is resident in the resident video RAM 189, it is not necessary to read the corresponding image data from the character ROM 187 configured by the NAND flash memory 187a having a slow read speed at the time of image drawing. The time required for reading the data can be omitted, and the image can be drawn immediately and the drawn image can be displayed on the auxiliary display unit 65.

In particular, since the resident video RAM 189 is resident with image data of images that are frequently displayed and image data of images that should be displayed immediately after the display is determined by the main control device 310 or the display control device 81. Even if the character ROM 187 is composed of the NAND flash memory 187a, the responsiveness until some image is displayed on the auxiliary display unit 65 can be kept high.

Further, when drawing an image using non-resident image data in the resident video RAM 189, the display control device 81 is required for drawing from the character ROM 187 to the normal video RAM 190 before the drawing is performed. The MPU 181 is configured to instruct the image controller 188 to transfer the image data. As will be described later, the image data transferred to the normal video RAM 190 may be deleted by overwriting after being used for drawing an image, but at the time of drawing an image, the NAND flash memory 187a has a slow read speed. Since it is not necessary to read the corresponding image data from the character ROM 187 configured by the above and the time required for the reading can be omitted, the image can be drawn immediately and the drawn image can be displayed on the auxiliary display unit 65.

Further, by storing the image data in the normal video RAM 190, it is not necessary to make all the image data resident in the resident video RAM 189, so that it is not necessary to prepare a large-capacity resident video RAM 189. Therefore, it is possible to suppress an increase in cost due to the provision of the resident video RAM 189.

The image controller 188 has a buffer RAM 188a composed of 132 kilobytes of SRAM, which is the capacity of one block of the NAND flash memory 187a. Further, the image data transfer instruction given by the MPU 181 to the image controller 188 includes a start address (storage source start address) and a final address (storage source final address) of the character ROM 187 in which the image data to be transferred is stored. Information on the transfer destination (information indicating whether to transfer to the resident video RAM 189 or the normal video RAM 190) and the start address of the transfer destination (resident video RAM 189 or the normal video RAM 190) are included. The data size of the image data to be transferred may be included instead of the final address of the storage source.

The image controller 188 reads data for one block from a predetermined address of the character ROM 187 and temporarily stores the data in the buffer RAM 188a according to various information of the transfer instruction, and when the resident video RAM 189 or the normal video RAM 190 is not used, the buffer RAM 188a The image data stored in is transferred to the resident RAM 189 or the normal video RAM 190. Then, the process is repeatedly executed until all the image data stored in the storage source final address is transferred from the storage source start address indicated by the transfer instruction.

As a result, the image data read from the character ROM 187 over time is temporarily stored in the buffer RAM 188a, and then the image data is transferred from the buffer RAM 188a to the resident video RAM 189 or the normal video RAM 190 in a short time. Can be done. Therefore, while the image data is transferred from the character ROM 187 to the resident video RAM 189 or the normal video RAM 190, the resident video RAM 189 or the normal video RAM 190 is prevented from being occupied for a long time by the transfer of the image data. be able to. Therefore, since the resident video RAM 189 and the normal video RAM 190 are occupied by the transfer of the image data, the video RAMs 189 and 190 cannot be used for the image drawing process, and as a result, the image can be drawn by the required time. , It is possible to prevent the display on the auxiliary display unit 65 from being missed.

Further, since the transfer of the image data from the buffer RAM 188a to the resident video RAM 189 or the normal video RAM 190 is performed by the image controller 188, the resident video RAM 189 and the normal video RAM 190 perform image drawing processing and the auxiliary display unit 65. It is possible to easily determine the period during which the image is not used for the display process, and the process can be simplified.

The resident video RAM 189 is composed of a DRAM having one input / output port (hereinafter referred to as "1 port type"), and the image data transferred from the character ROM 187 is not overwritten during power-on. Used to continue to be retained. As a result, the image data transferred from the character ROM 187 is resident in the resident video RAM 189. In the resident video RAM 189, among the images displayed on the auxiliary display unit 65, the data corresponding to the image displayed when the power is turned on, the data corresponding to the frequently displayed image, and the main control device 101 Alternatively, among the images determined to be displayed by the display control device 81, the data corresponding to the image to be displayed immediately is transferred from the character ROM 187 and is resident.

On the other hand, the normal video RAM 190 is used so that data is overwritten and updated at any time, and is composed of a 1-port type DRAM (Dynamic RAM). When the image controller 188 draws an image to be displayed on the auxiliary display unit 65 using the image data not resident in the resident video RAM 189 in the normal video RAM 190, the image data read from the character ROM 187 in advance. This is for temporarily storing. Further, the image data (drawn image data) drawn by the image controller 188 is alternately stored in the first frame buffer 190b and the second frame buffer 190c provided in the normal video RAM 190, and the image controller 188 is an auxiliary display unit. By transmitting the drawn image data stored in the first frame buffer 190b or the second frame buffer 190c to the auxiliary display unit 65 in accordance with the display timing of the 65, the image corresponding to the drawn image data is displayed on the auxiliary display unit 65. Is displayed.

The resident video RAM 189 is provided with a main image area 189a, a rear image area 189b, a character symbol area 189c, a notification effect image area 189d, and an error message image area 189e when the power is turned on.

The power-on main image area 189a corresponds to the power-on main image displayed on the auxiliary display unit 65 from the time the power is turned on until all the image data to be resident in the resident video RAM 189 is stored. This is the area for storing data. The main image at the time of power-on is a message image for notifying the player and the like that the initialization process accompanying the power-on is being performed, and a message such as "Power-on! Please wait for a while". Is displayed on the auxiliary display unit 65 until the initialization process of the display control device 81 is completed.

In the display control device 81, when the power switch 71 is turned on and power is supplied from the power supply device 91 to the display control device 81, the MPU 181 outputs the image data corresponding to the power-on main image from the character ROM 187 to the power-on main image. A transfer instruction is transmitted to the image controller 188 so as to transfer to the area 189a (see S703 in FIG. 21). The image controller 188 receives the transfer instruction from the MPU 181, reads the data corresponding to the main image at power-on from the character ROM 187, and transfers the data corresponding to the main image at power-on to the main image area 189a at power-on of the resident video RAM 189 via the buffer RAM 188a. ..

When the image data is stored in the main image area 189a at power-on, the simple image display flag 185e described later is turned on (see S705 in FIG. 21), and the image controller 188 stores the image data in the main image area 189a at power-on. The image data is used to control the main image to be displayed on the auxiliary display unit 65 when the power is turned on. Then, while the main image at power-on is displayed on the auxiliary display unit 65, other image data (image data other than the main image at power-on) to be stored in the resident video RAM 189 is read from the character ROM 187. And transferred to the resident video RAM 189. When all the image data to be resident is transferred to the resident video RAM 189, the simple image display flag 185e is turned off (see S827 in FIG. 29 (b)), and the image data resident in the resident video RAM 189 is used. However, the image controller 188 performs drawing processing of various images.

As a result, if the image data used for the drawing process is resident in the resident video RAM 189, it is not necessary to read the corresponding image data from the character ROM 187 configured by the NAND flash memory 187a having a slow read speed at the time of image drawing. Therefore, the time required for reading the data can be omitted, and the image can be drawn immediately and the drawn image can be displayed on the auxiliary display unit 65.

In particular, since the resident video RAM 189 is resident with image data of images that are frequently displayed and image data of images that should be displayed immediately after the display is determined by the main control device 101 or the display control device 81. Even if the character ROM 187 is composed of the NAND flash memory 187a, it is possible to maintain high responsiveness from the operation of the start lever 41 and the stop switches 42 to 44 by the player to the display of some image on the auxiliary display unit 65. can.

Further, in the slot machine 10, since the NAND type flash memory 187a is used for the character ROM 187, all the image data to be stored in the resident video RAM 189 is transmitted from the character ROM 187 due to the slow read speed. It takes a lot of time to be transferred to the resident video RAM 189, but after the power is turned on, the main image at power-on is first transferred from the character ROM 187 to the resident video RAM 189, and the main image at power-on is transferred to the resident video RAM 189. Is displayed on the auxiliary display unit 65, and then the image data to be resident in the remaining resident video RAM 189 is transferred from the character ROM 187 to the resident video RAM 189. Therefore, the remaining image data to be resident is transferred to the resident video RAM 189. While being transferred to, the player or a person involved in the hall can confirm the main image at power-on displayed on the auxiliary display unit 65. Therefore, the display control device 81 may transfer the remaining resident image data from the character ROM 187 to the resident video RAM 189 over time while displaying the main image at power-on on the auxiliary display unit 65. can. On the other hand, the player or the like can recognize that some processing is being performed while the main image is displayed on the auxiliary display unit 65 when the power is turned on, so that the image data to be resident in the remaining resident video RAM 189 can be stored. Until the transfer from the character ROM 187 to the resident video RAM 189, it is possible to wait until the transfer of the image data to the resident video RAM 189 is completed without worrying that the operation has stopped.

Further, even in the operation check in the factory at the time of manufacturing, the main image at the time of turning on the power is immediately displayed on the auxiliary display unit 65, so that the auxiliary display unit 65 is started to operate without any problem by turning on the power. It can be confirmed immediately, and by using the NAND flash memory 187a having a slow read speed for the character ROM 187, it is possible to suppress the deterioration of the operation check efficiency.

The rear image area 189b and the character symbol area 189c are areas for storing image data corresponding to the rear image and the character symbol used in various effects displayed on the auxiliary display unit 65, respectively. Here, the back image is an image displayed on the back side of the main image displayed on the auxiliary display unit 6 such as a character symbol.

The display control device 81 displays a rear image or a character symbol when it is determined that the gaming state of the slot machine 10 shifts to a different gaming state (for example, from a normal state to a bonus state) based on a command received from the main control device 101. It is configured to change the back image and the character symbol when changing or performing various other effects, and it is required that the back image and the character symbol change immediately according to the content of the received command.

On the other hand, in the slot machine 10, after the power is turned on, the display control device 81 displays the image data corresponding to the rear image and the character symbol from the character ROM 187 to the rear image area 189b and the character symbol area 189c of the resident video RAM 189, respectively. Will be transferred in advance to. Then, when the display control device 81 changes the rear image or the character symbol based on the content of the command received from the main control device 101, the display control device 81 does not newly read the corresponding image data from the character ROM 187, but the resident video RAM 189. By reading the image data resident in advance in the rear image area 189b or the character symbol area 189c, the image controller 188 can draw a predetermined image. As a result, it is not necessary to read the corresponding image data from the character ROM 187, so that even if the NAND flash memory 187a having a slow read speed is used for the character ROM 187, the rear image and the character design can be changed immediately.

In the present embodiment, the image data corresponding to all the back images is resident in the back image area 189b. However, the image data corresponding to a part of the back image may be resident. Further, when the image data corresponding to a part of the rear image is resident, at least the data corresponding to the rear image to be displayed immediately corresponding to the reception command from the main control device 101 may be resident. As a result, when a reception command is received from the main control device 101 and the rear image is changed immediately, the image data corresponding to the changed rear image is always resident in the rear image area 189b. An image can be immediately drawn by the image controller 188 using the image data and displayed on the auxiliary display unit 65.

Further, when the rear image is scrolled and displayed with the passage of time, the image data corresponding to the entire scrolled range may be resident in the rear image area 189b, or within a predetermined time from the time when the rear image is changed. The image data corresponding to the scroll range displayed in may be resident in the rear image area 189b. Further, for a predetermined rear image such as a rear image displayed after the power is turned on, image data corresponding to the entire scrolled range is resident in the rear image area 189b, and for another rear image, a predetermined time from the time when the rear image is changed. The image data corresponding to the scroll range displayed inside may be resident in the rear image area 189b. As a result, at least the image data corresponding to the scroll range displayed within a predetermined time from the time when the rear image is changed is resident in the rear image area 189b, so that when changing to the rear image that is scrolled with the passage of time. Even if there is, an image can be immediately drawn by the image controller 188 using the image data resident in the rear image area 189b and displayed on the auxiliary display unit 65.

Further, when changing to a scrolled back image, the display may always start from a fixed initial position as the position of the back image displayed at the time of change. As a result, the image data to be resident in the rear image area 189b can be limited to the image data corresponding to the scroll range displayed within a predetermined time from the fixedly set initial position, and the amount of the data can be reduced. It can be suppressed.

Further, when the image data displayed within a predetermined time from the time when the rear image is changed is resident in the rear image area 189b, the image controller 188 draws the image using the image data resident in the rear image area 189b. While the drawn image is displayed on the auxiliary display unit 65, the remaining image data may be read from the character ROM 187 by the MPU 181 and transferred to the normal video RAM 190.

As a result, while the rear image corresponding to the rear image data resident in the rear image area 189 is displayed on the auxiliary display unit 65, the rear image data not resident in the rear image area 189 is displayed in the normal video RAM 190. When displaying a rear image in a range that is not resident in the rear image area 189, the image controller immediately displays the image using the rear image data already stored in the normal video RAM 190. It can be drawn and displayed on the auxiliary display unit 65. Therefore, it is necessary to read the rear image again from the character ROM 187 at the time of shifting from the display of the rear image in the range resident in the rear image area 189b to the display of the rear image in the range not resident in the rear image area 189b. Therefore, even when the NAND flash memory 187a having a slow read speed is used for the character ROM 187, the back image can be smoothly transferred.

On the other hand, also in the character symbol area 189c, the data corresponding to all the character symbols may be resident, or the data corresponding to some character symbols may be resident. Further, when the data corresponding to a part of the character symbols is resident, at least the data corresponding to the character symbols to be immediately displayed in response to the reception command from the main control device 101 may be resident. As a result, when a reception command is received from the main control device 101 and the character symbol is changed immediately, the image data corresponding to the changed character symbol is always resident in the character symbol area 189c. An image can be immediately drawn by the image controller 188 using the image data and displayed on the auxiliary display unit 65.

The notification effect image area 189d is an area for storing image data corresponding to the notification effect displayed on the auxiliary display unit 65, and the error message image area 189e is when an error occurs in the slot machine 10. This is an area for storing image data corresponding to an error message displayed on the auxiliary display unit 65.

For example, when a game is played with one or two bets, and as a result of a lottery, any one of the BB winning mode, the watermelon winning mode, and the bell winning mode is won as a winning combination, the display control device 81 may use the display control device 81. According to the winning combination, the auxiliary display unit 65 is configured to control so that the BB winning notification effect, the watermelon winning announcement effect, and the bell winning announcement effect are performed (see S763 to S768 in FIG. 26). In this case, the display control device 81 grasps the winning combination by the lottery result command received from the main control device 101, and various notification effects are performed according to the grasped winning combination. It needs to be done before the stop switches 42-44 are operated by the player. In addition, since the lottery of the winning combination is performed after the start lever 41 is operated by the player by the main control device 101, the stop switches 42 to 44 can be operated by the player after the start lever 41 is operated. In an extremely short period of time, the main control device 101 draws a winning combination, and the lottery result command is notified from the main control device 101 to the display control device 81, and then the display control is performed. The corresponding announcement effect must be performed by means 81. In the slot machine 10, image data corresponding to each of the BB winning notification effect, the watermelon winning announcement effect, and the bell winning announcement effect is resident in advance in the image area 189d for the notification effect, so that the display control device 81 is mainly used. When performing a BB prize notification effect, a watermelon prize announcement effect, or a bell prize announcement effect based on the lottery result command received from the control device 101, the corresponding image data is not newly read from the character ROM 187, but a resident video. By reading the image data resident in advance in the notification effect image area 189d of the RAM 189, each notification effect image can be drawn by the image controller 188. As a result, it is not necessary to read the sequentially corresponding image data from the character ROM 187. Therefore, even if the NAND flash memory 187a having a slow read speed is used for the character ROM 187, each notification effect image is stopped after receiving the lottery result command. The switches 42 to 44 can be displayed before they can be operated by the player.

Further, in the slot machine 10, the inserted medals are inserted into the inserted medal sensor device based on the detection results of the inserted medal detection device (first inserted medal detection sensor 45a and second inserted medal detection sensor 45b) by the main control device 101. If it is determined that the medal is jammed or the medal is illegally pulled out during the passage, the main control device 101 notifies the display control device 81 of the occurrence of the sensor error by an error command, as described above. Further, even when the occurrence of other errors is detected by the main control device 101, the main control device 101 notifies the display control device 81 of the occurrence of the error together with the content of the error by the error command. When the display control device 81 receives an error command, the display control device 81 is configured to display an error message corresponding to the received error on the auxiliary display unit 65.

Here, from the viewpoint of preventing fraud of the player and protecting the player against the error, the error message is required to be displayed almost at the same time as the error occurs. In the slot machine 10, the error message image area 189e is used. Since the image data corresponding to various error messages is resident in advance, the display control device 81 newly obtains the image data corresponding to the predetermined error message from the character ROM 187 based on the error command received from the main control device 101. By reading the image data resident in advance in the error message image image area 189e of the resident video RAM 189, the image controller 188 can immediately draw each error message image. As a result, it is not necessary to read the image data corresponding to the sequential error message from the character ROM 187. Therefore, even if the NAND flash memory 187a having a slow read speed is used for the character ROM 187, each error message is received after receiving the error command. It can be displayed immediately.

As described above, the normal video RAM 190 is used so that the data is overwritten and updated at any time, and is provided with at least an image storage area 190a, a first frame buffer 190b, and a second frame buffer 190c.

The image storage area 190a is an area for storing image data that is not resident in the resident video RAM 189 among the image data necessary for drawing the image to be displayed on the auxiliary display unit 65. The image storage area 190a is divided into a plurality of sub-areas, and the type of image data stored in the sub-area is predetermined for each sub-area.

Of the image data that is not resident in the resident video RAM 189, the MPU 181 collects the image data required for subsequent image drawing from the character ROM 187 to the sub-area provided in the image storage area 190a of the normal video RAM 190. , Instruct the image controller 188 to transfer the type of the image data to a predetermined sub-area to be stored. As a result, the image controller 188 reads the image data instructed by the MPU 181 from the character ROM 187, and transfers the read image data to a designated predetermined sub-area of the image storage area 190a via the buffer RAM 188a.

The transfer instruction of the image data is performed by including the transfer data information in the drawing list described later in which the MPU 181 instructs the image controller 188 to draw the image. As a result, the MPU 181 can give an image drawing instruction and an image data transfer instruction only by transmitting the drawing list to the image controller 188, so that the processing load can be reduced.

The first frame buffer 190b and the second frame buffer 190c are buffers for developing an image to be displayed on the auxiliary display unit 65. The image controller 188 writes an image for one frame drawn according to the instruction from the MPU 181 to the frame buffer of either the first frame buffer 190b or the second frame buffer 190c, thereby writing one frame in the frame buffer. While expanding the image and expanding the image in one frame buffer, the image information for one frame previously expanded is read from the other frame buffer, and the image information is read out to the auxiliary display unit 65 together with the drive signal. By transmitting the image information, a process of displaying the image for one frame on the auxiliary display unit 65 is executed.

In this way, by providing two frame buffers, the first frame buffer 190b and the second frame buffer 190c, the image controller 188 expands the image for one frame drawn in one frame buffer and simultaneously expands the image. The image for one frame previously expanded can be read from the other frame buffer, and the image for the read one frame can be displayed on the auxiliary display unit 65.

Then, the frame buffer for expanding the image for one frame and the frame buffer for reading the image information for one frame in order to display the image on the auxiliary display unit 65 complete the drawing process for the image for one frame. Every 20 milliseconds, the MPU 181 alternately specifies one of the first frame buffers 190b and the second frame buffer 190c, respectively.

That is, at a certain timing, the first frame buffer 190b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 190c is designated as the frame buffer for reading the image information for one frame. When the drawing process and the display process are executed, the second frame buffer 190c is designated as the frame buffer for expanding the image for one frame 20 milliseconds after the drawing process for the image for one frame is completed, and the image for one frame is expanded. The first frame buffer 190b is designated as the frame buffer from which the image information of the above is read. As a result, the image information of the image previously expanded in the first frame buffer 190b can be read out and displayed on the auxiliary display unit 65, and at the same time, a new image is expanded in the second frame buffer 190c.

Then, after the next 20 milliseconds, the first frame buffer 190b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 190c is designated as the frame buffer for reading the image information for one frame. Will be done. As a result, the image information of the image previously expanded in the second frame buffer 190b can be read out and displayed on the auxiliary display unit 65, and at the same time, a new image is expanded in the first frame buffer 190c. After that, one of the first frame buffer 190b and the second frame buffer 190c is used every 20 milliseconds for the frame buffer that expands the image for one frame and the frame buffer for reading the image information for one frame. By alternately specifying the images, it is possible to continuously perform the display processing of the image for one frame in units of 20 milliseconds while performing the drawing processing of the image for one frame.

As described above, the image controller 188 is provided with the buffer RAM 188a. The buffer RAM 188a functions as a buffer memory for data transfer from the character ROM 187 to the resident video RAM 189 or the normal video RAM 190, and has a storage capacity of one block of the NAND flash memory 187a provided in the character ROM 187 (for example, 132). It is composed of an SRAM (Static RAM) having a kilobyte).

When the image controller 188 transfers image data from the character ROM 187 to the normal video RAM 189 or the normal video RAM 190, the image controller 188 reads one block of data from the character ROM 187 and temporarily stores the data in the buffer RAM 188a, and the resident video RAM 189 or the normal video RAM 189 or the normal. The image data stored in the buffer RAM 188a is transferred to the resident RAM 189 or the normal video RAM 190 in anticipation of when the video RAM 190 is not in use.

If the image data is directly transferred from the character ROM 187 to the resident video RAM 189 or the normal video RAM 190 without providing the buffer RAM 188, the read speed of the character ROM 187 is slow because it is composed of the NAND flash memory 187a. Therefore, while the image data of the desired size is transferred, the resident video RAM 189 or the normal video RAM 190 composed of the 1-port type DRAM occupies one port of the image data transfer from the character ROM 187, which is long. Time and other data access will not be possible. As a result, during that time, the image controller 188 cannot read image data from the resident video RAM 189 or the normal video RAM 190 to draw an image, or transfer the drawn image data to the auxiliary display unit 65. The image display of the auxiliary display unit 65 may be delayed. Further, even when a multi-port type (a type in which a plurality of input / output ports are provided) DRAM is used for the resident video RAM 189 or the normal video RAM 190, one port is occupied by the image data transfer from the character ROM 187. Therefore, the control using the resident video RAM 189 and the normal video RAM 190 in the image controller 188 is limited, and the control may be complicated.

On the other hand, since the slot machine 10 is provided with the buffer RAM 188a configured by the SRAM capable of high-speed operation in the image controller 188, the image data read from the character ROM 187 over time is once stored in the buffer RAM 188a. After storing, the image data can be transferred from the buffer RAM 188a to the resident video RAM 189 or the normal video RAM 190 in a short time. Therefore, while the image data is transferred from the character ROM 187 to the resident video RAM 189 or the normal video RAM 190, the resident video RAM 189 or the normal video RAM 190 is prevented from being occupied for a long time by the transfer of the image data. be able to.

The image displayed on the auxiliary display unit 65 is periodically displayed at regular time intervals (every 20 milliseconds in the present embodiment), and the image controller 188 displays the image on the auxiliary display unit 65. Image drawing and drawing image data must be transferred to the auxiliary display unit 65 in accordance with the display timing. Therefore, for access to the resident video RAM 189 and the normal video RAM 190, it is necessary to prioritize the reading of the image data necessary for drawing and the writing and reading of the drawn image data.

Here, with reference to FIG. 11, the display timing of the image in the auxiliary display unit 65 will be described. FIG. 11 is a schematic diagram schematically showing a scanning area of a screen included in the auxiliary display unit 65 and a display area in which an image is actually displayed on the screen. As shown in FIG. 11, an area larger than the display area where the image is actually displayed is set as the scanning area, and when the image is displayed on the screen of the auxiliary display unit 65, the scanning area is covered by the scanning area. Scanning is performed while driving each pixel constituting the screen (so-called raster scan) from left to right and from top to bottom toward the screen. At this time, since the drawn image data is actually set only in the display area where the image is displayed, the period during which the image is scanned on the blank area, which is a scanning area other than the display area (so-called blank period), is , The image controller 188 does not transfer the drawn image data to the auxiliary display unit 65. That is, during the blank period, even when displaying an image by scanning the auxiliary display unit 65, it is not possible to draw an image using the image data stored in the resident video RAM 189 or the normal video RAM 190. Therefore, the drawn image data stored in the normal video RAM 190 is not read out and transferred to the auxiliary display unit 65. Therefore, since there is always a period during which the resident video RAM 189 and the normal video RAM 190 are unused during this blank period, the transfer from the buffer RAM 188a to the resident video RAM 189 or the normal video RAM 190 is performed. By utilizing the unused period of each video RAM 189, 190 generated in this blank period, it can be surely performed.

The work RAM 185 is configured by the DRAM as described above, and has a command buffer area 185a, a bet number storage area 185b, a program storage area 185c, a data table storage area 185d, a simple image display flag 185e, a display data table buffer 185f, and a transfer data table. At least a buffer 185 g, a pointer 185 h, a drawing list area 185i, a stored image discrimination flag 185j, and a drawing target buffer flag 185k are provided.

The command buffer area 185a is an area for temporarily storing various commands transmitted from the main control device 101. When the display control device 81 receives the command transmitted from the main control device 101, the display control device 81 latches the received command by the signal latch circuit 182 and generates a command interruption signal toward the MPU 181. The MPU 181 executes a command interrupt process (see FIG. 23 (a)) triggered by the generation of a command interrupt signal, and stores the command latched by the signal latch circuit 182 in the command buffer area 185a.

The command buffer area 185a is configured to operate as a FIFA (First In First Out) type ring buffer, and is executed by the MPU 181 for each time required to display an image for one frame of the auxiliary display unit 65. When the command received from the main control device 101 is stored in the command buffer area 185a by the command which is one of the processes, the commands are read out in the order in which they are stored, and the process corresponding to each command (for example, FIG. 25). The state command processing shown in (a), the start command processing shown in FIG. 25 (b), the lottery result command processing shown in FIG. 26, the payout determination result command processing shown in FIG. 27 (a), and the error shown in FIG. 27 (b). Command processing, etc.) is executed.

The bet number storage area 185b is an area for storing information regarding the number of medals (number of bets) inserted at the start of the game. In the slot machine 10, when a specified number of medals are inserted and the start lever 41 is operated by the player, the number of inserted medals (number of bets) by the normal process executed by the MPU 102 of the main control device 101. A start command containing information about the above is set (see S209 in FIG. 16), and the start command is transmitted from the main controller 101 to the display controller 81 by the timer interrupt process executed by the MPU 102 of the main controller 101 (see S209 in FIG. 16). See S110 in FIG. 15). Upon receiving this start command, the display control device 81 grasps that the start lever 41 has been operated to generate the game start command, and executes the start command process (see FIG. 25B). Information about the number of bets included in the start command is extracted and the information is stored in the bet number storage area 185b. In the bet number storage area 185b, the information regarding the number of bets included in the start command may be stored as it is, or the information regarding the number of bets may be stored in a format different from the information regarding the number of bets included in the start command. It may be stored.

The display control device 81 grasps the number of medals (the number of bets) inserted at the start of the game based on the information stored in the bet number storage area 185b, and causes the auxiliary production unit to execute the medals based on the number of bets. Control the production mode of the production. For example, when it is determined that the game has started with the number of bets being 3, based on the information stored in the bet number storage area 185b, the display control device 81 has various commands received from the main control device 101. The production mode is selected based on the game state of the slot machine 10 determined by the above and the result of the lottery (judgment of winning / failing of the winning mode) performed based on the start command, and the auxiliary production unit is made to execute various effects (FIG. 26). See S762).

Among the effects corresponding to the number of bets of 3, as the effect to be executed when the lottery based on the start command is performed, for example, as a normal game effect, a character performing a predetermined operation is displayed on the auxiliary display unit 65. "Normal game production" to be displayed, "BB winning challenge production" that displays the message "Challenge to BB winning!" On the auxiliary display unit 65 and urges the player to arrange the stop symbols corresponding to the BB winning mode. The message "BB winning prize!" Is displayed on the auxiliary display unit 65, and the BB winning mode is set as the winning combination along with the lighting of the upper lamp 63 and the audio output from the speaker 64. The lottery (win / fail judgment) grasped by the value of the random number counter (not shown) prepared in the display control device 81 and the lottery result command to be described later received from the main control device 101, which includes "effect" and the like. As a result, according to the gaming state of the slot machine 10 grasped by the state command to be described later received from the main control device 101, the effect mode to be executed by the auxiliary effect unit is determined from among those effects.

On the other hand, if it is determined that the game has started with the number of bets being one or two, the game is executed by the auxiliary production unit based on the result of the lottery performed based on the generation of the start command by the main control device 101. Select the production mode of the production to be made. For example, it is determined that the number of bets is one, and the cherry bell winning mode, the 7 bell winning mode, or the replay winning mode is won by the lottery result command received from the main control device 101, or which winning mode is selected. If it is determined that the user has not won the prize, the display control device 81 displays the message "Challenge the cherry bell 7 bell!" On the auxiliary display unit 65, and outputs a dedicated voice from the speaker 64. The auxiliary effect unit is controlled so as to execute the "cherry bell winning / 7 bell winning challenge effect" in which the upper lamp 63 is turned on in a dedicated manner (see S771 in FIG. 26). Further, it is determined that the number of bets is 2, and the cherry bell winning mode or the replay winning mode is won by the lottery result command received from the main control device 101, or neither winning mode is won. If it is determined that the display control device 81 displays the message "Challenge the cherry bell!" On the auxiliary display unit 65, the speaker 64 outputs a dedicated voice, and the upper lamp 63 is set in a dedicated mode. The auxiliary production unit is controlled so as to execute the “cherry bell winning challenge effect” to be turned on (see S770 in FIG. 26).

If the game is played with one medal, the expectation that three or two medals will be paid out by the establishment of one cherry bell winning or seven bell winning mode by "cherry bell winning / seven bell winning challenge production". Can be strongly held by the player. In addition, when the game is played with two medals, the "cherry bell winning challenge production" can give the player a strong expectation that three medals will be paid out when the cherry bell winning mode is established. .. Therefore, since the player can play the game by playing one or two medals while having fun, the player can be strongly reminded that he wants to play the game to the end without leaving any extra medals.

The "cherry bell winning / 7 bell winning challenge effect" and the "cherry bell winning challenge effect" may be an effect mode performed in at least one of the upper lamp 63, the speaker 64, and the auxiliary display unit 65. .. In addition to these, a lamp is provided on the game panel 25, and for example, in the case of one piece, the lamp is lit in red, and in the case of two pieces, the lamp is lit in blue. May be configured to be executed.

If it is determined that the number of bets is one or two, and the lottery result command received from the main control device 101 determines that the BB winning mode has been won, the display control device 81 will use the BB. As an effect of notifying the player that the winning mode has been set as a winning combination, a "BB winning notification effect" for displaying the message "BB winning winning!" Is executed on the auxiliary display unit 65 (see S764 in FIG. 26). ), If it is determined that the watermelon winning mode has been won, the display control device 81 notifies the player that the watermelon winning mode has been set as the winning combination, and the auxiliary display unit 65 has "watermelon winning mode". If the "watermelon winning notification effect" for displaying the message "Winning!" Is executed (see S766 in FIG. 26) and it is determined that the bell winning mode is won, the display control device 81 wins the bell winning mode. As an effect of notifying the player that the combination has been set, a "bell prize announcement effect" for displaying the message "bell prize winning!" Is executed on the auxiliary display unit 65 (see S768 in FIG. 26).

Here, when the player starts the game with one or two cards, that is, when the number of bets is one or two, the lottery tables shown in FIGS. 9 (b) and 9 (c) are used for BB. While the winning probability of the winning mode, the watermelon winning mode, and the bell winning mode is kept extremely low, the winning probability of the cherry bell winning mode and the 7 bell winning mode is set high, so that the player can use the BB winning mode. There is a possibility that the game is played with the expectation that the watermelon winning mode and the bell winning mode will be established, and conversely, the cherry bell winning mode and the 7 bell winning mode will be established. In addition, in this slot machine 10, the cherry bell winning mode and the 7 bell winning mode are effective in the corresponding stop symbol without missing even if the stop switches 42 to 44 are operated at any timing once they are won as winning combinations. Since it is configured to stop on the line, the player who started the game by hanging one or two cards is attached to each reel 32L, 32M, 32R displayed on the display windows 26L, 26M, 26R. There is a possibility of operating the stop switches 42 to 44 without looking at the design.

Therefore, when the game is played with one or two cards, even if any one of the BB winning mode, the watermelon winning mode, and the bell winning mode is won as a winning combination, if the player does not notice it, Since the BB winning mode, the watermelon winning mode, and the bell winning mode are all winning modes that may be missed, there is a risk that the establishment of the BB winning mode and the like may be missed. Further, the winning of the BB winning mode is valid across the games until the BB winning mode is established (that is, until the stop symbols corresponding to the BB winning mode are aligned on the effective line), so that the player can BB. If the game ends without noticing the winning of the winning mode, another player establishes the BB winning mode based on the winning of the BB winning mode, and the player who has assigned the winning of the BB winning mode As a result, there is a risk of loss.

On the other hand, in the slot machine 10, when a game is played with one or two cards, if any one of the BB winning mode, the watermelon winning mode, and the bell winning mode is won in the game, the slot machine 10 is used. Winning is announced by the display of the auxiliary display unit 65. Then, the notification is made while the stop switches 42 to 44 cannot be operated by the player, as will be described later with reference to FIG. Therefore, the player can know the winning of any of the BB winning mode, the watermelon winning mode, and the bell winning mode before operating the stop switches 42 to 44. Therefore, when the player plays the game with one or two cards, if this notification is made by the auxiliary display unit 65, the winning combination (BB winning mode, watermelon winning mode, or bell winning mode) grasped by the notification is performed. Since the stop switches 42 to 44 can be operated aiming at the stop symbol in order to stop the stop symbol corresponding to the mode) on the effective line, those winning modes can be established with a higher probability. In addition, if the winning of the BB winning mode is announced, the player may receive a new medal loan and continue the game until the BB winning mode is established, even if the game is missed. can.

In addition, as a production mode of the effect executed when the payout judgment is made based on the stop of all reels, the winning combination is established, that is, the symbol corresponding to the winning combination won in the lottery is on the effective line. Includes a "winning establishment effect" that notifies that the payout will be made, and a "outside effect" that notifies that the payout will not be made due to a loss. When the display control device 81 receives the payout determination result command, the payout determination result grasped by the payout determination result command, the value of the random number counter (not shown) prepared in the display control device 81, and the main. Depending on the gaming state of the slot machine 10 grasped by the state command described later received from the control device 101, the effect mode to be executed by the auxiliary effect unit is determined from among those effect modes.

The above notification may be made by lighting the upper lamp 63 or outputting voice from the speaker 64, and may be performed by two or more types of display of the auxiliary display unit 65, lighting of the upper lamp 63, and voice output from the speaker 64. It may be done by a combination. Further, a lamp dedicated to notification may be provided on the game panel 25, and a notification effect corresponding to each winning combination may be performed depending on the lighting color of the lamp.

The program storage area 185c is an area for storing the control program executed by the MPU 181. When the system reset is released, the MPU 181 reads the control program from the character ROM 187, transfers it to the work RAM 185, and stores it in the program storage area 185c. Then, when all the control programs are stored in the program storage area 185c, the MPU 181 subsequently executes various controls using the control programs stored in the program storage area 185c. As described above, since the work RAM 185 is composed of the DRAM, the read operation is performed at high speed. Therefore, even when the control program is stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the display control device 81 can maintain high processing performance, and the auxiliary effect unit is used. , Diversified and complicated production can be easily executed.

The data table storage area 185d describes the display content (drawing content) to be displayed on the auxiliary display unit 65 with the passage of time, and is displayed on the auxiliary display unit 65 based on a command or the like from the main control device 101. Of the display data tables prepared for each effect mode and the image data prepared for each display data table and used for display (drawing) by the display data table, they are not resident in the resident video RAM 189. This area stores transfer data information for transferring image data from the character ROM 187 to the normal video RAM 190, and a transfer data table that defines the transfer timing.

These data tables are stored in the NAND flash memory 187a of the character ROM 187 together with the control program as a kind of fixed value data, and after the system reset is released, these data tables are transferred from the character ROM 187 to the work RAM 185, and this data is transferred. It is stored in the table storage area 185d. Then, when all the data tables are stored in the data table storage area 185d, the MPU 181 subsequently controls the display of the auxiliary display unit 65 by using the data table stored in the data table storage area 185d. As described above, since the work RAM 185 is composed of the DRAM, the read operation is performed at high speed. Therefore, even when various data tables are stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the display control device 81 can maintain high processing performance, and the auxiliary display unit 65 is used. Therefore, it is possible to easily carry out diversified and complicated productions.

Here, the details of various data tables will be described. First, one display data table is prepared for each effect mode displayed on the auxiliary display unit 65 based on a command from the main control device 81. For example, a normal game effect in a game performed based on the operation of the start lever 41, the above-mentioned notification effect (BB prize announcement effect, watermelon prize announcement effect, etc.) for announcing the winning of a winning combination by lottery, and a challenge effect for various prizes (BB). Display data tables corresponding to the winning challenge production, cherry bell winning challenge production, etc. are prepared respectively. In addition, as a result of the game (result of the number of payouts), a display data table corresponding to the establishment of the winning combination, the "winning establishment effect" for notifying the establishment of the winning combination, or the "outside effect" for notifying the loss, or between the games. A display data table corresponding to the "game start waiting effect" displayed in is also prepared for each effect.

The details of the display data table will be described with reference to FIG. FIG. 12 is a schematic diagram schematically showing an example of a display data table. The display data table corresponds to an address represented by the time (20 milliseconds in this embodiment) in which an image for one frame is displayed on the auxiliary display unit 65 as one unit, and one frame to be displayed at that time. It defines in detail the content (drawing content) of the minute image.

In the drawing content, the type of the display object is specified for each display object (rear image, effect, character, etc. described later) that constitutes the image for one frame, and the type of the display object is specified according to the type of the display object. , Display position coordinates, enlargement ratio, rotation angle, translucency value, α blending information, color information, filter designation information, and other drawing information for causing the third symbol display device 281 to draw a display object are defined. In the following, the display objects constituting the image will be referred to as sprites.

The type of sprite is information for specifying the sprite to be displayed. The display position coordinates are information for specifying the coordinates on the auxiliary display unit 65 on which the sprite should be displayed. The enlargement ratio is information for designating the enlargement ratio with respect to the standard display size preset for the sprite, and the size of the sprite displayed according to the enlargement ratio is specified. If the magnification is greater than 100%, the sprite will be enlarged and displayed, and if the magnification is less than 100%, the sprite will be smaller than the standard size. Is displayed.

The rotation angle is information for specifying the rotation angle when the sprite is rotated and displayed. The translucency value is for specifying the transparency of the entire sprite, and the higher the translucency value, the more the image displayed on the back side of the sprite can be seen through. The α-blending information is information for specifying a known α-blending coefficient used when performing superposition processing with other sprites. The color information is information for designating the color tone of the sprite to be displayed. Then, the filter designation information is information for designating an image filter to be applied to the sprite when drawing the designated sprite.

In the display data table, as the drawing content for one frame specified corresponding to each address, it is used for one back image, an effect that expresses the insertion of light in that image, and various effects such as people, objects, and characters. Drawing information for each sprite, such as the character to be created, is specified for each address. It should be noted that one or a plurality of information regarding the effect and the character is defined according to the content to be displayed in the frame.

The back image is an image displayed on the back side of the main image displayed on the auxiliary display unit 6 such as a character. The display position of the rear image is fixed to the entire screen of the auxiliary display unit 65, and the enlargement ratio, the rotation angle, the translucent value, the α blending information, the color information, and the filter designation information are constant with respect to the passage of time. Therefore, in the variable display data table, only the back type, which is information for specifying the type of the back image, is specified. This back type is information that specifies the type of the back image to be displayed in various effects.

The MPU181 specifies a back image specified by this back type as a drawing target. Further, when displaying the rear image by changing the range to be displayed with the passage of time, for example, when scrolling the rear image with the passage of time, the range of the rear image to be displayed is specified together with the specification of the type of the rear image. Is specified over time.

In this embodiment, a case where only the back type is specified as the drawing content of the back image in the display data table will be described. Instead, the back type and the range of the back image corresponding to the back type are described. It may be specified as the position information indicating whether or not the display should be performed. This position information may be, for example, information indicating the elapsed time since the rear image of the range corresponding to the initial position is displayed. In this case, the MPU 181 specifies the range of the back image to be displayed for the frame based on the elapsed time from the display of the back image of the range corresponding to the initial position indicated by the position information.

Further, the position information may be information indicating the elapsed time from the start of drawing the image (or the display of the auxiliary display unit 65) based on this display data table. In this case, the MPU 431 displays the range of the rear image to be displayed for the frame at the stage when the drawing of the image (or the display of the auxiliary display unit 65) is started based on the display database. Is specified based on the position of the image and the elapsed time from the start of drawing (or the display of the auxiliary display unit 65) of the image indicated by the position information.

Further, the position information is information indicating the elapsed time from the display of the rear image in the range corresponding to the initial position and the drawing of the image based on the display data table (or the display of the auxiliary display unit 65) according to the rear type. ) May indicate any of the information indicating the elapsed time from the start, and the back image of the position information (for example, the back image of the range corresponding to the initial position) together with the back type and the position information. Information indicating whether the information indicates the elapsed time since the display of the image, or the information indicating the elapsed time since the drawing of the image based on the display database (or the display of the auxiliary display unit 65) is started. ) May be specified as the drawing content of the rear image. In addition, the position information may not be information indicating the elapsed time, but may be information indicating an address in which the range of the rear image to be displayed is stored.

"Start" information indicating the start of the data table is described in "0000H" which is the start address of the display data table, and the data table is described in the final address of the display data table ("02F0H" in the example of FIG. 12). "End" information indicating the end of is described. Then, for each address between the address "0000H" in which the "Start" information is described and the address in which the "End" information is described, the drawing content corresponding to the effect mode to be specified in the display data table is obtained. Is described.

The MPU 181 selects a display data table to be used in response to a command from the main control device 101 (for example, a lottery result command or a payout determination result command), and reads the selected display data table from the data table storage area 185d. , Stores in the display data table buffer 185f and initializes the pointer 185h. Then, 185h is added by 1 each time the drawing process for one frame is completed, and in the display data table stored in the display data table buffer 185f, drawing is performed next based on the drawing content defined by the address indicated by the pointer 185h. The image content to be specified is specified, and a drawing list (see FIG. 14) described later is created. By transmitting this drawing list to the image controller 188, the drawing instruction of the image is given. As a result, the drawing contents are specified in the order specified in the display data table according to the update of the pointer 185h, so that the image as specified in the display data table is displayed on the auxiliary display unit 65.

As described above, in the slot machine 10, in the display control device 81, the program to be executed by the MPU 181 is changed according to the command from the main control device 101 (for example, the lottery result command or the payout determination result command). Instead, the effect image to be displayed on the auxiliary display unit 65 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 185d.

Here, when the program executed by the MPU 181 is started every time the effect image displayed on the display control device 81 is changed as in the conventional slot machine, it becomes complicated due to the diversification of the effect images. In addition, since a large load is applied to the processing of starting and executing the enormous program, the processing capacity of the display control device 81 is limited, and there is a possibility that the diversification of controllable production images is limited. .. On the other hand, in the slot machine 10, the display control device can change the effect image to be displayed on the auxiliary display unit 65 by a simple operation of appropriately replacing the display data table with the display data table buffer 185f. Regardless of the processing capacity of 81, various types of effect images can be displayed on the auxiliary display unit 65.

Further, in this way, a display data table is prepared corresponding to each effect mode, a display data table corresponding to the effect mode to be displayed is set in the display data table buffer 185f, and the set data table is followed. In the slot machine 10, the drawing list can be created frame by frame, and the effect to be displayed on the auxiliary display unit 65 is determined in advance based on the result of the lottery performed in response to the operation of the start lever 41. Because. On the other hand, in a game machine other than a game machine such as a slot machine 10, the display content changes on the spot based on the user's operation, so that the display content cannot be predicted. Therefore, as described above. It is not possible to have a display data table corresponding to each effect mode. In this way, a display data table is prepared corresponding to each effect mode, a display data table corresponding to the effect mode to be displayed is set in the display data table buffer 185f, and the set display data table is followed. The configuration in which the drawing list is created frame by frame is such that the slot machine 10 determines in advance the production mode of the effect to be displayed on the auxiliary display unit 65 based on the result of the lottery performed in response to the operation of the start lever 41. It can only be realized based on.

Next, the details of the transfer data table will be described with reference to FIG. FIG. 13 is a schematic diagram schematically showing an example of a transfer data table. The transfer data table is prepared corresponding to the display data table prepared for each effect, and as described above, among the sprite image data used in the effect specified by the display data table, the transfer data table is prepared. The transfer data information for transferring the image data not resident in the resident video RAM 189 from the character ROM 187 to the image storage area 190a of the normal video RAM 190, and the transfer timing thereof are specified.

If all the sprite image data used in the effect specified in the display data table is stored in the resident video RAM 189, the transfer data table corresponding to the display data table is not prepared. As a result, it is possible to suppress an increase in the capacity of the data table storage area 185d.

The transfer data table corresponds to the address specified in the display data table, and the transfer data information of the sprite image data (hereinafter referred to as "transfer target image data") to start the transfer at the time indicated by the address. Is described (corresponding to the addresses "0001H" and "097H" in FIG. 13). Here, the transfer start timing of the transfer target image data is set so that the image data corresponding to the predetermined sprite is stored in the image storage area 190a by the time the drawing of the predetermined sprite is started according to the display data table. In the transfer data table, the transfer data information of the image data to be transferred is defined in correspondence with the address corresponding to the transfer start timing.

On the other hand, if there is no transfer target image data to start transfer at the time indicated by the address specified in the display data table, there is no transfer target image data to start transfer corresponding to that address. Null data is defined (corresponding to the address "0002H" in FIG. 13).

The transfer data information includes the start address (storage source start address) and final address (storage source final address) of the character ROM 187 in which the transfer target image data is stored, and the start address of the transfer destination (normal video RAM 190). Is included.

As with the display data table, "Start" information indicating the start of the data table is described in "0000H", which is the start address of the transfer data table, and the final address of the transfer data table (in the example of FIG. 13 in the example of FIG. 13). In "02F0H"), "End" information indicating the end of the data table is described. Then, for each address between the address "0000H" in which the "Start" information is described and the address in which the "End" information is described, the transfer data information of the image data to be transferred that should be specified in the transfer data table. Is described.

When the display data table to be used is selected by the MPU 181 according to a command from the main control device 101 (for example, a lottery result command or a payout determination result command), a transfer data table corresponding to the display data table exists. Reads the transfer data table from the data table storage area 185d and stores it in the transfer data table buffer 185 g. Then, each time the pointer 185h is updated, the drawing content defined by the address indicated by the pointer 185h is specified from the display data table stored in the display data table buffer 185f, and a drawing list (see FIG. 14) described later is created. At the same time, the transfer data information of the image data of the predetermined sprite to be transferred at that time is acquired from the transfer data table stored in the transfer data table buffer 185 g, and the transfer data information is created in the drawing list. to add.

For example, in the example of FIG. 13, when the pointer 185h becomes "0001H" or "097H", the MPU181 transfers the transfer data information specified at the address of the transfer data table to the display data table and the additional data table. It is added to the drawing list created based on the above, and the added drawing list is transmitted to the image controller 188. On the other hand, when the pointer 185h is "0002H", since the Null data is specified in the address "0002H" of the transfer data table, it is determined that there is no transfer target image data to start the transfer, and the data is generated. The drawing list is transmitted to the image controller 188 without adding the transfer data information to the drawing list.

Then, when the transfer data information is described in the drawing list received from the MPU 181, the image controller 188 transfers the transfer target image data from the character ROM 187 to a predetermined sub-area of the image storage area 190a according to the transfer data information. Execute the process to be performed.

Here, as described above, in the transfer data table, the image data corresponding to the predetermined sprite is stored in the image storage area 190a by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information of the image data to be transferred is specified for a predetermined address, the image data is transferred from the character ROM 187 to the image storage area 190a according to the transfer data information specified in the transfer data table. When drawing a predetermined sprite according to the display data table, the image data that is not resident in the resident video RAM 189 required for drawing the sprite can always be stored in the image storage area 190a. Then, using the image data stored in the image storage area 190a, a predetermined sprite can be drawn based on the display data table.

As a result, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, the image necessary for display can be read in advance from the character ROM 187 and transferred to the normal video RAM 190 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the auxiliary display unit 65. Further, according to the description in the transfer data table, only the non-resident image data in the resident video RAM 189 can be easily and surely transferred from the character ROM 187 to the normal video RAM 190.

Further, in the slot machine 10, in the display control device 81, the display data table is set in the display data table buffer 185f in response to a command from the main control device 101 (for example, a lottery result command or a payout determination result command). Since the transfer data table corresponding to the display data table is set in the transfer data table 185d, the image data of the sprite used in the display data table can be reliably used from the character ROM 187 at a desired timing. It can be transferred to the video RAM 190.

Further, in the transfer data table, the transfer data information is defined so that the image data is transferred from the character ROM 187 to the normal video RAM 190 for each image data corresponding to the sprite. As a result, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 187 to the normal video RAM 190 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

Further, the transfer data table has the same data structure as the display data table, and is associated with the address specified in the display data table, and the transfer of the transfer target image data to be started at the time indicated by the address is transferred. Since the data information is specified, the image data of a predetermined sprite is surely stored in the normal video RAM 190 before the image data of a predetermined sprite is used based on the display data table set in the display data table buffer 185f. As such, the timing of starting transfer can be instructed. Therefore, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, a wide variety of effect images can be easily displayed on the auxiliary display unit 65.

The simple image display flag 185e is a flag indicating whether or not to display the main image when the power is turned on on the auxiliary display unit 65. This simple image display flag 185e is used when the image data corresponding to the main image at power-on is transferred from the character ROM 187 to the resident video RAM 189 in the main process (see FIG. 21) executed by the MPU 181 after the power is turned on. It is set to ON in order to display the main image at the time of input on the auxiliary display unit 65 (see S705 in FIG. 21). Then, at the stage where all the resident target image data is stored in the resident video RAM 435 by the resident image transfer process of the image transfer process, the auxiliary display unit 65 is turned off in order to display an image other than the main image when the power is turned on. (See S827 in FIG. 29 (b)).

This simple image display flag 185e is referred to in the V interrupt process executed by the MPU 181 each time a V interrupt signal transmitted from the image controller 188 is detected (see S721 in FIG. 23 (b)), and is simplified. When the image display flag 185e is on, the simple display setting process (see S728 in FIG. 23B) is executed so that the main image is displayed on the auxiliary display unit 65 when the power is turned on. On the other hand, when the simple image display flag 185e is off, the command determination process (see FIGS. 24 to 27) and the display setting so that various images are displayed according to the command received from the main control device 101. The process (see FIG. 28) is executed.

Further, the simple image display flag 185e is referred to in the transfer setting process executed by the MPU 181 in the V interrupt process (see S816 in FIG. 29 (a)), and the simple image display flag 185e is on. Executes the resident image transfer setting process (see FIG. 29 (b)) for transferring the resident image data from the character ROM 187 to the resident video RAM 189 because the resident image data that is not stored in the resident video RAM 189 exists. When the simple image display flag 185e is off, the normal image transfer setting process (see FIG. 30) for transferring the image data required for the drawing process from the character ROM 187 to the normal video RAM 190 is executed.

The display data table buffer 185f is a buffer for storing a display data table corresponding to an effect mode to be displayed on the auxiliary display unit 65 in response to a command or the like from the main control device 101. The MPU 181 determines the effect to be displayed on the auxiliary display unit 65 based on a command or the like from the main control device 101, selects a display data table corresponding to the effect mode of the effect from the data table storage area 185d, and selects the display data table from the data table storage area 185d. The selected display data table is stored in the display data table buffer 185f. Then, the MPU 181 adds the pointer 185h by one, and based on the drawing content defined by the address indicated by the pointer 185h in the display data table stored in the display data table buffer 185f, the image controller 188 is used for each frame. A drawing list (see FIG. 14), which will be described later, is generated, which describes the content of the image drawing instruction for the user. As a result, the auxiliary display unit 65 displays the effect corresponding to the display data table stored in the display data table buffer 185f.

The transfer data table buffer 185 g is a buffer for storing the transfer data table corresponding to the display data table stored in the display data table buffer 185f in response to a command or the like from the main control device 101. The MPU 181 selects a transfer data table corresponding to the display data table from the data table storage area 185d in accordance with storing the display data table in the display data table buffer 185f, and transfers the selected transfer data table. It is stored in the data table buffer 185 g. If all the sprite image data used in the display data table stored in the display data table buffer 185f is stored in the resident video RAM 189, the transfer data table corresponding to the display data table is not prepared. Therefore, the MPU 181 clears the contents by writing the Null data which means that the transfer target image data does not exist in the transfer data table buffer 185 g.

Then, while adding the pointer 185h one by one, the MPU 181 defines the transfer data information of the transfer target image data defined at the address indicated by the pointer 185h in the transfer data table stored in the transfer data table buffer 185 g. If (that is, if the Null data is not described), the transfer data information is added to the later drawing list (see FIG. 14) that describes the instruction content for image drawing to the image controller 188 generated for each frame. to add.

As a result, when the transfer data information is described in the drawing list received from the MPU 181, the image controller 188 transfers the transfer target image data from the character ROM 187 to a predetermined sub-area of the image storage area 190a according to the transfer data information. Execute the process to transfer. Here, as described above, in the transfer data table, the image data corresponding to the predetermined sprite is stored in the image storage area 190a by the time the drawing of the predetermined sprite is started according to the display data table. The transfer data information of the image data to be transferred is specified for a predetermined address. Therefore, when drawing a predetermined sprite according to the display data table by transferring the image data from the character ROM 187 to the image storage area 190a according to the transfer data information specified in the transfer data table, it is necessary to draw the sprite. Image data that is not resident in the resident video RAM 189 can be stored in the image storage area 190a in advance.

As a result, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, the image necessary for display can be read in advance from the character ROM 187 and transferred to the normal video RAM 190 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the auxiliary display unit 65. Further, according to the description in the transfer data table, only the non-resident image data in the resident video RAM 189 can be easily and surely transferred from the character ROM 187 to the normal video RAM 190.

The pointer 185h is an address to acquire the transfer data information of the corresponding drawing content or transfer target image data from the display data table and transfer data table stored in the display data table buffer 185f and the transfer data table buffer 185 g, respectively. Is for specifying. The MPU 181 temporarily initializes the pointer 185h to 0 in accordance with the display data table being stored in the display data table buffer 185f. Then, the display setting process of the V interrupt process executed by the MPU 181 based on the V interrupt signal transmitted from the image controller 188 every 20 milliseconds when the drawing process of the image for one frame is completed (FIG. 23 (a). ), The pointer update process (see S806 in FIG. 28) is executed, and the value of the pointer 185h is added one by one.

Each time the pointer 185h is updated, the MPU 181 specifies the drawing content defined by the address indicated by the pointer 185h from the display data table stored in the display data table buffer 185f, and a drawing list described later. (See FIG. 14) is created, and the transfer data information of the image data of the predetermined sprite to be transferred at that time is acquired from the transfer data table stored in the transfer data table buffer 185 g, and the transfer data is acquired. Add the information to the created drawing list.

As a result, the effect corresponding to the display data table stored in the display data table buffer 185f is displayed on the third symbol display device 281. Therefore, the effect to be displayed on the auxiliary display unit 65 can be easily changed only by changing the display data table stored in the display data table buffer 185f. Therefore, a wide variety of effects can be displayed regardless of the processing capacity of the display control device 81.

When the transfer data table stored in the transfer data table buffer 185 g is stored, the sprite is drawn by the corresponding display data table based on the transfer data table. Image data that is not resident in the resident video RAM 189 used for drawing can always be stored in the image storage area 190a. As a result, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, the image necessary for display can be read in advance from the character ROM 187 and transferred to the normal video RAM 190 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the auxiliary display unit 65. Further, according to the description in the transfer data table, only the non-resident image data in the resident video RAM 189 can be easily and surely transferred from the character ROM 187 to the normal video RAM 190.

The drawing list area 185i draws an image for one frame to the image controller 188, which is generated based on the display data table stored in the display data table buffer 185f and the transfer data table stored in the transfer data table buffer 185 g. This is an area for storing the drawing list to be instructed.

Here, the details of the drawing list will be described with reference to FIG. FIG. 14 is a schematic diagram schematically showing the contents of the drawing list. The drawing list is an instruction table instructing the image controller 188 to draw an image for one frame, and as shown in FIG. 14, a rear image and an effect (effect 1, effect 2) used in the image of one frame are used. , ...), Characters (character 1, character 2, ..., error symbol), and detailed drawing information (detailed information) of the sprite is described for each sprite. In addition, transfer data information for transferring predetermined image data from the character ROM 187 to the normal video RAM 190 to the image controller 188 is also described in the drawing list.

The detailed drawing information (detailed information) of each sprite includes information indicating the RAM type (resident video RAM 189 or normal video RAM 190) in which the image data of the corresponding sprite (display object) is stored, and the information thereof. The address is described, and the image controller 188 acquires the image data of the sprite from the memory area specified by the RAM type and the address. Further, the detailed drawing information (detailed information) includes display position coordinates, enlargement ratio, rotation angle, translucent value, α-blending information, color information, and filter specification information, and the image controller 188 includes various types of image controller 188. A standard image generated from the image data of the sprite read from the video RAM is scaled according to the enlargement ratio, rotated according to the rotation angle, and translucent according to the translucency value. Processing is performed, composition processing with other sprites is performed according to the α blending information, color tone correction processing is performed according to the color information, and filtering processing is performed by the method specified by the information according to the filter specification information. Then, the image obtained by performing various processes on the display position indicated by the display position coordinates is drawn. Then, the drawn image is expanded by the image controller 188 into either the first frame buffer 190b or the second frame buffer 190c specified by the drawing target buffer flag 185k.

In the display data table stored in the display data table buffer 185f, the MPU 181 has drawing contents defined by the address indicated by the pointer 185h and other contents of an image to be drawn (for example, a warning image notifying the occurrence of an error). ), Detailed drawing information (detailed information) for all sprites used for drawing an image for one frame is generated, and a drawing list is created by rearranging the detailed information for each sprite.

Here, among the detailed information of each sprite, the storage RAM type and address of the sprite (display object) data are the sprite type specified in the display data table and the sprite type specified from the contents of other images. Generated accordingly. That is, since the area of the resident video RAM 189 in which the image data of the sprite is stored or the sub area of the image storage area 190a of the normal video RAM 190 is fixed for each sprite, the MPU 181 can be used according to the sprite type. Therefore, the storage RAM type and address in which the image data of the sprite is stored can be immediately specified, and such information can be easily included in the detailed information of the drawing list.

Further, the MPU181 is defined in the display data table for other information (display position coordinates, enlargement ratio, rotation angle, translucent value, α-blending information, color information and filter designation information) among the detailed information of each sprite. Copy those information as it is. Since the display position coordinates of the rear image, the enlargement ratio, the rotation angle, the translucent value, the α blending information, the color information, and the filter specification information are constant with the passage of time, those information are shown in the display data table. Is not specified, so this information in the back image in the drawing list is always set to a fixed value.

Further, in generating the drawing list, the MPU 181 sorts the sprites to be arranged on the back side in the image for one frame in the order of the sprites to be arranged on the front side, and detailed drawing information for each sprite. Describe (detailed information). That is, in the drawing list, the detailed information corresponding to the back image is described first, and then the effect (effect 1, effect 2, ...), character (character 1, character 2, ..., error symbol). ), The detailed information corresponding to each sprite is described.

The image controller 188 executes the drawing process of each sprite in the order described in the drawing list, and expands the drawn sprites in the frame buffer by overwriting. Therefore, in the image for one frame generated by the drawing list, the sprite drawn first can be arranged on the backmost side, and the sprite drawn last can be arranged on the frontmost side.

Further, when the transfer data information is described in the transfer data table stored in the transfer data table buffer 185 g at the address indicated by the pointer 185h, the MPU 181 is the transfer data information (character in which the transfer target image data is stored). The storage source start address and storage source final address in ROM 187, and the storage destination head address of the sub-area provided in the image storage area 190a to store the transfer target image data) are added to the end of the drawing list. If the drawing list includes this transfer data information, the image controller 188 starts to image from a predetermined area (area indicated by the storage source start address and the storage source final address) of the character ROM 187 based on the transfer data information. The data is read out, and the image data to be transferred is transferred to a predetermined sub-area (storage destination address) provided in the image storage area 190a of the normal video RAM 190.

The stored image discrimination flag 185j indicates whether the image data corresponding to the sprite is stored in the image storage area 190a of the normal video RAM 190 for all the sprites whose corresponding image data is not resident in the resident video RAM 189. It is a flag indicating the storage state indicating whether or not.

The stored image discrimination flag 185j is generated by the initial setting process (see S702 in FIG. 21) executed by the MPU 181 in the display main process when the power is turned on. The stored image discrimination flag 185j generated here is set to "off" indicating that the stored state for all sprites is not stored in the image storage area 190a.

Then, the stored image discrimination flag 185j is updated when the transfer instruction of the transfer target image data corresponding to one sprite is set in the normal image transfer setting process (see FIG. 30) executed by the MPU181. (See S841 in FIG. 30). In this update, the storage state corresponding to one sprite for which the transfer instruction is set is set to "on" indicating that the corresponding image data is stored in the image storage area 190a. Further, the image data of other sprites that are to be stored in the sub-area of the same image storage area 190a as that one sprite is always in an unstored state by storing the image data of one sprite. Therefore, set the storage state corresponding to other sprites to "Off".

Further, the MPU 181 refers to the stored image discrimination flag 185j when transferring the image data of the sprite whose image data is not resident in the resident video RAM 189 from the character ROM 187 to the normal video RAM 190, and refers to the image of the sprite to be transferred. It is determined whether or not the data is already stored in the image storage area 190a of the normal video RAM 189 (see S839 in FIG. 30). If the storage state corresponding to the sprite to be transferred is "off" and the corresponding image data is not stored in the image storage area 190a, a transfer instruction for the image data is set (see S840 in FIG. 30). , The image controller 188 is made to transfer the image data from the character ROM 187 to a predetermined sub-area of the image storage area 190a. On the other hand, if the storage state corresponding to the sprite to be transferred is "on", the corresponding image data is already stored in the image storage area 190a, and the transfer process of the image data is stopped. As a result, it is possible to suppress unnecessary transfer from the character ROM 187 to the normal video RAM 190, reduce the processing load in each part of the display control device 314, and reduce the traffic in the internal bus. ..

The drawing target buffer flag 185k is a frame buffer (hereinafter, "drawing target buffer") that expands the image drawn by the image controller 188 from the two frame buffers (first frame buffer 190b and second frame buffer 190c). When the drawing target buffer flag 185k is 0, the first frame buffer 190b is specified as the drawing target buffer, and when it is 1, the second frame buffer 190c is specified. Then, the information of the designated drawing target buffer is transmitted to the image controller 188 together with the drawing list (see S852 in FIG. 31).

As a result, the image controller 188 executes a drawing process of expanding the image drawn based on the drawing list on the designated drawing target buffer. Further, the image controller 188 reads out the previously expanded drawing image information from the frame buffer different from the drawing target buffer in parallel with the drawing process, and outputs the image information to the auxiliary display unit 65 together with the drive signal. By transferring, a display process for displaying an image on the auxiliary display unit 65 is executed.

The drawing target buffer flag 185k is updated when the drawing target buffer information is transmitted to the image controller 188 together with the drawing list. This update is performed by inverting the value of the drawing target buffer flag 185k, that is, setting it to "1" if the value is "0" and "0" if the value is "1". It is done by. As a result, the drawing target buffers are alternately set between the first frame buffer 190b and the second frame buffer 190c each time the drawing list is transmitted. Further, the drawing list is transmitted by the V interrupt executed by the MPU 181 based on the V interrupt signal transmitted from the image controller 188 every 20 milliseconds when the drawing process and the display process of the image for one frame are completed. Each time the drawing process of the process (see FIG. 23B) is executed, it is performed (see S852 in FIG. 31).

That is, at a certain timing, the first frame buffer 190b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 190c is designated as the frame buffer for reading the image information for one frame. When the drawing process and the display process are executed, the second frame buffer 190c is designated as the frame buffer for expanding the image for one frame 20 milliseconds after the drawing process for the image for one frame is completed, and the image for one frame is expanded. The first frame buffer 190b is designated as the frame buffer from which the image information of the above is read. As a result, the image information of the image previously expanded in the first frame buffer 190b can be read out and displayed on the auxiliary display unit 65, and at the same time, a new image is expanded in the second frame buffer 190c.

Then, after the next 20 milliseconds, the first frame buffer 190b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 190c is designated as the frame buffer for reading the image information for one frame. Will be done. As a result, the image information of the image previously expanded in the second frame buffer 190b can be read out and displayed on the auxiliary display unit 65, and at the same time, a new image is expanded in the first frame buffer 190c. After that, one of the first frame buffer 190b and the second frame buffer 190c is used every 20 milliseconds for the frame buffer that expands the image for one frame and the frame buffer for reading the image information for one frame. By alternately specifying the images, it is possible to continuously perform the display processing of the image for one frame in units of 20 milliseconds while performing the drawing processing of the image for one frame.

Subsequently, each control process executed by the MPU 102 of the main control device 101 will be described. The processing of the MPU 102 is roughly divided into a main processing that is started when the power is turned on, a timer interrupt processing that is started periodically (at a cycle of 1.49 msec in this embodiment), and a power failure signal to the NMI terminal. There is NMI interrupt processing that is activated with input. In the following, among these processes, the processes related to the progress of the game, that is, the timer interrupt process and the normal process performed in the main process will be described with reference to the flowcharts of FIGS. 15 to 20.

First, with reference to FIG. 15, a timer interrupt process periodically executed by the MPU 102 of the main control unit 101 will be described. FIG. 15 is a flowchart showing the timer interrupt processing. In the MPU 102 of the main control device 101, for example, a timer interrupt is generated every 1.49 msec, and the timer interrupt process shown in FIG. 15 is executed by the MPU 102 in response to the timer interrupt.

In this timer interrupt process, first, register save processing is performed (S101). In this register save process, the values of all the registers in the MPU 102 used in the normal process described later are saved in the backup area of the RAM 106. Next, it is confirmed whether or not the power failure flag is set (S102), and if the power failure flag is set (S102: Yes), the power failure processing is executed (S103).

Here, the outline of the power failure processing executed in S103 will be described.

When the power is cut off due to the occurrence of a power failure or the like, a power failure signal is output from the power failure monitoring circuit 91b of the power supply device 91, and the power failure signal is input to the main control device 101 via the NMI terminal. When a power failure signal is input, the main control device 101 immediately executes NMI interrupt processing and sets the power failure flag in the power failure flag storage area (not shown) provided in the RAM 106.

In the power failure processing, it is first determined whether or not the command transmission is completed, and if the transmission is not completed, the main processing is terminated and the timer interrupt processing is restored, and the command transmission is terminated. When the transmission of the command is completed, the value of the stack pointer of the MPU 102 is saved in the backup area of the RAM 106. After that, the output state of the output port in the input / output port 104 is cleared, and all actuators (not shown) are turned off. This prevents the reel unit 31 from running out of control until the power supply is completely cut off, and preventing abnormal output from output devices such as the auxiliary display unit 65 and the speaker 64.

Then, when the power failure is resolved, the RAM determination value for determining whether the data in the RAM 106 is normal is calculated and stored in the backup area, thereby prohibiting the subsequent RAM access. After performing the above processing, an infinite loop is entered in preparation for the fact that the power supply is completely cut off and the processing cannot be executed. In consideration of the case where the power failure flag is erroneously set due to noise or the like, it is confirmed whether or not the power failure signal is output until the infinite loop is entered. If the power failure signal is not output, it means that the power has been restored from the power failure state. Therefore, writing to the RAM 106 is permitted, the power failure flag is reset, the timer interrupt processing is restored, and the process proceeds to S104. Moreover, if the output of the power failure signal is continuously performed, the loop enters the infinite loop as it is. By the way, it is confirmed whether or not the power failure signal is output even under the infinite loop, and if the power failure signal is no longer output, the process shifts to the main process.

Returning to the description of the timer interrupt process, if the power failure flag is not set in the process of S102 (S102: No), various processes after S104 are performed. That is, in the process of S104, the watchdog timer that initializes the value of the watchdog timer for monitoring the occurrence of a malfunction is cleared. Next, an interrupt end declaration process is performed on the MPU 102 itself so that the next timer interrupt can be set (S105), and stepping, which is a rotating cylinder drive motor, is performed to rotate each reel 32L, 32M, 32R. A stepping motor control process for driving the motor is performed (S106). Next, the states of various sensors (see FIG. 8) such as the stop detection sensors 42a to 44a, the first insertion medal detection sensor 45a, the second insertion medal detection sensor 45b, and the payout detection sensor 51a connected to the input / output port 104 are read. At the same time, a sensor monitoring process for monitoring whether or not the read result is normal is performed (S107).

In this sensor monitoring process, if there is an abnormality in the reading result of each sensor, for example, from the detection results of the first inserted medal detection sensor 45a and the second inserted medal detection sensor 45b, the inserted medals may be jammed or pulled out. When the fraud is detected, it is determined that a sensor error has occurred, and the occurrence of the sensor error is notified from the auxiliary effect unit (upper lamp 63, speaker 64, auxiliary display unit 65) regarding the type of error. An error command including information is transmitted to the display control device 81.

In the subsequent processing of S108, a timer calculation process for subtracting the values of each counter and timer is performed (S108), and the number of bets for medals and the number of bets for outputting the result of counting the number of payouts to the external centralized terminal board 121 are output. In / out counter processing is performed (S109).

Next, a command output process for transmitting various commands such as a start command and a lottery result command, which will be described later, to the display control device 81 is performed (S110). After that, a segment data setting process for setting segment data displayed on the credit display unit 60, the remaining payout number display unit 61, and the payout number display unit 62 is performed (S111), and then the segment set in the segment data setting process is performed (S111). Data is supplied to each display unit 60 to 62, and segment data display processing for displaying corresponding numbers, symbols, etc. is performed (S112).

Then, a port output process for outputting data corresponding to the I / O device is performed from the input / output port 104 (S113), and the values of the registers saved in the backup area in the previous process of S101 are stored in the MPU 102. It returns to the corresponding register of (S114). After that, an interrupt enable process for permitting the next timer interrupt is performed (S115), and this series of timer interrupt processes is terminated.

Next, with reference to FIG. 16, the normal processing executed by the MPU 102 of the main control device 101 will be described. FIG. 16 is a flowchart showing the normal processing.

The normal process is a process that performs the main control related to the game. When the normal process is executed by the MPU 102, the interrupt enable process for permitting the next timer interrupt is first performed (S201), and then the game is enabled. Pre-start processing for this is performed (S202). In this start pre-processing, the display control device 81 or the like waits until the initialization is completed. Then, when the initialization of the display control device 81 or the like is completed, the game management process shown in the following S203 to S213 is performed.

As a game management process, first, in the process of S203, data such as various game information stored in RAM 106 (for example, a random number value used in the previous game and each winning flag indicating winning of each winning except BB winning) are used. After clearing, the start waiting process is performed in the subsequent process of S204.

In the start waiting process of S204, it is determined whether or not the replay winning is established in the previous game, and if the replay winning is established, the automatic insertion process of automatically inserting the same number of virtual medals as the previous bet number. Is performed, and the start waiting process is terminated. In the automatic insertion process, virtual medals are inserted without reducing the number of virtual medals displayed on the credit display unit 60. That is, if the replay prize is established in the previous game, the player can play this game without reducing the number of medals owned and without inserting medals.

On the other hand, when none of the replay winnings is established, a sensor for confirming whether or not an error has occurred in the sensor reading result performed in the sensor monitoring process of the timer interrupt process (see S107 in FIG. 15). An abnormality confirmation process is performed, and if an error occurs, the slot machine 10 is put into an error state and an error occurrence process for notifying the occurrence of the error is performed. This error state is maintained until the reset switch 72 is operated.

If the reading result of the sensor is normal, it is determined whether or not the checkout switch 59 has been operated, and if the checkout switch 59 is operated, the medal return process of paying out the same number of medals as the credited virtual medal. I do. Whether or not the medal insertion or the credit insertion switches 56 to 58 have been operated between the previous start waiting process and the current start waiting process after the medal return process is completed or the settlement switch 59 is not operated. If any of these is performed, the medal insertion process is performed and the start waiting process is terminated. If neither the medal insertion nor the operation of the credit insertion switches 56 to 58 is performed between the previous start waiting process and the current start waiting process, the start waiting process is terminated as it is.

After the start waiting process of S204 is completed, it is nextly determined whether or not the number of bets on the medal has reached the specified number (S205), and if the number of bets has not reached the specified number (S205: No), S204. The process returns to the process of waiting for the start of, and the process after the sensor abnormality confirmation process is performed. In this embodiment, the specified number of bets is set according to the gaming state of the slot machine 10.

That is, when the gaming state of the slot machine 10 is in the general gaming state, the specified number is set to 1 to 3, and when the gaming state is in the bonus state, the specified number is set to 3. As a result, in the general game state, the game can be started not only with three bets but also with one or two bets. Then, when the game is started with the number of bets of 1 or 2 (1 or 2), the above-mentioned 1-card lottery table or 2 in the lottery process (see S210) described later. Since the lottery table is set and the winning mode (role) is drawn, there is a high probability that the number of medals to be paid out will be 3 when the game is played with 1 or 2 medals. It is possible to win a prize or win a 7-bell prize with two medals paid out. Then, if three medals are paid out due to the establishment of the Cherry Bell prize, the player can insert the three medals and play another game while expecting the establishment of the BB prize. The player can enjoy the game to the end without leaving any extra medals. In addition, if two medals are paid out due to the establishment of the 7-bell prize, the player inserts the two medals and expects the cherry-bell prize to be established in which three more medals are paid out. You can enjoy another game. Then, if the Cherry Bell prize is established, the player can play the game by inserting the three medals paid out while expecting the BB prize to be established, so that the player can play the game to the end without leaving any extra medals. Can be enjoyed. Further, even if the result of the game played by inserting one or two medals is off, the player can end the game without leaving any extra medals. As described above, even if the number of bets is one or two in the general game state, the player can be rehabilitated by using the one-card lottery table and the two-card lottery table set in the present embodiment. You can give the fun of the game, and you can enjoy the game to the end without leaving any extra medals.

On the other hand, by setting the specified number of bets to 3 when the gaming state of the slot machine 10 is in the bonus state, the watermelon with a large number of medals paid out while allowing the player to insert 3 medals in the bonus state. By increasing the winning probability of winning or bell winning and setting the expected value of the number of medals to be paid out in one game high, the total number of medals to be paid out in the bonus state can be achieved to 250 in a small number of games. Therefore, the player can receive many medals in a short time, and on the other hand, the operating rate of the slot machine 10 can be increased on the hall side.

If the number of bets has reached the specified number as a result of the processing of S205 (S205: Yes), then it is determined whether or not the start lever 41 has been operated (S206). Then, when the start lever 41 is not operated (S206: No), the process returns to the start waiting process of step S204, and the process after the sensor abnormality confirmation process is performed.

On the other hand, when the start lever 41 is operated (S206: Yes), the game can be started when the start lever 41 is operated while the slot machine 10 is betting a specified number of medals. Therefore, it means that a start command has been issued to start the game. Therefore, in such a case, the medal passage switching solenoid 46a is switched to the non-excited state to prohibit bet acceptance (S207). In the subsequent processing of 208, a valid line setting process for setting a valid line is performed (S208). In this effective line setting process, all the combination lines of the upper line L1, the middle line L2, the lower line L3, the right-down line L4, and the right-up line L5 are set as effective lines.

Then, the start command is set (S209). Here, the start command is a command transmitted to the display control device 81 so as to know that the start command has occurred. In this normal processing, information regarding the number of bets (number of inserted medals) accepted in the processing of S205 is included in this start command and set. The start command set here is temporarily stored in a ring buffer (not shown) that stores various commands generated in the normal processing, and is executed every 1.49 ms in the above-mentioned timer interrupt processing (FIG. 15). It is transmitted to the display control device 81 by the process of S110 of (see). As a result, the display control device 81 grasps that the start command of the game is generated by receiving the start command, and also grasps the number of medals (the number of bets) inserted by the player for the game. It is possible to make each auxiliary effect unit (upper lamp 63, speaker 64, auxiliary display unit 65) execute various effects according to the number of bets.

After that, the lottery process of S210, the reel control process of S211, the medal payout process of S212, and the bonus state process of S213 are executed in order, and the process returns to the process of S203. Then, in the power failure processing (S103) of the timer interrupt processing (see FIG. 15), the processing from S203 to S213 is repeatedly executed until the power is cut off by the power switch 71 or an infinite loop is entered due to the power failure.

Next, with reference to FIG. 17, the lottery process (S210) executed in the normal process (see FIG. 16) in the MPU 102 of the main control device 101 will be described. FIG. 17 is a flowchart showing the lottery process.

In the lottery process, first, a random number used when performing a lottery of a winning mode (combination) is acquired (S301). In this slot machine 10, as described above, each time the start lever 41 is operated, the hard circuit is configured to latch the value of the free run counter 107 at that time, and the latched free run is performed. By reading the value of the counter 107 and storing the value in a predetermined area of the RAM 106, the value of the random number used for the lottery is acquired.

After acquiring a random number by the process of S301, a lottery table setting process for setting a lottery table for performing a lottery of a winning mode is performed (S302). Here, with reference to FIG. 18, the details of the lottery table setting process of S302 will be described. FIG. 18 is a flowchart showing a lottery table setting process executed in the MPU 102 of the main control device 101. In this lottery table setting process, the current gaming state of the slot machine 10 is determined, and further, the lottery table storage area 105a is determined according to the number of medals inserted (number of bets) and the setting state set in the slot machine 10. A corresponding lottery table is set from a plurality of lottery tables stored in.

In this process, first, it is determined whether or not the gaming state of the slot machine 10 is a bonus state (S401), and as a result, if it is not a bonus state (S401: No), the gaming state of the slot machine 10 is a general game. Since it is in a state, it is then determined whether or not the number of inserted medals (number of bets) is 3 (3 bets) (S402). If the number of bets is 3 (S402: Yes), 6 lottery tables for hanging 3 cards are provided corresponding to the setting states of "setting 1" to "setting 6" that the slot machine 10 can take. Of these, the lottery table for hanging three cards corresponding to the currently set setting state is set (S403), the lottery table setting process is terminated, and the process returns to the lottery process. As a result, when the gaming state of the slot machine 10 is the general gaming state and the game is started with the number of bets of three, a three-card lottery table corresponding to the setting state of the slot machine 10 is set. ..

Further, when it is determined that the number of bets is not 3 as a result of the processing of S402 (S402: No), then it is determined whether or not the number of bets is 2 (2 bets) (S404). If the number of bets is two (S404: Yes), the six two-seat lottery tables provided corresponding to the setting states of "setting 1" to "setting 6" that the slot machine 10 can take. Of these, the lottery table for two-sheet hanging corresponding to the currently set setting state is set (S405), the lottery table setting process is terminated, and the process returns to the lottery process. As a result, when the gaming state of the slot machine 10 is the general gaming state and the game is started with the number of bets of two, a two-card lottery table corresponding to the setting state of the slot machine 10 is set. ..

Further, when it is determined that the number of bets is not two as a result of the processing of S404 (S404: No), it can be determined that the number of bets is one (one bet), so that the slot machine 10 can take ". Of the six 1-sheet hanging lottery tables provided corresponding to the setting states of "Setting 1" to "Setting 6", set the 1-sheet hanging lottery table corresponding to the currently set setting state. (S406), the lottery table setting process is terminated, and the process returns to the lottery process. As a result, when the gaming state of the slot machine 10 is the general gaming state and the game is started with the number of bets of one card, the one-card lottery table corresponding to the set state of the slot machine 10 is set. ..

On the other hand, if the gaming state of the slot machine 10 is a bonus state as a result of the processing of S401 (S401: Yes), it is provided corresponding to the setting states of "setting 1" to "setting 6" that the slot machine 10 can take. Of the six bonus state lottery tables, the bonus state lottery table corresponding to the currently set setting state is set (S407), the lottery table setting process is terminated, and the process returns to the lottery process. As a result, when the gaming state of the slot machine 10 is the bonus state, the bonus time lottery table corresponding to the setting state of the slot machine 10 is set.

As described above, in the lottery table setting process, the lottery table is stored in the lottery table storage area 105a according to the current gaming state of the slot machine 10, the number of medals inserted (the number of bets), and the setting state set in the slot machine 10. A corresponding lottery table is set from the plurality of lottery tables created.

Returning to FIG. 17, the explanation of the lottery process will be continued. After the lottery table setting process of S302 is completed, the index value IV is set to 1 (S303), and the determination value DV used when performing the lottery (win / fail determination) of the winning mode is set (S304). In such a judgment value setting process, a new judgment value DV is set by adding the point value PV corresponding to the current index value IV to the current judgment value DV. In the initial determination value setting process, the random value acquired in step S301 is used as the current determination value DV, and the point value PV corresponding to the current index value IV of 1 is added to this random value to create a new value. The determination value is DV.

After that, in step S305, a lottery of the winning mode corresponding to the index value IV is performed. In this lottery, it is determined whether or not the determination value DV exceeds 65535. Then, when it exceeds 65535 (S305: Yes), the winning flag of the winning mode corresponding to the index value IV at that time is set in the winning flag storage area 106a of the RAM 106 (S306). That is, when the determination value DV exceeds 65535 when IV = 1, the BB winning winning flag is set in the winning flag storage area 106a in the processing of S306, and the determination value DV exceeds 65535 when IV = 2. If, in the processing of S306, the watermelon winning winning flag is set in the winning flag storage area 106a, and if the determination value DV exceeds 65535 when IV = 3, in the processing of S306, the bell winning winning flag is set as the winning flag. If it is set in the storage area 106a and the judgment value DV exceeds 65535 when IV = 4, the cherry bell winning winning flag is set in the winning flag storage area 106a in the processing of S306, and the judgment is made when IV = 5. When the value DV exceeds 65535, the 7-bell winning winning flag is set in the winning flag storage area 106a in the processing of S306, and when the determination value DV exceeds 65535 when IV = 6, in the processing of S306, the 7-bell winning winning flag is set. The replay winning winning flag is set in the winning flag storage area 106a.

By the way, if the set winning flag is one of the watermelon winning flag, the bell winning flag, the cherry bell winning flag, the 7 bell winning flag, and the replay winning flag, this winning flag is set to the corresponding winning flag. It is reset after the end of the game (see S203 of the normal process shown in FIG. 16). On the other hand, when the set winning flag is the BB winning winning flag, this BB winning winning flag is reset on condition that the BB winning is established. That is, the BB Nyusho winning flag may be valid over a plurality of games. For example, after the BB winning flag is set, if the symbols are not aligned in the stop symbol of the BB winning mode, that is, if the BB winning is not established, the BB winning flag is not reset and is carried over to the next game. Is done.

In the processing of S306 in the state where the BB winning winning flag is carried over, if the current index value IV is 1, the BB winning winning flag is not set, and if the current index value IV is 2 to 6, the index value is not set. Set the winning flag corresponding to IV. That is, in a game in which the BB winning flag is carried over, the corresponding winning flag is set when a winning mode other than the BB winning is won, while the corresponding BB winning flag is set when the BB winning is won. Do not set.

If it is determined in the process of S305 that the determination value DV does not exceed 65535 (S305: No), it means that the winning mode corresponding to the index value IV is deviated. In such a case, the index value IV is added by 1 (S307), and then it is determined whether or not there is a winning mode corresponding to the index value IV, that is, whether or not there is a determination role to be drawn (win / fail determination) ( S308). Specifically, it is determined whether or not the added index value IV exceeds the maximum value of the index value IV set in the lottery table. If there is a determination combination to be determined (S308: Yes), the process returns to the process of S304, and the determination of the winning mode is continued. At this time, in the processing of S304, a new determination value DV is added by adding the point value PV corresponding to the current index value IV to the determination value DV (that is, the current determination value DV) used for the determination of whether or not the previous combination is correct. Then, in the process of S305, the winning / failing determination of the winning mode is performed based on the determination value DV.

Here, when the gaming state of the slot machine 10 is in the general gaming state by the lottery table setting process of S302, the three-card lottery table for the general gaming state, the two-card lottery table, and the one-card lottery lottery. Since the lottery table to be used is set from the table according to the number of bets, as shown in FIGS. 7 and 9, the winning probability of BB winning when the game is played by inserting three medals is 1. The lottery of the winning mode is performed after the game is set sufficiently higher than when the game is played by inserting one or two medals. Therefore, as described above, it is possible to insert three medals and play one game while expecting the player to pay out a large number of medals by establishing the BB prize. Therefore, the medals are consumed quickly, and it is possible to increase the operating rate of the slot machine in the hall.

In addition, when the game is played by inserting one or two medals, a cherry bell prize in which the number of medals paid out is three is set as a winning combination candidate, and the winning probability is set high, and then the winning mode is set. Since a lottery is held, if one or two medals remain in the player's hand, if the Cherry Bell prize is established, three medals can be paid out with a high probability of winning the BB prize. While expecting a person, one or two medals remaining at hand can be inserted to play one game. Furthermore, when the game is played by inserting one medal, a 7-bell prize with two medals paid out is also set as a winning combination candidate, and the winning probability is set high, and then the lottery of the winning mode is performed. Since it is done, if one medal remains in the player's hand, if the 7 bell prize is established, the player is expected to get two medals to aim for the cherry bell prize again. You can play one game by inserting one remaining medal. Therefore, the player can enjoy the game to the end without leaving any extra medals.

Further, when a lottery table for one-sheet hanging or a lottery table for two-sheet hanging is set and a lottery in a winning mode is performed, either one-sheet hanging or two-sheet hanging is performed as described above with reference to FIG. In this case as well, the lottery of the winning mode can be performed by setting the ratio of the number of medals to be paid out to the number of bets to a value less than 100% and as close to 100% as possible. Therefore, even if you play a game with one or two medals, the medals hardly decrease, so if one or two medals remain in the player's hand, use the one or two medals. It can surely make you want to play a game. On the other hand, if the game is repeated with one or two medals, the number of medals will decrease. If there are 3 or more medals, the player can be directed to play the game with 3 medals with a high probability of winning the BB prize.

Further, by switching each lottery table according to the number of bets and then performing a lottery in a winning mode, as described above with reference to FIGS. 7 and 9, the cherry bell winning is performed by one or two. It is a winning mode that is established only when the game is played, and if the game is played with three cards, it can be treated as a miss without establishing the cherry bell winning, so one cherry bell winning is given. It is possible to draw the player's attention as it is a special small winning combination dedicated to hanging and double-hanging. Similarly, if the 7-bell prize is played only when the game is played with 1 card, and the game is played with 2 or 3 cards, the 7-bell prize is not established. Since it is treated as an outlier, the player can be noticed that the 7-bell prize is a special small role prize dedicated to one piece. Therefore, when the game is played with one or two cards, if the symbol stops at the stop symbol of the cherry bell winning or the 7 bell winning, the player can be greatly delighted.

In addition, even when the game is played with one or two cards, although the winning probability is extremely low, the lottery of the winning mode can be performed by setting so that the BB winning is established. When the game is played with one or two cards, it is possible to give the player a sense of expectation that the BB prize will be established.

In addition, while lowering the winning probability of watermelon winning or bell winning when the game is played with one or two playing, the winning probability of cherry bell winning or 7 bell winning is set high, and the lottery of the winning mode is set. It is possible to further impress the player that the cherry bell winning or the 7 bell winning is a special small winning combination winning with one or two pieces, and one piece or two pieces. When the game is played with two cards, it is possible to give the player a sense of expectation that a cherry bell prize or a seven bell prize will be established.

After setting the winning flag in the process of S306, or when it is determined in the process of S308 that there is no determination combination to be drawn (S308: No), it means that the lottery of the winning mode is completed. In such a case, a lottery result command is set (S309). Here, the lottery result command is a command transmitted to the display control device 81 in order to grasp the result of the winning / failing determination of the winning combination, and the winning mode corresponding to the winning flag set in the winning flag storage area 106a is Generate a lottery result command to include information suggesting that you are a winner. Therefore, in addition to the winning flag set by the lottery of this game, if the BB winning winning flag is carried over from the past game and stored in the winning flag storage area 106a, the BB winning mode is also the winning combination. Is suggested by the lottery result command. Further, when the winning flag is not set in the winning flag storage area 106a, it is suggested by the lottery result command that there is no winning combination and the winning flag is out.

Like the start command, the lottery result command set here is temporarily stored in a ring buffer (not shown) that stores various commands generated in normal processing, and is executed every 1.49 ms as described above. It is transmitted to the display control device 81 by the processing of S110 of the interrupt processing (see FIG. 15). By receiving the lottery result command, the display control device 81 executes drive control of the upper lamp 63 and the auxiliary display unit 65, for example, to suggest a winning combination.

In the present embodiment, the lottery result command is set after the lottery of the winning mode and before the execution of the reel control process (S211 in FIG. 16) for controlling the rotation of each reel 32L, 32M, 32R, and the lottery result. The lottery result command is transmitted to the display control device 81 within about 1.5 ms at the latest after the command is set (that is, after a time lag until the command is transmitted by the timer interrupt process). Then, since the display control device 81 is configured to execute the lottery result command processing (see FIG. 26) described later without delay when the lottery result command is received, the start lever 41 is operated by the player. While the stop switches 42 to 44 cannot be operated, the auxiliary effect unit (upper lamp 63, speaker 64, auxiliary display unit 65) can be made to perform an effect suggesting a winning combination. Therefore, the player can grasp the winning combination suggested by the effect before operating the stop switches 42 to 44, and based on the grasped winning combination, the timing of the operation of the stop switches 42 to 44. Can be adjusted.

Next, a slide table setting process for setting a slide table (stop table) for reel stop control is performed (S310), and the lottery process is completed. Here, the sliding table is a table in which how much the reels 32L, 32M, 32R are slid (rotated) and then stopped from the timing when the stop switches 42 to 44 are operated. That is, the slip table is a arrival symbol (arrival symbol) that has reached the base point position (in the present embodiment, the lower position of each of the corresponding display windows 26L, 26M, 26R) when the stop switches 42 to 44 are pressed. It is a stop data group capable of deriving the relationship between the stop symbol (number) and the stop symbol (stop symbol number) that is actually stopped at the base point position.

As described above, in the slot machine 10, as a stop mode for stopping each reel 32L, 32M, 32R, when the stop switches 42 to 44 are operated, the arrival symbol reaching the base point position is stopped as it is. A stop mode, a stop mode in which the corresponding reel is slid by one symbol and then stopped, a stop mode in which the corresponding reel is slid by two symbols and then stopped, a stop mode in which the corresponding reel is slid by three symbols and then stopped, and four symbols. Five patterns of stopping modes are prepared, one is a stopping mode in which the machine is slid and then stopped. In the slide table, for each symbol number of each reel 32L, 32M, 32R, the stop mode to be set when the symbol indicated by the symbol number becomes the reached symbol is specified from the above five patterns. The sliding table is prepared for each winning mode.

By setting this sliding table, each reel 32L, 32M, 32R is set to stop in a predetermined stop mode from the timing when the stop switches 42 to 44 are operated until the specified time (190 msec) elapses. It is possible to give the player the impression that the symbol arrangement (stop roll) that stops within the visible range from the display windows 26L, 26M, 26R is determined by the player's operation.

Then, in the sliding table setting process of S310, the winning flag set in the winning flag storage area 106a of the RAM 106 is confirmed, and the sliding table uniquely corresponding to the set winning flag is stored in the sliding table storage area of the RAM 106. Set to 106b. This makes it possible to stop the combination of symbols corresponding to the winning mode (see FIG. 7), which will be described later, which has won the lottery as much as possible within the specified time, on the effective line (see FIG. 6). It is possible to prevent the combination of symbols corresponding to the winning modes that have not been won in the lottery from stopping on the valid line.

Here, as described above, the BB Nyusho winning flag is configured to be carried over to the next game until the BB Nyusho is established once the flag is set, so that the lottery performed in one game is performed. The winning flag corresponding to any of the watermelon winning, bell winning, cherry bell winning, 7 bell winning, and replay winning set as a result of, and the carried-over BB winning winning flag are set in the winning flag storage 106a at the same time. May be. In this case, instead of the BB prize, the process is to set the slide table corresponding to the watermelon prize, bell prize, cherry bell prize, 7 bell prize or replay prize with the winning flag set in the slide table storage area 106b. Will be done. As a result, the winning flag is cleared for each game, and if the winning is not established, the status as a winning role will be lost. Watermelon winning, bell winning, cherry bell winning, 7 bell winning, The replay winning can be established more reliably. Then, the BB winning flag corresponding to the BB winning that was not established here is continuously maintained and carried over to the next game.

By the way, in the sliding table setting process of S310, when the cherry bell winning sliding table is set in the winning flag storage area 106a, the cherry bell winning sliding table is stored in the sliding table storage area 106b. Here, the "cherry" symbol, which is the stop symbol of the left reel 32L when the cherry bell winning is established, is arranged on the left reel 32L so that the distance between the symbols of the same type is 7 symbols. As described above, regardless of the timing at which the left stop switch 42 is operated, the "cherry" symbol can be stopped at any of the upper, middle, and lower positions of the display window 26L. Further, the "bell" symbol, which is the stop symbol of the middle reel 32M when the cherry bell winning is established, is arranged on the middle reel 32M so that the distance between the symbols of the same type is 5 or less. As described above, the "bell" symbol can be stopped at the middle position of the display window 26M regardless of the timing at which the middle stop switch 43 is operated.

Therefore, in the cherry bell winning slide table, no matter what symbol arrives at the base point position when the left stop switch 42 is pressed (that is, no matter what arrival symbol number), the display window 26L is used. A stop mode is set in which the "cherry" symbol can be stopped at any of the upper, middle, and lower positions, and no matter what symbol reaches the base point position when the middle stop switch 43 is pressed (that is,). , Regardless of the arrival symbol number), a stop mode in which the "bell" symbol can be stopped is set at the position of the middle stage in the display window 26M. As a result, when the cherry bell winning flag is set, the cherry bell winning sliding table provides a stop symbol corresponding to the cherry bell winning on the middle line L2 regardless of the operation timing of the player's stop switches 42 to 44. , Can be displayed on any of the right-down line L4 and the right-up line L5 (see FIG. 6). Therefore, the cherry bell winning can be established without so-called omission.

When the 7-bell winning flag is set in the winning flag storage area 106a, the 7-bell winning sliding table is stored in the sliding table storage area 106b. Then, the "7" symbol, which is the stop symbol of the left reel 32L when the 7-bell prize is established, is arranged on the left reel 32L so that the distance between the symbols of the same type is 7 symbols, as in the "cherry" symbol. In addition, as described above, the "bell" symbol, which is the stop symbol of the middle reel 32M when the 7-bell prize is established, is arranged on the middle reel 32M so that the distance between the symbols of the same type is 5 or less. Has been done.

Therefore, in the 7-bell winning sliding table, as in the cherry-bell winning sliding table, no matter what symbol reaches the base point position when the left stop switch 42 is pressed (that is, any reaching symbol number). (Even if it is), a stop mode in which the "7" symbol can be stopped is set at any of the upper, middle, and lower positions of the display window 26L, and when the middle stop switch 43 is pressed, any position is set at the base point position. Even if the symbol has arrived (that is, no matter what the arrival symbol number is), a stop mode in which the "bell" symbol can be stopped is set at the position of the middle stage in the display window 26M. As a result, when the 7-bell winning flag is set, the 7-bell winning sliding table provides a stop symbol corresponding to the 7-bell winning on the middle line L2 regardless of the operation timing of the player's stop switches 42 to 44. , Can be displayed on any of the right-down line L4 and the right-up line L5 (see FIG. 6). Therefore, it is possible to win a 7-bell prize without missing a so-called omission.

In this way, when the cherry bell prize in which three medals are paid out or the seven bell prize in which two medals are paid out are won in the lottery of the winning mode, the player's stop switches 42 to 44 are operated. Regardless of the timing, the stop symbol corresponding to the cherry bell prize or the stop symbol corresponding to the 7 bell prize can be displayed on any of the middle line L2, the right-down line L4, and the right-up line L5 (see FIG. 6). Therefore, it is possible to win a cherry bell prize or a 7 bell prize without missing a so-called omission. Therefore, when the player starts the game with one or two cards, the cherry bell prize or the seven bell prize can be surely established without depending on human operation. In addition, the game can be played with the expectation that the cherry bell prize or the 7 bell prize will be established while aiming at the stop symbol of other prizes (for example, BB prize).

Next, with reference to FIG. 19, the reel control process, which is the process of S211 in the normal process (see FIG. 16), will be described. FIG. 19 is a flowchart showing the reel control process executed by the MUP 102 of the main control device 101.

In the reel control process, first, a rotation start process for starting the rotation of each reel 32L, 32M, 32R is performed (S501). In the rotation start process, it is confirmed whether or not a predetermined weight time (for example, 4.1 seconds) has elapsed from the time when the reel started rotation in the previous game, and if not, the weight time has elapsed. Wait until you do. When the weight time has elapsed, the weight time for the next game is reset, and the motor control initialization process for setting the rotation start information in the motor control storage area (not shown) provided in the RAM 106 is performed. conduct. By performing this process, the stepping motor control process (see S106 in FIG. 15) of the timer interrupt process starts the stepping motor acceleration process, and the reels 32L, 32M, and 32R start rotating. Therefore, even if the player bets a predetermined number of medals and operates the start lever 41, the reels 32L, 32M, 32R may not start rotating immediately. After that, it waits until each reel 32L, 32M, 32R rotates at a constant speed at a predetermined rotation speed, and ends the rotation start processing. Further, the MPU 102 can generate a stop command by lighting and displaying a lamp (not shown) of each stop switch 42 to 44 when the rotation speed of each reel 32L, 32M, 32R becomes a constant speed. Is notified to the players and the like.

After the rotation start processing of S501, the pre-stop processing is performed by the processing of S502 to S505. In this pre-stop processing, it is first determined whether or not any of the stop switches 42 to 44 has been operated (S502). Then, when none of the stop switches 42 to 44 is operated (S502: No), the process of S502 is repeatedly executed to wait until any of the stop switches 42 to 44 is operated.

On the other hand, if it is determined that any of the stop switches 42 to 44 has been operated (S502: Yes), the process proceeds to S503, and whether or not the stop switch corresponding to the rotating reel has been operated, that is, a stop command. Is determined (S503). Then, if the stop command has not been generated (S503: No), the process returns to the process of S502 and waits until any of the stop switches 42 to 44 is operated. As a result, if the stop switch corresponding to the non-rotating reel is operated, it is ignored.

On the other hand, when the stop command is generated (S503: Yes), then whether or not the stop command this time is the third stop command, that is, whether or not the stop switch is operated when only one reel is rotating. (S504). If the stop command this time is the third stop command (S504: Yes), the subsequent process of S505 is skipped, the pre-stop process is terminated as it is, and the process proceeds to the process of S506. On the other hand, in the case of the first stop command generated when all the reels 32L, 32M, 32R are rotating, or the second stop command generated when the two reels are rotating (S504: Yes), The process proceeds to S505, the slide table first change process is performed, and the pre-stop process is terminated. Then, the process proceeds to S506.

Here, the slide table first change process is a process of changing the slide table stored in the slide table storage area 106b of the RAM 106 before stopping the reel corresponding to the stop command. In the slide table first change process, for example, when the stop switches 43 and 44 other than the left stop switch 42 are operated and the first stop command is generated, the slide table is changed.

By the way, when the pre-stop processing of S502 to S505 is completed, it means that the stop switch corresponding to the rotating reel is operated to advance the game, and the stop command is generated. In such a case, in order to stop the rotating reel, the stop control process shown in S506 to S512 is then performed.

First, in S506, the symbol number of the arrival symbol reaching the lower stage is confirmed at the timing when the stop switch is operated. Specifically, the symbol number of the arrival symbol reaching the lower stage is confirmed by the number of excitation pulses output from the time when the detection signal of the reel index sensor is input. Subsequently, the number of reels to be stopped this time is calculated from the data of the symbol number corresponding to the reached symbol in the slide table set in the slide table storage area 106b (S507). After that, the calculated number of slips is added to the symbol number of the reached symbol, and the symbol number of the stopped symbol to be actually stopped is determined in the lower row (S508). Then, it is determined whether or not the symbol number of the arrival symbol of the reel to be stopped this time and the symbol number of the stopped symbol are equal (S509), and if they are not equal (S509: No), the process of S509 is repeatedly executed. If they become equal (S509: Yes), a reel stop process for stopping the rotation of the reel is performed (S510). After that, it is determined whether or not all reels 32L, 32M, 32R have stopped (S511), and if all reels 32L, 32M, 32R have not stopped (S511: No), the second slide table change process is performed. Do (S512). Then, the process returns to the process of S502, and the pre-stop process is executed again.

Here, the slide table second change process is a process of changing the slide table stored in the slide table storage area 106b of the RAM 106 after the reels are stopped. In the second slide table change process, the slide table is changed based on the set winning flag and the stop result of the stopped reel. For example, in a situation where only the bell winning flag is set, if the 12th "bell" symbol on the left reel 32L and the 12th "bell" symbol on the middle reel 32M are stopped in the middle row, the left reel 32L is on the upper row. Since the 13th symbol of No. 13 and the 13th "7" symbol of the middle reel 32M are stopped, the sliding table is changed in order to avoid the establishment of the BB prize.

On the other hand, if it is determined in the process of S511 that all reels 32L, 32M, 32R are stopped (S511: Yes), the payout determination process is performed (S513). The payout determination process is a process of setting the number of medals to be paid out on the condition that the combinations of winning symbols are lined up on the valid line.

In the payout determination process, a combination of symbols formed on each effective line is derived from the symbol number of the stopped symbol stopped at the lower stage of each reel 32L, 32M, 32R, and whether or not a prize is established on the effective line. To judge. If the winning is established, it is further determined whether or not the winning winning combination matches the winning flag set in the winning flag storage area 106a. When the winning winning combination and the winning flag match, the winning winning combination and the number of payouts corresponding to the winning winning combination are set in the payout information storage area (not shown) provided in the RAM 106. On the other hand, if the winning combination and the winning flag do not match, the slot machine 10 is put into an error state and an abnormality occurrence process for notifying the occurrence of an error is performed. This error state is maintained until the reset switch 72 is operated. When the payout determination is completed for all valid lines, the payout determination process is terminated.

Then, a payout determination result command for notifying the display control device 81 of the result of the payout determination performed by the payout determination process is set (S514), and the reel control process is terminated. The payout determination result command set here is transmitted to the display control device 81 by the command output process (S110 in FIG. 15) of the timer interrupt process. The display control device 81 receives the payout determination result command, and the payout determination result grasped by the payout determination result command, the number of bets placed on the game in which the payout determination is made, and the slot machine 10 Based on the game state and the like of the above, the effect mode to be displayed on the auxiliary display unit 65 is set.

Next, the medal payout process of S212, which is a normal process (see FIG. 16), will be outlined. In the medal payout process, it is determined whether or not the number of payouts set in the payout information storage area (not shown) in the payout determination process of S513 in the reel control process (see FIG. 19) is 0. When the number of payouts is 0, it means that it is determined in the previous payout determination process (see S513 in FIG. 19) that the winning of the medal to be paid out has not been established. In such a case, it is determined whether or not the replay winning is established based on the winning winning combination set in the payout determination process. Then, if the replay winning is not established, the medal payout process is ended as it is, and if the replay winning is established, the replay state setting process for setting the game state to the replay state is performed, and the medal payout process is completed. do. In the start waiting process (see S204 in FIG. 16), which is executed in the normal process described above, the automatic input process is performed when it is determined that the current game state is the replay state.

On the other hand, if the number of payouts set in the payout information storage area is not 0, the same number of medals as the number of payouts is paid out, and the medal payout process is completed. Regarding the payout of medals Specifically, if the count value of the credit counter has not reached the upper limit (the number of stored medals is 50), the number of payouts is added to the count value of the credit counter and the value after addition is added. It is displayed on the credit display unit 60. If the count value of the credit counter has reached the upper limit, or if the count value reaches the upper limit during the addition of the number of payouts, the rotating plate for paying medals is driven and the medals are ejected from the hopper device 51. Pay out to the medal tray 50 via the exit 49. In the medal payout process, the number of payouts displayed on the payout number display unit 62 is also changed according to the payout of medals. Further, when the current gaming state is a bonus state, a process of subtracting the number of payouts from the value of the remaining payout number counter, which will be described later, and subtracting the number of remaining payouts displayed on the remaining payout number display unit 61 is performed. ..

Next, with reference to FIG. 20, the bonus state processing executed in the processing of S213 of the normal processing (see FIG. 15) will be described. FIG. 20 is a flowchart showing a bonus state process executed by the MPU 102 of the main control device 101.

First, the outline of this bonus state processing will be described. The bonus state processing is a game in which, when the gaming state of the slot machine 10 is in the bonus state, the game continuously shifts to the RB state until a predetermined number of medals are paid out (250 in this embodiment). be. Then, 12 JAC games are played in one RB state, and if a prize is established 8 times during the JAC game, the RB state is terminated even before the JAC game is played 12 times. Further, the bonus state is terminated when the number of medals paid out reaches a predetermined number, and when the number of medals paid out reaches a predetermined number in the middle of the RB state, not only the bonus state but also the RB state is terminated.

Next, the details of the bonus state processing will be described. In the bonus state processing, first, it is determined whether or not the gaming state of the slot machine 10 is the bonus state (S601), and when it is not the bona state (S601: No), the BB determination processing shown in S602 to S605 is executed.

In this BB determination process, first, it is confirmed whether or not the BB winning flag is set in the winning flag storage area 106a (S602), and when the BB winning flag is set (S602: Yes), the reel control is performed. It is confirmed whether or not the BB winning is established based on the winning winning combination set in the payout determination processing executed by the processing of S513 of the processing (see FIG. 19) (S603).

When the BB prize is established in the process of S603 (S603: Yes), the BB start process is executed (S604). In the BB start process, the BB winning flag stored in the winning flag storage area 106a is reset, the setting flag stored in the state information storage area 106c is cleared, and then the BB setting flag is set to the state information storage area 106c. Set to BB game, which is a kind of bonus game. Further, 250 is set in the remaining payout number counter provided in the state information storage area 106c for counting the number of remaining medals that can be paid out during the BB game, and 250 is displayed on the remaining payout number display unit 61. I do. Incidentally, the determination as to whether or not the current gaming state is a bonus state (see S601) is determined by the presence or absence of the BB setting flag set in the state information storage area 106c.

Subsequently, in the process of S605, the RB start process is executed (S605). In the RB start process, 8 is set in the remaining JAC winning counter for counting the number of possible JAC winnings, and 12 is set in the remaining JAC game counter for counting the remaining number of JAC games. Each counter such as the remaining JAC winning counter and the remaining JAC game counter is provided in the state information storage area 106c. Further, in the RB start process, a set of RB commands transmitted to the display control device 81 is also performed so that the RB game is started.

Next, in the process of S606, a state command is set (S607). Here, the state command is a command transmitted to the display control device 81 in order to grasp the current gaming state. That is, if it is determined in the processing of S602 that the BB winning winning flag is not set (S602: No), a state command indicating that the game is a normal game is set, and the BB winning is established in the processing of S603. If it is determined that the game has not been performed (S603: No), a state command indicating that the game is a BB carry-over game is set, and if an RB command is set in the process of S605, it means that the game is a BB game. Set the status command.

Then, after the processing of S607, the game number display processing is performed (S607), and this processing is terminated. In the game number display process, when the current game state is not a BB game (RB game), a process of clearing the display of the remaining payout number display unit 61, the payout number display unit 62, or the like is performed.

Further, in the process of S601, when the game state is the bonus state (S601: Yes), the winning combination set in the payout determination process executed in the process of S513 of the reel control process (see FIG. 19) is small. It is confirmed whether or not the watermelon prize or the bell prize, which is the role prize, has been established (S608). When the watermelon winning or the bell winning is established in the process of S608 (S608: Yes), the value of the remaining JAC winning counter is subtracted by 1 (S609), and the value of the remaining JAC game counter is further subtracted by 1 (S610). Further, when the watermelon winning and the bell winning are not established (S608: No), one JAC game is exhausted, so the value of the remaining JAC game counter is subtracted by 1 without performing the processing of S609 (S608: No). S610).

Subsequently, in the process of S611, it is confirmed whether or not either the remaining JAC winning counter or the remaining JAC game counter becomes 0 (S611). It means that the end condition of the RB game is satisfied when any of them becomes 0 in the processing of S611, that is, when the JAC winning is established 8 times or the JAC game is digested 12 times (S611: Yes). Therefore, the RB end process for resetting the values of the remaining JAC winning counter and the remaining JAC game counter is executed (S612). As a result, if the JAC game is played 12 times in one RB state and the winning is established 8 times during the JAC game, the RB state can be terminated even before the JAC game is played 12 times.

Then, it is confirmed whether or not the count value of the remaining payout counter is 0 (S613), and if it is not 0 (S613: No), the number of medals paid out during the BB game has not reached the predetermined number. , Since it means that the end condition of the BB game is not satisfied, the above-mentioned RB start process is executed (S614). After that, a state command indicating that the game is a BB game is set (S606), a game number display process is executed (607), and this process ends.

On the other hand, when neither the remaining JAC winning counter nor the remaining JAC game counter is 0 in the processing of S611, that is, when the JAC winning has not been established 8 times and the JAC game has not been digested 12 times. (S611: No), it is confirmed whether or not the count value of the remaining payout counter is 0 (S615). If the counter value is not 0 in the process of S615 (S615: No), it means that the number of medals paid out during the BB game has not reached the predetermined number and the end condition of the BB game is not satisfied. Therefore, a state command indicating that the game is a BB game is set (S606), a game number display process is executed (S607), and this process is terminated.

On the other hand, in the process of S615, when the count value of the remaining payout counter is 0 (S615: Yes), it means that the end condition of the BB game is satisfied, so that the bonus state end process shown in S616 to S617 is satisfied. To execute. In the bonus state end process, first, the RB end process described above is executed (S616), and then the BB end process for clearing the data in the state information storage area 153b is executed (S617). Further, even when the count value of the remaining payout counter is 0 in the above-mentioned processing of S613 (S613: Yes), it means that the ending condition of the BB game is satisfied, so that the BB ending processing of S617 is executed. do. After performing the BB end process, a state command indicating that the game is a normal game (that is, a general game state) is set (S606), a game number display process is performed (S607), and this process is terminated. As a result, the bonus state can be terminated when the number of medals paid out reaches 250. Further, when the number of medals paid out reaches 250 in the middle of the RB state, not only the bonus state but also the RB state can be terminated by the processing of S616.

Next, with reference to FIGS. 21 to 31, each control process executed by the MPU 181 of the display control device 81 will be described. The processing of the MPU 181 is roughly divided into a display main processing that is repeatedly executed after the power is turned on, a command interrupt processing that is executed when a command is received from the main control device 101, and one frame of the image controller 188. There is a V interrupt process executed when the MPU 181 detects a V interrupt signal transmitted every 20 milliseconds when the image drawing process is completed. Normally, the MPU 181 executes the main process, and executes the command interrupt process and the V interrupt process in accordance with the reception of the command and the detection of the V interrupt signal. When the command reception and the V interrupt signal detection are performed at the same time, the command reception process is preferentially executed. As a result, the V interrupt process can be executed by quickly reflecting the content of the command received from the main control device 101.

First, the display main process executed by the MPU 181 in the display control device 81 will be described with reference to FIG. 21. FIG. 21 is a flowchart showing this display main process. The display main process executes the initialization process when the power is turned on.

Specifically, the activation of this display main process is performed according to the following flow. When the power is turned on from the power supply device 91 to the display control device 81 and the system reset is released, the MPU 181 sets the instruction pointer 181a provided in the MPU 181 to "0000H" according to its hardware configuration. , The address "0000H" indicated by the instruction pointer 181a is specified for the internal bus. When the ROM controller 187b of the character ROM 187 detects that the address specified in the internal bus is "0000H", the boot program stored in the first program storage area 187d1 of the NOR type ROM 187d is set in the buffer RAM 187c. The corresponding data (instruction code) is output to MPU181. Then, the MPU 181 fetches the instruction code received from the character ROM 187, and starts the execution of the process according to the fetched instruction to start the display main process.

Here, if all the boot programs initially processed by the MPU 181 after the system reset is released are stored in the NAND flash memory 187a, the character ROM 187 detects that the address specified in the internal bus is "0000H". Then, one page of data including the data (instruction code) corresponding to the address "0000H" must be read from the NAND flash memory 187a and set in the buffer RAM 187c. Due to the nature of the NAND flash memory 187a, it takes a lot of time to set the buffer RAM 187c from its read, so the MPU181 receives the instruction code corresponding to the address "0000H" after designating the address "0000H". It will consume a lot of waiting time. Therefore, it takes a long time to start the MPU 181. As a result, there is a problem that the control of the auxiliary effect unit in the display control device 81 may not be started immediately.

On the other hand, as in the present embodiment, among the boot programs, a predetermined number of instructions from the instruction to be processed first by the MPU 181 after the system reset is released are stored in the NOR type ROM 187d, so that the NOR type ROM has a high speed. Since it is a memory capable of reading data, when the address "0000H" is specified from the MPU181 via the internal bus after the system reset is released, the character ROM 187 is immediately stored in the first program storage area 187d1 of the NOR type ROM 187d. The boot program that has been reset can be set in the buffer RAM 187c, and the corresponding data (instruction code) can be output to the MPU 181. Therefore, since the MPU 181 can receive the instruction code corresponding to the address "0000H" in a short time after designating the address "0000H", the MPU 181 can start the main process in a short time. Therefore, even if the control program is stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the control of the auxiliary effect unit in the display control device 81 can be started immediately.

When the display main process is executed as described above, first, the boot process executed by the boot program is executed (S701), and the display control device 81 is started so that various controls for the auxiliary effect unit can be executed. do. Here, the boot process (S701) will be described with reference to FIG. 22. FIG. 22 is a flowchart showing a boot process (S701) executed in the display main process in the MPU 181 of the display control device 81.

As described above, in the present embodiment, the fixed value data for driving the control program executed by the MPU 181 and the upper lamp 63 is a dedicated program ROM (for example, the above-mentioned patent document) like a conventional gaming machine. The ROM 22) of 1 is not provided and stored, but is stored in the character ROM 187 provided for storing the image data to be displayed on the auxiliary display unit 64. Since the character ROM 187 is composed of a NAND flash memory 187a capable of increasing the capacity in a small area, it is possible to sufficiently store not only the image data but also the control program and the like, while controlling the character ROM 187. It is not necessary to provide a dedicated program ROM for storing programs and the like. Therefore, the number of parts in the display control device 81 can be reduced, the manufacturing cost can be reduced, and the increase in the failure occurrence rate due to the increase in the number of parts can be suppressed.

On the other hand, since the NAND flash memory has a slow read speed especially when performing random access, if the MPU 181 directly reads and processes the control program and fixed value data stored in the NAND flash memory 187a, the MPU 181 is used. Even if a high-performance processor is used, the processing performance of the display control device 91 may be deteriorated. Therefore, in this boot process, the control program and fixed value data stored in the second program storage area 187a1 of the NAND flash memory 187a are stored in the program storage area 185c and the data table provided in the work RAM 185 configured by the DRAM. The process of transferring to the storage area 185d and storing the data is executed.

Specifically, first, based on the above-mentioned operation by the hardware of the MPU 181 and the character ROM 187, after the system reset is released, the program is read from the first program storage area 187d1 of the NOR type ROM 187d and set in the buffer RAM 187c according to the boot program. 2 Of the control programs stored in the program storage area 187a1, only a predetermined amount is transferred to the program storage area 185c (S711). The predetermined amount of control programs transferred here includes the remaining boot programs that are not stored in the first program storage area 187d1.

Then, the instruction pointer 181a is set to the first predetermined address of the program storage area 185c, that is, the start address of the remaining boot program stored in the program storage area 185c (S712). As a result, the MPU 181 starts executing the remaining boot programs included in the control program transferred and stored in the program storage area 185c by the processing of S711.

Further, by setting the instruction pointer 181a to the predetermined address of the program storage area 185c by the processing of S712, the MPU 181 executes various processing while reading the control program stored in the program storage area 185c of the work RAM 185. become. That is, the MPU 181 does not read the control program from the NAND flash memory 187a having the second program storage area 187a1 and fetch the instructions, but reads the control program transferred to the work RAM 185 having the program storage area 185c and fetches the instructions. And execute various processes. As described above, since the work RAM 185 is composed of the DRAM, the read operation is performed at high speed. Therefore, even when the control program is stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the MPU 181 can fetch the instruction at high speed and execute the processing for the instruction.

When the instruction pointer 181a is set by the process of S712, it is subsequently stored in the second program storage area 187a1 of the NAND flash memory 187a according to the remaining boot programs whose execution is started by the set instruction pointer 181a. The remaining control programs and fixed value data that have not been transferred to the program storage area 185c among the control programs are transferred to the program storage area 185c or the data table storage area 185d in predetermined amounts (S713). Specifically, the control program is transferred to the program storage area 185c, and various data tables (display data table, transfer data table) are transferred to the data table storage area 185d.

Then, after executing other processing necessary for the boot processing (S714), the instruction pointer 181a is executed at the second predetermined address of the program storage area 185c, that is, after the boot processing (see S701 in FIG. 21) is completed. By setting the start address of the program corresponding to the power initialization process (see S702 in FIG. 21) (S715), the execution of the boot program is completed and the boot process is completed.

By executing the boot process (S701) in this way, the control program and the fixed value data stored in the second program storage area 187a1 of the NAND flash memory 187a are all stored in the work RAM 185 configured by the DRAM. It is transferred to and stored in the program storage area 185c and the data table storage area 185d. Then, at the end of the boot process, the instruction pointer 181a is set to the above-mentioned second predetermined address, and thereafter, the MPU 181 transfers the control program to the program storage area 185c without referring to the NAND flash memory 187a. Use to perform various processes.

Therefore, even when the control program is stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the control program and the fixed value data are stored in the program storage area 185c of the work RAM 185 and the program storage area 185c of the work RAM 185 after the system reset is released. By transferring to the data table storage area 185d, the MPU 181 can read a control program and fixed value data from a work RAM composed of a DRAM having a high read speed and perform various controls. Therefore, in the display control device 81. High processing performance can be maintained, and diversified and complicated effects can be easily executed by using the auxiliary effect unit.

On the other hand, instead of storing all the boot programs in the NOR type ROM 187d, a predetermined number of instructions are stored from the instruction to be processed first by the MPU 181 after the system reset is released, and the remaining boot programs are stored in the NAND flash memory 187a. Even if the control program is stored in the second program storage area 187a2, the control program stored in the second program storage area 187a1 can be reliably transferred to the program storage area 185c. Therefore, the character ROM 187 can start the MPU 181 in a short time only by adding an extremely small capacity NOR type ROM 187d, so that the cost increase of the character ROM 187 due to the shortening of the time can be suppressed. Can be done.

In the boot process shown in FIG. 22, the predetermined amount of control programs transferred to the program storage area 185c by the process of S711 includes all the remaining boot programs not stored in the first program storage area 187d1. Although configured, the control program is not necessarily limited to this, and a predetermined amount of control programs transferred to the program storage area 185c by the processing of S711 is a boot program that executes a boot processing to be processed following the processing of S712. May be part of. The boot program transferred here transfers the control program including all the remaining boot programs to the program storage area 185c by a predetermined amount, and further, the start address of the boot program stored in the program storage area 185c is indicated by an instruction pointer. It may execute the process set in 181a. Then, the processes of S713 to S715 may be executed by all the remaining boot programs stored in the program storage area 185c.

Further, the boot program transferred by the process of S711 further transfers a part of the remaining boot program to the program storage area 185c by a predetermined amount, and subsequently, the head of the boot program stored in the program storage area 185c. The process of setting the address to the instruction pointer 181a may be executed. Further, a part of the boot programs stored in the program storage area 185c by this process further transfers a part of the remaining boot programs to the program storage area 185c by a predetermined amount, and subsequently to the program storage area 185c. The process of setting the start address of the stored boot program to the instruction pointer 181a may be executed. Then, a part of the remaining boot program is transferred to the program storage area 185c by a predetermined amount, and subsequently, the process of setting the start address of the boot program stored in the program storage area 185c to the instruction pointer 181a is performed in S711. After repeating the process a plurality of times including the process of S712 and S712, the processes of S713 to S715 may be executed.

As a result, even if the program size of the boot program is large and the remaining boot programs not stored in the first program storage area 187d1 cannot be transferred to the program storage area 185c at a time, the MPU 181 is already stored in the program storage area 185c. The boot program can be used to transfer a predetermined amount to the program storage area 185c.

Further, in the present embodiment, a case has been described in which a part of the boot program executed by the MPU 181 is first stored in the first program storage area 187d1 when the system reset is released, but all the boot programs are stored in the first program storage area 187d1. It may be stored in one program storage area 187d1. In this case, when the boot process is started, the MPU 181 may execute the processes of S713 to S715 without performing the processes of S711 and S712. This eliminates the need for the process of transferring the boot program to the program storage area 185c, so that the number of times the program is transferred to the character ROM 187 or the program storage area 185c is reduced, so that the processing time of the boot process can be reduced. Therefore, it is possible to start the control of the auxiliary effect unit in the MPU 181 which becomes possible after the boot process earlier.

When the boot process is completed, the initial setting process is then executed according to the control program transferred and stored in the program storage area 185c of the work RAM 185 (S702). Specifically, the value of the stack pointer is set in the MPU181, and various settings are made for the register group in the MPU181, the I / O device, and the like. Further, a process of clearing the storage of the work RAM 185, the resident video RAM 189, and the normal video RAM 190 is performed. Further, various flags are provided in the work RAM 185, and initial values are set for each flag. As the initial value of each flag, "off" or "0" is set unless otherwise specified.

Next, a transfer instruction is transmitted to the image controller 188 so that the image data corresponding to the main image at power-on is transferred to the main image area 189a at power-on of the resident video RAM 189 (S703). In this transfer instruction, the start address and the last address of the character ROM 187 in which the image data corresponding to the main image at power-on is stored, the information of the transfer destination (here, the resident video RAM 189), and the transfer destination. The start address of the main image area 189a at power-on is included, and the image controller 188 receives the image data corresponding to the main image at power-on from the character ROM 187 to the resident video RAM 189 at power-on according to this transfer instruction. It is transferred to the image area 189a.

Then, when all the transfer of the image data indicated by the transfer instruction is completed, the image controller 188 transmits a transfer end signal indicating the end of transfer to the MPU 181. By receiving this transfer end signal, the MPU 181 can grasp that the transfer of the image data specified in the transfer instruction has been completed. Here, the image data transferred to the main image area 189a when the power is turned on is retained so as not to be overwritten until the power is turned off.

When the image controller 188 completes the transfer of all the image data indicated by the transfer instruction, the image controller 188 transmits the transfer end information indicating the transfer end to a register provided inside the image controller 188 or a part of the built-in memory. You may write it. Then, the MPU 181 reads out the information of a part of this register or the built-in memory at any time, and detects the writing of the transfer end information by the image controller 188, thereby grasping that the transfer of the image data specified by the transfer instruction is completed. You may do so.

When the transfer of the image data corresponding to the power-on main image to the power-on main image area 189a is completed based on the transfer instruction transmitted to the image controller 188 by the process of S703, then the simple image display flag 185e Is turned on (S704). As a result, while the simple image display flag 185e is on, all the image data that should be resident in the resident video RAM 189 is transferred from the character ROM 187 to the resident video RAM 189 in the transfer setting process (see FIG. 29 (a)) described later. The resident image transfer setting process for instructing the image controller 188 to transfer the image is executed (see S817 in FIG. 29 (a)).

Further, the simple image display flag 185e transfers all the image data to be resident in the resident video RAM 189 from the character ROM 188 to the resident video RAM 189 based on the transfer instruction to the image controller 188 by the resident image transfer setting process. It stays on until it finishes. As a result, during that time, the simple display setting process (see S728 in FIG. 23 (b)) is executed so that the main image is drawn when the power is turned on in the V interrupt process (see FIG. 23 (b)). ..

As described above, in the slot machine 10, since the NAND flash memory 187a is used for the character ROM 187, all the image data to be stored in the resident video RAM 189 due to its slow read speed can be stored in the resident video RAM 189. It takes a lot of time to transfer from the character ROM 187 to the resident video RAM 189. Therefore, as in this main process, after the power is turned on, the main image at the time of power-on is first transferred from the character ROM 187 to the resident video RAM 189, and the remaining image is displayed on the auxiliary display unit 65. While the image data to be resident is transferred to the resident video RAM 189, the player and the person concerned with the hall can confirm the main image at power-on displayed on the auxiliary display unit 65. Therefore, the display control device 81 may transfer the remaining resident image data from the character ROM 187 to the resident video RAM 189 over time while displaying the main image at power-on on the auxiliary display unit 65. can. On the other hand, the player or the like can recognize that some processing is being performed while the main image is displayed on the auxiliary display unit 65 when the power is turned on, so that the image data to be resident in the remaining resident video RAM 189 can be stored. Until the transfer from the character ROM 187 to the resident video RAM 189, it is possible to wait until the transfer of the image data to be resident is completed without worrying that the operation has stopped.

Further, even in the operation check in the factory at the time of manufacturing, the main image at the time of turning on the power is immediately displayed on the auxiliary display unit 65, so that the auxiliary display unit 65 is started to operate without any problem by turning on the power. It can be confirmed immediately, and by using the NAND flash memory 187a having a slow read speed for the character ROM 187, it is possible to suppress the deterioration of the operation check efficiency.

After the processing of S704, the interrupt permission is set (S705). As a result, when the command is received and the V interrupt signal is detected, the display main process is stopped, and the command interrupt process (see FIG. 73 (a)) and the V interrupt process (FIG. 73 (b)) described later are stopped. ) Is executed.

Next, it is confirmed whether or not the system state is in the voltage drop state, that is, whether or not the drive voltage has dropped to a predetermined voltage (less than 10 volts in this embodiment) (S706), and when the system state is not in the voltage drop state. (S706: No), the process of S706 is repeatedly executed. That is, when the display main process starts the process of S706, the process of S706 continues to be executed until the system state becomes the voltage drop state. Then, the MPU 181 repeatedly executes the process of S706, and executes the command interrupt process and the V interrupt process according to the reception of the command and the detection of the V interrupt signal.

On the other hand, when it is confirmed by the process of S706 that the system state is a voltage drop state (S706: Yes), it is determined that the power supply has been cut off, and the power failure process is executed (S707). Then, an infinite loop process is executed in the power failure process of S707 until the power supply is completely cut off.

Next, the command interrupt process executed by the MPU 181 of the display control device 81 will be described with reference to FIG. 23 (a). FIG. 23A is a flowchart showing the command interrupt process. As described above, when the display control device 81 receives a command from the main control device 101, the display control device 81 latches the received command by the signal latch circuit 182 and generates a command reception interruption signal. The MPU181 executes this command interrupt process triggered by the generation of this command interrupt signal.

In this command interrupt process, the commands latched by the signal latch circuit 182 are extracted, the extracted commands are sequentially stored in the command buffer area 185a provided in the work RAM 185 (S720), and the command is terminated. Various commands stored in the command buffer area 185a by this command interrupt processing are sequentially read by the command determination processing of the V interrupt processing described later, and processing is performed according to the contents of the read commands.

Next, the V interrupt process executed by the MPU 181 of the display control device 81 will be described with reference to FIG. 23 (b). FIG. 23B is a flowchart showing the V interrupt process. In this V interrupt process, various processes corresponding to the commands stored in the command buffer area are executed by the command interrupt process, and after specifying the image to be displayed on the auxiliary display unit 65, the drawing list of the image ( By creating (see FIG. 14) and transmitting the drawing list to the image controller 188, the image controller 188 is instructed to execute the drawing process and the display processing of the image.

As described above, the execution of this V interrupt process is started when the V interrupt signal from the image controller 188 is detected. This V interrupt signal is a signal generated by the image controller 188 every 20 milliseconds when the drawing process of an image for one frame is completed and transmitted to the MPU 181. Therefore, by executing the V interrupt process in synchronization with this V interrupt signal, a drawing instruction is given to the image controller 188 every 20 milliseconds when the drawing process of the image for one frame is completed. become. Therefore, in the image controller 188, since the drawing instruction of the next image is not received at the stage where the drawing processing and the display processing of the image are not completed, the drawing of a new image may be started in the middle of drawing the image. It is possible to prevent the image from being expanded in accordance with a new drawing instruction in the frame buffer in which the image information being displayed is stored.

Here, first, the outline of the flow of the V interrupt processing will be described, and then the details of each processing will be described with reference to other drawings. In this V-interruption process, as shown in FIG. 23B, first, it is determined whether or not the simple image display flag 185e is on (S721), and the simple image display flag 185e is not on, that is, If it is off (S721: No), it means that the transfer of all the image data that should be resident in the resident video RAM 189 is completed, so that the normal production image is displayed as an auxiliary display instead of the main image when the power is turned on. The command determination process (S722) is executed so that the unit 65 can display the image, and then the display setting process (S723) is executed.

In the command determination process (S722), the content of the command from the main control device 101 stored in the command buffer area 185a is analyzed by the command interrupt process, the process corresponding to the command is executed, and the lottery result command and the payout are executed. When the determination result command is stored, the number of bets at the time of the lottery, the game state of the slot machine 10, the result of the lottery (determination of the winning combination) grasped by the lottery result command, or the payout determination result command is grasped. The display data table according to various production modes determined according to the result of the payout determination to be made is set in the display data table buffer 185f, and the transfer data table corresponding to the set display data table is set in the transfer data table buffer. Set to 185 g.

In this command determination process, all commands stored in the command buffer area at that time are sequentially read and analyzed, and the process is executed. This is because the command determination process is performed at intervals of 20 milliseconds when the V interrupt process is executed, so there is a high possibility that multiple commands are stored in the command buffer area during that 20 milliseconds. be. In particular, in the main control device 101, when the start lever 41 is operated to determine the start of the game when the number of bets has reached the specified number, the start command, the lottery result command, and the like are simultaneously stored in the command buffer area. There is a high possibility that it is. Therefore, by analyzing and executing all of these commands in one command determination process, the number of bets and the lottery result (determination of the winning combination) can be quickly grasped, and the effect image corresponding to them is displayed on the auxiliary display unit 65. It is possible to control the drawing of the image so as to make it. The details of this command interrupt process will be described later with reference to FIGS. 24 to 27.

In the display setting process (S723), the content of the image for one frame to be displayed next in the auxiliary display unit 65 based on the content of the display data table set in the display data table buffer 185f by the command determination process (S722) or the like. Is specifically specified. The details of this display setting process will be described later with reference to FIG. 28.

After the display setting process is executed, the task process is then executed (S724). In this task process, the image is configured based on the content of the image for the next frame to be displayed on the auxiliary display unit 65 specified by the display setting process (S723) or the simple display setting process (S728) described later. In addition to specifying the type of sprite (display object) to be displayed, various parameters necessary for drawing such as the display coordinate position, the enlargement ratio, and the rotation angle are determined for each sprite.

Next, the transfer setting process is executed (S725). In this transfer setting process, while the simple image display flag 185e is on, the image controller 188 transfers the image data to be resident in the resident video RAM 189 from the character ROM 187 to a predetermined area of the resident video RAM 189. Set instructions. Further, while the simple image display flag 185e is off, predetermined image data is normally used from the character ROM 187 to the image controller 188 based on the transfer data information of the transfer data table set in the transfer data table buffer 185 g. Set a transfer instruction to transfer to a predetermined sub-area of the image storage area 190a of the video RAM 190. The details of the transfer setting process will be described later with reference to FIGS. 50 and 30.

Next, the drawing process is executed (S726). In this drawing process, the types of various sprites constituting one frame, the parameters required for drawing each sprite, and the transfer instruction set by the transfer setting process (S725), which are determined in the task process (S724), are used. , The drawing list shown in FIG. 14 is generated, and the drawing list is transmitted to the image controller 188 together with the drawing target buffer information. As a result, the image controller 188 executes the image drawing process according to the drawing list. The details of the drawing process will be described later with reference to FIG. 31.

Next, update processing of various counters provided in the display control device 81 is executed (S727). Then, the V interrupt process is terminated. As the counter updated by the process of S727, for example, there is a random number counter (not shown) for determining the effect mode to be displayed on the auxiliary effect unit 65. The value of this random number counter is stored in the work RAM 185, and the update process is performed every time the V interrupt process is executed. When the lottery result command and the payout determination result command are stored in the command determination process, the number of bets at the time of the lottery, the game state of the slot machine 10, and the lottery (combination) grasped by the lottery result command. The effect mode to be displayed on the auxiliary effect unit 65 is finally set according to the result of the determination), the result of the payout determination grasped by the payout determination result command, and the value of the random number counter.

On the other hand, if it is determined in the process of S721 that the simple image display flag is ON (S721: Yes), it means that the transfer of all the image data that should be resident in the resident video RAM 189 has not been completed. , The simple display setting process (S728) is executed in order to display the main image when the power is turned on on the auxiliary display unit 65, and the process shifts to the process of S724. In this simple display setting process, the main image at power-on is specified as the image for the next frame to be displayed on the auxiliary display unit 65. Then, as information necessary for drawing the main image when the power is turned on, the type of sprite (display unit) constituting the image, the display coordinate position and enlargement ratio of each sprite, the rotation angle, the translucent value, the α blending information, Expand various parameters required for drawing such as color information and filter specification information. In the task processing (S724), based on the expanded image information, the type of sprite (display object) constituting the image for the next frame to be displayed on the auxiliary display unit 65 is specified, and each sprite is specified. In addition, various parameters necessary for drawing such as display coordinate position, enlargement ratio, rotation angle, semi-transparency value, α blending information, color information, and filter specification information are determined.

Here, even if the transfer of all the image data to be resident in the resident video RAM 189 from the character ROM 187 is not completed, the V interrupt processing is performed by the display main processing (see FIG. 21) for interrupt permission setting (see FIG. 21). Since it is executed after the processing of S705) is executed, the image data necessary for drawing the main image at power-on is the display main processing (Fig.) At the time when the simple display setting processing and the task processing are executed. By the process of S703 (see 21), the resident video RAM 189 is stored in advance in the main image area 185a when the power is turned on. Therefore, the image controller 188 is a character ROM 187 of all image data that should be resident in the resident video RAM 189 when an image drawing instruction regarding the main image at power-on is given from the MPU 181 based on a process such as a simple display setting process. Even if the transfer from is not completed, the image can be drawn immediately by using the image data stored in the main image area 189a when the power is turned on.

Next, with reference to FIGS. 24 to 27, the details of the above-mentioned command determination process (S722), which is one of the V interrupt processes executed by the MPU 181 of the display control device 81, will be described. First, FIG. 24 is a flowchart showing this command determination process.

In this command determination process, as shown in FIG. 24, first, it is determined whether or not there is an unprocessed new command in the command buffer area 185a (S731), and if there is no unprocessed new command (S731: No). , Ends the command judgment process and returns to the V interrupt process. On the other hand, if there is an unprocessed new command (S731: Yes), the new command flag is set to ON (S732). This new command flag notifies the display setting process (S723) that a new command has been processed in the ON state, and is initialized to the OFF state in the initialization process immediately after the power is turned on (see S702 in FIG. 21). Ru.

Next, among the unprocessed commands stored in the command buffer area 185a, the type of the command stored in the past is analyzed (S733). Then, it is determined whether or not the analyzed command is a state command (S734), and if it is a state command (S734: Yes), the state command process is executed (S735), and the process returns to the process of S731. As described above, the state command is a command transmitted from the main control device 101 to the display control device 81 in order to grasp the current gaming state.

Here, the details of the state command processing (S735) will be described with reference to FIG. 25 (a). FIG. 25A is a flowchart showing a state command process executed by the MPU 181 of the display control device 81. This state command process executes the process corresponding to the state command received from the main control unit 101.

In the state command processing, one of a normal game, a BB carry-over game, and a BB game is extracted from the state command as the game state of the slot machine 10 (S751), and the extracted game state is stored in the work RAM 185. (S752), this process is terminated.

When the display control device 81 receives the lottery result command or the payout determination result command, the display control device 81 refers to the game state stored in the work RAM 185 by this state command process, and sets the game state of the slot machine 10 at that time as the normal game, BB. Know whether it is a carry-over game or a BB game. Then, in setting the effect mode to be executed by the auxiliary effect unit based on the lottery result command or the payout determination result command, the effect mode corresponding to the game state of the grasped slot machine 10 is selected.

The explanation will be continued by returning to FIG. 24. In the processing of S734, if it is determined that it is not a state command (S734: No), then it is determined whether or not the command analyzed by the processing of S733 is a start command (S736), and if it is a start command, it is determined. (S736: Yes), the start command process is executed (S737), and the process returns to the process of S731. As described above, the start command is a command from the main control device 101 to notify the display control device 81 that the start lever 41 has been operated and a game start command has been issued.

Here, the details of the start command processing (S737) will be described with reference to FIG. 25 (b). FIG. 25B is a flowchart showing a start command process executed by the MPU 181 of the display control device 81. This start command process executes the process corresponding to the start command received from the main control unit 101.

In this start command process, first, information on the number of bets included in the start command is extracted (S756), information on the extracted bet number is stored in the bet number storage area 185b of the work RAM 185 (S757), and this process is performed. finish. As described above in the description of S209 of FIG. 16, the number of bets suggested by the information contained in the start command is the medal inserted by the player for the game in which the start command has been indicated by the start command. By storing the information regarding the number of bets in the bet number storage area 185b, the display control device 81 can produce an effect according to the number of bets placed on the game by the auxiliary effect unit (upper lamp 63, speaker). 64, the auxiliary display unit 65) can be used to select the effect mode.

The explanation will be continued by returning to FIG. 24. In the process of S736, if it is determined that it is not a start command (S736: No), then it is determined whether or not the command analyzed by the process of S733 is a lottery result command (S738), and the lottery result command is used. If there is (S738: Yes), the lottery result command process is executed (S739), and the process returns to the process of S731. As described above, the lottery result command is a command for notifying the display control device 81 of the result of the winning / failing determination of the winning combination performed by the main control device 101 when the start lever 41 is operated by the player.

Here, the details of the lottery result command processing (S739) will be described with reference to FIG. 26. FIG. 26 is a flowchart showing a lottery result command process executed by the MPU 181 of the display control device 81. This lottery result command processing executes the processing corresponding to the lottery result command received from the main control device 101, and is an auxiliary display according to the result of the lottery (determination of the winning combination) grasped by the lottery result command. The effect mode to be executed is determined in the auxiliary effect unit such as unit 65, the display data table corresponding to the determined effect mode is set in the display data table buffer 185f, and the set display data table is supported. The transfer data table to be transferred is set in the transfer data table buffer 185 g.

In the lottery result command processing, first, the information regarding the number of bets stored in the bet number storage area 185b is confirmed, and whether the number of bets placed on the game for which the start command is indicated by the start command is three. It is determined whether or not (S761). When the number of bets is three (S761: Yes), one of the production modes corresponding to the number of bets is one as the production mode of the effect to be executed by the auxiliary production unit including the auxiliary display unit 65. The production mode is determined (S762), and the process proceeds to S772. Specifically, in addition to the winning combination grasped by the lottery result command, any one of the gaming state (normal game state, BB game state, and BB carry-over game state) of the slot machine 10 notified by the state command and stored in the work RAM 185. ) And the value of the random number counter provided in the work RAM 185, and one of the effect modes corresponding to the number of bets of 3 is determined. By determining the effect mode, the driving of each auxiliary effect unit is started so that the effect is executed in the determined effect mode. The process of migrating to S772 will be described later.

On the other hand, if it is determined that the number of bets is not 3 as a result of the processing of S761 (S761: No), the number of bets placed on the game for which the start command is indicated by the start command is 1 or 2. It can be grasped that it is a sheet. Therefore, next, it is determined whether or not the winning combination grasped by the lottery result command, that is, the winning combination of the game started by the start command is the BB winning mode (S763). Then, when the BB winning mode is the winning combination (S763: Yes), the auxiliary display unit 65 is displayed with the message "BB winning combination!" As the effect mode of the effect to be executed by the auxiliary effect unit, and the winning combination. Determines the "BB prize notification effect" for notifying the player that the BB prize mode is (S764), and shifts to the process of S772. As a result, the driving of each auxiliary effect unit is started so that the BB prize announcement effect is executed.

Further, if the winning combination is not in the BB winning mode as a result of the processing of S763 (S763: No), then the winning combination grasped by the lottery command, that is, the winning combination of the game started by the start command is the watermelon winning combination. It is determined whether or not it is an embodiment (S765). If the watermelon winning mode is a winning combination (S765: Yes), the auxiliary display unit 65 is displayed with the message "Watermelon winning mode!" As the effect mode to be executed by the auxiliary effect unit, and the winning combination is displayed. Determines the "watermelon winning notification effect" for notifying the player that the watermelon winning mode is (S766), and shifts to the processing of S772. As a result, the driving of each auxiliary production unit is started so that the watermelon winning notification effect is executed.

Further, if the winning combination is not in the watermelon winning mode as a result of the processing of S765 (S765: No), then the winning combination grasped by the lottery command, that is, the winning combination of the game started by the start command is the bell winning combination. It is determined whether or not it is an embodiment (S767). Then, when the bell winning mode is a winning combination (S767: Yes), the auxiliary display unit 65 is displayed with the message "Bell winning combination!" As the effect mode of the effect to be executed by the auxiliary effect unit, and the winning combination. Determines the "bell winning notification effect" for notifying the player that the bell winning mode is used (S768), and proceeds to the process of S772. As a result, the driving of each auxiliary production unit is started so that the bell winning notification effect is executed.

In this way, the winning combination in the game in which the number of bets is set to 1 or 2 by the processing of S763 to S768 is any of the BB winning mode, the watermelon winning mode, and the bell winning mode. In that case, the auxiliary production unit can be made to execute the BB prize notification effect, the watermelon prize announcement effect, and the bell prize announcement effect to notify the player that the role has been won.

As described above, when the number of bets is one or two, the winning probabilities of the BB winning mode, the watermelon winning mode, and the bell winning mode are suppressed to be extremely low, so that the player can win the BB winning mode and the watermelon winning mode. There is a possibility that the game is played with the expectation that the cherry bell winning mode and the 7 bell winning mode will be established without expecting the establishment of the mode and the bell winning mode. Further, when the cherry bell winning mode or the 7 bell winning mode becomes a winning combination, the winning combination can be established without fail regardless of the timing at which the stop switches 42 to 44 are operated. A player who starts the game with two cards may operate the stop switches 42 to 44 at any timing. Therefore, if any one of the BB winning mode, the watermelon winning mode, and the bell winning mode is won as a winning combination, if the player does not notice it, the BB winning mode, the watermelon winning mode, and the bell winning mode are all missed. Since it is a winning mode that there is a risk, there is a risk that the winning combination will be missed. Further, since the winning of the BB winning mode is valid across the games until the BB winning mode is established, if the player ends the game without noticing the winning of the BB winning mode, another player However, there is a risk that the BB winning mode will be established based on the winning of the BB winning mode, and the player who has assigned the winning of the BB winning mode will lose as a result.

On the other hand, in the game in which the number of bets is set to one or two by the processing of S763 to S768, if any one of the BB winning mode, the watermelon winning mode, and the bell winning mode is won, the winning mode is won. Is announced by the BB prize announcement production, the watermelon prize announcement production, and the bell prize announcement production.

Here, as described above, in the present lottery result command processing, the command received from the main control device 101 is stored in the command buffer area 185a of the work RAM 185 by the command determination processing of the V interrupt processing executed by the MPU 181 every 20 ms. It is executed when it is determined that the command is a lottery result command. Therefore, the display control device 81 executes the main lottery result command processing until a maximum of 20 ms elapses after receiving the lottery result command. Further, the lottery result command controls the rotation of each reel 32L, 32M, 32R in the main control device 101 after the lottery (determination of winning or failing the winning combination) accompanying the game start command based on the operation of the start lever by the player is completed. It is set before the execution of the reel control process (see S211 in FIG. 16) to be performed (see S309 in FIG. 17), and then within about 1.5 ms at the latest (that is, after a time lag until the command is transmitted by the timer interrupt process). ), The lottery result command is transmitted to the display control device 81.

On the other hand, in the display control device 81, the image data corresponding to the image displayed on the auxiliary display unit 65 in various notification effects such as the BB prize notification effect, the watermelon prize announcement effect, and the bell prize announcement effect is the notification of the resident video RAM 189. It is resident in advance in the production image area 189d. Then, when the display control device 81 decides to perform the BB winning notification effect, the watermelon winning announcement effect, or the bell winning announcement effect based on the lottery result command received from the main control device 101, the character ROM 187 responds. Instead of reading out new image data, by reading out the image data resident in advance in the notification effect image area 189d of the resident video RAM 189, each notification effect image can be drawn by the image controller 188. There is. As a result, it is not necessary to read the sequentially corresponding image data from the character ROM 187. Therefore, even if the NAND flash memory 187a having a slow read speed is used for the character ROM 187, the determined notification effect image is received by the lottery result command. It can be immediately displayed on the auxiliary display unit 65.

Therefore, various notification effects can be displayed on the auxiliary display unit 65 at least several tens of ms after the player operates the start lever 41. Therefore, after the player operates the start lever 41, the reel 32L, Before the stop switches 42 to 44 can be operated to stop the rotation of the 32M and 32R, the notification effect of the winning combination is executed on the auxiliary effect section (upper lamp 63, speaker 64, auxiliary display section 65). Can be made to. Therefore, the player can know the winning of any of the BB winning mode, the watermelon winning mode, and the bell winning mode before operating any of the stop switches 42 to 44. As a result, when the player plays the game with one or two cards, if this notification effect is performed by the auxiliary display unit 65, the winning combination (BB winning mode, watermelon winning mode) grasped by the notification effect Alternatively, in order to stop the stop symbols corresponding to the bell winning mode) on the effective line, the stop switches 42 to 44 can be operated aiming at the stop symbols, so that the winning modes can be established with a higher probability. Can be done. In addition, if the winning of the BB winning mode is announced, the player may receive a new medal loan and continue the game until the BB winning mode is established, even if the game is missed. can.

Further, when the BB winning mode is carried over from the past game and a plurality of winning combinations are set together with the winning combination in the lottery of this game, the slide table setting process executed by the MPU 102 of the main control device 101 is executed. In (see S310 in FIG. 17), a sliding table corresponding to a winning combination other than the BB winning mode is set, but in this lottery result command processing, a lottery is performed when the number of bets is set to one or two. The winning combination grasped by the result command is determined from the BB winning mode (see S763). As a result, if the winning combination in which the sliding table is set is the watermelon winning mode or the bell winning mode, the winning combination may be missed, but if the BB winning mode is set as the winning combination, the winning combination may be missed. Since the BB winning notification effect is given priority, it is possible to make the player surely understand that the BB winning mode, which is more advantageous for the player, is the winning combination.

As a result of the processing of S767, when the winning combination is not the bell winning mode (S767: No), if the number of bets is 2, the cherry bell winning mode or the replay winning mode is set as the winning combination, or the winning combination is If it can be grasped that it is not set (that is, it is out of order) and the number of bets is 1, the cherry bell winning mode, the 7 bell winning mode, or the replay winning mode is set as a winning combination, or the winning combination is won. It can be grasped that the winning combination is not set (that is, it is out of order). Therefore, next, the information regarding the number of bets stored in the bet number storage area 185b is confirmed, and whether or not the number of bets placed on the game for which the start command is indicated by the start command is two or not is confirmed. Judgment (S769).

If the number of bets is two (S769: Yes), the auxiliary display unit 65 is displayed with the message "Challenge the cherry bell!" A "cherry bell winning challenge effect" that outputs a dedicated voice and lights the upper lamp 63 in a dedicated mode is determined (S770), and the process proceeds to S772. As a result, the driving of each auxiliary production unit is started so that the cherry bell winning challenge production is executed. Further, if the number of bets is not two (S769: No), it can be grasped that the number of bets is one. "Challenge the bell!" Is displayed, and a dedicated voice is output from the speaker 64, and the upper lamp 63 is turned on in a dedicated manner. "Cherry bell winning / 7 bell winning challenge production" is decided (S771). , S772. As a result, the driving of each auxiliary production unit is started so that the cherry bell winning and 7 bell winning challenge productions are executed.

By the processing of S770, the "cherry bell winning challenge production" is executed in the auxiliary production section, so if the game is played with two medals, it is expected that three medals will be paid out by the establishment of the cherry bell winning mode. It is possible to give the player a strong feeling. In addition, since the "cherry bell winning / 7 bell winning challenge production" is executed in the auxiliary production section by the processing of S771, when the game is played with one piece, the cherry bell winning or the 7 bell winning mode is executed. It is possible to give the player a strong sense of expectation that three or two medals will be paid out upon establishment. Therefore, since the player can play the game by playing one or two medals while having fun, the player can be strongly reminded that he wants to play the game to the end without leaving any extra medals.

In the processing of S772, the display data table corresponding to the effect mode determined by the processing of S762, S764, S766, S768, S770 or S771 is set in the display data table buffer 185f, and the set display data table is supported. The transfer data table to be transferred is set to the transfer data table buffer 185 g (S772). Then, the pointer 185h is initialized to 0 (S773), and the lottery result command processing is terminated. If the transfer data table corresponding to the set display data table is not prepared in the processing of S772, all the image data of the sprite used in the effect specified in the display data table is the resident video. Since it is stored in the RAM 189 and means that the transfer from the character ROM 187 to the normal video RAM 190 is unnecessary, it means that the transfer target image data for which the transfer should be started does not exist in the transfer data table buffer 185 g. The transfer data table buffer 185 g is set by writing the Null data to be performed to all the addresses.

As described above, by executing this lottery result command processing, the display control device 81 determines the effect mode to be executed by the auxiliary effect unit in accordance with the operation of the start lever 41 by the player, and determines the effect mode. It is possible to start driving each auxiliary effect unit so that the effect is performed in the effect mode. Further, in the determination of the effect mode, the effect mode is determined based on the result of the winning / failing determination of the winning combination performed by the main control device 101 based on the operation of the start lever 41 of the player. At the same time, the auxiliary production unit can be made to perform an effect of notifying the player of the winning combination and giving a feeling of expectation for the establishment of each winning mode. Therefore, it is possible to improve the interest of the player in the game.

Further, the display data table and the transfer data table are set to the display data table buffer 185f and the transfer data table buffer 185 g by the process of S772, respectively, and the pointer 185h is initialized by the process of S783, whereby the MPU181 performs the display setting process ( (Refer to FIG. 49), while updating the pointer 185h, the drawing contents specified at the address indicated by the pointer 185h are extracted from the display data table set in the display data table buffer 185f, and then the auxiliary display unit 65 next. It is possible to specify the content of one frame of image to be displayed. Further, the MPU 181 is indicated by the pointer 185h from the transfer data table set in the transfer data table buffer 185 g in the normal image transfer setting process (see FIG. 51), which is one of the transfer setting processes (see FIG. 50 (a)). The image controller extracts the transfer data information specified in the address and transfers the image data of the sprite required in the set display data table from the character ROM 187 to the image storage area 190a of the normal video RAM 190 in advance. 188 can be controlled. As a result, the images drawn by the display data table set in the display data table buffer 185f are sequentially displayed on the auxiliary display unit 65, and the effect of the effect mode corresponding to the display data table is displayed on the auxiliary display unit 65. Can be made to.

Here, when the program executed by the MPU 181 is started every time the effect image displayed on the display control device 81 is changed as in the conventional slot machine, it becomes complicated due to the diversification of the effect images. In addition, since a large load is applied to the processing of starting and executing the enormous program, the processing capacity of the display control device 81 is limited, and there is a possibility that the diversification of controllable production images is limited. .. On the other hand, in the slot machine 10, the effect image to be displayed on the auxiliary display unit 65 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 185f as in the process of S772. Therefore, various types of effect images can be displayed on the auxiliary display unit 65 regardless of the processing capacity of the display control device 81.

Further, as the display data table is set in the display data table buffer 185f, the transfer data table corresponding to the display data table is set in the transfer data table 185d. As described above, the transfer data table has a data structure similar to that of the display data table, and the transfer target image to correspond to the address specified in the display data table and to start the transfer at the time indicated by the address. Since the data transfer data information is specified, the image data is surely transferred to the normal video RAM 190 before the image data of the predetermined sprite is used based on the display data table set in the display data table buffer 185f. The timing of the transfer start can be instructed so that it is stored. Therefore, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, a wide variety of effect images can be easily displayed on the auxiliary display unit 65.

The explanation will be continued by returning to FIG. 24. In the process of S738, if it is determined that it is not a lottery result command (S738: No), then it is determined whether or not the command analyzed by the process of S733 is a payout determination result command (S740), and a payout determination is made. If it is a result command (S740: Yes), the payout determination result command process is executed (S741), and the process returns to the process of S731. As described above, the payout determination result command is a payout determination that is performed when the stop switches 42 to 44 are operated by the player and all reels 32L, 32M, 32R are stopped after the game is started by operating the start lever 41. This is a command for notifying the display control device 81 of the result, that is, the determination result of the number of medals to be paid out on the condition that the combination of winning symbols is lined up on the valid line.

Here, the details of the payout determination result command processing (S741) will be described with reference to FIG. 27 (a). FIG. 27A is a flowchart showing the payout determination result command processing executed by the MPU181 of the display control device 81. This payout determination result command process executes the process corresponding to the payout determination result command received from the main control device 101, and is an auxiliary display unit according to the result of the payout determination grasped by the payout determination result command. The effect mode to be executed is determined in the auxiliary effect unit such as 65, the display data table corresponding to the determined effect mode is set in the display data table buffer 185f, and the set display data table is supported. The transfer data table is set in the transfer data table buffer 185 g.

In this payout determination result command processing, first, the payout determination result is extracted from the received payout determination result command (S781). Then, the extracted payout determination result, the game status of the slot machine 10 notified by the status command and stored in the work RAM 185, and the start command notified by the start command and started by the start command stored in the bet number storage area 185b. As an effect mode to be executed by the auxiliary effect unit based on the number of bets placed on the game to which the command is indicated and the value of the random number counter provided in the work RAM 185, from among a plurality of effect modes. 1 is determined (S782). Here, for example, a "winning establishment effect" for notifying that the symbols corresponding to the winning combinations won in the lottery are aligned on the valid line and paying out, and a "missing" for notifying that the payout is not performed due to a loss. "Direction" etc. are set.

Then, the display data table corresponding to the determined effect mode is set in the display data table buffer 185f, and the transfer data table corresponding to the set display data table is set in the transfer data table buffer 185 g (S783). Initialize the pointer 185h to 0 (S784), and end the payout determination result command processing. If the transfer data table corresponding to the set display data table is not prepared in the processing of S783, all the image data of the sprite used in the effect specified in the display data table is the resident video. Since it is stored in the RAM 189 and means that the transfer from the character ROM 187 to the normal video RAM 190 is unnecessary, it means that the transfer target image data for which the transfer should be started does not exist in the transfer data table buffer 185 g. The transfer data table buffer 185 g is set by writing the Null data to be performed to all the addresses.

As described above, by executing this payout determination result command process, the display control device 81 is performed when all reels 32L, 32M, 32R are stopped in response to the operation of the stop switches 42 to 44 by the player. Depending on the result of the payout determination, that is, whether or not the symbols lined up on the effective line are a combination of winning symbols, the effect mode to be executed by the auxiliary production unit is determined, and the effect mode is determined. Can be started to drive each auxiliary effect unit so that Therefore, since the auxiliary effect unit can execute the effect that matches the payout determination result of the game, the player can be made to have a stronger impression of the result of the game. Therefore, it is possible to improve the interest of the game.

Further, the display data table and the transfer data table are set to the display data table buffer 185f and the transfer data table buffer 185 g by the process of S783, respectively, and the pointer 185h is initialized by the process of S784, whereby the MPU181 performs the display setting process ( (Refer to FIG. 49), while updating the pointer 185h, the drawing contents specified at the address indicated by the pointer 185h are extracted from the display data table set in the display data table buffer 185f, and then the auxiliary display unit 65 next. It is possible to specify the content of one frame of image to be displayed. Further, the MPU 181 is indicated by the pointer 185h from the transfer data table set in the transfer data table buffer 185 g in the normal image transfer setting process (see FIG. 51), which is one of the transfer setting processes (see FIG. 50 (a)). The image controller extracts the transfer data information specified in the address and transfers the image data of the sprite required in the set display data table from the character ROM 187 to the image storage area 190a of the normal video RAM 190 in advance. 188 can be controlled. As a result, the images drawn by the display data table set in the display data table buffer 185f are sequentially displayed on the auxiliary display unit 65, and the effect of the effect mode corresponding to the display data table is displayed on the auxiliary display unit 65. Can be made to.

Further, in the slot machine 10, the effect image to be displayed on the auxiliary display unit 65 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 185f as in the process of S783. Therefore, as compared with the case where the program executed by the MPU 181 is started every time the effect image to be displayed on the display control device 81 is changed as in the conventional slot machine, regardless of the processing capacity of the display control device 81, Various types of effect images can be displayed on the auxiliary display unit 65.

Further, as the display data table is set in the display data table buffer 185f, the transfer data table corresponding to the display data table is set in the transfer data table 185d. As described above, the transfer data table has a data structure similar to that of the display data table, and the transfer target image to correspond to the address specified in the display data table and to start the transfer at the time indicated by the address. Since the data transfer data information is specified, the image data is surely transferred to the normal video RAM 190 before the image data of the predetermined sprite is used based on the display data table set in the display data table buffer 185f. The timing of the transfer start can be instructed so that it is stored. Therefore, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, a wide variety of effect images can be easily displayed on the auxiliary display unit 65.

The explanation will be continued by returning to FIG. 24. In the processing of S740, if it is determined that the command is not a payout determination result command (S740: No), then it is determined whether or not the command analyzed by the processing of S733 is an error command (S742), and the error command is used. If there is (S742: Yes), the error command processing is executed (S742), and the process returns to the processing of S731. As described above, the error command is a command for notifying the display control device 81 of the error type when various errors such as a sensor error are detected by the main control device 101.

Here, the details of the error command processing (S743) will be described with reference to FIG. 27 (b). FIG. 27B is a flowchart showing an error command process executed by the MPU 181 of the display control device 81. This error command processing executes the processing corresponding to the error command received from the main control unit 101.

In the error command processing, first, the error occurrence flag indicating that an error has occurred in the ON state is set to ON (S791). Then, among the error discrimination flags provided for each error type, the error discrimination flag corresponding to the error type indicated by the error command is set to ON (S792), the error command processing is terminated, and the process returns to the command judgment processing. ..

In the display setting process, when an error is detected based on the error occurrence flag set by the process of S791, the error type generated from the error discrimination flag set by the process of S792 is determined and the error type is dealt with. The process is executed so that the warning image to be displayed is displayed on the auxiliary display unit 65.

Once the error discrimination flag provided corresponding to each error type is set to ON in the processing of S792, the error discrimination flag is turned on until the reset switch 72 provided in the power supply box 70 is turned on. Continue to be done. Therefore, when error command processing is executed for two or more error commands, the error discrimination flags corresponding to all the error types indicated by each error command are set to on, so all error types are supported. The warning image is displayed on the third symbol display device 281. Therefore, the player and the person involved in the hall can correctly grasp the error occurrence status.

Returning to FIG. 75, the description will be continued. If it is determined that the command is not an error command in the process of S742 (S742: No), then the process corresponding to the other unprocessed command is executed (S744), and the process returns to the process of S731.

In the processing of S731 that is executed again after the processing of each command is executed, it is determined again whether or not there is an unprocessed new command in the command buffer area, and if there is an unprocessed new command (S7311: Yes). ), The processing of S732 to S744 is executed again. Then, the processes of S732 to S744 are repeatedly executed until there are no unprocessed new commands in the command buffer area, and when it is determined in the process of S731 that there are no unprocessed new commands in the command buffer area, this command determination is made. End the process.

Next, with reference to FIG. 28, the details of the above-mentioned display setting process (S723), which is one of the V interrupt processes executed by the MPU 181 of the display control device 81, will be described. FIG. 28 is a flowchart showing this display setting process. As described above, the display setting process is based on the contents of the display data table set in the display data table buffer 185f by the command determination process (S722) or the like, and the image for one frame to be displayed next in the auxiliary display unit 65. It specifically specifies the contents of.

In this display setting process, first, it is determined whether or not the new command flag is on (S801), and if the new command flag is not on, that is, it is off (S801: No), it is executed first. In the command determination process, it is determined that the new command has not been processed, the processes of S802 to S805 are skipped, and the process proceeds to the process of S806. On the other hand, if the new flag is on (S801: Yes), it is determined that the new command has been processed in the command determination process executed first, and after the new command flag is set to off (S802), S803 to S805. By the processing of, the processing corresponding to the new command processed in the command judgment processing, in particular, the error command is executed.

In the process of S803, it is determined whether or not the error occurrence flag is on (S803). Then, if the gill occurrence flag is off (S803: No), the process proceeds to S806 as it is, and if the error occurrence flag is on (S803: Yes), an error command is executed in the command determination process to be executed first. Since it means that the processing has been executed, the error warning image corresponding to all the error discrimination flags set to be turned on is displayed on the auxiliary display unit 65 with reference to the error discrimination flag set by the error command processing. The warning image data to be generated is expanded (S804). Then, after the processing of S804, the error occurrence flag is set to off (S805), and the process proceeds to the processing of S806.

The warning image data developed in the processing of S804 has a type of sprite (display object) constituting the warning image by the task processing (S724), which is one of the V interruption processing (see FIG. 23B). It is used to specify and determine various parameters required for drawing such as display coordinate position, enlargement ratio, and rotation angle for each sprite.

Next, in the processing of S806 to S810, the pointer 185h is updated. First, in S806, 1 is added to the pointer 185h (S2791). As a result, the pointer 185h is, in principle, updated so that only 1 is added each time the V interrupt processing is executed. As described above, in the various data tables, Start information is described at the address "0000H", and the substance of each data is defined after the address "0001H", and the display data table is the display data table. When the value of the pointer 185h is initialized to 0 in accordance with the storage in the buffer 185f, the value is updated to 1 by this pointer update process, so that each data table is in order from the address "0001H". Substantial data can be read from.

Next, in the display data table set in the display data table buffer 185f, it is determined whether or not the data at the address indicated by the updated pointer 185h is End information (S807). As a result, if it is End information (S807: Yes), it means that the pointer 185h has been updated past the address in which the actual data is described in the display data table set in the display data table buffer 185f.

Therefore, the display data table stored in the display data table buffer 185f is directed to the payout result, for example, "winning" to notify that the symbols corresponding to the winning combinations won in the lottery are aligned on the valid line and paid out. It is determined whether or not the effect corresponds to the effect mode set by the payout determination result command processing, such as the "establishment effect" and the "disengagement effect" for notifying that the payout is not performed due to the disengagement (S808). As a result, if it is a display data table corresponding to the effect for the payout result (S808: Yes), the player operates the start lever 41 to start the next game after the effect for the payout result is completed. The display data table corresponding to the "game start waiting effect" displayed up to is set in the display data table buffer 185f, and the transfer data table corresponding to the set display data table is set in the transfer data table buffer 185 g. Set (S809). Then, the pointer 185h is set to 1 (S810), and the process proceeds to S813.

As a result, in the display setting process, when the effect for the payout result such as the "winning establishment effect" or the "off effect" started by the setting of the payout determination result command process is displayed on the auxiliary display unit 65 until the end, then, The drawing contents are expanded in order from the beginning of the display data table corresponding to the "game start waiting effect" set by the process of S809. Therefore, after the display of the effect for the payout result is completed, the auxiliary display unit 65 can display the effect waiting for the start of the game.

On the other hand, as a result of the determination of S808, if the display data table stored in the display data table buffer 185f does not correspond to the effect for the payout result (S808: No), then it is stored in the display data table buffer 185f. The displayed data table is used for the above-mentioned notification effects such as "BB prize announcement effect", "watermelon prize announcement effect", and "bell prize announcement effect" to notify the player of the winning combination at the time of lottery, and "BB prize challenge". It is determined whether or not it corresponds to the above-mentioned challenge production that encourages the player to establish a winning combination, such as "directing", "cherry bell winning / 7 bell winning challenge production", and "cherry bell winning challenge production". S811). As a result, if it is a display data table corresponding to the notification effect or the challenge effect (S811: Yes), the value of the pointer 188h is subtracted by 1 (S812), and the process proceeds to S813. As a result, in the display setting process, when the display data table corresponding to the notification effect or the challenge effect is set in the display data table buffer 185f, the notification effect or the challenge effect is displayed on the auxiliary display unit 65 until the end. The drawing content of the previous address in which the End information is described is always expanded. Therefore, when the notification effect and the challenge effect are displayed to the end, the auxiliary display unit 65 can display the last image defined in the display data table in a stopped state.

On the other hand, as a result of the determination of S811, if the display data table stored in the display data table buffer 185f does not correspond to the notification effect or the challenge effect (S811: No), the process proceeds to S810. Then, the pointer 185h is set to 1, and the process proceeds to S813. As a result, in the display setting process, when an effect that does not correspond to any of the effect for the payout result, the notification effect, and the challenge effect, for example, a normal game effect or a game start waiting effect is displayed to the end, it corresponds again. Since the drawing contents can be expanded in order from the top of the display data table, the auxiliary display unit 65 can repeatedly display those effects.

In this way, when the display data table stored in the display data table buffer 185f is read to the end, a new display is made in the display data table buffer 185f according to the type of effect mode corresponding to the display data table. By setting the data table, setting the pointer 185h to 1, or subtracting only 1, the effect mode displayed on the auxiliary display unit 65 can be changed, or the effect is stored in the display data table buffer 185f. It is possible to repeatedly display the effect mode corresponding to the display data table from the beginning, or to display the last image of the effect mode in a stopped state. Therefore, when the display data table stored in the display data table buffer 185f is read to the end, it is possible to easily set an image to be continuously displayed on the auxiliary display unit 65 according to the contents of the display data table. Can be done. In particular, the pointer 185h is set to 1 when the set effect mode is repeatedly displayed on the auxiliary effect unit 65, and the value of the pointer 185h is set to 1 only when the last image of the set effect mode is stopped and displayed. Since it is possible to display these effects simply by subtracting them, it is not necessary to reset the display data table buffer 185f, and the processing load related to them can be lightened.

In the present embodiment, in the above-mentioned notification effect and challenge effect, when those effects are displayed on the auxiliary display unit 65 until the end, the case where the last image is stopped and displayed has been described, but it is not always the case. The present invention is not limited to this, and in another effect, when those effects are displayed on the auxiliary display unit 65 until the end, the last image may be stopped and displayed. In this case, in the process of S811, it may be determined whether or not the display data table stored in the display data table buffer 185f is an effect of stopping and displaying the last image.

Further, in the notification effect or the challenge effect, when the effect is displayed on the auxiliary display unit 65 until the end, it may be repeatedly displayed from the beginning. In this case, in the process of S811, if the display data table stored in the display data table buffer 185f is a notification effect or a challenge effect to be repeatedly displayed from the beginning, the determination of S811: No is performed and the process of S810 is performed. You may try to move to. As a result, in the notification effect or the challenge effect, when the effect is displayed on the auxiliary display unit 65 until the end, it can be repeatedly displayed from the beginning.

As a result of the processing of S807, in the display data table set in the display data table buffer 185f, when it is determined that the data of the address indicated by the pointer 185h after the update by the processing of S806 is not the End information, S808 to S812 The process of S813 is skipped and the process proceeds to S813.

In the process of S813, the drawing contents of the address indicated by the updated pointer 185h are expanded from the display data table set in the display data table buffer 185f (S813). Then, after the processing of S813 is completed, the display setting processing is ended, and the process returns to the V interrupt processing. In the task process (see S724 in FIG. 23 (b)) performed after the display setting process (S722), an image is configured based on the previously expanded warning image and the drawing contents expanded in the process of S813. The type of sprite (display object) to be displayed is specified, and various parameters necessary for drawing such as the display coordinate position, the enlargement ratio, and the rotation angle are determined for each sprite.

Next, with reference to FIGS. 29 and 51, the details of the above-mentioned transfer setting process (S725), which is one of the V interrupt processes executed by the MPU 181 of the display control device 81, will be described. First, FIG. 50A is a flowchart showing this transfer setting process. As described above, in this transfer setting process, while the simple image display flag 185e is on, the image data to be resident in the resident video RAM 189 is set to the image controller 188 from the character ROM 187 to the resident video RAM 189. While the transfer instruction to be transferred to the area is set and the simple image display flag 185e is off, a predetermined image controller 188 is set based on the transfer data information of the transfer data table set in the transfer data table buffer 185 g. This is a process for setting a transfer instruction for transferring image data from the character ROM 187 to a predetermined sub-area of the image storage area 190a of the normal video RAM 190.

In this transfer setting process, first, it is determined whether or not the simple image display flag 185e is on (S816). If the simple image display flag 185e is on (S816: Yes), all the image data that should be resident in the resident video RAM 189 is not transferred from the character ROM 187 to the resident video RAM 189, so that the resident image transfer setting is made. The process is executed (S817), the transfer setting process is terminated, and the process returns to the V interrupt process. As a result, a transfer instruction for transferring the image data to be resident in the resident video RAM 189 from the character ROM 187 to the resident video RAM 189 is set to the image controller 188. The details of the resident image transfer setting process will be described later with reference to FIG. 50 (b).

On the other hand, if the simple image display flag 185e is not on as a result of the processing of S816, that is, if it is off (S816: No), all the image data that should be resident in the resident video RAM 189 is the resident video from the character ROM 187. It has been transferred to RAM 189. In this case, the normal image transfer setting process is executed (S818), the transfer setting process is terminated, and the process returns to the V interrupt process. As a result, the transfer instruction is set so that the subsequent transfer of image data from the character ROM 187 is performed to the normal video RAM 190. The details of the normal image transfer setting process will be described later with reference to FIG. 30.

Next, the resident image transfer setting process (S817), which is one of the transfer setting processes (S725) executed by the MPU 181 of the display control device 81, will be described with reference to FIG. 29 (b). FIG. 29B is a flowchart showing this resident image transfer setting process. As described above, in this resident image transfer setting process, while the simple image display flag 185e is on, the image data to be resident in the resident video RAM 189 is transmitted from the character ROM 187 to the resident video RAM 189 to the image controller 188. This is a process for setting a transfer instruction to transfer to a predetermined area.

In this resident image transfer setting process, first, it is determined whether or not the image controller 188 is instructed to transfer the untransferred image data (S821), and if the transfer instruction is transmitted (S8211: Yes). ) Further, it is determined whether or not the image data transfer process performed by the image controller 188 is completed based on the transfer instruction (S822). In the process of S822, when the image controller 188 is instructed to transfer the image data and then the transfer end signal indicating the end of the transfer process is received from the image controller 188, it is determined that the transfer process is completed. .. When it is determined by the process of S822 that the transfer process has not been completed (S822: No), the image transfer process is continuously performed in the image controller 188, so that the resident image transfer setting process is performed. finish. On the other hand, when it is determined that the transfer process is completed (S822: Yes), the process proceeds to the process of S823. Further, as a result of the processing of S821, even if the transfer instruction of the untransferred image data is not transmitted to the image controller 188 (S8211: No), the process proceeds to the processing of S823.

In the process of S823, it is determined whether or not all the resident target image data to be resident in the resident video RAM 189 has been transferred (S823), and if there is untransferred resident target image data (S823: No), the non-resident image data is not transferred. A transfer instruction is set for the image controller 188 so that the resident image data to be transferred is transferred from the character ROM 187 to the resident video RAM 189 (S824), and the resident image transfer setting process is terminated.

As a result, the drawing list transmitted to the image controller 188 in the drawing process (see S726 in FIG. 23 (b)) executed after the transfer setting process (see S725 in FIG. 23 (b)) is not transferred to the drawing list. The transfer data information regarding the resident target image data will be included, and the image controller 188 transfers the resident target image data from the character ROM 187 to the resident video RAM 189 based on the transfer data information described in the drawing list. Can be done. The transfer data information includes the start address and end address of the character ROM 187 in which the resident image data is stored, the transfer destination information (in this case, the resident video RAM 189), and the transfer destination (transferred here). The start address of the resident video RAM 189 (area provided in the resident video RAM 189) for storing the resident target image data is included. The image controller 188 executes an image transfer process based on this transfer data information, reads the image data specified in the transfer process from the character ROM 187, temporarily stores the image data in the buffer RAM 188a, and then the resident video RAM 189 is unused. During the period, transfer to the specified address of the resident video RAM 189. Then, when the transfer is completed, the transfer end signal is transmitted to the MPU 188.

If all the resident target image data has been transferred as a result of the processing of S823 (S823: Yes), the above-mentioned display will be displayed until the start lever 41 is operated by the player and the next game is started. The display data table corresponding to the "game start waiting effect" is set in the display data table buffer 185f, and the transfer data table corresponding to the set display data table is set in the transfer data table buffer 185 g (S825). Further, the pointer 185h is initialized to 0 (S826).

As a result, in the display setting process of the V interrupt process (see FIG. 23B) executed by the next and subsequent V interrupts, the display data table corresponding to the "game start waiting effect" set by the process of S825. The drawing contents will be expanded in order from the beginning of. Therefore, after all the image data to be resident in the resident video RAM 189 is transferred from the character ROM 187 to the resident video RAM 189, the auxiliary display unit 65 can display the game start waiting effect.

After the processing of S826, the simple image display flag 185e is set to off (S827). Then, the resident image transfer setting process is terminated. As a result, in the V interrupt process (see FIG. 23 (b)), the simple display setting process (see S728), the command determination process (see FIGS. 24 to 27), and the display setting process (see FIG. 28) are executed. Therefore, the drawing of the image in the normal time is set, and the image in the normal time is displayed in the auxiliary teaching unit 65. Further, the subsequent transfer of image data from the character ROM 187 is performed to the normal video RAM 190 by the normal image transfer setting process (see FIG. 51) (see S816: No in FIG. 50 (a)).

By executing this resident image transfer setting process, the MPU 181 characterizes all resident target image data that should be resident in the resident video RAM 189, except for the main image at power-on that has already been transferred in the display main process. It can be transferred from the ROM 187 to the resident video RAM 189. Then, the MPU 181 controls that the image data transferred to the resident video RAM 189 is continuously held without being overwritten while the power is turned on. As a result, the image data transferred to the resident video RAM 189 by the resident image transfer setting process will be resident in the resident video RAM 189 while the power is turned on.

Therefore, after all the image data to be resident in the resident video RAM 189 is transferred to the resident video RAM 189, the display control device 81 uses the image data resident in the resident video RAM 189 while using the image controller 188. The image drawing process can be performed with. As a result, if the image data used for the drawing process is resident in the resident video RAM 189, it is not necessary to read the corresponding image data from the character ROM 187 configured by the NAND flash memory 187a having a slow read speed at the time of image drawing. Therefore, the time required for reading the data can be omitted, and the image can be drawn immediately and the drawn image can be displayed on the auxiliary display unit 65.

In particular, the resident video RAM 189 is provided with image data of frequently displayed images such as a rear image, a character pattern, a notification effect image, and an error message, and a display control device 81 based on a command from the main control device 101. Since the image data of the image to be displayed immediately after the display is determined is resident, even if the character ROM 187 is configured with the NAND flash memory 187a, the auxiliary display is performed from various operations performed by the player at any timing. It is possible to maintain high responsiveness until some image is displayed on the unit 65.

Next, with reference to FIG. 30, a normal image transfer setting process (S818), which is one process of the transfer setting process (S725) executed by the MPU 181 of the display control device 81, will be described. FIG. 30 is a flowchart showing this normal image transfer setting process. As described above, the normal image transfer setting process is predetermined to the image controller 188 based on the transfer data information of the transfer data table set in the transfer data table buffer 185 g while the simple image display flag 185e is off. This is a process for setting a transfer instruction for transferring the image data of the above to a predetermined sub-area of the image storage area 190a of the normal video RAM 190 from the character ROM 187.

In this normal image transfer setting process, first, from the transfer data table set in the transfer data table buffer 185 g, the address indicated by the pointer 185h updated by the display setting process (S723, see FIG. 28) executed earlier. (S831). Then, it is determined whether or not the acquired information is transfer data information (S832), and if it is transfer data information (S832: Yes), the character ROM 187 in which the transfer target image data is stored is stored from the transfer data information. The start address (storage source final address), the final address (storage source final address), and the start address of the transfer destination (normal video RAM 190) are extracted and stored in the transfer data buffer provided in the work RAM 185 (. S833), further, the transfer start flag provided in the work RAM 185 and indicating that there is image data to be transferred in the ON state is set to ON (S834), and the process proceeds to S835.

Further, in the process of S832, if the acquired information is not the transfer data information but the Null data (S832: No), the processes of S833 and S834 are skipped, and the process proceeds to the process of S835. In the process of S835, it is determined whether or not a new image data transfer instruction has been set for the image controller 188 after the previous image data transfer is completed (S835), and the transfer instruction is set. If so (S835: Yes), it is further determined whether or not the image data transfer performed by the image controller 188 is completed based on the transfer instruction (S836).

In the process of S836, after setting the image data transfer instruction to the image controller 188, when the transfer end signal indicating the end of the transfer process is received from the image controller 188, it is determined that the transfer process is completed. .. When it is determined by the process of S836 that the transfer process has not been completed (S836: No), the image transfer process is continuously performed in the image controller 188, so that the normal image transfer setting process is performed. finish. On the other hand, when it is determined that the transfer process is completed (S836: Yes), the process proceeds to the process of S837. Further, as a result of the processing of S835, even if the image data transfer instruction is not set for the image controller 188 after the previous image data transfer is completed (S835: No), the process proceeds to S837. do.

In the process of S837, it is determined whether or not the transfer start flag is on (S837), and if the transfer start flag is on (S837: Yes), the image data to be transferred exists, so that the transfer start flag is present. Is turned off (S837), the image data of the sprite indicated by various information stored in the transfer data buffer by the process of S833 is set as the transfer target image, and then the process proceeds to the process of S839. On the other hand, if the transfer start flag is not on but off (S837: No), there is no image data to be transferred, so the normal image transfer setting process is terminated as it is.

In the process of S839, it is determined whether or not the image to be transferred is already stored in the normal video RAM 190 (S839). The discrimination in the process of S839 is performed by referring to the stored image discrimination flag. That is, the stored state corresponding to the sprite as the transfer target image is read from the stored image discrimination flag 185k, and if the stored state is "on", the image data of the sprite to be transferred is stored in the normal video RAM 436. It is determined that the sprite is stored, and if the storage state is "off", it is determined that the image data of the sprite to be transferred is not stored in the normal video RAM 436.

Then, if the image to be transferred is stored in the normal video RAM 190 as a result of the processing of S839 (S839: Yes), it is not necessary to transfer the image data of the sprite from the character ROM 187 to the normal video RAM 190. Therefore, the normal image transfer setting process is terminated as it is. As a result, it is possible to suppress unnecessary transfer of image data from the character ROM 187 to the normal video RAM 190, reduce the processing load in each part of the display control device 81, and reduce the traffic in the internal bus. be able to.

On the other hand, if the transfer target image is not stored in the normal video RAM 190 as a result of the processing of S839 (S839: Yes), the transfer instruction of the transfer target image is set (S840). As a result, in the drawing process (see S726 in FIG. 23 (b)) executed after the transfer setting process (see S725 in FIG. 23 (b)), the transfer target is transferred to the drawing list transmitted to the image controller 188. The image transfer data information will be included, and the image controller 188 can transfer the image data of the image to be transferred from the character ROM 187 to the normal video RAM 190 based on the transfer data information described in the drawing list. can. The transfer data information includes the start address and end address of the character ROM 187 in which the image data of the image to be transferred is stored, the transfer destination information (in this case, the normal video RAM 190), and the transfer destination (transferred here). The start address of the sub-area) provided in the image storage area 190a of the normal video RAM 190 for storing the image data of the image to be transferred is included. The image controller 188 executes an image transfer process based on the transfer data information, reads the image data specified in the transfer process from the character ROM 187, and designates the specified video RAM (here, the normal video RAM 190). Forward to the given address. Then, when the transfer is completed, the transfer end signal is transmitted to the MPU181.

After the processing of S840, the stored image discrimination flag 185k is updated (S841), and this normal transfer setting processing is terminated. To update the stored image discrimination flag 185k, as described above, the storage state corresponding to the sprite that is the transfer target image is set to "on", and the sub-area of the same image storage area 189a as the one sprite is set. This is done by setting the storage state corresponding to the other sprites that are supposed to be stored to "off".

As described above, in the display control device 81, the display data table is set in the display data table buffer 185f in response to a command from the main control device 101 (for example, a lottery result command or a payout determination result command). At the same time, the transfer data table corresponding to the display data table is set in the transfer data table buffer 185 g. Then, the MPU 181 transfers to the image controller 188 according to the transfer data information described at the address indicated by the pointer 185h of the transfer data table set in the transfer data table buffer 185 g by executing the normal image transfer setting process. Since the transfer instruction of the target image is set, the image data of the sprite specified in the display data table set in the display data table buffer 185f can be reliably transferred from the character ROM 187 to the normal video RAM 190 at a desired timing. can.

Here, in the transfer data table, the image data to be transferred is stored in the image storage area 190a so that the image data corresponding to the predetermined sprite is stored in the image storage area 190a by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information is specified for a predetermined address, the image data is transferred from the character ROM 187 to the image storage area 190a according to the transfer data information specified in the transfer data table, so that the transfer data information is specified according to the display data table. When drawing the sprite, the image data that is not resident in the resident video RAM 189 necessary for drawing the sprite can be stored in the image storage area 190a without fail.

As a result, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, the image necessary for display can be read in advance from the character ROM 187 and transferred to the normal video RAM 190 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the auxiliary display unit 65. Further, according to the description in the transfer data table, only the non-resident image data in the resident video RAM 189 can be easily and surely transferred from the character ROM 187 to the normal video RAM 190.

Further, in the transfer data table, the transfer data information is defined so that the image data is transferred from the character ROM 187 to the normal video RAM 190 for each image data corresponding to the sprite. As a result, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 187 to the normal video RAM 190 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

Next, with reference to FIG. 31, the details of the above-mentioned drawing process (S726), which is one of the V interrupt processes executed by the MPU 181 of the display control device 81, will be described. FIG. 31 is a flowchart showing this drawing process. As described above, the drawing process is a process of generating the drawing list shown in FIG. 14 and transmitting the drawing list to the image controller 188 together with the drawing target buffer information.

In this drawing setting process, the types of various sprites constituting one frame determined by the task process (S724) and the parameters required for drawing each sprite (display position coordinates, enlargement ratio, rotation angle, translucent value, α). The drawing list shown in FIG. 14 is generated from the transfer instruction set by the blending information, the color information, the filter designation information) and the transfer setting process (S725) (S851). That is, in the processing of S851, the storage RAM type and address in which the image data of the sprite is stored are specified for each sprite from the types of various sprites constituting one frame determined in the task processing (S724). Then, the specified stored RAM type and address are associated with the parameters required for the sprite determined by the task processing. Then, each sprite is rearranged in the order of the sprites to be arranged on the front side from the sprites to be arranged on the back side in the image for one frame, and then the details for each sprite are arranged in the order of the sprites after the rearrangement. A drawing list is generated by describing the storage RAM type in which the image data of the sprite is stored, the address, and the parameters necessary for drawing the sprite as various drawing information (detailed information). When a transfer instruction is set by the transfer setting process (S725), the start address (storage source start address) of the character ROM 187 in which the transfer target image data is stored as the transfer data information at the end of the drawing list. And the final address (final address of the storage source) and the start address of the transfer destination (normal video RAM 190) are added.

As described above, since the area of the resident video RAM 189 in which the image data of the sprite is stored or the sub area of the image storage area 190a of the normal video RAM 190 is fixed for each sprite, the MPU181 has a fixed area. , The storage RAM type and address in which the image data of the sprite is stored can be immediately specified according to the sprite type, and the information can be easily included in the detailed information of the drawing list.

When the drawing list is generated, the generated drawing list and the drawing target buffer information specified by the drawing target buffer flag 185k are transmitted to the image controller (S852). Here, when the drawing target buffer flag 185k is 0, the drawing target buffer flag 185k is 1 including information instructing the image drawn in the first frame buffer 190b to be expanded as the drawing target buffer information. Includes information instructing the image drawn in the second frame buffer 190c to be expanded as the drawing target buffer information.

The image controller 188 draws an image in order from the sprite described at the top of the drawing list based on the drawing list received from the MPU181, and expands the image by overwriting the frame buffer specified by the drawing target buffer information. As a result, in the image for one frame generated by the drawing list, the sprite drawn first can be arranged on the backmost side, and the sprite drawn last can be arranged on the frontmost side.

If the drawing list contains transfer data information, the transfer data information includes the start address (storage source start address) and the final address (storage source final address) of the character ROM 187 in which the transfer target image data is stored. ) And the start address of the transfer destination (normal video RAM 190) are extracted, and the image data stored from the storage source start address to the storage source final address are sequentially read from the character ROM 187 and temporarily stored in the buffer RAM 188a. After that, the image data stored in the buffer RAM 188a is sequentially transferred to the area indicated by the transfer destination start address of the normal video RAM 190, in anticipation of when the normal video RAM 190 is in an unused state. The image data stored in the normal video RAM 190 is used based on the drawing list subsequently transmitted from the MPU 181, and the image is drawn according to the drawing list.

The image controller 188 reads the image information of the previously expanded image from the frame buffer different from the frame buffer specified by the drawing target buffer information, and transmits the image information together with the drive signal to the auxiliary display unit 65. do. As a result, the auxiliary display unit 65 can display the expanded image in the frame buffer. Further, while expanding the image drawn in one frame buffer, the image expanded from one frame buffer can be displayed on the auxiliary display unit 65, and the drawing process and the display process can be processed in parallel at the same time. can.

The drawing process updates the drawing target buffer flag 185k after the processing of S852 (S853). Then, the drawing process is terminated, and the process returns to the V interrupt process. The drawing target buffer flag 185k is updated by inverting its value, that is, by setting it to "1" when the value is "0" and to "0" when the value is "1". Will be done. As a result, the drawing target buffers are alternately set between the first frame buffer 190b and the second frame buffer 190c each time the drawing list is transmitted.

Here, the transmission of the drawing list is performed by the MPU 181 based on the V interrupt signal transmitted from the image controller 188 every 20 milliseconds when the drawing process and the display process of the image for one frame are completed. The drawing process (see FIG. 23B) is performed every time the drawing process is executed. As a result, at a certain timing, the first frame buffer 190b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 190c is designated as the frame buffer for reading the image information for one frame. When the drawing process and the display process of are executed, the second frame buffer 190c is designated as the frame buffer for expanding the image for one frame 20 milliseconds after the drawing process for the image for one frame is completed, and one frame is specified. The first frame buffer 190b is designated as the frame buffer from which the minute image information is read. Therefore, the image information of the image previously expanded in the first frame buffer 190b can be read out and displayed on the auxiliary display unit 65, and at the same time, a new image is expanded in the second frame buffer 190c.

Then, after the next 20 milliseconds, the first frame buffer 190b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 190c is designated as the frame buffer for reading the image information for one frame. Will be done. Therefore, the image information of the image previously expanded in the second frame buffer 190b can be read out and displayed on the auxiliary display unit 65, and at the same time, a new image is expanded in the first frame buffer 190c. After that, one of the first frame buffer 190b and the second frame buffer 190c is used every 20 milliseconds for the frame buffer that expands the image for one frame and the frame buffer for reading the image information for one frame. By alternately specifying the images, it is possible to continuously perform the display processing of the image for one frame in units of 20 milliseconds while performing the drawing processing of the image for one frame.

As described above, according to the slot machine 10 of the first embodiment, the display control device 81 responds to a command from the main control device 101 (for example, a lottery result command or a payout determination result command). A display data table to be used is selected, read from the data table storage area 185d, stored in the display data table buffer 185f, and the pointer 185h is initialized. Then, the pointer 185h is incremented by 1 each time the drawing process for one frame is completed, and in the display data table stored in the display data table buffer 185f, the next is based on the drawing content defined by the address indicated by the pointer 185h. An image content to be drawn is specified, a drawing list (see FIG. 14) is created, and the drawing list is transmitted to the image controller 188 to give an instruction to draw the image. As a result, the drawing contents are specified in the order specified in the display data table according to the update of the pointer 185h, so that the image as specified in the display data table is displayed on the auxiliary display unit 65.

As described above, in the slot machine 10, in the display control device 81, the program to be executed by the MPU 181 is changed according to the command from the main control device 101 (for example, the lottery result command or the payout determination result command). Instead, the effect image to be displayed on the auxiliary display unit 65 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 185f.

Here, when the program executed by the MPU 181 is started every time the effect image displayed on the auxiliary display unit 65 is changed like a conventional gaming machine, it is complicated due to the diversification of the effect images. In addition, since a large load is applied to the processing of starting and executing the enormous program, the processing capacity of the display control device 81 is limited, and there is a possibility that the diversification of controllable production images is limited. .. On the other hand, in the slot machine 10, the display control device can change the effect image to be displayed on the auxiliary display unit 65 by a simple operation of appropriately replacing the display data table with the display data table buffer 185f. Regardless of the processing capacity of 81, various types of effect images can be displayed on the auxiliary display unit 65.

Further, in this way, a display data table is prepared corresponding to each effect mode, a display data table buffer is set according to the effect mode to be displayed, and one frame is drawn according to the set data table. The reason why the list can be created is that in the slot machine 10, the effect to be displayed on the auxiliary display unit 65 is determined in advance based on the result of the lottery performed based on the operation of the start lever 41. On the other hand, in game machines other than gaming machines such as slot machines 10, the display contents must be changed from moment to moment based on the user's operation, so that the display contents cannot be predicted. It is not possible to have a display data table corresponding to each effect mode as described above. In this way, a display data table is prepared corresponding to each effect mode, a display data table buffer is set according to the effect mode to be displayed, and a drawing list is drawn frame by frame according to the set data table. The configuration for creating the above is based on the configuration in which the slot machine 10 determines in advance the production mode of the effect to be displayed on the auxiliary display unit 65 based on the result of the lottery performed in response to the operation of the start lever 41. It can be realized for the first time.

Further, according to the slot machine 10 of the first embodiment, all the image data to be resident is transferred to the resident video RAM 189 in the initialization process immediately after the power is turned on, so that after the initialization process is completed, the image data is transferred to the resident video RAM 189. The image controller 188 can perform image drawing processing while using the image data resident in the resident video RAM 189. As a result, if the image data used for the drawing process is resident in the resident video RAM 189, it is not necessary to read the corresponding image data from the character ROM 187 configured by the NAND flash memory 187a having a slow read speed at the time of image drawing. Therefore, the time required for reading the data can be omitted, and the image can be drawn immediately and the drawn image can be displayed on the auxiliary display unit 65. In particular, since the image data of the frequently displayed image and the image data of the image to be displayed immediately after the display is determined by the main control device 101 or the display control device 81 are resident in the resident video RAM 189, the game is played. It is possible to maintain high responsiveness from the operation of the start lever 41 and the stop switches 42 to 44 by a person to the display of some image on the auxiliary display unit 65.

Further, in the slot machine 10, since the NAND type flash memory 187a is used for the character ROM 187, all the image data to be stored in the resident video RAM 189 is transmitted from the character ROM 187 due to the slow read speed. It takes a lot of time to transfer to the resident video RAM 189, but after the power is turned on, the main image at power-on is first transferred from the character ROM 187 to the resident video RAM 189, and the main image at power-on is transferred. Is displayed on the auxiliary display unit 65, so that while the remaining image data to be resident is transferred to the resident video RAM 189, the player or the person concerned with the hall is displayed on the auxiliary display unit 65 when the power is turned on. You can check the image.

Therefore, the display control device 81 may transfer the remaining resident image data from the character ROM 187 to the resident video RAM 189 over time while displaying the main image at power-on on the auxiliary display unit 65. can. On the other hand, the player or the like can recognize that some initialization processing is being performed while the main image is displayed on the auxiliary display unit 65 when the power is turned on, so that the image should be resident in the remaining resident video RAM 189. Until the data is transferred from the character ROM 187 to the resident video RAM 189, it is possible to wait until the initialization is completed without worrying that the operation has stopped. Further, even in the operation check in the factory or the like at the time of manufacturing, the main image at the time of power-on is immediately displayed on the auxiliary display unit 65, so that the slot machine 10 is immediately started to operate without any problem by power-on. Can be confirmed in. Therefore, by using the NAND flash memory 187a having a slow read speed for the character ROM 187, it is possible to prevent the efficiency of the operation check from deteriorating.

Further, according to the slot machine 10 of the first embodiment, the fixed value data for driving the control program executed by the MPU 181 and the upper lamp 63 and the like is a dedicated program ROM (for example, a dedicated program ROM like a conventional game machine). It is possible to increase the capacity in a small area for the purpose of storing a large amount of image data to be displayed on the auxiliary display unit 64, instead of providing and storing the ROM 22) of Patent Document 1 described above. It is stored in the character ROM 187 configured by the NAND flash memory 187a. As a result, since it is not necessary to provide a dedicated program ROM for storing the control program and the like, the number of parts in the display control device 81 can be reduced, the manufacturing cost can be reduced, and the failure occurrence rate increases due to the increase in the number of parts. Can be suppressed.

Further, the control program or the like stored in the NAND flash memory 187a (second program storage area 187a1) is transferred to the program storage area 185c provided in the work RAM 185 when the boot process is executed by the MPU 181. Various processes are executed with reference to the control program or the like stored in the storage area 185c. That is, the MPU 181 does not directly read the control program or the like from the NAND flash memory 187a having a slow read speed, but reads the control program or the like from the work RAM 185 configured by the DRAM capable of reading at high speed and performs various controls. Can be done. Therefore, even when the control program or the like is stored in the character ROM 187 configured by the NAND flash memory 187a, the high-performance MPU181 can be used without being limited by the read speed of the NAND flash memory 187a. High processing performance can be maintained in the display control device 81. Therefore, it is possible to easily execute a diversified and complicated production by using the auxiliary production unit.

Further, in the slot machine 10, among the boot programs, a predetermined number of instructions from the instruction to be processed first by the MPU 181 after the system reset is released are stored in the NOR type ROM 187d, and after the system reset is released, the MPU 181 via the internal bus. When the address "0000H" is specified, the character ROM 187 immediately sets the boot program stored in the first program storage area 187d1 of the NOR type ROM 187d in the buffer RAM 187c, and transfers the corresponding data (instruction code) to the MPU 181. Output. Here, since the NOR type ROM is a memory capable of reading data at high speed, the MPU 181 can receive the instruction code corresponding to the address "0000H" in a short time after the address "0000H" is specified. .. Therefore, since the display main process can be started in a short time in the MPU 181 even if the control program is stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the auxiliary effect in the display control device 81 is produced. The control of the unit can be started immediately.

Next, the slot machine 10 in the second embodiment will be described with reference to FIGS. 32 to 37. In the slot machine 10 according to the first embodiment described above, when the display control device 81 determines the effect mode of the effect in the auxiliary effect unit determined according to the command or the like received from the main control device 101, the determined effect mode is determined. The display data table corresponding to is set in the display data table buffer 185f, and the transfer data table corresponding to the display data table is set in the transfer data table buffer 185 g, and then set in the display data table buffer 185f. According to the display data table and the transfer data table set in the transfer data table buffer 185 g, the drawing of the image to be displayed on the auxiliary display unit 65 and the transfer of the image data used for the drawing from the character ROM 187 to the normal video RAM 190. The case of controlling and was explained.

On the other hand, in the slot machine 10 of the second embodiment, when the effect mode of the effect in the auxiliary effect unit determined according to the command received from the main control device 101 is determined, the display corresponding to the determined effect mode is determined. One synthetic data table obtained by synthesizing the data table and the transfer data table corresponding to the display data table is generated and set in the synthetic data table buffer 191f, and according to the synthetic data table set in the synthetic data table buffer 191f. , The drawing of the image to be displayed on the auxiliary display unit 65 and the transfer of the image data used for the drawing from the character ROM 187 to the normal video RAM 190 are controlled.

The difference in configuration of the slot machine 10 in the second embodiment from the slot machine 10 in the first embodiment is that the display control device 81 is provided with the work RAM 191 instead of the work RAM 185. Further, among the V interrupt processes (see FIG. 23 (a)) executed by the MPU 181 of the display control device 81, the lottery result command process (S739) and the payout determination result command, which are one of the command determination processes (S722). Partial processing included in the resident image transfer setting process (S817) and the normal image transfer setting process (S818), which are one of the processes (S741), the display setting process (S723), and the transfer setting process (S725). However, it is different from the slot machine 10 in the first embodiment. Other configurations, various processes executed by the MPU 102 of the main control device 101, and other processes executed by the MPU 181 of the display control device 81 are the same as those of the slot machine 10 in the first embodiment. Hereinafter, the same elements as those in the first embodiment are designated by the same reference numerals, and the illustration and description thereof will be omitted.

First, with reference to FIG. 32, the electrical configuration of the display control device 81 of the slot machine 10 in the second embodiment will be described. FIG. 32 is a block diagram showing an electrical configuration of the display control device 81 according to the second embodiment. As described above, as shown in FIG. 32, the display control device 81 in the present embodiment is provided with the work RAM 191 instead of the work RAM 185 in the display control device 81 in the first embodiment. Since other configurations are the same as those of the display control device 81 in the first embodiment, the description thereof will be omitted.

The work RAM 191 is configured by a DRAM like the work RAM 185 in the first embodiment. The work RAM 191 stores the command buffer area 191a, the bet number storage area 191b, the program storage area 191c, the data table storage area 191d, the simple image display flag 191e, the composite data table buffer 191f, the pointer 191h, and the drawing list area 191i. At least the image discrimination flag 191j and the drawing target buffer flag 191k are provided. Of these, the command buffer area 191a, the bet number storage area 191b, the program storage area 191c, the data table storage area 191d, the simple image display flag 191e, the pointer 191h, the drawing list area 191i, the stored image discrimination flag 191j, and the drawing target buffer flag 191k. Is a command buffer area 185a, a bet number storage area 185b, a program storage area 185c, a data table storage area 185d, a simple image display flag 185e, a pointer 185h, a drawing list area 185i, and a stored image discrimination flag 185j, respectively, in the first embodiment. , Has the same configuration and function as the drawing target buffer flag 185k.

For example, the data table storage area 191d is displayed on the auxiliary display unit 65 with the passage of time for one effect to be displayed based on a command from the main control device 101, similarly to the data table storage area 185d in the first embodiment. Character ROM 187 is a display data table (see FIG. 12) that describes the display contents to be displayed, and image data that is not resident in the resident video RAM 189 among the image data used in one effect displayed by the display data table. This is an area in which transfer data information for transfer from the normal video RAM 190 to the normal video RAM 190 and a transfer data table (see FIG. 13) that defines the transfer timing thereof are stored. Others are the same as those in the first embodiment, and thus the description thereof will be omitted here.

The synthetic data table buffer 191f is a buffer for storing the synthetic data table corresponding to the effect mode of the effect to be displayed on the auxiliary display unit 65 in response to a command or the like from the main control device 101. The composite data table is generated by synthesizing a display data table corresponding to the effect mode of the effect displayed on the auxiliary display unit 65 and a transfer data table corresponding to the display data table.

Here, the details of the synthetic data table will be described with reference to FIG. 33. FIG. 33 is a schematic diagram schematically showing an example of a synthetic data table. In the composite data table, the time for displaying an image for one frame on the auxiliary display unit 65 (20 milliseconds in this embodiment) corresponds to an address represented as one unit, and is displayed at the time indicated by that address. The content of the image for one frame to be transferred (drawing content) and the transfer data information of the sprite image data (hereinafter referred to as "transfer target image data") to start the transfer at the time indicated by the address are combined. Is stipulated.

Specifically, as shown in FIG. 33, the composite data table is provided with a display data table area and a transfer data table area for each address. The display data table area of each address is associated with the same address as the address specified in the composite data table in the display data table corresponding to the effect mode of the effect to be displayed on the auxiliary display unit 65. The content (drawing content) of the image for one frame to be displayed at the time indicated by the address is transcribed as it is. For example, in the display data table area of the address "0001H" of the composite data table, the address "0001H" associated with the address "0001H" of the display data table corresponding to the effect mode of the effect to be displayed on the auxiliary display unit 65 is associated with the address "0001H". The drawing content to be displayed at the time indicated by "0001H" is transcribed as it is.

Further, in the transfer data table area of each address of the composite data table, in the transfer data table corresponding to the display data table for posting the drawing contents to the display data table area, the same address as the address specified in the composite data table is used. The transfer data information of the image data to be transferred that should start the transfer at the time indicated by the associated address is posted as it is. If Null data, which means that there is no transfer target image data to be transferred corresponding to the address, is specified in one address of the transfer data table, one of the composite data tables is specified. Null data is posted as it is to the transfer data table area of the address.

For example, the transfer data table area of the composite data table address "0001H" is associated with the transfer data table address "0001H" corresponding to the display data table posted in the display data table area. The transfer data information of the transfer target image data to be transferred at the time indicated by "0001H" is transferred as it is. Further, when the Null data is specified in the transfer data table address "0002H" corresponding to the display data table posted in the display data table area, the transfer data table area of the composite data table address "0002H" is used. However, the Null data is posted as it is.

If the transfer data table corresponding to the display data table for posting the drawing contents is not prepared in the display data table area, all the image data of the sprite used in the effect specified in the display data table is resident. Since it is stored in the video RAM 189 and means that the transfer from the character ROM 187 to the normal video RAM 190 is unnecessary, the transfer target image to be transferred to the transfer data table area of all the addresses of the composite data table. Null data is described, which means that the data does not exist.

Similar to the display data table shown in FIG. 12, "Start" information indicating the start of the data table is described in the "0000H" which is the start address of the synthetic data table, and the final address of the synthetic data table (example of FIG. 33). Then, in "02F0H"), "End" information indicating the end of the data table is described. Then, each address between the address "0000H" in which the "Start" information is described and the address in which the "End" information is described is displayed on the auxiliary display unit 65 to be specified in the composite data table. The drawing contents corresponding to the effect mode of the above and the transfer data information of the transfer target image data are described.

The MPU 181 corresponds to an effect mode to be displayed on the auxiliary display unit 65, which is one of the auxiliary effect units, when the effect mode to be executed by the auxiliary effect unit is determined based on a command or the like received from the main control device 101. The display data table to be displayed and the transfer data table corresponding to the display data table are extracted from the data table storage area 191d. Then, the content (drawing content) of the image for one frame to be displayed at the time indicated by the address specified for each address in the extracted display data table is displayed in the display data table of the same address in the composite data table. The transfer data information of the transfer target image data that should be transferred to the area and the transfer should be started at the time indicated by that address specified for each address in the extracted transfer data table is transferred to the same address in the composite data table. By posting to the transfer data table area, a composite data table that combines the display data table and the transfer data table is generated.

If the transfer data table corresponding to the display data table for posting the drawing contents is not prepared in the display data table area of the composite data table, as described above, the transfer data table area of all the addresses of the composite data table. The composite data table is generated by writing the Null data, which means that there is no transfer target image data to be transferred to.

The MPU 181 initializes the pointer 191h when the generated synthetic data table is set in the synthetic data table buffer 191f. Then, after adding 1 to 191h each time the drawing process for one frame is completed, the drawing contents defined in the display data table area of the address indicated by the pointer 191h from the synthetic data table stored in the synthetic data table buffer 191f. The image content to be drawn next is specified based on the above, and the transfer data information of the image data of the predetermined sprite specified in the transfer data table area of the address to start the transfer at that time is specified and drawn. Create a list (see Figure 14). By transmitting this drawing list to the image controller 188, the MPU 181 gives an image controller 188 a drawing instruction for the image and an image data transfer instruction. Further, when the Null data is specified in the transfer data table area of the address indicated by the pointer 191h, it is determined that the transfer target image data to be transferred does not exist, and the transfer data information is not included in the drawing list. , The drawing list is transmitted to the image controller 188.

As a result, the drawing contents are specified in the order specified in the display data table according to the update of the pointer 191h, so that the image as specified in the display data table is displayed on the auxiliary display unit 65. Further, according to the update of the pointer 191h, a process of transferring the image data of the predetermined sprite from the character ROM 187 to the predetermined sub-area of the image storage area 190a provided in the normal video RAM 190 is executed at a predetermined time.

As described above, in the slot machine 10, in the display control device 81, the program to be executed by the MPU 181 is changed according to the command from the main control device 101 (for example, the lottery result command or the payout determination result command). Instead, the effect image to be displayed on the auxiliary display unit 65 can be changed only by a simple operation of appropriately replacing the display data table used for generating the composite data table.

Here, when the program executed by the MPU 181 is started every time the effect image displayed on the display control device 81 is changed as in the conventional slot machine, it becomes complicated due to the diversification of the effect images. In addition, since a large load is applied to the processing of starting and executing the enormous program, the processing capacity of the display control device 81 is limited, and there is a possibility that the diversification of controllable production images is limited. .. On the other hand, in the slot machine 10, the effect image to be displayed on the auxiliary display unit 65 can be changed by a simple operation of appropriately replacing the display data table used for generating the composite data table, so that the display control can be performed. Regardless of the processing capacity of the device 81, various types of effect images can be displayed on the auxiliary display unit 65.

Further, in this way, a display data table is prepared corresponding to each effect mode, a composite data table is generated from the display data table according to the effect mode to be displayed, and the synthetic data table is according to the generated composite data table. The reason why the drawing list can be created frame by frame is that in the slot machine 10, the effect to be displayed on the auxiliary display unit 65 is determined in advance based on the result of the lottery performed in response to the operation of the start lever 41. Is. On the other hand, in a game machine other than a game machine such as a slot machine 10, the display content changes on the spot based on the user's operation, so that the display content cannot be predicted. Therefore, as described above. It is not possible to have a display data table corresponding to each effect mode. In this way, a display data table is prepared corresponding to each effect mode, a composite data table is generated from the display data table according to the effect mode to be displayed, and this is set in the composite data table buffer 191f. The configuration in which the drawing list is created frame by frame according to the set synthetic data table is an effect that the slot machine 10 displays in advance on the auxiliary display unit 65 based on the result of the lottery performed in response to the operation of the start lever 41. It can be realized only based on the configuration that determines the aspect.

Further, in the transfer data table, as described above in the first embodiment, the image data corresponding to the predetermined sprite is stored in the image of the normal video RAM 190 by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information of the image data to be transferred is specified for a predetermined address so as to be stored in the area 190a, the image data is stored according to the transfer data information specified in the transfer data table area of the composite data table. By transferring from the character ROM 187 to the image storage area 190a, when drawing a predetermined sprite according to the display data table area of the composite data table, the image data that is not resident in the resident video RAM 189 required for drawing the sprite is transferred. , Can always be stored in the image storage area 190a. Then, using the image data stored in the image storage area 190a, a predetermined sprite can be drawn based on the display data table.

As a result, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, the image necessary for display can be read in advance from the character ROM 187 and transferred to the normal video RAM 190 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the auxiliary display unit 65. Further, by describing the transfer data table area of the composite data table, only the non-resident image data in the resident video RAM 189 can be easily and surely transferred from the character ROM 187 to the normal video RAM 190.

Further, in the slot machine 10, the display control device 81 extracts the display data table from the data table storage area 191d in response to a command from the main control device 101 (for example, a lottery result command or a payout determination result command). The transfer data table corresponding to the display data table is extracted from the data table storage area 191d, and a composite data table is generated by combining the extracted display data table and the transfer data table. The transfer timing of image data can be easily grasped and controlled. Therefore, the image data of the sprite used for drawing the image performed according to the display data table area of the composite data table can be reliably transferred from the character ROM 187 to the normal video RAM 190 at a desired timing.

Further, in the transfer data table, the transfer data information is defined so that the image data is transferred from the character ROM 187 to the normal video RAM 190 for each image data corresponding to the sprite. Therefore, in the transfer data table area of the composite data table. Also, the transfer data information is defined so that the image data is transferred from the character ROM 187 to the normal video RAM 190 for each image data corresponding to the sprite. As a result, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 187 to the normal video RAM 190 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

Further, the transfer data table has a data structure similar to that of the display data table, and is associated with an address specified in the display data table, and transfer of transfer target image data to be started at the time indicated by the address. Since the data information is specified, a synthetic data table can be easily generated.

Further, a display data table area and a transfer data table area are provided for each address of the composite data table, and the display data table area of each address defines the drawing content to be displayed at the time indicated by the address. At the same time, the transfer data table area of each address defines the transfer data information of the transfer target image data to start the transfer at the time indicated by the address. Therefore, the image data of the predetermined sprite based on the display data table area. The transfer start timing can be specified and instructed based on the transfer data table area so that the image data is surely stored in the normal video RAM 190 before the transfer is used. Therefore, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, a wide variety of effect images can be easily displayed on the auxiliary display unit 65.

Further, since the drawing content and the transfer data information can be specified from one composite data table, the specification can be compared with the case where the drawing content and the transfer data information are specified from the display data table and the transfer data table, respectively. The processing load required for this can be reduced.

Next, with reference to FIGS. 34 to 37, various processes executed by the MPU 181 of the display control device 81 in the second embodiment will be described. First, FIG. 34 is a flowchart showing a lottery result command process (S739) executed by the MPU 181 of the display control device 81. As described above in the first embodiment, the lottery result command process is a process executed in the command determination process (S722), which is one process of the V interrupt process (see FIG. 23 (b)), and is a main process. When the lottery result command is received from the control device 101, the process corresponding to the lottery result command is executed.

In this lottery result command processing, the processing of S761 to S771 and the processing of S773 are the same as the processing of S761 to S771 and the processing of S773 of the lottery result command processing in the first embodiment. Therefore, although detailed description of these processes will be omitted, the information regarding the number of bets stored in the bet number storage area 191b by the processes of S761 to S771, the winning combination grasped by the lottery result command, and the status command Each auxiliary effect is based on the game state (either the normal game state, the BB game state, or the BB carry-over game state) of the slot machine 10 notified and stored in the work RAM 185, the value of the random number counter provided in the work RAM 185, and the like. The production mode of the effect to be executed by the department is determined.

Then, when the effect mode of the effect to be executed by each auxiliary effect unit is determined by the processes of S761 to S771, the lottery result command process in the second embodiment is the process of S762, S764, S766, S768, S770 or S771. The display data table corresponding to the effect mode determined by the above and the transfer data table corresponding to the display data table are extracted from the data table storage area 191d and synthesized to generate the composite data table shown in FIG. 33. (S901).

That is, as described above, the display data table area provided for each address of the composite data table is associated with the same address as the address specified in the composite data table in the extracted display data table. The content (drawing content) of the image for one frame to be displayed at the time indicated by the address is transcribed as it is. Further, in the transfer data table area provided for each address of the composite data table, the extracted transfer data table is indicated by the address associated with the same address as the address specified in the composite data table. The transfer data information of the transfer target image data to be transferred at the time is transferred as it is.

If the one address in the transfer data table specifies the Null data that means that the transfer target image data that should start the transfer does not exist corresponding to that address, the one in the composite data table is specified. The Null data is also posted to the transfer data table area of the address as it is. If the transfer data table corresponding to the extracted display data table is not prepared, all the image data of the sprite used in the effect specified in the display data table is stored in the resident video RAM 189. This means that the transfer from the character ROM 187 to the normal video RAM 190 is unnecessary, and therefore, it means that the transfer target image data to be transferred does not exist in the transfer data table area of all the addresses of the composite data table. The synthetic data table is generated by writing the Null data. As a result, if the Null data is written in the transfer data table area of the address indicated by the pointer 191h in the synthetic data table set in the synthetic data table buffer 191f, the MPU 181 transfers the data at the time indicated by the address. It is possible to grasp that there is no transfer target image data to be started.

Then, after the processing of S901, the synthetic data table generated by the processing of S901 is set in the synthetic data table buffer 191f (S902). After that, the pointer h is initialized to 0 (S773) as in the first embodiment, and the lottery result command processing is terminated.

As described above, in the lottery result command processing, when the effect mode of the effect displayed on the auxiliary display unit 65 is determined according to the winning combination grasped by the lottery result command, the determined effect mode is adopted. A synthetic data table is generated from the corresponding display data table and the transfer data table corresponding to the display data table, the generated synthetic data table is set in the synthetic data table buffer 191f, and the pointer 191h is initialized. Will be done.

As a result, the MPU 181 updates the pointer 191h in the display setting process (see FIG. 36), and displays the display data of the address indicated by the pointer 191h from the synthetic data table set in the synthetic data table buffer 191f by the process of S902. The drawing contents defined in the table area can be extracted, and the contents of the image for one frame to be displayed next can be specified in the auxiliary display unit 65. Further, the MPU 181 is used from the composite data table set in the composite data table buffer 191f by the process of S902 in the normal image transfer setting process (see FIG. 37), which is one of the transfer setting processes (see FIG. 50 (a)). The transfer data information specified in the transfer data table area of the address indicated by the pointer 191h is extracted, and the image data of the sprite specified in the display data table area is previously transferred from the character ROM 187 to the image storage area 190a of the normal video RAM 190. The image controller 188 can be controlled to be transferred. As a result, the images drawn by the composite data table set in the composite data table buffer 191f are sequentially displayed on the auxiliary display unit 65, and the effect of the effect mode corresponding to the composite data table is displayed on the auxiliary display unit 65. Can be made to.

Next, with reference to FIG. 35, the payout determination result command processing (S741) executed by the MPU 181 of the display control device 81 will be described. FIG. 35 is a flowchart showing the payout determination result command processing. As described above in the first embodiment, the payout determination result command process is a process executed in the command determination process (S722), which is one process of the V interrupt process (see FIG. 23 (b)). When the payout result command is received from the main control device 101, the process corresponding to the payout determination result command is executed.

In this payout determination result command processing, the processing of S781 to S782 and the processing of S784 are the same as the processing of S781 to S782 and the processing of S784 of the lottery result command processing in the first embodiment. Therefore, although detailed description of these processes will be omitted, the process of S781 to S782 extracts the payout determination result from the payout determination result command, and the extracted payout determination result and the bet number storage area 191b. Based on the information about the number of bets stored in, the game state of the slot machine 10 notified by the state command and stored in the work RAM 185, the value of the random number counter provided in the work RAM 185, and the like, each auxiliary effect The production mode of the effect to be executed by the department is determined.

Then, when the effect mode of the effect to be executed by each auxiliary effect unit is determined by the processing of S782, in the lottery result command processing in the second embodiment, the display data table corresponding to the determined effect mode and the display data table thereof. The transfer data table corresponding to the display data table is extracted from the data table storage area 191d and synthesized to generate the composite data table shown in FIG. 33 (S903). Since the specific method for generating the synthetic data table is the same as that of S901 (see FIG. 34) described above, the description thereof will be omitted here.

Then, the synthetic data table generated by the process of S903 is set in the synthetic data table buffer 191f (S904). After that, the pointer h is initialized to 0 (S784) as in the first embodiment, and the payout determination result command processing is terminated.

As described above, in the payout determination result command processing, as in the lottery result command processing, the effect mode of the effect displayed on the auxiliary display unit 65 is set according to the result of the payout determination grasped by the payout determination result command. Once determined, a synthetic data table is generated from the display data table corresponding to the determined effect mode and the transfer data table corresponding to the display data table, and the generated synthetic data table is the synthetic data table buffer. The pointer 191h is initialized while being set to 191f.

As a result, the MPU 181 updates the pointer 191h in the display setting process (see FIG. 36), and displays the display data of the address indicated by the pointer 191h from the synthetic data table set in the synthetic data table buffer 191f by the process of S904. The drawing contents defined in the table area can be extracted, and the contents of the image for one frame to be displayed next can be specified in the auxiliary display unit 65. Further, the MPU 181 is used from the composite data table set in the composite data table buffer 191f by the process of S904 in the normal image transfer setting process (see FIG. 37), which is one of the transfer setting processes (see FIG. 50 (a)). The transfer data information specified in the transfer data table area of the address indicated by the pointer 191h is extracted, and the image data of the sprite specified in the display data table area is previously transferred from the character ROM 187 to the image storage area 190a of the normal video RAM 190. The image controller 188 can be controlled to be transferred. As a result, the images drawn by the composite data table set in the composite data table buffer 191f are sequentially displayed on the auxiliary display unit 65, and the effect of the effect mode corresponding to the composite data table is displayed on the auxiliary display unit 65. Can be made to.

Next, the display setting process (S723) executed by the MPU 181 of the display control device 81 will be described with reference to FIG. 36. FIG. 36 is a flowchart showing this display setting process. As described above in the first embodiment, the display setting process is a process executed in the V interrupt process (see FIG. 23 (b)), and is a composite data table buffer 191f by a command determination process (S722) or the like. Based on the content of the composite data table set in, the content of the image for one frame to be displayed next in the auxiliary display unit 65 is specifically specified. Further, in the display setting process, the pointer 191h is also updated.

In this display setting process, the processes of S801 to S805, the process of S806, the process of S810, and the process of S812 are the processes of S801 to S805, the process of S806, and the process of S810 of the display setting process in the first embodiment. And, the same processing as the processing of S812 is performed. Therefore, although detailed description of these processes is omitted, when the process corresponding to the error command is executed in the command determination process executed earlier by the processes of S801 to S805, it is grasped by the error command. When the warning image data corresponding to the error type is expanded and then 1 is added to the pointer 191h by the processing of S806, in the display setting processing in the second embodiment, the composition set in the composition data table buffer 191f is performed. In the data table, it is determined whether or not the data at the address indicated by the updated pointer 191h is End information (S905).

As a result, if it is End information (S905: Yes), it means that the pointer 191h is updated past the address in which the actual data is described in the synthetic data table set in the synthetic data table buffer 191f.

Therefore, the synthetic data table stored in the synthetic data table buffer 191f is directed to the payout result, for example, the "winning prize" is notified that the symbols corresponding to the winning winning combinations won in the lottery are aligned on the valid line. Whether or not it corresponds to the effect mode set by the payout determination result command processing, such as "establishment effect" and "disappearance effect" that notifies that the payout is not performed due to the disengagement, that is, the payout determination result command processing. It is determined whether or not the data is generated based on the display data table corresponding to the effect mode set by (S906). For this determination, for example, when the composite data table is generated, the effect mode corresponding to the display data table used in the generation is stored in the work RAM 191 and stored in the work RAM 191 in the processing of S906. It is performed by reading out the effect mode.

As a result, if it is a synthetic data table corresponding to the effect on the payout result (S906: Yes), the player operates the start lever 41 to start the next game after the effect on the payout result is completed. The display data table corresponding to the "game start waiting effect" displayed up to and the transfer data table corresponding to the display data table are extracted from the data table storage area 191d, and these are combined and shown in FIG. 33. The composite data table shown is generated (S907). Since the specific method for generating the synthetic data table is the same as that of S901 (see FIG. 34) described above, the description thereof will be omitted here.

Then, the synthetic data table generated by the process of S907 is set in the synthetic data table buffer 191f (S908). After that, the pointer h is set to 1 (S810) as in the first embodiment, and the process proceeds to S910.

In this way, in the display setting process, when the effect for the payout result such as the "winning establishment effect" or the "off effect" started by the setting of the payout determination result command process is displayed on the auxiliary display unit 65 until the end, " A synthetic data table is generated from the display data table corresponding to the "game start waiting effect" and the transfer data table corresponding to the display data table, and the generated synthetic data table is set in the synthetic data table buffer 191f. , The pointer 191h is set to 1.

As a result, after that, while updating the pointer 191h each time the display setting process is executed, the address indicated by the pointer 191h is displayed from the synthetic data table corresponding to the game start waiting effect set in the synthetic data table buffer 191f. The drawing contents defined in the display data table area can be extracted, and the contents of the image for one frame to be displayed next can be specified in the auxiliary display unit 65. Therefore, after the display of the effect for the payout result is completed, the auxiliary display unit 65 can display the effect waiting for the start of the game. Further, the MPU 181 is a composite corresponding to the game start waiting effect set in the composite data table buffer 191f in the normal image transfer setting process (see FIG. 37), which is one of the transfer setting processes (see FIG. 50 (a)). The transfer data information specified in the transfer data table area of the address indicated by the pointer 191h is extracted from the data table, and the image data of the sprite specified in the display data table area is the image of the normal video RAM 190 from the character ROM 187 in advance. The image controller 188 can be controlled so that it is transferred to the storage area 190a. As a result, the images drawn by the composite data table set in the composite data table buffer 191f are sequentially displayed on the auxiliary display unit 65, and the game start waiting effect corresponding to the composite data table is displayed on the auxiliary display unit 65. Can be made to.

On the other hand, as a result of the determination of S906, if the synthetic data table stored in the synthetic data table buffer 191f does not correspond to the effect for the payout result (S906: No), then it is stored in the synthetic data table buffer 191f. The synthetic data table is used for the above-mentioned notification effects such as "BB prize announcement effect", "watermelon prize announcement effect", and "bell prize announcement effect" to announce the winning role at the time of lottery, and "BB prize challenge". Whether or not it corresponds to the above-mentioned challenge production that encourages the player to establish a winning combination, such as "directing", "cherry bell winning / 7 bell winning challenge production", and "cherry bell winning challenge production", that is, notification. It is determined whether or not the data is generated based on the display data table corresponding to the effect or challenge effect (S909). As a result, if it is a display data table corresponding to the notification effect or the challenge effect (S909: Yes), the value of the pointer 191h is subtracted by 1 (S812) as in the first embodiment, and the process proceeds to S910. .. As a result, in the display setting process, when the composite data table corresponding to the notification effect or the challenge effect is set in the composite data table buffer 191f, the notification effect or the challenge effect is displayed on the auxiliary display unit 65 until the end. The drawing content of the previous address in which the End information is described is always expanded. Therefore, when the notification effect and the challenge effect are displayed to the end, the auxiliary display unit 65 can display the last image defined in the composite data table in a stopped state.

On the other hand, as a result of the determination of S909, if the synthetic data table stored in the synthetic data table buffer 191f does not correspond to the notification effect or the challenge effect (S909: No), the process proceeds to S810. Then, as in the first embodiment, the pointer 191h is set to 1, and the process proceeds to S910. As a result, in the display setting process, when an effect that does not correspond to any of the effect for the payout result, the notification effect, and the challenge effect, for example, a normal game effect or a game start waiting effect is displayed to the end, it corresponds again. Since the drawing contents can be expanded in order from the beginning of the composite data table, the auxiliary display unit 65 can repeatedly display those effects.

As described above, when the synthetic data table stored in the synthetic data table buffer 191f is read to the end, it is used to generate an effect mode corresponding to the synthetic data table, specifically, a synthetic data table. Auxiliary display is performed by setting a new composite data table in the composite data table buffer 191f, setting the pointer 191h to 1, or subtracting only 1 according to the type of effect mode corresponding to the display data table. The effect mode displayed in the unit 65 is changed, the effect mode corresponding to the composite data table stored in the composite data table buffer 191f is repeatedly displayed from the beginning, and the last image of the effect mode is stopped. It can be displayed in the state where it is made. Therefore, when the composite data table stored in the composite data table buffer 191f is read to the end, it is possible to easily set an image to be continuously displayed on the auxiliary display unit 65 according to the contents of the composite data table. Can be done. In particular, the pointer 191h is set to 1 when the set effect mode is repeatedly displayed on the auxiliary effect unit 65, and the value of the pointer 191h is set to 1 when the last image of the set effect mode is stopped and displayed. Since these effects can be displayed only by subtraction, it is not necessary to reset the composite data table buffer 191f, and the processing load related to them can be lightened.

In the present embodiment, in the above-mentioned notification effect and challenge effect, when those effects are displayed on the auxiliary display unit 65 until the end, the case where the last image is stopped and displayed has been described, but it is not always the case. The present invention is not limited to this, and in another effect, when those effects are displayed on the auxiliary display unit 65 until the end, the last image may be stopped and displayed. In this case, in the process of S909, it may be determined whether or not the composite data table stored in the composite data table buffer 191f is an effect of stopping and displaying the last image.

Further, in the notification effect or the challenge effect, when the effect is displayed on the auxiliary display unit 65 until the end, it may be repeatedly displayed from the beginning. In this case, in the process of S909, if the composite data table stored in the composite data table buffer 191f is a notification effect or a challenge effect to be repeatedly displayed from the beginning, the determination of S909: No is performed and the process of S810 is performed. You may try to move to. As a result, in the notification effect or the challenge effect, when the effect is displayed on the auxiliary display unit 65 until the end, it can be repeatedly displayed from the beginning.

As a result of the processing of S905, in the synthetic data table set in the synthetic data table buffer 191f, when it is determined that the data of the address indicated by the pointer 191h updated by the processing of S806 is not End information, S906 to S909 And, the processing of S810 and S812 is skipped, and the process proceeds to the processing of S910.

In the process of S910, the drawing contents described in the display data table area provided at the address indicated by the updated pointer 191h are expanded from the synthetic data table set in the synthetic data table buffer 191f (S910). Then, after finishing the processing of S910, the display setting processing is finished, and the process returns to the V interrupt processing. In the task process (see S724 in FIG. 23 (b)) performed after the display setting process (S723), an image is configured based on the previously expanded warning image and the drawing contents expanded in the process of S910. The type of sprite (display object) to be displayed is specified, and various parameters necessary for drawing such as the display coordinate position, the enlargement ratio, and the rotation angle are determined for each sprite.

The resident image transfer setting process (S817, FIG. 29) executed in the transfer setting process (S725), which is one of the V interrupt processes (see FIG. 23 (b)) executed by the MPU 181 of the display control device 81 (see FIG. 23 (b)). In b)) as well, among the resident image transfer setting processes in the first embodiment, the process of S825 is replaced with the same process as the processes of S907 and S908 of the display setting process (see FIG. 36) in the second embodiment. Be done. Regarding the other processes of the resident image transfer setting process, that is, the processes of S821 to S824 and S826 to S827, the same processes as those of the resident image transfer setting processes S821 to S824 and S826 to S827 in the first embodiment are performed. It will be done.

As a result, when all the image data to be resident in the resident video RAM 189 is transferred from the character ROM 187 to the resident video RAM 189, the V interrupt process executed by the next and subsequent V interrupts (see FIG. 23 (b)). In the display setting process of)), the drawing contents are expanded in order from the beginning of the synthetic data table corresponding to the "game start waiting effect" set by the same process as S907 and S908. Therefore, after all the image data that should be resident in the resident video RAM 189 is transferred from the character ROM 187 to the resident video RAM 189, the auxiliary display unit 65 displays the game start waiting effect instead of the main image when the power is turned on. be able to.

In this way, in the resident image transfer setting process, when all the image data that should be resident in the resident video RAM 189 is transferred from the character ROM 187 to the resident video RAM 189, the display data table corresponding to the "game start waiting effect" is displayed. , A synthetic data table is generated from the transfer data table corresponding to the display data table, the generated synthetic data table is set in the synthetic data table buffer 191f, and the pointer 191h is initialized to 0.

As a result, while updating the pointer 191h each time the display setting process (S723) is executed, the address indicated by the pointer 191h is displayed from the synthetic data table corresponding to the game start waiting effect set in the synthetic data table buffer 191f. The drawing contents defined in the display data table area can be extracted, and the contents of the image for one frame to be displayed next can be specified in the auxiliary display unit 65. Therefore, after all the image data to be resident in the resident video RAM 189 is transferred from the character ROM 187 to the resident video RAM 189, the auxiliary display unit 65 can display the game start waiting effect. Further, the MPU 181 is a composite corresponding to the game start waiting effect set in the composite data table buffer 191f in the normal image transfer setting process (see FIG. 37), which is one of the transfer setting processes (see FIG. 50 (a)). The transfer data information specified in the transfer data table area of the address indicated by the pointer 191h is extracted from the data table, and the image data of the sprite specified in the display data table area is stored in advance from the character ROM 187 in the image of the normal video RAM 190. The image controller 188 can be controlled so that it is transferred to the area 190a. As a result, the images drawn by the composite data table set in the composite data table buffer 191f are sequentially displayed on the auxiliary display unit 65, and the game start waiting effect corresponding to the composite data table is displayed on the auxiliary display unit 65. Can be made to.

Next, the normal image transfer setting process (S818) executed by the MPU 181 of the display control device 81 will be described with reference to FIG. 37. FIG. 37 is a flowchart showing this normal image transfer setting process. As described above in the first embodiment, the normal image transfer setting process is a process executed in the transfer setting process (S725), which is one of the V interrupt processes (see FIG. 23 (b)). While the simple image display flag 185e is off, predetermined image data is sent to the image controller 188 based on the transfer data information described in the transfer data table area of the composite data table set in the composite data table buffer 191f. A transfer instruction for transferring from the character ROM 187 to a predetermined sub-area of the image storage area 190a of the normal video RAM 190 is set.

In this normal image transfer setting process, first, from the composite data table set in the composite data table buffer 191f, the address indicated by the pointer 191h updated by the display setting process (S723, see FIG. 36) executed earlier. The information described in the transfer data table area provided in S911 is acquired (S911), and the process proceeds to S832. Then, in the processing of S832 to S841, the same processing as the processing of S832 to S841 of the normal image transfer setting processing in the first embodiment is performed. Therefore, detailed description of these processes will be omitted.

As described above, in the display control device 81, the display data table is extracted from the data table storage area 185d in response to a command from the main control device 101 (for example, a lottery result command or a payout determination result command). At the same time, the transfer data table corresponding to the display data table is also extracted in the data table storage area 185d, and a composite data table as shown in FIG. 33 is generated from these display data tables and the transfer data table, and the composite data table is generated. It is set in the buffer 191f. Then, the MPU 181 executes the normal image transfer setting process, and the transfer data described in the transfer data table area provided at the address indicated by the pointer 191h of the composite data table set in the composite data table buffer 191f. Since the transfer instruction of the transfer target image is set to the image controller 188 according to the information, the image data of the sprite specified in the display data table area of the composite data table buffer 191f can be reliably transferred from the character ROM 187 to the normal video at a desired timing. It can be transferred to RAM 190.

Here, as in the first embodiment, the transfer data is stored so that the image data corresponding to the predetermined sprite is stored in the image storage area 190a by the time the drawing of the predetermined sprite is started according to the display data table. In the table, since the transfer data information of the image data to be transferred is specified for a predetermined address, the image data is transferred from the character ROM 187 to the image storage area according to the transfer data information specified in the transfer data table area of the composite data table. By transferring to 190a, when drawing a predetermined sprite according to the display data table area of the composite data table, the image data that is not resident in the resident video RAM 189 required for drawing the sprite is sure to be stored in the image storage area 190a. Can be stored in. Then, using the image data stored in the image storage area 190a, a predetermined sprite can be drawn based on the display data table.

As a result, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, the image necessary for display can be read in advance from the character ROM 187 and transferred to the normal video RAM 190 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the auxiliary display unit 65. Further, by describing the transfer data table area of the composite data table, only the non-resident image data in the resident video RAM 189 can be easily and surely transferred from the character ROM 187 to the normal video RAM 190.

Further, in the transfer data table, the transfer data information is defined so that the image data is transferred from the character ROM 187 to the normal video RAM 190 for each image data corresponding to the sprite. Therefore, in the transfer data table area of the composite data table. Also, the transfer data information is defined so that the image data is transferred from the character ROM 187 to the normal video RAM 190 for each image data corresponding to the sprite. As a result, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 187 to the normal video RAM 190 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

As described above, according to the slot machine 10 of the second embodiment, the display control device 81 responds to a command from the main control device 101 (for example, a lottery result command or a payout determination result command). A display data table to be used is selected, it is extracted from the data table storage area 191d, and a transfer data table corresponding to the extracted display data table is extracted from the data table storage area 191d. Then, the extracted display data table and the transfer data table are combined to generate the synthetic data table shown in FIG. 33, which is stored in the synthetic data table buffer 191f, and the pointer 191h is initialized. Next, the pointer 191h is incremented by 1 each time the drawing process for one frame is completed, and in the composite data table stored in the composite data table buffer 191f, the drawing content defined in the display data table area of the address indicated by the pointer 191h. The next image content to be drawn is specified based on. Then, based on the specified drawing content, the drawing list shown in FIG. 14 is created by the drawing process (S726, see FIG. 31), and the drawing list is transmitted to the image controller 188 to give an instruction to draw the image. Therefore, by specifying the drawing contents in the order specified in the composite data table according to the update of the pointer 191h, the image as specified in the display data table is displayed on the auxiliary display unit 65.

As described above, in the slot machine 10, in the display control device 81, the program to be executed by the MPU 181 is changed according to the command from the main control device 101 (for example, the lottery result command or the payout determination result command). Instead, the effect image to be displayed on the auxiliary display unit 65 can be changed only by a simple operation of appropriately replacing the display data table used for generating the composite data table.

Here, when the program executed by the MPU 181 is started every time the effect image displayed on the display control device 81 is changed as in the conventional slot machine, it becomes complicated due to the diversification of the effect images. In addition, since a large load is applied to the processing of starting and executing the enormous program, the processing capacity of the display control device 81 is limited, and there is a possibility that the diversification of controllable production images is limited. .. On the other hand, in the slot machine 10, the effect image to be displayed on the auxiliary display unit 65 can be changed by a simple operation of appropriately replacing the display data table used for generating the composite data table, so that the display control can be performed. Regardless of the processing capacity of the device 81, various types of effect images can be displayed on the auxiliary display unit 65.

Further, in this way, a display data table is prepared corresponding to each effect mode, a composite data table is generated from the display data table according to the effect mode to be displayed, and the synthetic data table is according to the generated composite data table. The reason why the drawing list can be created frame by frame is that in the slot machine 10, the effect to be displayed on the auxiliary display unit 65 is determined in advance based on the result of the lottery performed in response to the operation of the start lever 41. Is. On the other hand, in a game machine other than a game machine such as a slot machine 10, the display content changes on the spot based on the user's operation, so that the display content cannot be predicted. Therefore, as described above. It is not possible to have a display data table corresponding to each effect mode. In this way, a display data table is prepared corresponding to each effect mode, a display data table buffer is set according to the effect mode to be displayed, and a drawing list is drawn frame by frame according to the set data table. The configuration for creating the above is based on the configuration in which the slot machine 10 determines in advance the production mode of the effect to be displayed on the auxiliary display unit 65 based on the result of the lottery performed in response to the operation of the start lever 41. It can be realized for the first time.

Further, a display data table area and a transfer data table area are provided for each address of the composite data table, and the display data table area of each address defines the drawing content to be displayed at the time indicated by the address. At the same time, the transfer data table area of each address defines the transfer data information of the transfer target image data to start the transfer at the time indicated by the address. Therefore, the image data of the predetermined sprite based on the display data table area. The transfer start timing can be specified and instructed based on the transfer data table area so that the image data is surely stored in the normal video RAM 190 before the transfer is used. Therefore, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, a wide variety of effect images can be easily displayed on the auxiliary display unit 65.

Further, since the drawing content and the transfer data information can be specified from one composite data table, the specification can be compared with the case where the drawing content and the transfer data information are specified from the display data table and the transfer data table, respectively. The processing load required for this can be reduced.

In addition, the slot machine 10 in the second embodiment can exert the same operation and effect as the slot machine 10 in the first embodiment based on the same components as the slot machine 10 in the first embodiment.

Next, the slot machine 10 in the third embodiment will be described with reference to FIGS. 38 to 43. In the slot machine 10 according to the first embodiment described above, a display data table describing display contents (drawing contents) to be displayed on the auxiliary display unit 65 with the passage of time is displayed as an auxiliary display based on a command or the like from the main control device 101. An image that is not resident in the resident video RAM 189 among the image data used for display (drawing) by the display data table is prepared for each effect mode of the effect displayed in the unit 65. The case of preparing the transfer data information for transferring the data from the character ROM 187 to the normal video RAM 190 and the transfer data table defining the transfer timing has been described.

On the other hand, in the slot machine 10 in the third embodiment, the display contents to be displayed on the auxiliary display unit 65 with the passage of time in the display data table prepared for each effect mode of the effect displayed on the auxiliary display unit 65. Transfer data information for transferring not only (drawing content) but also image data used for display (drawing) that is not resident in the resident video RAM 189 from the character ROM 187 to the normal video RAM 190, and the transfer data information thereof. Specify the transfer timing. Then, when the display control device 81 determines the effect mode of the effect in the auxiliary effect unit determined according to the command or the like received from the main control device 101, the display data table displays the display data table corresponding to the determined effect mode. By setting the buffer 192f, the image to be displayed on the auxiliary display unit 65 is drawn according to the display data table set in the display data table buffer 192f, and the image data used for the drawing is drawn from the character ROM 187 to the normal video. Controls transfer to RAM 190.

The difference in configuration of the slot machine 10 in the third embodiment from the slot machine 10 in the first embodiment is that the display control device 81 is provided with the work RAM 192 instead of the work RAM 185. Further, among the V interrupt processes (see FIG. 23 (a)) executed by the MPU 181 of the display control device 81, the lottery result command process (S739) and the payout determination result command, which are one of the command determination processes (S722). Partial processing included in the resident image transfer setting process (S817) and the normal image transfer setting process (S818), which are one of the processes (S741), the display setting process (S723), and the transfer setting process (S725). However, it is different from the slot machine 10 in the first embodiment. Other configurations, various processes executed by the MPU 102 of the main control device 101, and other processes executed by the MPU 181 of the display control device 81 are the same as those of the slot machine 10 in the first embodiment. Hereinafter, the same elements as those in the first embodiment are designated by the same reference numerals, and the illustration and description thereof will be omitted.

First, with reference to FIG. 38, the electrical configuration of the display control device 81 of the slot machine 10 in the third embodiment will be described. FIG. 38 is a block diagram showing an electrical configuration of the display control device 81 according to the third embodiment. As described above, as shown in FIG. 38, the display control device 81 in the present embodiment is provided with a work RAM 192 instead of the work RAM 185 in the display control device 81 in the first embodiment. Since other configurations are the same as those of the display control device 81 in the first embodiment, the description thereof will be omitted.

The work RAM 192 is configured by a DRAM like the work RAM 185 in the first embodiment. The work RAM 192 stores the command buffer area 192a, the bet number storage area 192b, the program storage area 192c, the data table storage area 192d, the simple image display flag 192e, the display data table buffer 192f, the pointer 192h, and the drawing list area 192i. At least the image discrimination flag 192j and the drawing target buffer flag 192k are provided. Of these, the command buffer area 192a, the bet number storage area 192b, the program storage area 192c, the simple image display flag 192e, the pointer 192h, the drawing list area 192i, the stored image discrimination flag 192j, and the drawing target buffer flag 192k are each the first. The same configuration and function as the command buffer area 185a, bet number storage area 185b, program storage area 185c, simple image display flag 185e, pointer 185h, drawing list area 185i, stored image discrimination flag 185j, and drawing target buffer flag 185k in the embodiment. Therefore, these explanations will be omitted here.

The data table storage area 192d describes the display content (drawing content) to be displayed on the auxiliary display unit 65 with the passage of time, and is resident in the resident video RAM 189 among the image data used for the display (drawing). It defines the transfer data information for transferring the non-image data from the character ROM 187 to the normal video RAM 190 and the transfer timing thereof, and is displayed on the auxiliary display unit 65 based on a command or the like from the main control device 101. This is an area in which a display data table prepared for each effect mode of the effect is stored.

This display data table is stored in the NAND flash memory 187a of the character ROM 187 together with the control program as a kind of fixed value data, and these data tables are transferred from the character ROM 187 to the work RAM 192 after the system reset is released, and this data is obtained. It is stored in the table storage area 192d. Then, when all the display data tables are stored in the data table storage area 192d, the MPU 181 subsequently controls the display of the auxiliary display unit 65 by using the data table stored in the data table storage area 192d. As described above, since the work RAM 192 is composed of the DRAM, the read operation is performed at high speed. Therefore, even when various data tables are stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the display control device 81 can maintain high processing performance, and the auxiliary display unit 65 is used. Therefore, it is possible to easily carry out diversified and complicated productions.

Here, the details of the display data table in the third embodiment will be described with reference to FIG. 39. FIG. 39 is a schematic diagram schematically showing an example of this display data table. In the display data table in the third embodiment, as shown in FIG. 39, the address represents the time (20 milliseconds in this embodiment) for displaying an image for one frame on the auxiliary display unit 65 as one unit. Correspondingly, the content of the image for one frame (drawing content) to be displayed at the time indicated by the address and the image data of the sprite to start the transfer at the time indicated by the address, that is, the image data to be transferred. It is also specified together with the transfer data information of.

Similar to the display data table of the first embodiment, the drawing content defines the type of sprite for each sprite (rear image, effect, character, etc.) constituting the image for one frame, and also defines the type of the sprite. Display objects such as display position coordinates, enlargement ratio, rotation angle, translucent value, α-blending information, color information, and filter specification information of the sprite are drawn on the third symbol display device 281 in association with the type of each sprite. The drawing information for this is specified.

On the other hand, as the transfer data information, as in the transfer data table of the first embodiment, the start address (storage source start address) and the final address (storage source final address) of the character ROM 187 in which the transfer target image data is stored. , And the start address of the transfer destination (normal video RAM 190). Further, as the transfer data information in which the image data corresponding to the predetermined sprite is the image data to be transferred, the image data corresponding to the predetermined sprite is usually used by the time the drawing of the predetermined sprite is started according to the drawing content. It is specified for a predetermined address so that it is stored in the image storage area 190a of the video RAM 190.

If there is no transfer target image data to start transfer at the time indicated by the address, it means that there is no transfer target image data to start transfer corresponding to the address as the transfer data information. The Null data to be used is specified (corresponding to the address "0002H" in FIG. 13). Further, when all the image data of the sprite used in the effect specified in the display data table is stored in the resident video RAM 189, Null data is specified as the transfer data information at all the addresses.

Similar to the display data table (see FIG. 12) in the first embodiment, "Start" information indicating the start of the data table is described in the "0000H" which is the start address of the display data table, and the final display data table is described. The address (“02F0H” in the example of FIG. 39) contains “End” information indicating the end of the data table. Then, for each address between the address "0000H" in which the "Start" information is described and the address in which the "End" information is described, the drawing content corresponding to the effect mode to be specified in the display data table is obtained. And the transfer data information of the image data to be transferred are described.

The MPU 181 corresponds to an effect mode to be displayed on the auxiliary display unit 65, which is one of the auxiliary effect units, when the effect mode to be executed by the auxiliary effect unit is determined based on a command or the like received from the main control device 101. The display data table to be displayed is extracted from the data table storage area 192d, stored in the display data table buffer 192f, and the pointer 192h is initialized.

Then, after adding 1 to 192h each time the drawing process for one frame is completed, the next drawing is performed from the display data table stored in the display data table buffer 192f based on the drawing content defined by the address indicated by the pointer 192h. A drawing list (see FIG. 14) is created by specifying the image content to be transferred and specifying the transfer data information of the transfer target image data to be transferred at that time. By transmitting this drawing list to the image controller 188, the MPU 181 gives an image controller 188 a drawing instruction for the image and an image data transfer instruction. Further, when the Null data is specified in the transfer data table area of the address indicated by the pointer 192h, it is determined that the transfer target image data to be transferred does not exist, and the transfer data information is not included in the drawing list. , The drawing list is transmitted to the image controller 188.

As a result, the drawing contents are specified in the order specified in the display data table according to the update of the pointer 192h, so that the image as specified in the display data table is displayed on the auxiliary display unit 65. Further, according to the update of the pointer 192h, the image data of the predetermined sprite designated as the transfer target image data is transferred from the character ROM 187 to the predetermined sub-area of the image storage area 190a provided in the normal video RAM 190 at a predetermined time. The process is executed.

As described above, in the slot machine 10, in the display control device 81, the program to be executed by the MPU 181 is changed according to the command from the main control device 101 (for example, the lottery result command or the payout determination result command). Instead, the effect image to be displayed on the auxiliary display unit 65 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 192f.

Here, when the program executed by the MPU 181 is started every time the effect image displayed on the display control device 81 is changed as in the conventional slot machine, it becomes complicated due to the diversification of the effect images. In addition, since a large load is applied to the processing of starting and executing the enormous program, the processing capacity of the display control device 81 is limited, and there is a possibility that the diversification of controllable production images is limited. .. On the other hand, in the slot machine 10, the display control device can change the effect image to be displayed on the auxiliary display unit 65 by a simple operation of appropriately replacing the display data table with the display data table buffer 192f. Regardless of the processing capacity of 81, various types of effect images can be displayed on the auxiliary display unit 65.

Further, in this way, a display data table is prepared corresponding to each effect mode, a display data table corresponding to the effect mode to be displayed is set in the display data table buffer 192f, and the set data table is followed. In the slot machine 10, the drawing list can be created frame by frame, and the effect to be displayed on the auxiliary display unit 65 is determined in advance based on the result of the lottery performed in response to the operation of the start lever 41. Because. On the other hand, in a game machine other than a game machine such as a slot machine 10, the display content changes on the spot based on the user's operation, so that the display content cannot be predicted. Therefore, as described above. It is not possible to have a display data table corresponding to each effect mode. In this way, a display data table is prepared corresponding to each effect mode, a display data table corresponding to the effect mode to be displayed is set in the display data table buffer 192f, and the set display data table is followed. The configuration in which the drawing list is created frame by frame is such that the slot machine 10 determines in advance the production mode of the effect to be displayed on the auxiliary display unit 65 based on the result of the lottery performed in response to the operation of the start lever 41. It can only be realized based on.

Further, in the display data table, the transfer target is such that the image data corresponding to the predetermined sprite is stored in the image storage area 190a of the normal video RAM 190 by the time the drawing of the predetermined sprite is started according to the drawing contents. Since the transfer data information of the image data is specified for a predetermined address, the display data is transferred by transferring the image data from the character ROM 187 to the image storage area 190a according to the transfer data information specified in the display data table. When drawing a predetermined sprite according to the table, the image data that is not resident in the resident video RAM 189 necessary for drawing the sprite can be always stored in the image storage area 190a. Then, using the image data stored in the image storage area 190a, a predetermined sprite can be drawn based on the display data table.

As a result, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, the image necessary for display can be read in advance from the character ROM 187 and transferred to the normal video RAM 190 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the auxiliary display unit 65. Further, according to the description in the display data table, only the non-resident image data in the resident video RAM 189 can be easily and surely transferred from the character ROM 187 to the normal video RAM 190.

Further, in the slot machine 10, the display control device 81 draws the data on the display data table extracted from the data table area 192d in response to a command from the main control device 101 (for example, a lottery result command or a payout determination result command). Since not only the content but also the transfer data information and the transfer timing of the image data to be transferred are defined, the transfer timing can be easily and accurately grasped and controlled. Therefore, the image data of the sprite used for drawing the image performed according to the display data table can be reliably transferred from the character ROM 187 to the normal video RAM 190 at a desired timing.

Further, since the display data table defines the transfer data information so that the image data is transferred from the character ROM 187 to the normal video RAM 190 for each image data corresponding to the sprite, the transfer of the image data is performed for each sprite. It can be managed and controlled, and the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 187 to the normal video RAM 190 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

Further, for each address in the display data table, the drawing content to be displayed at the time indicated by that address is defined, and the transfer data information of the image data to be transferred to be transferred is defined. Before the sprite image data is used, the transfer start timing can be specified and instructed based on the transfer data table area so that the image data is surely stored in the normal video RAM 190. Therefore, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, a wide variety of effect images can be easily displayed on the auxiliary display unit 65.

Further, since the drawing content and the transfer data information can be specified from one display data table, the specification can be compared with the case where the drawing content and the transfer data information are specified from the display data table and the transfer data table, respectively. The processing load required for this can be reduced. Further, since a display data table in which drawing contents and transfer data information are defined is prepared in advance in the data table storage area 192d, a data table in which drawing contents are specified and a data table in which transfer data information is specified are prepared. Therefore, the processing load can be further reduced as compared with the case where each data table is combined and the drawing content and the transferred data information are specified from the combined data table.

Returning to FIG. 38, the description of the work RAM 192 will be continued. The display data table buffer 192f is a buffer for storing a display data table corresponding to an effect mode to be displayed on the auxiliary display unit 65 in response to a command or the like from the main control device 101. The MPU 181 determines the effect to be displayed on the auxiliary display unit 65 based on a command or the like from the main control device 101, selects a display data table corresponding to the effect mode of the effect from the data table storage area 192d, and selects the display data table from the data table storage area 192d. The selected display data table is stored in the display data table buffer 192f. Then, the MPU 181 adds the pointer 192h by one to the drawing content defined by the address indicated by the pointer 192h in the display data table stored in the display data table buffer 192f and the transfer data information of the image data to be transferred. Based on this, a drawing list (see FIG. 14) describing the content of the image drawing instruction to the image controller 188 and the transfer data information of the transfer target image data to be transferred at that time is created for each frame.

As a result, the auxiliary display unit 65 displays the effect corresponding to the display data table stored in the display data table buffer 185f, and among the image data used in the display (drawing) according to the transfer data information. , Image data that is not resident in the resident video RAM 189 is transferred from the character ROM 187 to the normal video RAM 190 before its use.

Next, with reference to FIGS. 40 to 43, various processes executed by the MPU 181 of the display control device 81 in the third embodiment will be described. First, FIG. 40 is a flowchart showing a lottery result command process (S739) executed by the MPU 181 of the display control device 81. As described above in the first embodiment, the lottery result command process is a process executed in the command determination process (S722), which is one process of the V interrupt process (see FIG. 23 (b)), and is a main process. When the lottery result command is received from the control device 101, the process corresponding to the lottery result command is executed.

In this lottery result command processing, the processing of S761 to S771 and the processing of S773 are the same as the processing of S761 to S771 and the processing of S773 of the lottery result command processing in the first embodiment. Therefore, although detailed description of these processes will be omitted, the information regarding the number of bets stored in the bet number storage area 191b by the processes of S761 to S771, the winning combination grasped by the lottery result command, and the status command Each auxiliary effect is based on the game state (either the normal game state, the BB game state, or the BB carry-over game state) of the slot machine 10 notified and stored in the work RAM 185, the value of the random number counter provided in the work RAM 185, and the like. The production mode of the effect to be executed by the department is determined.

Then, when the effect mode of the effect to be executed by each auxiliary effect unit is determined by the processes of S761 to S771, the lottery result command process in the third embodiment is the process of S762, S764, S766, S768, S770 or S771. The display data table corresponding to the effect mode determined by is extracted from the data table storage area 191d and set in the display data table buffer 192f (S901). After that, the pointer h is initialized to 0 (S773) as in the first embodiment, and the lottery result command processing is terminated.

In this way, in the lottery result command, when the effect mode of the effect displayed on the auxiliary display unit 65 is determined according to the winning combination or the like grasped by the lottery result command, the effect mode is corresponding to the determined effect mode. The displayed display data table is set in the display data table buffer 192f, and the pointer 192h is initialized.

As a result, the MPU 181 updates the pointer 192h in the display setting process (see FIG. 49), and from the display data table set in the display data table buffer 192f, draws the drawing content defined by the address indicated by the pointer 192h. It is possible to extract and specify the content of the image for one frame to be displayed next on the auxiliary display unit 65. Further, the MPU 181 is defined by the address indicated by the pointer 192h from the set display data table in the normal image transfer setting process (see FIG. 43), which is one of the transfer setting processes (see FIG. 50 (a)). The image controller 188 is controlled so that the image data of the sprite required in the set display data table is transferred from the character ROM 187 to the image storage area 190a of the normal video RAM 190 in advance by extracting the transfer data information. Can be done. As a result, the images drawn by the display data table set in the display data table buffer 192f are sequentially displayed on the auxiliary display unit 65, and the effect of the effect mode corresponding to the display data table is displayed on the auxiliary display unit 65. Can be made to.

Next, the payout determination result command processing (S741) executed by the MPU 181 of the display control device 81 will be described with reference to FIG. 41. FIG. 41 is a flowchart showing the payout determination result command processing. As described above in the first embodiment, the payout determination result command process is a process executed in the command determination process (S722), which is one process of the V interrupt process (see FIG. 23 (b)). When the payout result command is received from the main control device 101, the process corresponding to the payout determination result command is executed.

In this payout determination result command processing, the processing of S781 to S782 and the processing of S784 are the same as the processing of S781 to S782 and the processing of S784 of the lottery result command processing in the first embodiment. Therefore, although detailed description of these processes will be omitted, the process of S781 to S782 extracts the payout determination result from the payout determination result command, and the extracted payout determination result and the bet number storage area 191b. Based on the information about the number of bets stored in, the game state of the slot machine 10 notified by the state command and stored in the work RAM 185, the value of the random number counter provided in the work RAM 185, and the like, each auxiliary effect The production mode of the effect to be executed by the department is determined.

Then, when the effect mode of the effect to be executed by each auxiliary effect unit is determined by the processing of S782, in the lottery result command processing in the third embodiment, the display data table corresponding to the determined effect mode is displayed as a data table. It is extracted from the storage area 192d and set in the display data table buffer 192f (S922). After that, the pointer h is initialized to 0 (S784) as in the first embodiment, and the payout determination result command processing is terminated.

As described above, in the payout determination result command processing, as in the lottery result command processing, the effect mode of the effect displayed on the auxiliary display unit 65 is set according to the result of the payout determination grasped by the payout determination result command. Once determined, the display data table corresponding to the determined effect mode is set in the display data table buffer 192f, and the pointer 192h is initialized.

As a result, the MPU 181 updates the pointer 192h in the display setting process (see FIG. 49), and from the display data table set in the display data table buffer 192f, draws the drawing content defined by the address indicated by the pointer 192h. It is possible to extract and specify the content of the image for one frame to be displayed next on the auxiliary display unit 65. Further, the MPU 181 is defined by the address indicated by the pointer 192h from the set display data table in the normal image transfer setting process (see FIG. 51), which is one of the transfer setting processes (see FIG. 50 (a)). The image controller 188 is controlled so that the image data of the sprite required in the set display data table is transferred from the character ROM 187 to the image storage area 190a of the normal video RAM 190 in advance by extracting the transfer data information. Can be done. As a result, the images drawn by the display data table set in the display data table buffer 192f are sequentially displayed on the auxiliary display unit 65, and the effect of the effect mode corresponding to the display data table is displayed on the auxiliary display unit 65. Can be made to.

Next, the display setting process (S723) executed by the MPU 181 of the display control device 81 will be described with reference to FIG. 63. FIG. 63 is a flowchart showing this display setting process. As described above in the first embodiment, the display setting process is a process executed in the V interrupt process (see FIG. 23B), and is a display data table buffer 192f by a command determination process (S722) or the like. Based on the content of the display data table set in, the content of the image for one frame to be displayed next in the auxiliary display unit 65 is specifically specified. Further, in the display setting process, the pointer 192h is also updated.

In this display setting processing, the processing of S801 to S805, the processing of S806 to S808 and S810 to S812, and the processing of S813 are the processing of S801 to S805, the processing of S806 to S808 and S810 to the display setting processing in the first embodiment. The process of S812 and the same process as the process of S813 are performed. Therefore, although detailed description of these processes is omitted, when the process corresponding to the error command is executed in the command determination process executed earlier by the processes of S801 to S805, it is grasped by the error command. The warning image data corresponding to the error type is expanded, and then 1 is added to the pointer 191h by the processing of S806.

Then, in the display data table set in the display data table buffer 192f, whether or not the data at the address indicated by the updated pointer 192h is End information is determined by the processing of S807, and as a result, the End information is used. If there is (S807: Yes), it means that the pointer 192h has been updated past the address where the actual data is described in the display data table set in the display data table buffer 192f. Therefore, further processing of S808 is performed. It is determined whether or not the display data table stored in the display data table buffer 196f is an effect on the payout result.

As a result, in the case of the display data table corresponding to the effect for the payout result (S808: Yes), in the display setting process in the third embodiment, after the effect for the payout result is completed, the player sets the start lever 41. The display data table corresponding to the "game start waiting effect" displayed until the next game is started after being operated is extracted from the data table storage area 191d, and this is set in the display data table buffer 192f. (S923). Then, as in the first embodiment, the pointer 192h is set to 1 (S810), and the process proceeds to S813.

In this way, in the display setting process, when the effect for the payout result such as the "winning establishment effect" or the "off effect" started by the setting of the payout determination result command process is displayed on the auxiliary display unit 65 until the end, " The display data table corresponding to the "game start waiting effect" is set in the display data table buffer 192f, and the pointer 192h is set to 1.

As a result, after that, the pointer 192h is updated every time the display setting process is executed, and the display data table corresponding to the game start waiting effect set in the display data table buffer 192f is changed to the address indicated by the pointer 192h. The defined drawing contents can be extracted, and the contents of the image for one frame to be displayed next can be specified in the auxiliary display unit 65. Therefore, after the display of the effect for the payout result is completed, the auxiliary display unit 65 can display the effect waiting for the start of the game. Further, the MPU 181 is a display corresponding to the game start waiting effect set in the display data table buffer 192f in the normal image transfer setting process (see FIG. 37), which is one of the transfer setting processes (see FIG. 50 (a)). The transfer data information specified at the address indicated by the pointer 192h is extracted from the data table, and the sprite image data required in the set display data table is previously stored in the image storage area 190a of the normal video RAM 190 from the character ROM 187. The image controller 188 can be controlled to be transferred. As a result, the images drawn by the display data table set in the display data table buffer 192f are sequentially displayed on the auxiliary display unit 65, and the game start waiting effect corresponding to the display data table is displayed on the auxiliary display unit 65. Can be made to.

The resident image transfer setting process (S817, FIG. 29) executed in the transfer setting process (S725), which is one of the V interrupt processes (see FIG. 23 (b)) executed by the MPU 181 of the display control device 81 (see FIG. 23 (b)). Also in b)), among the resident image transfer setting processes in the first embodiment, the process of S825 is replaced with the same process as the process of S923 of the display setting process (see FIG. 63) in the third embodiment. Regarding the other processes of the resident image transfer setting process, that is, the processes of S821 to S824 and S826 to S827, the same processes as those of the resident image transfer setting processes S821 to S824 and S826 to S827 in the first embodiment are performed. It will be done.

As a result, when all the image data to be resident in the resident video RAM 189 is transferred from the character ROM 187 to the resident video RAM 189, the V interrupt process executed by the next and subsequent V interrupts (see FIG. 23 (b)). In the display setting process of)), the drawing contents are expanded in order from the beginning of the display data table corresponding to the "game start waiting effect" set by the same process as S923. Therefore, after all the image data that should be resident in the resident video RAM 189 is transferred from the character ROM 187 to the resident video RAM 189, the auxiliary display unit 65 displays the game start waiting effect instead of the main image when the power is turned on. be able to.

As described above, in the resident image transfer setting process, when all the image data to be resident in the resident video RAM 189 is transferred from the character ROM 187 to the resident video RAM 189, the display data table corresponding to the "game start waiting effect" is displayed. The display data table buffer 192f is set, and the pointer 192h is set to 0.

As a result, while updating the pointer 192h each time the display setting process (S723) is executed, the display data table corresponding to the game start waiting effect set in the display data table buffer 192f is changed to the address indicated by the pointer 192h. The defined drawing contents can be extracted, and the contents of the image for one frame to be displayed next can be specified in the auxiliary display unit 65. Therefore, after all the image data to be resident in the resident video RAM 189 is transferred from the character ROM 187 to the resident video RAM 189, the auxiliary display unit 65 can display the game start waiting effect. Further, the MPU 181 is a display corresponding to the game start waiting effect set in the display data table buffer 192f in the normal image transfer setting process (see FIG. 37), which is one of the transfer setting processes (see FIG. 50 (a)). The transfer data information specified at the address indicated by the pointer 192h is extracted from the data table, and the sprite image data required in the set display data table is previously stored in the image storage area 190a of the normal video RAM 190 from the character ROM 187. The image controller 188 can be controlled to be transferred. As a result, the images drawn by the display data table set in the display data table buffer 192f are sequentially displayed on the auxiliary display unit 65, and the game start waiting effect corresponding to the display data table is displayed on the auxiliary display unit 65. Can be made to.

Next, the normal image transfer setting process (S818) executed by the MPU 181 of the display control device 81 will be described with reference to FIG. 43. FIG. 43 is a flowchart showing this normal image transfer setting process. As described above in the first embodiment, the normal image transfer setting process is a process executed in the transfer setting process (S725), which is one of the V interrupt processes (see FIG. 23 (b)). While the simple image display flag 185e is off, predetermined image data is normally used from the character ROM 187 to the image controller 188 based on the transfer data information described in the display data table set in the display data table buffer 192f. A transfer instruction for transferring to a predetermined sub-area of the image storage area 190a of the video RAM 190 is set.

In this normal image transfer setting process, first, from the display data table set in the display data table buffer 192f, the address indicated by the pointer 192h updated by the display setting process (S723, see FIG. 63) executed earlier. Acquires the transfer data information described in (S924). Then, it is determined whether or not the acquired transfer data information is Null data (S925), and if it is not Null data (S925: No), the character ROM 187 in which the transfer target image data is stored is stored from the transfer data information. The start address (storage source final address), the final address (storage source final address), and the start address of the transfer destination (normal video RAM 190) are extracted and stored in the transfer data buffer provided in the work RAM 185 (. S833), further, the transfer start flag provided in the work RAM 185 and indicating that there is image data to be transferred in the ON state is set to ON (S834), and the process proceeds to S835.

Further, in the process of S925, if the acquired transfer data information is Null data (S925: Yes), the processes of S833 and S834 are skipped, and the process proceeds to the process of S835. Then, in the processing of S835 to S841, the same processing as the processing of S835 to S841 of the normal image transfer setting processing in the first embodiment is performed. Therefore, detailed description of these processes will be omitted.

As described above, in the display control device 81, the display data table is extracted from the data table storage area 192d and displayed in response to a command from the main control device 101 (for example, a lottery result command or a payout determination result command). It is set in the data table buffer 192f. Then, the MPU 181 transfers to the image controller 188 according to the transfer data information described at the address indicated by the pointer 192h of the display data table set in the display data table buffer 192f by executing the normal image transfer setting process. Since the transfer instruction of the target image is set, the image data of the sprite required in the display data table can be reliably transferred from the character ROM 187 to the normal video RAM 190 at a desired timing.

Here, in the display data table, the image data to be transferred is stored in the image storage area 190a so that the image data corresponding to the predetermined sprite is stored in the image storage area 190a by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information is specified for a predetermined address, by transferring the image data from the character ROM 187 to the image storage area 190a according to the transfer data information specified in the display data table, the transfer data information is specified according to the display data table. When drawing the sprite, the image data that is not resident in the resident video RAM 189 necessary for drawing the sprite can be stored in the image storage area 190a without fail. Then, using the image data stored in the image storage area 190a, a predetermined sprite can be drawn based on the display data table.

As a result, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, the image necessary for display can be read in advance from the character ROM 187 and transferred to the normal video RAM 190 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the auxiliary display unit 65. Further, according to the description in the display data table, only the non-resident image data in the resident video RAM 189 can be easily and surely transferred from the character ROM 187 to the normal video RAM 190.

Further, in the slot machine 10, the display control device 81 draws the data on the display data table extracted from the data table area 192d in response to a command from the main control device 101 (for example, a lottery result command or a payout determination result command). Since not only the content but also the transfer data information and the transfer timing of the image data to be transferred are defined, the transfer timing can be easily and accurately grasped and controlled. Therefore, the image data of the sprite used for drawing the image performed according to the display data table can be reliably transferred from the character ROM 187 to the normal video RAM 190 at a desired timing.

Further, since the display data table defines the transfer data information so that the image data is transferred from the character ROM 187 to the normal video RAM 190 for each image data corresponding to the sprite, the transfer of the image data is performed for each sprite. It can be managed and controlled, and the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 187 to the normal video RAM 190 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

Further, for each address in the display data table, the drawing content to be displayed at the time indicated by that address is defined, and the transfer data information of the image data to be transferred to be transferred is defined. Before the sprite image data is used, the transfer start timing can be specified and instructed based on the transfer data table area so that the image data is surely stored in the normal video RAM 190. Therefore, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, a wide variety of effect images can be easily displayed on the auxiliary display unit 65.

Further, since the drawing content and the transfer data information can be specified from one display data table, the specification can be compared with the case where the drawing content and the transfer data information are specified from the display data table and the transfer data table, respectively. The processing load required for this can be reduced. Further, since a display data table in which drawing contents and transfer data information are defined is prepared in advance in the data table storage area 192d, a data table in which drawing contents are specified and a data table in which transfer data information is specified are prepared. Therefore, the processing load can be further reduced as compared with the case where each data table is combined and the drawing content and the transferred data information are specified from the combined data table.

As described above, according to the slot machine 10 of the third embodiment, in the display data table prepared for each effect mode of the effect displayed on the auxiliary display unit 65, the auxiliary display unit 65 with the passage of time. To transfer not only the display content (drawing content) to be displayed in the character ROM 187 but also the image data used for the display (drawing) that is not resident in the resident video RAM 189 from the character ROM 187 to the normal video RAM 190. The transfer data information and the transfer timing thereof are specified.

The display control device 81 selects a display data table to be used in response to a command from the main control device 101 (for example, a lottery result command or a payout determination result command), stores it in the display data table buffer 192f, and stores it in the display data table buffer 192f. , Initializes the pointer 192h. Then, the pointer 192h is incremented by 1 each time the drawing process for one frame is completed, and the next drawing is performed based on the drawing content defined by the address indicated by the pointer 192h in the display data table stored in the display data table buffer 192f. In addition to specifying the image content to be transferred, the transfer data information of the image data to be transferred to be transferred at that time is specified. Based on the specified drawing content and the transfer data information of the image data to be transferred, the drawing list shown in FIG. 14 is created by the drawing process (S726, see FIG. 31), and the drawing list is transmitted to the image controller 188. Then, in the image controller 188, the drawing of the image according to the drawing list and the transfer of the image data to be transferred from the character ROM 187 to the normal video RAM 190 are performed. Then, by specifying the drawing contents in the order specified in the display data table according to the update of the pointer 192h, the image as specified in the display data table is displayed on the auxiliary display unit 65.

As described above, in the slot machine 10, in the display control device 81, the program to be executed by the MPU 181 is changed according to the command from the main control device 101 (for example, the lottery result command or the payout determination result command). Instead, the effect image to be displayed on the auxiliary display unit 65 can be changed only by a simple operation of appropriately replacing the display data table of the display data table buffer 192f.

Here, when the program executed by the MPU 181 is started every time the effect image to be displayed on the display control device 81 is changed as in the conventional slot machine, it is complicated due to the diversification of the effect images. In addition, since a large load is applied to the processing of starting and executing the enormous program, the processing capacity of the display control device 81 is limited, and there is a possibility that the diversification of controllable production images is limited. .. On the other hand, in the slot machine 10, the effect image to be displayed on the auxiliary display unit 65 can be changed by a simple operation of appropriately replacing the display data table of the display data table buffer 192f, so that the display control device can be used. Regardless of the processing capacity of 81, various types of effect images can be displayed on the auxiliary display unit 65.

Further, it is a slot machine that can prepare a display data table corresponding to each effect mode and create a drawing list frame by frame according to the display data table according to the effect mode to be displayed. This is because in 10, the effect to be displayed on the auxiliary display unit 65 is determined in advance based on the result of the lottery performed in response to the operation of the start lever 41. On the other hand, in a game machine other than a game machine such as a slot machine 10, the display content changes on the spot based on the user's operation, so that the display content cannot be predicted. Therefore, as described above. It is not possible to have a display data table corresponding to each effect mode. In this way, a display data table is prepared corresponding to each effect mode, a display data table corresponding to the effect mode to be displayed is set in the display data table buffer 192f, and the set display data table is followed. The configuration in which the drawing list is created frame by frame is such that the slot machine 10 determines in advance the production mode of the effect to be displayed on the auxiliary display unit 65 based on the result of the lottery performed in response to the operation of the start lever 41. It can only be realized based on.

Further, for each address in the display data table, the drawing content to be displayed at the time indicated by that address is defined, and the transfer data information of the image data to be transferred to be transferred is defined. Before the sprite image data is used, the transfer start timing can be specified and instructed based on the transfer data table area so that the image data is surely stored in the normal video RAM 190. Therefore, even if the character ROM 187 is configured by the NAND flash memory 187a having a slow read speed, a wide variety of effect images can be easily displayed on the auxiliary display unit 65.

Further, since the drawing content and the transfer data information can be specified from one display data table, the specification can be compared with the case where the drawing content and the transfer data information are specified from the display data table and the transfer data table, respectively. The processing load required for this can be reduced. Further, since a display data table in which drawing contents and transfer data information are defined is prepared in advance in the data table storage area 192d, a data table in which drawing contents are specified and a data table in which transfer data information is specified are prepared. Therefore, the processing load can be further reduced as compared with the case where each data table is combined and the drawing content and the transferred data information are specified from the combined data table.

In addition, the slot machine 10 in the third embodiment can exert the same operation and effect as the slot machine 10 in the first embodiment based on the same components as the slot machine 10 in the first embodiment.

Next, the slot machine 10 in the fourth embodiment will be described with reference to FIG. 44. In the slot machine 10 according to the first embodiment described above, the NOR type ROM 187d is provided in the character ROM 187 composed of the NAND flash memory 187a, and most of the control program and the fixed value data are stored in the NAND flash memory 187a. In addition, the NOR type ROM 187d stores a part of the boot program that is executed first in the MPU 181 after the system reset is released, and the system reset is released and the MPU 181 sends the address "0000H" to the internal bus. When specified, the case where the ROM controller 187b of the character ROM 187 sets a part of the boot program stored in the NOR type ROM 187d in the buffer RAM 187c and then outputs the instruction code of the specified address to the MPU 181 has been described.

On the other hand, in the slot machine 10 of the fourth embodiment, the character ROM 195 is provided in the display control device 81 instead of the character ROM 187 of the first embodiment described above. Then, all the control programs including the boot program and all the fixed value data are stored in the NAND flash memory 195a provided in the character ROM 195, and when the power is turned on from the power supply device 91, the character ROM 195 is provided. The ROM controller 195b has set a part of the boot program stored in the NAND flash memory 195a in advance in the buffer RAM 195c, the system reset is released, and the address "0000H" is specified from the MPU 181 via the internal bus. Then, the instruction code of the specified address is read from the buffer RAM 195c and output to the MPU 181 via the internal bus.

Other configurations of the display control device 81, other configurations of the slot machine 10, various processes executed by the MPU 102 of the main control device 101 (see FIGS. 15 to 20), and execution by the MPU 181 of the display control device 81. The various processes (see FIGS. 21 to 31) are the same as those of the slot machine 10 in the first embodiment. Hereinafter, the same elements as those in the first embodiment are designated by the same reference numerals, and the illustration and description thereof will be omitted.

As shown in FIG. 44, the character ROM 195 has a NAND flash memory 195a, a ROM controller 195b, and a buffer RAM 195c, and like the character ROM 187 of the first embodiment, the MPU 181, the input / output port 186, and the image controller 188. Is connected to the internal bus to which. Of these, the buffer RAM 195c has the same configuration and function as the buffer RAM 187c of the character ROM 187 in the first embodiment, and therefore the description thereof will be omitted.

The NAND flash memory 195a is a non-volatile memory provided as a storage unit in the character ROM 195. Similar to the NAND flash memory 187a in the first embodiment, the NAND flash memory 195a has at least a character storage area 195a2 for storing image (character or the like) data to be displayed on the auxiliary display unit 65. .. Then, as in the first embodiment, the image controller 188 accesses the character ROM 195 according to the transfer instruction from the MPU 181 or the transfer data information included in the drawing list, and the image data stored in the character storage area 195a2 of the character ROM 195. Of these, when the predetermined image data is transferred to the resident video RAM 189 during the initialization process and is resident, or when the image data that is not resident in the resident video RAM 189 is used, it is usually performed in advance before the image data is used. Transfer to the video RAM 190 for storage.

Here, the NAND flash memory has a feature that a large storage capacity can be obtained in a small area, and an auxiliary display is performed by using, for example, a NAND flash memory 195a having a capacity of 2 gigabytes as a storage unit of the character ROM 195. As the image to be displayed on the unit 65, many images can be stored in the character storage area 195a2. Therefore, in order to further enhance the interest of the player, the image displayed on the auxiliary display unit 65 can be diversified and complicated. On the other hand, since the image data used for the drawing process is resident in the resident video RAM 189 and stored in the normal video RAM 190 in advance, the character ROM 195 composed of the NAND flash memory 195a having a slow read speed at the time of image drawing. It is not necessary to read the corresponding image data from, and the time required for the reading can be omitted. Therefore, the image can be drawn immediately and the drawn image can be displayed on the auxiliary display unit 65.

Further, the character ROM 195 is provided with a program storage area 195a1 in the NAND flash memory 195a instead of the second program storage area 187a1 provided in the NAND flash memory 187a of the first embodiment. The program storage area 195a1 stores all the control programs executed by the MPU181 and the fixed value data for driving the upper lamp 63 and the like. That is, in the first embodiment, among the control programs, a part of the boot program that is first executed after the system reset is released in the MPU181 is stored in the NOR type ROM 187d, and the other control programs and the fixed value data are stored in the NAND type flash memory. Although it is stored in 187a, in the fourth embodiment, all control programs and fixed value data are stored in the NAND flash memory 195a. Since the content of the control program and the content of the fixed value data are the same as those in the first embodiment, the description thereof will be omitted.

Here, since the NAND flash memory 195a can easily increase the capacity in a small area as described above, all the controls are further controlled while a large amount of image data is stored in the character storage area 195a2. The program and fixed value data can be stored in the program storage area 195a1. As a result, the control program and the fixed value data are displayed on the auxiliary display unit 64 without being stored by providing a dedicated program ROM (for example, ROM 22 of Patent Document 1 described above) as in a conventional gaming machine. Since the data can be stored in the character ROM 187 provided for storing the data, the number of parts in the display control device 81 can be reduced, the manufacturing cost can be reduced, and the number of parts can be reduced, as in the first embodiment. It is possible to suppress an increase in the failure rate due to an increase.

Further, since the character ROM 195 in the fourth embodiment does not require the NOR type ROM 187a1 as compared with the character ROM 187 in the first embodiment, the cost of the character ROM 195 itself can be reduced by omitting the NOR type ROM 187a1. In addition, the reliability of the character ROM 195 itself can be improved by reducing the number of parts.

The ROM controller 195b is a controller for controlling the operation of the character ROM 195, like the ROM controller 187b of the character ROM 187 in the first embodiment, and is, for example, an address transmitted from the MPU 181 or the image controller 188 via the internal bus. The corresponding data is read from the NAND flash memory 195a and output to the MPU 181 and the image controller 188 via the internal bus. At this time, the ROM controller 195b is known to perform known error correction on the data read from the NAND flash memory 195a, and to read and write data to and from the NAND flash memory 195a while avoiding defective data blocks. Data address conversion (see, for example, Patent Document 1) is performed.

As a result, even if the NAND flash memory 195a, in which error bits are likely to occur frequently, is used as the character ROM 195, the MPU 181 performs processing based on erroneous data, and the image controller 188 generates various images. Can be suppressed. Further, since the defective data block of the NAND flash memory 195a is analyzed by the ROM controller 195b and access to the defective data block is avoided, the MPU 181 and the image controller 188 have different defective data in each NAND flash memory 195a. Access to the character ROM 195 can be easily performed without considering the address position of the block. Therefore, even if the NAND flash memory 195a is used for the character ROM 195, it is possible to suppress the complicated access control to the character ROM 195.

Here, when the ROM controller 187b of the character ROM 187 in the first embodiment detects that the MPU 181 has specified the address "0000H" for the internal bus after the system reset is released, it is a part of the boot program stored in the NOR type ROM 187d. Was set in the buffer RAM 187c, and the instruction code of the specified address was output to the MPU 181. On the other hand, when the ROM controller 195b of the character ROM 195 in the fourth embodiment is supplied with power from the power supply device 91 to the display control device 81, the ROM controller 195b is immediately after the power is turned on in the MPU 181 from the program storage area 195a1 of the NAND flash memory 195a. A part of the boot program executed first is read, and a part of the read boot program is set in the buffer RAM 195c.

That is, the ROM controller 195b is configured so that the start address of the boot program stored in the program storage area 195a1 is automatically set by the hardware immediately after the power is turned on, and one page including the start address. The NAND flash memory 195a is driven so as to read the minute data (instruction code). Then, by writing the data (instruction code) read from the NAND flash memory 195a to one bank of the buffer RAM 195c, a part of the boot program first executed after the system reset is released in the MPU 181 is set in the buffer RAM 181c.

After a part of the boot program is set in the buffer RAM 181c, when the ROM controller 195b detects that the address "0000H" is specified for the internal bus by the MPU 181 due to the system reset release, the buffer RAM 195c has the corresponding address. It is configured to output the instruction code to the MPU181. The MPU 181 fetches the instruction code received from the character ROM 195 and starts the execution of the process according to the fetched instruction to activate the display main process shown in FIG. 21 and start the process. Then, as shown in FIG. 21, the display main process first executes the boot process (S701) shown in FIG. 22.

As described above, in the slot machine 10 according to the fourth embodiment, when the power is turned on from the power supply device 91, the ROM controller 195b in the character ROM 195 first releases the system reset from the NAND flash memory 195a to the MPU181. Since a part of the boot program to be executed is read and a part of the read boot program is set in the buffer RAM 195c, when the address "0000H" is specified for the internal bus by the MPU 181, the NAND flash memory 195a is used. A part of the boot program has been read, or a part of the boot program has already been set in the buffer RAM 195c.

Therefore, if a part of the boot program is already set in the buffer RAM 195c at the stage where the MPU 181 specifies the address "0000H" on the internal bus when the system reset is released, the character ROM 195 has the data (instruction code) of the specified address. ) Can be immediately read from the buffer RAM 195c. Further, even if a part of the boot program is not set in the buffer RAM 101c at the stage when the MPU181 specifies the address "0000H" for the internal bus, a part of the boot program is already read from the NAND flash memory 195a. Since the processing has started, the MPU 181 starts reading a part of the boot program from the NAND flash memory 195a in response to the designation of the address "0000H" in the internal bus. Time from when the address "0000H" is specified to MPU181 until the character ROM 195 sets a part of the boot program in the buffer RAM 195c and outputs the data (instruction code) of the specified address from the buffer RAM 195c to the MPU181. Can be shortened.

Therefore, since the MPU 181 can receive the instruction code corresponding to the address "0000H" in a short time after designating the address "0000H", the display main process can be started in the MPU 181 in a short time. As a result, even if the control program is stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the control of the auxiliary effect unit in the display control device 81 can be started immediately.

In addition, the slot machine 10 in the fourth embodiment can exert the same operation and effect as the slot machine 10 in the first embodiment based on the same components as the slot machine 10 in the first embodiment.

Next, the slot machine 10 according to the fifth embodiment will be described with reference to FIG. 45. In the slot machine 10 of the fifth embodiment, the character ROM 196 is provided in the display control device 81 instead of the character ROM 187 of the first embodiment described above. In this character ROM 196, a first program storage area 196d is provided in the ROM controller 196b, and a part of the boot program first executed after the system reset is released in the MPU 181 of the control programs is provided in the first program storage area 196d. It is remembered. Then, when the system reset is released and the MPU181 specifies the address "0000H" for the internal bus, the ROM controller 196b of the character ROM 196 sets a part of the boot program stored in the first program storage area 196d in the buffer RAM 196c. Above, the instruction code of the specified address is read from the buffer RAM 196c and output to the MPU 181 via the internal bus.

Other configurations of the display control device 81, other configurations of the slot machine 10, various processes executed by the MPU 102 of the main control device 101 (see FIGS. 15 to 20), and execution by the MPU 181 of the display control device 81. The various processes (see FIGS. 21 to 31) are the same as those of the slot machine 10 in the first embodiment. Hereinafter, the same elements as those in the first embodiment are designated by the same reference numerals, and the illustration and description thereof will be omitted.

As shown in FIG. 45, the character ROM 196 has a NAND flash memory 196a, a ROM controller 196b, and a buffer RAM 196c, and like the character ROM 187 of the first embodiment, the MPU 181, the input / output port 186, and the image controller 188. Is connected to the internal bus to which.

Of these, the NAND flash memory 196a, the second program storage area 196a1 and the character storage area 196a2 provided in the NAND flash memory 196a, and the buffer RAM 196c are the NAND flash memory 187a of the character ROM 187 in the first embodiment, respectively. It has the same configuration and function as the second program storage area 187a1, the character storage area 187a2, and the buffer RAM 187c provided in the NAND flash memory 187a. The data stored in the second program storage area 196a1 and the character storage area 196a2 are the same as those in the second program storage area 187a1 and the character storage area 187a2. Therefore, these explanations will be omitted below.

The ROM controller 196b is a controller for controlling the operation of the character ROM 196, like the ROM controller 187b of the character ROM 187 in the first embodiment. For example, the address transmitted from the MPU 181 or the image controller 188 via the internal bus. The corresponding data is read from the NAND flash memory 196a and output to the MPU 181 and the image controller 188 via the internal bus. At this time, the ROM controller 196b is known to perform known error correction on the data read from the NAND flash memory 196a, and to read and write data to and from the NAND flash memory 196a while avoiding defective data blocks. Data address conversion (see, for example, Patent Document 1) is performed.

As a result, even if the NAND flash memory 196a, in which error bits are likely to occur frequently, is used as the character ROM 196, the MPU 181 performs processing based on erroneous data, and the image controller 188 generates various images. Can be suppressed. Further, since the defective data block of the NAND flash memory 196a is analyzed by the ROM controller 196b and access to the defective data block is avoided, the MPU 181 and the image controller 188 have different defective data in each NAND flash memory 196a. Access to the character ROM 196 can be easily performed without considering the address position of the block. Therefore, even if the NAND flash memory 196a is used for the character ROM 196, it is possible to suppress the complicated access control to the character ROM 196.

On the other hand, the ROM controller 196b in the fifth embodiment is different from the ROM controller 187b of the character ROM 187 in the first embodiment in that it has the first program storage area 196d. The first program storage area 196d is composed of a small-capacity ROM built in the ROM controller 196b, and is a program stored in the first program storage area 187d1 of the NOR type ROM 187d in the character ROM 187 of the first embodiment. That is, a part of the boot program first executed after the system reset is released in the MPU 181 is stored in the first program storage area 196d in the fifth embodiment.

Then, when the ROM controller 196b detects that the MPU 181 has specified the address "0000H" in the internal bus after the system reset is released, a part of the boot program stored in the first program storage area 196d is partly stored in one of the buffer RAM 196c. It is set in the bank and the instruction code of the specified address is output to MPU181. The MPU 181 fetches the instruction code received from the character ROM 196 and starts the execution of the process according to the fetched instruction to activate the display main process shown in FIG. 21 and start the process. Then, as shown in FIG. 21, the display main process first executes the boot process (S701) shown in FIG. 22.

Here, since the built-in ROM can generally shorten the connection wiring, the parasitic capacitance applied to the wiring can be reduced. As a result, the wiring delay that occurs in the propagation of the signal can be reduced, so that the data read time can be shortened. In addition, the built-in ROM can be freely designed for its data bus width according to individual hardware specifications, so if the data bus width is set wide, it is possible to read a large amount of data at once. Is.

Therefore, if the first program storage area 196d is configured with such a built-in ROM, a part of the boot program first executed after the system reset is released in the MPU 181 is read out from the first program storage area 196d at high speed. It is set in the buffer RAM 196c, and the data (instruction code) corresponding to the address specified in the internal bus can be output to the MPU 181 from the set program. Therefore, since the MPU 181 can receive the instruction code corresponding to the address "0000H" in a short time after designating the address "0000H", the display main process can be started in the MPU 181 in a short time. As a result, even if the control program is stored in the character ROM 187 configured by the NAND flash memory 187a having a slow read speed, the control of the auxiliary effect unit in the display control device 81 can be started immediately.

In addition, the slot machine 10 in the fifth embodiment can exert the same operation and effect as the slot machine 10 in the first embodiment based on the same components as the slot machine 10 in the first embodiment.

Next, the slot machine 10 in the sixth embodiment will be described with reference to FIG. 46. In the slot machine 10 of the sixth embodiment, the character ROM 197 is provided in the display control device 81 in place of the character ROM 187 of the first embodiment described above, and the MPU181, the input / output port 186, and the image controller are provided in the display control device 81. The NOR type ROM 198 is connected to the internal bus to which the 188 and the character ROM 197 are connected. The NOR type ROM 198 is provided with at least a first program storage area 198a, and the first program storage area 198a stores a part of the boot program that is first executed after the system reset is released in the MPU 181 among the control programs. There is. Then, when the MPU181 specifies an address (for example, "0000H" to "0400H") corresponding to a part of the boot program to be executed first after the system reset is released to the internal bus, the NOR type ROM 198 corresponds to the address. The data (instruction code) is read from the first program storage area 198a and output to the MPU 181.

Other configurations of the display control device 81, other configurations of the slot machine 10, various processes executed by the MPU 102 of the main control device 101 (see FIGS. 15 to 20), and execution by the MPU 181 of the display control device 81. The various processes (see FIGS. 21 to 31) are the same as those of the slot machine 10 in the first embodiment. Hereinafter, the same elements as those in the first embodiment are designated by the same reference numerals, and the illustration and description thereof will be omitted.

As shown in FIG. 46, the character ROM 197 has a NAND flash memory 197a, a ROM controller 197b, and a buffer RAM 197c, and like the character ROM 187 of the first embodiment, the MPU 181, the input / output port 186, and the image controller 188. Is connected to the internal bus to which.

Of these, the NAND type flash memory 197a, the second program storage area 197a1 and the character storage area 197a2 provided in the NAND type flash memory 197a, and the buffer RAM 197c are the NAND type flash memory 187a of the character ROM 187 in the first embodiment, respectively. It has the same configuration and function as the second program storage area 187a1, the character storage area 187a2, and the buffer RAM 187c provided in the NAND flash memory 187a. The data stored in the second program storage area 197a1 and the character storage area 197a2 are the same as those in the second program storage area 187a1 and the character storage area 187a2. Therefore, these explanations will be omitted below.

The ROM controller 197b is a controller for controlling the operation of the character ROM 197, like the ROM controller 187b of the character ROM 187 in the first embodiment. For example, the address transmitted from the MPU 181 or the image controller 188 via the internal bus. The corresponding data is read from the NAND flash memory 197a and output to the MPU 181 and the image controller 188 via the internal bus. At this time, the ROM controller 197b is known to perform known error correction on the data read from the NAND flash memory 197a and to read and write the data to and from the NAND flash memory 197a while avoiding defective data blocks. Data address conversion (see, for example, Patent Document 1) is performed.

As a result, even if the NAND flash memory 197a, in which error bits are likely to occur frequently, is used as the character ROM 197, the MPU 181 performs processing based on erroneous data, and the image controller 188 generates various images. Can be suppressed. Further, since the defective data block of the NAND flash memory 197a is analyzed by the ROM controller 197b and access to the defective data block is avoided, the MPU 181 and the image controller 188 have different defective data in the individual NAND flash memory 197a. Access to the character ROM 197 can be easily performed without considering the address position of the block. Therefore, even if the NAND flash memory 197a is used for the character ROM 197, it is possible to suppress the complicated access control to the character ROM 197.

On the other hand, when the ROM controller 187b in the first embodiment detects that the address "0000H" is specified in the internal bus, the ROM controller 187b reads a part of the boot program first executed after the system reset is released in the MPU181 from the NOR type ROM 187d. However, in the ROM controller 197b in the sixth embodiment, even if it is detected that the address "0000H" is specified for the internal bus, such an operation is not executed. It is different from the ROM controller 187b in the first embodiment in that.

Further, when the address of the internal bus is specified as the address corresponding to a part of the control program stored in the NOR type ROM198 described later, that is, the boot program first executed after the system reset is released in the MPU181, the ROM. The controller 197b is different from the ROM controller 187b in the first embodiment in that the data output to the internal bus is set to the high impedance state and the data is not output.

As a result, if the MPU181 specifies to the internal bus an address corresponding to a part of the boot program that should be executed first after the system reset is released, the data output of the character ROM 197 will be in a high impedance state. The data (instruction code) corresponding to the address specified in the internal bus can be reliably output from the NOR type RAM 198 to the MPU 181. Further, in this case, since unnecessary operations are not executed in the character ROM 197, it is possible to suppress wasteful consumption of electric power in the character ROM 197.

As described above, the NOR type ROM 198 is a non-volatile memory having an extremely small capacity (for example, 2 kilobytes) connected to an internal bus to which the MPU 181, the input / output port 186, the image controller 188, and the character ROM 197 are connected. The NOR type ROM 198 has a first program storage area 198a, and the first program storage area 198a has the same control program as the first program storage area 187d1 of the NOR type ROM 187d in the first embodiment, that is, , A part of the boot program that is first executed after the system reset is released in MPU181 is stored.

In this NOR type ROM 198, the address specified for the internal bus by the MPU 181 is an address corresponding to a part of the boot program that the MPU 181 should execute first after the system reset is released (for example, "0000H" to "0400H"). When this is detected, the data (instruction code) corresponding to the address is read from the first program storage area 198a and output to the MPU 181.

At this time, since the data output of the character ROM 197 is set to the high impedance state as described above, the data output from the NOR type ROM 198 is surely output to the MPU 181. On the other hand, the address specified for the internal bus is different from the control program stored in the NOR type ROM198, that is, the address corresponding to a part of the boot program that the MPU 181 should execute first after the system reset is released. If the addresses are different, the NOR type ROM 198 sets the data output to the high impedance state. As a result, when such an address is set, the data read from the memory corresponding to the address (resident video RAM 189, normal video RAM 190, character ROM 197, etc.) is surely output to the internal bus. Can be done.

Here, as in the first embodiment, when the system reset is released, the MPU 181 sets the value of the instruction pointer 181a to "0000H" by the hardware and indicates the instruction pointer 181a to the internal bus. It is configured to specify the address "0000H". On the other hand, when the NOR type ROM 198 detects that the address "0000H" is specified for the internal bus, it reads out the boot program stored in the first program storage area 198a of the NOR type ROM 198 and corresponds to it, as described above. The data (instruction code) is output to MPU181.

Then, the MPU 181 fetches the instruction code received from the character ROM 187 and starts the execution of the process according to the fetched instruction, thereby activating the display main process shown in FIG. 21 and starting the process. Then, as shown in FIG. 21, the display main process first executes the boot process (S701) shown in FIG. 22.

Here, since the NOR type ROM is a memory capable of reading data at high speed, the NOR type ROM 198 stores a part of the boot program that the MPU 181 should execute first after the system reset is released, and also By connecting this NOR type ROM 198 to the internal bus, a part of the boot program can be read out from the NOR type ROM 198 at high speed and output to the MPU 181. Therefore, in the MPU181, the instruction code of the boot program read at high speed can be fetched immediately, so that the display main process can be started in a short time. Therefore, even if the control program is stored in the character ROM 197 configured by the NAND flash memory 197a having a slow read speed, the control of the auxiliary effect unit in the display control device 81 can be started immediately.

Further, in the display control device 81 in the sixth embodiment, since the NOR type ROM 198 is connected to the internal bus, the number of parts increases as compared with the first embodiment, but in this NOR type ROM 198, the MPU 181 resets the system. It is provided to store a part of the boot program that should be executed first after the release, and as the capacity thereof, as described above, an extremely small one can be used. Therefore, the increase in cost due to the provision of the NOR type ROM 198 can be suppressed to a small extent.

In addition, the slot machine 10 in the sixth embodiment can exert the same operation and effect as the slot machine 10 in the first embodiment based on the same components as the slot machine 10 in the first embodiment.

Next, with reference to FIGS. 47 to 87, as a seventh embodiment, an embodiment when the present invention is applied to a pachinko gaming machine (hereinafter, simply referred to as “pachinko machine”) 200 will be described. 47 is a front view of the pachinko machine 200 according to the seventh embodiment, FIG. 48 is a front view of the gaming board 213 of the pachinko machine 200, and FIG. 49 is a rear view of the pachinko machine 200.

As shown in FIG. 47, the pachinko machine 200 has an outer frame 211 in which an outer shell is formed by a wooden frame combined in a substantially rectangular shape, and an outer frame 211 formed in substantially the same outer shape as the outer frame 211. It is equipped with an inner frame 212 that can be opened and closed. Metal hinges 218 are attached to the outer frame 211 at two upper and lower positions on the left side of the front view (see FIG. 47) in order to support the inner frame 212, and the side on which the hinge 218 is provided is used as an opening / closing axis. The frame 212 is supported so as to be openable and closable toward the front side of the front surface.

A game board 213 (see FIG. 48) having a large number of nails, winning openings 263, 264, and the like is detachably attached to the inner frame 212 from the back surface side. A ball game is performed by a ball flowing down the front surface of the game board 213. The inner frame 212 includes a ball launching unit 312a (see FIG. 51) that launches a ball into the front region of the game board 213 and a launch that guides the ball launched from the ball launching unit 312a to the front region of the game board 213. Rails (not shown) etc. are attached.

On the front side of the inner frame 212, a front frame 214 that covers the upper side of the front surface and a lower plate unit 215 that covers the lower side thereof are provided. Metal hinges 19 are attached to the upper and lower two places on the left side of the front view (see FIG. 47) to support the front frame 214 and the lower plate unit 215, and the front frame with the side on which the hinge 19 is provided as the axis for opening and closing. The 214 and the lower plate unit 215 are supported so as to be openable and closable toward the front side of the front surface. The lock of the inner frame 212 and the lock of the front frame 214 are released by inserting a dedicated key into the keyhole 221 of the cylinder lock 220 and performing a predetermined operation.

The front frame 214 is assembled with decorative resin parts, electric parts, and the like, and a window portion 214c having a substantially elliptical opening is provided at a substantially central portion thereof. A glass unit 216 having two plate glasses is arranged on the back surface side of the front frame 214, and the front surface of the game board 213 can be visually recognized on the front side of the pachinko machine 200 via the glass unit 216.

In the front frame 214, an upper plate 217 for storing balls is formed in a substantially box shape with the upper surface open so as to project forward, and prize balls, rented balls, and the like are discharged to the upper plate 217. The bottom surface of the upper plate 217 is formed so as to be inclined downward to the right side when viewed from the front (see FIG. 47), and the ball thrown into the upper plate 217 is guided to the ball launching unit 312a by the inclination. Further, a frame button 222 is provided on the upper surface of the upper plate 217. The frame button 222 is operated by the player, for example, when changing the stage of the effect displayed by the third symbol display device 281 (FIG. 48) described later, or changing the effect content of the super reach. Will be done.

The stage is an effect mode in which various effects displayed on the third symbol display device 281 are unified. In this pachinko machine 200, there are three stages: "city stage", "empty stage", and "island stage". There are two stages. Then, various effects such as variable effect and reach effect performed in association with the entry (starting prize) into the first entrance 264, which will be described later, are designed to be performed according to the theme given to each stage. Has been done. The stage is changed when the frame button 222 is operated by the player during the period when the fluctuation effect is not performed or during the high-speed fluctuation, and each time the frame button 222 is operated, "city stage" → "empty stage" "→" Island stage "→" City stage "→ ... It is changed repeatedly in this order. Immediately after the power is turned on, the "city stage" is set as the initial stage.

On the other hand, the third symbol display device 281 is configured so that when the normal reach effect is started and the normal reach is developed into the super reach, the selection screen of the effect mode of the super reach is displayed during the normal reach. If the frame button 222 is operated by the player while the selection screen is displayed, the effect content at the time of super reach is changed.

The front frame 214 is provided with light emitting means such as various lamps around the front frame 214 (for example, a corner portion). These light emitting means change and control the light emitting mode by lighting or blinking according to a change in the gaming state at the time of a big hit or a predetermined reach, and play a role of enhancing the effect of the effect during the game. Illuminations 229 to 233 having a light emitting means such as an LED are provided on the peripheral edge of the window portion 214c. In the pachinko machine 200, these illumination units 229 to 233 function as effect lamps such as jackpot lamps, and each illumination unit 229 to 233 is lit by lighting or blinking the built-in LED at the time of jackpot or reach effect. Or it blinks to notify that the jackpot is in progress or that the reach is one step before the jackpot. Further, in the upper left portion of the front frame 214 when viewed from the front (see FIG. 47), a light emitting means such as an LED is built in, and a display lamp 234 capable of displaying the time when the prize ball is being paid out and the time when an error occurs is provided.

Further, on the lower side of the illuminated portion 232 on the right side, a small window 235 is formed by attaching a transparent resin from the back surface side so that the back surface side of the front frame 214 can be visually recognized, and a sticking space K1 on the front surface of the game board 213 (FIG. The certificate stamp or the like attached to (see 48) is visible from the front of the pachinko machine 200. Further, in the pachinko machine 200, a plating member 236 made of ABS resin, which is chrome-plated, is attached to a region around the illuminated portions 229 to 233 in order to bring out more glitter.

A ball rental operation unit 240 is arranged below the window unit 214c. The ball lending operation unit 240 is provided with a frequency display unit 241, a ball lending button 242, and a return button 243. When the ball lending operation unit 240 is operated with bills, cards, etc. inserted in the card unit (ball lending unit) (not shown) arranged on the side of the pachinko machine 200, the ball is operated according to the operation. Lending is done. Specifically, the frequency display unit 241 is an area where the remaining amount information such as a card is displayed, and the built-in LED is turned on and the remaining amount is displayed as a numerical value as the remaining amount information. The ball lending button 242 is operated to obtain a lending ball based on the information recorded on the card or the like (recording medium), and the lending ball is supplied to the upper plate 217 as long as the remaining amount is present on the card or the like. Will be done. The return button 243 is operated when requesting the return of the card or the like inserted in the card unit. A pachinko machine that directly lends balls to the upper plate 217 from a ball lending device or the like without going through a card unit, a so-called cash machine, does not require a ball lending operation unit 240. In this case, the ball lending operation unit 240 is not required. A decorative sticker or the like may be added to the installation portion of the above to make the component configuration common. It is possible to standardize pachinko machines and cash machines that use card units.

In the lower plate unit 215 located on the lower side of the upper plate 217, a lower plate 250 for storing balls that could not be stored in the upper plate 217 is formed in a substantially box shape with an open upper surface in the central portion thereof. There is. On the right side of the lower plate 250, an operation handle 251 operated by the player to drive the ball into the front surface of the game board 213 is arranged, and the inside of the operation handle 251 permits the driving of the ball launch unit 312a. Touch sensor 251a for this purpose, push button type stop switch 251b that stops the firing of the ball during the pressing operation, and a variable resistor that detects the amount of rotation operation of the operation handle 251 by the change in electrical resistance. (Not shown) and is built-in. When the operation handle 251 is rotated clockwise by the player, the touch sensor 251a is turned on and the resistance value of the variable resistor changes according to the operation amount, depending on the rotation operation amount of the operation handle 251. The ball is launched with a strength corresponding to the resistance value of the variable resistor, which changes, and the ball is driven into the front surface of the game board 213 with a jump amount corresponding to the operation of the player. Further, when the operation handle 251 is not operated by the player, the touch sensor 251a and the stop switch 251b are turned off.

A ball pulling lever 252 for operating the ball stored in the lower plate 250 when the ball stored in the lower plate 250 is discharged downward is provided in the lower front portion of the lower plate 250. The ball pulling lever 252 is always urged to the right, and by sliding it to the left against the urging, the bottom opening formed on the bottom of the lower plate 250 opens, and the bottom opening thereof is opened. The ball naturally falls from the bottom opening and is discharged. The operation of the ball removing lever 252 is usually performed in a state where a box (generally referred to as "Senryobako") for receiving the balls discharged from the lower plate 250 is placed below the lower plate 250. As described above, the operation handle 251 is arranged on the right side of the lower plate 250, and the ashtray 53 is attached to the left side of the lower plate 250.

As shown in FIG. 48, the game board 213 has a wooden base plate 260 machined into a substantially square shape in front view, a large number of nails and windmills for ball guidance, rails 261,262, a general winning opening 263, and a first. It is configured by assembling a ball entry port 264, a variable winning device 265, a variable display device unit 280, and the like, and a peripheral portion thereof is attached to the back surface side of the inner frame 212. The general winning opening 263, the first winning opening 264, the variable winning device 265, and the variable display device unit 280 are arranged in the through holes formed in the base plate 260 by router processing, and are wood screws from the front side of the game board 213. It is fixed by such as. Further, the front central portion of the game board 213 can be visually recognized from the front side of the inner frame 212 through the window portion 214c (see FIG. 47) of the front frame 214. Hereinafter, the configuration of the game board 213 will be described mainly with reference to FIG. 48.

An outer rail 262 formed by bending a strip-shaped metal plate into a substantially arc shape is planted on the front surface of the game board 213, and a strip-shaped metal plate is placed inside the outer rail 262 in the same manner as the outer rail 262. The arc-shaped inner rail 261 formed in 1 is planted. The inner rail 261 and the outer rail 262 surround the front outer periphery of the game board 213, and the game board 213 and the glass unit 216 (see FIG. 47) surround the front and back, so that the front surface of the game board 213 is a ball. A game area in which the game is played is formed by the behavior of. The game area is a substantially circular area (a winning opening or the like is arranged and a fired ball is arranged) formed on the front surface of the game board 213 and is divided by two rails 261,262 and an arc member 270. The area where it flows down).

The two rails 261,262 are provided to guide the ball launched from the ball launching unit 312a (see FIG. 51) to the upper part of the game board 213. A return ball prevention member 268 is attached to the tip of the inner rail 261 (upper left portion in FIG. 48) to prevent the ball once guided to the upper part of the game board 213 from returning to the ball guide passage. Will be done. A return rubber 269 is attached to the tip of the outer rail 262 (upper right part in FIG. 48) at a position corresponding to the maximum flight portion of the ball, and the ball launched with a predetermined momentum hits the return rubber 269 and has momentum. Is attenuated and bounced back toward the center. Further, between the lower right tip of the inner rail 261 and the upper right tip of the outer rail 262, a resin arc member 270 formed by providing an arc connecting the rails on the inner surface side is a base. It is fixed by driving it into the plate 260.

A first design provided with a plurality of light emitting diodes (hereinafter abbreviated as "LED") 237a and a 7-segment display 237b, which are light emitting means, on the upper right side of the front view (upper right side of FIG. 48) of the game area. A display device 237 is arranged. The first symbol display device 237 displays according to each control performed by the main control device 310, which will be described later, and mainly displays the gaming state of the pachinko machine 200. The plurality of LEDs 237a display the fluctuation by indicating whether or not the ball is in the fluctuation performed in association with the ball entering the first ball opening 264 (starting prize) by the lighting state, or the stop symbol after the fluctuation is completed. As a result, a symbol corresponding to the result of the lottery performed for the start winning is shown by the lighting state, or among the balls entered in the first entry opening 264, the ball (reserved ball) whose fluctuation has not been executed. The number of reserved balls, which is a number, is indicated by the lighting state. The 7-segment display 237b displays the number of rounds during the jackpot and an error. The LED 237a is configured so that the emission colors (for example, red, green, and blue) of each LED are different, and the combination of the emission colors can suggest various gaming states of the pachinko machine 200 with a small number of LEDs.

In the pachinko machine 200, in the lottery performed for the ball entering the first ball entry port 264, whether or not it is a big hit is determined, and if it is determined to be a big hit, the type of the big hit is also determined. .. As the jackpot type determined here, 15R probability variation jackpot, 2R probability variation jackpot, and time saving jackpot are prepared. The LED 237a not only indicates whether or not the result of the lottery is a big hit as a stop symbol after the end of the fluctuation, and if it is a big hit, a symbol corresponding to the jackpot type is shown.

Here, the "15R probability variation jackpot" is a probability variation jackpot in which the maximum number of rounds shifts to a high probability state after the jackpot of 15 rounds, and the "2R probability variation jackpot" is a jackpot with a maximum number of rounds of 2 rounds. It is a probabilistic jackpot that shifts to a high-probability state after. Further, the "time saving jackpot" is a jackpot in which the maximum number of rounds is 15 rounds, and then the jackpot shifts to a low probability state and becomes a time saving state during a predetermined number of fluctuations (for example, 100 fluctuations).

In addition, the "high probability state" refers to a state in which the probability of a big hit is increased as an added value after the end of the big hit, that is, during a so-called probability fluctuation (probability change), in other words, a game in which it is easy to shift to a special gaming state. It is the state of. The high-probability state (during probabilistic change) in the present embodiment includes a game state in which the hit probability of the second symbol, which will be described later, is increased and the ball can easily enter the first ball entry port 264. On the other hand, the "low probability state" means a state in which the probability change is not in progress, and a state in which the jackpot probability is normal, that is, a state in which the jackpot probability is lower than in the probability change state. In addition, the time-saving state (during the time-saving) in the "low probability state" is a state in which the jackpot probability is a normal state, and the jackpot probability remains the same, but only the hit probability of the second symbol increases and the first ball entrance It refers to the state of the game in which the ball easily enters the 264. In addition, instead of changing the hit probability of the second symbol, the time during which the electric accessory (not shown) attached to the first entrance 264 is opened or once, depending on the gaming state of the pachinko machine 200. The number of times the electric accessory is opened by hitting may be changed.

In the game area, a plurality of general winning openings 263 are arranged in which 5 to 15 balls are paid out as prize balls when the balls win a prize. Further, a variable display device unit 280 is arranged in the central portion of the game area. The variable display device unit 280 is a liquid crystal display that displays the fluctuation of the third symbol while synchronizing with the fluctuation display of the first symbol display device 237, triggered by the entry of a ball into the first entry port 264 (starting prize). The second symbol is composed of a third symbol display device 281 configured (hereinafter, simply abbreviated as "display device") and an LED that variablely displays the second symbol triggered by the passage of a ball in the second entry port 267. A symbol display device 283 is provided. Further, in the variable display device unit 280, a center frame 286 is arranged so as to surround the outer periphery of the third symbol display device 281.

The third symbol display device 281 is composed of a large liquid crystal display having an 8-inch size, and by controlling the display contents by the display control device 314 described later, for example, three symbol rows of left, middle, and right. Is displayed. Each symbol row is composed of a plurality of symbols, and these symbols are vertically scrolled for each symbol row so that the third symbol is variably displayed on the display screen of the third symbol display device 281. In the third symbol display device 281 of the present embodiment, the game state is displayed by the control of the main control device 310 by the first symbol display device 237, whereas the display of the first symbol display device 237 is displayed. It is a decorative display according to the situation. In addition, instead of the display device, for example, a reel or the like may be used to configure the third symbol display device 281.

Here, the display contents of the third symbol display device 281 will be described with reference to FIG. 50. FIG. 50 is a drawing for explaining a display screen of the third symbol display device 281, and FIG. 50 (a) is a diagram schematically showing an area division setting and an effective line setting of the display screen. FIG. 50B is a diagram illustrating an actual display screen.

The third symbol is composed of 10 types of main symbols with numbers from "0" to "9". Each main symbol is composed of a rear symbol consisting of a wooden box with numbers from "0" to "9", of which the main symbols with odd numbers (1, 3, 5, 7, 9) are , A large number is added to almost the front of the wooden box. On the other hand, the main design with even numbers (0, 2, 4, 6, 8) has an attached design that imitates a character such as a furoshiki, a helmet, etc., which is almost full on the front of the wooden box. An even number is added to the lower right side of the attached symbol so that it is small in green and displayed on the front side of the attached symbol.

Further, in the pachinko machine 200 of the present embodiment, when the lottery result by the main control device 310 (see FIG. 51) described later is a big hit, a variable display in which the same main symbols are aligned is performed, and the variable display is displayed. It is configured to generate a jackpot after it is over. When shifting to the high probability state (probability change state) after the jackpot ends, a variable display is performed in which the main symbols with odd numbers added (corresponding to the "high probability symbol") are aligned. On the other hand, when the state shifts to the low probability state after the end of the big hit, a variable display is performed in which the main symbols to which even numbers are added (corresponding to the "low probability symbol") are aligned.

As shown in FIG. 50 (a), the display screen of the third symbol display device 281 is roughly divided into upper and lower parts, and the lower two-thirds are the main display area Dm for variable display of the third symbol, and the rest. The upper 1/3 of the above is the sub-display area Ds for displaying the advance notice effect, the character, the number of reserved balls, and the like.

The main display area Dm is divided into three display areas Dm1 to Dm3 on the left, middle, and right, and three symbol columns Z1, Z2, and Z3 are displayed in the three display areas Dm1 to Dm3, respectively. In each of the symbol rows Z1 to Z3, the above-mentioned third symbols are displayed in a specified order. That is, the main symbols are arranged in the ascending or descending order of the numbers in each of the symbol rows Z1 to Z3, and the variable display is performed by scrolling from top to bottom with periodicity for each of the symbol rows Z1 to Z3. In particular, in the left symbol row Z1, the numbers of the main symbols are arranged so as to appear in descending order, and in the middle symbol row Z2 and the right symbol row Z3, the numbers of the main symbols are arranged so as to appear in ascending order.

Further, in the main display area Dm, the third symbol is displayed in the upper, middle, and lower three rows for each symbol row Z1 to Z3. The middle part of this main display area Dm is set as the effective line L1, and the third symbol stops on the effective line L1 in the order of the left symbol row Z1 → the right symbol row Z3 → the middle symbol row Z2 in each game. Is displayed. When the third symbol is stopped, if the combination of jackpot symbols (in the present embodiment, the same combination of main symbols) is arranged on the effective line L1, the jackpot moving image is displayed as a jackpot.

On the other hand, the sub-display area Ds is provided horizontally above the main display area Dm, and is further divided into three small areas Ds1 to Ds3 in the left-right direction. Of these, the small area Ds1 is an area for displaying the number of reserved balls, which is the number of balls (reserved balls) whose fluctuation has not been executed among the balls entered in the first entry port 264, and is the small area Ds2. And Ds3 are areas for displaying the preview effect image.

On the actual display screen, as shown in FIG. 50 (b), a total of nine main symbols of the third symbol are displayed in the main display area Dm. In the sub-display area Ds, the moving image is displayed in the small area Ds3 on the right, suggesting to the player that the transition to the jackpot is easier than usual. In the central small area Ds2, a predetermined character (a boy with a headband in this embodiment) usually performs a predetermined action, and sometimes a special action different from the predetermined action is performed, or another character appears. A notice will be given, such as by issuing it.

On the other hand, if the ball enters the first entry port 264 while the variation display is being performed on the third symbol display device 281 (first symbol display device 237), the number of entry times is up to four times. It is held, and the number of held balls is shown by the first symbol display device 237 and also in the small area Ds1 of the sub-display area Ds. In the small area Ds1, one reserved ball number symbol is displayed for each reserved ball number symbol, and the reserved ball number is displayed according to the display number of the reserved ball number symbol. That is, when one reserved ball number symbol is displayed in the small area Ds1, it indicates that the reserved ball number is one, and when four reserved ball number symbols are displayed, the reserved ball number is Indicates that it is 4 balls. Further, when the reserved ball number symbol is not displayed in the small area Ds1, it indicates that the reserved ball number is 0, that is, the reserved ball does not exist.

In the present embodiment, the ball entering the first ball entry port 264 is configured to be held up to 4 times, but the maximum number of held balls is not limited to 4 times, but 3 times. The number of times may be set to 5 or more (for example, 8 times). Further, instead of displaying the reserved ball number symbol in the small area Ds1, the reserved ball number is different by a number in a part of the third symbol display device 281 or the area divided into four is different by the number of reserved balls. (For example, a color or a lighting pattern) may be displayed. Further, since the number of reserved balls is indicated by the first symbol display device 237, the number of reserved balls may not be displayed on the third symbol display device 281. Further, the variable display device unit 280 may be provided with four hold lamps indicating the number of hold balls for the maximum number of hold balls, and the number of hold balls may be displayed according to the number of hold lamps in the lit state.

Returning to FIG. 48, the description will be continued. The second symbol display device 283 displays a variable display in which the “○” symbol and the “×” symbol as the display symbol (second symbol) are alternately lit each time the ball passes through the second entry port 267. It is something to do. In the pachinko machine 200, when the variation display on the second symbol display device 283 is stopped at a predetermined symbol (in the present embodiment, the symbol “○”), the first ball entry port 264 is activated (opened) for a predetermined time. Is configured to be). The number of times the ball has passed through the second entry port 267 is held up to four times, and the number of held balls is displayed by the above-mentioned first symbol display device 237 and is also lit and displayed by the second symbol holding lamp 284. Four second symbol holding lamps 284 are provided for the maximum number of holding lamps, and are arranged symmetrically below the third symbol display device 281.

The variation display of the second symbol is performed by switching the lighting and non-lighting of a plurality of lamps in the second symbol display device 283 as in the present embodiment, as well as the first symbol display device 237 and the third symbol. It may be performed by using a part of the display device 281. Similarly, the second symbol holding lamp 284 may be turned on by a part of the third symbol display device 281. Further, the maximum number of reserved balls is not limited to 4 times, and the number of times of passing through the 2nd entrance 267 is 3 times or less, or 5 times or more (for example). , 8 times). Further, since the number of reserved balls is indicated by the first symbol display device 237, the lighting display may not be performed by the second symbol hold lamp 284.

Below the variable display device unit 280, a first ball entry port 264 through which a ball can enter is arranged. When a ball enters the first entry port 264, the first entry opening switch (not shown) provided on the back surface side of the game board 213 is turned on, and the first entry opening switch is turned on. A big hit lottery is made by the main control device 310, and the display according to the lottery result is indicated by the LED 237a of the first symbol display device 237. Further, the first entry slot 264 is also one of the winning openings in which five balls are paid out as prize balls when a ball enters.

A variable winning device 265 is disposed below the first ball entry opening 264, and a horizontally long rectangular specific winning opening (large opening opening) 265a is provided in a substantially central portion thereof. In the pachinko machine 200, when the lottery in the main control device 310 becomes a big hit, after a predetermined time (variable time) has elapsed, the LED 237a of the first symbol display device 237 is turned on and the LED 237a of the first symbol display device 237 is turned on so as to be the stop symbol of the big hit. The stop symbol corresponding to the jackpot is displayed on the third symbol display device 281 to indicate the occurrence of the jackpot. After that, the game state shifts to the special game state (big hit) where the ball is easy to win. As this special gaming state, the specific winning opening 265a, which is normally closed, is opened for a predetermined time (for example, until 30 seconds have elapsed or until 10 balls are won).

The specific winning opening 265a is closed after a predetermined time has elapsed, and after the closing, the specific winning opening 265a is opened again for a predetermined time. The opening / closing operation of the specific winning opening 265a can be repeated up to, for example, 15 times (15 rounds). The state in which this opening / closing operation is performed is a form of a special gaming state that is advantageous to the player, and the player is given a larger amount of prize balls than usual as a game value (game value). Is done.

Specifically, the variable winning device 265 has a horizontally long rectangular opening / closing plate that covers the specific winning opening 265a, and a large opening solenoid (not shown) for driving the opening / closing to the front side with the lower side of the opening / closing plate as an axis. And have. The specific winning opening 265a is normally closed so that the ball cannot win or it is difficult to win. In the case of a big hit, the large opening solenoid is driven to tilt the opening / closing plate to the lower front side to temporarily form an open state in which the ball can easily win a prize in the specific winning opening 265a. It operates so as to alternate between the state and the state.

The special gaming state is not limited to the above-mentioned form. A large opening that opens and closes separately from the specific winning opening 265a is provided in the game area, and when the LED 237a corresponding to the big hit is turned on in the first symbol display device 237, the specific winning opening 265a is opened for a predetermined time and the specific winning opening is opened. A special gaming state is a game state in which a large opening provided separately from the specific winning opening 265a is opened a predetermined number of times for a predetermined time when the ball wins a prize in the specific winning opening 265a while the opening 265a is open. It may be formed.

Attachment spaces K1 and K2 for attaching certificate stamps and identification labels are provided in the left and right corners on the lower side of the game board 213, and the certificate stamps and the like attached to the attachment space K1 are the front frame 214. It can be visually recognized through the small window 235 (see FIG. 47).

Further, the game board 213 is provided with an out port 266. Balls that do not enter any of the winning openings 263, 264, 265a are guided to a ball discharge path (not shown) through the out opening 266. A large number of nails are planted on the game board 213 in order to appropriately disperse and adjust the falling direction of the ball, and various members (accessories) such as a windmill are arranged.

As shown in FIG. 49, the control board units 290 and 291 and the back pack unit 294 are mainly provided on the back side of the pachinko machine 200. The control board unit 290 is unitized by mounting a main board (main control device 310), a voice lamp control board (voice lamp control device 313), and a display control board (display control device 314). The control board unit 291 is unitized by mounting a payout control board (payout control device 311), a launch control board (launch control device 312), a power supply board (power supply device 315), and a card unit connection board 316.

In the back pack unit 294, the back pack 292 forming the protective cover portion and the payout unit 293 are unitized. In addition, each control board is used for MPU as a one-chip microcomputer that controls each control, a port for contacting various devices, a random number generator used for various lottery, and for time counting and synchronization. A clock pulse generation circuit, etc. is installed as needed.

The main control device 310, the voice lamp control device 313 and the display control device 314, the payout control device 311 and the emission control device 312, the power supply device 315, and the card unit connection board 316 are housed in the board boxes 300 to 304, respectively. .. The board boxes 300 to 304 include a box base and a box cover that covers an opening of the box base, and the box base and the box cover are connected to each other to house each control device and each board.

Further, in the board box 300 (main control device 310) and the board box 302 (payout control device 311 and launch control device 312), the box base and the box cover are connected (caulked structure) by a sealing unit (not shown) so as not to be opened. (Consolidated by). Further, a sealing sticker (not shown) is attached to the connecting portion between the box base and the box cover over the box base and the box cover. This seal is made of a brittle material, and if you try to peel off the seal to open the board boxes 300, 302, or if you try to forcibly open the board boxes 300, 302, the box base side and the box cover Cut to the side. Therefore, by checking the sealing unit or the sealing seal, it is possible to know whether or not the board boxes 300 and 302 have been opened.

The payout unit 293 includes a tank 330 located at the top of the back pack unit 294 and opened upward, a tank rail 331 connected below the tank 330 and gently inclined toward the downstream side, and a downstream of the tank rail 331. It is provided with a case rail 332 that is vertically connected to the side and a payout device 333 that is provided at the most downstream portion of the case rail 332 and that pays out balls by a predetermined electrical configuration of a payout motor 416 (see FIG. 51). ing. The tank 330 is sequentially replenished with balls supplied from the island equipment of the game hall, and the required number of balls are appropriately paid out by the payout device 333. A vibrator 334 for adding vibration to the tank rail 331 is attached to the tank rail 331.

Further, the payout control device 311 is provided with a state return switch 320, the launch control device 312 is provided with a variable resistor operation knob 321 and the power supply device 315 is provided with a RAM erasing switch 322. The state return switch 320 is operated to clear the ball jam (return to the normal state) when a payout error occurs, such as a ball jam in the payout motor 416 (see FIG. 51). The operation knob 321 is operated to adjust the firing force of the firing solenoid. The RAM erase switch 322 is operated when the power is turned on when it is desired to return the pachinko machine 200 to the initial state.

Next, with reference to FIG. 51, the electrical configuration of the pachinko machine 200 will be described. FIG. 51 is a block diagram showing an electrical configuration of the pachinko machine 200.

The main control device 310 is equipped with an MPU 401 as a one-chip microcomputer which is an arithmetic unit. The MPU 401 is a ROM 402 that stores various control programs and fixed value data executed by the MPU 401, and a memory for temporarily storing various data and the like when the control program stored in the ROM 402 is executed. A certain RAM 403 and various other circuits such as an interrupt circuit, a timer circuit, and a data transmission / reception circuit are built-in. In order to instruct the operation of the sub control device such as the payout control device 311 and the voice lamp control device 313, various commands are transmitted from the main control device 310 to the sub control device by the data transmission / reception circuit. Such a command is transmitted from the main controller 310 to the sub controller in only one direction.

The main control device 310 executes the main processing of the pachinko machine 200, such as a jackpot lottery, display setting in the first symbol display device 237 and the third symbol display device 281, and lottery of display results in the second symbol display device 283. The RAM 403 is provided with various counters for controlling these processes. Here, with reference to FIG. 52, a counter and the like provided in the RAM 403 of the main control device 310 will be described. These counters and the like are used for the jackpot lottery, the display setting of the first symbol display device 237 and the third symbol display device 281, the lottery of the display result of the second symbol display device 283, and the like, and the MPU 401 of the main control device 310. Used in.

The jackpot lottery and the display settings of the first symbol display device 237 and the third symbol display device 281 include the first hit random number counter C1 used for the jackpot lottery and the first hit type counter C2 used for selecting the jackpot symbol. , The stop pattern selection counter C3, the first initial value random number counter CINI1 used for setting the initial value of the first random number counter C1, and the variation type counter CS1 used for the variation pattern selection are used. Further, the second random number counter C4 is used for the lottery of the second symbol display device 283, and the second initial value random number counter CINI2 is used for setting the initial value of the second random number counter C4. Each of these counters is a loop counter in which 1 is added to the previous value each time it is updated, and after reaching the maximum value, it returns to 0.

Each counter is updated, for example, at intervals of 2 milliseconds, which is the execution interval of the timer interrupt process (see FIG. 61), and some counters are updated irregularly in the main process (see FIG. 67). Then, the updated value is appropriately stored in the counter buffer set in the predetermined area of the RAM 403. The RAM 403 is provided with a hold ball storage area consisting of one execution area and four hold areas (hold 1st to 4th areas), and each of these areas has a hold ball entrance 264. Each value of the first random number counter C1, the first hit type counter C2, and the stop pattern selection counter C3 is stored according to the ball entry timing.

Each counter will be described in detail. The first random number counter C1 is incremented by 1 in order within a predetermined range (for example, 0 to 899) and reaches the maximum value (for example, 899 in the case of a counter that can take a value of 0 to 899) and then 0. It is configured to return to. In particular, when the first random number counter C1 makes one round, the value of the first initial value random number counter CINI1 at that time is read as the initial value of the first random number counter C1.

Further, the first initial value random number counter CINI1 is configured as a loop counter updated in the same range as the first random number counter C1. That is, for example, when the first random number counter C1 is a loop counter that can take a value of 0 to 899, the first initial value random number counter CINI1 is also a loop counter in the range of 0 to 899. The first initial value random number counter CINI1 is updated once for each execution of the timer interrupt process (see FIG. 61), and is repeatedly updated within the remaining time of the main process (see FIG. 67).

The value of the first random number counter C1 is updated periodically (once for each timer interrupt process in this embodiment), and the reserved ball storage area of the RAM 403 is set at the timing when the ball wins the first entry port 264. Stored in. The value of the random number that becomes the jackpot is set by the jackpot random number table (not shown) stored in the ROM 402 of the main controller, and the value of the first hit random number counter C1 is set by the jackpot random number table. If it matches the value of a random number that is a big hit, it is judged as a big hit. In addition, this jackpot random number table is divided into two types, one for low probability (during the period during which the probability is not changing) and the other for high probability (during probability change) where the probability of becoming a jackpot is higher than that of the low probability. The number of random numbers included in the jackpot is set differently. In this way, by making the number of random numbers that become big hits different, the probability of becoming a big hit is changed between the low probability time and the high probability time.

The first hit type counter C2 determines the display mode of the first symbol display device 237 at the time of a big hit, and is added by 1 in order within a predetermined range (for example, 0 to 9), and the maximum value (for example, for example). , In the case of a counter that can take a value of 0 to 9, it is configured to return to 0 after reaching 9). The value of the first hit type counter C2 is updated periodically (once for each timer interrupt process in this embodiment), and the reserved ball is stored in the RAM 403 at the timing when the ball wins the first entry port 264. Stored in the area.

Here, if the value of the first random number counter C1 stored in the reserved ball storage area is not a random number that is a big hit, that is, if it is a random number that is out of order, the stop symbol displayed on the first symbol display device 237. The display mode corresponding to is the one at the time of disengagement.

On the other hand, if the value of the first hit random number counter C1 stored in the reserved ball storage area is a random number that is a big hit, the display mode corresponding to the stop symbol displayed on the first symbol display device 237 is the one at the time of big hit. It becomes. In this case, the specific display mode at the time of the big hit is the display mode indicated by the value of the first hit type counter C2 stored in the same reserved ball storage area.

The first random number counter C1 in the pachinko machine 200 of the present embodiment is configured as a 2-byte loop counter in the range of 0 to 899. In this first hit random number counter C1, the number of random numbers that become big hits at low probability is 3, and the value "7,307,582" is stored in the big hit random number table at low probability. On the other hand, the number of random numbers that are big hits at high probability is 30, and the values are "28,58,85,122,144,178,213,238,276,298,322,354,390,420,448". , 486,506,534,567,569,618,656,681,716,750,772,809,836,866,892 ”are stored in the high-probability jackpot random number table.

In this embodiment, the value of the big hit random number stored in the low-probability jackpot random number table and the value of the jackpot random number stored in the high-probability jackpot random number table are duplicated values. The value of each random number that is a big hit is set so that it does not become. Here, if there is a value that is always used as the value of the random number that becomes the jackpot regardless of the situation of the pachinko machine 200, the value may be input from the outside and the jackpot may be easily assigned illegally. On the other hand, as in the present embodiment, by changing the value of the random number that becomes the big hit according to the situation (that is, depending on whether the pachinko machine 200 is in the high probability state or the low probability state), it becomes a big hit. Since the value of the random number can be difficult to predict, it is possible to suppress fraud.

Further, the value of the first type counter C2 in the pachinko machine 200 of the present embodiment is configured as a loop counter in the range of 0 to 9. In this first hit type counter C2, when the value of the random number is "6,7,8,9", the jackpot type is "15R probability change" in which the maximum number of rounds shifts to the high probability state after the jackpot of 15 rounds. On the other hand, when the value of the first hit type counter C2 is "4,5", the jackpot type is "2R probability change" in which the maximum number of rounds shifts to a high probability state after a big hit of 2 rounds. When the value of the first hit type counter C2 is "0, 1, 2, 3", the jackpot type shifts to a low probability state after a jackpot with a maximum number of rounds of 15 rounds. At the same time, it is a "time saving jackpot" in which the time is shortened during 100 fluctuations.

As described above, the pachinko machine 200 of the present embodiment is configured so that three types of hit types (15R probability variation jackpot, 2R probability variation jackpot, time saving jackpot) are determined by the value of the random number indicated by the first hit type counter C2. Has been done.

The stop pattern selection counter C3 is configured to be incremented by 1 in order in the range of 0 to 99, and returns to 0 after reaching the maximum value (that is, 99). In the present embodiment, the stop pattern selection counter C3 selects the stop pattern at the time of disconnection displayed by the third symbol display device 281, and after the reach occurs, the final stop symbol shifts by one before and after the reach symbol. "Reach other than front and back" (for example, 98,99), and "reach other than front and back" (for example, range of 90 to 97) where the final stop symbol stops outside the front and back of the reach symbol after the same reach occurs. Three stop (effect) patterns with "complete deviation" (for example, in the range of 0 to 89) where reach does not occur are selected. The value of the stop pattern selection counter C3 is updated periodically (once for each timer interrupt process in this embodiment), and the reserved ball storage area of the RAM 403 is reached when the ball wins the first ball entry port 264. Stored.

Further, the ROM 402 is provided with a plurality of tables (not shown) having different ranges of random values for which the stop pattern is selected, corresponding to the stop pattern selection counter C3. This is because the selection ratio of the stop pattern is changed according to whether the current state of the pachinko machine 200 is a high probability state or a low probability state.

For example, in a high-probability state, a table with a wide range of random values from 0 to 89 corresponding to the "completely off" stop pattern is selected so that the reach effect is not selected more than necessary because a big hit is likely to occur. It becomes easier to select "completely off". In this table, the "reach outside the front and rear" is narrowed to 98,99 and the "reach other than the front and rear" is also narrowed to 90 to 97, making it difficult to select "reach outside the front and back" or "reach other than the front and rear". In the low probability state, a table with a narrow random value range of 0 to 79 corresponding to the "completely off" stop pattern is selected in order to secure the ball entry time to the first entry port 264. It becomes difficult to select "completely off". In this table, the range of random value corresponding to the stop pattern of "reach other than front and back deviation" is widened to 80 to 97, and "reach other than front and rear deviation" is easily selected. Therefore, in the low probability state, it is possible to perform many reach displays with a long effect time, so that the ball entry time to the first entry port 264 can be secured, and the variation display by the third symbol display device 281 continues. It will be easier to do. Also in the latter table, the range of random values corresponding to the stop pattern of "reach before and after" is set to 98,99.

The variation type counter CS1 is configured to be incremented by 1 in order within the range of, for example, 0 to 198, reach the maximum value (that is, 198), and then return to 0. The variation type counter CS1 determines a rough display mode such as so-called normal reach and super reach. Specifically, the determination of the display mode is the determination of the fluctuation time of the symbol variation. Based on the fluctuation time determined by the variation type counter CS1, the reach type and the fine symbol variation mode of the third symbol displayed on the third display device 281 are determined by the voice lamp control device 421 and the display control device 314. .. The value of the variation type counter CS1 is updated once every time the main process (see FIG. 67) described later is executed once, and is repeatedly updated even within the remaining time in the main process.

The second random number counter C4 is configured as a loop counter in which, for example, 1 is sequentially added in the range of 0 to 250, the maximum value (that is, 250) is reached, and then the counter returns to 0. Further, when the second random number counter C4 makes one round, the value of the second initial value random number counter CINI2 at that time is read as the initial value of the second random number counter C4. In the present embodiment, the value of the second random number counter C4 is updated periodically, for example, for each timer interrupt process, and it is detected that the ball has passed through either the left or right second entry port (through gate) 267. Obtained when it is done. The number of random numbers to be won is 149, and the range is "5 to 153". That is, when the value of the acquired second random number counter C4 is in the range of "5 to 153", it is determined that the player has won, and the second symbol display device 283 has a symbol "○" as a stop symbol (second symbol). Is lit and displayed, and the first ball entry port 264 is opened for a predetermined time. The second initial value random number counter CINI2 is configured as a loop counter updated in the same range as the second random number counter C4 (value = 0 to 250), and is once for each timer interruption process (see FIG. 61). At the same time as being updated, it is repeatedly updated within the remaining time of the main process (see FIG. 67).

As described above, the RAM 403 is provided with various counters and the like, and in the main control device 310, the jackpot lottery and the display in the first symbol display device 237 and the third symbol display device 281 are displayed according to the values of the counters and the like. It is possible to execute the main processing of the pachinko machine 200 such as setting and lottery of display results in the second symbol display device 283.

Returning to FIG. 51, the description will be continued. In addition to the various counters shown in FIG. 52, the RAM 403 has a stack area in which the contents of the internal registers of the MPU 401 and the return address of the control program executed by the MPU 401 are stored, various flags and counters, I / O, and the like. It has a work area (work area) in which the value of is stored. The RAM 403 has a configuration in which a backup voltage is supplied from the power supply device 315 to hold (back up) data even after the power of the pachinko machine 200 is cut off, and all the data stored in the RAM 403 is backed up. ..

When the power is cut off due to the occurrence of a power failure or the like, the stack pointer at the time of the power failure (including the time when a power failure occurs; the same applies hereinafter) and the value of each register are stored in the RAM 403. On the other hand, at the time of turning on the power (including turning on the power by eliminating the power failure, the same applies hereinafter), the state of the pachinko machine 200 is restored to the state before the power is cut off based on the information stored in the RAM 403. Writing to the RAM 403 is executed by the main process (see FIG. 67) when the power is cut off, and restoration of each value written in the RAM 403 is executed in the start-up process (see FIG. 66) at the time of turning on the power. The NMI terminal (non-maskable interrupt terminal) of the MPU 401 is configured to input a power failure signal SG1 from the power failure monitoring circuit 452 when the power is cut off due to a power failure or the like, and the power failure signal SG1 is the MPU 401. When input to, the NMI interrupt process (see FIG. 65) as the power failure process is immediately executed.

The RAM 403 further has a reserved ball number counter 403a. The hold ball number counter 403a holds the fluctuation display (variation display performed by the third symbol display device 281) performed by the first symbol display device 237 based on the entry into the first ball entry port 264 (starting prize). It is a counter that counts the number of balls (waiting number) up to 4 times. The initial value of the reserved ball number counter 403a is set to zero, and each time a ball enters the first entry port 264 and the number of reserved balls in the variable display increases, 1 is added up to the maximum value of 4. (See S1403 in FIG. 64). On the other hand, the reserved ball number counter 403a is decremented by 1 each time the variation display based on the ball entering the first ball opening 264 (starting winning) is executed (see S1205 in FIG. 62).

The value of the hold ball number counter 403a (that is, the hold ball number) is notified to the voice lamp control device 313 by the hold ball number command (see S1406 in FIG. 64). The hold ball number command is a command transmitted from the main control device 310 to the voice lamp control device 313 each time the ball is entered into the first ball entry port 264 and the hold ball number counter 403a is incremented by 1.

The voice lamp control device 313 is the value of the reserved ball number itself of the fluctuation display held in the main control device 310 by the reserved ball number command transmitted from the main control device 310 every time the reserved ball number counter 403a is incremented by 1. Can be obtained. As a result, the number of reserved balls in the variable display managed by the reserved ball number counter 423a of the voice lamp control device 313 deviates from the actual number of reserved balls in the variable display held in the main control device 310 due to the influence of noise or the like. Even if it has happened, the deviation can be corrected by the next received hold ball number command.

The voice lamp control device 313 manages the number of reserved balls based on the reserved ball number command, and the display hold for notifying the display control device 314 of the number of reserved balls each time the number of reserved balls changes. Send a ball count command. The display control device 314 displays the reserved ball number symbol in the small area Ds1 of the third symbol display device 281 based on the reserved ball number notified by the display reserved ball number command.

On the other hand, the hold ball number command transmitted from the main control device 310 to the voice lamp control device 313 includes the number of hold balls and the RAM 403 according to the entry timing (starting winning timing) to the first entry opening 264. Each value of the first hit random number counter C1, the first hit type counter C2, and the stop pattern selection counter C3 acquired from the counter buffer of the above is also included, and is notified to the voice lamp control device 313.

When the hold ball number command is received by the voice lamp control device 313, the voice lamp control device 313 of the first hit random number counter C1, the first hit type counter C2, and the stop pattern selection counter C3 included in the hold ball number command. From each value, the stop display mode when the variation effect based on the corresponding start prize is performed is estimated, the estimated stop display mode, and the value of the number of hold balls at that time indicated by the hold ball number command. Therefore, it is determined whether or not to perform a series of continuous advance notice productions for the variable productions reserved at that time.

The continuous advance notice effect is a kind of advance notice effect that suggests (notice) that the result of the lottery performed with the start winning is likely to be a big hit, and all the variable effects (variable display) that are reserved at the time of the winning. ), The same or related symbols are displayed on the third symbol display device 281 together with the variation effect. For example, by displaying a "bubble" image on the third symbol display device 281 immediately after the stop display of the variation effect over all the pending variation effects, the jackpot symbol does not appear as the stop symbol of the variation effect. Even if the jackpot is not a big hit, the player can continuously see the "bubble" image immediately after the fluctuation is stopped over multiple fluctuation displays, so that the player can get a jackpot after the continuous notice production is completed. It is possible to have a sense of expectation that can be obtained, and it is possible to give the player a motivation to continue the game.

In addition, "eggs" are displayed during the first fluctuation production, "chicks" are displayed during the second fluctuation production, and "chicken" is displayed during the third fluctuation production, and during the fourth fluctuation production. Display the "chicken group" (however, if the number of reserved balls at the time when the continuous notice effect is set is 3 or less, the "chicken group" is displayed in the last variable effect in which the continuous notice effect is set). As a result, each time the variation effect is performed on the third symbol display device 281, the symbol displayed by the continuous advance notice effect gradually changes (steps up), so that the player gradually changes the symbol. By looking at it, it is possible to give the player a feeling of expectation that when the chicken group is displayed, it will be a big hit in the variable effect in which the chicken group is displayed.

If the variable effect for which the continuous advance notice effect is set is 3, the continuous advance notice effect is performed in the order of "egg" → "chick" → "chicken group", and the variable effect for which the continuous advance notice effect is set is 2. In some cases, the continuous notice effect is performed in the order of "egg" → "chicken group", and when the variable effect for which the continuous notice effect is set is 1, the "chicken group" is suddenly displayed. In this way, when the number of variable effects for which the continuous notice effect is set is 3 or less, the pattern in the middle is skipped and the chicken group is suddenly displayed, so that the player suddenly displays the chicken group. Looking at it, it is possible to give a feeling of expectation that it will be a big hit in the variable production in which the chicken group is displayed.

In the pachinko machine 200, in the main control device 310, each value of the first hit random number counter C1, the first hit type counter C2, and the stop pattern selection counter C3 acquired at the time of starting winning is set to the voice lamp control device by the hold ball number command. Notifying 313, the voice lamp control device 313 determines the start of the continuous advance notice effect and sets the mode of the continuous advance notice effect based on the values of the various counters notified by the hold ball number command and the value of the hold ball number. conduct. As a result, the processing in the main control device 310 can be concentrated in the most important processing of the pachinko machine 200, which is the lottery processing for drawing the game state to be transitioned based on the ball entering the first ball entry port 264. On the other hand, if the MPU 421 having a high processing capacity is used for the voice lamp control device 313, the execution conditions of the continuous advance notice effect can be set in various modes.

Further, the number of reserved balls and the values of various counters can be transmitted from the main control device 310 to the voice lamp control device 313 with one command for the number of reserved balls. As a result, in the voice lamp control device 313, it is possible to accurately grasp the correspondence between the values of various counters acquired with the start winning and the number of reserved balls at the time when the starting winning is detected. When it is decided to execute the continuous advance notice effect, the number of reserved balls to which the continuous advance notice effect is added can be accurately grasped. Therefore, the control of the voice lamp control device 313 is facilitated as compared with the case where the number of reserved balls and the values of various counters are transmitted from the main control device 310 to the voice lamp control device 313 by another command. be able to.

An input / output port 405 is connected to the MPU 401 of the main control device 310 via a bus line 404 composed of an address bus and a data bus. The input / output port 405 has a payout control device 311, a voice lamp control device 313, a first symbol display device 237, a second symbol display device 283, a second symbol hold lamp 284, and the lower side of the opening / closing plate of the specific winning opening 265a. A solenoid 409 consisting of a large opening solenoid for driving the opening and closing and a solenoid for driving an electric accessory is connected to the front side, and the MPU 401 sends various commands and control signals to these via the input / output port 405. To send.

Further, various switches 408 including switch groups and sensor groups (not shown) and a RAM erasing switch circuit 453 described later provided in the power supply device 315 are connected to the input / output port 405, and the MPU 401 is output from the various switches 408. Various processes are executed based on the signal and the RAM erasing signal SG2 output from the RAM erasing switch circuit 453.

The payout control device 311 drives the payout motor 416 to control the payout of prize balls and rented balls. The MPU 411, which is an arithmetic unit, has a ROM 412 that stores a control program executed by the MPU 411, fixed value data, and the like, and a RAM 413 that is used as a work memory and the like.

Like the RAM 403 of the main control device 310, the RAM 413 of the payout control device 311 has a stack area in which the contents of the internal registers of the MPU 411 and the return destination address of the control program executed by the MPU 411 are stored, and various flags and counters. It has a work area (work area) in which values such as I / O are stored. The RAM 413 has a configuration in which a backup voltage is supplied from the power supply device 315 to hold (back up) data even after the power of the pachinko machine 200 is cut off, and all the data stored in the RAM 413 is backed up. Similar to the MPU 401 of the main control device 310, the NMI terminal of the MPU 411 is also configured so that the power failure signal SG1 is input from the power failure monitoring circuit 452 when the power is cut off due to the occurrence of a power failure or the like. When input to the MPU 411, the NMI interruption process (see FIG. 65) as the power failure process is immediately executed.

An input / output port 415 is connected to the MPU 411 of the payout control device 311 via a bus line 414 composed of an address bus and a data bus. A main control device 310, a payout motor 416, a launch control device 312, and the like are connected to the input / output port 415, respectively. Further, although not shown, the payout control device 311 is connected to a prize ball detection switch for detecting the paid out prize balls. The prize ball detection switch is connected to the payout control device 311 but not to the main control device 310.

The launch control device 312 controls the ball launch unit 312a so that when the main control device 310 gives an instruction to launch the ball, the launch strength of the ball corresponds to the amount of rotation of the operation handle 251. The ball launching unit 312a includes a firing solenoid and an electromagnet (not shown), and the firing solenoid and the electromagnet are permitted to be driven when predetermined conditions are met. Specifically, the operation handle is detected by the touch sensor 251a that the player is touching the operation handle 251 and the stop switch 251b for stopping the firing of the ball is turned off (not operated). The firing solenoid is excited in response to the amount of rotation of 251 and the ball is fired with a strength corresponding to the amount of operation of the operation handle 251.

The audio lamp control device 313 outputs audio in an audio output device (speaker, etc. not shown) 426, outputs lighting and extinguishing lights in a lamp display device (illumination units 229 to 233, indicator lamp 234, etc.) 427, and produces fluctuations (variations). It controls the setting of the display mode of the third symbol display device 281 performed by the display control device 314 such as display) and continuous notice effect. The MPU 421, which is an arithmetic unit, has a ROM 422 that stores a control program executed by the MPU 421, fixed value data, and the like, and a RAM 423 that is used as a work memory and the like.

An input / output port 425 is connected to the MPU 421 of the voice lamp control device 313 via a bus line 424 composed of an address bus and a data bus. A main control device 310, a display control device 314, an audio output device 426, a lamp display device 427, a vibration sensor 428, a frame button 222, and the like are connected to the input / output port 425, respectively.

The voice lamp control device 313 monitors the input from the frame button 222, and when the frame button 222 is operated by the player, the stage displayed on the third symbol display device 281 is changed, or at the time of super reach. The audio output device 426 and the lamp display device 427 are controlled so as to change the effect content, and the display control device 314 is instructed. When the stage is changed, a rear image change command including information about the changed stage is transmitted to the display control device 314 so that the rear image corresponding to the changed stage is displayed on the third symbol display device 281. .. Here, the back image is an image displayed on the back side of the third symbol, which is the main image to be displayed on the third symbol display device 281.

Further, the vibration sensor 428 is attached to the back surface of the game plate 213. In the pachinko machine 200, since the ball entering the ball entry port is an important factor for determining the game state, the flow of the ball is changed by vibration to prevent the ball from being intentionally entered into the ball entry port. There is a need. Therefore, when it is determined from the output of the vibration sensor 428 that the pachinko machine 200 has been vibrated by a player or the like, an error command for transmitting the vibration error is transmitted to the display control device 314. In addition, the voice lamp control device 313 determines an error according to the command from the main control device 310 and the status of various devices connected to the voice lamp control device 313, and issues an error command including the type of the error. It is transmitted to the display control device 314. The display control device 314 controls the third symbol display device 281 to display an error message image according to the error type (for example, vibration error) indicated by the received error command without delay.

The RAM 423 of the voice lamp control device 313 is provided with at least a hold ball number counter 423a. The reserved ball number counter 423a is a variable effect (variable display) performed by the first symbol display device 237 (and the third symbol display device 281), similarly to the reserved ball number counter 403a of the main control device 310. It is a counter that counts the number of reserved balls (number of standbys) of the variable effect held in the control device 310 up to four times.

As described above, the voice lamp control device 313 cannot directly access the main control device 310 to acquire the value of the reserved ball number counter 403a stored in the RAM 403 of the main control device 310. Therefore, the voice lamp control device 313 counts the number of reserved balls based on the command transmitted from the main control device 310, and the reserved ball number counter 423a manages the number of reserved balls.

Specifically, in the voice lamp control device 313, when the number of reserved balls in the variable display is added by entering the first ball entry port 264, and the value of the reserved ball number counter 403a is added in the main control device 310. When the hold ball number command transmitted from the main control device 310 is received, the value after addition of the hold ball number counter 403a of the main control device 310 included in the hold ball number command (that is, hold in the main control device 310). (The number of reserved balls in the variable display) is stored in the reserved ball number counter 423a (see S2007 in FIG. 71).

Further, the voice lamp control device 313 receives a variation pattern command transmitted from the main control device 310 when the value of the reserved ball number counter 403a is subtracted in the main control device 310, and the third symbol is accompanied by the reception. When the mode of variable display in the display device 281 is set, the value of the reserved ball number counter 423a is subtracted by 1 (see S2105 in FIG. 72). In this way, since the value of the hold ball number counter 423a is updated according to the command transmitted from the main control device 310, the value can be updated while synchronizing with the hold ball number counter 403a of the main control device 310. ..

The value of the reserved ball number counter 423a is used for displaying the reserved ball number symbol in the third symbol display device 281. That is, the voice lamp control device 313 stores the number of reserved balls indicated by the command in response to the reception of the reserved ball number command in the reserved ball number counter 423a, or stores the reserved ball number counter 423a in response to the reception of the variation pattern command. At the timing of updating the value of, a display holding ball number command is transmitted to the display control device 314 in order to notify the display control device 314 of the value of the reserved ball number counter 423a after storage or updating.

When the display control device 314 receives this display hold ball number command, the value of the hold ball number indicated by the command, that is, the hold ball number symbol corresponding to the value of the hold ball number counter 423a of the voice lamp control device 313. The drawing of the image is controlled so as to be displayed in the small area Ds1 of the third symbol display device 281 (see S2751 in FIG. 82 (a)). As described above, the value of the hold ball number counter 423a is changed while synchronizing with the hold counter 403a of the main control device 310. Therefore, the number of reserved sphere symbols displayed in the small area Ds1 of the third symbol display device 281 can also be changed while synchronizing with the value of the hold counter 403a of the main control device 310. Therefore, the third symbol display device 281 can accurately display the number of reserved balls for which the variable display is reserved.

The RAM 423 also indicates a command storage area (not shown) that temporarily stores commands received from the main control device 310 until processing corresponding to the commands is performed, and whether or not variable display should be started. It has a fluctuation start flag (not shown) and the like. The command storage area is composed of a ring buffer, and data is read / written by a FIFO (First In First Out) method. When the command determination process (see FIG. 71) of the voice lamp processing device 313 is executed, the command stored first among the unprocessed commands stored in the command storage area is read out, and the command determination process causes the command determination process to be performed. The command is parsed and processing is performed according to the command. Further, the fluctuation start flag is turned on when the fluctuation pattern command output from the main control device 310 is received (see S2002 in FIG. 71), and is turned off when the fluctuation display is set in the third symbol display device 281. (See S2102 in FIG. 72).

The display control device 314 is connected to the voice lamp control device 313 and the third symbol display device 281, and based on the command received from the voice lamp control device 313, the third symbol display (variation) in the third symbol display device 281 is displayed. It controls the production) and continuous notice production. The details of the display control device 314 will be described later with reference to FIG. 53.

The power supply device 315 is provided with a power supply unit 451 for supplying power to each part of the pachinko machine 200, a power failure monitoring circuit 452 for monitoring power failure due to a power failure, and a RAM erasing switch 322 (see FIG. 49). It has an erasing switch circuit 453. The power supply unit 451 is a device that supplies the required operating voltage to each of the control devices 310 to 314 and the like through a power supply path (not shown). As an outline, the power supply unit 451 takes in a voltage of 24 volt AC supplied from the outside, and a voltage of 12 volt for driving various switches such as various switches 408, a solenoid such as a solenoid 409, and a motor. A 5 volt voltage for logic, a backup voltage for RAM backup, and the like are generated, and these 12 volt voltage, 5 volt voltage, and backup voltage are supplied to each control device 310 to 314 and the like.

The power failure monitoring circuit 452 is a circuit for outputting a power failure signal SG1 to each NMI terminal of the MPU 401 of the main control device 310 and the MPU 411 of the payout control device 311 when the power is cut off due to the occurrence of a power failure or the like. The power failure monitoring circuit 452 monitors the DC stable 24 volt voltage, which is the maximum voltage output from the power supply unit 451 and determines that a power failure (power failure, power failure) has occurred when this voltage becomes less than 22 volts. Then, the power failure signal SG1 is output to the main control device 310 and the payout control device 311. By the output of the power failure signal SG1, the main control device 310 and the payout control device 311 recognize the occurrence of the power failure and execute the NMI interrupt process. The power supply unit 451 outputs a voltage of 5 volts, which is the drive voltage of the control system, for a sufficient time for executing the NMI interrupt process even after the voltage of DC stable 24 volts becomes less than 22 volts. Is configured to maintain normal values. Therefore, the main control device 310 and the payout control device 311 can normally execute and complete the NMI interrupt process (see FIG. 65).

The RAM erase switch circuit 453 is a circuit for outputting the RAM erase signal SG2 for clearing the backup data to the main control device 310 when the RAM erase switch 322 (see FIG. 49) is pressed. When the RAM erasing signal SG2 is input when the power of the pachinko machine 200 is turned on, the main control device 310 clears the backup data and issues a payout initialization command for clearing the backup data in the payout control device 311. It transmits to the device 311.

Next, with reference to FIG. 53, the electrical configuration of the display control device 314 will be described. FIG. 53 is a block diagram showing an electrical configuration of the display control device 314. The display control device 314 includes an MPU 431, a work RAM 433, a character ROM 434, a resident video RAM 435, a normal video RAM 436, an image controller 437, an input port 438, an output port 439, and a bus line 440, 441. have.

The output side of the voice lamp control device 313 is connected to the input side of the input port 438, and the MPU 431, the work RAM 433, the character ROM 434, and the image controller 437 are connected to the output side of the input port 438 via the bus line 440. .. A resident video RAM 435 and a normal video RAM 436 are connected to the image controller 437, and an output port 439 is connected to the image controller 437 via a bus line 441. Further, a third symbol display device 281 is connected to the output side of the output port 439.

Even if the pachinko machine 200 is another model in which the lottery probability of the jackpot and the number of prize balls paid out in one jackpot are different, the pachinko machine 200 has the same specifications as the symbol configuration displayed on the third symbol display device 281. Therefore, the display control device 314 is made into a common component to reduce the cost.

In the following, the MPU 431, the character ROM 434, the image controller 437, the resident video RAM 435, and the normal video RAM 436 will be described first, and then the work RAM 433 will be described.

First, the MPU 431 controls the display content of the third symbol display device 281 based on the display variation pattern command output from the voice lamp control device 313 based on the variation pattern command of the main control device 310. The MPU 431 has a built-in instruction pointer 431a, reads an instruction code stored at the address indicated by the instruction pointer 431a, fetches it, and executes various processes according to the instruction code. Immediately after the MPU 431 is turned on (including recovery from a power failure; the same applies hereinafter), a system reset can be applied from the power supply device 315. When the system reset is released, the instruction pointer 431a is used. Is automatically set to "0000H" by the hardware of MPU431. Then, each time the instruction code is fetched, the value of the instruction pointer 431a is incremented by one. When the MPU 431 executes the instruction pointer setting instruction, the value of the pointer instructed by the setting instruction is set in the instruction pointer 431a.

Although details will be described later, in the present embodiment, the control program executed by the MPU 431 and various fixed value data used in the control program are stored in a dedicated program ROM (for example, a conventional game machine) like a conventional gaming machine. The ROM 22) of Patent Document 1 described above is not provided and stored, but is stored in the character ROM 434 provided for storing the image data to be displayed on the third symbol display device 281.

Although the details will be described later, the character ROM 434 is composed of a NAND flash memory 434a capable of increasing the capacity in a small area. As a result, not only the image data but also the control program and the like can be sufficiently stored. If the control program or the like is stored in the character ROM 187, it is not necessary to provide a dedicated program ROM for storing the control program or the like. Therefore, the number of parts in the display control device 314 can be reduced, the manufacturing cost can be reduced, and the increase in the failure occurrence rate due to the increase in the number of parts can be suppressed.

On the other hand, the NAND flash memory has a problem that the read speed becomes slow, especially when performing random access. For example, when reading data that is continuously arranged on a plurality of pages, high-speed reading is possible for the data on the second and subsequent pages, but an address is specified for reading the data on the first page. It takes a long time to output the data. Further, when reading non-consecutive data, it takes a long time to read the data. As described above, since the speed of reading the NAND flash memory is slow, if the MPU 431 is configured to directly read the control program from the character ROM 434 and execute various processes, it takes time to read the instructions constituting the control program. Even if a high-performance processor is used as the MPU 431, the processing performance of the display control device 314 may be deteriorated.

Therefore, in the present embodiment, when the system reset of the MPU 431 is released, first, the control program stored in the NAND flash memory 434a of the character ROM 434 is transferred to the work RAM 433 provided for temporary storage of various data. And store it. Then, the MPU 431 executes various processes according to the control program stored in the work RAM 433. Since the work RAM 433 is configured by a DRAM (Dynamic RAM) as described later and data is read / written at high speed, the MPU 431 can read out the instructions constituting the control program without delay. Therefore, high processing performance can be maintained in the display control device 314, and diversified and complicated effects can be easily executed by using the third symbol display device 281.

The character ROM 434, the image controller 437, the resident video RAM 435, and the normal video RAM 436 are all the character ROM 187, the image controller 188, and the resident video RAM 189 provided in the display control device 314 of the slot machine 10 in the first embodiment. It has the same configuration or function as the normal video RAM 190.

That is, as described above, the character ROM 434 is a memory that stores the control program executed in the MPU 431 and the image data displayed on the third symbol display device 281, and is connected to the MPU 431 via the bus line 440. ing. The MPU 431 directly accesses the character ROM 434 after the system reset is released via the bus line 440, and transfers the control program stored in the second program storage area 431a1 described later of the character ROM 434 to the program storage area 433a of the work RAM 433. An image controller 437 is also connected to the bus line 440, and the image controller 437 transfers the image data stored in the character storage area 434a2 described later of the character ROM 434 to the resident video RAM 435 connected to the image controller 437. Transfer to the normal video RAM 436.

The character ROM 434 is configured by modularizing a NAND flash memory 434a, a ROM controller 434b, a buffer RAM 434c, and a NOR flash memory 434d.

The NAND flash memory 434a is a non-volatile memory provided as a main storage unit in the character ROM 434, and stores most of the control programs executed by the MPU 431 and fixed value data for driving the third symbol display device 281. It has at least a second program storage area 431a1 to be stored and a character storage area 434a2 to store data of an image (character or the like) to be displayed on the third symbol display device 281.

Here, the NAND flash memory has a feature that a large storage capacity can be obtained in a small area, and the character ROM 434 can be easily increased in capacity. As a result, in this pachinko machine, for example, by using a NAND flash memory 434a having a capacity of 2 gigabytes, many images can be stored in the character storage area 434a2 as images to be displayed on the third symbol display device 281. can. Therefore, in order to further enhance the interest of the player, the image displayed on the third symbol display device 281 can be diversified and complicated.

Further, the NAND flash memory 434a can store a large amount of image data in the character storage area 434a2, and further, the control program and fixed value data can be stored in the second program storage area 431a1. In this way, the control program and the fixed value data are displayed on the third symbol display device 281 without storing the control program and the fixed value data by providing a dedicated program ROM (for example, ROM 22 of the above-mentioned Patent Document 1) as in the conventional gaming machine. Since it can be stored in the character ROM 434 provided to store the image data to be stored, the number of parts in the display control device 314 can be reduced, the manufacturing cost can be reduced, and the failure occurrence rate due to the increase in the number of parts can be reduced. Can be suppressed from increasing.

The ROM controller 434b is a controller for controlling the operation of the character ROM 434, and is, for example, the corresponding data from the NAND flash memory 434a or the like based on the address transmitted from the MPU 431 or the image controller 437 via the bus line 440. Is read out and output to the MPU 431 or the image controller 437 via the bus line 440.

Here, due to the nature of the NAND flash memory 434a, a relatively large number of error bits (bits in which erroneous data is written) are generated when writing data, or a defective data block in which data cannot be written occurs. Or something. Therefore, the ROM controller 434b is known to perform known error correction on the data read from the NAND flash memory 434a, and to read and write data to and from the NAND flash memory 434a while avoiding defective data blocks. Data address conversion (see, for example, Patent Document 1) is performed.

Since the ROM controller 434b performs error correction on the data read from the NAND flash memory 434a including the error bit, even if the NAND flash memory 434a is used as the character ROM 434, it is based on the erroneous data. It is possible to prevent the MPU 431 from performing processing and the image controller 437 from generating various images.

Further, since the defective data block of the NAND flash memory 434a is analyzed by the ROM controller 434b and access to the defective data block is avoided, the MPU 431 and the image controller 437 have different defective data in each NAND flash memory 434a. Access to the character ROM 434 can be easily performed without considering the address position of the block. Therefore, even if the NAND flash memory 434a is used for the character ROM 434, it is possible to suppress the complicated access control to the character ROM 434.

The buffer RAM 434c is a memory used as a buffer for temporarily storing data read from the NAND flash memory 434a. When an address assigned to the character ROM 434 from the MPU 431 or the image controller 437 via the bus line 440 is specified, the ROM controller 434b has one page (for example, 2 kilobytes) containing the data corresponding to the specified address. It is determined whether or not the data of is set in the buffer RAM 434c. If it is not set, one page (for example, 2 kilobytes) of data including the data corresponding to the specified address is read from the NAND flash memory 434a (or NOR type ROM 434d) and temporarily set in the buffer RAM 434c. do. Then, the ROM controller 434b performs a known error correction process, and then outputs the data corresponding to the designated address to the MPU 431 or the image controller 437 via the bus line 440.

The buffer RAM 434c is composed of two banks, and data for one page of the NAND flash memory 434a can be set in one bank. As a result, the ROM controller 434b can output the data of the NAND flash memory 187a to the outside by using the other bank while the data is set in one bank, or can be designated by the MPU 431 or the image controller 437. The process of transferring one page of data including the data corresponding to the assigned address from the NAND flash memory 434a to one bank and setting the data, and the data corresponding to the address specified by the MPU 431 or the image controller 437 of the other The process of reading from the bank and outputting to the MPU 431 or the image controller 437 can be processed in parallel. Therefore, it is possible to improve the responsiveness in reading the character ROM 434.

The NOR type ROM 434d is a non-volatile memory provided as a sub storage unit in the character ROM 434, and has an extremely smaller capacity (for example, 2 kilobytes) than the NAND type flash memory 434a for the purpose of complementing the NAND type flash memory 434a. ). Among the control programs stored in the character ROM 434, the program not stored in the second program storage area 431a1 of the NAND flash memory 434a, specifically, the first program stored in the NOR type ROM 434d after the system reset is released in the MPU 431. At least a first program storage area 434d1 for storing a part of the boot program to be executed is provided.

The boot program is a control program for starting the display control device 314 so that various controls for the third symbol display device 281 can be executed, and the MPU 431 first executes this boot program after the system reset is released. As a result, various controls can be executed in the display control device 314. The first program storage area 434d1 should be processed first by the MPU 181 after the system reset is released within the capacity range of one bank of the buffer RAM 434c (that is, one page of the NAND flash memory 434a) in this boot program. A predetermined number of instructions (for example, if the capacity of one page is 2 kilobytes, 1024 words (1 word = 2 bytes) worth of instructions) are stored from the instructions. The number of boot program instructions stored in the first program storage area 434d1 may be less than or equal to the capacity of one bank of the buffer RAM 434c, and is appropriately set according to the specifications of the display control device 314. There may be.

When the system reset is released, the MPU 431 sets the value of the instruction pointer 431a to "0000H" by hardware and specifies the address "0000H" indicated by the instruction pointer 431a to the bus line 440. It is configured. On the other hand, when the ROM controller 434b of the character ROM 434 detects that the address "0000H" is specified for the bus line 440, the boot program stored in the first program storage area 434d1 of the NOR type ROM 434d is stored in one bank of the buffer RAM 434c. Is set to, and the corresponding data (command code) is output to the MPU 431.

When the MPU 431 fetches the instruction code received from the character ROM 434, it executes various processes according to the fetched instruction code, adds only one instruction pointer 431a, and assigns the address indicated by the instruction pointer 431a to the bus line 440. To specify. Then, the ROM controller 434b of the character ROM 434 is among the programs previously set in the buffer RAM 434c from the NOR type ROM 434d while the address specified by the bus line 440 is an address indicating the program stored in the NOR type ROM 434d. , The instruction code of the corresponding address is read from the buffer RAM 434c and output to the MPU 431.

Here, in the present embodiment, instead of storing all the control programs in the NAND flash memory 434a, among the boot programs, a predetermined number of instructions from the instructions to be processed first by the MPU 431 after the system reset is released are stored in the NOR type ROM 434d. It is stored in for the following reasons. That is, as described above, the NAND flash memory 434a is peculiar to the NAND flash memory that it takes a long time from the designation of the address to the output of the data in reading the data on the first page. There's a problem.

When all the control programs are stored in such a NAND flash memory 434a, the address "0000H" is specified from the MPU 431 via the bus line 440 in order to fetch the instruction code to be executed first by the MPU 431 after the system reset is released. If so, the character ROM 434 must read one page of data including the data (instruction code) corresponding to the address "0000H" from the NAND flash memory 434a and set it in the buffer RAM 434c. Due to the nature of the NAND flash memory 434a, it takes a long time to set the buffer RAM 434c from the read thereof. Therefore, the MPU 431 specifies the address "0000H" and then gives an instruction corresponding to the address "0000H". It consumes a lot of waiting time to receive the code. Therefore, it takes a long time to start the MPU 431, and as a result, there is a problem that the control of the third symbol display device 281 in the display control device 314 may not be started immediately.

On the other hand, since the NOR type ROM is a memory capable of reading data at high speed, a predetermined number of instructions from the instruction to be processed first by the MPU 431 after the system reset is released are stored in the NOR type ROM 434d among the boot programs. By doing so, when the address "0000H" is specified from the MPU 431 via the bus line 440 after the system reset is released, the character ROM 434 immediately stores the boot program stored in the first program storage area 434d1 of the NOR type ROM 434d in the buffer RAM 434c. The corresponding data (instruction code) can be output to the MPU 431. Therefore, the MPU 431 can receive the instruction code corresponding to the address "0000H" in a short time after designating the address "0000H", and can start the MPU 431 in a short time. Therefore, even if the control program is stored in the character ROM 434 configured by the NAND flash memory 434a having a slow read speed, the control of the third symbol display device 281 in the display control device 314 can be started immediately.

The boot program includes a control program stored in the second program storage area 431a1 of the NAND flash memory 434a, that is, a control program excluding the boot program stored in the first program storage area 434d1 of the NOR type ROM 434d. , The fixed value data used in the control program (for example, display data table, additional data table, transfer data table, etc., which will be described later) is divided into predetermined amounts (for example, the capacity of one page of the NAND flash memory 434a) in the work RAM 433. It is programmed to transfer to the program storage area 433a or the data table storage area 433b. Then, in the MPU 431, first, the boot program in the first program storage area 434d1 sets the control program stored in the second program storage area 431a1 according to the boot program read from the first program storage area 434d1 after the system reset is released. While using a bank different from the bank of the buffer RAM 434c, a predetermined amount is transferred to and stored in the program storage area 433a.

Here, since the boot program stored in the first program storage area 434d1 has a capacity corresponding to one bank of the buffer RAM 434c as described above, the address of the internal bus is designated as "0000H". When the boot program of the first program storage area 434d1 is set in the buffer RAM 434c in response to the above, the boot program is set in only one bank of the buffer RAM 434c. Therefore, when transferring the control program stored in the second program storage area 434a1 to the program storage area 433c according to the boot program of the first program storage area 434d1, the first program set in one bank of the buffer RAM 434c The transfer process can be executed using the other bank while leaving the boot program in the storage area 434d1. Therefore, since it is not necessary to reset the boot program in the first program storage area 434d1 to the buffer RAM 434c after the transfer process, the time required for the boot process can be shortened.

When the boot program stored in the first program storage area 434d1 transfers the control program stored in the second program storage area 431a1 to the program storage area 433a by a predetermined amount, the instruction pointer 431a is transferred to the program storage area 433a. It is programmed to set to the first predetermined address. As a result, after the system reset is released, when the control program stored in the second program storage area 431a1 is transferred to the program storage area 433a by a predetermined amount by the MPU 431, the instruction pointer 431a becomes the first predetermined program storage area 433a. Set to the address.

Therefore, when a predetermined amount of programs among the control programs stored in the second program storage area 431a1 are stored in the program storage area 433a, the MPU 431 reads the control program stored in the program storage area 433a and reads the control program. Various processes can be executed. That is, the MPU 431 does not read the control program from the NAND flash memory 434a having the second program storage area 431a1 and fetch the instructions, but reads the control program transferred to the work RAM 433 having the program storage area 433a and fetches the instructions. Then, various processes will be executed. As will be described later, since the work RAM 433 is composed of the DRAM, the read operation is performed at high speed. Therefore, even when the control program is stored in the character ROM 434 configured by the NAND flash memory 434a having a slow read speed, the MPU 431 can fetch the instruction at high speed and execute the processing for the instruction.

Here, the control program stored in the second program storage area 431a1 includes the remaining boot programs that are not stored in the first program storage area 434d1. On the other hand, the boot program stored in the first program storage area 434d1 has the remaining boot programs in the control program transferred from the second program storage area 431a1 by a predetermined amount to the program storage area 433a of the work RAM 433. It is programmed to be included, and the instruction pointer 431a is programmed so that the start address of the remaining boot program stored in the program storage area 433a is set as the first predetermined address.

As a result, the MPU 431 transfers the control program stored in the second program storage area 434a1 to the program storage area 433a by a predetermined amount by the boot program stored in the first program storage area 434d1, and then transfers the control program. Run the rest of the boot program contained in the control program.

In this remaining boot program, all the remaining control programs that have not been transferred to the program storage area 433a and the fixed value data (for example, display data table, additional data table, transfer data table, etc. described later) used in the control program are all included. A process of transferring a predetermined amount from the second program storage area 434a1 to the program storage area 433a or the data table storage area 433b is executed. Further, at the end of the boot program, the instruction pointer 431a is set to the second predetermined address in the program storage area 433a. Specifically, as this second predetermined address, the initialization process (see S2201 in FIG. 73) executed after the boot process (see S2201 in FIG. 73) stored in the program storage area 433a by the boot program is completed. Set the start address of the program corresponding to.

By executing the remaining boot program, the MPU 431 transfers all the control programs and fixed value data stored in the second program storage area 434a1 to the program storage area 433a or the data table storage area 433b. Then, when the boot program is executed to the end by the MPU 431, the instruction pointer 431a is set to the second predetermined address, and thereafter, the MPU 431 is transferred to the program storage area 433a without referring to the NAND flash memory 434a. Various processes are executed using the control program.

Therefore, even when the control program is stored in the character ROM 434 configured by the NAND flash memory 434a having a slow read speed, the control program can be transferred to the program storage area 433a of the work RAM 433 after the system reset is released. , MPU431 can read a control program from a work RAM configured by a DRAM having a high read speed and perform various controls. Therefore, high processing performance can be maintained in the display control device 314, and diversified and complicated effects can be easily executed by using the third symbol display device 281.

Further, as described above, instead of storing all the boot programs in the NOR type ROM 434d, a predetermined number of instructions are stored from the instruction to be processed first by the MPU 431 after the system reset is released, and the remaining boot programs are stored. Even if the program is stored in the second program storage area 187a2 of the NAND flash memory 434a, the control program stored in the second program storage area 434a1 can be reliably transferred to the program storage area 433a. Therefore, the character ROM 434 can start the MPU 431 in a short time only by adding an extremely small capacity NOR type ROM 434d, so that the cost increase of the character ROM 434 due to the shortening of the time can be suppressed. Can be done.

The image controller 437 is a digital signal processor (DSP) that draws an image and displays the drawn image on the third symbol display device 281 at a predetermined timing. The image controller 437 draws an image for one frame based on the drawing list (see FIG. 60) described later transmitted from the MPU 431, and draws one frame of the first frame buffer 436b and the second frame buffer 436c described later. The image drawn in the buffer is expanded, and the image information for one frame previously expanded in the other frame buffer is output to the third symbol display device 281 to display the image on the third symbol display device 281. .. The image controller 437 performs the image drawing process for one frame and the image display process for one frame in the image display time for one frame in the third symbol display device 281 (20 milliseconds in this embodiment). Parallel processing in.

The image controller 437 transmits a vertical synchronization interrupt signal (hereinafter referred to as “V interrupt signal”) to the MPU 431 every 20 milliseconds when the image drawing process for one frame is completed. Each time the MPU 431 detects this V interrupt signal, it executes a V interrupt process (see FIG. 74 (b)) and instructs the image controller 437 to draw an image for the next frame. In response to this instruction, the image controller 437 executes an image drawing process for the next frame, and also executes a process of displaying the image previously developed by drawing on the third symbol display device 281.

In this way, the MPU 431 executes the V interrupt process in response to the V interrupt signal from the image controller 437, and gives a drawing instruction to the image controller 437. Therefore, the image controller 437 draws and displays an image. An image drawing instruction can be received from the MPU 431 at each processing interval (20 milliseconds). Therefore, in the image controller 437, since the drawing instruction of the next image is not received at the stage where the drawing processing and the display processing of the image are not completed, the drawing of a new image may be started in the middle of drawing the image. It is possible to prevent the image from being expanded in accordance with a new drawing instruction in the frame buffer in which the image information being displayed is stored.

The image controller 437 also executes a process of transferring image data from the character ROM 434 to the resident video RAM 435 or the normal video RAM 436 based on the transfer instruction from the MPU 431 and the transfer data information included in the drawing list.

The image is drawn using the image data stored in the resident video RAM 435 and the normal video RAM 436. That is, the image data required for drawing is transferred from the character ROM 434 to the resident video RAM 435 or the normal video RAM 436 based on the instruction from the MPU 431 before the drawing is performed.

Here, the NAND flash memory facilitates a large capacity of the ROM, but the read speed is slower than that of other ROMs (mask ROM, EEPROM, etc.). On the other hand, in the display control device 314, the MPU 431 instructs the image controller 437 to transfer a part of the image data stored in the character ROM 434 to the resident video RAM 435 after the power is turned on. It is configured to do. Then, as will be described later, the image data stored in the resident video RAM 435 is controlled so as to be resident without being overwritten.

As a result, after the transfer of the image data that should be resident in the resident video RAM 435 is completed after the power is turned on, the image is drawn by the image controller 437 while using the image data resident in the resident video RAM 435. Processing can be performed. Therefore, if the image data used for the drawing process is resident in the resident video RAM 435, it is not necessary to read the corresponding image data from the character ROM 434 configured by the NAND flash memory 434a having a slow read speed at the time of image drawing. The time required for reading the image can be omitted, and the image can be drawn immediately and the drawn image can be displayed on the third symbol display device 281.

In particular, since the resident video RAM 435 is resident with image data of images that are frequently displayed and image data of images that should be displayed immediately after the display is determined by the main control device 310 or the display control device 314. Even if the character ROM 434 is composed of the NAND flash memory 434a, it is possible to maintain high responsiveness until some image is displayed on the third symbol display device 281.

Further, when drawing an image using non-resident image data in the resident video RAM 435, the display control device 314 is required for drawing from the character ROM 434 to the normal video RAM 436 before the drawing is performed. The MPU 431 is configured to instruct the image controller 437 to transfer image data. As will be described later, the image data transferred to the normal video RAM 436 may be deleted by overwriting after being used for drawing an image, but at the time of drawing an image, the NAND flash memory 434a having a slow read speed. Since it is not necessary to read the corresponding image data from the character ROM 434 configured by the above and the time required for the reading can be omitted, the image can be drawn immediately and the drawn image can be displayed on the third symbol display device 281. can.

Further, by storing the image data in the normal video RAM 436, it is not necessary to make all the image data resident in the resident video RAM 435, so that it is not necessary to prepare a large-capacity resident video RAM 435. Therefore, it is possible to suppress an increase in cost due to the provision of the resident video RAM 435.

The image controller 437 has a buffer RAM 437a composed of 132 kilobytes of SRAM, which is the capacity of one block of the NAND flash memory 434a, similarly to the buffer RAM 188a provided in the image controller 188 in the first embodiment. There is.

The image data transfer instruction given by the MPU 431 to the image controller 437 by the transfer instruction or the transfer data information of the drawing list includes the start address (storage source start address) of the character ROM 434 in which the image data to be transferred is stored. Final address (storage source final address), transfer destination information (information indicating whether to transfer to resident video RAM 435 or normal video RAM 436), and the beginning of transfer destination (resident video RAM 435 or normal video RAM 436) Contains the address. The data size of the image data to be transferred may be included instead of the final address of the storage source.

The image controller 437 reads data for one block from a predetermined address of the character ROM 435 and temporarily stores the data in the buffer RAM 437a according to various information of the transfer instruction, and when the resident video RAM 435 or the normal video RAM 436 is not used, the buffer RAM 437a The image data stored in is transferred to the resident RAM 435 or the normal video RAM 436. Then, the process is repeatedly executed until all the image data stored in the storage source final address is transferred from the storage source start address indicated by the transfer instruction.

As a result, the image data read from the character ROM 434 over time is temporarily stored in the buffer RAM 437a, and then the image data is transferred from the buffer RAM 437a to the resident video RAM 435 or the normal video RAM 436 in a short time. Can be done. Therefore, while the image data is transferred from the character ROM 434 to the resident video RAM 435 or the normal video RAM 436, the resident video RAM 435 or the normal video RAM 436 is prevented from being occupied for a long time by the transfer of the image data. be able to. Therefore, since the resident video RAM 435 and the normal video RAM 436 are occupied by the transfer of the image data, those video RAMs 435 and 436 cannot be used for the image drawing process, and as a result, the image can be drawn by the required time. , It is possible to prevent the display on the third symbol display device 281 from being missed.

Further, since the transfer of the image data from the buffer RAM 437a to the resident video RAM 435 or the normal video RAM 436 is performed by the image controller 437, the resident video RAM 435 and the normal video RAM 436 perform image drawing processing and display the third symbol. The period during which the display process on the device 281 is unused can be easily determined, and the process can be simplified.

Similar to the display control device 81 in the first embodiment, the resident video RAM 435 is used so that the image data transferred from the character ROM 434 is continuously held without being overwritten during the power-on, and the power is turned on. In addition to the main image area 435a, the rear image area 435c, the character symbol area 435e, and the error message image area 435f, at least the variable image area 435b when the power is turned on and the third symbol area 435d are provided.

Similar to the power-on main image area 189a of the first embodiment, the power-on main image area 435a is from the time the power is turned on until all the image data to be resident in the resident video RAM 435 is stored. This is an area for storing data corresponding to the main image when the power is turned on, which is displayed on the third symbol display device 281. Further, in the variable image area 435b when the power is turned on, the player starts the game while the main image when the power is turned on is displayed on the third symbol display device 281, and the ball entering the first ball entry port 164 is detected. This is an area for storing image data corresponding to a variable image when the power is turned on, which displays the lottery result performed by the main control device 310 by a variable effect.

When the power supply from the power supply unit 451 is started, the MPU 431 transfers the image data corresponding to the power-on main image and the power-on fluctuation image from the character ROM 434 to the power-on main image area 435a. A transfer instruction is transmitted to the controller 437 (see S2203 and S2204 in FIG. 73).

Here, a variation image when the power is turned on will be described with reference to FIG. 54. FIG. 54 shows the power-on displayed by the third symbol display device 281 while the display control device 314 is transferring the image data to be stored to the resident video RAM 435 from the character ROM 434 immediately after the power is turned on. It is explanatory drawing explaining the time image.

Immediately after the power is turned on, the display control device 314 transfers the image data corresponding to the power-on main image and the power-on variable image from the character ROM 434 to the power-on main image area 435a and the power-on variable image area 435b. Subsequently, the remaining image data to be stored in the resident video RAM 435 is transferred from the character ROM 434 to the resident video RAM 435. While the remaining image data is being transferred, the display control device 314 uses the image data previously stored in the main image area 435a at power-on, and the main image at power-on shown in FIG. 54 (a). The image is displayed on the third symbol display device 281.

At this time, when the display variation pattern command transmitted from the voice lamp control device 313 based on the variation pattern command from the main control device 310, which is the instruction command for starting the variation, is received, the display control device 314 displays FIG. 54 (b). On the display screen of the main image when the power is turned on, as shown in FIG. At the same position as the symbol, the image of the "x" symbol that fluctuates when the power is turned on is displayed alternately and repeatedly during the fluctuation period. Then, from the display variation pattern command and the display stop type command transmitted from the voice lamp control device 313 based on the variation pattern command from the main control device 310 and the stop type command, the lottery performed by the main control device 310 is performed. Judging the result, if it is a "big hit", the image shown in FIG. 54 (b) is displayed for a certain period after the variation effect is stopped, and if it is "off", the image shown in FIG. 54 (c) is displayed in the variation effect. Display for a certain period after stopping.

The MPU 431 used the image data stored in the main image area 435a at power-on for the image controller 437 until all the image data to be resident in the resident video RAM 435 was transferred to the resident video RAM 435. Instructs the drawing of the main image when the power is turned on. As a result, while the remaining image data to be resident is transferred to the resident video RAM 435, the player or the person concerned with the hall can confirm the main image at power-on displayed on the third symbol display device 281. can. Therefore, the display control device 314 transfers the remaining resident image data from the character ROM 434 to the resident video RAM 435 over time while the main image at power-on is displayed on the third symbol display device 281. be able to. Further, since the player or the like can recognize that some processing is being performed while the main image at power-on is displayed on the third symbol display device 281, the image to be resident in the remaining resident video RAM 435. Until the data is transferred from the character ROM 434 to the resident video RAM 435, it is possible to wait until the transfer of the image data to the resident video RAM 435 is completed without worrying that the operation has stopped. can.

Further, even in the operation check in the factory at the time of manufacturing, the main image at the time of turning on the power is immediately displayed on the third symbol display device 281, so that the operation of the third symbol display device 281 is started without any problem by turning on the power. By using the NAND flash memory 434a having a slow read speed for the character ROM 434, it is possible to prevent the efficiency of the operation check from deteriorating.

Further, when the player starts the game while the main image at the time of power-on is displayed on the third symbol display device 281 and the entry into the first entrance ball 264 is detected, the fluctuation image area at the time of power-on The power-on fluctuation image is drawn using the image data corresponding to the power-on fluctuation image resident in 435b, and the images shown in FIGS. 54 (b) and 54 (c) are alternately displayed on the third symbol display device 281. The MPU 431 instructs the image controller 437 to do so. As a result, it is possible to perform a simple fluctuation effect using the fluctuation image when the power is turned on. Therefore, the player can confirm that the lottery has been surely performed by the simple variation effect even while the main image at the time of turning on the power is displayed on the third symbol display device 281.

Further, since the image data corresponding to the power-on fluctuation effect image is already resident in the power-on fluctuation image area 435b at the stage when the power-on main image is displayed on the third symbol display device 281, the power is turned on. If a ball entering the first entrance ball 264 is detected while the time main image is displayed on the third symbol display device 281, the corresponding variation effect may be immediately displayed on the third symbol display device 281. can.

Returning to FIG. 53, the description will be continued. The rear image area 435c is an area for storing image data corresponding to the rear image displayed on the third symbol display device 281, similarly to the rear image area 189b of the first embodiment. Here, with reference to FIGS. 55 and 56, the back image and the range of the back image stored in the back image area 435c among the back images will be described. 55 and 56 are explanatory views illustrating the three types of rear images and the range of the rear image stored in the rear image area 435c of the resident video RAM 435 for each rear image. FIG. 55 (a). Is for the back surface A corresponding to the "city stage", FIG. 55 (b) is for the back surface B corresponding to the "empty stage", and FIG. 56 is for the back surface C corresponding to the "island stage". These are shown below.

Of the back surfaces A to C, as shown in FIG. 55, the back image corresponding to the back surfaces A and B is a character whose image is longer in the horizontal direction than the display area displayed on the third symbol display device 281. It is prepared in ROM 434. The image controller 437 draws an image so that the rear image is displayed on the third symbol display device 281 while scrolling the image horizontally from left to right.

The images prepared on the back surfaces A and B (hereinafter referred to as "scrolling images") are configured so that the back image is continuous at the positions a and c. The image between the position c and the position d and the image between the position a and the position a'are composed of an image corresponding to the width in the horizontal direction of the display area, and the image between the position c and the position d. Is displayed on the third symbol display device 281 as a display area, and then the image between the position a and the position a'is displayed on the third symbol display device 281 as a display area. The back image is scrolled and displayed in a simple connection.

When the frame button 222 is operated by the player to change the stage to "city stage" or "empty stage", the MPU 431 sets the initial position of the display area between the first position a and the position a'of the corresponding rear image. The image controller 437 is controlled so that the image at the initial position is displayed on the third symbol display device 281. Then, with the passage of time, the display area is moved from left to right with respect to the scroll image, and the image controller 437 is controlled so that the display area is sequentially displayed on the third symbol display device 281. When the area reaches the image between the position c and the position d, the image controller 437 is controlled so that the display area is displayed again on the third symbol display device 281 as an image from the position a to the position a'. Therefore, the third symbol display device 281 can repeatedly scroll and display the image between the positions a and c so as to flow toward the left.

On the other hand, as shown in FIG. 56, the rear image on the back surface C is displayed in the order of (a) → (b) → (c) → (a) → ... In FIG. 56 with the passage of time. Displayed on device 281. Specifically, on the back surface C, the image of the mountain towering over the island, the image of the sandy beach spreading at the foot of the mountain, and the image of the sea surrounding the island are displayed in a fixed position. It is displayed on the display device 281. On the other hand, the color tone of the sky image spreading on the mountain changes with the passage of time.

When the stage is changed to the "island stage" by the operation of the frame button 222 by the player, the rear image shown in FIG. 56A is displayed as the initial rear image of the rear surface C. In the rear image shown in FIG. 56 (a), an orange sky indicating a morning glow is displayed. Then, with the passage of time, the color tone of the sky gradually changes from orange to bright blue, and after a predetermined time elapses, the back image shown in FIG. 56B is displayed. In the rear image shown in FIG. 56B, a bright blue sky indicating daytime is displayed. Next, the color tone of the sky gradually changes from bright blue to black with the lapse of time, and after a lapse of a predetermined time, the back image shown in FIG. 56 (c) is displayed. In the rear image shown in FIG. 56 (c), a black sky indicating the night is displayed. After that, with the passage of time, the color tone of the sky gradually begins to turn white from black and then changes to orange. Then, after the lapse of a predetermined time, the image returns to the back image shown in FIG. 56 (a), and the back images of FIGS. 56 (a) to 56 (c) are displayed on the third symbol display device 281 again.

Next, in each back image, the range of the back image stored in the back image area 435c will be described. As shown in FIG. 55A, the back surface A corresponding to the city stage, which is the initial stage, has the entire range of the back surface A, that is, the back surface of the resident video RAM 435 in which all the image data corresponding to the position a to the position d is recorded. It is stored in the image area 435c. Normally, the game is played without changing the stage while the city stage, which is the initial stage, is displayed. Therefore, all the image data on the back A corresponding to the frequently displayed city stage is displayed in the back image area. By making it resident in 435c, the number of data accesses to the character ROM 434 can be reduced, and the load on the display control device 314 can be reduced.

On the other hand, as shown in FIG. 55 (b), the back surface B corresponding to the empty stage contains only a part of the back surface, that is, the image data corresponding to the image between the position a and the position b, for the resident video RAM 435. It is stored in the rear image area 435c of. Further, the back surface C corresponding to the island stage includes FIG. 56 (a), and the image data corresponding to the back image between FIGS. 56 (a) to 56 (b) excluding FIG. 56 (b) is obtained after the power is turned on. It is stored in the rear image area 435c of the resident video RAM 435 and is resident in the start-up process.

Here, since the operation of the frame button 222 performed by the player to change the stage is performed at an arbitrary timing based on the intention of the player, even if the frame button 222 is operated at an arbitrary timing. In order to change the rear image immediately, it is ideal to make the entire range of image data resident in the resident video RAM 435 for all the rear images, but doing so makes it very resident video RAM 435. A large capacity RAM must be used, which may lead to an increase in cost.

On the other hand, in the pachinko machine 200, the initial position of the rear image first displayed when the stage is changed is set to the range from the position a to the position a'or the range of FIGS. 56 (a) to 56 (b). It is fixed, and the image data corresponding to the image between the position a and the position b including the initial position or the image between FIGS. 56 (a) and 56 (b) is stored in the rear image area 435c of the resident video RAM 435. Therefore, even if the character ROM 434 is configured with a NAND flash memory 434a having a slow read speed, the rear image area of the resident video RAM 435 when the stage is changed at an arbitrary timing by the operation of the frame button 222 by the player. By using the image data resident in 435c, the initial positions of the back surface B and the back surface C are immediately displayed on the third symbol display device 281, and the scroll display or the color tone is changed with the passage of time. be able to. Further, since only the image data corresponding to a part of the range of images is stored in the back surface B and the back surface C, it is possible to suppress an increase in the storage capacity of the resident video RAM 435 and suppress an increase in cost.

Further, on the back surface B, after the image at the initial position is displayed, the range from the position a to the position b is scrolled from left to right using the image data resident in the rear image area 435c of the resident video RAM 435. During this period, the range from the position a to the position b is set so that the image data corresponding to the image from the position b'to the position d can be completely transferred from the character ROM 434 to the normal RAM 436. As a result, the image data from the position b'to the position d can be transferred to the normal video RAM 436 while scrolling the range from the position a to the position b, so that the image data stored in the rear image area 435c of the resident video RAM 435 can be transferred. After scrolling the range from position a to position b using the image data corresponding to the rear image stored in the normal video RAM 436 without delay, the range from position b'to position d is scrolled to the third position. It can be displayed on the symbol display device 281.

Similarly, on the back surface C, after the image at the initial position is displayed, the images of FIGS. 56 (a) to 56 (b) are displayed using the image data resident in the rear image area 435c of the resident video RAM 435. 56 (a), so that the image data of the images corresponding to FIGS. 56 (b) to 56 (c) and 56 (c) to (a) can be completely transferred from the character ROM 434 to the normal RAM 436. The range of (b) is set. As a result, while the images of FIGS. 56 (a) to 56 (b) are displayed, the image data corresponding to the images of FIGS. 56 (b) to (c) and 56 (c) to (a) is stored in the normal video RAM 436. Since the images can be transferred to, the images of FIGS. 56A to 56B are displayed using the image data resident in the rear image area 435c of the resident video RAM 435, and then stored in the normal video RAM 436 without delay. Using the image data corresponding to the rear image, the images of FIGS. 56 (b) to (c) and FIGS. 56 (c) to (a) can be sequentially displayed on the third symbol display device 281 over time. can.

In the back surface B and the back surface C, the image data stored in the normal video RAM 436 is stored in a sub area dedicated to the rear image provided in the image storage area 436a (see FIG. 53) of the normal video RAM 436. As a result, the back image data stored in the sub area dedicated to the back image is not overwritten by other image data, so that the back image can be reliably displayed.

Further, on the rear surface B, the image data stored in the rear image area 435c of the resident video RAM 435 and the image data stored in the normal video RAM 436 are images corresponding to the images between the positions b'and b. Data is stored in duplicate. Then, under the control of the image controller 437 by the MPU 431, the image up to the position b is displayed on the third symbol display device 281 using the image data stored in the rear image area 435c of the resident video RAM 435, and then the normal video is displayed. By displaying the image from the position b'on the third symbol display device 281 using the image data stored in the RAM 436, the rear image is scrolled and displayed on the third symbol display device 281 with a smooth connection. ing.

Further, the MPU 431 controls the image controller 437 so that the image between the position c and the position d is displayed on the third symbol display device 281 as the display area by using the image data of the normal video RAM 436, and then the image controller 437 is controlled. The MPU 431 controls the image controller 437 so that the image between the position a and the position a'is displayed on the third symbol display device 281 as a display area by using the image data of the rear image area 435c of the resident video RAM 435. do. As a result, the third symbol display device 281 can be repeatedly scrolled and displayed with a smooth connection so that the image between the positions a and c flows toward the left.

Returning to FIG. 53, the description will be continued. The third symbol area 435d is an area for resident the third symbol used in the variation effect displayed on the third symbol display device 281. That is, in the third symbol area 435, image data corresponding to the above-mentioned 10 types of main symbols (see FIG. 50) with numbers “0” to “9”, which are the third symbols, are resident. As a result, when performing variable effect on the third symbol display device 281, it is not necessary to read the image data from the character ROM 187 one by one. Therefore, even if the NAND flash memory 187a is used for the character ROM 187, the third symbol display device 281 You can start the variable effect quickly. Therefore, after the ball enters the first ball entry port 264, the variation effect is immediately started in the third symbol display device 281 even though the variation effect is started in the first symbol display device 237. It is possible to suppress the occurrence of a state that does not occur.

Further, in the third symbol area 435d, as the main symbols without the numbers "0" to "9", the main symbol consisting of the rear symbol such as a wooden box, the rear symbol and the character such as the furoshiki, the helmet, etc. Image data corresponding to the main symbol consisting of the attached symbol imitating the above is also resident. These image data are used for the demonstration effect displayed on the third symbol display device 281 when the next variation effect accompanying the start winning is not started even after a predetermined time has elapsed from the stop of one variation effect. Will be. As a result, when the demo effect is displayed on the third symbol display device 281, the main symbol without a number is displayed as the third symbol in the demo effect. Therefore, the player can easily recognize that the pachinko machine 200 is in the demo state by visually recognizing the main symbol without numbers from the display image of the third symbol display device 281.

Similar to the first embodiment, the character symbol area 435e is an area for storing image data corresponding to the character symbols used in various effects displayed on the third symbol display device 281. In this pachinko machine 200, various characters such as "boy" are displayed according to various effects, and the data corresponding to these is resident in the character symbol area 435e to control the display. When the device 314 changes the character symbol based on the content of the command received from the voice lamp control device 313, the device 314 does not newly read the corresponding image data from the character ROM 434, but instead enters the character symbol area 435e of the resident video RAM 435. By reading out the image data resident in advance, a predetermined image can be drawn by the image controller 437. As a result, it is not necessary to read the corresponding image data from the character ROM 434, so that the character symbol can be changed immediately even if the NAND flash memory 434a having a slow read speed is used for the character ROM 434.

The error message image area 435f is an area for storing image data corresponding to an error message displayed when an error occurs in the pachinko machine 200, similarly to the error message image area 189e of the first embodiment. In the pachinko machine 200, when vibration is detected by the voice lamp control device 313 from the output of the vibration sensor 428 attached to the back surface of the game board 213, the voice lamp control device 313 displays the occurrence of a vibration error by an error command. Notify 314. Further, even when the occurrence of other errors is detected by the voice lamp control device 313, the voice lamp control device 313 notifies the display control device 314 of the occurrence of the error together with the error type by an error command. When the display control device 314 receives an error command, the display control device 314 is configured to display an error message corresponding to the received error on the third symbol display device 281.

Here, from the viewpoint of preventing fraud of the player and protecting the player against the error, the error message is required to be displayed almost at the same time as the occurrence of the error. In the pachinko machine 200, image data corresponding to various error messages is resident in advance in the error message image area 435f, so that the display control device 314 has an error message of the resident video RAM 435 based on the received error command. By reading out the image data resident in the image area 435f in advance, each error message image can be immediately drawn by the image controller 437. As a result, it is not necessary to read the image data corresponding to the sequential error message from the character ROM 435. Therefore, even if the NAND flash memory 434a having a slow read speed is used for the character ROM 434, the corresponding error message is sent after receiving the error command. It can be displayed immediately.

The normal video RAM 436 is used so that data is overwritten and updated at any time, like the normal video RAM 190 of the first embodiment, and has an image storage area 436a, a first frame buffer 436b, and a second frame buffer 436c. Is provided at least.

The image storage area 436a is an area for storing image data that is not resident in the resident video RAM 435 among the image data necessary for drawing an image to be displayed on the third symbol display device 281. The image storage area 436a is divided into a plurality of sub-areas, and the type of image data stored in the sub-area is predetermined for each sub-area.

Among the image data not resident in the resident video RAM 435, the MPU 431 collects the image data required for subsequent image drawing from the character ROM 434 in the sub area provided in the image storage area 436a of the normal video RAM 436. , Instruct the image controller 437 to transfer the type of the image data to a predetermined sub-area to be stored. As a result, the image controller 437 reads the image data instructed by the MPU 431 from the character ROM 434 and transfers the read image data to a designated predetermined sub-area of the image storage area 436a via the buffer RAM 437a.

The transfer instruction of the image data is performed by including the transfer data information in the drawing list described later in which the MPU 431 instructs the image controller 437 to draw the image. As a result, the MPU 431 can give an image drawing instruction and an image data transfer instruction only by transmitting the drawing list to the image controller 437, so that the processing load can be reduced.

The first frame buffer 436b and the second frame buffer 436c are buffers for developing an image to be displayed on the third symbol display device 281. The image controller 437 writes an image for one frame drawn according to the instruction from the MPU 431 into the frame buffer of either the first frame buffer 436b or the second frame buffer 436c, thereby writing one frame in the frame buffer. While expanding the image and expanding the image in one of the frame buffers, the image information for one frame previously expanded is read from the other frame buffer, and the drive signal and the third symbol display device 281 are displayed. By transmitting the image information, the process of displaying the image for one frame on the third symbol display device 281 is executed.

In this way, by providing two frame buffers, the first frame buffer 436b and the second frame buffer 436c, the image controller 437 expands the image for one frame drawn in one frame buffer and simultaneously expands the image. The image for one frame previously expanded can be read from the other frame buffer, and the read image for one frame can be displayed on the third symbol display device 281.

The frame buffer that expands the image for one frame and the frame buffer for reading the image information for one frame in order to display the image on the third symbol display device 281 are the drawing process of the image for one frame. Every 20 milliseconds to complete, the MPU 431 alternately specifies one of the first frame buffers 436b and the second frame buffer 436c, respectively.

That is, at a certain timing, the first frame buffer 436b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 436c is designated as the frame buffer for reading the image information for one frame. When the drawing process and the display process are executed, the second frame buffer 436c is designated as a frame buffer for expanding the image for one frame 20 milliseconds after the drawing process for the image for one frame is completed, and one frame is specified. The first frame buffer 436b is designated as the frame buffer from which the image information of the above is read. As a result, the image information of the image previously expanded in the first frame buffer 436b can be read out and displayed on the third symbol display device 281, and at the same time, a new image is expanded in the second frame buffer 436c. To.

Then, after the next 20 milliseconds, the first frame buffer 436b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 436c is designated as the frame buffer for reading the image information for one frame. Will be done. As a result, the image information of the image previously expanded in the second frame buffer 436c can be read out and displayed on the third symbol display device 281, and at the same time, a new image is expanded in the first frame buffer 436b. To. After that, one of the first frame buffer 436b and the second frame buffer 436c is used every 20 milliseconds for the frame buffer that expands the image for one frame and the frame buffer for reading the image information for one frame. By alternately specifying the images, it is possible to continuously perform the display processing of the image for one frame in units of 20 milliseconds while performing the drawing processing of the image for one frame.

The work RAM 433 is a memory for storing control programs and fixed value data stored in the character ROM 434, and temporarily storing work data and flags used when executing various control programs by the MPU 431, and is used by the DRAM. It is composed. The work RAM 433 includes a program storage area 433a, a data table storage area 433b, a simple image display flag 433c, a display data table buffer 433d, an additional data table buffer 433e, a transfer data table buffer 433f, a pointer 433g, a drawing list area 433h, and a timing counter. It has at least 433i, a stored image discrimination flag 433j, and a drawing target buffer flag 433k.

The program storage area 433a is an area for storing the control program executed by the MPU 431. When the system reset is released, the MPU 431 reads the control program from the character ROM 434, transfers it to the work RAM 433, and stores it in the program storage area 433a. Then, when all the control programs are stored in the program storage area 433a, the MPU 431 subsequently executes various controls using the control programs stored in the program storage area 433a. As described above, since the work RAM 433 is composed of the DRAM, the read operation is performed at high speed. Therefore, even when the control program is stored in the character ROM 434 configured by the NAND flash memory 434a having a slow read speed, the display control device 314 can maintain high processing performance, and the third symbol display device 281 can be maintained. Can be used to easily perform diversified and complicated productions.

The data table storage area 433b is a display data table in which display contents to be displayed on the third symbol display device 281 with the passage of time are described for one effect to be displayed based on a command from the main control device 310, and a main control. For the effect to be displayed on the third symbol display device 281 in addition to one effect based on the command from the device 310, it is displayed by the additional data table and the display data table that describe the display contents to be displayed with the passage of time. This is an area for storing transfer data information of image data that is not resident in the resident video RAM 435 and a transfer data table that defines transfer timing among the image data used in the production.

These data tables are usually stored as a type of fixed value data in the second program storage area 434 provided in the NAND flash memory 434a of the character ROM 434, and are stored according to the boot program executed by the MPU 431 after the system reset is released. , These data tables are transferred from the character ROM 434 to the work RAM 433 and stored in the data table storage area 433b. Then, when all the data tables are stored in the data table storage area 433b, the MPU 431 subsequently controls the display of the third symbol display device 281 using the data table stored in the data table storage area 433b. As described above, since the work RAM 433 is composed of the DRAM, the read operation is performed at high speed. Therefore, even when various data tables are stored in the character ROM 434 configured by the NAND flash memory 434a having a slow read speed, the display control device 314 can maintain high processing performance, and the third symbol display device can be used. By using 281, it is possible to easily carry out a diversified and complicated production.

Here, the details of various data tables will be described. First, the display data table is prepared one by one for each effect mode displayed on the third symbol display device 281 based on the command from the main control device 310. For example, a variable effect and a demo effect. , A display data table corresponding to the final display effect and the restart effect is prepared.

As described above, the demo effect is displayed on the third symbol display device 281 when the next variation effect accompanying the start winning is not started even after a predetermined time has elapsed from the stop of one variation effect. The third symbol consisting of the main symbols without the numbers "0" to "9" is stopped and displayed, and only the rear image changes. If the demonstration effect is displayed on the third symbol display device 281, the player or the person involved in the hall can recognize that the pachinko machine 200 is not playing a game.

Further, the final display effect is a third symbol display device when the stop symbol is confirmed and displayed by receiving a confirmation command (display confirmation command) from the main control device 310 via the voice lamp control device 313 after the fluctuation effect. It is an effect displayed on 281. For example, if the stop symbol is a missed symbol, an effect of emphasizing the miss is performed, and if the stop symbol is either a 15R probability variation jackpot, a 15R normal jackpot, or a 2R probability variation jackpot, each jackpot is emphasized. The production is done. By visually recognizing this definite display effect, the player can easily determine the game value given by the content of the stop symbol.

Further, the restart effect is centered on the predetermined position when the confirmation command transmitted from the main control device 310 is not received even after a predetermined time has elapsed from the stop display of the third symbol with the end of the variation effect. This is an effect of displaying an image of the third symbol vibrated (oscillated) on the third symbol display device 281. When the player visually recognizes that the third symbol is vibrated and displayed after the fluctuation of the third symbol is stopped and displayed on the third symbol display device 281, the stopped symbol is not determined at that time. Can be recognized.

In the data table storage area 433b, one display data table corresponding to the demo effect, the final display effect, and the restart effect is stored. Further, as the variation display data table, which is a display data table for variation effect, if there are 32 patterns of variation effect patterns to be set, one table is prepared for one variation effect pattern, for a total of 32 tables.

Further, when the variation effect pattern instructed by the main control device 310 via the voice lamp control device 313 and the stop symbol to be displayed at the time of stop display of the variation effect do not match in the variation display data table, for example, the variation is displayed. A display pattern table for special variation is also prepared, which is used when the stop symbol of the deviation is instructed by the main control device 310 when the effect pattern is a variation effect pattern for hitting. This special variation causes the third symbol to be variablely displayed at high speed until the confirmation command (display confirmation command) transmitted from the main control device 310 via the voice lamp control device 313 is received, and the confirmation command is received. A special stop symbol (for example, a symbol displayed as "3", "4", or "1" in order from the left column) is determined as a stop symbol.

When the variation effect pattern instructed by the main control device 310 via the voice lamp control device 313 and the stop symbol to be displayed at the time of stop display of the variation effect do not match, the display control device 314 sets the line in the main control device 310. There is a risk that it will not be possible to accurately reflect the results of the lottery and perform variable effects and definite display effects. On the other hand, in the pachinko machine 200, in such a case, a special variation effect is performed, and after the variation display, a special stop symbol indicating a special deviation is confirmed and displayed on the third symbol display device 281. Even if the result of the lottery in 310 is wrong, it is possible to prevent the third symbol display device 281 from erroneously performing a definite display effect of the jackpot. Further, even if the special stop symbol is confirmed and displayed on the third symbol display device 281, if the lottery result in the main control device 310 is a big hit, the actual gaming state in the pachinko machine 200 shifts to the special gaming state. The person can continue the game with peace of mind. Further, by setting the confirmation display to a special stop symbol, it is possible to suggest to the player that the pachinko machine 200 may be in a big hit state even if the confirmation display is off. Even though the confirmation display is off, the pachinko machine 200 is in a big hit state, so that the player does not feel uneasy.

Here, the details of the display data table will be described with reference to FIG. 57. FIG. 57 is a schematic diagram schematically showing an example of a variable display data table among the display data tables. The display data table should be displayed at the time corresponding to the address represented by the time (20 milliseconds in this embodiment) in which the image for one frame is displayed on the third symbol display device 281 as one unit. It defines in detail the content (drawing content) of the image for one frame.

In the drawing content, the type of sprite is specified for each sprite that is a display object that constitutes an image for one frame, and the display position coordinates, enlargement ratio, rotation angle, and translucency are specified according to the type of sprite. Drawing information for causing the third symbol display device 281 to draw a sprite, such as a value, α blending information, color information, and filter designation information, is defined.

The type of sprite is information for specifying the sprite to be displayed. The display position coordinates are information for specifying the coordinates on the third symbol display device 281 to display the sprite. The enlargement ratio is information for designating the enlargement ratio with respect to the standard display size preset for the sprite, and the size of the sprite displayed according to the enlargement ratio is specified. If the magnification is greater than 100%, the sprite will be enlarged and displayed, and if the magnification is less than 100%, the sprite will be smaller than the standard size. Is displayed.

The rotation angle is information for specifying the rotation angle when the sprite is rotated and displayed. The translucency value is for specifying the transparency of the entire sprite, and the higher the translucency value, the more the image displayed on the back side of the sprite can be seen through. The α-blending information is information for specifying a known α-blending coefficient used when performing superposition processing with other sprites. The color information is information for designating the color tone of the sprite to be displayed. Then, the filter designation information is information for designating an image filter to be applied to the sprite when drawing the designated sprite.

In the variable display data table, one back image, nine third symbols (design 1, symbol 2, ...), and light in the image are drawn contents for one frame defined corresponding to each address. Drawing information for each sprite, such as an effect that expresses the insertion of a light, and a character used for various effects such as a boy image and characters, is specified for each address. It should be noted that one or a plurality of information regarding the effect and the character is defined according to the content to be displayed in the frame.

Here, the display position of the rear image is fixed to the entire screen of the third symbol display device 281, and the enlargement ratio, the rotation angle, the translucent value, the α blending information, the color information, and the filter designation information are obtained with respect to the passage of time. Since it is fixed, only the back type, which is information for specifying the type of the back image, is specified in the variable display data table. For this back type, display one of the backs A to C corresponding to the stage selected by the player (either "city stage", "sky stage", or "island stage"), or backside A to. Information that specifies whether to display a rear image different from C is described. Further, as the back surface type, when it is specified to display a back image different from the back surfaces A to C, information for specifying which back image is to be displayed is also described.

When it is specified that any of the back surfaces A to C is to be displayed by the back surface type, the MPU 431 specifies a back image corresponding to the stage designated by the player among the back surfaces A to C as a drawing target. In addition, the range of the rear image to be displayed for the frame is specified with the passage of time. On the other hand, when it is specified to display a back image different from the back images A to C, the back image to be displayed is specified from the back type.

In this embodiment, a case where only the back type is specified as the drawing content of the back image in the display data table will be described. Instead, the back type and the range of the back image corresponding to the back type are described. It may be specified as the position information indicating whether or not the display should be performed. This position information may be, for example, information indicating the elapsed time since the rear image of the range corresponding to the initial position is displayed. In this case, the MPU 431 specifies the range of the back image to be displayed for the frame based on the elapsed time from the display of the back image of the range corresponding to the initial position indicated by the position information.

Further, the position information may be information indicating the elapsed time from the start of drawing the image (or the display of the third symbol display device 281) based on the display data table. In this case, the MPU 431 displayed the range of the rear image to be displayed for the frame at the stage when the drawing of the image (or the display of the third symbol display device 281) was started based on the display database. It is specified based on the position of the rear image and the elapsed time from the start of drawing (or the display of the third symbol display device 281) of the image indicated by the position information.

Further, the position information is information indicating the elapsed time since the rear image of the range corresponding to the initial position is displayed and the drawing of the image based on the display data table (or the third symbol display device 281) according to the rear type. It may indicate any of the information indicating the elapsed time since the start of the display), and the type information of the position information (for example, the range corresponding to the initial position) together with the back type and the position information. It is information indicating the elapsed time since the rear image is displayed, or information indicating the elapsed time since the drawing of the image based on the display database (or the display of the third symbol display device 281) is started. Information indicating that) may be specified as the drawing content of the back image. In addition, the position information may not be information indicating the elapsed time, but may be information indicating an address in which the range of the rear image to be displayed is stored.

In the third symbol (design 1, symbol 2, ...), the symbol type offset information is described as the symbol type information for specifying the third symbol to be displayed. This offset information is information representing the difference between the numbers attached to each third symbol. Instead of directly specifying the type of the third symbol, the offset information is specified because the display of the third symbol in the variation effect is the stop symbol of the variation effect that was performed immediately before and the variation effect that is performed this time. This is because it changes according to the stop symbol, and in the symbol offset information from the start of the fluctuation to the lapse of a predetermined time, the offset information from the stop symbol of the variation effect performed immediately before is described. As a result, the variation effect is started from the stop symbol in the previous variation effect.

On the other hand, after a predetermined time has elapsed from the start of the fluctuation, the offset from the stop symbol set according to the stop type command (display stop type command) received from the main control device 310 via the voice lamp control device 313. Describe the information. As a result, the variation effect can be stopped at the stop symbol corresponding to the stop type designated by the main control device 310.

Since each third symbol has a unique number, the third symbol can be the variation symbol in the previous variation effect or the stop symbol according to the stop type specified by the main control device 310. By managing by the numbers attached to and expressing the offset information by the difference of the numbers attached to each third symbol, it is possible to easily specify the third symbol to be displayed from the offset information.

Further, in the symbol offset information, the third symbol fluctuates at high speed for a predetermined time during which the offset information of the stop symbol of the fluctuation effect performed immediately before is switched to the offset information of the stop symbol of the variation effect performed this time. It is set to be the displayed time. While the third symbol is variablely displayed at high speed, the third symbol is invisible to the player. Therefore, during that time, the stop symbol of the variation effect performed immediately before the symbol offset information is displayed. By switching from the offset information to the offset information of the stop symbol of the fluctuation effect performed this time, even if the continuity of the numbers of the third symbol is interrupted, the player is prevented from recognizing the interruption of the continuity of the numbers. be able to.

"Start" information indicating the start of the data table is described in "0000H" which is the start address of the display data table, and the data table is described in the final address of the display data table ("02F0H" in the example of FIG. 57). "End" information indicating the end of is described. Then, for each address between the address "0000H" in which the "Start" information is described and the address in which the "End" information is described, the drawing content corresponding to the effect mode to be specified in the display data table is obtained. Is described.

The MPU 431 selects a display data table to be used according to a command (for example, a display variation pattern command) transmitted from the voice lamp control device 313 based on a command or the like from the main control device 310, and displays the selected display. The data table is read from the data table storage area 433b, stored in the display data table buffer 433d, and the pointer 433g is initialized. Then, each time the drawing process for one frame is completed, the pointer 433g is added by 1, and in the display data table stored in the display data table buffer 433d, based on the drawing content defined by the address indicated by the pointer 433g, the next The image content to be drawn is specified, and a drawing list (see FIG. 60) described later is created. By transmitting this drawing list to the image controller 437, the drawing instruction of the image is given. As a result, the drawing contents are specified in the order specified in the display data table according to the update of the pointer 433g, so that the image as specified in the display data table is displayed on the third symbol display device 281.

As described above, in the pachinko machine 200, in the display control device 314, the display control device 314 responds to a command (for example, a display variation pattern command) transmitted from the voice lamp control device 313 based on a command or the like from the main control device 310. Instead of changing the program to be executed by the MPU 431, the effect image to be displayed on the third symbol display device 281 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 433d. ..

Here, when the program executed by the MPU 431 is activated every time the effect image displayed on the third symbol display device 281 is changed like the conventional pachinko machine, the effect image is diversified. Since a large load is applied to the complicated and enormous process of starting and executing a program, the processing capacity of the display control device 314 may be limited, and the diversification of controllable production images may be limited. there were. On the other hand, in the pachinko machine 200, the effect image to be displayed on the third symbol display device 281 can be changed by a simple operation of appropriately replacing the display data table with the display data table buffer 433d. Regardless of the processing capacity of the control device 314, various types of effect images can be displayed on the third symbol display 281.

Further, in this way, a display data table is prepared corresponding to each effect mode, a display data table buffer is set according to the effect mode to be displayed, and a drawing list is drawn frame by frame according to the set data table. This can be created because, in the pachinko machine 200, the effect to be displayed on the third symbol display device 281 is determined in advance based on the result of the lottery performed based on the start winning prize. On the other hand, in game machines other than gaming machines such as pachinko machines, the display contents change on the spot based on the user's operation, so the display contents cannot be predicted. It is not possible to have a display data table corresponding to the effect mode. In this way, a display data table is prepared corresponding to each effect mode, a display data table buffer is set according to the effect mode to be displayed, and a drawing list is created frame by frame according to the set data table. This configuration can only be realized based on the configuration in which the pachinko machine 200 determines in advance the effect mode to be displayed on the third symbol display device 281 based on the result of the lottery performed based on the start winning prize.

Then, with reference to FIG. 58, the details of the additional data table will be described. FIG. 58 is a schematic diagram schematically showing an example of an additional data table. As described above, the additional data table describes the display contents to be displayed with the passage of time for the effect to be displayed on the third symbol display device 281 in addition to the effect based on the command from the main control device 310. It was done. Here, "adding to one effect" means changing the display content of one effect based on a command from the main control device 310, for example, displaying an image that is not normally displayed in one effect. It includes the concept of displaying another effect on top of that one effect, changing the color tone of a part or all of the one effect, and changing the image displayed in one effect. ..

That is, the additional data table is a drawing content necessary for adding and displaying an image that is not normally displayed for one effect displayed by the display data table selected based on the command from the main control device 310. , The drawing content required to change the color tone of a part or all of the one effect, and the drawing content required to change and display the image displayed in the one effect are defined. Is.

In this embodiment, a continuous notice is additionally displayed for the variation effect displayed by the variation display data table selected based on the variation pattern command (display variation pattern command) from the main control device 310. A case where the display content for displaying the effect is defined by the additional data table will be described.

That is, the additional data table is prepared, for example, in response to the continuous advance notice effect that is additionally set for the variable effect, and specifically, "bubble" and "egg" which are the display modes of the continuous advance notice effect. , "Chicken", "Chicken", and "Chicken group" are stored in the data table storage area 433b.

In this additional data table, the content (drawing content) of an image for one frame to be additionally displayed at the time indicated by the address is specified in detail in correspondence with the address specified in the display data table. In the drawing content, the type of sprite is specified for each sprite that should be additionally displayed in the image for one frame, and the display position coordinates, enlargement ratio, rotation angle, etc. are specified according to the type of sprite. Drawing information for causing the third symbol display device 281 to draw a sprite, such as a semi-transparent value, α-blending information, color information, and filter designation information, is defined.

For example, in the example of FIG. 58, two effects (effect 1, effect 2) and two characters (character 1, character 2) are associated with the address "097H" specified in the display data table, respectively. Sprite type (effect type, character type), display position, enlargement ratio, rotation angle, translucent value, α blending information, color information, and filter specification information are specified. On the other hand, if there is no display object to be additionally displayed at the time indicated by the address specified in the display data table, it means that there is no display object to be added corresponding to the address in the additional data table. Null data is specified (corresponding to the address "0001H" in FIG. 58).

As with the display data table, "Start" information indicating the start of the data table is described in "0000H", which is the start address of the additional data table, and the final address of the additional data table (in the example of FIG. 58, in the example of FIG. 58). In "00FDH"), "End" information indicating the end of the data table is described. Then, for each address between the address "0000H" in which the "Start" information is described and the address in which the "End" information is described, the drawing content corresponding to the effect mode to be specified in the additional data table is obtained. Is described.

When the MPU 431 receives a continuous advance notice command from the voice lamp control device 313, the MPU 431 reads an additional data table corresponding to the continuous advance notice mode indicated by the continuous advance notice command from the data table storage area 433b, and reads an additional data table of the work RAM 433 described later. It is stored in the buffer 433e. Then, each time the pointer 433g is updated, the drawing content defined by the address indicated by the pointer 433g is obtained from the display data table stored in the display data table buffer 433d and the additional data table stored in the additional data table buffer 433e. A drawing list (see FIG. 60), which will be described later, is created by specifying and then specifying the image content to be drawn.

For example, in the example of FIG. 58, when the pointer 433g becomes "097H", the MPU 431 is specified in the address "097H" of the additional data table in various sprites specified in the address "097H" of the display data table. Each sprite of the effect 1, effect 2, character 1, and character 2 is added to create a drawing list, and the image controller 437 is instructed to draw the image. On the other hand, when the pointer 433g is "0001H", since the Null data is specified in the address "0001H" of the additional data table, it is determined that there is no display object to be added, and the address of the display data table "0001H". A drawing list is generated based on various sprites specified in "0001H". Further, when the information specified by the address indicated by the pointer 433g in the additional data table is "End" information, or when the pointer 433g indicates an address not specified in the additional data table (for example,). , In the example of FIG. 58, when the pointer 433g indicates an address after "00FEH"), it is determined that there is no display object to be added, and drawing is performed based on various sprites specified in the display data table. Generate a list.

Then, by transmitting the generated drawing list to the image controller 437, the drawing instruction of the image is given. As a result, according to the update of the pointer 433g, the drawing contents are specified in the order specified in the display data table, and the drawing contents specified in the additional data table are added. Therefore, the display data table and the additional data table are used. The specified image is displayed on the third symbol display device 281.

As described above, in the pachinko machine 200, in the display control device 314, a command (for example, a display variation pattern command) transmitted from the voice lamp control device 313 based on a command from the main control device 310 or the like is used. 3 When an effect image to be displayed on the symbol display device 281 (for example, a variable effect image) is added to display another effect image (for example, a continuous advance notice effect image), the other effect to be additionally displayed is displayed. By setting the additional data table corresponding to the image in the additional data table buffer 433e, the effect image can be easily added to the base effect image and displayed. As a result, for example, when there are 32 types of original effect images and there are 5 types of other effect images to be additionally displayed, a display in which an image in which other effect images are superimposed for each original effect image is defined. If a data table is prepared separately, 32 x (1 + 5) = 192 types of display data tables must be prepared, but a data table corresponding to other production images such as this pachinko machine 200 is used as an additional data table. By separately specifying, 32 + 5 = 37 types of displays and additional data tables may be prepared, and the capacity increase of the data table storage area 433b can be suppressed. Therefore, it is possible to store the data table corresponding to various aspects of the effect within the capacity prepared in the data table storage area 433b, and it is possible to easily further diversify the effect image.

Further, by defining another effect image to be additionally displayed as an additional data table as in the pachinko machine 200, after setting the display data table corresponding to the original effect image in the display data table buffer 433d, Even if it is decided to display another effect image to be additionally displayed, an additional data table corresponding to the other effect image is added without changing the display data table set in the display data table buffer 433d. By simply setting the data table buffer 433e, other effect images to be added and displayed can be added to the original effect image and easily displayed.

Further, since the additional data table is configured to have the same data structure as the display data table, the display data table set in the display data table buffer 433d and the additional data set in the additional data table buffer 433e. While updating the pointer 433g every hour from the table, the drawing contents specified by the address indicated by the pointer can be easily specified, and one drawing list corresponding to one frame can be easily specified from these. Can be generated in. Therefore, even if the display of other effects is determined by the voice lamp control device 313 or the like in addition to the effects performed based on the command from the main control device 310, the effects to be additionally displayed are to be displayed. By defining the display contents in the additional data table, it is possible to easily perform a wide variety of effect display from a small number of data tables.

Next, the details of the transfer data table will be described with reference to FIG. 59. FIG. 59 is a schematic diagram schematically showing an example of a transfer data table. The transfer data table is prepared corresponding to the display data table prepared for each effect, and as described above, among the sprite image data used in the effect specified by the display data table, the transfer data table is prepared. The transfer data information for transferring the image data not resident in the resident video RAM 435 from the character ROM 434 to the image storage area 436a of the normal video RAM 436, and the transfer timing thereof are specified.

If all the sprite image data used in the effect specified in the display data table is stored in the resident video RAM 435, the transfer data table corresponding to the display data table is not prepared. As a result, it is possible to suppress an increase in the capacity of the data table storage area 433b.

The transfer data table corresponds to the address specified in the display data table, and the transfer data information of the sprite image data (hereinafter referred to as "transfer target image data") to start the transfer at the time indicated by the address. Is described (corresponding to the addresses "0001H" and "097H" in FIG. 59). Here, the transfer start timing of the transfer target image data is set so that the image data corresponding to the predetermined sprite is stored in the image storage area 436a by the time the drawing of the predetermined sprite is started according to the display data table. In the transfer data table, the transfer data information of the image data to be transferred is defined in correspondence with the address corresponding to the transfer start timing.

On the other hand, if there is no transfer target image data to start transfer at the time indicated by the address specified in the display data table, there is no transfer target image data to start transfer corresponding to that address. Null data is defined (corresponding to the address "0002H" in FIG. 59).

The transfer data information includes the start address (storage source start address) and final address (storage source final address) of the character ROM 434 in which the transfer target image data is stored, and the start address of the transfer destination (normal video RAM 436). Is included.

As with the display data table, "Start" information indicating the start of the data table is described in "0000H", which is the start address of the transfer data table, and the final address of the transfer data table (in the example of FIG. 59, in the example of FIG. 59). In "02F0H"), "End" information indicating the end of the data table is described. Then, for each address between the address "0000H" in which the "Start" information is described and the address in which the "End" information is described, the transfer data information of the image data to be transferred that should be specified in the transfer data table. Is described.

When the MPU 431 selects a display data table to be used according to a command (for example, a display variation pattern command) transmitted from the voice lamp control device 313 based on a command or the like from the main control device 313, the display data table is selected. If the transfer data table corresponding to the above exists, the transfer data table is read from the data table storage area 433b and stored in the transfer data table buffer 433f of the work RAM 433 described later. Then, each time the pointer 433g is updated, the drawing content defined by the address indicated by the pointer 433g is obtained from the display data table stored in the display data table buffer 433d and the additional data table stored in the additional data table buffer 433e. The drawing list (see FIG. 60) to be specified and described later is created, and the transfer data information of the image data of the predetermined sprite to be transferred from the transfer data table stored in the transfer data table buffer 433f at that time. And add the transfer data information to the created drawing list.

For example, in the example of FIG. 59, when the pointer 433g becomes "0001H" or "097H", the MPU 431 transfers the transfer data information specified at the address in the transfer data table to the display data table and the additional data table. It is added to the drawing list created based on the above, and the added drawing list is transmitted to the image controller 437. On the other hand, when the pointer 433g is "0002H", since the Null data is specified in the address "0002H" of the transfer data table, it is determined that there is no transfer target image data to start the transfer, and the data is generated. The drawing list is transmitted to the image controller 437 without adding the transfer data information to the drawing list.

Then, when the transfer data information is described in the drawing list received from the MPU 431, the image controller 437 transfers the transfer target image data from the character ROM 434 to a predetermined sub-area of the image storage area 436a according to the transfer data information. Execute the process to be performed.

Here, as described above, in the transfer data table, the image data corresponding to the predetermined sprite is stored in the image storage area 436a by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information of the image data to be transferred is specified for a predetermined address, the image data is transferred from the character ROM 434 to the image storage area 436a according to the transfer data information specified in this transfer data table. When drawing a predetermined sprite according to the display data table, the image data that is not resident in the resident video RAM 435 required for drawing the sprite can always be stored in the image storage area 436a. Then, using the image data stored in the image storage area 436a, a predetermined sprite can be drawn based on the display data table.

As a result, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, the image necessary for display can be read in advance from the character ROM 434 and transferred to the normal video RAM 436 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the third symbol display device 281. Further, according to the description in the transfer data table, only the non-resident image data in the resident video RAM 435 can be easily and surely transferred from the character ROM 434 to the normal video RAM 436.

Further, in the pachinko machine 200, in the display control device 314, display data is displayed according to a command (for example, a display variation pattern command) transmitted from the voice lamp control device 313 based on a command or the like from the main control device 313. As the table is set in the display data table buffer 433d, the transfer data table corresponding to the display data table is set in the transfer data table 344d, so that the image data of the sprite used in the display data table is desired. It is possible to reliably transfer data from the character ROM 434 to the normal video RAM 436 at the timing of.

Further, in the transfer data table, the transfer data information is defined so that the image data is transferred from the character ROM 434 to the normal video RAM 436 for each image data corresponding to the sprite. As a result, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 434 to the normal video RAM 436 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

Further, the transfer data table has the same data structure as the display data table, and is associated with the address specified in the display data table, and the transfer of the transfer target image data to be started at the time indicated by the address is transferred. Since the data information is specified, the image data of a predetermined sprite is surely stored in the normal video RAM 436 before the image data of a predetermined sprite is used based on the display data table set in the display data table buffer 433d. As described above, since the transfer start timing can be instructed, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, a wide variety of effect images can be easily displayed on the third symbol display device 281. be able to.

The simple image display flag 433c indicates whether or not to display the power-on images (main image at power-on and variable image at power-on) shown in FIGS. 54 (a) to 54 (c) on the third symbol display device 281. It is a flag to indicate. The simple image display flag 433c is set after the image data corresponding to the power-on main image and the power-on variable image are transferred to the power-on main image area 435a or the power-on variable image area 435b of the resident video RAM. , MPU 431 set to on in the main process (see FIG. 73) (see S2205 in FIG. 73). Then, at the stage where all the resident target image data is stored in the resident video RAM 435 by the resident image transfer process of the image transfer process, the third symbol display device 281 is displayed in order to display an image other than the image at the time of turning on the power. It is set to off (see S3105 in FIG. 85 (b)).

This simple image display flag 433c is referred to in the V interrupt process executed by the MPU 431 every time the V interrupt signal transmitted from the image controller 437 is detected (see S2401 in FIG. 74), and the simple image display flag is referenced. When 433c is on, a simple command determination process (see S2408 in FIG. 74 (b)) and a simple display setting process (FIG. 74 (b) so that the image at power-on is displayed on the third symbol display device 281). ) S2409) is executed. On the other hand, when the simple image display flag 433c is off, the command determination is made so that various images are displayed according to the command transmitted from the voice lamp control device 313 based on the command from the main control device 313 or the like. Processing (see FIGS. 75 to 79) and display setting processing (see FIGS. 80 to 84) are executed.

Further, the simple image display flag 433c is referred to in the transfer setting process executed by the MPU 431 in the V interrupt process (see S3001 in FIG. 85 (a)), and the simple image display flag 433c is turned on. Executes the resident image transfer setting process (see FIG. 85 (b)) for transferring the resident image data from the character ROM 434 to the resident video RAM 435 because the resident image data that is not stored in the resident video RAM 435 exists. When the simple image display flag 433c is off, the normal image transfer setting process (see FIG. 86) for transferring the image data required for the drawing process from the character ROM 434 to the normal video RAM 436 is executed.

The display data table buffer 433d stores a display data table corresponding to an effect mode to be displayed on the third symbol display device 281 according to a command or the like transmitted from the voice lamp control device 313 based on a command or the like from the main control device 313. It is a buffer to do. The MPU 431 determines an effect mode to be displayed on the third symbol display device 281 based on a command or the like transmitted from the voice lamp control device 313, and displays a display data table corresponding to the effect mode from the data table storage area 433b. It is selected and the selected display data table is stored in the display data table buffer 433d. Then, the MPU 431 adds the pointer 433g by 1, and based on the drawing content defined by the address indicated by the pointer 433g in the display data table stored in the display data table buffer 433d, the image controller 437 is used for each frame. A drawing list (see FIG. 60), which will be described later, is generated in which the contents of instructions for drawing an image are described. As a result, the effect corresponding to the display data table stored in the display data table buffer 433d is displayed on the third symbol display device 281.

The additional data table buffer 433e is additionally displayed in addition to the effect displayed on the third symbol display device 281 by the display data table stored in the display data table buffer 433d in response to a command or the like from the voice lamp control device 313. It is a buffer for storing an additional data table corresponding to the effect (continuous notice effect, etc.). The MPU 431 stores the display data table in the display data table buffer 433d, and temporarily writes Null data in the additional data table buffer 433e, which means that there is no display object to be displayed. Clear the contents.

After that, the MPU 431 is an effect of adding to the effect displayed on the third symbol display device 281 by the display data table stored in the display data table buffer 433d based on a command or the like from the voice lamp control device 313. If the presence or absence is determined and there is an effect to be additionally displayed, an additional data table corresponding to the effect mode is selected from the data table storage area 433b, and the selected additional data table is set in the additional data table buffer 433e. Store.

Then, the MPU 431 is stored in the additional data table buffer 433e and the drawing contents specified by the address indicated by the pointer 433g in the display data table stored in the display data table buffer 433d while adding the pointer 433g one by one. Based on the drawing content specified at the address indicated by the pointer 433g in the additional data table, a drawing list (see FIG. 60) described later that describes the instruction content for image drawing to the image controller 437 is generated for each frame. .. As a result, the effect corresponding to the additional data table is additionally displayed on the third symbol display device 281 in addition to the effect corresponding to the display data table. Further, when the additional data table is not stored in the additional data table buffer 433e, since the All data is stored in the additional data table buffer 433e, the third symbol display device 281 has an effect corresponding to the display data table. Is displayed as it is.

The transfer data table buffer 433f is a transfer data table corresponding to the display data table stored in the display data table buffer 433d in response to a command or the like transmitted from the voice lamp control device 313 based on a command or the like from the main control device 313. It is a buffer for storing. The MPU 431 selects a transfer data table corresponding to the display data table from the data table storage area 433b in accordance with storing the display data table in the display data table buffer 433d, and transfers the selected transfer data table. It is stored in the data table buffer 433f. If all the sprite image data used in the display data table stored in the display data table buffer 433d is stored in the resident video RAM 435, the transfer data table corresponding to the display data table is not prepared. Therefore, the MPU 431 clears the contents by writing the Full data which means that the transfer target image data does not exist in the transfer data table buffer 433f.

Then, while adding the pointer 433g one by one, the MPU 431 defines the transfer data information of the transfer target image data specified at the address indicated by the pointer 433g in the transfer data table stored in the transfer data table buffer 433f. If (that is, if the Null data is not described), the transfer data information is added to the later drawing list (see FIG. 60) that describes the instruction content for image drawing to the image controller 437 generated for each frame. to add.

As a result, when the transfer data information is described in the drawing list received from the MPU 431, the image controller 437 transfers the transfer target image data from the character ROM 434 to a predetermined sub-area of the image storage area 436a according to the transfer data information. Execute the process to transfer. Here, as described above, in the transfer data table, the image data corresponding to the predetermined sprite is stored in the image storage area 436a by the time the drawing of the predetermined sprite is started according to the display data table. The transfer data information of the image data to be transferred is specified for a predetermined address. Therefore, when drawing a predetermined sprite according to the display data table by transferring the image data from the character ROM 434 to the image storage area 436a according to the transfer data information specified in the transfer data table, it is necessary to draw the sprite. Image data that is not resident in the resident video RAM 435 can always be stored in the image storage area 436a.

As a result, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, the image necessary for display can be read in advance from the character ROM 434 and transferred to the normal video RAM 436 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the third symbol display device 281. Further, according to the description in the transfer data table, only the non-resident image data in the resident video RAM 435 can be easily and surely transferred from the character ROM 434 to the normal video RAM 436.

The pointer 433g is a drawing content or a transfer target image from the display data table, the additional data table, and the transfer data table stored in the display data table buffer 433d, the additional data table buffer 433e, and the transfer data table buffer 433f, respectively. Data transfer This is to specify the address from which data information should be acquired. The MPU 431 temporarily initializes the pointer 433g to 0 in accordance with the display data table being stored in the display data table buffer 433d. Then, the display setting process of the V interrupt process executed by the MPU 431 based on the V interrupt signal transmitted from the image controller 437 every 20 milliseconds when the drawing process of the image for one frame is completed (S2403 in FIG. 74). (See), the pointer update process (see S2711 in FIG. 80) is executed, and the value of the pointer 433g is added one by one.

The MPU 431 has an address indicated by the pointer 433g from the display data table stored in the display data table buffer 433d and the additional data table stored in the additional data table buffer 433e each time the pointer 433g is updated. A predetermined sprite that should start transfer at that time from the transfer data table stored in the transfer data table buffer 433f while specifying the drawing contents specified in 1 and creating a drawing list (see FIG. 60) described later. Acquires the transfer data information of the image data of, and adds the transfer data information to the created drawing list.

As a result, the effect corresponding to the display data table stored in the display data table buffer 433d is displayed on the third symbol display device 281, and when the additional data table is stored in the additional data table buffer 433e, the effect is displayed. The effect corresponding to the additional data table can be displayed on the third symbol display device 281 in addition to the effect corresponding to the display data table. Therefore, the effect to be displayed on the third symbol display device 281 can be easily changed only by changing the display data table stored in the display data table buffer 433d and the additional data table stored in the additional data table buffer 433e. .. Therefore, a wide variety of effects can be displayed regardless of the processing capacity of the display control device 341.

If the transfer data table stored in the transfer data table buffer 433f is stored, the sprite is drawn by the corresponding display data table based on the transfer data table. Image data that is not resident in the resident video RAM 435 used for drawing can always be stored in the image storage area 436a. As a result, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, the image necessary for display can be read in advance from the character ROM 434 and transferred to the normal video RAM 436 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the third symbol display device 281. Further, according to the description in the transfer data table, only the non-resident image data in the resident video RAM 435 can be easily and surely transferred from the character ROM 434 to the normal video RAM 436.

The drawing list area 433h is generated based on the display data table stored in the display data table buffer 433d, the additional data table stored in the additional data table buffer 433e, and the transfer data table stored in the transfer data table buffer 433e. This is an area for storing a drawing list that instructs the image controller 437 to draw an image for one frame.

Here, the details of the drawing list will be described with reference to FIG. 60. FIG. 60 is a schematic diagram schematically showing the contents of the drawing list. The drawing list is an instruction table instructing the image controller 437 to draw an image for one frame, and as shown in FIG. 60, a rear image used in the image of one frame and a third symbol (designs 1,). Symbol 2, ...), Effect (Effect 1, Effect 2, ...), Character (Character 1, Character 2, ..., Number of reserved balls Design 1, Number of reserved balls Design 2, ..., Error For each sprite such as a design), detailed drawing information (detailed information) of the sprite is described. In addition, transfer data information for transferring predetermined image data from the character ROM 434 to the normal video RAM 436 to the image controller 437 is also described in the drawing list.

The detailed drawing information (detailed information) of each sprite includes information indicating the RAM type (resident video RAM 435 or normal video RAM 436) in which the image data of the corresponding sprite (display object) is stored, and the information thereof. The address is described, and the image controller 437 acquires the image data of the sprite from the memory area specified by the RAM type and the address. Further, the detailed drawing information (detailed information) includes display position coordinates, enlargement ratio, rotation angle, translucent value, α-blending information, color information, and filter specification information, and the image controller 437 includes various types. A standard image generated from the image data of the sprite read from the video RAM is scaled according to the enlargement ratio, rotated according to the rotation angle, and translucent according to the translucency value. Processing is performed, composition processing with other sprites is performed according to the α blending information, color tone correction processing is performed according to the color information, and filtering processing is performed by the method specified by the information according to the filter specification information. Then, the image obtained by performing various processes on the display position indicated by the display position coordinates is drawn. Then, the drawn image is expanded by the image controller 437 into either the first frame buffer 436b or the second frame buffer 436c specified by the drawing target buffer flag 433k.

The MPU 431 is a display data table stored in the display data table buffer 433d and an additional data table stored in the additional data table buffer 433e. Detailed drawing information (detailed information) for all sprites used to draw one frame of image based on the contents of (for example, a hold image displaying a hold ball number symbol, a warning image notifying the occurrence of an error, etc.). ) Is generated, and the detailed information is sorted by sprite to create a drawing list.

Here, among the detailed information of each sprite, the storage RAM type and address of the sprite (display object) data are specified from the sprite type specified in the display data table and the additional data table, and the contents of other images. Generated according to the sprite type. That is, since the area of the resident video RAM 435 in which the image data of the sprite is stored or the sub area of the image storage area 436a of the normal video RAM 436 is fixed for each sprite, the MPU 431 can be used according to the sprite type. Therefore, the storage RAM type and address in which the image data of the sprite is stored can be immediately specified, and such information can be easily included in the detailed information of the drawing list.

Further, the MPU 431 displays a display data table and additional data for other information (display position coordinates, enlargement ratio, rotation angle, translucency value, α-blending information, color information and filter specification information) among the detailed information of each sprite. Copy the information specified in the table as it is.

Further, when generating the drawing list, the MPU 431 rearranges the sprites to be arranged on the back side in the image for one frame in the order of the sprites to be arranged on the front side, and detailed drawing information for each sprite. Describe (detailed information). That is, in the drawing list, detailed information corresponding to the back image is described first, and then the third symbol (design 1, symbol 2, ...), effect (effect 1, effect 2, ...). , Characters (character 1, character 2, ..., Hold ball number symbol 1, hold ball number symbol 2, ..., error symbol), detailed information corresponding to each sprite is described.

The image controller 437 executes the drawing process of each sprite in the order described in the drawing list, and expands the drawn sprites in the frame buffer by overwriting. Therefore, in the image for one frame generated by the drawing list, the sprite drawn first can be arranged on the backmost side, and the sprite drawn last can be arranged on the frontmost side.

Further, when the transfer data information is described in the transfer data table stored in the transfer data table buffer 433f at the address indicated by the pointer 433g, the MPU 431 performs the transfer data information (character in which the transfer target image data is stored). The storage source start address and storage source final address in ROM 434 and the storage destination head address of the sub-area provided in the image storage area 436a to store the transfer target image data) are added to the end of the drawing list. If the drawing list contains this transfer data information, the image controller 437 will image from a predetermined area (the area indicated by the storage source start address and the storage source final address) of the character ROM 434 based on the transfer data information. The data is read out, and the image data to be transferred is transferred to a predetermined sub-area (storage destination address) provided in the image storage area 436a of the normal video RAM 436.

The timekeeping counter 433i is a counter that counts the effect time of the effect displayed on the third symbol display device 281 by the display data table stored in the display data table buffer 433d. The MPU 431 sets time data indicating the effect time of the effect displayed based on the display data table in accordance with storing one display data table in the display data table buffer 433d. This time data is a value obtained by dividing the effect time by the image display time for one frame (20 milliseconds in this embodiment) in the third symbol display device 281.

Then, the V interrupt process executed by the MPU 431 based on the V interrupt signal transmitted from the image controller 437 every 20 milliseconds when the drawing process and the display process of the image for one frame are completed (see FIG. 74). Each time the display setting process of is executed, the time counting counter 433i is decremented by 1 (see S2713 in FIG. 80). As a result, when the value of the timekeeping counter 433i becomes 0 or less, the MPU 431 determines that the effect displayed by the display data table stored in the display data table buffer 433d has ended, and performs the effect in accordance with the end of the effect. Perform various processes to be performed.

The stored image discrimination flag 433j indicates whether the image data corresponding to the sprite is stored in the image storage area 436a of the normal video RAM 436 for all the sprites whose corresponding image data is not resident in the resident video RAM 435. It is a flag indicating the storage state indicating whether or not.

The stored image discrimination flag 433j is generated by the initial setting process (see S2202 in FIG. 73) executed by the MPU 431 in the main process when the power is turned on. The stored image discrimination flag 433j generated here is set to "off" indicating that the stored state for all sprites is not stored in the image storage area 436a.

Then, the stored image discrimination flag 433j is updated when the transfer instruction of the transfer target image data corresponding to one sprite is set in the normal image transfer setting process (see FIG. 86) executed by the MPU 431. .. In this update, the storage state corresponding to one sprite for which the transfer instruction is set is set to "on" indicating that the corresponding image data is stored in the image storage area 436a. Further, the image data of the other sprites that are to be stored in the sub-area of the same image storage area 436a as the one sprite is always in the non-stored state by storing the image data of the one sprite. Therefore, set the storage state corresponding to other sprites to "Off".

Further, the MPU 431 refers to the stored image discrimination flag 433j when transferring the image data of the sprite whose image data is not resident in the resident video RAM 435 from the character ROM 434 to the normal video RAM 436, and refers to the image of the sprite to be transferred. It is determined whether or not the data is already stored in the image storage area 436a of the normal video RAM 435 (see S3216 in FIG. 86). If the storage state corresponding to the sprite to be transferred is "off" and the corresponding image data is not stored in the image storage area 436a, a transfer instruction for the image data is set (see S3217 in FIG. 86). , The image controller 437 is made to transfer the image data from the character ROM 434 to a predetermined sub-area of the image storage area 436a. On the other hand, if the storage state corresponding to the sprite to be transferred is "on", the corresponding image data is already stored in the image storage area 436a, so the transfer process of the image data is stopped. As a result, it is possible to suppress unnecessary transfer from the character ROM 434 to the normal video RAM 436, reduce the processing load in each part of the display control device 314, and reduce the traffic in the bus line 440. can.

The drawing target buffer flag 433k is a frame buffer (hereinafter, "drawing target buffer") that expands the image drawn by the image controller 437 from the two frame buffers (first frame buffer 436b and second frame buffer 436c). When the drawing target buffer flag 433k is 0, the first frame buffer 436b is specified as the drawing target buffer, and when it is 1, the second frame buffer 436c is specified. Then, the information of the designated drawing target buffer is transmitted to the image controller 437 together with the drawing list (see S3302 in FIG. 87).

As a result, the image controller 437 executes a drawing process of expanding the image drawn based on the drawing list on the designated drawing target buffer. Further, the image controller 437 reads the previously expanded drawing image information from the frame buffer different from the drawing target buffer in parallel with the drawing process, and together with the drive signal, the image is displayed on the third symbol display device 281. By transferring the information, a display process for displaying an image on the third symbol display device 281 is executed.

The drawing target buffer flag 433k is updated when the drawing target buffer information is transmitted to the image controller 437 together with the drawing list. This update is performed by inverting the value of the drawing target buffer flag 433k, that is, when the value is "0", it is set to "1", and when the value is "1", it is set to "0". It is done by. As a result, the drawing target buffer is alternately set between the first frame buffer 436b and the second frame buffer 436c each time the drawing list is transmitted. Further, the drawing list is transmitted by the V interrupt executed by the MPU 431 based on the V interrupt signal transmitted from the image controller 437 every 20 milliseconds when the drawing process and the display process of the image for one frame are completed. Each time the drawing process of the process (see FIG. 74) is executed, it is performed (see S3302 in FIG. 87).

That is, at a certain timing, the first frame buffer 436b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 436c is designated as the frame buffer for reading the image information for one frame. When the drawing process and the display process are executed, the second frame buffer 436c is designated as a frame buffer for expanding the image for one frame 20 milliseconds after the drawing process for the image for one frame is completed, and one frame is specified. The first frame buffer 436b is designated as the frame buffer from which the image information of the above is read. As a result, the image information of the image previously expanded in the first frame buffer 436b can be read out and displayed on the third symbol display device 281, and at the same time, a new image is expanded in the second frame buffer 436c. To.

Then, after the next 20 milliseconds, the first frame buffer 436b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 436c is designated as the frame buffer for reading the image information for one frame. Will be done. As a result, the image information of the image previously expanded in the second frame buffer 436c can be read out and displayed on the third symbol display device 281, and at the same time, a new image is expanded in the first frame buffer 436b. To. After that, one of the first frame buffer 436b and the second frame buffer 436c is used every 20 milliseconds for the frame buffer that expands the image for one frame and the frame buffer for reading the image information for one frame. By alternately specifying the images, it is possible to continuously perform the display processing of the image for one frame in units of 20 milliseconds while performing the drawing processing of the image for one frame.

Next, each control process executed by the MPU 401 in the main control device 310 will be described with reference to the flowcharts of FIGS. 61 to 67. The processing of the MPU 401 is roughly divided into a start-up process that is started when the power is turned on, a main process that is executed after the start-up process, and a timer that is started periodically (in this embodiment, at a cycle of 2 ms). There are an interrupt process and an NMI interrupt process that is activated by inputting the power failure signal SG1 to the NMI terminal. For convenience of explanation, the timer interrupt process and the NMI interrupt process are explained first, and then the start-up process is performed. The main process will be explained.

FIG. 61 is a flowchart showing a timer interrupt process executed by the MPU 401 in the main control device 310. The timer interrupt process is, for example, a periodic process executed every 2 milliseconds. In the timer interrupt processing, first, the reading processing of various winning switches is executed (S1101). That is, the state of various switches connected to the main control device 310 is read, the state of the switch is determined, and the detection information (winning detection information) is stored.

Next, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are updated (S1102). Specifically, the first initial value random number counter CINI1 is added by 1, and when the counter value reaches the maximum value (899 in this embodiment), it is cleared to 0. Then, the updated value of the first initial value random number counter CINI1 is stored in the corresponding buffer area of the RAM 403. Similarly, the second initial value random number counter CINI2 is added by 1, and when the counter value reaches the maximum value (250 in this embodiment), it is cleared to 0 and the updated value of the second initial value random number counter CINI2. Is stored in the corresponding buffer area of the RAM 403.

Further, the first random number counter C1, the first type counter C2, the stop pattern selection counter C3, and the second random number counter C4 are updated (S1103). Specifically, the first random number counter C1, the first type counter C2, the stop pattern selection counter C3, and the second random number counter C4 are each added by 1, and their counter values are the maximum values (in the present embodiment). When it reaches 899, 9, 99, 250), it clears to 0, respectively. Then, the updated values of the counters C1 to C4 are stored in the corresponding buffer area of the RAM 403.

Next, a process for displaying by the first symbol display device 237 and a variation process for setting a variation pattern of the third symbol by the third symbol display device 281 are executed (S1104), and then the first ball entry port is executed. The start winning process accompanying the winning of 264 is executed (S1105). The details of the variation processing and the start winning processing will be described later with reference to FIGS. 62 and 64, respectively.

After the start winning process is executed, the launch control process is executed (S1106), and other processes to be executed periodically are executed (S1107) to end the timer interrupt process. The launch control process detects that the player is touching the operation handle 251 by the touch sensor 251a, and launches the ball on condition that the stop switch 251b for stopping the launch is not operated. It is a process of determining on / off of. The main control device 310 instructs the launch control device 312 to launch the ball when the launch of the ball is on.

Next, with reference to FIG. 62, the variation processing (S1104) executed by the MPU 401 in the main controller 310 will be described. FIG. 62 is a flowchart showing this variation processing (S1104). This variation processing (S1104) is executed in the timer interrupt processing (see FIG. 61), and controls the variation display performed by the first symbol display device 237 and the third symbol display device 281.

In this fluctuation processing, first, it is determined whether or not the jackpot is currently being hit (S1201). The jackpot includes the middle of the jackpot game displayed by the third symbol display device 281 and the first symbol display device 237 at the time of the jackpot, and the middle of a predetermined time after the jackpot game is completed. As a result of the determination, if the jackpot is in progress (S1201: Yes), the present process is terminated as it is.

If it is not a big hit (S1201: No), it is determined whether or not the display mode of the first symbol display device 237 is changing (S1202), and if the display mode of the first symbol display device 237 is not changing. (S1202: No), then, it is determined whether or not a predetermined time has elapsed after the fluctuation display in the first symbol display device 237 is stopped (S1203). As a result, if a predetermined time has not elapsed after the fluctuation is stopped (S1203: No), this process is terminated as it is. As a result, the stop symbol in the variation effect is displayed on the first symbol display device 237 and the third symbol display device 281 for a predetermined time, so that the player can visually recognize the stop symbol.

On the other hand, as a result of the processing of S1204, if a predetermined time has elapsed after the fluctuation is stopped (S1203: Yes), the value of the reserved ball counter 403a (the number of reserved balls N of the variable display held in the main control device 310). Is greater than 0 (S1204), and if the value of the hold ball counter 403a (hold ball number N) is not 0 (S1204: Yes), the value of the hold ball counter 403a (hold ball number). N) is subtracted by 1 (S1205), and the data stored in the reserved ball storage area is shifted (S1206). This data shift process is a process of sequentially shifting the data stored in the hold 1st to 4th areas of the hold ball storage area to the execution area side, and is a process of sequentially shifting the hold 1st area → execution area, hold 2nd area →. The data in each area is shifted such as the hold 1st area, the hold 3rd area → the hold 2nd area, the hold 4th area → the hold 3rd area, and so on. After the data shift processing, the fluctuation start processing of the first symbol display device 237 is executed (S1207). The fluctuation start processing will be described later with reference to FIG. 63.

In the process of S1204, when it is determined that the value (number of reserved balls N) of the reserved ball number counter 403a is 0 (S1204: No), a state in which the demonstration effect is being performed on the third symbol display device 281, that is, , Determining whether or not the demo is in progress (S1208). In this discrimination process, after the demo command is transmitted to the display control device 314 via the voice lamp control device 313, until it is determined that the value of the hold ball number counter 403a (hold ball number N) is larger than 0. Determine the interval as being demoed.

Then, if it is determined that the demo is not in progress (S1208: No), a demo command is set (S1212), this process is terminated, and if it is determined that the demo is in progress (S1208: Yes). This process ends as it is. The demo command set in the process of S1212 is stored in the ring buffer for command transmission provided in the RAM 403, and is executed in the external output process (S1701) of the main process (see FIG. 67) described later, which is executed by the MPU 401. , Is transmitted toward the voice lamp control device 313. The voice lamp control device 313 transmits this demo command as it is to the display control device 314, and the display control device 314 controls to display the demo effect on the third symbol display device 281 according to this demo command.

Here, the demo command is set when, as described above, there is no reserved ball when a predetermined time has elapsed after the fluctuation has stopped. Therefore, when the fluctuation display is not started when a predetermined time has elapsed after the fluctuation is stopped, the demo command can be set and the demo effect can be displayed on the third symbol display device 281.

In the process of S1202, when it is determined that the display mode of the first symbol display device 237 is changing (S1202: Yes), it is determined whether or not the fluctuation time has elapsed (S1210). The display time during fluctuation of the first symbol display device 237 is determined according to the fluctuation pattern selected by the fluctuation type counter CS1 (determined according to the fluctuation pattern command), and this fluctuation time has elapsed. If not (S1210: No), the display of the first symbol display device 237 is updated (S1211), and this process is terminated.

In the present embodiment, among the LEDs 237a of the first symbol display device 237, from the start of the fluctuation until the fluctuation time elapses, for example, if the currently lit LED is red, the red LED is turned off. At the same time, turn on the green LED, if the green LED is on, turn off the green LED and turn on the blue LED, and if the blue LED is on, turn off the blue LED. At the same time, the display mode for turning on the red LED is set.

The variation processing is executed every 2 milliseconds, but if the LED lighting color is changed each time the variation processing is executed, the player cannot confirm the change in the LED lighting color. Therefore, a counter (not shown) is counted by 1 each time the fluctuation process is executed so that the player can confirm the change in the lighting color of the LED, and when the counter reaches 200, the LED is displayed. Change the lighting color of. That is, the lighting color of the LED is changed every 0.4 s. The value of the counter is reset to 0 when the lighting color of the LED is changed.

On the other hand, if the fluctuation time of the first symbol display device 237 has elapsed (S1210: Yes), the display mode corresponding to the stopped symbol of the first symbol display device 237 is set (S1212). The stop symbol is set in advance by the fluctuation start process (S1207) described later with reference to FIG. 63. That is, by the processing of S1206, whether or not it is a big hit is determined according to the value of the first random number counter C1 stored in the execution area of the reserved ball storage area, and if it is a big hit, the first hit type counter. Depending on the value of C2, a symbol that becomes a 15R probability variation jackpot after a jackpot (a probability variation jackpot that shifts to a high probability state after a jackpot with a maximum number of 15 rounds) or a 2R probability variation jackpot (a probability variation state after a jackpot with a maximum number of rounds of 2 rounds) It is determined whether the symbol is a probability variable jackpot to be transferred or a time-saving jackpot (a jackpot that shifts to a low probability state after a jackpot with a maximum number of 15 rounds).

In the present embodiment, the blue LED is turned on when the 15R probability variation jackpot is reached after the jackpot, the red LED is turned on when the 2R probability variation jackpot is reached, and the red LED and the blue LED are turned on when the time saving jackpot is reached. Turn on the LED. If it is off, the red LED and the green LED are turned on. The display of each LED is turned off when the next fluctuation display is started, but it may be turned on only for a few seconds after the fluctuation is stopped.

When the display mode of the first symbol display device 237 corresponding to the stop symbol is set in the process of S1212, the stop symbol of the variation effect of the third symbol display device 281 is synchronized with the lighting of the LED in the first symbol display device 237. A confirmation command is set (S1213) to confirm the process, and this process ends. Upon receiving this confirmation command, the voice lamp control device 313 transmits the confirmation command to the display control device 314 as it is. The third symbol display device 281 stops the fluctuation when the fluctuation time elapses, and by receiving the confirmation command, the stop symbol in the third symbol display device 281 is confirmed.

Next, with reference to FIG. 63, the fluctuation start processing (S1207) executed by the MPU 401 in the main control device 310 will be described. FIG. 63 is a flowchart showing the fluctuation start processing (S1207). This fluctuation start processing (S1207) is executed in the fluctuation processing (see FIG. 62) of the timer interrupt processing (see FIG. 61), and is based on the values of various counters stored in the execution area of the reserved ball storage area. A "big hit" or "missing" lottery (win / fail determination) is performed, and an effect pattern (variation effect pattern) of the variation effect performed by the first symbol display device 237 and the third symbol display device 281 is determined.

In the fluctuation start processing, first, a lottery (win / fail determination) process for determining whether or not a jackpot is a big hit is performed based on the value of the first random number counter C1 stored in the execution area of the reserved ball storage area (S1301). Whether or not it is a big hit is determined based on the relationship between the value of the first random number counter C1 and the mode at that time. As described above, when the possible state (mode) of the pachinko machine 200 is a normal low probability, "7,307,582" among the numerical values 0 to 899 of the first random number counter C1 becomes the winning value, and the pachinko machine 200 When the possible state (mode) is high probability, "28,58,85,122,144,178,213,238,276,298,322,354,390,420,448,486,506,543,567,596 , 618,656,681,716,750,772,809,863,866,892 ”is the winning value. In the process of S1301, the value of the first random number counter C1 stored in the execution area of the reserved ball storage area is compared with these hit values, and if they match, it is determined to be a big hit. ..

Then, when it is determined that the jackpot is a big hit as a result of the processing of S1301 (S1301: Yes), the display at the time of the jackpot is displayed based on the value of the first hit type counter C2 stored in the execution area of the reserved ball storage area. Aspects are set (S1302). In this process, the jackpot type set by the first hit type counter C2, that is, the 15R probability variable jackpot that shifts to the high probability state after the jackpot with the maximum number of rounds of 15 rounds, or the high probability after the jackpot with the maximum number of rounds of 2 rounds. The display mode (LED 237a lighting state) of the first symbol display device 237 is set based on whether the 2R probability variable jackpot that shifts to the state or the time-saving jackpot that shifts to the low probability state after the jackpot with the maximum number of rounds of 15 rounds. Will be done. In addition, the jackpot type (15R probability variation jackpot, 2R probability variation jackpot, time saving jackpot) is set as the stop type in order to stop and display the jackpot symbols corresponding to various jackpots on the third symbol display device 281 based on the transition state after the jackpot. Set. In addition, among the numerical values 0 to 9 of the first hit type counter C2, in the case of "0,1,2,3", it shifts to the low probability state (time saving big hit), and in the case of "4,5". After that, it shifts to the high probability state (2R probability variation jackpot), and in the case of "6,7,8,9", it shifts to the high probability state (15R probability variation jackpot).

Next, the fluctuation pattern at the time of big hit is determined (S1303). When the fluctuation pattern is set in the process of S1303, the display time of the first symbol display device 237 is set, and the fluctuation time of the third symbol until the third symbol display device 281 stops at the jackpot symbol is determined. To. At this time, the value of the variation type counter CS1 stored in the counter buffer of the RAM 403 is confirmed, and the variation time of the symbol variation such as normal reach and super reach is determined based on the value of the variation type counter CS1. The relationship between the numerical value of the fluctuation type counter CS1 and the fluctuation time is defined in advance by a table or the like.

If it is determined in the process of S1301 that it is not a big hit (S1301: No), the display mode at the time of disconnection is set (S1304). In the process of S1304, the display mode of the first symbol display device 237 is set to the display mode corresponding to the out-of-order symbol, and based on the value of the stop pattern selection counter C3 stored in the execution area of the reserved ball storage area, the display mode is set. As the stop type to be displayed on the third symbol display device 281, it is set whether the reach is out of front / back, the reach is out of front / back, or the reach is completely out. In the present embodiment, as described above, the table is set so that the range of values corresponding to each stop pattern of the stop pattern selection counter C3 differs depending on whether the state is a high probability state or a low probability state. There is.

Next, the fluctuation pattern at the time of disengagement is determined (S1305), the display time of the first symbol display device 237 is set, and the fluctuation time of the third symbol until the third symbol display device 281 stops at the disengaged symbol. Is determined. At this time, similarly to the processing of S1303, the value of the variation type counter CS1 stored in the counter buffer of the RAM 403 is confirmed, and the fluctuation time of the symbol variation such as normal reach and super reach is confirmed based on the value of the variation type counter CS1. To determine.

When the processing of S1303 or the processing of S1305 is completed, next, a variation pattern is determined, and a variation pattern command for notifying the display control device 314 of the variation pattern type is set (S1306). The variation pattern is selected from the variation pattern table (not shown) stored in the ROM 402 according to the result of the lottery in S1301 and the variation time determined by the processing of S1303 or S1305.

In the variation pattern table, for example, as variation patterns for disconnection, "disengagement (for long time)", "disengagement (for short time)", "disengagement normal reach", "disengagement super reach", "disengagement special reach" Various types are specified, and as fluctuation patterns for shared 15R fixed jackpots and short-time jackpots, various types of "15R shared normal reach", various types of "15R shared super reach", and various types of "15R shared special reach" are specified, and fluctuations for 15R probability variable jackpots are specified. Various "15R probability variation special reach" are defined as patterns, various "special variation" are defined as variation patterns for 2R probability variation jackpot, and various "shared normal reach" and "shared supermarket" are defined as variation patterns for both hit and miss. Various types of "reach" and various types of "shared special reach" are stipulated. Then, from the various fluctuation patterns defined in the fluctuation pattern table, the fluctuation pattern is selected according to the result of the lottery in S1301 and the fluctuation time determined by the processing of S1303 or S1305.

Next, a stop type command for notifying the display control device 314 of the stop type set in the process of S1302 or S1304 is set (S1307). These fluctuation pattern commands and stop type commands are stored in the ring buffer for command transmission provided in the RAM 403, and these commands are transmitted to the voice lamp control device 313 in the process of S1701 of the main process (FIG. 67). To. The voice lamp control device 313 transmits the stop type command as it is to the display control device 314. When the processing of S1307 is completed, the process returns to the variable processing.

Next, the start winning process (S1105) executed by the MPU 401 in the main control unit 310 will be described with reference to the flowchart of FIG. 64. FIG. 64 is a flowchart showing this start winning process (S1105). This start winning process (S1105) is executed in the timer interrupt process (see FIG. 61), determines whether or not there is a prize (starting prize) in the first ball opening 264, and if there is a starting winning. , The hold processing of the value indicated by the various random number counters and the permission determination process for starting the continuous advance notice effect in the third symbol display device 281 are executed from the values indicated by the various held random number counters.

When the start winning process is executed, first, it is determined whether or not the ball has won a prize (starting prize) in the first ball opening 264 (S1401). Here, the ball entering the first ball entry port 264 is detected over three timer interrupt processes. Then, when it is determined that the ball has won the first ball entry port 264 (S1401: Yes), the value of the hold ball number counter 403a (the number of hold balls N of the variable effect held in the main control device 310) is changed. It is determined whether or not it is less than the upper limit value (4 in this embodiment) (S1402). Then, whether or not there is a prize in the first ball opening 264 (S1401: No), or even if there is a prize in the first ball slot 264, the number of balls on hold for operation is not N <4 (S1402: No). , Return to timer interrupt processing. On the other hand, if there is a prize in the first entry slot 264 (S1401: Yes) and the number of reserved balls N <4 (S1402: Yes), the value of the reserved ball counter 403a (number of reserved balls N) is set. 1 is added (S1403), and each value of the first random number counter C1, the first hit type counter C2, and the stop pattern selection counter C3 updated in step S1103 is added to the empty hold area of the hold ball storage area of the RAM 403. It is stored in the first area (S1404).

Next, the reserved ball number N updated by the processing of S1403 and the respective values of the first random number counter C1, the first hit type counter C2, and the stop pattern selection counter C3 stored in the reserved ball storage area by the processing of S1404 are set. The included reserved ball count command is created (S1405), the created reserved ball count command is set (S1406), the start winning process is terminated, and the process returns to the timer interrupt process. This reserved ball number command is stored in the ring buffer for command transmission provided in the RAM 403, and is transmitted to the voice lamp control device 313 in the process of S1701 of the main process (FIG. 67). The voice lamp control device 313 manages the number of hold balls in the voice lamp control device 313 based on the hold ball number N included in the hold ball number command, and various counters included in the hold ball number command. Based on the value, it is determined whether or not the continuous advance notice effect is executed.

FIG. 65 is a flowchart showing an NMI interrupt process executed by the MPU 401 in the main control device 310. The NMI interrupt process is a process executed by the MPU 401 of the main control device 310 when the power of the pachinko machine 200 is cut off due to the occurrence of a power failure or the like. By this NMI interrupt processing, the power-off occurrence information is stored in the RAM 403. That is, when the power of the pachinko machine 200 is cut off due to the occurrence of a power failure or the like, the power failure signal SG1 is output from the power failure monitoring circuit 452 to the NMI terminal of the MPU 401 in the main control device 310. Then, the MPU 401 interrupts the control during execution and starts the NMI interrupt processing, stores the power interruption occurrence information in the RAM 403 (S1501) as the setting of the power interruption occurrence information, and ends the NMI interrupt processing. do.

The above NMI interrupt process is also executed in the payout launch control device 311, and the power cutoff occurrence information is stored in the RAM 413 by the NMI interrupt process. That is, when the power of the pachinko machine 200 is cut off due to the occurrence of a power failure or the like, the power failure signal SG1 is output from the power failure monitoring circuit 452 to the NMI terminal of the MPU 411 in the payout control device 311, and the MPU 411 interrupts the control during execution. Then, the NMI interrupt process is started.

Next, with reference to FIG. 66, the start-up process executed by the MPU 401 in the main control device 310 when the power is turned on to the main control device 310 will be described. FIG. 66 is a flowchart showing this start-up process. This start-up process is started by resetting when the power is turned on. In the start-up process, first, the initial setting process accompanying the power-on is executed (S1601). For example, a predetermined value is set in the stack pointer. Next, a weight process (1 second in this embodiment) is executed in order to wait for the control device on the sub side (peripheral control device such as the voice lamp control device 313 and the payout control device 311) to be in an operable state. (S1602). Then, the access of the RAM 403 is permitted (S1603).

After that, it is determined whether or not the RAM erasing switch 322 (see FIG. 49) provided in the power supply device 315 is turned on (S1604), and if it is turned on (S1604: Yes), the process shifts to S1611. On the other hand, if the RAM erase switch 322 is not turned on (S1604: No), it is determined whether or not the power cutoff occurrence information is stored in the RAM 403 (S1605), and if it is not stored (S1605: No). Since there is a possibility that the process at the time of the previous power cutoff did not end normally, the process is also shifted to S1611 in this case as well.

If the power cutoff occurrence information is stored in the RAM 403 (S1605: Yes), the RAM determination value is calculated (S1606), and if the calculated RAM determination value is not normal (S1607: No), that is, the calculated RAM. If the determination value does not match the RAM determination value saved when the power is cut off, the backed up data is destroyed, and the process is shifted to S1611 even in such a case. As will be described later in the process of S1712 in FIG. 67, the RAM determination value is, for example, a checksum value at the work area address of the RAM 403. Instead of this RAM determination value, the effectiveness of the backup may be determined based on whether or not the keyword written in the predetermined area of the RAM 403 is correctly saved.

In the process of S1611, a payout initialization command is transmitted to initialize the payout control device 311 which is a control device (peripheral control device) on the sub side (S1611). Upon receiving this payout initialization command, the payout control device 311 clears an area (work area) other than the stack area of the RAM 413, sets an initial value, and is ready to start payout control of the game ball. After transmitting the payout initialization command, the main control device 310 executes the initialization process (S1612, S1613) of the RAM 403.

As described above, in the pachinko machine 200, when the RAM data is initialized at the time of turning on the power, for example, when the hall is open for business, the power is turned on while pressing the RAM erasing switch 322. Therefore, if the RAM erase switch 322 is pressed when the startup process is executed, the RAM initialization process (S1612, S1613) is executed. In addition, the initialization process (S1612, S1613) of the RAM 403 is executed in the same manner when the power-off occurrence information is not set or when a backup abnormality is confirmed by the RAM determination value (checksum value, etc.). .. In the RAM initialization process (S1612, S1613), the used area of the RAM 403 is cleared to 0 (S1612), and then the initial value of the RAM 403 is set (S1613). After executing the initialization process of the RAM 403, the process proceeds to the process of S1610.

On the other hand, if the RAM erase switch 322 is not turned on (S1604: No), the power failure occurrence information is stored (S1605: Yes), and the RAM determination value (checksum value, etc.) is normal ( S1607: Yes), the information on the occurrence of the power failure is cleared while holding the data backed up in the RAM 403 (S1608). Next, a payout return command at the time of power recovery for returning the control device (peripheral control device) on the sub side to the gaming state at the time of power cutoff is transmitted (S1609), and the process proceeds to S1610. Upon receiving this payout return command, the payout control device 311 is in a state where the payout control of the game ball can be started while holding the data stored in the RAM 413.

In the process of S1610, interrupts are permitted (S1610). Then, it shifts to the main process described later.

Next, with reference to FIG. 67, the main process executed by the MPU 401 in the main controller 310 after the above-mentioned start-up process will be described. FIG. 67 is a flowchart showing this main process. In this main process, the main process of the game is executed. As an outline, each process of S1701 to S1705 is executed as a periodic process having a cycle of 4 ms, and the counter update process of S1708 and S1709 is executed in the remaining time.

In the main processing, first, in the timer interrupt processing (see FIG. 61), the output data such as commands stored in the ring buffer for command transmission provided in the RAM 234 is input to each control device (peripheral control device) on the sub side. ) Is executed (S1701). Specifically, the presence or absence of the winning detection information detected by the switch reading processing of S1101 in the timer interrupt processing (see FIG. 61) is determined, and if the winning detection information is present, the number of acquired balls corresponds to the payout control device 311. Send a prize ball command. Further, the hold ball number command set in the start winning process (see FIG. 64) is transmitted to the voice lamp control device 313. Further, by this external output processing, the variation pattern command, the stop type command, the confirmation command, etc. necessary for the variation display of the third symbol by the third symbol display device 281 are transmitted to the voice lamp control device 313. In addition, when launching a ball, a ball launch signal is transmitted to the launch control device 312.

Next, the value of the variation type counter CS1 is updated (S1702). Specifically, the variation type counter CS1 is added by 1, and when the counter value reaches the maximum value (198 in the present embodiment), it is cleared to 0. Then, the update value of the variation type counter CS1 is stored in the corresponding buffer area of the RAM 403.

When the update of the variable type counter CS1 is completed, the prize ball counting signal and the payout abnormality signal received from the payout control device 311 are read (S1703), and then the specific winning opening (large opening) of the variable winning device 265 in the case of a big hit state. Mouth) A large opening opening / closing process for opening or closing 265a is executed (S1704). That is, the specific winning opening 265a is opened for each round in the jackpot state, and it is determined whether the maximum opening time of the specific winning opening 265a has elapsed or whether the specified number of balls have won in the specific winning opening 265a. Then, when any of these conditions is satisfied, the specific winning opening 265a is closed. The opening and closing of the specific winning opening 265a is repeatedly executed for a predetermined number of rounds.

Next, the display control process of the second symbol (for example, the symbol of “◯” or “×”) by the second symbol display device 283 is executed (S1705). Briefly, on condition that the ball has passed through the second entry port (through gate) 267, the value of the second random number counter C4 is acquired at the timing of the passage, and the second symbol display device 283 is used. The variation display of the second symbol is carried out at. Then, the lottery of the second symbol is carried out by the value of the second random number counter C4, and when the second symbol is in the winning state, the electric accessory attached to the first entry port 264 is released for a predetermined time.

After that, it is determined whether or not the power outage occurrence information is stored in the RAM 403 (S1706), and if the power outage occurrence information is not stored in the RAM 403 (S1706: No), the power failure signal from the power failure monitoring circuit 452. SG1 is not output and the power supply is not cut off. Therefore, in such a case, it is determined whether or not the execution timing of the next main process has been reached, that is, whether or not a predetermined time (4 msec in the present embodiment) has elapsed from the start of the previous main process (S1707). If the predetermined time has already passed (S1707: Yes), the process is shifted to S1701 and each process after S1701 described above is repeatedly executed.

On the other hand, if a predetermined time has not yet elapsed from the start of the previous main process (S1707: No), the first is within the period until the predetermined time is reached, that is, within the remaining time until the execution timing of the next main process is reached. 1 The initial value random number counter CINI1, the second initial value random number counter CINI2, and the variation type counter CS1 are repeatedly updated (S1708, S1709).

First, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are updated (S1708). Specifically, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are added by 1, and when the counter value reaches the maximum value (899, 250 in this embodiment), it is cleared to 0. .. Then, the updated values of the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are stored in the corresponding buffer areas of the RAM 403, respectively. Next, the variation type counter CS1 is updated by the same method as the processing of S1702 (S1709).

Here, since the execution time of each process of S1701 to S1705 changes according to the state of the game, the remaining time until the execution timing of the next main process is not constant and fluctuates. Therefore, by repeatedly updating the first initial value random number counter CINI1 and the second initial value random number counter CINI2 using the remaining time, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 (that is, , The initial value of the first random number counter C1 and the initial value of the second random number counter C4) can be updated at random, and similarly, the variation type counter CS1 can also be updated at random.

Further, in the process of S1706, if the power cutoff occurrence information is stored in the RAM 403 (S1706: Yes), the power supply is cut off due to the occurrence of a power failure or the power is turned off, and the power failure signal SG1 is output from the power failure monitoring circuit 452. As a result, since the NMI interrupt process shown in FIG. 65 has been executed, the process when the power is cut off after S1710 is executed. First, the occurrence of each interrupt process is prohibited (S1710), and a power off command indicating that the power is cut off is issued to other control devices (peripheral control devices such as payout control device 311 and voice lamp control device 313). (S1711). Then, the RAM determination value is calculated, the value is saved (S1712), the access of the RAM 403 is prohibited (S1713), and the infinite loop is continued until the power supply is completely shut off and the process cannot be executed. Here, the RAM determination value is, for example, a checksum value in the backed up stack area and work area of the RAM 403.

The processing of S1706 is performed at the end of a series of processing corresponding to the state change of the game performed in S1701 to S1705, or at the end of one cycle of the processing of S1708 and S1709 performed within the remaining time. It is running. Therefore, in the main process of the main control device 310, the power cutoff occurrence information is confirmed at the timing when each setting is completed. Therefore, when returning from the power cutoff state, the process is performed after the start-up process is completed. It can be started from the process of S1701. That is, the process can be started from the process of S1701 as in the case of being initialized in the start-up process. Therefore, even if the contents of each register used by the MPU 401 are not saved in the stack area or the value of the stack pointer is not saved in the process when the power is cut off, the stack pointer is used in the initial setting process (S1601). By setting a predetermined value (initial value), it is possible to start from the process of S1701. Therefore, the control load of the main control device 310 can be reduced, and accurate control can be performed without the main control device 310 malfunctioning or running out of control.

Next, with reference to FIGS. 68 to 72, each control process executed by the MPU 421 in the voice lamp control device 313 will be described. The processing of the MPU 421 is roughly classified into a start-up process that is started when the power is turned on and a main process that is executed after the start-up process.

First, the start-up process executed by the MPU 421 in the voice lamp control device 313 will be described with reference to FIG. 68. FIG. 68 is a flowchart showing this start-up process. This start-up process is started when the power is turned on.

When the start-up process is executed, first, the initial setting process associated with turning on the power is executed (S1801). Specifically, a predetermined predetermined value is set in the stack pointer. After that, depending on whether or not the power cutoff processing flag is turned on, the power cutoff process of S1917 (see FIG. 69) is caused by a momentary voltage drop (momentary power failure, so-called "momentary power failure") in this start-up process. ) Is started in the middle of execution (S1802). As will be described later with reference to FIG. 69, when the voice lamp control device 313 receives the power cutoff command from the main control device 310 (see S1914 in FIG. 69), the voice lamp control device 313 executes the power cutoff process of S1917. The power cutoff processing flag is turned on before the power cutoff process is executed, and the power cutoff process in progress flag is turned off after the power cutoff process is completed. Therefore, whether or not the power cutoff process of S1917 is in the middle of execution can be determined by the state of the power cutoff process in progress flag.

If the power off processing flag is off (S1802: No), the start-up process is started after the power is completely cut off, or after a momentary power failure occurs and the power of S1917 is turned off. It was started after the execution of the process was completed, or it was started by resetting only the MPU 421 of the audio lamp control device 313 (without receiving the power off command from the main control device 310) due to noise or the like. be. Therefore, in these cases, it is confirmed whether or not the data in the RAM 423 is destroyed (S1803).

Confirmation of data corruption in RAM423 is performed as follows. That is, the data as the keyword of "55AAh" is written in the specific area of the RAM 423 by the processing of S1806. Therefore, the data stored in the specific area can be checked, and if the data is "55AAh", there is no data destruction in the RAM 423, and conversely, if the data is not "55AAh", the data destruction in the RAM 423 can be confirmed. If the data destruction of the RAM 423 is confirmed (S1803: Yes), the process proceeds to S1804 and the initialization of the RAM 423 is started. On the other hand, if the data destruction of the RAM 423 is not confirmed (S1803: No), the process proceeds to S1808.

If the start-up process is started after the power is completely cut off, the keyword "55AAh" is not stored in the specific area of the RAM 423 (the memory of the RAM 423 is lost due to the power off). (From), it is determined that the data of the RAM 423 is destroyed (S1803: Yes), and the process proceeds to S1804. On the other hand, the start-up process this time was started after the execution of the power cutoff process of S1917 was completed after the momentary power failure occurred, or it was reset only to the MPU 421 of the voice lamp control device 313 due to noise or the like. Since the keyword "55AAh" is stored in the specific area of the RAM 423, the data of the RAM 423 is determined to be normal (S1803: No), and the data shifts to S1808.

If the power-off processing flag is on (S1802: Yes), the start-up processing this time is after a momentary power failure occurs, and the voice lamp control device 313 is being executed during the power-off processing of S1917. The MPU 421 of the MPU 421 was reset and started. In such a case, the storage state of the RAM 423 is not always correct because the power cutoff process is being executed. Therefore, in such a case, the control cannot be continued, so the process is shifted to S1804 and the initialization of the RAM 423 is started.

In the process of S1804, the storage area of the entire range of the RAM 423 is checked (S1804). As a check method, first, "0FFh" is written for each byte, it is read for each byte, it is confirmed whether or not it is "0FFh", and if it is "0FFh", it is determined to be normal. Such writing and confirmation for each byte are performed in the order of "0FFh", then "55h", "0AAh", and "00h". By this read / write check of the RAM 423, all the storage areas of the RAM 423 are cleared to zero.

If the read / write check is determined to be normal for all the storage areas of the RAM 423 (S1805: Yes), the keyword "55AAh" is written in the specific area of the RAM 423 to set the RAM destruction check data (S1806). By confirming the keyword "55AAh" written in this specific area, it is checked whether or not the RAM 423 has data corruption. On the other hand, if an abnormality in the read / write check is detected in any of the storage areas of the RAM 423 (S1805: No), an abnormality in the RAM 423 is notified (S1807), and an infinite loop is performed until the power is cut off. The abnormality of the RAM 423 is notified by the indicator lamp 234. The voice output device 426 may output voice to notify the abnormality of the RAM 423, or an error command may be sent to the display control device 314 to display an error message on the third symbol display device 281. You may do it.

In the process of S1808, it is determined whether or not the power off flag is turned on (S1808). The power-off flag is turned on when the power-off process of S1917 is executed (see S1916 in FIG. 69). That is, since the power-off flag is turned on before the power-off process of S1917 is executed, the process of S1808 is reached with the power-off flag turned on because the start-up process is instantaneous. This is a case where the power is started after the power failure has occurred and the execution of the power cutoff process of S1917 has been completed. Therefore, in such a case (S1808: Yes), the work area of the RAM is cleared in order to initialize each process of the voice lamp control device 313 (S1809), the initial value of the RAM 423 is set (S1810), and then an interrupt occurs. Set the permission (S1811) and move to the main process. The work area of the RAM 423 refers to an area other than the area for storing commands and the like received from the main control device 310.

On the other hand, the reason why the process of S1808 is reached with the power off flag turned off is that the start-up process of this time is started after the power supply is completely cut off, for example, so that the process of S1808 is performed via the process of S1804 to S1806. This is the case when the process is reached or the MPU 421 of the voice lamp control device 313 is reset (without receiving the power off command from the main control device 310) due to noise or the like. Therefore, in such a case (S1808: No), S1809, which is the clear processing of the work area of RAM423, is skipped, the processing is shifted to S1810, the initial value of RAM423 is set (S1810), and then interrupt permission is set. Then (S1811), the process proceeds to the main process.

The reason for skipping the clear processing of S1809 is that when the processing of S1808 is reached from S1804 via the processing of S1806, all the storage areas of the RAM 423 have already been cleared by the processing of S1804. When only the MPU 421 of the voice lamp control device 313 is reset due to noise or the like and the start-up process is started, the data in the work area of the RAM 423 is saved without being cleared, so that the voice lamp control device 313 is saved. This is because the control of can be continued.

Next, with reference to FIG. 69, the main process executed by the MPU 421 in the voice lamp control device 313 after the start-up process of the voice lamp control device 313 will be described. FIG. 69 is a flowchart showing this main process. When the main process is executed, it is first determined whether or not 1 msec or more has elapsed since the main process was started or since the previous process of S1901 was executed (S1901), and 1 msec or more has elapsed. If not (S1901: No), the process proceeds to S1912 without performing the processes of S1902 to S1911. In the process of S1901, whether or not 1 msec has elapsed is a process related to display (effect) in S1902 to S1911, and it is not necessary to edit in a short cycle (within 1 msec), whereas in S1912. This is because it is preferable to execute the fluctuation display processing of S1913 and the command determination processing of S1913 in a short cycle. By executing the processing of S1913 in a short cycle, it is possible to prevent the reception omission of the command transmitted from the main controller 310, and by executing the processing of S1912 in a short cycle, the command received by the command determination processing. Based on the above, the settings related to the variable effect can be made without delay.

If 1 msec or more has elapsed in the process of S1901 (S1901: Yes), first, various commands for the display control device 314 set by the process of S1903 to S1913 are transmitted to the display control device 314. Next, the output of each lamp is set so as to set the lighting mode of the indicator lamp 234 and the lighting mode of the lamp edited by the process of S1909 described later (S1903), and then the power-on notification process is executed (S1904). The power-on notification process notifies that the power has been turned on for a predetermined time (for example, 30 seconds) when the power is turned on, and the notification is performed by the voice output device 426 or the lamp display device 427. Will be. Further, a command may be transmitted to the display control device 314 to notify that the power is supplied on the screen of the third symbol display device 281. If the power is not turned on, the process proceeds to S1905 without being notified by the power on notification process.

In the process of S1905, the customer waiting effect is executed, and then the pending quantity display update process is executed (S1906). In the customer waiting effect, when a predetermined time elapses when the pachinko machine 200 is not played by the player, a setting is made to switch the display of the third symbol display device 281 to the title screen, and the setting is a display control device as a command. It is transmitted to 314. In the hold quantity display update process, a process of turning on the hold lamp 285 according to the value of the hold ball number counter 423a is performed.

After that, the frame button input monitoring / effect processing is executed (S1907). In this frame button input monitoring / effect processing, the input of whether or not the frame button 222 operated by the player is pressed in order to enhance the effect is monitored, and the input of the frame button 222 is confirmed. It is a process to set to perform the production. In this process, when the operation of the frame button 222 by the player is detected, a frame button operation command for notifying the display control device 314 that the frame button 222 has been operated is set.

Further, when the frame button 222 is pressed during the period when the variation effect is not executed or during the high-speed variation period, the stage is changed and the rear image change command for the display control device 314 is set. By including information on the type of the rear image corresponding to the changed stage in this rear image change command, the rear image displayed on the third symbol display device 281 in the display control device 314 is displayed as an image according to the stage. The process of changing to is performed. In addition, when the notice character appears at the start of the fluctuation display, the expected value of the jackpot due to this fluctuation can be displayed by pressing the frame button 222, or the expected value of the jackpot can be displayed by pressing the frame button 222 during the reach production. The effect may be changed to a possessable effect, or the frame button 222 may be used as a decision button for selecting one of the reach effects among a plurality of reach effects. If the frame button 222 is not arranged, the process of S1907 is omitted.

When the frame button input monitoring / effect processing is completed, the vibration sensor input monitoring processing is performed (S1908). This vibration sensor input monitoring process is a process of monitoring the input signal from the vibration sensor 428 and detecting whether or not vibration is applied to the pachinko machine 200.

Here, the details of the vibration sensor input monitoring process (S1908) will be described with reference to FIG. 70. FIG. 70 is a flowchart showing a vibration sensor input monitoring process (S1908) executed by the MPU 421 in the voice lamp control device 313.

In the vibration sensor input monitoring process (S1908), first, the output value (vibration level) of the vibration sensor 428 is read from the vibration sensor 428 (S1951), and it is determined from the read output value whether or not the vibration level is equal to or higher than a predetermined level. (S1952). As a result, if the vibration level is less than the predetermined level (S1952: No), the vibration sensor input monitoring process is terminated and the process returns to the main process (FIG. 69).

On the other hand, if the vibration level is equal to or higher than a predetermined level (S1952: Yes), it is determined that vibration has been applied to the pachinko machine 200, and an alarm sound is set to be output from the voice output device 426 (S1953) and displayed. An error command for notifying the occurrence of a vibration error is set for the control device 314 (S1954), and the process returns to the main process (FIG. 69). As a result, the display control device 31 performs a process of displaying an error message image for notifying the vibration error on the third symbol display device 281.

Returning to FIG. 69, the description of the main process will be continued. When the vibration sensor input monitoring process (S1908) is completed, the lamp editing process is then executed (S1909), and then the sound editing / output process is executed (S1910). In the lamp editing process, the lighting patterns of the illumination units 229 to 233 and the like are set so as to correspond to the display performed by the third symbol display device 281. In the sound editing / output processing, the output pattern of the voice output device 426 or the like is set so as to correspond to the display performed by the third symbol display device 281, and the sound is output from the voice output device 426 according to the setting. If the alarm sound output is set by the vibration sensor input monitoring process (see FIG. 70) (see S1953), the alarm sound output pattern is set by this sound editing / output process, and the alarm sound is voiced. It is output from the output device 426.

After the process of S1910, the liquid crystal display effect execution management process is executed (S1911), and the process proceeds to the process of S1912. In the liquid crystal display execution management process, a time synchronized with the time required for the fluctuation display performed by the third symbol display device 281 is set based on the fluctuation pattern command transmitted from the main control device 310. The lamp editing process of S1909 is executed based on the time set in the liquid crystal display effect execution monitoring process. The sound editing / output processing of S1910 is also executed at a time synchronized with the time required for the fluctuation display performed by the third symbol display device 281.

In the process of S1912, in order to display the variation effect on the third symbol display device 281, a display variation pattern command is generated based on the variation pattern command received from the main control device 310, and the command is transmitted to the display control device 314. Executes the variable display process, which is the process set for transmission. The details of this variation display process will be described later with reference to FIG. 72. Then, after the fluctuation display processing, a command determination processing is performed (S1913), in which processing is performed according to the command received from the main control device 310. The details of this command determination process will be described later with reference to FIG. 71.

When the processing of S1913 is completed, it is determined whether or not the power cutoff occurrence information is stored in the work RAM 433 (S1914). The power-off occurrence information is stored when a power-off command is received from the main control device 310. If the power-off occurrence information is stored in the process of S1914 (S1914: Yes), both the power-off flag and the power-off process in progress flag are turned on (S1916), and the power-off process is executed (S1917). After the power cutoff process is executed, the power cutoff process in progress flag is turned off (S1918), and then the process is looped infinitely. In the power cutoff process, the occurrence of the interrupt process is prohibited, and each output port is turned off to turn off the output from the audio output device 426 and the lamp display device 427. In addition, the memory of the information on the occurrence of the power failure is also erased.

On the other hand, if the power-off occurrence information is not stored in the process of S1914 (S1914: No), it is determined whether or not the RAM 423 is destroyed based on the keyword stored in the RAM 423 (S1915), and the RAM 423 is destroyed. If not (S1915: No), the process returns to the process of S1901 and the main process is repeatedly executed. On the other hand, if the RAM 423 is destroyed (S1915: Yes), the processing is looped infinitely in order to stop the execution of the subsequent processing. Here, if it is determined that the RAM is destroyed and an infinite loop is performed, the main process is not executed, so that the display by the third symbol display device 281 does not change thereafter. Therefore, since the player can know that the abnormality has occurred, he / she can call a clerk in the hall or the like and ask for the repair of the pachinko machine 200 or the like. Further, when it is confirmed that the RAM 423 is destroyed, the voice output device 426 or the lamp display device 427 may be used to notify the RAM destruction.

Next, the command determination process (S1913) executed by the MPU 421 in the voice lamp control device 313 will be described with reference to FIG. 71. FIG. 71 is a flowchart showing this command determination process (S1913). This command determination process (S1913) is executed in the main process (see FIG. 69) executed by the MPU 421 in the voice lamp control device 313, and as described above, determines the command received from the main control device 310. .. Further, this process also determines the start of the continuous advance notice effect by the third symbol display device 281 when the hold ball number command is received from the main control device 310.

In the command determination process, first, the first command received from the main control unit 310 among the unprocessed commands is read from the command storage area provided in the RAM 423, analyzed, and the variation pattern command is received from the main control unit 310. It is determined whether or not it has been done (S2001). Then, when it is determined that the variation pattern command has been received (S2001: Yes), the variation start flag provided in the RAM 423 is turned on (S2002), and the variation pattern type is extracted from the variation pattern command (S2003). , Return to the main process. The variation pattern type extracted here is stored in the RAM 423, and in the variation display processing (see FIG. 72) described later, the display variation pattern for notifying the display control device 314 of the start of the variation effect and the variation pattern type. Used when setting commands.

On the other hand, when it is determined that the variation pattern command has not been received (S2001: No), it is then determined whether or not the stop type command has been received from the main control unit 310 (S2004). Then, when it is determined that the stop type command has been received (S2004: Yes), the display stop type command is set in order to transmit the stop type command as it is to the display control device 314 (S2005).

On the other hand, when it is determined that the stop type command has not been received (S2004: No), it is then determined whether or not the reserved ball count command has been received from the main control device 310 (S2006). Then, when it is determined that the hold ball number command has been received (S2006: Yes), the value of the hold ball number counter 403a of the main control device 310 included in the hold ball number command (that is, the hold is held by the main control device 310). (Number of reserved balls for variable effect) is extracted and stored in the reserved ball number counter 423a of the voice lamp control device 313 (S2007).

Here, since the hold ball number command is transmitted from the main control device 310 when the ball wins a prize (starting prize) in the first ball opening 264, every time there is a starting winning, the process of S2008 , The value of the hold ball number counter 423a of the voice lamp control device 313 can be adjusted to the value of the hold ball number counter 403a of the main control device 310. Therefore, even if the value of the hold ball number counter 423a of the voice lamp control device 313 deviates from the value of the hold ball number counter 403a of the main control device 310 due to the influence of noise or the like, the voice lamp control device 313 is used when the start winning prize is detected. The value of the reserved ball number counter 423a can be modified to match the value of the reserved ball number counter 403a of the main controller 310.

Further, after the processing of S2007, a display holding ball number command for notifying the display control device 314 of the value of the holding ball number counter 423a updated by the processing of S2007 is set (S2008). As a result, the display control device 314 executes a process so that the third symbol display device 281 displays the reserved ball number symbol according to the reserved ball number.

After that, the continuous notice determination process is executed (S2009), and the process returns to the main process. In this continuous advance notice determination process, the value of the number of reserved balls received from the main control device 310 by the reserved ball number command and the values of the first random number counter C1, the first hit type counter C2, and the stop pattern selection counter C3 are used. It is determined whether or not to perform the continuous advance notice effect in which the advance notice effect image is continuously displayed over the variable effect held at the time point. Further, in the case of performing the continuous advance notice effect, whether the continuous advance notice effect mode is the same effect type continuous advance notice effect mode in which the same image (for example, a “bubble” image) is displayed across a plurality of variable effects. , Display related images in order each time a variable effect is performed (for example, display each image in the order of "egg" → "chick" → "chicken" → "chicken group") Step-up type continuous notice effect Decide whether to use the mode.

Specifically, the determination of whether or not to perform the continuous advance notice effect is made when the hold ball number command is transmitted based on the values of the first random number counter C1, the first hit type counter C2, and the stop pattern selection counter C3. The result of the lottery performed in response to the reserved balls held in (1) and the stop type after the fluctuation effect are estimated, and the estimation result is performed based on the estimated result and the number of reserved balls held at that time. For example, when it is estimated that the stop type after the variable effect is a 15R probability variation jackpot or a front-back out-of-reach reach, it may be determined that the continuous advance notice effect is performed with a predetermined probability. Further, in this case, it may be determined that the continuous advance notice effect is performed with a higher probability as the number of reserved balls increases.

In addition to this, if the estimated lottery result is a big hit, the continuous notice effect may be performed with a predetermined probability regardless of the stop type, and the lottery result is out of order. However, when the stop type is reach, that is, when it is presumed that the reach is out of front and back and the reach is other than out of front and back, the continuous advance notice effect may be performed with a predetermined probability. As described above, the conditions for determining the continuous advance notice effect may be appropriately set according to the playability of the pachinko machine 200.

Further, as the continuous advance notice effect mode, the conditions of the same effect type or the step-up type may be appropriately set. For example, a random number counter may be provided inside the voice lamp control device 313, and the continuous advance notice effect mode may be determined according to the value of the random number counter.

In the pachinko machine 200, in the main control device 310, each value of the first hit random number counter C1, the first hit type counter C2, and the stop pattern selection counter C3 acquired at the time of starting winning is set to the voice lamp control device by the hold ball number command. Notifying 313, the voice lamp control device 313 determines the start of the continuous advance notice effect and sets the mode of the continuous advance notice effect based on the values of the various counters notified by the hold ball number command and the value of the hold ball number. conduct. As a result, the processing in the main control device 310 can be concentrated in the most important processing of the pachinko machine 200, which is the lottery processing for drawing the game state to be transitioned based on the ball entering the first ball entry port 264. On the other hand, if the MPU 421 having a high processing capacity is used for the voice lamp control device 313, the execution conditions of the continuous advance notice effect can be set in various modes.

Further, the number of reserved balls and the values of various counters can be transmitted from the main control device 310 to the voice lamp control device 313 with one command for the number of reserved balls. As a result, in the voice lamp control device 313, it is possible to accurately grasp the correspondence between the values of various counters acquired in connection with the start winning and the number of reserved balls at the time when the starting winning is detected. When it is decided to execute the continuous advance notice effect, the number of reserved balls to which the continuous advance notice effect is added can be accurately grasped. Therefore, the control of the voice lamp control device 313 is facilitated as compared with the case where the number of reserved balls and the values of various counters are transmitted from the main control device 310 to the voice lamp control device 313 by another command. be able to.

If it is determined that the reserved ball count command has not been received as a result of the processing of S2006 (S2006: No), it is determined whether or not another command has been received, and the processing corresponding to the received command is executed. (S2010), the process shifts to the main process. For example, if the other command is a command used in the voice lamp control device 313, the processing corresponding to the command is performed, the processing result is stored in the RAM 423, and if the command is used in the display control device 314, the command is displayed and controlled. Set the command so that it is sent to the device 314. The demo command and the confirmation command received from the main control device 310 are set as the display demo command and the display confirmation command by the process of S2010, and are transmitted to the display control device 314.

Next, with reference to FIG. 72, the variation display process (S1912) executed by the MPU 421 in the voice lamp control device 313 will be described. FIG. 72 is a flowchart showing this variation display process (S1912). This variation display process (S1912) is executed in the main process (see FIG. 69) executed by the MPU 421 in the voice lamp control device 313, and as described above, the variation effect is displayed on the third symbol display device 281. In order to generate a display variation pattern command based on the variation pattern command received from the main control device 310, the variation display process, which is a process set to transmit the command to the display control device 314, is executed. In addition, the value of the reserved ball number counter 423a is updated along with the display of the fluctuation effect, and the display reserved ball number command is set and generated in order to notify the display control device 314 of the updated reserved ball number. When a decision is made to perform a continuous advance notice effect for the variation effect displayed on the third symbol display device 281 by the display variation pattern command, a continuous advance notice command is set after the display variation pattern command.

In the variation display process, first, it is determined whether or not the variation start flag provided in the RAM 423 is on (S2101). Then, when it is determined that the fluctuation start flag is not on (that is, it is off) (S2101: No), the fluctuation pattern command has not been received from the main controller 310, so this fluctuation display process is performed. Exit and return to the main process. On the other hand, when it is determined that the fluctuation start flag is on (S2101: Yes), the fluctuation start flag is turned off (S2102), and then extracted from the fluctuation pattern command in the processing of S2003 of the command determination processing (see FIG. 71). The variation pattern type in the variation effect is acquired from the RAM 423 (S2103).

Then, a display variation pattern command for notifying the display control device 314 of the acquired variation pattern type is generated, and the command is set to be transmitted to the display control device 314 (S2104). When the display control device 314 receives the display variation pattern command, the display control device 314 displays the variation of the third symbol on the third symbol display device 281 with the variation pattern indicated by the display variation pattern command. Start the display control of the fluctuation effect.

Next, the value of the hold ball count counter 423a is decremented by 1 as the hold ball is consumed (that is, the change display corresponding to the hold ball is set) with the setting of the display change pattern command. (S2105), a display hold ball number command for notifying the display control device 314 of the hold ball number indicated by the value of the hold ball number counter 423a after the update is set (S2106). The display control device 314 executes a process of displaying the number of reserved ball symbols corresponding to the number of reserved balls indicated by the display reserved ball number command on the third symbol display device 281. Therefore, the player can recognize the number of reserved balls by counting the number of reserved balls displayed on the third symbol display device 281.

Next, it is determined whether or not a decision is made to perform a continuous advance notice effect by the process of S2009 of the command determination process (see FIG. 71) for the variation effect corresponding to the display variation pattern command set by the process of S2104. (S2107) If it has been decided to perform the continuous advance notice effect (S2107: Yes), a continuous advance notice command for notifying the display control device 314 of the execution of the continuous advance notice effect is set (S2108). , End this process and return to the main process. On the other hand, in the process of S2107, if it is not decided to perform the continuous advance notice effect (S2107: No), the variation display process is terminated as it is, and the process returns to the main process.

Here, the continuous advance notice command set by the process of S2108 is additionally displayed in addition to the variable effect according to the continuous advance notice effect mode determined by the process of S2009 of the command determination process (see FIG. 71). The continuous preview image type (one of "foam", "egg", "chick", "chicken" and "chicken group") is included. When the display control device 314 receives the continuous notice command, the display control device 314 adds a continuous notice image of the type indicated by the continuous notice effect command to the variation effect performed based on the previously received display variation pattern command, and has a third symbol. The process is executed so as to be displayed on the display device 281.

Next, with reference to FIGS. 73 to 87, each control executed by the MPU 431 of the display control device 314 will be described. The processing of the MPU 431 is roughly divided into a main processing that is repeatedly executed after the power is turned on, a command interrupt processing that is executed when a command is received from the voice lamp control device 313, and one frame of the image controller 437. There is a V interrupt process executed when the MPU 431 detects a V interrupt signal transmitted every 20 milliseconds when the image drawing process is completed. Normally, the MPU 431 executes the main process, and executes the command interrupt process and the V interrupt process in accordance with the reception of the command and the detection of the V interrupt signal. When the command reception and the V interrupt signal detection are performed at the same time, the command reception process is preferentially executed. As a result, the content of the command received from the voice lamp control device 313 can be quickly reflected, and the V interrupt process can be executed.

First, with reference to FIG. 82, the main process executed by the MPU 431 in the display control device 314 will be described. FIG. 82 is a flowchart showing this main process. The main process is to execute the initialization process when the power is turned on.

Specifically, the activation of this main process is performed according to the following flow. When the power is turned on from the power supply circuit 315 to the display control device 314 and the system reset is released, the MPU 431 sets the instruction pointer 431a provided in the MPU 431 to "0000H" according to its hardware configuration. , The address "0000H" indicated by the instruction pointer 431a is specified for the bus line 440. When the ROM controller 434b of the character ROM 434 detects that the address specified in the bus line 440 is "0000H", the boot program stored in the first program storage area 434d1 of the NOR type ROM 434d is set in the buffer RAM 434c. , The corresponding data (instruction code) is output to MPU431. Then, the MPU 431 fetches the instruction code received from the character ROM 434 and starts the execution of the process according to the fetched instruction to start the main process.

Here, if all the boot programs initially processed by the MPU 431 after the system reset is released are stored in the NAND flash memory 434a, the character ROM 434 indicates that the address specified in the bus line 440 is "0000H". When detected, one page of data including the data (instruction code) corresponding to the address "0000H" must be read from the NAND flash memory 434a and set in the buffer RAM 434c. Due to the nature of the NAND flash memory 434a, it takes a long time to set the buffer RAM 434c from the read thereof. Therefore, the MPU 431 receives the instruction code corresponding to the address "0000H" after designating the address "0000H". It will consume a lot of waiting time. Therefore, it takes a long time to start the MPU 431, and as a result, there is a problem that the control of the third symbol display device 281 in the display control device 314 may not be started immediately.

On the other hand, as in the present embodiment, among the boot programs, a predetermined number of instructions from the instruction to be processed first by the MPU 431 after the system reset is released are stored in the NOR type ROM 434d, so that the NOR type ROM has a high speed. Since it is a memory capable of reading data, when the address "0000H" is specified from the MPU 431 via the bus line 440 after the system reset is released, the character ROM 434 immediately shifts to the first program storage area 434d1 of the NOR type ROM 434d. The stored boot program can be set in the buffer RAM 434c, and the corresponding data (instruction code) can be output to the MPU 431. Therefore, since the MPU 431 can receive the instruction code corresponding to the address "0000H" in a short time after designating the address "0000H", the MPU 431 can start the main process in a short time. Therefore, even if the control program is stored in the character ROM 434 configured by the NAND flash memory 434a having a slow read speed, the control of the third symbol display device 281 in the display control device 314 can be started immediately.

When the main process is executed as described above, first, the boot process executed by the boot program is executed (S2201), and the display control device 314 is capable of executing various controls for the third symbol display device 281. To start. Since the boot process executed here is the same as the boot process executed by the MPU 181 of the display control device 81 of the slot machine 10 in the first embodiment (see FIG. 22), the illustration and description thereof will be omitted. However, in the pachinko machine 200 according to the seventh embodiment, in the boot process shown in FIG. 22, the control program and a part of the fixed data are stored in the program storage area 433a of the work RAM 433, and the above-mentioned fixed value data is described above. Various data tables (display data table, additional data table, transfer data table) are stored in the data table storage area 433b.

Here, as described above, in the present embodiment, the control program and the fixed value data executed by the MPU 431 are provided with a dedicated program ROM (for example, ROM 22 of the above-mentioned Patent Document 1) as in a conventional gaming machine. It is stored in the character ROM 434 provided for storing the image data to be displayed on the third symbol display device 281 instead of storing the data. Since the character ROM 434 is composed of a NAND flash memory 434a capable of increasing the capacity in a small area, it is possible to sufficiently store not only the image data but also the control program and the like, while controlling the character ROM 434. It is not necessary to provide a dedicated program ROM for storing programs and the like. Therefore, the number of parts in the display control device 314 can be reduced, the manufacturing cost can be reduced, and the increase in the failure occurrence rate due to the increase in the number of parts can be suppressed.

On the other hand, since the NAND flash memory has a slow read speed especially when performing random access, if the MPU 431 directly reads and processes the control program and fixed value data stored in the NAND flash memory 434a, the MPU 431 is used. Even if a high-performance processor is used, the processing performance of the display control device 91 may be deteriorated. Therefore, in this boot process, the control program and fixed value data stored in the second program storage area 434a1 of the NAND flash memory 434a are stored in the program storage area 433a and the data table provided in the work RAM 433 configured by the DRAM. The process of transferring to the storage area 434b and storing the data is executed. Then, at the end of the boot process, the instruction pointer 431a is set to the above-mentioned second predetermined address, and thereafter, the MPU 431 is transferred to the program storage area 433a without referring to the NAND flash memory 434a. , Various processes are executed using the data table storage area 433b.

Therefore, even when the control program is stored in the character ROM 434 configured by the NAND flash memory 434a having a slow read speed, the control program or the like is transferred to the program storage area 433a or the like of the work RAM 433 after the system reset is released. As a result, the MPU 431 can read a control program or the like from a work RAM composed of a DRAM having a high read speed and perform various controls, so that high processing performance can be maintained in the display control device 314, and the third By using the symbol display device 281, it is possible to easily execute a diversified and complicated effect.

On the other hand, instead of storing all the boot programs in the NOR type ROM 434d, a predetermined number of instructions are stored from the instruction to be processed first by the MPU 431 after the system reset is released, and the remaining boot programs are stored in the NAND flash memory 434a. Even if the control program is stored in the second program storage area 434a2, the control program stored in the second program storage area 434a1 can be reliably transferred to the program storage area 433a. Therefore, the character ROM 434 can start the MPU 431 in a short time only by adding an extremely small capacity NOR type ROM 434d, so that the cost increase of the character ROM 434 due to the shortening of the time can be suppressed. Can be done.

When the boot process is completed, the initial setting process is then executed according to the control program transferred and stored in the program storage area 433a of the work RAM 433 (S2202). Specifically, the process of initializing the MPU 431 and clearing the storage of the work RAM 433, the resident video RAM 435, and the normal video RAM 436 is performed. Further, various flags are provided in the work RAM 433, and initial values are set for each flag. As the initial value of each flag, "off" or "0" is set unless otherwise specified.

Further, in the initial setting process, after the initial setting of the image controller 437 is performed, an image is drawn on the image controller 437 so that the image of a specific color is displayed on the entire screen on the third symbol display device 281. And instruct to execute the display process. As a result, immediately after the power is turned on, the third symbol display device 281 first displays an image of a specific color on the entire screen. Here, the color of the image displayed on the entire screen of the third symbol display device 281 immediately after the power is turned on is set to be different depending on the model of the pachinko machine. As a result, in the operation check in the factory or the like at the time of manufacturing, the pachinko machine 200 is inspected whether or not the image of the color corresponding to the model is displayed on the third symbol display device 281 immediately after the power is turned on. It is possible to easily and immediately determine whether or not the startup has started normally.

Next, a transfer instruction is transmitted to the image controller 437 so that the image data corresponding to the main image at power-on is transferred to the main image area 435a at power-on of the resident video RAM 435 (S2203). In this transfer instruction, the start address and the last address of the character ROM 434 in which the image data corresponding to the main image at power-on is stored, the information of the transfer destination (here, the resident video RAM 435), and the transfer destination. The start address of the main image area 435a at power-on is included, and the image controller 437 receives the image data corresponding to the main image at power-on from the character ROM 434 to the power-on main of the resident video RAM 435 according to this transfer instruction. It is transferred to the image area 435a.

Then, when all the transfer of the image data indicated by the transfer instruction is completed, the image controller 437 transmits a transfer end signal indicating the end of transfer to the MPU 431. By receiving this transfer end signal, the MPU 431 can grasp that the transfer of the image data specified in the transfer instruction has been completed. When the image controller 437 completes the transfer of all the image data indicated by the transfer instruction, the image controller 437 transmits the transfer end information indicating the transfer end to a register provided inside the image controller 437 or a part of the built-in memory. You may write it. Then, the MPU 431 reads the information of a part of the register or the built-in memory at any time, and detects the writing of the transfer end information by the image controller 437, thereby grasping that the transfer of the image data specified by the transfer instruction is completed. You may do so.

The image data transferred to the main image area 435a when the power is turned on is retained so as not to be overwritten until the power is turned off.

When the transfer of the image data corresponding to the power-on main image to the power-on main image area 435a is completed based on the transfer instruction transmitted to the image controller 437 by the process of S2203, then the power-on variable image A transfer instruction is transmitted to the image controller so as to transfer the image data corresponding to the above to the variable image area 435b when the power of the resident video RAM 435 is turned on (S2204). In this transfer instruction, the start address of the character ROM 434 in which the image data corresponding to the fluctuating image when the power is turned on, the data size of the image data, and the transfer destination information (here, the resident video RAM 435) are included. , The start address of the power-on variable image area 435b, which is the transfer destination, is included, and the image controller receives the image data corresponding to the power-on variable image from the character ROM 434 to the resident video RAM 435 according to this transfer instruction. It is transferred to the variable image area 435b when the power is turned on. Then, the image data transferred to the variable image area 435b when the power is turned on is held so as not to be overwritten until the power is turned off.

When the transfer of the image data corresponding to the power-on variable image to the power-on variable image area 435b is completed based on the transfer instruction transmitted to the image controller 437 by the process of S2204, then the simple image display flag 433c Is turned on (S2205). As a result, while the simple image display flag 433c is on, all the image data that should be resident in the resident video RAM 435 is transferred from the character ROM 434 to the resident video RAM 435 in the transfer setting process (see FIG. 85 (a)) described later. A resident image transfer setting process for instructing the image controller 434 to transfer is executed (see S3002 in FIG. 85 (a)).

Further, the simple image display flag 433c transfers all the image data to be resident in the resident video RAM 435 from the character ROM 434 to the resident video RAM 435 based on the transfer instruction to the image controller 434 by the resident image transfer setting process. It stays on until it finishes. Thereby, in the meantime, in the V interrupt process (see FIG. 74 (b)), a simple command is drawn so that the power-on image (power-on main image and power-on fluctuation image) shown in FIG. 54 is drawn. The determination process (see S2408 in FIG. 74 (b)) and the simple display setting process (see S2409 in FIG. 74 (b)) are executed.

As described above, in the pachinko machine 200, since the NAND flash memory 434a is used for the character ROM 434, all the image data to be stored in the resident video RAM 435 due to the slow read speed of the character ROM 434 can be stored in the resident video RAM 435. It takes a lot of time to transfer from the character ROM 434 to the resident video RAM 435. Therefore, as in this main process, after the power is turned on, the main image when the power is turned on and the variable image when the power is turned on are first transferred from the character ROM 434 to the resident video RAM 435, and the main image when the power is turned on is the third. By displaying the image on the symbol display device 281, while the remaining image data to be resident is transferred to the resident video RAM 435, the player or the person concerned with the hall can turn on the power displayed on the third symbol display device 281. You can check the main image. Therefore, the display control device 314 transfers the remaining resident image data from the character ROM 434 to the resident video RAM 435 over time while the main image at power-on is displayed on the third symbol display device 314. be able to. On the other hand, the player or the like can recognize that some initialization processing is being performed while the main image is displayed on the third symbol display device 281 when the power is turned on, so that the player or the like resides in the remaining resident video RAM 435. Until the image data to be transferred is transferred from the character ROM 434 to the resident video RAM 435, it is possible to wait until the initialization is completed without worrying about whether the operation has stopped.

Further, even in the operation check in the factory at the time of manufacturing, the main image at the time of turning on the power is immediately displayed on the third symbol display device 281, so that the operation of the third symbol display device 281 is started without any problem by turning on the power. By using the NAND flash memory 434a having a slow read speed for the character ROM 434, it is possible to prevent the efficiency of the operation check from deteriorating.

Further, in the display control device 314 of the pachinko machine 200, after the power is turned on, the power-on fluctuation image is also transferred from the character ROM 434 to the resident video RAM 435 together with the power-on main image, so that the power-on main image is the third symbol. Since the player started the game while it was displayed on the display device 281, there was a ball entering (starting prize) at the first entry port 264, and the start instruction of the variation effect was controlled by the voice lamp from the main control device 310. When the display variation pattern command is received via the device 313, that is, when the variation pattern command for display is received, the variation image at power-on shown in FIGS. 54 (b) and 54 (c) is immediately displayed during the variation effect period. A simple variable effect can be performed. Therefore, the player can confirm that the lottery has been surely performed by the simple variation effect even while the main image at the time of turning on the power is displayed on the third symbol display device 281.

Further, as described above, while the remaining image data to be resident is transferred from the character ROM 434 to the resident video RAM 435, the main image is continuously displayed on the third symbol display device 281 when the power is turned on, but the character ROM 434 is displayed. Is composed of a NAND flash memory 434a having a slow read speed, so that it takes time to transfer the data. Therefore, after the power is turned on, the main image is continuously displayed at the time of turning on the power for a long time. However, in this pachinko machine 200, since a simple fluctuation effect can be performed using the fluctuation image at power-on transferred to the resident video RAM 435 after the power is turned on, for example, a power failure recovery is performed immediately after the power is turned on. Immediately after, even while the main image is displayed when the power is turned on, the player can play the game with peace of mind.

After the process of S2205, the interrupt permission is set (S2206), and thereafter, the main process executes an infinite loop process until the power is turned off. As a result, after the interrupt permission is set by the process of S2206, the command interrupt process and the V interrupt process are executed according to the reception of the command and the detection of the V interrupt signal.

Next, the command interrupt process executed by the MPU 431 of the display control device 314 will be described with reference to FIG. 74 (a). FIG. 74 (a) is a flowchart showing the command interrupt process. As described above, when a command is received from the voice lamp control device 313, the command interrupt process is executed by the MPU 431.

In this command interrupt process, the received command data is extracted, the extracted command data is sequentially stored in the command buffer area provided in the work RAM 433 (S2301), and the process is terminated. Various commands stored in the command buffer area by this command interrupt process are read by the command determination process or the simple command determination process of the V interrupt process described later, and the process corresponding to the command is performed.

Next, the V interrupt process executed by the MPU 431 of the display control device 314 will be described with reference to FIG. 74 (b). FIG. 74B is a flowchart showing the V interrupt process. In this V interrupt process, various processes corresponding to the commands stored in the command buffer area are executed by the command interrupt process, and after specifying the image to be displayed on the third symbol display device 281, the image is drawn. By creating a list (see FIG. 60) and transmitting the drawing list to the image controller 437, the image controller 437 is instructed to execute the drawing process and the display processing of the image.

As described above, the execution of this V interrupt process is started when the V interrupt signal from the image controller 437 is detected. This V interrupt signal is a signal generated by the image controller 437 every 20 milliseconds when the drawing process of an image for one frame is completed and transmitted to the MPU 431. Therefore, by executing the V interrupt process in synchronization with this V interrupt signal, a drawing instruction is given to the image controller 437 every 20 milliseconds when the drawing process of the image for one frame is completed. become. Therefore, in the image controller 437, since the drawing instruction of the next image is not received at the stage where the drawing processing and the display processing of the image are not completed, the drawing of a new image may be started in the middle of drawing the image. It is possible to prevent the image from being expanded in accordance with a new drawing instruction in the frame buffer in which the image information being displayed is stored.

Here, first, the outline of the flow of the V interrupt processing will be described, and then the details of each processing will be described with reference to other drawings. In this V interruption process, as shown in FIG. 74 (b), first, it is determined whether or not the simple image display flag 433c is on (S2401), and the simple image display flag 433c is not on, that is, If it is off (S2401: No), it means that the transfer of all the image data that should be resident in the resident video RAM 435 is completed. In order to display the image on the third symbol display device 281, the command determination process (S2402) is executed, and then the display setting process (S2403) is executed.

In the command determination process (S2402), the content of the command from the voice lamp control device 313 stored in the command buffer area is analyzed by the command interrupt process, the process corresponding to the command is executed, and the display demo command and the display demo command are executed. When the display variation pattern command is stored, the demo display data table or the variation display data table according to the variation pattern type is set in the display data table buffer 433d and corresponds to the set display data table. The transfer data table is set in the transfer data table buffer 433f. When the continuous advance notice command is stored, the continuous advance notice additional data table according to the continuous advance notice image type is set in the additional data table buffer 433e.

In this command determination process, all commands stored in the command buffer area at that time are analyzed and the process is executed. This is because the command determination process is performed at intervals of 20 milliseconds when the V interrupt process is executed, so there is a high possibility that multiple commands are stored in the command buffer area during that 20 milliseconds. be. In particular, when the start of the variation effect is determined in the main control device 310, there is a high possibility that the variation pattern command for display, the stop type command, the continuous notice command, and the like are simultaneously stored in the command buffer area. Therefore, by analyzing and executing these commands at once, it is possible to quickly grasp the mode of the variable effect and the continuous advance notice effect selected by the main control device 310 and the audio lamp control device 313, and the effect image corresponding to the mode. Can be controlled to be displayed on the third symbol display device 281. The details of this command interrupt process will be described later with reference to FIGS. 75 to 79.

In the display setting process (S2403), the third symbol display device 281 is based on the contents of the display data table and the additional data table set in the display data table buffer 433d and the additional data table buffer 433e by the command determination process (S2402) or the like. Next, the content of the image for one frame to be displayed is specifically specified. Further, the effect mode to be displayed on the third symbol display device 281 is determined according to the processing status and the like, and the display data table corresponding to the determined effect mode is set in the display data table buffer 433d. The details of this display setting process will be described later with reference to FIGS. 80 to 84.

After the display setting process is executed, the task process is then executed (S2404). In this task process, the image is configured based on the content of the image for the next frame to be displayed on the third display device 281 specified by the display setting process (S2403) or the simple display setting process (S2409). In addition to specifying the type of sprite (display object), various parameters necessary for drawing such as display coordinate position, enlargement ratio, and rotation angle are determined for each sprite.

Next, the transfer setting process is executed (S2405). In this transfer setting process, while the simple image display flag 433c is on, the image controller 437 transfers the image data to be resident in the resident video RAM 435 from the character ROM 434 to a predetermined area of the resident video RAM 435. Set instructions. Further, while the simple image display flag 433b is off, predetermined image data is normally used from the character ROM 434 to the image controller 437 based on the transfer data information of the transfer data table set in the transfer data table buffer 433f. Even when a transfer instruction to be transferred to a predetermined sub-area of the image storage area 436a of the video RAM 436 is set and a continuous notice command or a rear image change command is received from the voice lamp control device 313, the image controller 437 is continuously connected. A transfer instruction is set to transfer the image data of the continuous preview image used in the preview effect and the image data of the rear image after the change from the character ROM 434 to the predetermined sub-area of the image storage area 436a of the normal video RAM 436.

Next, the drawing process is executed (S2406). In this drawing process, the types of various sprites constituting one frame, the parameters required for drawing each sprite, and the transfer instruction set by the transfer setting process (S2405), which are determined in the task process (S2404), are used. , The drawing list shown in FIG. 60 is generated, and the drawing list is transmitted to the image controller 437 together with the drawing target buffer information. As a result, the image controller 437 executes the image drawing process according to the drawing list. The details of the drawing process will be described later with reference to FIG. 87.

Next, the update processing of various counters provided in the display control device 314 is executed (S2407). Then, the V interrupt process is terminated. As a counter updated by the process of S2407, for example, there is a stop symbol counter (not shown) for determining a stop symbol. The value of this stop symbol counter is stored in the work RAM 433, and the update process is performed every time the V interrupt process is executed. Then, when the reception of the display stop type command is detected in the command determination process, the stop type indicated by the display stop type command (15R probability variation jackpot, 2R probability variation jackpot, time saving jackpot, front / rear deviation reach, reach other than front / rear deviation) , Completely off) and the stop type counter are compared, and the stop symbol after the variation effect displayed on the third symbol display device 281 is finally set.

On the other hand, if it is determined in the process of S2401 that the simple image display flag is on (S2401: Yes), it means that the transfer of all the image data that should be resident in the resident video RAM 435 has not been completed. , The simple command determination process (S2408) is executed in order to display the power-on image shown in FIG. 54 on the third symbol display device 281, and then the simple display setting process (S2409) is executed to process S2404. Move to.

Next, with reference to FIGS. 75 to 79, the details of the above-mentioned command determination process (S2402), which is one of the V interrupt processes executed by the MPU 431 of the display control device 314, will be described. First, FIG. 75 is a flowchart showing this command determination process.

In this command determination process, as shown in FIG. 75, first, it is determined whether or not there is an unprocessed new command in the command buffer area (S2501), and if there is no unprocessed new command (S2501: No), The command judgment process is terminated and the process returns to the V interrupt process. On the other hand, if there is an unprocessed new command (S2501: Yes), the new command flag that notifies the display setting process (S2403) that the new command has been processed in the ON state is set to ON (S2502), and then the command. The type of the unprocessed command stored in the buffer area is analyzed (S2503).

Then, first, it is determined whether or not there is a hold ball number command for display among the unprocessed commands (S2504), and if there is a hold ball number command for display (S2504: Yes), the hold ball number command process is performed. Is executed (S2505), and the process returns to the process of S2501.

Here, the details of the reserved ball number command processing (S2505) will be described with reference to FIG. 76 (a). FIG. 76A is a flowchart showing the reserved ball number command processing. This hold ball number command process executes the process corresponding to the display hold ball number command received from the voice lamp control device 314.

In the hold ball count command processing, first, the new hold ball count command flag that notifies the display setting process (S2403) that the display hold ball count command has been processed in the on state is turned on (S2601), and then the display hold ball count command is turned on (S2601). Acquires the reserved ball number information included in the ball number command (S2602). If two or more display hold ball count commands are stored in the command buffer area in the process of S2602, the hold ball count information is acquired from the display hold ball count command stored last. As a result, the latest information on the number of reserved balls can be obtained.

Then, among the number determination flags provided for each number of reserved balls, the number determination flag corresponding to the number of reserved balls acquired in the process of S2602 is turned on, and the number determination flags corresponding to the other number of reserved balls are turned off. (S2603), the process returns to the command determination process.

As a result, in the display setting process, when the new reserved ball count command flag is on, by referring to the number determination flag, the number of reserved balls for the number of reserved balls corresponding to the number determination flag for which the on is set is set. Is displayed on the third symbol display device 281 to expand the reserved image data.

Returning to FIG. 75, when it is determined that there is no display reserved ball count command in the processing of S2504 (S2504: No), then it is determined whether or not there is a display confirmation command among the unprocessed commands. Then (S2506), if there is a confirmation command for display (S2506: Yes), the confirmation command process is executed (S2507), and the process returns to the process of S2501.

Here, the details of the confirmation command processing (S2507) will be described with reference to FIG. 76 (b). FIG. 76B is a flowchart showing the confirmation command processing. This confirmation command processing executes the processing corresponding to the display confirmation command received from the voice lamp control device 314.

In the confirmation command processing (S2507), the confirmation command flag for notifying the display setting processing (S2403) that the display confirmation command is received in the ON state is set to ON (S2611), this processing is terminated, and the command is determined. Return to processing. As a result, in the display setting process, the state of the confirmation command flag is monitored, and when the flag is turned on, the display setting process is started so that the display of the confirmation display effect is started on the third symbol display device 281. To execute. Further, when the display setting of the variable effect is processed and the confirmation command flag is not turned on even after the effect time set for the variable effect has elapsed, the restart effect is displayed on the third symbol display device 281. Execute the display setting process so that it will be displayed.

Returning to FIG. 75, when it is determined that there is no display confirmation command in the processing of S2506 (S2506: No), then it is determined whether or not there is a display demo command among the unprocessed commands (S2506: No). S2508) If there is a display demo command (S2508: Yes), the demo command process is executed (S2509), and the process returns to the process of S2501.

Here, the details of the demo command processing (S2509) will be described with reference to FIG. 76 (c). FIG. 76C is a flowchart showing demo command processing. This demo command process executes the process corresponding to the display demo command received from the voice lamp control device 314.

In the demo command process (S2509), first, the demo display data table corresponding to the demo effect is selected from the data table storage area 433b and set in the display data table buffer 433d (S2621). Next, the contents are cleared by writing the Null data to the additional data table buffer 433e, and in the demo display data table, it is necessary to newly transfer the image data necessary for drawing from the character ROM 434 to the normal video RAM 436. Since the drawing of the image is specified so that the image is not drawn, the corresponding transfer data table is not prepared in the data table storage area 433b. Therefore, the Bull data is also written to the transfer data table buffer 433f to clear the contents (S2622). ).

Next, the time data corresponding to the demo effect is set in the timekeeping counter 433i (S2623), and the pointer 433g is initialized to 0 (S2624). Then, the demo display flag indicating that the demo effect is displayed in the on state of the third symbol display device 281 is set to on, and the confirmed display effect is displayed on the third symbol display device 281 in the on state. The confirmation display flag shown is set to off, and the confirmation display flag indicating that the confirmation display effect is being performed in the on state is set to off (S2625), the demo command processing is terminated, and the process returns to the command determination processing.

By executing this demo command processing, in the display setting processing, while updating the pointer 433g initialized by the processing of S2624, from the demo display data table set in the display data table buffer 433d by the processing of S2621. , The drawing content defined by the address indicated by the pointer 433g is extracted, and the content of the image for one frame to be displayed next on the third symbol display device 281 is specified. Further, in the display setting process, the time of the demo effect specified in the demo display data table is timed by using the time counter 433i in which the time data corresponding to the demo effect is set by the process of S2623, and the process of S2625 is performed. When it is determined by the timekeeping of the display setting control timekeeping counter 433i that the demo effect in the demo display data table has been completed based on the states of the demo display flag and the confirmed display flag set by, the next effect to be displayed. As a result, control is performed so that the demo effect is displayed again.

Returning to FIG. 75, when it is determined that there is no display demo command in the processing of S2508 (S2508: No), then it is determined whether or not there is a display variation pattern command among the unprocessed commands. (S2510) If there is a display variation pattern command (S2510: Yes), the variation pattern command process is executed (S2511), and the process returns to the process of S2501.

Here, the details of the variation pattern command processing (S2511) will be described with reference to FIG. 77 (a). FIG. 77A is a flowchart showing the variation pattern command processing. This variation pattern command processing executes the processing corresponding to the display variation pattern command received from the voice lamp control device 314.

In the variation pattern command processing, first, a variation display data table corresponding to the variation effect pattern indicated by the display variation pattern command is determined, and the determined variation display data table is read from the data table storage area 433b and displayed. It is set in the data table buffer 433d (S2631).

Here, since the determination of the start of fluctuation is always performed in the main control device 310 at a distance of several seconds or more, two or more display fluctuation pattern commands are not received within 20 milliseconds, and therefore, the command determination process is performed. When executing, it is impossible that two or more display fluctuation pattern commands are stored in the command buffer area, but a part of the command changes due to the influence of noise etc., and another command is mistakenly for display. It may be interpreted as a variation pattern command. In the process of S2631, in preparation for such a case, when it is determined that two or more display variation pattern commands are stored in the command buffer area, the variation display data corresponding to the variation pattern having the shortest variation time Set the table in the display data table buffer 433d.

If the display data table for variation corresponding to the variation pattern having a long variation time is set in the display data table buffer 433d, the variation effect having a shorter variation time than the set display data table is actually the main control. When instructed by the device 310, a confirmation command (display confirmation command) is given from the main control device 310 while the third symbol display device 281 is displaying the variation effect according to the set variation display data table. ) Will be received, and the changing third symbol will be suddenly stopped and displayed, which may give the player a sense of discomfort.

On the other hand, by setting the display data table for variation corresponding to the variation pattern having the shortest variation time in the display data table buffer 433d as in the present embodiment, the display data table is actually longer than the set display data table. Even when the variation effect having the variation time is instructed by the main control device 310, as will be described later, after the variation effect according to the display data table buffer 433d is completed, the confirmation command from the main control device 310 Since the display of the third symbol display device 281 is controlled by the display setting process so that the restart effect is displayed until the (display confirmation command) is received, the player changes the restart effect. It can be visually recognized as a part of the effect, and the fluctuation of the third symbol in the third symbol display device 281 can be continuously observed until the stop display of the third symbol is confirmed.

Next, the transfer data table corresponding to the display data table set in S2631 is determined, read from the data table storage area 433b, and set in the transfer data table buffer 433f (S2632). Then, the contents are cleared by writing Null data to the additional data table buffer 433e (S2633).

After that, among the data table discrimination flags provided for each fluctuation display data table corresponding to each fluctuation pattern, the data table discrimination flag corresponding to the fluctuation display data table set by the processing of S2631 is turned on, and other data tables are discriminated. The data table discrimination flag corresponding to the variable display data table of is set to off (S2634). In the display setting process, by referring to the data table discrimination flag set by the process of S2634, it is easy to determine which variation pattern the variation display data table set in the display data table buffer 433d corresponds to. Can be judged. Then, in the display setting process, it is determined whether or not there is a contradiction between the fluctuation pattern of the set fluctuation display data table and the stop symbol set by the display stop type command received later, and if there is a contradiction. Is configured to set the display data table corresponding to the special variation in the display data table buffer 433d, as will be described later.

Next, based on the fluctuation time of the fluctuation pattern corresponding to the fluctuation display data table set in the display data table buffer 433d by the processing of S2631, time data representing the fluctuation time is set in the timekeeping counter 433i (S2635). Initialize the pointer 433g to 0 (S2636). Then, the confirmation command flag, the demo display flag, and the confirmation display flag are all set to off (S2637), and the restart timer counter used in the display setting process is initialized to 0 (S2638). Is terminated, and the process returns to the command judgment process.

By executing this variation pattern command process, in the display setting process, the pointer 433g initialized by the process of S2636 is updated, and the variation display data table set in the display data table buffer 433d by the process of S2631 is executed. Extracts the drawing content specified at the address indicated by the pointer 433g from, and specifies the content of the image for one frame to be displayed next in the third symbol display device 281. At the same time, the transfer data table buffer is processed by S2632. The transfer data information specified at the address indicated by the pointer 433g is extracted from the transfer data table set in 433f, and the sprite image data required in the set variation display data table is preliminarily used from the character ROM 434 for normal use. The image controller 437 is controlled so as to be transferred to the image storage area 436a of the video RAM 436.

Further, in the display setting process, the time of the variation effect specified in the variation display data table is timed by using the clock counter 433i in which the variation time data is set by the process of S2635, and the variation effect in the variation display data table is measured. If it is determined that the confirmation command (display confirmation command) from the main control device 310 is received, the confirmation display effect is displayed on the third symbol display device 281 and confirmed within a predetermined time after the variation effect is completed. If the command (display confirmation command) cannot be received, the display setting is controlled so that the restart effect is displayed on the third symbol display device 281.

Here, if both the display confirmation command and the display variation pattern command are stored in the command buffer area as unprocessed commands, if the processing corresponding to the display confirmation command is prioritized, the display is used. Since the variation effect associated with the variation pattern command will not be performed, it is necessary to give priority to the processing corresponding to the variation pattern command for display. On the other hand, in this command judgment process, the presence or absence of the display confirmation command is determined first, so that the confirmation command processing, which is the process corresponding to the display confirmation command, is always executed first, while the display is displayed. The process corresponding to the variation pattern command is executed later, and the confirmation command flag set by the confirmation command for display can be set to off by overwriting as in the process of S2637. Therefore, the processing of the display variation pattern command can be prioritized over the display confirmation command, and the variation effect accompanying the display variation pattern command can be prioritized and displayed on the third symbol display device 281.

Similarly, if both the display demo command and the display variation pattern command are stored in the command buffer area as unprocessed commands, if the processing corresponding to the display demo command is prioritized, it is for display. Since the variation effect associated with the variation pattern command will not be performed, it is necessary to give priority to the processing corresponding to the variation pattern command for display. On the other hand, in this command judgment process, the presence or absence of the display demo command is determined first, so that the demo command process, which is the process corresponding to the display demo command, is always executed first, while the display is displayed. The process corresponding to the variation pattern command is executed later, and the demo display data table set in the display data table buffer 433d by the display demo command is rewritten to the variation display data table by overwriting as in the process of S2631. Can be done. Therefore, the processing of the display variation pattern command can be prioritized over the display demo command, and the variation effect accompanying the display variation pattern command can be prioritized and displayed on the third symbol display device 281.

Returning to FIG. 75, when it is determined that there is no display variation pattern command in the processing of S2510 (S2510: No), then it is determined whether or not there is a display stop type command among the unprocessed commands. If there is a display variation type command (S2511: Yes), the stop type command process is executed (S2513), and the process returns to the process of S2501.

Here, the details of the stop type command processing (S2513) will be described with reference to FIG. 77 (b). FIG. 77B is a flowchart showing the stop type command processing. This stop type command process executes the process corresponding to the display variation type command received from the voice lamp control device 314.

In the variable type command processing, first, the stop corresponding to the stop type information (15R probability variation jackpot, 2R probability variation jackpot, time saving jackpot, front / rear out reach, reach other than front / rear out, or complete out) indicated by the display stop type command. The type table is determined (S2641), and the stop type table is compared with the value of the stop type counter that is updated every time the V interrupt process (see FIG. 74 (b)) is executed, and the third symbol is used. The stop symbol after the variation effect displayed on the display device 281 is finally set (S2642).

Then, among the stop symbol discrimination flags provided for each stop symbol, the stop symbol discrimination flag corresponding to the stop symbol set by the process of S2642 is turned on, and the stop symbol discrimination flag corresponding to other stop symbols is set. Set to off (S2643).

Here, as described above, in the variation display data table, the type information that specifies the third symbol to be displayed on the third symbol display device 281 after a predetermined time has elapsed from the start of the variation based on the data table. , The offset information (symbol offset information) from the stop symbol set by the process of S2642 is described. In the above-mentioned task processing (S2404), after a predetermined time has elapsed from the start of the fluctuation, the stop symbol set by the processing of S2642 is specified from the stop symbol determination flag set by S2643, and the specified stop is specified. By adding the symbol offset information acquired by the display setting process to the symbol, the third symbol to be actually displayed is specified. Then, the address in which the image data corresponding to the specified third symbol is stored is specified. As described above, the image data corresponding to the third symbol is stored in the third symbol area 435d of the resident video RAM 435.

After the processing of S2643, the comparison flag is then turned on (S2644) to end this stop type command processing, and the process returns to the command determination processing. By turning on this comparison flag, in the display setting process, whether or not there is a contradiction between the variation pattern of the variation display table set by the above variation pattern command setting process and the stop symbol set by the process of S2642. If there is a contradiction, the display data table corresponding to the special variation is set in the display data table buffer 433d as described later.

Since the determination of the start of the fluctuation is always performed in the main control device 310 at a distance of several seconds or more, the display stop type command for two or more is not received within 20 milliseconds, and therefore the command determination process is executed. In this case, it is impossible that two or more display stop type commands are stored in the command buffer area, but part of the command changes due to the influence of noise, etc., and another command is mistakenly stopped for display. It may be interpreted as a type command. In the process of S2641, in preparation for such a case, if it is determined that two or more display stop type commands are stored in the command buffer area, it is assumed that the stop type is completely out of order, and the stop type is completely out of order. Determine the table. As a result, the stop symbol corresponding to the complete deviation is set by the process of S2642.

If the stop symbol corresponding to the jackpot is set, the stop symbol of the jackpot will be displayed on the third symbol display device 281 even if it is actually off, and the player The game state of the pachinko machine 200 was misunderstood as a big hit, and there was a risk that the reliability of the pachinko machine 200 would be lowered. On the other hand, as in the present embodiment, by setting the stop symbol corresponding to the complete disengagement, in fact, if it is a big hit, the completely disengaged stop symbol is displayed on the third symbol display device 281. However, since the gaming state of the pachinko machine 200 shifts to the jackpot state, the player can be pleased.

Returning to FIG. 75, when it is determined that there is no display stop type command in the processing of S2512 (S2512: No), then it is determined whether or not there is a continuous warning command among the unprocessed commands (S2512: No). S2514) If there is a continuous notice command (S2514: Yes), the continuous notice command process is executed (S2515), and the process returns to the process of S2501.

Here, the details of the continuous advance notice command processing (S2515) will be described with reference to FIG. 78 (a). FIG. 78 (a) is a flowchart showing continuous advance notice command processing. This continuous advance notice command process executes the process corresponding to the continuous advance notice command received from the voice lamp control device 314.

In the continuous notice command processing, first, a new continuous notice command flag for notifying the transfer setting process (S2405) that the continuous notice command has been processed in the ON state is set to ON (S2651). Next, the additional data table for continuous notice corresponding to the continuous notice image type (one of "bubble", "tamago", "chick", "chicken", and "chicken group") indicated by the continuous notice command is determined. , The determined additional data table for continuous advance notice is read from the data table storage area 433b, and it is set in the additional data table buffer 433e.

As a result, in the display setting process, the effect corresponding to the display data table stored in the display data table buffer 433d is continuously corresponding to the continuous advance notice additional data table stored in the additional data table buffer 433e by the process of S2652. The display content of the next one frame of the image in the third symbol display device 281 is specified so that the advance notice effect is additionally displayed.

After that, among the continuous advance notice determination flags provided for each continuous advance notice image type, the continuous advance notice determination flag corresponding to the continuous advance notice image type included in the continuous advance notice command is turned on, and the continuous advance notice image types corresponding to other continuous advance notice image types are turned on. The advance notice determination flag is set to off (S2653), the continuous advance notice command processing is terminated, and the process returns to the command determination processing.

In the transfer setting process, when it is detected that the new continuous advance notice command flag set by the process of S2651 is turned on, it is said that a predetermined additional data table for continuous advance notice is set in the additional data table buffer 433e by the continuous advance notice command process. Judgment is made, and the continuous notice type corresponding to the continuous notice additional data table set in the additional data table buffer 433e is specified from the continuous notice determination flag set by the process of S2653. Then, the image controller 437 is instructed to transfer the image data necessary for displaying the specified continuous advance notice type.

Returning to FIG. 75, when it is determined that there is no continuous advance notice command in the processing of S2514 (S2514: No), then it is determined whether or not there is a rear image change command among the unprocessed commands (S2516). ), If there is a rear image change command (S2516: Yes), the rear image change command process is executed (S2517), and the process returns to S2501.

Here, the details of the rear image change command processing (S2517) will be described with reference to FIG. 78 (b). FIG. 78B is a flowchart showing the rear image change command process. This rear image change command process executes the process corresponding to the rear image change command received from the voice lamp control device 314.

In the rear image change command process, first, the rear image change flag for notifying the transfer setting process (S2405) of the change of the rear image due to the reception of the rear image change command in the on state is set to on (S2661). Then, among the rear image discrimination flags provided for each rear image type (back A to C), the rear image discrimination flag corresponding to the rear image type indicated by the rear image change command is turned on, and other rear images are turned on. The rear image discrimination flag corresponding to the type is set to off (S2662), the rear image change command process is terminated, and the process returns to the command determination process.

In the transfer setting process, when it is detected that the rear image change flag set by the process of S2661 is turned on, the rear image type after the change is specified from the rear image discrimination flag set by the process of S2662. When the specified back image type is back B or back C, as described above, a part of the image data corresponding to those back images is resident in the back image area 435c of the resident video RAM 435. Therefore, the transfer instruction is set to the image controller 437 so that the image data corresponding to the rear image in the predetermined range is transferred from the character ROM 434 to the predetermined sub area of the image storage area 436a of the normal video RAM 436.

Further, in the task processing, when it is specified to display any of the backsides A to C according to the backside type of the backside image specified in the display data table, the backside image discrimination flag set by S2662 is used. The type of back image to be displayed at the time is specified, and the range of the back image to be displayed is specified according to the passage of time, and the RAM type (resident) in which the image data corresponding to the range of the back image is stored. Video RAM 435 or normal video RAM 436) and the address of the RAM are specified.

Since the player does not continuously operate the frame button 222 in 20 milliseconds or less, he / she does not receive two or more rear image change commands within 20 milliseconds, and therefore, the command determination process is executed. In that case, there should be no case where two or more back image change commands are stored in the command buffer area, but part of the command changes due to the influence of noise etc., and another command mistakenly changes the back image. It may be interpreted as a command. In the process of S2662, when it is determined that two or more rear image commands are stored in the command buffer area, the rear image discrimination flag corresponding to the rear image type indicated by the previously received rear image command is turned on. Alternatively, the rear image discrimination flag corresponding to the rear image type indicated by the rear image command received later may be turned on. Further, any one rear image change command may be extracted and the rear image discrimination flag corresponding to the rear image type indicated by the command may be turned on. Since this change in the rear image does not directly affect the gaming value of the pachinko machine 200, it is preferable to appropriately set the change according to the characteristics and operability of the pachinko machine 200.

Returning to FIG. 75, when it is determined that there is no rear image change command in the processing of S2516 (S2516: No), then it is determined whether or not there is a frame button operation command among the unprocessed commands (S2516: No). S2518), if there is a frame button operation command (S2518: Yes), the frame button operation command process is executed (S2519), and the process returns to the process of S2501.

Here, the details of the frame button operation command processing (S2519) will be described with reference to FIG. 79 (a). FIG. 79A is a flowchart showing the frame button operation command processing. This frame button operation command process executes the process corresponding to the frame button operation command received from the voice lamp control device 314.

In the frame button operation command, the frame button operation flag indicating that the frame button has been operated in the on state is set to on (S2671), this process is terminated, and the process returns to the command determination process.

In the display setting process, the frame button was operated while the super reach selection screen was displayed on the third symbol display device 281 according to the variable display data table based on the frame button operation flag set by the process of S2671. Is detected, the process of updating the type of super reach to be displayed later is executed. This allows the player to select his / her favorite super reach effect.

Returning to FIG. 75, when it is determined that there is no frame button operation command in the processing of S2518 (S2518: No), then it is determined whether or not there is an error command among the unprocessed commands (S2520). If there is an error command (S2520: Yes), the error command processing is executed (S2521), and the process returns to the processing of S2501.

Here, the details of the error command processing (S2521) will be described with reference to FIG. 79 (b). FIG. 79B is a flowchart showing error command processing. This error command processing executes the processing corresponding to the error command received from the voice lamp control device 314.

In the error command processing, first, the error occurrence flag indicating that an error has occurred in the on state is set to on (S2681). Then, among the error discrimination flags provided for each error type, the error discrimination flag corresponding to the error type indicated by the error command is turned on, and the other error discrimination flags are set to off (S2682), and the error command is used. Ends the process and returns to the command judgment process.

In the display setting process, when an error is detected based on the error occurrence flag set by the process of S2681, the error type generated from the error discrimination flag set by the process of S2682 is determined, and the error type is dealt with. The process is executed so that the warning image to be displayed is displayed on the third symbol display device 281.

When it is determined that two or more error commands are stored in the command buffer area, the error discrimination flag corresponding to all the error types indicated by each error command is set to ON in the process in S2682. As a result, the warning images corresponding to all the error types are displayed on the third symbol display device 281 so that the player and the person concerned with the hall can correctly grasp the error occurrence status.

Returning to FIG. 75, if it is determined that there is no error command in the process of S2520 (S2520: No), then the process corresponding to the other unprocessed command is executed (S2522), and the process returns to the process of S2501.

In the processing of S2501 that is executed again after the processing of each command is executed, it is determined again whether or not there is an unprocessed new command in the command buffer area, and if there is an unprocessed new command (S2501: Yes). ), The processing of S2502 to S2522 is executed again. Then, the processes of S2501 to S2522 are repeatedly executed until there are no unprocessed new commands in the command buffer area, and when it is determined in the process of S2501 that there are no unprocessed new commands in the command buffer area, this command determination is made. End the process.

The simple command determination process (S2408) executed when the simple image display flag 433c is turned on in the V interrupt process (see FIG. 74 (b)) is also the same as the command determination process. However, in the simple command determination process, the commands required to display the power-on image shown in FIG. 54 from the unprocessed commands stored in the command buffer area, that is, the display table confirmation command and the display variation pattern. Confirmation command processing (see FIG. 76 (b)), variation pattern command processing (see FIG. 77 (a)), and stop type, which are processes corresponding to each command by extracting only the command and the stop type command for display. A command process (see FIG. 77 (c)) is executed, and other commands are discarded without executing the process corresponding to the command.

Here, in the variation pattern command process (see FIG. 77 (a)) executed in this case, the display data table buffer corresponding to the display of the variation image at power-on is changed to the display data table buffer 433d in the process of S2631. The image data of the main image at power-on and the variable image at power-on, which are set and required in that case, are stored in the main image area 435a at power-on and the variable dynamic image area 435b at power-on of the resident video RAM 435. Therefore, in the process of S2632, the process of writing the Null data to the transfer data table buffer 433b and clearing the contents thereof is performed.

Next, with reference to FIGS. 80 to 84, the details of the above-mentioned display setting process (S2403), which is one of the V interrupt processes executed by the MPU 431 of the display control device 314, will be described. First, FIGS. 80 and 81 are flowcharts showing this display setting process.

In this display setting process, as shown in FIG. 80, it is determined whether or not the new command flag is on (S2701), and if the new command flag is not on, that is, it is off (S2701: No). It is determined that the new command has not been processed in the command determination process executed first, the processes of S2702 to S2710 are skipped, and the process proceeds to the process of S2711. On the other hand, if the new flag is on (S2701: Yes), it is determined that the new command has been processed in the command determination process executed first, and after the new command flag is set to off (S2702), S2703 to S2710. Executes the process corresponding to the new command by the process of.

In the process of S2703, it is determined whether or not the new reserved ball count command flag is on (S2703), and if the new reserved ball count command flag is on (S2703: Yes), it is for display in the previous command determination process. It is determined that the hold ball count command has been processed, and the hold image setting process is executed (S2704).

Here, the details of the reserved image setting process will be described with reference to FIG. 82 (a). FIG. 82A is a flowchart showing the hold image setting process. In this reserved image setting process, the third symbol display device 281 displays the reserved ball number symbols for the number of reserved balls notified from the voice lamp control device 313 in accordance with the processing of the reserved ball number command for display. This is a process for expanding image data.

In the hold image setting process, first, the number determination flag is referred to, and the number of reserved balls corresponding to the number determination flag for which the on is set is set to the small area Ds1 of the third symbol display device 281 (see FIG. 50). ) Is expanded (S2751). In the task processing, based on this expanded reserved image data, the type of sprite (display object) that constitutes the reserved image is specified, and for each sprite, drawing such as display coordinate position, enlargement ratio, and rotation angle is performed. Determine the various required parameters.

In the hold image setting process, after the process of S2751, the new hold ball number command is set to off (S2752), and the process returns to the display setting process.

Returning to FIG. 80, after the hold image setting process (S3104) or in the process of S2703, when it is determined that the new hold ball number command flag is not on, that is, is off (S2703: No), then , It is determined whether or not the error occurrence flag is on (S2705). Then, if the error occurrence flag is on (S2705: Yes), the warning image setting process is executed (S2706).

Here, the details of the warning image setting process will be described with reference to FIG. 82 (b). FIG. 82B is a flowchart showing the warning image setting process. This process is a process for expanding the image data for displaying the warning image corresponding to the generated error on the third symbol display device 281. First, the error discrimination flag is referred to and all the error discrimination set to ON is performed. The warning image data for displaying the error warning image corresponding to the flag on the third symbol display device 281 is expanded (S2761).

In the task processing, based on this expanded warning image data, the type of sprite (display object) that constitutes the warning image is specified, and for each sprite, drawing such as display coordinate position, enlargement ratio, and rotation angle is performed. Determine the various required parameters.

Then, in the warning image setting process, after the process of S2761, the error occurrence flag is set to off (S2762), and the process returns to the display setting process.

Returning to FIG. 80, after the warning image setting process (S2706) or in the process of S2705, when it is determined that the error occurrence flag is not on, that is, is off (S2705: No), then the frame button is displayed. It is determined whether or not the operation flag is on (S2707). Then, if the frame button operation flag is on (S2707: Yes), the frame button operation process is executed (S2708).

Here, the details of the frame button operation process will be described with reference to FIG. 82 (c). FIG. 82B is a flowchart showing the frame button operation process. In this process, when the frame button 222 is operated by the player while the selection screen for selecting the display mode of the super reach is displayed on the third symbol display device 281, the super reach to be displayed is displayed according to the operation. This is a process for selecting an aspect.

In the frame button operation process, first, after the frame button operation flag is set to off (S2771), it is determined whether or not the super reach selection screen is displayed on the third symbol display device 281 (S2772). This super reach selection screen is displayed on the third symbol display device 281 according to the variation display data table set in the display data table buffer 433d, and the variation set in the previously executed V interrupt process. When the image controller 437 is instructed to draw a sprite for the super reach selection screen based on the display data table, it is determined that the super reach selection screen is displayed on the third symbol display device 281.

If it is determined in the process of S2772 that the super reach selection screen is not displayed on the third symbol display device 281 (S2772: No), the frame button operation process is terminated as it is, and the process returns to the display setting process. On the other hand, if it is determined that the super reach selection screen is displayed on the third symbol display device 281 as a result of the processing of S2772 (S2772: Yes), the super reach type flag provided for each display mode of super reach is displayed. Among them, the super reach type flag is updated so that only the super reach type flag corresponding to one display mode is turned on and the other super reach type flags are set to off according to a predetermined order (S2773). Return to the display setting process.

In the present embodiment, when the display of the super reach of the mode selected by the player in the variable display data table is specified, the drawing content corresponding to the display mode of each super reach is specified for each address. In the display setting process, when the contents of the display data table are expanded in the process of S2712 described later, only the drawing contents corresponding to the display mode of the super reach with the super reach type flag turned on are extracted. As a result, in the task processing, the type of sprite (display object) corresponding to the display mode of the selected super reach is specified, and each sprite is required for drawing such as the display coordinate position, the enlargement ratio, and the rotation angle. Since various parameters are set, the super reach effect is displayed on the third symbol display device 281 in the selected display mode.

Returning to FIG. 80, when it is determined that the frame button operation flag is not on, that is, is off (S2707: No) after the frame button operation process (S2708) or in the process of S2707, then comparison is performed. It is determined whether or not the flag is on (S2709). Then, if the comparison flag is on (S2709: Yes), the comparison process is executed (S2710).

Here, the details of the comparison process will be described with reference to FIG. 83. FIG. 83 is a flowchart showing the comparison process. This processing is performed when the variation display data table set in the display data table buffer 433d based on the display variation pattern command and the stop symbol set based on the display stop type command are inconsistent. To change the effect to a special variable effect that displays the third symbol at high speed until the confirmation command (display confirmation command) transmitted from the main control device 310 via the voice lamp control device 313 is received. It is the processing of.

In the comparison process, first, among the data table discrimination flags, the data table discrimination flag set to the ON state is specified, and the specified data table discrimination flag is used for fluctuation stored in the display data table buffer 433b. The type of the display data table is specified (S2781). Next, among the stop symbol discrimination flags, the stop symbol discrimination flag set in the on state is specified, and the set stop symbol is specified from the specified stop symbol discrimination flag (S2782).

Then, it is determined whether or not the type of the variable display data table specified by the process of S2781 matches the stop symbol specified by the process of S2782 (S2783). As described above, the display data table for fluctuations is prepared for each fluctuation pattern, and each fluctuation pattern includes for off, 15R fixed jackpot / time saving jackpot shared, 15R probability variable jackpot, and 2R probability variable jackpot. ··and so on. Therefore, in the process of S2783, for example, even though the fluctuation display data table corresponds to the fluctuation pattern for deviation, if the stop symbol is set as the jackpot symbol, it is determined that these do not match. ..

In the process of S2783, if it is determined to match (S2783: Yes), the process proceeds to the process of S2788, the comparison flag is set to off (S2788), and then the process returns to the display setting process. On the other hand, when it is determined that there is no match (S2783: No), first, the display data table for special variation in which the special variation is defined is set in the display data table buffer 433d, and the additional data table buffer 433e and the transfer data table are set. By writing the Null data to each of the buffers 433f, their contents are cleared (S2784).

Next, the stop symbol discrimination flag corresponding to the special stop symbol (for example, the symbol displayed as "3", "4", "1" from the left column) is turned on, and the stop symbol discrimination flag corresponding to other stop symbols is turned on. Is set to off (S2785), and the time data corresponding to the effect time of the special variation effect is set in the time counter 433i (S2786). As described above, the special variation effect changes the third symbol at high speed until the confirmation command (display confirmation command) transmitted from the main control device 310 via the voice lamp control device 313 is received. Since it is to be displayed, the effect time is set to a long time (for example, 3 minutes). Therefore, in the timekeeping counter 433i, 3 minutes (180000 milliseconds) ÷ 20 milliseconds = 9000 is set as the time data corresponding to the effect time of the special fluctuation effect.

Then, the pointer 433g is initialized to 0 (S2787), the comparison flag is set to off (S2788), and the process returns to the display setting process.

In this way, if the variation display data table set in the display data table buffer 433d based on the display variation pattern command and the stop symbol set based on the display stop type command are inconsistent, it is special. Since the variation display data table is set in the display data table buffer 433d, the third symbol display device 281 displays a special variation effect in which the third symbol continues to fluctuate at high speed. Then, since the special stop symbol is set as the stop symbol, when the confirmation command (display confirmation command) transmitted from the main control device 310 via the voice lamp control device 313 is received, the special stop symbol is set. Can be confirmed and displayed on the third symbol display 281.

Here, when the variation effect pattern instructed by the main control device 310 via the voice lamp control device 313 and the stop symbol to be displayed at the time of stop display of the variation effect do not match, the display control device 314 uses the main control device. There is a possibility that it is not possible to correctly reflect the result of the lottery performed in 310 and perform a variable effect or a definite display effect. On the other hand, in the pachinko machine 200, in such a case, a special variation effect is performed, and after the variation display, a special stop symbol indicating a special deviation is confirmed and displayed on the third symbol display device 281. Even if the result of the lottery in 310 is wrong, it is possible to prevent the third symbol display device 281 from erroneously performing a definite display effect of the jackpot. Further, even if the special stop symbol is confirmed and displayed on the third symbol display device 281, if the lottery result in the main control device 310 is a big hit, the actual gaming state in the pachinko machine 200 shifts to the special gaming state. The person can continue the game with peace of mind. Further, by setting the confirmation display to a special stop symbol, it is possible to suggest to the player that the pachinko machine 200 may be in a big hit state even if the confirmation display is off. Even though the confirmation display is off, the pachinko machine 200 is in a big hit state, so that the player does not feel uneasy.

Returning to FIG. 80, after the comparison process (S2708) or in the process of S2709, when it is determined that the comparison flag is not on, that is, it is off (S2709: No), then the process proceeds to the process of S2711. do.

In S2711, the pointer update process is executed (S2711). Here, the details of the pointer update process will be described with reference to FIG. 84. FIG. 84 is a flowchart showing the pointer update process. This pointer update process performs the corresponding drawing contents or transfer from the display data table, the additional data table, and the transfer data table stored in each buffer of the display data table buffer 433d, the additional data table buffer 433e, and the transfer data table buffer 433f, respectively. This is a process of updating the pointer 433g that specifies the address from which the transfer data information of the target image data should be acquired.

In this pointer update process, first, 1 is added to the pointer 433g (S2791). That is, in principle, the pointer 433g is updated so that only 1 is added each time the V interrupt processing is executed. Further, as described above, in the various data tables, Start information is described at the address "0000H", and the substance of each data is defined after the address "0001H", and the display data table is displayed. When the value of the pointer 433g is initialized to 0 in accordance with the storage in the data table buffer 433e, the value is updated to 1 by this pointer update process, so that the respective values are sequentially started from the address "0001H". Substantial data can be read from the data table.

After updating the value of the pointer 433g by the process of S2791, then, in the display data table set in the display data table buffer 433d, whether or not the data of the address indicated by the updated pointer 433g is End information. Is determined (S2792). As a result, if it is End information (S2792: Yes), it means that the pointer 433g has been updated past the address in which the actual data is described in the display data table set in the display data table buffer 433d.

Therefore, it is determined whether or not the display data table stored in the display data table buffer 433d is a demo display data table or a restart display data table (S2793), and the demo display data table or restart display data is determined. If it is a table (S2793: Yes), the pointer 433g is set to 1 (S2794), and further corresponds to the effect time of the demo display data table or the restart display data table set in the display data table buffer 433d. The time data is set in the time counting counter 433i (S2795), and the process proceeds to S2797. As a result, in the display setting process, the drawing contents can be expanded in order from the beginning of the demo display data table or the restart display data table, so that the demo effect or the restart effect is repeated on the third symbol display device 281. It can be displayed.

On the other hand, in the process of S2793, when it is determined that the display data table stored in the display data table buffer 433d is neither the demo display data table nor the restart display data table (S2793: No), the pointer 433g is used. The value is subtracted by 1 (S2796), and the process proceeds to S2797. As a result, in the display setting process, when a display data table other than the demo display data table and the restart display data table, for example, a variable display data table or a definite display data table, is set in the display data table buffer 433d. , Since the drawing content of the previous address in which the End information is described is always expanded, the third symbol display device 281 is made to display the last image specified in the display data table in a stopped state. be able to.

As a result of the processing of S2792, in the display data table set in the display data table buffer 433d, when it is determined that the data of the address indicated by the pointer 433g after the update by the processing of S2791 is not the End information, S2793 to S2795 are determined. The process of S2797 is skipped and the process proceeds to S2797.

In the processing of S2797, it is determined whether or not the confirmation command flag is on (S2797), and if the confirmation command flag is not on but off (S2797: No), the pointer update processing is terminated and the display is set. Return to processing. On the other hand, if the confirmation command flag is on (S2797: Yes), it means that the confirmation command (display confirmation command) has been received from the main control unit 310 via the voice lamp control device 313, and thus the display data table buffer. In the display data buffer set to 433d, the value of the pointer 433g is set to the value obtained by subtracting 1 from the end position address where the End information is stored (S2798), and the value of the clock counter is set to 1. (S2799), the process returns to the display setting process. As a result, when the confirmation command is received, the display setting process can expand the drawing content defined at the end of the set display data table and control the start of the confirmation display effect.

Returning to FIG. 80, after the pointer update process, the address indicated by the pointer 433 g updated by the pointer update process from the display data table and the additional data table set in the display data table buffer 433d and the additional data table buffer 433e. The drawing contents are expanded (S2712). In the task processing, the types of sprites (displays) that make up the image are specified based on the drawing contents expanded in the processing of S2712 together with the previously expanded pending image and warning image, and for each sprite. , Display coordinate position, enlargement ratio, rotation angle, and other parameters required for drawing are determined. If Null data is described in the additional data table, the subsequent processing is executed assuming that there is no sprite to be added. Further, when the additional data table buffer 433e is cleared by the Null data, the Null data is always expanded from the additional data table buffer 433e.

Next, the value of the timekeeping counter g is subtracted by 1 (S2713), and it is determined whether or not the value of the timekeeping counter 433i after the subtraction is 0 or less (S2714). If the value of the timekeeping counter 433i is 1 or more (S2714: No), the display setting process is terminated as it is, and the process returns to the V interrupt process. On the other hand, when the value of the timekeeping counter 433i is 0 or less (S2714: Yes), it means that the effect time corresponding to the display data table set in the display data table buffer 433d has elapsed. At this time, if the variable display data table is set in the display data table buffer 433d, a confirmation command (display confirmation command) is sent from the main control device 310 via the voice lamp control device 314 at the end of the effect. ) Should be transmitted, so in the subsequent processing of S2715, it is confirmed whether or not the confirmation command flag is on (S2715).

As a result, if the confirmation command flag is on (S2715: Yes), it means that the confirmation command (display confirmation command) has been received from the main control device 310 via the voice lamp control device 314. The display data table is set in the display data table buffer 433d, and the contents are cleared by writing the Null data to the additional data table buffer 433e and the transfer data table buffer 433f, respectively (S2716). Next, the time data corresponding to the effect time of the confirmation display is set in the time counter 433i (S2717), and the value of the pointer 433g is initialized to 0 (S2718). Then, after the confirmation command flag is set to off (S2719) and then the confirmation display flag indicating that the confirmation display effect is being performed in the on state is set to on (S2720), the content of the stop symbol discrimination flag is used as it is in the work RAM433. It is copied to the previous stop symbol determination flag provided in (S2721), and the process returns to the V interrupt process.

As a result, when a variable display data table is set in the display data table buffer 433d, a confirmation command (display confirmation) is given from the main control device 310 via the voice lamp control device 313 at the end of the effect. When the command) is received, the drawing content can be set so that the final display effect of the stop symbol in the variation effect is displayed on the third symbol display device 281. Further, the effect displayed on the third symbol display device 281 can be easily changed to the confirmed display effect simply by changing the display data table set in the display data table buffer 433b to the confirmed display data table. Further, as compared with the case where the display content is changed by starting another program as in the conventional case, the program is not complicated and bloated, and therefore, a large load is not applied to the MPU 431. Regardless of the processing capacity of the display control device 314, various types of effect images can be displayed on the third symbol display 281.

The previous stop symbol determination flag set by the process of S2721 is used to specify the third symbol to be displayed on the third symbol display device 281 in the next variation effect. That is, as described above, the display of the third symbol in the variation effect changes according to the stop symbol of the variation effect performed immediately before, and in the variation display data table, the variation based on the data table. From the start of the operation until a predetermined time elapses, the symbol offset information from the stop symbol of the variation effect performed immediately before is described. In the task process (S2404), the stop symbol of the variation effect performed immediately before is specified from the previous stop symbol determination flag set by S2721 until a predetermined time elapses from the start of the variation, and the stop symbol thereof is specified. By adding the symbol offset information acquired by the display setting process to the specified stop symbol, the third symbol to be actually displayed is specified. As a result, the variation effect is started from the stop symbol in the previous variation effect.

On the other hand, if the confirmation command flag is off instead of on in the processing of S2715 (S2715: No), the process proceeds to the processing of S2722 shown in FIG. 81, and it is determined whether or not the confirmation display flag is on (S2722). ). If the confirmed display flag is on (S2722: Yes), the result of the determination in the process of S2714 (S2714: Yes) means that the confirmed display effect has ended, so the confirmed display flag is set to off. Later (S2723), the demo display data table is set in the display data table buffer 433d (S2724), and then the time data corresponding to the effect time of the data display is set in the time counter 433i (S2725). Then, the pointer 433g is initialized to 0 (S2726), the demo display flag indicating that the demo is being produced in the ON state is set to ON (S2727), and the V interrupt process is terminated.

As a result, if the display variation pattern command indicating the start of the next variation effect or the display demo effect command indicating the start of the demo effect is not received by the end of the final display effect, the display automatically. The drawing content can be set so that the demo effect is displayed on the third symbol display device 281.

It should be noted that the branch condition of S2722: Yes is satisfied when the definite display effect is performed. In this case, the contents of the additional data table buffer 433e and the transfer data table buffer 433f are both changed by the processing of S2716. It has been cleared. Therefore, in the process of S2724, the process of clearing those data table buffers is omitted. As a result, the processing load on the MPU 431 can be reduced.

In the process of S2722, if the confirmation display flag is not on but off (S2722: No), then it is determined whether or not the demo display flag is on (S2728). If the demo display flag is on (S2728: Yes), the result of the determination in the processing of S2714 (S2714: Yes) means that the demo effect has ended, so the display setting process is ended as it is, and V Return to the interrupt process. Then, in this case, as described above, various settings are made so that the demo effect is started again by the pointer update process executed in the next V interrupt process. Therefore, from the voice lamp control device 313. Until a new display variation pattern command is received, the demo effect can be repeated and displayed on the third symbol display device 281.

On the other hand, in the process of S2728, when the demo display flag is not on but off (S2728: No), the result of the determination in the process of S2714 (S2714: Yes) means that the variation effect is completed. Therefore, if the confirmation command is not received even after a predetermined time has elapsed from the end of the variation effect, the variation display data table corresponding to the variation effect is set in the display data table buffer 433d in order to start the restart effect. 1 is added to the restart timer counter initialized to 0 (S2729), and it is determined whether or not the value of the restart timer counter after the addition has reached a predetermined value (S2730).

Then, when the restart timer counter is not a predetermined value (S2730: No), the display setting process is terminated as it is, and the process returns to the V interrupt process. When the restart timer counter is a predetermined value (S2730: Yes), the restart display data table is set in the display data table buffer 433d, and the additional data table buffer 433e and the transfer data table buffer 433f are set to the Null data, respectively. Clears those contents by writing (S2731). Then, the time data corresponding to the effect time of the restart effect is set in the time counter 433i (S2732), the value of the pointer 433 g is initialized to 0 (S2733), and the process returns to the V interrupt process.

As a result, in the display control device, even if a predetermined time elapses after the third symbol is stopped and displayed with the end of the variation effect, the confirmation command (confirmed command) transmitted from the main control device 310 via the voice lamp control device 313 ( When the display confirmation command) is not received, the drawing content can be set so that the restart effect is displayed on the third symbol display device 281. Then, as described above, the restart effect is an effect of displaying the image obtained by vibrating the third symbol on the third symbol display device 281. Therefore, the player can display the third symbol on the third symbol display device 281. By visually recognizing that the third symbol is vibrated and displayed after the change of is stopped and displayed, it can be recognized that the stopped symbol has not been determined at that time.

After the last drawing content specified by the restart display data table is expanded, the drawing content is expanded again from the beginning of the restart display data table by the pointer update process described above. Therefore, the restart effect can be repeated and displayed on the third symbol display device 281 until a display confirmation command is received from the voice lamp control device 313 or a new display variation pattern command is received. Here, the restart effect is to display the third symbol on the third symbol display device 281 in a mode of vibrating (oscillating) the third symbol around a predetermined position, and in the restart display data table, the third symbol is displayed. Only the drawing contents necessary for shaking and displaying at least once are specified. Then, by repeatedly expanding the drawing contents from the beginning of the restart display data table, the restart effect of repeatedly vibrating the third symbol is displayed on the third symbol display device 281. In this way, by setting the restart effect to cause the third symbol display device 281 to vibrate and display the third symbol, the restart display data table is shaken at least once for the third symbol. Since it is only necessary to store the drawing contents required for display, the capacity required for storing the restart display data table can be kept small.

Further, if a display confirmation command is received from the voice lamp control device 313 while the restart effect is being performed by the restart display data table, the process of S2716 shown in FIG. 83 is performed and the display data table buffer is performed. A definite display data table is set in 433d. As a result, even during the restart effect, the stop display of the third symbol is made with the stop symbol indicated by the stop symbol determination flag in accordance with the reception of the display confirmation command, and the confirmation display is displayed on the third symbol display device 281. Is displayed.

Further, if a display variation pattern command is received from the voice lamp control device 313 while the restart effect is being performed by the start display data table, the process of S2631 in FIG. 77 (a) is performed and the display data is displayed. A variation display data table is set in the table buffer 433d, and the variation effect is displayed on the third symbol display device 281. Further, if a display demo command is received from the voice lamp control device 313 while the restart effect is being performed by the start display data table, the process of S2621 in FIG. 76 (c) is performed and the display data table is performed. A display data table for demo is set in the buffer 433d, and a demo effect is displayed on the third symbol display device 281. In the restart effect, the confirmation command (display confirmation command) from the main control device 310 that should be originally received is not received even after a predetermined time has elapsed from the stop display of the third symbol due to the end of the variation effect. Since it is an effect displayed in some cases, there is a possibility that the confirmation command is not received even while the restart effect is displayed due to the influence of noise, malfunction, and the like. On the other hand, in the present embodiment, if a display variation pattern command or a display demo command is received during the restart effect, the effect corresponding to the command can be displayed on the third symbol display device 281. Various effects on the third symbol display device 281 can be performed according to the gaming state of the pachinko machine 200.

The simple display setting process (S2409) executed when the simple image display flag 433c is turned on in the V interrupt process (see FIG. 74 (b)) is also the same process as the display setting process. However, in the simple display setting process, if a confirmation command (display confirmation command) is received from the main control device 310 via the voice lamp control device 313 after the effect time of the variation effect by the variation image when the power is turned on ends. It is stipulated that one of the images (one of FIGS. 54 (b) and (c)) of the fluctuation image when the power is turned on according to the stop symbol set based on the stop type command for display is stopped and displayed for a predetermined time. The process of setting the display data table in the display data table buffer 433i is performed. Further, when the confirmation command (display confirmation command) that should be originally received from the main control device 310 via the voice lamp control device 313 is not recognized after the effect time of the variation effect by the variation image when the power is turned on is completed. Is performed to set the display data table in the display data table buffer 433d, which stipulates that the variation effect of the variation image when the power is turned on is restarted as it is.

Further, in the comparison process, the fluctuation pattern instructed by the display variation pattern command is compared with the stop type instructed by the display stop type, and if they do not match, the symbol is out of alignment as a stop symbol (FIG. 54 (FIG. 54). c) See).

Next, with reference to FIGS. 85 and 86, the details of the above-mentioned transfer setting process (S2405), which is one of the V interrupt processes executed by the MPU 431 of the display control device 314, will be described. First, FIG. 85A is a flowchart showing this transfer setting process.

In this transfer setting process, first, it is determined whether or not the simple image display flag 433c is on (S3001). If the simple image display flag 433c is on (S3001: Yes), all the image data that should be resident in the resident video RAM 435 has not been transferred from the character ROM 434 to the resident video RAM 435, so that the resident image transfer setting is made. The process is executed (S3002), the transfer setting process is terminated, and the process returns to the V interrupt process. As a result, a transfer instruction for transferring the image data to be resident in the resident video RAM 435 from the character ROM 434 to the resident video RAM 435 is set to the image controller 437. The details of the resident image transfer setting process will be described later with reference to FIG. 85 (b).

On the other hand, if the simple image display flag 433c is not on as a result of the processing of S3001, that is, if it is off (S3001: No), all the image data that should be resident in the resident video RAM 435 is the resident video from the character ROM 434. It has been transferred to RAM 435. In this case, the normal image transfer setting process is executed (S2603), the transfer setting process is terminated, and the process returns to the V interrupt process. As a result, the transfer instruction is set so that the subsequent transfer of image data from the character ROM 434 is performed to the normal video RAM 436. The details of the normal image transfer setting process will be described later with reference to FIG. 86.

Next, the resident image transfer setting process (S3002), which is one of the transfer setting processes (S2405) executed by the MPU 431 of the display control device 314, will be described with reference to FIG. 85 (b). FIG. 85B is a flowchart showing this resident image transfer setting process (S3002).

In this resident image transfer setting process, first, it is determined whether or not the image controller 437 is instructed to transfer the untransferred image data (S3101), and if the transfer instruction is transmitted (S3101: Yes). ) Further, it is determined whether or not the image data transfer process performed by the image controller 437 is completed based on the transfer instruction (S3102). In the process of S3102, it is determined that the transfer process is completed when the image controller 437 is instructed to transfer the image data and then the transfer end signal indicating the end of the transfer process is received from the image controller 437. .. When it is determined by the process of S3102 that the transfer process has not been completed (S3102: No), the image transfer process is continuously performed in the image controller 437, so that the resident image transfer setting process is performed. finish. On the other hand, when it is determined that the transfer process is completed (S3102: Yes), the process proceeds to the process of S3103. Further, as a result of the processing of S3101, even if the transfer instruction of the untransferred image data is not transmitted to the image controller 437 (S3101: No), the process proceeds to the processing of S3103.

In the process of S3103, it is determined whether or not all the resident target image data to be resident in the resident video RAM 435 has been transferred (S3103), and if there is untransferred resident target image data (S3103: No), the non-resident image data has not been transferred. A transfer instruction is set for the image controller 437 so that the resident image data to be transferred is transferred from the character ROM 434 to the resident video RAM 435 (S3104), and the resident image transfer setting process is terminated.

As a result, the drawing list transmitted to the image controller 437 in the drawing process includes the transfer data information regarding the untransferred resident target image data, and the image controller 437 is described in the drawing list. Based on the data information, the resident target image data can be transferred from the character ROM 434 to the resident video RAM 436. The transfer data information includes the start address and end address of the character ROM 434 in which the resident image data is stored, the transfer destination information (in this case, the resident video RAM 435), and the transfer destination (transferred here). The start address of the resident video RAM 435 (area provided in the resident video RAM 435) for storing the resident target image data is included. The image controller 437 executes an image transfer process based on this transfer data information, reads the image data specified in the transfer process from the character ROM 434, temporarily stores the image data in the buffer RAM 437a, and then during the unused period of the resident video RAM 436. Transfers to the specified address of the resident video RAM 436. Then, when the transfer is completed, the transfer end signal is transmitted to the MPU 431.

If all the resident image data has been transferred as a result of the process of S3103 (S3103: Yes), the simple image display flag 433c is set to off (S3105), and the resident image transfer setting process is terminated. As a result, in the V interrupt process (see FIG. 75 (b)), the command is not the simple command determination process (see S2408 in FIG. 75 (b)) and the simple display setting process (see S2409 in FIG. 75 (b)). Since the determination process (see FIGS. 75 to 79) and the display setting process (see FIGS. 80 to 84) are executed, the drawing of the image at the normal time is set, and the third symbol display device 281 is set. The normal image is displayed. Further, the subsequent transfer of image data from the character ROM 434 is performed to the normal video RAM 436 by the normal image transfer setting process (see FIG. 86) (see S3001: No in FIG. 85 (a)).

By executing this resident image transfer setting process, the MPU 431 is resident in all resident video RAMs 435 except for the main image at power-on and the variable image at power-on that have already been transferred in the main process. The target image data can be transferred from the character ROM 434 to the resident video RAM 435. Then, the MPU 431 controls that the image data transferred to the resident video RAM 435 is continuously held without being overwritten while the power is turned on. As a result, the image data transferred to the resident video RAM 435 by the resident image transfer setting process will be resident in the resident video RAM 435 while the power is turned on.

Therefore, after all the image data that should be resident in the resident video RAM 435 is transferred to the resident video RAM 435, the display control device 314 uses the image data resident in the resident video RAM 435 while using the image controller 437. The image drawing process can be performed with. As a result, if the image data used for the drawing process is resident in the resident video RAM 435, it is not necessary to read the corresponding image data from the character ROM 434 configured by the NAND flash memory 434a having a slow read speed at the time of image drawing. Therefore, the time required for reading the data can be omitted, and the image can be drawn immediately and the drawn image can be displayed on the third symbol display device 282.

In particular, the resident video RAM 435 includes image data of frequently displayed images such as a rear image, a third symbol, a character symbol, and an error message, a main control device 310, an audio lamp control device 313, and a display control device 314. Since the image data of the image to be displayed is resident immediately after the display is determined by such as, even if the character ROM 434 is configured by the NAND type flash memory 434a, various operations performed by the player at any timing can be performed. , It is possible to maintain high responsiveness until some image is displayed on the third symbol display device 281.

Next, with reference to FIG. 86, a normal image transfer setting process (S3003), which is one process of the transfer setting process (S2405) executed by the MPU 431 of the display control device 314, will be described. FIG. 86 is a flowchart showing this normal image transfer setting process (S3003).

In this normal image transfer setting process, first, from the transfer data table set in the transfer data table buffer 433f, the pointer 433g updated by the pointer update process (S2711) of the display setting process (S2403) executed earlier is used. Acquire the information described in the indicated address (S3201). Then, it is determined whether or not the acquired information is transfer data information (S3202), and if it is transfer data information (S3202: Yes), the character ROM 434 in which the transfer target image data is stored is stored from the transfer data information. The start address (storage source start address), the final address (storage source final address), and the start address of the transfer destination (normal video RAM 436) are extracted and stored in the transfer data buffer provided in the work RAM 433 (. S3203) Further, the transfer start flag provided in the work RAM 433 and indicating that there is image data to be transferred in the ON state is set to ON (S3204), and the process proceeds to S3205.

Further, in the process of S3202, if the acquired information is not the transfer data information but the Null data (S3202: No), the processes of S3203 and S3204 are skipped, and the process proceeds to the process of S3205. In the process of S3205, it is determined whether or not a new image data transfer instruction has been set for the image controller 437 after the previous image data transfer is completed (S3205), and the transfer instruction is set. If so (S3205: Yes), it is further determined whether or not the image data transfer performed by the image controller 437 is completed based on the transfer instruction (S3206).

In the process of S3206, after setting the image data transfer instruction to the image controller 437, when the transfer end signal indicating the end of the transfer process is received from the image controller 437, it is determined that the transfer process is completed. .. When it is determined by the process of S3206 that the transfer process has not been completed (S3206: No), the image transfer process is continuously performed in the image controller 437, so that the normal image transfer setting process is performed. finish. On the other hand, when it is determined that the transfer process is completed (S3206: Yes), the process proceeds to the process of S3207. Further, as a result of the processing of S3205, even if the image data transfer instruction is not set for the image controller 437 after the end of the previous transfer processing (S3205: No), the process proceeds to the processing of S3207.

In the process of S3207, it is determined whether or not the transfer start flag is on (S3207), and if the transfer start flag is on (S3207: Yes), the image data to be transferred exists, so that the transfer start flag is present. Is turned off (S3208), the image data of the sprite indicated by various information stored in the transfer data buffer by the process of S3203 is set as the transfer target image, and then the process proceeds to the process of S3216. On the other hand, if the transfer start flag is not on but off (S3207: No), then it is determined whether or not the new continuous notice command flag is on (S3209).

If the new continuous notice command flag is on (S3209: Yes), it means that the continuous notice command is processed and the continuous notice additional data table for the continuous notice effect is set in the additional data table buffer 733c. Therefore, after the new continuous advance notice command flag is set to off (S3210), among the continuous advance notice determination flags provided for each continuous advance notice image type, the image data of the continuous advance notice image corresponding to the continuous advance notice determination flag in the ON state. The start address (storage source start address) and end address (storage source final address) of the character ROM 434 in which the data is stored, and the start address of the transfer destination (normal video RAM 436) are specified (S3211), and the specified various types are specified. After using the image data of the sprite indicated by the information as the transfer target image, the process proceeds to S3216.

In the process of S3209, if the new continuous notice command flag is not on but off (S3209: No), then it is determined whether or not the rear image change flag is on (S3212). If the rear image change flag is not on but off (S3212: No), the image data to be transferred does not exist, so the normal image transfer setting process is terminated as it is.

On the other hand, if the rear image change flag is on (S3212: Yes), it means that the rear image is changed. Therefore, after the rear image change flag is set to off (S3213), the rear image provided for each rear image type is provided. Among the discrimination flags, the start address (storage source start address), the final address (storage source final address), and the transfer of the character ROM 434 in which the image data of the rear image corresponding to the rear image discrimination flag in the ON state is stored. The start address of the destination (normal video RAM 436) is specified (S3214), the image data of the sprite indicated by the specified various information is used as the transfer target image, and then the process proceeds to S3216.

When the rear image discrimination flag in the ON state is that of the rear A, all the corresponding image data is resident in the rear image area 435c of the resident video RAM 435, so that the image should be transferred to the normal video RAM 436. No data exists. Therefore, in the process of S3214, if the rear image discrimination flag in the ON state is that of the rear surface A, the normal image transfer process is terminated as it is.

In the process of S3216, it is determined whether or not the image to be transferred is already stored in the normal video RAM 436 (S3216). The discrimination in the processing of S3216 is performed by referring to the stored image discrimination flag 433j. That is, the stored state corresponding to the sprite as the transfer target image is read from the stored image discrimination flag 433j, and if the stored state is "on", the image data of the sprite to be transferred is stored in the normal video RAM 436. It is determined that the sprite is stored, and if the storage state is "off", it is determined that the image data of the sprite to be transferred is not stored in the normal video RAM 436.

If, as a result of the processing of S3216, the image to be transferred is stored in the normal video RAM 436 (S3216: Yes), it is not necessary to transfer the image data from the character ROM 434 to the normal video RAM 436. The normal image transfer setting process is terminated as it is. As a result, it is possible to suppress unnecessary transfer of image data from the character ROM 434 to the normal video RAM 436, reduce the processing load in each part of the display control device 314, and reduce the traffic in the bus line 440. Can be planned.

On the other hand, if the transfer target image is not stored in the normal video RAM 436 as a result of the processing of S3216 (S3216: Yes), the transfer instruction of the transfer target image is set (S3217). As a result, the transfer data information of the image to be transferred is included in the drawing list transmitted to the image controller 437 in the drawing process, and the image controller 437 is based on the transfer data information described in the drawing list. In addition, the image data of the image to be transferred can be transferred from the character ROM 434 to the normal video RAM 436. The transfer data information includes the start address and end address of the character ROM 434 in which the image data of the image to be transferred is stored, the transfer destination information (in this case, the normal video RAM 436), and the transfer destination (transferred here). The start address of the sub-area) provided in the image storage area 436a of the normal video RAM 436 for storing the image data of the image to be transferred is included. The image controller 437 executes an image transfer process based on the transfer data information, reads the image data specified in the transfer process from the character ROM 434, and designates the specified video RAM (here, the normal video RAM 436). Forward to the given address. Then, when the transfer is completed, the transfer end signal is transmitted to the MPU 431.

After the processing of S3217, the stored image discrimination flag 433j is updated (S3218), and this normal transfer setting processing is terminated. To update the stored image discrimination flag 433j, as described above, the storage state corresponding to the sprite that is the transfer target image is set to "on", and the sub-area of the same image storage area 436a as the one sprite is set. This is done by setting the storage state corresponding to the other sprites that are supposed to be stored to "off".

In this way, by executing this normal image transfer process, the process for the continuous notice command is executed in the command determination process executed earlier, and the continuous notice image indicated by the continuous notice command is supported. When the additional data table is set in the additional data table buffer 433e, the image data of the continuous preview image used in the additional data table can be transferred from the character ROM 434 to the normal video RAM 436 without delay. Further, when the rear image is changed based on the reception of the rear image change command in the command determination process executed earlier, among the image data used in the rear image, the rear surface of the resident video RAM 435 is used. Image data not stored in the image area 435c can be transferred from the character ROM 434 to the normal video RAM 436 without delay.

Further, in the present embodiment, the display data table is displayed as the display data table buffer 433d in response to a command (for example, a display variation pattern command) transmitted from the voice lamp control device 313 based on a command or the like from the main control device 313. The transfer data table corresponding to the display data table is set in the transfer data table buffer 433f in accordance with the setting of. Then, the MPU 431 transfers to the image controller 437 according to the transfer data information described in the area indicated by the pointer 433g of the transfer data table set in the transfer data table buffer 433f by executing the normal image transfer setting process. Since the transfer instruction of the target image is set, the image data of the sprite used in the display data table set in the display data table buffer 433d can be reliably transferred from the character ROM 434 to the normal video RAM 436 at a desired timing. ..

Here, in the transfer data table, the image data to be transferred is stored in the image storage area 436a so that the image data corresponding to the predetermined sprite is stored in the image storage area 436a by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information is specified for a predetermined address, the image data is transferred from the character ROM 434 to the image storage area 436a according to the transfer data information specified in the transfer data table, so that the transfer data information is specified according to the display data table. When drawing the sprite, the image data that is not resident in the resident video RAM 435 required for drawing the sprite can be stored in the image storage area 436a without fail.

As a result, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, the image necessary for display can be read in advance from the character ROM 434 and transferred to the normal video RAM 436 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the third symbol display device 281. Further, according to the description in the transfer data table, only the non-resident image data in the resident video RAM 435 can be easily and surely transferred from the character ROM 434 to the normal video RAM 436.

Further, in the transfer data table, the transfer data information is defined so that the image data is transferred from the character ROM 434 to the normal video RAM 436 for each image data corresponding to the sprite. As a result, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 434 to the normal video RAM 436 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

Next, with reference to FIG. 87, the details of the above-mentioned drawing process (S2406), which is one of the V interrupt processes executed by the MPU 431 of the display control device 314, will be described. FIG. 87 is a flowchart showing this drawing process.

In the drawing process, the types of various sprites constituting one frame determined by the task process (S2404) and the parameters required for drawing each sprite (display position coordinates, enlargement ratio, rotation angle, translucency value, α blending information). , Color information, filter designation information), and the transfer instruction set by the transfer setting process (S2405), the drawing list shown in FIG. 60 is generated (S3301). That is, in the processing of S3301, the storage RAM type and address in which the image data of the sprite is stored are specified for each sprite from the types of various sprites constituting one frame determined in the task processing (S2404). Then, the specified stored RAM type and address are associated with the parameters required for the sprite determined by the task processing. Then, each sprite is rearranged in the order of the sprites to be arranged on the front side from the sprites to be arranged on the back side in the image for one frame, and then the details for each sprite are arranged in the order of the sprites after the rearrangement. A drawing list is generated by describing the storage RAM type in which the image data of the sprite is stored, the address, and the parameters necessary for drawing the sprite as various drawing information (detailed information). When a transfer instruction is set by the transfer setting process (S2405), the start address (storage source start address) of the character ROM 434 in which the transfer target image data is stored as the transfer data information at the end of the drawing list. And the final address (final address of the storage source) and the start address of the transfer destination (normal video RAM 436) are added.

As described above, since the area of the resident video RAM 435 in which the image data of the sprite is stored or the sub area of the image storage area 436a of the normal video RAM 436 is fixed for each sprite, the MPU 431 has a fixed area. , The storage RAM type and address in which the image data of the sprite is stored can be immediately specified according to the sprite type, and the information can be easily included in the detailed information of the drawing list.

When the drawing list is generated, the generated drawing list and the drawing target buffer information specified by the drawing target buffer flag 433k are transmitted to the image controller (S3302). Here, when the drawing target buffer flag 433k is 0, the drawing target buffer flag 433k is 1 including the information instructing the image drawn in the first frame buffer 436b to be expanded as the drawing target buffer information. Includes information instructing the image drawn in the second frame buffer 436c to be expanded as the drawing target buffer information.

The image controller 437 draws an image in order from the sprite described at the top of the drawing list based on the drawing list received from the MPU 431, and expands the image by overwriting the frame buffer specified by the drawing target buffer information. As a result, in the image for one frame generated by the drawing list, the sprite drawn first can be arranged on the backmost side, and the sprite drawn last can be arranged on the frontmost side.

If the drawing list contains transfer data information, the transfer data information is used to determine the start address (storage source start address) and final address (storage source final address) of the character ROM 434 in which the transfer target image data is stored. ) And the start address of the transfer destination (normal video RAM 436) are extracted, and the image data stored from the storage source start address to the storage source final address is read in order from the character ROM 434 and temporarily stored in the buffer RAM 437a. Then, in anticipation of when the normal video RAM 436 is in an unused state, the image data stored in the buffer RAM 437a is sequentially transferred to the area indicated by the transfer destination start address of the normal video RAM 436. Then, the image data stored in the normal video RAM 436 is used based on the drawing list subsequently transmitted from the MPU 431, and the image is drawn according to the drawing list.

The image controller 437 reads the image information of the previously expanded image from the frame buffer different from the frame buffer specified by the drawing target buffer information, and displays the image information together with the drive signal in the third symbol display device 281. Send to. As a result, the image expanded in the frame buffer can be displayed on the third symbol display device 281. Further, while expanding the image drawn in one frame buffer, the image expanded from one frame buffer can be displayed on the third symbol display 281, and the drawing process and the display process can be processed in parallel at the same time. Can be done.

The drawing process updates the drawing target buffer flag 433k after the processing of S3302 (S3303). Then, the drawing process is terminated, and the process returns to the V interrupt process. The drawing target buffer flag 433k is updated by inverting its value, that is, by setting it to "1" when the value is "0" and to "0" when the value is "1". Will be done. As a result, the drawing target buffer is alternately set between the first frame buffer 436b and the second frame buffer 436c each time the drawing list is transmitted.

Here, the transmission of the drawing list is performed by the MPU 431 based on the V interrupt signal transmitted from the image controller 437 every 20 milliseconds when the drawing process and the display process of the image for one frame are completed. It will be performed every time the drawing process of the embedded process (see FIG. 74) is executed. As a result, at a certain timing, the first frame buffer 436b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 436c is designated as the frame buffer for reading the image information for one frame. When the drawing process and the display process of are executed, the second frame buffer 436c is designated as the frame buffer for expanding the image for one frame 20 milliseconds after the drawing process for the image for one frame is completed, and one frame is specified. The first frame buffer 436b is designated as the frame buffer from which the minute image information is read. Therefore, the image information of the image previously expanded in the first frame buffer 436b can be read out and displayed on the third symbol display device 281, and at the same time, a new image is expanded in the second frame buffer 436c. ..

Then, after the next 20 milliseconds, the first frame buffer 436b is designated as the frame buffer for expanding the image for one frame, and the second frame buffer 436c is designated as the frame buffer for reading the image information for one frame. Will be done. Therefore, the image information of the image previously expanded in the second frame buffer 436c can be read out and displayed on the third symbol display device 281, and at the same time, a new image is expanded in the first frame buffer 436b. .. After that, one of the first frame buffer 436b and the second frame buffer 436c is used every 20 milliseconds for the frame buffer that expands the image for one frame and the frame buffer for reading the image information for one frame. By alternately designating, it is possible to continuously perform the display processing of the image for one frame in units of 20 milliseconds while performing the drawing processing of the image for one frame.

As described above, according to the pachinko machine 200 of the seventh embodiment, the display control device 314 is a command (for example, display) transmitted from the voice lamp control device 313 based on a command or the like from the main control device 313. The display data table to be used is selected according to the variation pattern command), etc., read from the data table storage area 433b, stored in the display data table buffer 433d, and the pointer 433g is initialized. Then, each time the drawing process for one frame is completed, the pointer 433g is added by 1, and in the display data table stored in the display data table buffer 433d, the next is based on the drawing content defined by the address indicated by the pointer 433g. An image content to be drawn is specified, a drawing list (see FIG. 60) described later is created, and the drawing list is transmitted to the image controller 437 to give an instruction to draw the image. As a result, the drawing contents are specified in the order specified in the display data table according to the update of the pointer 433g, so that the image as specified in the display data table is displayed on the third symbol display device 281.

As described above, in the pachinko machine 200, in the display control device 314, the display control device 314 responds to a command (for example, a display variation pattern command) transmitted from the voice lamp control device 313 based on a command or the like from the main control device 313. Instead of changing the program to be executed by the MPU 431, the effect image to be displayed on the third symbol display device 281 can be changed only by a simple operation of replacing the display data table with the display data table buffer 433d as appropriate. ..

Here, when the program executed by the MPU 431 is activated every time the effect image displayed on the third symbol display device 281 is changed like the conventional pachinko machine, the effect image is diversified. Since a large load is applied to the complicated and enormous process of starting and executing a program, the processing capacity of the display control device 314 may be limited, and the diversification of controllable production images may be limited. there were. On the other hand, in the pachinko machine 200, the effect image to be displayed on the third symbol display device 281 can be changed by a simple operation of appropriately replacing the display data table with the display data table buffer 433d. Regardless of the processing capacity of the control device 314, various types of effect images can be displayed on the third symbol display 281.

Further, in this way, a display data table is prepared corresponding to each effect mode, a display data table buffer is set according to the effect mode to be displayed, and a drawing list is drawn frame by frame according to the set data table. This can be created because, in the pachinko machine 200, the effect to be displayed on the third symbol display device 281 is determined in advance based on the result of the lottery performed based on the start winning prize. On the other hand, in game machines other than gaming machines such as pachinko machines, the display contents must be changed from moment to moment based on the user's operation, so that the display contents cannot be predicted. Therefore, as described above. It is not possible to have a display data table corresponding to each effect mode as described above. In this way, a display data table is prepared corresponding to each effect mode, a display data table buffer is set according to the effect mode to be displayed, and a drawing list is created frame by frame according to the set data table. This configuration can only be realized based on the configuration in which the pachinko machine 200 determines in advance the effect mode to be displayed on the third symbol display device 281 based on the result of the lottery performed based on the start winning prize. be.

On the other hand, in the pachinko machine 200, in the display control device 314, an effect image (for example) to be displayed on the third symbol display device 281 in response to a command from the voice lamp control device 313 (for example, a display variation pattern command) or the like. , Variable effect image) to display another effect image (for example, continuous notice effect image), an additional data table corresponding to the other effect image to be added and displayed is added to the additional data table buffer 433e. By setting, the effect image can be easily added to the base effect image and displayed. As a result, for example, when there are 32 types of original effect images and there are 5 types of other effect images to be additionally displayed, the display data specified by adding another effect image to each original effect image. If a table is prepared separately, 32 x (1 + 5) = 192 types of display data tables must be prepared, but a data table corresponding to other production images, such as this pachinko machine 200, is separately used as an additional data table. By specifying, 32 + 5 = 37 types of displays and additional data tables may be prepared, and the capacity increase of the data table storage area 433b can be suppressed. Therefore, it is possible to store the data table corresponding to various aspects of the effect within the capacity prepared in the data table storage area 433b, and it is possible to easily further diversify the effect image.

Further, by defining another effect image to be additionally displayed as an additional data table as in the pachinko machine 200, after setting the display data table corresponding to the original effect image in the display data table buffer 433d, Even if it is decided to display another effect image to be additionally displayed, an additional data table corresponding to the other effect image is added without changing the display data table set in the display data table buffer 433d. By simply setting the data table buffer 433e, other effect images to be added and displayed can be added to the original effect image and easily displayed.

Further, since the additional data table is configured to have the same data structure as the display data table, the display data table set in the display data table buffer 433d and the additional data set in the additional data table buffer 433e. While updating the pointer 433g every hour from the table, the drawing contents specified by the address indicated by the pointer can be easily specified, and one drawing list corresponding to one frame can be easily specified from these. Can be generated in. Therefore, even if the display of other effects is determined by the voice lamp control device 313 or the like in addition to the effects performed based on the command from the main control device 310, the effects to be additionally displayed are to be displayed. By defining the display contents in the additional data table, it is possible to easily perform a wide variety of effect display from a small number of data tables.

Further, in the pachinko machine 200, all the image data to be resident is transferred to the resident video RAM 435 in the initialization process immediately after the power is turned on. Therefore, after the initialization process is completed, the image data is resident in the resident video RAM 435. The image controller 437 can perform image drawing processing while using the created image data. As a result, if the image data used for the drawing process is resident in the resident video RAM 435, it is not necessary to read the corresponding image data from the character ROM 434 configured by the NAND flash memory 434a having a slow read speed at the time of image drawing. Therefore, the time required for reading the image can be omitted, and the image can be drawn immediately and the drawn image can be displayed on the third symbol display device. In particular, the resident video is the image data of the image that is frequently displayed, or the image data of the image that should be displayed immediately after the display is determined by the main control device 310, the voice lamp control device 313, the display control device 314, or the like. Since it is resident in the RAM 435, it is possible to maintain high responsiveness from various operations performed by the player at arbitrary timings to displaying some image on the third symbol display device 281.

Further, in the pachinko machine 200, the display data table to be used is selected according to a command (for example, a display variation pattern command) transmitted from the voice lamp control device 313 based on a command or the like from the main control device 313. , To transfer the image data that is not resident in the resident video RAM 435 from the character ROM 434 to the image storage area 436a of the normal video RAM 435 among the image data of the sprite used in the effect specified in the display data table. The transfer data information and the transfer data table that defines the transfer timing should be set in the transfer data table buffer 433f, and the transfer should be started at the time specified at the address specified by the pointer 433g every time the pointer 433g is updated. The transfer data information of the image data of a predetermined sprite is acquired, and the transfer data information is transmitted to the image controller 437 by a transfer instruction or a drawing list.

As a result, when the transfer data information is described in the drawing list received from the MPU 431, the image controller 437 transfers the transfer target image data from the character ROM 434 to a predetermined sub-area of the image storage area 436a according to the transfer data information. Execute the process to transfer. Here, in the transfer data table, the image data to be transferred is stored in the image storage area 436a so that the image data corresponding to the predetermined sprite is stored in the image storage area 436a by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information is specified for a predetermined address, the image data is transferred from the character ROM 434 to the image storage area 436a according to the transfer data information specified in the transfer data table, so that the transfer data information is specified according to the display data table. When drawing the sprite, the image data that is not resident in the resident video RAM 435 required for drawing the sprite can be stored in the image storage area 436a without fail.

As a result, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, the image necessary for display can be read in advance from the character ROM 434 and transferred to the normal video RAM 436 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the third symbol display device 281. Further, according to the description in the transfer data table, only the non-resident image data in the resident video RAM 435 can be easily and surely transferred from the character ROM 434 to the normal video RAM 436.

Further, the transfer data table has the same data structure as the display data table, and is associated with the address specified in the display data table, and the transfer of the transfer target image data to be started at the time indicated by the address is transferred. Since the data information is specified, the image data of a predetermined sprite is surely stored in the normal video RAM 436 before the image data of a predetermined sprite is used based on the display data table set in the display data table buffer 433d. As described above, since the transfer start timing can be instructed, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, a wide variety of effect images can be easily displayed on the third symbol display device 281. be able to.

Further, in the pachinko machine 200, since the NAND type flash memory 434a is used for the character ROM 434, all the image data to be stored in the resident video RAM 435 is transmitted from the character ROM 434 due to the slow read speed. It takes a lot of time to transfer to the resident video RAM 435, but after the power is turned on, the main image at power-on is first transferred from the character ROM 434 to the resident video RAM 435, and the main image at power-on is transferred. Is displayed on the third symbol display device 281 so that the player and the person concerned with the hall are displayed on the third symbol display device 281 while the remaining image data to be resident is transferred to the resident video RAM 435. You can check the main image when the power is turned on.

Therefore, the display control device 310 transfers the remaining resident image data from the character ROM 434 to the resident video RAM 435 over time while the main image at power-on is displayed on the third symbol display device 281. be able to. On the other hand, the player or the like can recognize that some initialization processing is being performed while the main image is displayed on the third symbol display device 281 when the power is turned on, so that the player or the like resides in the remaining resident video RAM 435. Until the image data to be transferred is transferred from the character ROM 434 to the resident video RAM 435, it is possible to wait until the initialization is completed without worrying about whether the operation has stopped. Further, even in the operation check in the factory or the like at the time of manufacturing, the main image at the time of turning on the power is immediately displayed on the third display device 218, so that the pachinko machine 200 has started the operation without any problem by turning on the power. You can check it immediately. Therefore, by using the NAND flash memory 434a having a slow read speed for the character ROM 434, it is possible to prevent the efficiency of the operation check from deteriorating.
The control program and fixed value data executed by the MPU 431 are not stored by providing a dedicated program ROM (for example, ROM 22 of Patent Document 1 described above) as in a conventional game machine, but are stored in the third symbol display device 281. For the purpose of storing a large amount of image data to be displayed on the screen, the data is stored in a character ROM 434 configured by a NAND flash memory 434a capable of increasing the capacity in a small area. As a result, since it is not necessary to provide a dedicated program ROM for storing the control program and the like, the number of parts in the display control device 314 can be reduced, the manufacturing cost can be reduced, and the failure occurrence rate increases due to the increase in the number of parts. Can be suppressed.

Further, according to the pachinko machine 200 of the seventh embodiment, the fixed value data such as the control program and various data tables stored in the NAND flash memory 434a (second program storage area 434a1) is booted by the MPU 431. Occasionally, it is transferred to the program storage area 433a or the data table storage area 433b provided in the work RAM 433, and the MPU 431 executes various processes with reference to the control program or the like stored in the program storage area 433a or the like. That is, the MPU 431 does not directly read the control program or the like from the NAND flash memory 434a having a slow read speed, but reads the control program or the like from the work RAM 433 configured by the DRAM capable of reading at high speed and performs various controls. Can be done. Therefore, even when the control program or the like is stored in the character ROM 434 configured by the NAND flash memory 434a, the high-performance MPU 431 can be used without being limited by the read speed of the NAND flash memory 434a. High processing performance can be maintained in the display control device 314. Therefore, it is possible to easily execute a diversified and complicated production by using the auxiliary production unit.

Further, in the pachinko machine 200, among the boot programs, a predetermined number of instructions from the instruction to be processed first by the MPU 431 after the system reset is released are stored in the NOR type ROM 434d, and after the system reset is released, the MPU 431 via the internal bus. When the address "0000H" is specified, the character ROM 434 immediately sets the boot program stored in the first program storage area 434d1 of the NOR type ROM 434d in the buffer RAM 434c, and transfers the corresponding data (instruction code) to the MPU 431. Output. Here, since the NOR type ROM is a memory capable of reading data at high speed, the MPU 431 can receive the instruction code corresponding to the address "0000H" in a short time after the address "0000H" is specified. .. Therefore, since the display main process can be started in a short time in the MPU 431, even if the control program is stored in the character ROM 434 configured by the NAND flash memory 434a having a slow read speed, the auxiliary effect in the display control device 314 is produced. The control of the unit can be started immediately.

Next, the pachinko machine 200 according to the eighth embodiment will be described with reference to FIGS. 88 to 96. In the pachinko machine 200 according to the seventh embodiment described above, the display control device 314 is determined according to a command or the like transmitted from the voice lamp control device 313 based on a command or the like from the main control device 313. When the effect mode of the effect is determined, the display data table corresponding to the determined effect mode is set in the display data table buffer 433d, and the transfer data table corresponding to the display data table is set in the transfer data table buffer 433f. Further, an additional data table corresponding to the effect to be added and displayed according to another command from the voice lamp control device 313 is set in the additional data table buffer 433e, and then in the display data table buffer 433d. Drawing of an image to be displayed on the third symbol display device 281 according to the set display data table, the additional data table set in the additional data table buffer 433e, and the transfer data table set in the transfer data table buffer 433f. And the case of controlling the transfer of the image data used for the drawing from the character ROM 434 to the normal video RAM 436 have been described.

On the other hand, in the pachinko machine 200 according to the eighth embodiment, the effect of the third symbol display device 281 determined according to the command or the like transmitted from the voice lamp control device 313 based on the command or the like from the main control device 313 is produced. A display data table corresponding to the mode, a transfer data table corresponding to the display data table, and an additional data table corresponding to an effect to be additionally displayed according to another command from the voice lamp control device 313. A composite data table is generated and set in the composite data table buffer 451d, and an image to be displayed on the third symbol display device 281 is drawn according to the composite data table set in the composite data table buffer 451d. And the transfer of the image data used for the drawing from the character ROM 434 to the normal video RAM 436 is controlled.

The difference in configuration between the pachinko machine 200 in the eighth embodiment and the pachinko machine 200 in the seventh embodiment is that the display control device 314 is provided with a work RAM 451 instead of the work RAM 433. Further, among the V interrupt processing (see FIG. 74 (a)) executed by the MPU 431 of the display control device 314, the demo command processing (S2509) and the variation pattern command processing (S2509), which are one of the command determination processing (S2402). S2511) and continuous notice command processing (S2515), comparison processing (S2710) which is one processing of display setting processing (S2403) and its display setting processing, and normal image transfer setting which is one processing of transfer setting processing (S2405). The partial treatment included in the treatment (S3003) is different from that of the pachinko machine 200 in the seventh embodiment. Other configurations, various processes executed by the MPU 401 of the main control device 310, various processes executed by the MPU 411 of the payout control device 311, various processes executed by the MPU 421 of the voice lamp control device 313, and the display control device 314. The other processing performed by the MPU 431 of the above is the same as that of the pachinko machine 200 in the seventh embodiment. Hereinafter, the same elements as those in the seventh embodiment are designated by the same reference numerals, and the illustration and description thereof will be omitted.

First, with reference to FIG. 88, the electrical configuration of the display control device 314 of the pachinko machine 200 according to the eighth embodiment will be described. FIG. 88 is a block diagram showing an electrical configuration of the display control device 314 according to the eighth embodiment. As described above, as shown in FIG. 88, the display control device 314 according to the present embodiment is provided with the work RAM 451 instead of the work RAM 433 in the display control device 314 according to the seventh embodiment. Since other configurations are the same as those of the display control device 314 in the seventh embodiment, the description thereof will be omitted.

The work RAM 451 is configured by a DRAM like the work RAM 433 in the seventh embodiment. The work RAM 451 has a program storage area 451a, a data table storage area 451b, a simple image display flag 451c, a composite data table buffer 451d, a pointer 451g, a drawing list area 451h, a time counting counter 451i, a stored image discrimination flag 451j, and a drawing target. At least the buffer flag 451k is provided. Of these, the program storage area 451a, the data table storage area 451b, the simple image display flag 451c, the pointer 451g, the drawing list area 451h, the time counting counter 451i, the stored image discrimination flag 451j, and the drawing target buffer flag 451k are each the seventh implementation. It has the same configuration and function as the program storage area 433a, data table storage area 433b, simple image display flag 433c, pointer 433g, drawing list area 433h, timing counter 433i, stored image discrimination flag 433j, and drawing target buffer flag 433k in the mobile device. It is a thing.

For example, the data table storage area 451b is displayed based on a command or the like transmitted from the voice lamp control device 313 based on a command or the like from the main control device 313, similarly to the data table storage area 433b in the seventh embodiment. For the effect, it is added to the display data table (see FIG. 57) that describes the display contents to be displayed on the third symbol display device 281 with the passage of time, and one effect based on the command from the voice lamp control device 313. It is used in an additional data table (see FIG. 58) that describes the display contents to be displayed over time and one effect displayed by the display data table, in contrast to the effect displayed on the third symbol display device 281. Of the image data, transfer data information for transferring image data that is not resident in the resident video RAM 435 from the character ROM 187 to the normal video RAM 436 and a transfer data table (see FIG. 59) that defines the transfer timing are stored. Area. Others are the same as those in the seventh embodiment, and thus the description thereof will be omitted here.

The synthetic data table buffer 451d is a synthetic data table corresponding to an effect mode of displaying on the third symbol display device 281 in response to a command or the like transmitted from the voice lamp control device 313 based on a command or the like from the main control device 310. It is a buffer for storing. The composite data table includes a display data table corresponding to the effect mode to be displayed on the third symbol display device 281, and an additional data table corresponding to the effect to be displayed on the third symbol display device 281 in addition to the effect. It is generated by synthesizing the transfer data table corresponding to the display data table.

Here, the details of the synthetic data table will be described with reference to FIG. 89. FIG. 89 is a schematic diagram schematically showing an example of a synthetic data table. In the composite data table, the time indicated by the address corresponding to the time (20 milliseconds in this embodiment) in which the image for one frame is displayed on the third symbol display device 281 is represented as one unit. Image content (drawing content) for one frame to be displayed in, and transfer data information of sprite image data (hereinafter referred to as "transfer target image data") to start transfer at the time indicated by the address. Is also specified.

Specifically, as shown in FIG. 89, the composite data table is provided with a display data table area, an additional data table area, and a transfer data table area for each address. The display data table area of each address is associated with the same address as the address specified in the composite data table in the display data table corresponding to the effect mode of the effect to be displayed on the third symbol display device 281. The content (drawing content) of the image for one frame to be displayed at the time indicated by the address is transcribed as it is. For example, the display data table area of the address "0001H" of the composite data table is associated with the address "0001H" of the display data table corresponding to the effect mode of the effect to be displayed on the third symbol display device 281. The drawing content to be displayed at the time indicated by the address "0001H" is posted as it is.

In the additional data table area of each address of the composite data table, the composite data table in the additional data table corresponding to the effect added to the effect corresponding to the display data table for posting the drawing contents to the display data table area. The content (drawing content) of the image for one frame to be additionally displayed at the time indicated by the address, which is associated with the same address as the address specified in the above, is transcribed as it is.

For example, in the additional data table area of the synthetic data table address "097H", at the time indicated by the address "097H" associated with the address "0907H" of the additional data table corresponding to the added effect. The drawing content to be added is posted as it is. If the Null data is specified in the synthetic data table address "0001H" posted in the synthetic data table area, the Null data remains in the transfer data table area of the synthetic data table address "0001H". Posted.

If the effect to be added to the effect corresponding to the display data table for posting the drawing contents to the display data table area has not been determined, it should be added to the composite data table area of all the addresses of the composite data table. Null data, which means that the display does not exist but does not exist, is described.

In the transfer data table area of each address of the composite data table, the same address as the address specified in the composite data table is associated with the transfer data table corresponding to the display data table for posting the drawing contents to the display data table area. The transfer data information of the transfer target image data to be transferred at the time indicated by the address is posted as it is. If Null data, which means that there is no transfer target image data to be transferred corresponding to the address, is specified in one address of the transfer data table, one of the composite data tables is specified. Null data is posted as it is to the transfer data table area of the address.

For example, the transfer data table area of the composite data table address "0001H" is associated with the transfer data table address "0001H" corresponding to the display data table posted in the display data table area. The transfer data information of the transfer target image data to be transferred at the time indicated by "0001H" is transferred as it is. Further, when the Null data is specified in the transfer data table address "097H" corresponding to the display data table posted in the display data table area, the transfer data table area of the composite data table address "097H" is used. However, the Null data is posted as it is.

If the transfer data table corresponding to the display data table for posting the drawing contents is not prepared in the display data table area, all the image data of the sprite used in the effect specified in the display data table is resident. Since it is stored in the video RAM 435 and means that the transfer from the character ROM 434 to the normal video RAM 436 is unnecessary, the transfer target image to be transferred to the transfer data table area of all the addresses of the composite data table. Null data is described, which means that the data does not exist.

The MPU 431 has an effect mode of causing the third symbol display device 281 to execute in response to a command (display variation pattern command) transmitted from the voice lamp control device 313 based on a command or the like received from the main control device 310. Once determined, the display data table corresponding to the effect mode and the transfer data table corresponding to the display data table are extracted from the data table storage area 451b. Then, the content (drawing content) of the image for one frame to be displayed at the time indicated by the address specified for each address in the extracted display data table is displayed in the display data table of the same address in the composite data table. The transfer data information of the transfer target image data that should be transferred to the area and the transfer should be started at the time indicated by that address specified for each address in the extracted transfer data table is transferred to the same address in the composite data table. By posting to the transfer data table area, a composite data table that combines the display data table and the transfer data table is generated. Then, the generated synthetic data table is set in the synthetic data table buffer 451d.

At this point, the effect to be additionally displayed on the third symbol display device 281 has not been determined. Therefore, when generating this composite data table, Null data is added to the additional data table area of all the addresses. Write it down. If the transfer data table corresponding to the display data table for posting the drawing contents is not prepared in the display data table area of the composite data table, as described above, the transfer data table area of all the addresses of the composite data table. The composite data table is generated by writing the Null data, which means that there is no transfer target image data to be transferred to.

The MPU 431 is a command different from the command for which the effect mode of the effect to be executed by the third symbol display device 281 is determined, and is a command transmitted from the voice lamp control device 313 (in the present embodiment, continuous). When the effect to be added to the effect to be executed on the third symbol display device 281 is determined in response to the notice command), the additional data table corresponding to the effect to be added is extracted from the data table storage area 451b. The content (drawing content) of the image for one frame to be additionally displayed at the time indicated by the address specified for each address in the extracted additional data table is set in the composite data table buffer 451d. Post by overwriting to the additional data table area at the same address in the composite data table. As a result, the drawing content of the effect to be added is added to the additional data table area of the composite data table previously generated by the display data table and the transfer data table.

Further, the MPU 431 initializes the pointer 451g when the generated synthetic data table is set in the synthetic data table buffer 451d. Then, after adding 1 of 451 g each time the drawing process for one frame is completed, the composite data table stored in the composite data table buffer 451d is transferred to the display data table area and the additional data table area of the address indicated by the pointer 451 g. The image content to be drawn next is specified based on the specified drawing content, and the transfer data information of the image data of the predetermined sprite specified in the transfer data table area of the address and to start the transfer at that time is used. Specify and create a drawing list (see FIG. 60). By transmitting this drawing list to the image controller 437, the MPU 431 gives an image controller 437 a drawing instruction for the image and an image data transfer instruction. Further, when the Null data is specified in the transfer data table area of the address indicated by the pointer 451g, it is determined that the transfer target image data to be transferred does not exist, and the transfer data information is not included in the drawing list. , The drawing list is transmitted to the image controller 437.

As a result, the drawing contents are specified in the order specified by the display data table and the additional data table according to the update of the pointer 451g, so that the image as specified by the display data table and the additional data table is the third symbol display device. Displayed at 281. Further, according to the update of the pointer 451g, a process of transferring the image data of the predetermined sprite from the character ROM 434 to the predetermined sub-area of the image storage area 436 a provided in the normal video RAM 436 is executed at a predetermined time.

As described above, in the pachinko machine 200, in the display control device 314, a program to be executed by the MPU 431 in response to a command (for example, a display variation pattern command or a continuous warning command) transmitted from the voice lamp control device 313. The effect image to be displayed on the third symbol display device 281 can be changed only by a simple operation of appropriately replacing the display data table and the additional data table used for generating the composite data table, instead of changing the above.

Here, when the program executed by the MPU 431 is activated every time the effect image displayed on the display control device 314 is changed like the conventional pachinko machine, it becomes complicated due to the diversification of the effect images. In addition, since a large load is applied to the processing of starting and executing an enormous amount of programs, the processing capacity of the display control device 314 may be limited, and the diversification of controllable production images may be limited. .. On the other hand, in the pachinko machine 200, the effect image to be displayed on the third symbol display device 281 can be changed only by a simple operation of appropriately replacing the display data table and the additional data table used for generating the synthetic data table. Therefore, various types of effect images can be displayed on the third symbol display device 281 regardless of the processing capacity of the display control device 314.

Further, in this way, a display data table is prepared corresponding to each effect mode, a composite data table is generated from the display data table according to the effect mode to be displayed, and the synthetic data table is according to the generated composite data table. The reason why the drawing list can be created frame by frame is that in the pachinko machine 200, the effect to be displayed on the third symbol display device 281 is determined in advance based on the result of the lottery performed based on the start winning prize. be. On the other hand, in game machines other than gaming machines such as the pachinko machine 200, the display contents change on the spot based on the user's operation, so that the display contents cannot be predicted. Therefore, as described above. It is not possible to have a display data table corresponding to each effect mode. In this way, a display data table is prepared corresponding to each effect mode, a composite data table is generated from the display data table according to the effect mode to be displayed, and this is set in the composite data table buffer 451d. The configuration in which the drawing list is created frame by frame according to the set synthetic data table is an effect mode in which the pachinko machine 200 displays in advance on the third symbol display device 281 based on the result of the lottery performed based on the start winning prize. It can be realized only based on the configuration that determines.

Further, the MPU 431 is defined as an additional data table corresponding to the additional effect to be displayed when the other effect is displayed in addition to the effect mode to be displayed on the third symbol display device 281. Since the drawing content is added to the additional data table buffer area of the composite data table set in the composite data table buffer 451d, the effect can be easily added to the base effect mode and displayed. As a result, for example, when there are 32 types of original effect images and there are 5 types of other effect images to be additionally displayed, a display in which an image in which other effect images are superimposed for each original effect image is defined. If a data table is prepared separately, 32 x (1 + 5) = 192 types of display data tables must be prepared, but a data table corresponding to other production images such as this pachinko machine 200 is used as an additional data table. By separately specifying, 32 + 5 = 37 types of displays and additional data tables may be prepared, and the capacity increase of the data table storage area 451b can be suppressed. Therefore, it is possible to store the data table corresponding to various aspects of the effect within the capacity prepared in the data table storage area 451b, and it is possible to easily further diversify the effect image.

Further, as in the case of this pachinko machine 200, when other effects to be additionally displayed are specified as an additional data table and the display of other effects to be additionally displayed is decided, the original effect mode is supported. Since the drawing contents specified in the additional data table corresponding to other effects are added to the composite data table generated by the display data table and the transfer data table, the composite data set in the composite data table buffer 451d is added. Never regenerate the table from scratch. Therefore, it is possible to easily add and display the other effect images to be added and displayed to the original effect image.

Further, in the transfer data table, as described above in the seventh embodiment, the image data corresponding to the predetermined sprite is stored in the image of the normal video RAM 436 by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information of the image data to be transferred is specified for a predetermined address so as to be stored in the area 436a, the image data is stored according to the transfer data information specified in the transfer data table area of the composite data table. By transferring from the character ROM 434 to the image storage area 436a, when drawing a predetermined sprite according to the display data table area of the composite data table, the image data that is not resident in the resident video RAM 435 required for drawing the sprite is transferred. , Can always be stored in the image storage area 436a. Then, using the image data stored in the image storage area 436a, a predetermined sprite can be drawn based on the display data table.

As a result, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, the image necessary for display can be read in advance from the character ROM 434 and transferred to the normal video RAM 436 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the third symbol display device 281. Further, by describing the transfer data table area of the composite data table, only the non-resident image data in the resident video RAM 435 can be easily and surely transferred from the character ROM 434 to the normal video RAM 436.

Further, in the pachinko machine 200, in the display control device 314, the display data table is extracted from the data table storage area 451b in response to a command or the like from the voice lamp control device 313, and the display data table is supported. Since the transfer data table to be transferred is extracted from the data table storage area 451b and a composite data table is generated by combining the extracted display data table and the transfer data table, the transfer timing of the image data to be transferred can be easily grasped. Can be controlled. Therefore, the image data of the sprite used for drawing the image performed according to the display data table area of the composite data table can be reliably transferred from the character ROM 434 to the normal video RAM 436 at a desired timing.

Further, in the transfer data table, the transfer data information is defined so that the image data is transferred from the character ROM 434 to the normal video RAM 436 for each image data corresponding to the sprite. Therefore, in the transfer data table area of the composite data table. Also, the transfer data information is defined so that the image data is transferred from the character ROM 434 to the normal video RAM 436 for each image data corresponding to the sprite. As a result, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 434 to the normal video RAM 436 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

In addition, the additional data table and the transfer data table have the same data structure as the display data table, and in the additional data table, they are added at the time indicated by the address corresponding to the address specified in the display data table. In the transfer data table, the transfer data information of the transfer target image data to be transferred is defined in correspondence with the address specified in the display data table. Therefore, a synthetic data table can be easily generated.

Further, a display data table area, an additional data table area, and a transfer data table area are provided for each address of the synthetic data table, and the time indicated by the display data table area and the additional data table area of each address indicates the time. The drawing content to be displayed is specified in, and the transfer data table area of each address defines the transfer data information of the transfer target image data to be transferred at the time indicated by that address. Before the image data of a predetermined sprite is used based on the area, the transfer start timing is specified and instructed based on the transfer data table area so that the image data is surely stored in the normal video RAM 436. Can be done. Therefore, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, a wide variety of effect images can be easily displayed on the third symbol display device 281.

In addition, since it is possible to specify the drawing content of the effect mode originally determined from one composite data table, the drawing content of the effect added later, and the transfer data information of the image data to be transferred, the display data. Compared with the case where the drawing content and the transfer data information are specified from the table, the additional data table, and the transfer data table, the processing load required for the identification can be reduced.

Next, with reference to FIGS. 90 to 96, various processes executed by the MPU 431 of the display control device 314 according to the eighth embodiment will be described. First, FIG. 90 is a flowchart showing a demo command process (S2509) executed by the MPU 431 of the display control device 314. As described above in the seventh embodiment, the demo command process is a process executed in the command determination process (S2402), which is one process of the V interrupt process (see FIG. 74 (b)), and is a voice lamp. When a demo command is received from the control device 313, the process corresponding to the demo command is executed.

In the demo command processing in the eighth embodiment, first, the drawing contents defined for each address of the demo display data table are transferred to the display data table area provided at the same address of the composite data table, and the composite is performed. A synthetic data table is generated by writing Null data to the additional data table area and the transfer data table area of all the addresses of the data table (S3621). Then, the generated synthetic data table is set in the synthetic data table buffer 451d (S3622).

After that, the same processing as S2623 to S2625 of the demo command processing in the seventh embodiment is executed. That is, the time data corresponding to the demo effect is set in the timekeeping counter 451i (S2623), and the pointer 451g is initialized to 0 (S2624). Then, the demo display flag indicating that the demo effect is displayed in the on state of the third symbol display device 281 is set to on, and the confirmed display effect is displayed on the third symbol display device 281 in the on state. The confirmation display flag shown is set to off, and the confirmation display flag indicating that the confirmation display effect is being performed in the on state is set to off (S2625), the demo command processing is terminated, and the process returns to the command determination processing.

By executing this demo command processing, in the display setting processing, while updating the pointer 451g initialized by the processing of S2624, the pointer from the synthetic data table set in the synthetic data table buffer 451d by the processing of S3622. By extracting the drawing contents defined in the display data table area of the address shown in 451 g, the demo effect is displayed on the third symbol display device 281. Since Null data is written in the additional data table area and the transfer data table area, another effect is not added and displayed for the demo effect, and the image data used for the demo effect is a character. It is not transferred from the ROM 434 to the normal video RAM 436. For the demonstration effect, drawing is performed using the image data resident in the resident video RAM 435.

Next, with reference to FIG. 91, the variation pattern command processing executed by the MPU 431 of the display control device 314 will be described (S2511). FIG. 91 is a flowchart showing the fluctuation pattern command processing. As described above in the seventh embodiment, the variation pattern command process is a process executed in the command determination process (S2402), which is one process of the V interrupt process (see FIG. 74 (b)), and is a main process. When a display variation pattern command transmitted from the voice lamp control device 313 based on the variation pattern command from the control device 310 is received, the process corresponding to the display variation pattern command is executed.

In the variation pattern command processing in the eighth embodiment, first, a variation display data table corresponding to the variation effect pattern indicated by the display variation pattern command and a transfer data table corresponding to the variation display pattern data table are determined. (S3631). In this process, as in the process of S2631 of the variation pattern command process in the seventh embodiment, a part of the command is changed due to the influence of noise or the like, and another command is erroneously interpreted as a variation pattern command for display. If it is determined that two or more display variation pattern commands are stored in the command buffer area, the variation display data table corresponding to the variation pattern with the shortest variation time is determined. As a result, even when the fluctuation effect having a longer variation time than the set display data table is actually instructed by the main control device 310, the variation effect according to the composite data table buffer 451d is completed. After that, the display of the third symbol display device 281 is controlled by the display setting process so that the restart effect is displayed until the confirmation command (display confirmation command) from the main control device 310 is received. Therefore, the player can visually recognize the restart effect as a part of the variation effect, and can continue to see the variation of the third symbol in the third symbol display device 281 without discomfort until the stop display of the third symbol is confirmed.

Next, the drawing contents specified in each address of the determined variation table display data table are transferred to the display data table area provided at the same address of the synthetic data table, and specified in each address of the determined transfer data table. By posting the transferred data information to the transfer data table area provided at the same address of the composite data table, and further writing the Null data to the additional data table area of all the addresses of the composite data table, the composite data Generate a table (S3632). Then, the generated synthetic data table is set in the synthetic data table buffer 451d (S3633).

After that, the same processing as S2634 to S2638 of the variation pattern command processing in the seventh embodiment is executed. That is, among the data table discrimination flags provided for each fluctuation display data table corresponding to each fluctuation pattern, the data table discrimination flag corresponding to the fluctuation display data table determined by the processing of S3631 is turned on, and other The data table discrimination flag corresponding to the variable display data table of is set to off (S2634). In the display setting process, by referring to the data table discrimination flag set by the process of S2634, which variation pattern is the variation display data table used to generate the composite data table set in the composite data table buffer 451d. It can be easily determined whether or not it corresponds to.

Then, in the display setting process, it is determined whether or not there is a contradiction between the fluctuation pattern of the variable display data table used to generate the composite data table and the stop symbol set by the display stop type command received later. However, if there is a contradiction, as will be described later, a synthetic data table is generated using the display data table corresponding to the special variation and set in the synthetic data table buffer 451d.

Next, time data representing the fluctuation time is measured based on the fluctuation time of the fluctuation pattern corresponding to the fluctuation display data table used for generating the composite data table set in the composite data table buffer 451d by the processing of S3633. The counter 451i is set (S2635), and the pointer 451g is initialized to 0 (S2636). Then, the confirmation command flag, the demo display flag, and the confirmation display flag are all set to off (S2637), and the restart timer counter used in the display setting process is initialized to 0 (S2638). Is terminated, and the process returns to the command judgment process.

By executing this variation pattern command processing, in the display setting processing, while updating the pointer 451g initialized by the processing of S2636, from the synthetic data table set in the synthetic data table buffer 451d by the processing of S3633, The drawing content defined in the display data table area of the address indicated by the pointer 451g is extracted, and the content of the image for one frame to be displayed next in the third symbol display device 281 is specified, and at the same time, it is indicated by the pointer 451g. The transfer data information of the transfer data table area specified in the address is extracted, and the image data of the sprite necessary for drawing the image specified in the display data table area is previously stored in the image storage area 436a of the normal video RAM 436 from the character ROM 434. The image controller 437 is controlled so as to be transferred to. Since the Null data is written in the additional data table area, the other effect is not displayed until another effect (continuous notice effect) is added to the variable effect.

Further, in the display setting process, the time of the variation effect specified in the composite data table is measured by using the time counting counter 451i in which the variation time data is set by the process of S2635, so that the variation effect in the composite data table is completed. If it is determined that the confirmation command (display confirmation command) is received from the main control device 310, the confirmation display effect is displayed on the third symbol display device 281, and the confirmation command (display) is displayed within a predetermined time after the variation effect is completed. If the confirmation command) cannot be received, the display setting can be controlled so that the restart effect is displayed on the third symbol display device 281.

Next, with reference to FIG. 92, the continuous advance notice command processing executed by the MPU 431 of the display control device 314 will be described (S2515). FIG. 92 is a flowchart showing the continuous advance notice command processing. As described above in the seventh embodiment, the continuous notice command process is a process executed in the command determination process (S2402), which is one process of the V interrupt process (see FIG. 74 (b)), and is a voice. When a continuous warning command transmitted from the lamp control device 313 is received, the process corresponding to the continuous warning command is executed.

In the continuous notice command processing, the processing of S2651 and S2653 is the same as the processing of S2651 and S2653 of the continuous notice command processing in the seventh embodiment. Therefore, although detailed description of these processes will be omitted, in the continuous notice command processing in the eighth embodiment, first, a new continuous notification that the continuous notice command has been processed in the ON state is notified to the transfer setting process (S2405). When the notice command flag is set to on (S2651), then the continuous notice image type (one of "bubble", "tamago", "chick", "chicken", and "chicken group") indicated by the continuous notice command is set. The corresponding additional data table for continuous notice is determined, the determined additional data table for continuous notice is read from the data table storage area 433b, and the drawing contents specified in each address of the read additional data table for continuous notice are read. Is added to the additional data table area provided at the same address of the synthetic data table set in the synthetic data table buffer 451d (S3652).

As a result, in the display setting process, the process of S3652 is applied to the effect corresponding to the display data table posted in the display data table area provided at each address of the composite data table set in the composite data table buffer 451d. , Next in the third symbol display device 281 so that the continuous notice effect corresponding to the continuous notice additional data table added to the additional data table area provided at each address of the composite data table is additionally displayed. Specify the display content of the image for one frame of.

After that, among the continuous advance notice determination flags provided for each continuous advance notice image type, the continuous advance notice determination flag corresponding to the continuous advance notice image type included in the continuous advance notice command is turned on, and the continuous advance notice image types corresponding to other continuous advance notice image types are turned on. The advance notice determination flag is set to off (S2653), the continuous advance notice command processing is terminated, and the process returns to the command determination processing.

In the transfer setting process, when it is detected that the new continuous advance notice command flag set by the process of S2651 is turned on, it is said that a predetermined additional data table for continuous advance notice is added to the synthetic data table buffer 451d by the continuous advance notice command process. Judgment is made, and the continuous advance notice type corresponding to the continuous advance notice additional data table added to the synthetic data table buffer 451d is specified from the continuous advance notice determination flag set by the process of S2653. Then, the image controller 437 is instructed to transfer the image data necessary for displaying the specified continuous advance notice type.

Next, the display setting process (S2403) executed by the MPU 431 of the display control device 314 will be described with reference to FIGS. 93 and 94. FIG. 93 and FIG. 94 are flowcharts showing the display setting process. As described above in the seventh embodiment, the display setting process is a process executed in the command determination process (S2402), which is one process of the V interrupt process (see FIG. 74 (b)), and is a command determination. Based on the content of the composite data table set in the composite data table buffer 451d by processing (S2402) or the like, the content of the image for one frame to be displayed next in the third symbol display device 281 is specifically specified. be. Further, in the display setting process, the pointer 451 g is also updated.

In the display setting process of the eighth embodiment, the processes of S3712, S3716, S3724, and S3731 are executed instead of the processes of S2712, S2716, S2724, and S2731 of the display setting process of the seventh embodiment. On the other hand, the processing of the other steps of the display setting processing in the eighth embodiment is the same as the processing of the step with the same reference numeral in the display setting processing in the seventh embodiment, and therefore the detailed description thereof is omitted here. do. Hereinafter, the processes of S3712, S3716, S3724, and S3731, which are steps specific to the display setting process in the eighth embodiment, will be mainly described.

In this display setting process, the pointer update process is executed by the process of S2711, and when the pointer 451 g is updated, it is then updated by the pointer update process from the composite data table set in the composite data table buffer 451d. The drawing contents specified in the display data table area and the additional data table area of the address indicated by the pointer 451g are expanded (S3712). In the task processing, a sprite (display object) that composes an image based on the drawing contents developed by the processing of S3712 together with the hold image previously developed by the processing of S2704 and the warning image developed by the processing of S2706. In addition to specifying the type of image, various parameters required for drawing such as display coordinate position, enlargement ratio, and rotation angle are determined for each sprite. If Null data is described in the additional data table area, the subsequent processing is executed assuming that there is no sprite to be added.

In the subsequent processing of S2713, similarly to the seventh embodiment, the value of the timekeeping counter g is subtracted by 1, and it is determined whether or not the value of the timekeeping counter 451i after the subtraction is 0 or less (S2714), and the timekeeping is performed. When the value of the counter 451i is 0 or less (S2714: Yes), the effect time corresponding to the display data table used to generate the composite data table set in the composite data table buffer 451d has elapsed. Means. At this time, if the variable display data table is used to generate the composite data table, a confirmation command (display confirmation command) is sent from the main control device 310 via the voice lamp control device 314 at the end of the effect. ) Should be transmitted, so in the subsequent processing of S2715, it is confirmed whether or not the confirmation command flag is on (S2715).

As a result, if the confirmation command flag is on (S2715: Yes), it means that the confirmation command (display confirmation command) has been received from the main control device 310 via the voice lamp control device 314. The drawing contents specified for each address of the display data table are posted to the display data table area provided at the same address of the composite data table, and the composite data table area and transfer data table of all the addresses of the composite data table are posted. By writing Null data to the area, a synthetic data table is generated, and the generated synthetic data table is set in the synthetic data table buffer 451d (S3716). Then, the process proceeds to S2717.

As a result, when the composite data table generated from the variable display data table is set in the composite data table buffer 451d, the main control device 310 via the voice lamp control device 313 at the end of the effect. When the confirmation command (display confirmation command) is received, the drawing content can be set so that the confirmation display effect of the stopped symbol in the variation effect is displayed on the third symbol display device 281. Further, by simply changing the display data table posted in the display data table area of the composite data table to the confirmed display data table, the effect displayed on the third symbol display device 281 can be easily changed to the confirmed display effect. can. Further, as compared with the case where the display content is changed by starting another program as in the conventional case, the program is not complicated and bloated, and therefore, a large load is not applied to the MPU 431. Regardless of the processing capacity of the display control device 314, various types of effect images can be displayed on the third symbol display 281.

Further, in the processing of S2715, if the confirmation command flag is off instead of on (S2715: No), the process proceeds to the processing of S2722 shown in FIG. 94, and the confirmation display flag indicating that the confirmation display effect is being performed in the ON state. It is determined whether or not the confirmation display flag is on (S2722). If the confirmed display flag is on (S2722: Yes), the result of the determination in the process of S2714 (S2714: Yes) means that the confirmed display effect has ended, so the confirmed display flag is set to off. Later (S2723), the drawing contents specified for each address of the demo display data table are posted to the display data table area provided at the same address of the synthetic data table, and all the addresses of the synthetic data table are added. By writing Null data to the data table area and the transfer data table area, a synthetic data table is generated, and the generated synthetic data table is set in the synthetic data table buffer 451d (S3724). Then, the process proceeds to S2725.

As a result, if the display variation pattern command indicating the start of the next variation effect or the display demo effect command indicating the start of the demo effect is not received by the end of the final display effect, the display automatically. The drawing content can be set so that the demo effect is displayed on the third symbol display device 281.

Further, in the process of S2722, if the confirmation display flag is not on but off (S2722: No), then it is determined whether or not the demo display flag indicating that the demo is being produced in the on state is on. (S2728). As a result, when the demo display flag is not on but off (S2728: No), the result of the determination in the processing of S2714 (S2714: Yes) means that the variation effect is completed. Therefore, if the confirmation command is not received even after a predetermined time has elapsed from the end of the variation effect, the composite data generated based on the variation display data table corresponding to the variation effect in order to start the restart effect. 1 is added to the restart timer counter initialized to 0 when the table is set in the composite data table buffer 451d (S2729), and whether or not the value of the restart timer counter after addition has reached a predetermined value. (S2730).

Then, when the restart timer counter is a predetermined value (S2730: Yes), the drawing contents defined for each address of the restart display data table are provided in the display data table area at the same address of the composite data table. Generates a synthetic data table by posting to and writing Null data to the additional data table area and transfer data table area of all addresses of the synthetic data table, and sets the generated synthetic data table in the synthetic data table buffer 451d. (S3731). Then, the process proceeds to S2732.

As a result, in the display control device, even if a predetermined time elapses after the third symbol is stopped and displayed with the end of the variation effect, the confirmation command (confirmed command) transmitted from the main control device 310 via the voice lamp control device 313 ( When the display confirmation command) is not received, the drawing content can be set so that the restart effect is displayed on the third symbol display device 281. Then, as described above, the restart effect is an effect of displaying the image obtained by vibrating the third symbol on the third symbol display device 281. Therefore, the player can display the third symbol on the third symbol display device 281. By visually recognizing that the third symbol is vibrated and displayed after the change of is stopped and displayed, it can be recognized that the stopped symbol has not been determined at that time.

Next, the comparison process (S2710) executed by the MPU 431 of the display control device 314 will be described with reference to FIG. 95. FIG. 95 is a flowchart showing the comparison process. This process is executed when it is determined that the comparison flag is on in the above-mentioned display setting process (FIGS. 93 and 95) (S2709: Yes), and is based on the display variation pattern command. , When the variable display data table used to generate the composite data table set in the composite data table buffer 451d and the stop symbol set based on the display stop type command are inconsistent, the fluctuation occurs. To change the effect to a special variable effect that displays the third symbol at high speed until the confirmation command (display confirmation command) transmitted from the main control device 310 via the voice lamp control device 313 is received. It is the processing of.

As described above in the seventh embodiment, the fluctuation display data table is prepared for each fluctuation pattern, and each fluctuation pattern includes, for off, for 15R fixed jackpot / time saving jackpot, and for 15R probability variation jackpot. For 2R probability change jackpot ... etc. Therefore, for example, when the stop symbol is set as the jackpot symbol even though the variation display data table corresponds to the deviation pattern, it is determined in the comparison process that these are inconsistent. ..

In the comparison process in the eighth embodiment, the process of S3784 is executed instead of the process of S2784 of the display setting process in the seventh embodiment. On the other hand, the processing of the other steps of the display setting processing in the eighth embodiment is the same as the processing of the step with the same reference numeral in the display setting processing in the seventh embodiment, and therefore the detailed description thereof is omitted here. do. Hereinafter, the process of S3784, which is a step peculiar to the display setting process in the eighth embodiment, will be mainly described.

In this comparison process, it is determined whether or not the type of the variable display data table specified by the process of S2781 matches the stop symbol specified by the process of S2782 (S2783), and it is determined that they do not match. In the case (S2783: No), the drawing contents specified for each address of the special variation display data table are transferred to the display data table area provided at the same address of the composite data table, and all of the composite data table is transferred. By writing Null data to the additional data table area and the transfer data table area of the address, a synthetic data table is generated, and the generated synthetic data table is set in the synthetic data table buffer 451d (S3784). Then, the process proceeds to S2785.

As a result, the variation display data table used to generate the composite data table set in the composite data table buffer 451d based on the display variation pattern command and the stop symbol set based on the display stop type command are displayed. If there is a contradiction, the composite data table is generated from the special variation display data table and set in the composite data table buffer 451d, so that the third symbol continues to fluctuate at high speed on the third symbol display device 281. A special variation effect is displayed. Since the special stop symbol is set as the stop symbol by the process of S2785, when the confirmation command (display confirmation command) transmitted from the main control device 310 via the voice lamp control device 313 is received. , The special stop symbol can be confirmed and displayed on the third symbol display 281.

Here, when the variation effect pattern instructed by the main control device 310 via the voice lamp control device 313 and the stop symbol to be displayed at the time of stop display of the variation effect do not match, the display control device 314 uses the main control device. There is a possibility that it is not possible to correctly reflect the result of the lottery performed in 310 and perform a variable effect or a definite display effect. On the other hand, in the pachinko machine 200, in such a case, a special variation effect is performed, and after the variation display, a special stop symbol indicating a special deviation is confirmed and displayed on the third symbol display device 281. Even if the result of the lottery in 310 is wrong, it is possible to prevent the third symbol display device 281 from erroneously performing a definite display effect of the jackpot. Further, even if the special stop symbol is confirmed and displayed on the third symbol display device 281, if the lottery result in the main control device 310 is a big hit, the actual gaming state in the pachinko machine 200 shifts to the special gaming state. The person can continue the game with peace of mind. Further, by setting the confirmation display to a special stop symbol, it is possible to suggest to the player that the pachinko machine 200 may be in a big hit state even if the confirmation display is off. Even though the confirmation display is off, the pachinko machine 200 is in a big hit state, so that the player does not feel uneasy.

Next, the normal image transfer setting process (S3003) executed by the MPU 431 of the display control device 314 will be described with reference to FIG. 96. FIG. 96 is a flowchart showing the normal image transfer setting process. As described above in the seventh embodiment, the normal image transfer setting process is a process executed in the transfer setting process (S2405), which is one of the V interrupt processes (see FIG. 74 (b)). While the simple image display flag 451c is off, predetermined image data is sent to the image controller 437 based on the transfer data information described in the transfer data table area of the composite data table set in the composite data table buffer 451d. A transfer instruction for transferring from the character ROM 434 to a predetermined sub-area of the image storage area 436a of the normal video RAM 436 is set.

In this normal image transfer setting process, first, from the composite data table set in the composite data table buffer 451d, the address indicated by the pointer 451g updated by the display setting process (S2403, see FIG. 93) executed earlier. The information described in the transfer data table area provided in S4201 is acquired (S4201), and the process proceeds to S3202. Then, in the processing of S3202 to S3218, the same processing as the processing of S3202 to S3218 of the normal image transfer setting processing in the seventh embodiment is performed. Therefore, detailed description of these processes will be omitted.

As described above, in the display control device 314, a synthetic data table as shown in FIG. 89 is generated from the display data table, the additional data table, and the transfer data table, and is set in the synthetic data table buffer 451d. Then, the MPU 431 executes the normal image transfer setting process, and the transfer data described in the transfer data table area provided at the address indicated by the pointer 451 g of the composite data table set in the composite data table buffer 451d. Since the transfer instruction of the transfer target image is set to the image controller 437 according to the information, the image data of the sprite specified in the display data table area of the composite data table buffer 451d can be reliably transferred from the character ROM 434 to the normal video at a desired timing. It can be transferred to RAM 436.

Here, as in the seventh embodiment, the transfer data is stored so that the image data corresponding to the predetermined sprite is stored in the image storage area 436a by the time the drawing of the predetermined sprite is started according to the display data table. In the table, the transfer data information of the image data to be transferred is specified for a predetermined address, so that the image data is transferred from the character ROM 434 to the image storage area according to the transfer data information specified in the transfer data table area of the composite data table. By transferring to 436a, when drawing a predetermined sprite according to the display data table area of the composite data table, the image data that is not resident in the resident video RAM 435 required for drawing the sprite is sure to be stored in the image storage area 436a. Can be stored in. Then, using the image data stored in the image storage area 436a, a predetermined sprite can be drawn based on the display data table.

As a result, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, the image necessary for display can be read in advance from the character ROM 434 and transferred to the normal video RAM 436 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the third symbol display device 281. Further, by describing the transfer data table area of the composite data table, only the non-resident image data in the resident video RAM 435 can be easily and surely transferred from the character ROM 434 to the normal video RAM 436.

Further, in the transfer data table, the transfer data information is defined so that the image data is transferred from the character ROM 434 to the normal video RAM 436 for each image data corresponding to the sprite. Therefore, in the transfer data table area of the composite data table. Also, the transfer data information is defined so that the image data is transferred from the character ROM 434 to the normal video RAM 436 for each image data corresponding to the sprite. As a result, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 434 to the normal video RAM 436 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

As described above, according to the pachinko machine 200 of the eighth embodiment, the command (display variation pattern command) or the like transmitted from the voice lamp control device 313 based on the command or the like received from the main control device 310 may be used. When the effect mode to be executed by the third symbol display device 281 is determined accordingly, the display data table corresponding to the effect mode and the transfer data table corresponding to the display data table are extracted from the data table storage area 451b. do. Then, the content (drawing content) of the image for one frame to be displayed at the time indicated by the address specified for each address in the extracted display data table is displayed in the display data table of the same address in the composite data table. The transfer data information of the transfer target image data that should be transferred to the area and the transfer should be started at the time indicated by that address specified for each address in the extracted transfer data table is transferred to the same address in the composite data table. By posting to the transfer data table area, a composite data table that combines the display data table and the transfer data table is generated. Then, the generated synthetic data table is set in the synthetic data table buffer 451d.

Further, when an effect to be added to the effect executed on the third symbol display device 281 is determined in response to another command (for example, a continuous advance notice command) transmitted from the voice lamp control device 313, the effect is added. An additional data table corresponding to the effect to be output is extracted from the data table storage area 451b, and one frame to be additionally displayed at the time indicated by the address specified for each address in the extracted additional data table. The content (drawing content) of the image is transferred by overwriting to the additional data table area of the same address of the composite data table set in the composite data table buffer 451d. As a result, the drawing content of the effect to be added is added to the additional data table area of the composite data table previously generated by the display data table and the transfer data table.

On the other hand, when the generated synthetic data table is set in the synthetic data table buffer 451d, the pointer 451g is initialized. Then, after adding 1 of 451 g each time the drawing process for one frame is completed, the composite data table stored in the composite data table buffer 451d is transferred to the display data table area and the additional data table area of the address indicated by the pointer 451 g. The image content to be drawn next is specified based on the specified drawing content, and the transfer data information of the image data of the predetermined sprite specified in the transfer data table area of the address and to start the transfer at that time is used. Specify and create a drawing list (see FIG. 60). Then, by transmitting this drawing list to the image controller 437, the image controller 437 is instructed to draw the image and to transfer the image data.

As a result, the drawing contents are specified in the order specified by the display data table and the additional data table according to the update of the pointer 451g, so that the image as specified by the display data table and the additional data table is the third symbol display device. Displayed at 281. Further, according to the update of the pointer 451g, a process of transferring the image data of the predetermined sprite from the character ROM 434 to the predetermined sub area of the image storage area 436 a provided in the normal video RAM 436 is executed at a predetermined time.

As described above, in the pachinko machine 200, in the display control device 314, a program to be executed by the MPU 431 in response to a command (for example, a display variation pattern command or a continuous warning command) transmitted from the voice lamp control device 313. The effect image to be displayed on the third symbol display device 281 can be changed only by a simple operation of appropriately replacing the display data table and the additional data table used for generating the composite data table, instead of changing the above.

Here, when the program executed by the MPU 431 is started every time the effect image displayed on the display control device 314 is changed like the conventional slot machine, it becomes complicated due to the diversification of the effect images. In addition, since a large load is applied to the processing of starting and executing an enormous amount of programs, the processing capacity of the display control device 314 may be limited, and the diversification of controllable production images may be limited. .. On the other hand, in the pachinko machine 200, the effect image to be displayed on the third symbol display device 281 can be changed only by a simple operation of appropriately replacing the display data table and the additional data table used for generating the synthetic data table. Therefore, it is possible to display various types of effect images on the third symbol display device 281 regardless of the processing capacity of the display control device 314.

Further, in this way, a display data table is prepared corresponding to each effect mode, a composite data table is generated from the display data table according to the effect mode to be displayed, and the synthetic data table is according to the generated composite data table. The reason why the drawing list can be created frame by frame is that in the pachinko machine 200, the effect to be displayed on the third symbol display device 281 is determined in advance based on the result of the lottery performed based on the start winning prize. be. On the other hand, in game machines other than gaming machines such as the pachinko machine 200, the display contents change on the spot based on the user's operation, so that the display contents cannot be predicted. Therefore, as described above. It is not possible to have a display data table corresponding to each effect mode. In this way, a display data table is prepared corresponding to each effect mode, a composite data table is generated from the display data table according to the effect mode to be displayed, and this is set in the composite data table buffer 451d. The configuration in which the drawing list is created frame by frame according to the set synthetic data table is an effect mode in which the pachinko machine 200 displays in advance on the third symbol display device 281 based on the result of the lottery performed based on the start winning prize. It can be realized only based on the configuration that determines.

Further, a display data table area, an additional data table area, and a transfer data table area are provided for each address of the synthetic data table, and the time indicated by the display data table area and the additional data table area of each address indicates the time. The drawing content to be displayed is specified in, and the transfer data table area of each address defines the transfer data information of the transfer target image data to be transferred at the time indicated by that address. Before the image data of a predetermined sprite is used based on the area, the transfer start timing is specified and instructed based on the transfer data table area so that the image data is surely stored in the normal video RAM 436. Can be done. Therefore, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, a wide variety of effect images can be easily displayed on the third symbol display device 281.

In addition, since it is possible to specify the drawing content of the effect mode originally determined from one composite data table, the drawing content of the effect added later, and the transfer data information of the image data to be transferred, the display data. Compared with the case where the drawing content and the transfer data information are specified from the table, the additional data table, and the transfer data table, the processing load required for the identification can be reduced.

In addition, the pachinko machine 200 in the eighth embodiment can exert the same action and effect as the pachinko machine 200 in the seventh embodiment based on the same components as the pachinko machine 200 in the seventh embodiment.

Next, the pachinko machine 200 according to the ninth embodiment will be described with reference to FIGS. 97 to 104. In the pachinko machine 200 according to the seventh embodiment described above, the display data table describing the display contents (drawing contents) to be displayed on the third symbol display device 281 with the passage of time is used as a command from the voice lamp control device 313. Based on this, an additional data table is prepared for each effect mode displayed on the third symbol display device 281, and an additional data table describing display contents (drawing contents) to be added to the effect mode displayed in the display data table is provided. , Prepared for each production mode of the effect that can be added, and further, for each display data table, image data that is not resident in the resident video RAM 189 among the image data used for display (drawing) by the display data table. The case where the transfer data information for transferring from the character ROM 187 to the normal video RAM 190 and the transfer data table defining the transfer timing are prepared has been described.

On the other hand, in the pachinko machine 200 according to the ninth embodiment, the display data table prepared for each effect mode displayed on the third symbol display device 281 is displayed on the third symbol display device 281 with the passage of time. Not only the display content (drawing content) to be added, but also the display content (drawing content) to be added is specified for each effect that can be additionally displayed for the effect mode, and used for the display (drawing). It defines transfer data information for transferring image data that is not resident in the resident video RAM 435 from the character ROM 434 to the normal video RAM 436, and the transfer timing thereof.

Then, the display control device 314 is determined when the effect mode of the effect in the third symbol display device 281 determined according to the command (for example, the display variation pattern command) received from the voice lamp control device 313 is determined. By setting the display data table corresponding to the effect mode in the display data table buffer 452d, the image to be displayed on the third symbol display device 281 can be drawn according to the display data table set in the display data table buffer 452d. , The transfer of the image data used for the drawing from the character ROM 434 to the normal video RAM 436 is controlled. Further, when the effect to be additionally displayed on the third symbol display device 281 is determined according to a predetermined condition, the drawing of the image to be additionally displayed on the third symbol display device 281 is also controlled in response to the determined effect. ..

The difference in configuration between the pachinko machine 200 in the ninth embodiment and the pachinko machine 200 in the seventh embodiment is that the display control device 314 is provided with a work RAM 452 instead of the work RAM 433. Further, among the V interrupt processing (see FIG. 74 (a)) executed by the MPU 431 of the display control device 314, the demo command processing (S2509) and the variation pattern command processing (S2509), which are one of the command determination processing (S2402). S2511) and continuous notice command processing (S2515), comparison processing (S2710) which is one processing of display setting processing (S2403) and its display setting processing, and normal image transfer setting which is one processing of transfer setting processing (S2405). The partial treatment included in the treatment (S3003) is different from that of the pachinko machine 200 in the seventh embodiment. Other configurations, various processes executed by the MPU 401 of the main control device 310, various processes executed by the MPU 411 of the payout control device 311, various processes executed by the MPU 421 of the voice lamp control device 313, and the display control device 314. The other processing performed by the MPU 431 of the above is the same as that of the pachinko machine 200 in the seventh embodiment. Hereinafter, the same elements as those in the seventh embodiment are designated by the same reference numerals, and the illustration and description thereof will be omitted.

First, with reference to FIG. 97, the electrical configuration of the display control device 314 of the pachinko machine 200 according to the ninth embodiment will be described. FIG. 97 is a block diagram showing an electrical configuration of the display control device 314 according to the ninth embodiment. As described above, as shown in FIG. 97, the display control device 314 according to the present embodiment is provided with the work RAM 452 instead of the work RAM 433 in the display control device 314 according to the seventh embodiment. Since other configurations are the same as those of the display control device 314 in the seventh embodiment, the description thereof will be omitted.

The work RAM 452 is configured by a DRAM like the work RAM 433 in the seventh embodiment. The work RAM 452 has a program storage area 452a, a data table storage area 452b, a simple image display flag 452c, a display data table buffer 452d, a pointer 452g, a drawing list area 452h, a time counting counter 452i, a stored image discrimination flag 452j, and a drawing target. At least the buffer flag 452k is provided. Of these, the program storage area 452a, the simple image display flag 452c, the pointer 452g, the drawing list area 452h, the time counting counter 452i, the stored image discrimination flag 452j, and the drawing target buffer flag 452k are each the program storage area 433a in the seventh implementation mobile phone. , Simple image display flag 433c, pointer 433g, drawing list area 433h, time counting counter 433i, stored image discrimination flag 433j, drawing target buffer flag 433k, and so on. do.

The data table storage area 452b describes the display content (drawing content) to be displayed on the third symbol display device 281 with the passage of time, and is additionally displayed on the third symbol display device 281 according to the conditions. Transfer data for defining the content (drawing content) and further transferring the image data not resident in the resident video RAM 435 from the image data used for the display (drawing) from the character ROM 434 to the normal video RAM 436. Information and its transfer timing are specified, and a display data table prepared for each effect mode displayed on the third symbol display device 281 based on a command from the voice lamp control device 313 is stored. It is an area.

This display data table is stored in the NAND flash memory 434a of the character ROM 434 together with the control program as a kind of fixed value data, and these data tables are transferred from the character ROM 434 to the work RAM 192 after the system reset is released, and this data is obtained. It is stored in the table storage area 452b. Then, when all the display data tables are stored in the data table storage area 452b, the MPU 431 subsequently controls the display of the third symbol display device 281 using the data table stored in the data table storage area 452b. As described above, since the work RAM 192 is composed of the DRAM, the read operation is performed at high speed. Therefore, even when various data tables are stored in the character ROM 434 configured by the NAND flash memory 434a having a slow read speed, the display control device 314 can maintain high processing performance, and the third symbol display device 281 can be stored. Can be used to easily perform diversified and complicated productions.

Here, the details of the display data table in the ninth embodiment will be described with reference to FIG. 98. FIG. 98 is a schematic diagram schematically showing an example of this display data table. In the display data table in the ninth embodiment, as shown in FIG. 98, the time for displaying an image for one frame on the third symbol display device 281 (20 milliseconds in this embodiment) is represented as one unit. One frame of image content (drawing content) to be displayed at the time indicated by the address corresponding to the address, and sprite image data to start transfer at the time indicated by the address, that is, the transfer target. It is defined together with the transfer data information of the image data.

Similar to the display data table of the first embodiment, the drawing content defines the type of sprite for each sprite (rear image, effect, character, etc.) constituting the image for one frame, and also defines the type of the sprite. Drawing for drawing a display object on the third symbol display device 281 such as display position coordinates, enlargement ratio, rotation angle, semi-transparency value, α-blending information, color information, and filter designation information according to the type of the display object. Information is specified.

On the other hand, as the transfer data information, the start address (storage source start address) and the final address (storage source final address) of the character ROM 434 in which the transfer target image data is stored, as in the transfer data table of the seventh embodiment. , And the start address of the transfer destination (normal video RAM 436). Further, as the transfer data information in which the image data corresponding to the predetermined sprite is the image data to be transferred, the image data corresponding to the predetermined sprite is usually used by the time the drawing of the predetermined sprite is started according to the drawing content. It is specified for a predetermined address so that it is stored in the image storage area 436a of the video RAM 436.

If there is no transfer target image data to start transfer at the time indicated by the address, it means that there is no transfer target image data to start transfer corresponding to the address as the transfer data information. The Null data to be used is specified (corresponding to the address "097H" in FIG. 98). Further, when all the image data of the sprite used in the effect specified in the display data table is stored in the resident video RAM 435, Null data is specified as the transfer data information at all the addresses.

Further, in the display data table in the ninth embodiment, one frame of images to be additionally displayed at the time indicated by each address for each effect that can be additionally displayed with respect to the effect mode corresponding to the display data table. The content (drawing content) of is specified as an additional drawing content. This additional drawing content is indicated by the address in association with the identification information (“additional effect 1”, “additional effect 2”, etc.) for identifying the effect that can be additionally displayed for each address. The types of sprites (effects, characters, etc.) that make up the image to be additionally displayed at the time are specified, and the display position coordinates, magnification, rotation angle, etc. of the sprites are associated with each sprite type. Drawing information such as a semi-transparent value, α-blending information, color information, and filter designation information for causing the display object to be drawn on the third symbol display device 281 is defined (for example, the address "097H"). If there is no image for one frame to be additionally displayed at the time indicated by the address in each effect that can be additionally displayed, the effect that the image to be additionally displayed does not exist is identified for that address. Information and additional drawing contents of the effect are not described. As a result, it is possible to suppress an increase in the capacity of one display data table.

Similar to the display data table (see FIG. 57) in the seventh embodiment, "Start" information indicating the start of the data table is described in the "0000H" which is the start address of the display data table, and the final display data table is described. The address (“02F0H” in the example of FIG. 98) contains “End” information indicating the end of the data table. Then, for each address between the address "0000H" in which the "Start" information is described and the address in which the "End" information is described, the drawing content corresponding to the effect mode to be specified in the display data table is obtained. The transfer data information of the image data to be transferred and the additional drawing contents corresponding to the effects that can be additionally displayed are described.

When the MPU 431 determines an effect mode to be displayed on the third symbol display device 281 based on a command or the like received from the voice lamp control device 313, the MPU 431 extracts a display data table corresponding to the effect mode from the data table storage area 452b. Then, it is stored in the display data table buffer 452d and the pointer 452g is initialized.

Then, after adding 1 to 452 g each time the drawing process for one frame is completed, the display data table stored in the display data table buffer 452d is next drawn based on the drawing content defined by the address indicated by the pointer 452 g. A drawing list (see FIG. 60) is created by specifying the image content to be transferred and specifying the transfer data information of the transfer target image data to be transferred at that time. By transmitting this drawing list to the image controller 437, the MPU 431 gives an image controller 437 a drawing instruction for the image and an image data transfer instruction. Further, when the Null data is specified in the transfer data table area of the address indicated by the pointer 452g, it is determined that the transfer target image data to be transferred does not exist, and the transfer data information is not included in the drawing list. , The drawing list is transmitted to the image controller 437.

Further, when the MPU 431 determines an effect to be additionally displayed on the third symbol display device 281 in response to a command or the like from the voice lamp control device 313, a plurality of additional display-capable effects specified in the display data table are available. An additional drawing content corresponding to the determined effect is specified from among them, and a drawing list (see FIG. 60) is created together with the normal drawing content. By transmitting this drawing list to the image controller 437, the MPU 431 instructs the image controller 437 to draw an image of the effect to be additionally displayed together with the image corresponding to the original effect mode.

As described above, in the pachinko machine 200, in the display control device 314, the program to be executed by the MPU 431 is changed according to the command from the voice lamp control device 313 (for example, the display fluctuation pattern command or the continuous notice command). The effect image to be displayed on the third symbol display device 281 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 452d.

Here, when the program executed by the MPU 431 is activated every time the effect image displayed on the display control device 314 is changed like the conventional pachinko machine, it becomes complicated due to the diversification of the effect images. In addition, since a large load is applied to the processing of starting and executing an enormous amount of programs, the processing capacity of the display control device 314 may be limited, and the diversification of controllable production images may be limited. .. On the other hand, in the pachinko machine 200, the effect image to be displayed on the third symbol display device 281 can be changed by a simple operation of appropriately replacing the display data table with the display data table buffer 452d. Regardless of the processing capacity of the control device 314, various types of effect images can be displayed on the third symbol display device 281.

Further, in this way, a display data table is prepared corresponding to each effect mode, a display data table corresponding to the effect mode to be displayed is set in the display data table buffer 452d, and the set data table is followed. The reason why the drawing list can be created frame by frame is that in the pachinko machine 200, the effect to be displayed on the third symbol display device 281 is determined in advance based on the result of the lottery performed based on the start winning prize. Is. On the other hand, in game machines other than gaming machines such as the pachinko machine 200, the display contents change on the spot based on the user's operation, so that the display contents cannot be predicted. Therefore, as described above. It is not possible to have a display data table corresponding to each effect mode. In this way, a display data table is prepared corresponding to each effect mode, a display data table corresponding to the effect mode to be displayed is set in the display data table buffer 452d, and the display data table is set according to the set display data table. The configuration in which the drawing list is created frame by frame is such that the pachinko machine 200 determines in advance the production mode of the effect to be displayed on the third symbol display device 281 based on the result of the lottery performed based on the start winning prize. It can only be realized based on this.

Further, since the additional drawing contents corresponding to all the effects that can be additionally displayed are defined in the display data table, the MPU 431 is added to the effect mode to be displayed on the third symbol display device 281, and the like. In the case of displaying the effect of, it is possible to add another effect easily determined to the effect of the base and display it without resetting the display data table to the display data table buffer 452d.

Further, for example, when there are 32 types of original effect images and there are 5 types of other effect images to be additionally displayed, a display defining an image in which one additional effect image is superimposed for each original effect image. If a data table is prepared separately, 32 x (1 + 5) = 192 types of display data tables must be prepared, but like this pachinko machine 200, additional drawing corresponding to all the effects that can be additionally displayed. Since the contents are specified in the display data table, 32 types of display data tables may be prepared by separately specifying the data table corresponding to other production images as an additional data table, and the data table storage area. It is possible to suppress the capacity increase of 452b. Therefore, it is possible to store the data table corresponding to various aspects of the effect within the capacity prepared in the data table storage area 452b, and it is possible to easily further diversify the effect image.

Further, in the display data table, as described above in the seventh embodiment, the image data corresponding to the predetermined sprite is stored in the image storage area of the normal video RAM 436 by the time the drawing of the predetermined sprite is started according to the drawing content. Since the transfer data information of the image data to be transferred is specified for a predetermined address so as to be stored in the 436a, the image data is stored in the image storage area from the character ROM 434 according to the transfer data information specified in the display data table. By transferring to 436a, when drawing a predetermined sprite according to the display data table, the image data that is not resident in the resident video RAM 435 required for drawing the sprite is always stored in the image storage area 436a. Can be left. Then, using the image data stored in the image storage area 436a, a predetermined sprite can be drawn based on the display data table.

As a result, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, the image necessary for display can be read in advance from the character ROM 434 and transferred to the normal video RAM 436 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the third symbol display device 281. Further, by describing the display data table, only the non-resident image data in the resident video RAM 435 can be easily and surely transferred from the character ROM 434 to the normal video RAM 436.

Further, in the pachinko machine 200, in the display control device 314, not only the drawing contents but also the transfer data of the image data to be transferred are transferred to the display data table extracted from the data table area 452b in response to a command or the like from the voice lamp control device 313. Since the information and the transfer timing are specified, the transfer timing can be easily and accurately grasped and controlled. Therefore, the image data of the sprite used for drawing the image performed according to the display data table can be reliably transferred from the character ROM 434 to the normal video RAM 436 at a desired timing.

Further, since the display data table defines the transfer data information so that the image data is transferred from the character ROM 434 to the normal video RAM 436 for each image data corresponding to the sprite, the transfer of the image data is performed for each sprite. It can be managed and controlled, and the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 434 to the normal video RAM 436 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

Further, for each address in the display data table, the drawing content to be displayed at the time indicated by that address is defined, and the transfer data information of the image data to be transferred to be transferred is defined. Before the sprite image data is used, the transfer start timing can be specified and instructed based on the transfer data table area so that the image data is surely stored in the normal video RAM 436. Therefore, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, a wide variety of effect images can be easily displayed on the third symbol display device 281.

Further, since the drawing content, the transfer data information, and the additional drawing content can be specified from one display data table, the drawing content, the additional drawing content, and the transfer data information can be specified from the display data table, the additional data table, and the transfer data table, respectively. It is possible to reduce the processing load required for the specification as compared with the case of specifying the above. Further, since a display data table in which drawing contents, additional drawing contents, and transfer data information are defined is prepared in advance in the data table storage area 452b, a data table that defines drawing contents and data that defines additional drawing contents are prepared. A table and a data table that defines transfer data information are prepared, and each data table is synthesized each time, and processing is performed in comparison with the case where the drawing content and the transfer data information are specified from the combined data table. The load can be further reduced.

Returning to FIG. 97, the description of the work RAM 452 will be continued. The display data table buffer 452d is a buffer for storing a display data table corresponding to an effect mode to be displayed on the third symbol display device 281 in response to a command or the like from the voice lamp control device 313. The MPU 431 determines the effect to be displayed on the third symbol display device 281 based on a command or the like from the voice lamp control device 313, and selects a display data table corresponding to the effect mode of the effect from the data table storage area 452b. Then, the selected display data table is stored in the display data table buffer 452d. Then, the MPU 431 adds 1 to each of the pointers 452g to the drawing contents defined by the address indicated by the pointer 452g in the display data table stored in the display data table buffer 452d and the transfer data information of the image data to be transferred. Based on this, a drawing list (see FIG. 60) describing the content of the image drawing instruction to the image controller 437 and the transfer data information of the transfer target image data to be transferred at that time is created for each frame.

Further, when the MPU 431 determines an effect to be displayed in addition to the effect mode to be displayed on the third symbol display device 281 determined earlier, based on a command or the like from the voice lamp control device 313. Including the additional drawing contents corresponding to the determined additional drawing contents to be displayed among the additional drawing contents specified in the address indicated by the pointer 452g in the display data table stored in the display data table buffer 452d. Then, the above-mentioned drawing list (see FIG. 60) is created.

The work RAM 452 is also provided with an additional data flag. This additional data flag is provided corresponding to all the effects that can be added to the effect mode displayed on the third symbol display device 281. If there is an additional data flag in the ON state, the additional data flag is turned on. Indicates that the effect corresponding to the additional data flag of the state is set as an effect to be additionally displayed. This additional data flag is set to off as the initial value, and when a predetermined condition is met, the additional data flag corresponding to the additional display to be displayed determined according to the condition is set to on. The flag. Then, when the additional display of the effect is finished, all the additional data flags are set to off.

Next, various processes executed by the MPU 431 of the display control device 314 according to the ninth embodiment will be described with reference to FIGS. 99 to 105. First, FIG. 99 is a flowchart showing a demo command process (S2509) executed by the MPU 431 of the display control device 314. As described above in the ninth embodiment, the demo command process is a process executed in the command determination process (S2402), which is one process of the V interrupt process (see FIG. 74 (b)), and is a voice lamp. When a demo command is received from the control device 313, the process corresponding to the demo command is executed.

In this demo command processing, first, as in the demo command processing in the seventh embodiment, a demo display data table corresponding to the demo effect is selected from the data table storage area 433b and set in the display data table buffer 433d. (S2621), in the ninth embodiment, then, all the additional data flags provided in the work RAM 452 are set to off (S5622). As a result, in the demo effect displayed on the third symbol display device 281, another effect is not added and is not displayed.

After that, the same processing as S2623 to S2625 of the demo command processing in the seventh embodiment is executed. That is, the time data corresponding to the demo effect is set in the timekeeping counter 452i (S2623), and the pointer 452g is initialized to 0 (S2624). Then, the demo display flag indicating that the demo effect is displayed in the on state of the third symbol display device 281 is set to on, and the confirmed display effect is displayed on the third symbol display device 281 in the on state. The confirmation display flag shown is set to off, and the confirmation display flag indicating that the confirmation display effect is being performed in the on state is set to off (S2625), the demo command processing is terminated, and the process returns to the command determination processing.

By executing this demo command processing, in the display setting processing, the pointer is updated from the display data table set in the display data table buffer 452d by the processing of S2621 while updating the pointer 451g initialized by the processing of S2624. By extracting the drawing contents defined in the display data table area of the address shown in 452 g, the demo effect is displayed on the third symbol display device 281.

Next, with reference to FIG. 100, the variation pattern command processing executed by the MPU 431 of the display control device 314 will be described (S2511). FIG. 100 is a flowchart showing the fluctuation pattern command processing. As described above in the seventh embodiment, the variation pattern command process is a process executed in the command determination process (S2402), which is one process of the V interrupt process (see FIG. 74 (b)), and is a main process. When a display variation pattern command transmitted from the voice lamp control device 313 based on the variation pattern command from the control device 310 is received, the process corresponding to the display variation pattern command is executed.

In the variation pattern command processing, first, as in the variation pattern command processing in the seventh embodiment, a variation display data table corresponding to the variation effect pattern indicated by the display variation pattern command is determined, and the determined variation display is determined. The data table is read from the data table storage area 452b and set in the display data table buffer 452d (S2631). Then, in the ninth embodiment, all the additional data flags provided in the work RAM 452 are set to off (S56223). As a result, in the variable effect displayed on the third symbol display device 281, another effect is temporarily not added and is not displayed.

After that, the same processing as S2634 to S2638 of the variation pattern command processing in the seventh embodiment is executed. That is, among the data table discrimination flags provided for each fluctuation display data table corresponding to each fluctuation pattern, the data table discrimination flag corresponding to the fluctuation display data table determined by the processing of S2631 is turned on, and other The data table discrimination flag corresponding to the variable display data table of is set to off (S2634). In the display setting process, by referring to the data table discrimination flag set by the process of S2634, it is easy to determine which variation pattern the variation display data table set in the display data table buffer 452d corresponds to. Can be judged.

Then, in the display setting process, it is determined whether or not there is a contradiction between the fluctuation pattern of the variable display data table set in the display data table buffer 452d and the stop symbol set by the display stop type command received later. However, if there is a contradiction, the display data table corresponding to the special variation is set in the display data table buffer 452d as described later.

Next, based on the fluctuation time of the fluctuation pattern corresponding to the fluctuation display data table set in the display data table buffer 452d by the processing of S2631, time data representing the fluctuation time is set in the timekeeping counter 452i (S2635). Initialize the pointer 452g to 0 (S2636). Then, the confirmation command flag, the demo display flag, and the confirmation display flag are all set to off (S2637), and the restart timer counter used in the display setting process is initialized to 0 (S2638). Is terminated, and the process returns to the command judgment process.

By executing this variation pattern command process, in the display setting process, the pointer 452 g initialized by the process of S2636 is updated, and the variation display data table set in the display data table buffer 452d by the process of S2631 is executed. Extracts the drawing content specified at the address indicated by the pointer 452g, specifies the content of the image for one frame to be displayed next on the third symbol display device 281, and at the same time, the transfer data specified at that address. The image controller 437 is such that the image data of the sprite necessary for drawing the image specified in the variable display data table is transferred from the character ROM 434 to the image storage area 436a of the normal video RAM 436 in advance. To control. While the additional data flag is off, the additional drawing content is ignored. Therefore, another effect is not displayed without being added.

Further, in the display setting process, the time of the variation effect specified in the display data table is measured by using the time counting counter 452i in which the variation time data is set by the process of S2635, so that the variation effect in the display data table is completed. If it is determined that the confirmation command (display confirmation command) is received from the main control device 310, the confirmation display effect is displayed on the third symbol display device 281, and the confirmation command (display) is displayed within a predetermined time after the variation effect is completed. If the confirmation command) cannot be received, the display setting can be controlled so that the restart effect is displayed on the third symbol display device 281.

Next, with reference to FIG. 101, the continuous advance notice command processing executed by the MPU 431 of the display control device 314 will be described (S2515). FIG. 101 is a flowchart showing the continuous advance notice command processing. As described above in the seventh embodiment, the continuous notice command process is a process executed in the command determination process (S2402), which is one process of the V interrupt process (see FIG. 74 (b)), and is a voice. When a continuous warning command transmitted from the lamp control device 313 is received, the process corresponding to the continuous warning command is executed.

In the continuous notice command processing, the processing of S2651 and S2653 is the same as the processing of S2651 and S2653 of the continuous notice command processing in the seventh embodiment. Therefore, although detailed description of these processes will be omitted, in the continuous notice command processing in the eighth embodiment, first, a new continuous notification that the continuous notice command has been processed in the ON state is notified to the transfer setting process (S2405). When the notice command flag is set to on (S2651), then the continuous notice image type (one of "bubble", "tamago", "chick", "chicken", and "chicken group") indicated by the continuous notice command is set. The additional data flag corresponding to the effect indicated by the continuous preview image type is set to ON so that the corresponding effect is additionally displayed for the variable effect, and the additional data flag corresponding to the other effect is set. Is set to off (S5652).

As a result, if there is an additional data flag that is turned on in the display setting process, the additional drawing content of the effect indicated by the turned on additional data flag is expanded, and the additional drawing content is included in the drawing list. .. Therefore, since the image controller 437 draws an image based on the drawing list including the additional drawing content, the image of the effect indicated by the continuous notice type indicated by the turned on additional data flag is the third symbol display device. It is added to the variable effect and displayed in 281.

After that, among the continuous advance notice determination flags provided for each continuous advance notice image type, the continuous advance notice determination flag corresponding to the continuous advance notice image type included in the continuous advance notice command is turned on, and the continuous advance notice image types corresponding to other continuous advance notice image types are turned on. The advance notice determination flag is set to off (S2653), the continuous advance notice command processing is terminated, and the process returns to the command determination processing.

Next, the display setting process (S2403) executed by the MPU 431 of the display control device 314 will be described with reference to FIGS. 102 and 103. 102 and 103 are flowcharts showing the display setting process. As described above in the seventh embodiment, the display setting process is a process executed in the command determination process (S2402), which is one process of the V interrupt process (see FIG. 74 (b)), and is a command determination. Based on the contents of the display data table set in the display data table buffer 452d by processing (S2402) or the like, the contents of the image for one frame to be displayed next in the third symbol display device 281 are specifically specified. be. Further, in the display setting process, the pointer 452 g is also updated.

In the display setting process according to the ninth embodiment, the processes S5712 to S5714 are executed instead of the process S2712 of the display setting process according to the seventh embodiment. Further, instead of the processing of S2716 and S2731 of the display setting processing in the seventh embodiment, the processing of S5716 and S5731 is executed. Since the processing of the other steps of the display setting processing in the ninth embodiment is the same as the processing of the steps with the same reference numerals in the display setting processing in the seventh embodiment, detailed description thereof will be omitted here. Hereinafter, the processes of S5712 to S5714, S5716, and S5731, which are steps specific to the display setting process in the eighth embodiment, will be mainly described.

In this display setting process, the pointer update process is executed by the process of S2711, the pointer 452 g is updated, and then the display data table set in the display data table buffer 452d is updated by the pointer update process. Of the drawing contents of the address indicated by the pointer 452g, the drawing contents excluding the additional drawing contents are expanded (S5712). Next, it is determined whether or not the additional data flag corresponding to all the additional displayable effects is on (S5713), and if it is off (S5713: Yes), the process proceeds to S2713. If any one of the additional data flags is turned on as a result of the determination in S5713 (S5713: No), the pointer 452g updated by the pointer update process from the display data table set in the display data table buffer 452d. Of the drawing contents of the address indicated by, the additional drawing contents corresponding to the effect type indicated by the additional data flag are expanded (S5714), and the process proceeds to S2713.

In the task processing, the types of sprites (displays) that make up the image are specified based on the drawing contents expanded in the processing of S5712 together with the previously expanded pending image and warning image, and for each sprite. , Display coordinate position, enlargement ratio, rotation angle, and other parameters required for drawing are determined. When any one of the additional data flags is turned on, the sprite (display) constituting the image includes not only the drawing contents expanded by the processing of S5712 but also the additional drawing contents expanded by the processing of S5714. In addition to specifying the type of object), various parameters required for drawing such as display coordinate position, enlargement ratio, and rotation angle are determined for each sprite. Therefore, when any one of the additional data flags is turned on, the additional drawing content of the effect indicated by the turned on additional data flag is included in the drawing list, and the image controller 437 adds this. By drawing the image based on the drawing list including the drawing contents, the effect image indicated by the turned on additional data flag is added to and displayed on the third symbol display device 281.

In the subsequent processing of S2713, similarly to the seventh embodiment, the value of the timekeeping counter g is subtracted by 1, and it is determined whether or not the value of the timekeeping counter 452i after the subtraction is 0 or less (S2714), and the timekeeping is performed. When the value of the counter 452i is 0 or less (S2714: Yes), it means that the effect time corresponding to the display data table set in the display data table buffer 452d has elapsed. At this time, if the variable display data table is set in the display data table buffer 452d, a confirmation command (display confirmation command) is given from the main control device 310 via the voice lamp control device 314 at the end of the effect. ) Should be transmitted, so in the subsequent processing of S2715, it is confirmed whether or not the confirmation command flag is on (S2715).

As a result, if the confirmation command flag is on (S2715: Yes), it means that the confirmation command (display confirmation command) has been received from the main control device 310 via the voice lamp control device 314, and thus the confirmation display data. The table is set in the display data table buffer 452d and all additional data flags are set off (S5716). Then, the process proceeds to S2717.

As a result, when the display data table for variation is set in the display data table buffer 452d, a confirmation command (confirmation for display) is given from the main control device 310 via the voice lamp control device 313 at the end of the effect. When the command) is received, the drawing content can be set so that the final display effect of the stop symbol in the variation effect is displayed on the third symbol display device 281. Further, the effect displayed on the third symbol display device 281 can be easily changed to the definite display effect simply by changing the display data table buffer 452d to the definite display data table. Further, as compared with the case where the display content is changed by starting another program as in the conventional case, the program is not complicated and bloated, and therefore, a large load is not applied to the MPU 431. Regardless of the processing capacity of the display control device 314, various types of effect images can be displayed on the third symbol display 281. Further, since all the additional data flags are set to off, in the final display effect displayed on the third symbol display device 281, another effect is not added and is not displayed.

Further, in the processing of S2715, if the confirmation command flag is off instead of on (S2715: No), the process proceeds to the processing of S2722 shown in FIG. 94, and the confirmation display flag indicating that the confirmation display effect is being performed in the ON state. It is determined whether or not the confirmation display flag is on (S2722). Then, if the confirmation display flag is not on but off (S2722: No), then it is determined whether or not the demo display flag indicating that the demo is being produced in the on state is on (S2728). As a result, when the demo display flag is not on but off (S2728: No), the result of the determination in the processing of S2714 (S2714: Yes) means that the variation effect is completed. Therefore, if the confirmation command is not received even after a predetermined time has elapsed from the end of the variation effect, the variation display data table corresponding to the variation effect is set in the display data table buffer 452d in order to start the restart effect. 1 is added to the restart timer counter initialized to 0 (S2729), and it is determined whether or not the value of the restart timer counter after the addition has reached a predetermined value (S2730).

Then, when the restart timer counter is a predetermined value (S2730: Yes), the restart display data table is set in the display data table buffer 452d, and all the additional data flags are set to off (S5731). Then, the process proceeds to S2732.

As a result, in the display control device, even if a predetermined time elapses after the third symbol is stopped and displayed with the end of the variation effect, the confirmation command (confirmed command) transmitted from the main control device 310 via the voice lamp control device 313 ( When the display confirmation command) is not received, the drawing content can be set so that the restart effect is displayed on the third symbol display device 281. Then, as described above, the restart effect is an effect of displaying the image obtained by vibrating the third symbol on the third symbol display device 281. Therefore, the player can display the third symbol on the third symbol display device 281. By visually recognizing that the third symbol is vibrated and displayed after the change of is stopped and displayed, it can be recognized that the stopped symbol has not been determined at that time. Further, since all the additional data flags are set to off, in the restart effect displayed on the third symbol display device 281, another effect is not added and is not displayed.

In the process of S2724, when the demo display data table is set in the display data table buffer 452d, the additional data flag is not set to off, and the branch condition of S2722: Yes is confirmed. This is a case where the effect is being performed, and in this case, all the additional data flags are set to off by the processing of S5716. Therefore, in the process of S2724, the process of setting the additional data flag to off is omitted. As a result, the processing load on the MPU 431 can be reduced.

Next, the comparison process (S2710) executed by the MPU 431 of the display control device 314 will be described with reference to FIG. 104. FIG. 104 is a flowchart showing the comparison process. This process is executed when it is determined that the comparison flag is on in the above-mentioned display setting process (FIGS. 102 and 103) (S2709: Yes), and is based on the display variation pattern command. , When the variable display data table set in the display data table buffer 452d and the stop symbol set based on the display stop type command are inconsistent, the variable effect is produced via the voice lamp control device 313. This is a process for changing the third symbol to a special variation effect for displaying the third symbol at high speed until the confirmation command (display confirmation command) transmitted from the main control device 310 is received.

As described above in the seventh embodiment, the fluctuation display data table is prepared for each fluctuation pattern, and each fluctuation pattern includes, for off, for 15R fixed jackpot / time saving jackpot, and for 15R probability variation jackpot. For 2R probability change jackpot ... etc. Therefore, for example, when the stop symbol is set as the jackpot symbol even though the variation display data table corresponds to the deviation pattern, it is determined in the comparison process that these are inconsistent. ..

In the comparison process in the ninth embodiment, the process of S5784 is executed instead of the process of S2784 of the display setting process in the seventh embodiment. On the other hand, the processing of the other steps of the display setting processing in the ninth embodiment is the same as the processing of the step with the same reference numeral in the display setting processing in the seventh embodiment, and therefore the detailed description thereof is omitted here. do. Hereinafter, the process of S5784, which is a step peculiar to the display setting process in the ninth embodiment, will be mainly described.

In this comparison process, it is determined whether or not the type of the variable display data table specified by the process of S2781 matches the stop symbol specified by the process of S2782 (S2783), and it is determined that they do not match. In the case (S2783: No), the display data table for special variation in which the special variation is defined is set in the display data table buffer 452d, and all the additional data flags are set to off (S5784). Then, the process proceeds to S2785.

As a result, if the variation display data table set in the display data table buffer 452d based on the display variation pattern command and the stop symbol set based on the display stop type command are inconsistent, special variation is performed. Since the display data table for use is set in the display data table buffer 452d, the third symbol display device 281 displays a special variation effect in which the third symbol continues to fluctuate at high speed. Since the special stop symbol is set as the stop symbol by the process of S2785, when the confirmation command (display confirmation command) transmitted from the main control device 310 via the voice lamp control device 313 is received. , The special stop symbol can be confirmed and displayed on the third symbol display 281.

Here, when the variation effect pattern instructed by the main control device 310 via the voice lamp control device 313 and the stop symbol to be displayed at the time of stop display of the variation effect do not match, the display control device 314 uses the main control device. There is a possibility that it is not possible to correctly reflect the result of the lottery performed in 310 and perform a variable effect or a definite display effect. On the other hand, in the pachinko machine 200, in such a case, a special variation effect is performed, and after the variation display, a special stop symbol indicating a special deviation is confirmed and displayed on the third symbol display device 281. Even if the result of the lottery in 310 is wrong, it is possible to prevent the third symbol display device 281 from erroneously performing a definite display effect of the jackpot. Further, even if the special stop symbol is confirmed and displayed on the third symbol display device 281, if the lottery result in the main control device 310 is a big hit, the actual gaming state in the pachinko machine 200 shifts to the special gaming state. The person can continue the game with peace of mind. Further, by setting the confirmation display to a special stop symbol, it is possible to suggest to the player that the pachinko machine 200 may be in a big hit state even if the confirmation display is off. Even though the confirmation display is off, the pachinko machine 200 is in a big hit state, so that the player does not feel uneasy.

Further, since all the additional data flags are set to off, in the special variation effect displayed on the third symbol display device 281, another effect is not added and is not displayed. In particular, in the special variation effect, the stop symbol may be a special stop symbol, and it is not appropriate to additionally display a continuous notice effect image in order to emphasize the peculiarity of the variation effect. On the other hand, in the present embodiment, all the additional data flags are set to off, so at least even if the addition of the continuous advance notice effect is set at this point, the setting can be cleared and the setting is set. It is possible to prevent the continuous notice effect from being additionally displayed.

In the continuous advance notice command processing, the type of the display data table set in the display data table buffer 452d is determined, and if it is a display data table for special variation, all the additional data flags are set instead of the processing of S5652. You may set it to off. As a result, even if the continuous notice command processing is executed after the display data table for special variation is set in the display data table buffer 452d, all the additional data flags are set to off, so that the special variation effect can be achieved. On the other hand, it is possible to prevent the continuous notice effect from being additionally displayed.

Next, the normal image transfer setting process (S3003) executed by the MPU 431 of the display control device 314 will be described with reference to FIG. 105. FIG. 105 is a flowchart showing the normal image transfer setting process. As described above in the seventh embodiment, the normal image transfer setting process is a process executed in the transfer setting process (S2405), which is one of the V interrupt processes (see FIG. 74 (b)). While the simple image display flag 452c is off, predetermined image data is normally used from the character ROM 434 to the image controller 437 based on the transfer data information described in the display data table set in the display data table buffer 452d. A transfer instruction for transferring to a predetermined sub-area of the image storage area 436a of the video RAM 436 is set.

In this normal image transfer setting process, first, from the display data table set in the display data table buffer 452d, the address indicated by the pointer 452g updated by the display setting process (S2403, see FIG. 102) executed earlier. Acquires the transfer data information described in (S6201). Then, it is determined whether or not the acquired transfer data information is Null data (S6202), and if it is not Null data (S6202: No), the character in which the transfer target image data is stored is stored from the transfer data information. The start address (storage source start address) and final address (storage source final address) of ROM 434 and the start address of the transfer destination (normal video RAM 436) are extracted and stored in the transfer data buffer provided in the work RAM 452. (S3203) Further, the transfer start flag provided in the work RAM 185 and indicating that there is image data to be transferred in the ON state is set to ON (S3204), and the process proceeds to S3205.

Further, in the process of S6202, if the acquired transfer data information is Null data (S6202: Yes), the processes of S3203 and S3204 are skipped, and the process proceeds to the process of S3205. Then, in the processing of S3205 to S3218, the same processing as the processing of S3205 to S3218 of the normal image transfer setting processing in the seventh embodiment is performed. Therefore, detailed description of these processes will be omitted.

As described above, in the display control device 314, by executing the normal image transfer setting process, the transfer data information described in the address indicated by the pointer 452g of the display data table set in the display data table buffer 452d is followed. Since the transfer instruction of the transfer target image is set to the image controller 437, the image data of the sprite specified by the display data table buffer 452d can be reliably transferred from the character ROM 434 to the normal video RAM 436 at a desired timing. ..

Here, in the display data table, the image data to be transferred is stored in the image storage area 436a so that the image data corresponding to the predetermined sprite is stored in the image storage area 436a by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information is specified for a predetermined address, by transferring the image data from the character ROM 434 to the image storage area 436a according to the transfer data information specified in the display data table, the transfer data information is specified according to the display data table. When drawing the sprite, the image data that is not resident in the resident video RAM 435 required for drawing the sprite can be stored in the image storage area 436a without fail. Then, using the image data stored in the image storage area 436a, a predetermined sprite can be drawn based on the display data table.

As a result, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, the image necessary for display can be read in advance from the character ROM 434 and transferred to the normal video RAM 436 without delay. While drawing the image of each sprite specified in the data table, the corresponding effect can be displayed on the third symbol display device 281. Further, by describing the display data table, only the non-resident image data in the resident video RAM 435 can be easily and surely transferred from the character ROM 434 to the normal video RAM 436.

Further, in the pachinko machine 200, in the display control device 314, only the drawing contents are displayed in the display data table extracted from the data table area 452b in response to a command from the voice lamp control device 313 (for example, a display variation pattern command). Since the transfer data information and the transfer timing of the image data to be transferred are specified instead, the transfer timing can be easily and accurately grasped and controlled. Therefore, the image data of the sprite used for drawing the image performed according to the display data table can be reliably transferred from the character ROM 434 to the normal video RAM 436 at a desired timing.

Further, in the display data table, the transfer data information is defined so that the image data is transferred from the character ROM 434 to the normal video RAM 436 for each image data corresponding to the sprite. Therefore, in the transfer data table area of the composite data table. Also, the transfer data information is defined so that the image data is transferred from the character ROM 434 to the normal video RAM 436 for each image data corresponding to the sprite. As a result, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. Then, by controlling the transfer of the image data from the character ROM 434 to the normal video RAM 436 in sprite units, it is possible to control the transfer of the image data in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in the load applied to the transfer.

Further, for each address in the display data table, the drawing content to be displayed at the time indicated by that address is defined, and the transfer data information of the image data to be transferred to be transferred is defined. Before the sprite image data is used, the transfer start timing can be specified and instructed based on the transfer data table area so that the image data is surely stored in the normal video RAM 436. Therefore, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, a wide variety of effect images can be easily displayed on the third symbol display device 281.

Further, since the drawing content and the transfer data information can be specified from one display data table, the specification can be compared with the case where the drawing content and the transfer data information are specified from the display data table and the transfer data table, respectively. The processing load required for this can be reduced. Further, since a display data table in which drawing contents and transfer data information are defined is prepared in advance in the data table storage area 452b, a data table that defines drawing contents, a data table that defines additional drawing contents, and transfer A data table that defines the data information is prepared, and each data table is synthesized each time, and the processing load is further increased compared to the case where the drawing content and the transferred data information are specified from the synthesized data table. Can be lightened.

As described above, according to the pachinko machine 200 of the ninth embodiment, in the display data table prepared for each effect mode of the effect displayed on the third symbol display device 281, the third pattern is displayed over time. Not only the display content (drawing content) to be displayed on the symbol display device 281 but also the image data used for the display (drawing) that is not resident in the resident video RAM 435 is displayed from the character ROM 434 to the normal video RAM 436. The transfer data information to be transferred to and the transfer timing thereof are specified. Further, the display data table defines additional drawing contents corresponding to the effects that can be additionally displayed with respect to the effect mode of the effects displayed on the third symbol display device 281 by the display data table.

When the display control device 314 determines the effect mode to be displayed on the third symbol display device 281 based on the command or the like received from the voice lamp control device 313, the display data table corresponding to the effect mode is stored in the data table storage area. It is extracted from 452b, stored in the display data table buffer 452d, and the pointer 452g is initialized. Then, after adding 1 to 452 g each time the drawing process for one frame is completed, the display data table stored in the display data table buffer 452d is next drawn based on the drawing content defined by the address indicated by the pointer 452 g. A drawing list (see FIG. 60) is created by specifying the image content to be transferred and specifying the transfer data information of the transfer target image data to be transferred at that time. By transmitting this drawing list to the image controller 437, the MPU 431 gives an image controller 437 a drawing instruction for the image and an image data transfer instruction. Further, when the Null data is specified in the transfer data table area of the address indicated by the pointer 452g, it is determined that the transfer target image data to be transferred does not exist, and the transfer data information is not included in the drawing list. , The drawing list is transmitted to the image controller 437.

Further, when the display control device 314 determines the effect to be additionally displayed in the third symbol display device 281 in response to a command or the like from the voice lamp control device 313, a plurality of additional displays specified in the display data table can be performed. An additional drawing content corresponding to the determined effect is specified from among the various effects, and a drawing list (see FIG. 60) is created together with the normal drawing content. By transmitting this drawing list to the image controller 437, the MPU 431 instructs the image controller 437 to draw an image of the effect to be additionally displayed together with the image corresponding to the original effect mode.

As described above, in the pachinko machine 200, in the display control device 314, the program to be executed by the MPU 431 is changed according to the command from the voice lamp control device 313 (for example, the display fluctuation pattern command or the continuous notice command). The effect image to be displayed on the third symbol display device 281 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 452d.

Here, when the program executed by the MPU 431 is activated every time the effect image displayed on the display control device 314 is changed like the conventional pachinko machine, it becomes complicated due to the diversification of the effect images. In addition, since a large load is applied to the processing of starting and executing an enormous amount of programs, the processing capacity of the display control device 314 may be limited, and the diversification of controllable production images may be limited. .. On the other hand, in the pachinko machine 200, the effect image to be displayed on the third symbol display device 281 can be changed by a simple operation of appropriately replacing the display data table with the display data table buffer 452d. Regardless of the processing capacity of the control device 314, various types of effect images can be displayed on the third symbol display device 281.

Further, in this way, a display data table is prepared corresponding to each effect mode, a display data table corresponding to the effect mode to be displayed is set in the display data table buffer 452d, and the set data table is followed. The reason why the drawing list can be created frame by frame is that in the pachinko machine 200, the effect to be displayed on the third symbol display device 281 is determined in advance based on the result of the lottery performed based on the start winning prize. Is. On the other hand, in game machines other than gaming machines such as the pachinko machine 200, the display contents change on the spot based on the user's operation, so that the display contents cannot be predicted. Therefore, as described above. It is not possible to have a display data table corresponding to each effect mode. In this way, a display data table is prepared corresponding to each effect mode, a display data table corresponding to the effect mode to be displayed is set in the display data table buffer 452d, and the display data table is set according to the set display data table. The configuration in which the drawing list is created frame by frame is such that the pachinko machine 200 determines in advance the production mode of the effect to be displayed on the third symbol display device 281 based on the result of the lottery performed based on the start winning prize. It can only be realized based on this.

Further, for each address in the display data table, the drawing content to be displayed at the time indicated by that address is defined, and the transfer data information of the image data to be transferred to be transferred is defined. Before the sprite image data is used, the transfer start timing can be specified and instructed based on the transfer data table area so that the image data is surely stored in the normal video RAM 436. Therefore, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, a wide variety of effect images can be easily displayed on the third symbol display device 281.

Further, since the drawing content, the transfer data information, and the additional drawing content can be specified from one display data table, the drawing content, the additional drawing content, and the transfer data information can be specified from the display data table, the additional data table, and the transfer data table, respectively. It is possible to reduce the processing load required for the specification as compared with the case of specifying the above. Further, since a display data table in which drawing contents, additional drawing contents, and transfer data information are defined is prepared in advance in the data table storage area 452b, a data table that defines drawing contents and data that defines additional drawing contents are prepared. A table and a data table that defines transfer data information are prepared, and each data table is synthesized each time, and processing is performed in comparison with the case where the drawing content and the transfer data information are specified from the combined data table. The load can be further reduced.

Next, the pachinko machine 200 according to the tenth embodiment will be described with reference to FIG. 106. In the pachinko machine 200 according to the seventh embodiment described above, the NOR type ROM 434d is provided in the character ROM 434 configured by the NAND flash memory 434a, and most of the control program and fixed value data are stored in the NAND flash memory 434a. In addition, the NOR type ROM 434d stores a part of the boot program that is first executed after the system reset is released in the MPU 431 among the control programs, and the system reset is released and the MPU 431 is sent to the bus line 440 at the address "0000H". Is specified, the case where the ROM controller 434b of the character ROM 434 sets a part of the boot program stored in the NOR type ROM 434d in the buffer RAM 434c and then outputs the instruction code of the specified address to the MPU 431 has been described.

On the other hand, in the pachinko machine 200 according to the tenth embodiment, the character ROM 534 is provided in the display control device 314 instead of the character ROM 434 according to the seventh embodiment described above. Then, all the control programs including the boot program and all the fixed value data are stored in the NAND flash memory 534a provided in the character ROM 534, and when the power is turned on from the power supply device 315, the character ROM 534 is provided. The ROM controller 534b has set a part of the boot program stored in the NAND flash memory 534a in advance in the buffer RAM 534c, the system reset is released, and the address "0000H" is sent from the MPU 431 via the bus line 440. When specified, the instruction code of the specified address is read from the buffer RAM 534c and output to the MPU 431 via the bus line 440.

Other configurations of the display control device 314, other configurations of the pachinko machine 200, various processes executed by the MPU 401 of the main control device 310 (see FIGS. 61 to 67), and execution by the MPU 421 of the voice lamp control device 313. The various processes performed (see FIGS. 68 to 72) and the various processes executed by the MPU 431 of the display control device 314 (see FIGS. 73 to 87) are the same as those of the pachinko machine 200 in the seventh embodiment. Hereinafter, the same elements as those in the seventh embodiment are designated by the same reference numerals, and the illustration and description thereof will be omitted.

As shown in FIG. 106, the character ROM 534 has a NAND flash memory 534a, a ROM controller 534b, and a buffer RAM 534c, and is connected to the bus line 440 like the character ROM 434 of the seventh embodiment. Of these, the buffer RAM 534c has the same configuration and function as the buffer RAM 434c of the character ROM 434 in the seventh embodiment, and thus the description thereof will be omitted.

The NAND flash memory 534a is a non-volatile memory provided as a storage unit in the character ROM 534. Similar to the NAND flash memory 434a in the seventh embodiment, the NAND flash memory 534a has at least a character storage area 534a2 for storing image (character or the like) data to be displayed on the third symbol display device 281. ing. Then, as in the seventh embodiment, the image controller 437 accesses the character ROM 534 according to the transfer instruction from the MPU 431 or the transfer data information included in the drawing list, and the image data stored in the character storage area 534a2 of the character ROM 534. Of these, when the predetermined image data is transferred to the resident video RAM 435 during the initialization process and is resident, or when the image data that is not resident in the resident video RAM 435 is used, it is usually performed in advance before the image data is used. Transfer to the video RAM 436 for storage.

Here, the NAND flash memory has a feature that a large storage capacity can be obtained in a small area. For example, by using the NAND flash memory 534a having a capacity of 2 gigabytes, the NAND flash memory is displayed on the third symbol display device 281. Many images can be stored in the character storage area 534a2 as the images to be stored. Therefore, in order to further enhance the interest of the player, the image displayed on the third symbol display device 281 can be diversified and complicated. On the other hand, since the image data used for the drawing process is resident in the resident video RAM 435 and stored in the normal video RAM 436 in advance, the character ROM 534 is composed of the NAND flash memory 534a having a slow read speed at the time of image drawing. It is not necessary to read the corresponding image data from, and the time required for the reading can be omitted. Therefore, the image can be drawn immediately and the drawn image can be displayed on the third symbol display device 281.

Further, the character ROM 534 is provided with a program storage area 534a in the NAND flash memory 534a instead of the second program storage area 434a1 provided in the NAND flash memory 434a of the seventh embodiment. The program storage area 534a stores all the control programs executed by the MPU 431 and the fixed value data used in the control programs. That is, in the seventh embodiment, among the control programs, a part of the boot program that is first executed after the system reset is released in the MPU 431 is stored in the NOR type ROM 434d, and the other control programs and the fixed value data are stored in the NAND flash memory. Although it is stored in the 434a, in the tenth embodiment, all the control programs and the fixed value data are stored in the NAND flash memory 534a. Since the content of the control program and the content of the fixed value data are the same as those in the seventh embodiment, the description thereof will be omitted.

Here, since the NAND flash memory 534a can easily increase the capacity in a small area as described above, all the controls are further controlled while a large amount of image data is stored in the character storage area 534a2. The program and fixed value data can be stored in the program storage area 534a1. In this way, the control program and the fixed value data are displayed on the third symbol display device 281 without storing the control program and the fixed value data by providing a dedicated program ROM (for example, ROM 22 of Patent Document 1 described above) as in the conventional gaming machine. Since the character ROM 534 provided for storing the image data to be stored can be stored, the number of parts in the display control device 314 can be reduced and the manufacturing cost can be reduced as in the seventh embodiment. , It is possible to suppress an increase in the failure rate due to an increase in the number of parts.

Further, since the character ROM 534 in the tenth embodiment does not require the NOR type ROM 434a1 as compared with the character ROM 434 in the seventh embodiment, the cost of the character ROM 534 itself can be reduced by omitting the NOR type ROM 434a1. In addition, the reliability of the character ROM 534 itself can be improved by reducing the number of parts.

The ROM controller 534b is a controller for controlling the operation of the character ROM 534, similarly to the ROM controller 434b of the character ROM 434 in the seventh embodiment, and is transmitted from, for example, the MPU 431 or the image controller 437 via the bus line 440. Based on the address, the corresponding data is read from the NAND flash memory 534a and output to the MPU 431 or the image controller 437 via the bus line 440. At this time, the ROM controller 534b is known to perform known error correction on the data read from the NAND flash memory 534a, and to read and write data to and from the NAND flash memory 534a while avoiding defective data blocks. Data address conversion (see, for example, Patent Document 1) is performed.

As a result, even if the NAND flash memory 534a, in which error bits are likely to occur frequently, is used as the character ROM 534, the MPU 431 performs processing based on erroneous data, and the image controller 437 generates various images. Can be suppressed. Further, since the defective data block of the NAND flash memory 534a is analyzed by the ROM controller 534b and access to the defective data block is avoided, the MPU 431 and the image controller 437 have different defective data in each NAND flash memory 534a. Access to the character ROM 534 can be easily performed without considering the address position of the block. Therefore, even if the NAND flash memory 534a is used for the character ROM 534, it is possible to suppress the complicated access control to the character ROM 534.

Here, when the ROM controller 434b of the character ROM 434 in the seventh embodiment detects that the MPU 431 has specified the address "0000H" for the bus line 440 after the system reset is released, it is one of the boot programs stored in the NOR type ROM 434d. The unit was set in the buffer RAM 4434c, and the instruction code of the specified address was output to the MPU 431. On the other hand, the ROM controller 534b of the character ROM 534 in the tenth embodiment releases the system reset in the MPU 431 from the program storage area 534a of the NAND flash memory 534a when the power is supplied from the power supply device 315 to the display control device 314. A part of the boot program executed first is read, and a part of the read boot program is set in the buffer RAM 534c.

That is, the ROM controller 534b is configured so that the start address of the boot program stored in the program storage area 534a is automatically set by the hardware immediately after the power is turned on, and one page including the start address. The NAND flash memory 534a is driven so as to read the minute data (instruction code). Then, by writing the data (instruction code) read from the NAND flash memory 534a to one bank of the buffer RAM 534c, a part of the boot program first executed after the system reset is released in the MPU 431 is set in the buffer RAM 534c.

After a part of the boot program is set in the buffer RAM 534c, when the ROM controller 534b detects that the address "0000H" is specified for the bus line 440 by the MPU 431 due to the release of the system reset, the corresponding address is sent from the buffer RAM 534c. Is configured to output the instruction code of MPU431. The MPU 431 fetches the instruction code received from the character ROM 534 and starts the execution of the process according to the fetched instruction to activate the main process shown in FIG. 73 and start the process. Then, as shown in FIG. 73, the main process first executes the boot process (S2201). The boot process executed here is the same as the boot process shown in FIG.

As described above, in the pachinko machine 200 according to the tenth embodiment, when the power is turned on from the power supply device 315, the ROM controller 534b in the character ROM 534 first automatically releases the system reset from the NAND flash memory 534a to the MPU 431. Since a part of the boot program to be executed first is read later and a part of the read boot program is set in the buffer RAM 534c, the NAND type is used at the stage where the address "0000H" is specified to the bus line 440 by the MPU 431. A part of the boot program is read from the flash memory 534a, or a part of the boot program is already set in the buffer RAM 534c.

Therefore, if a part of the boot program is already set in the buffer RAM 534c at the stage when the MPU 431 specifies the address "0000H" to the bus line 440 when the system reset is released, the character ROM 534 is the data (instruction) of the specified address. The code) can be read immediately from the buffer RAM 534c. Further, even if a part of the boot program is not set in the buffer RAM 101c at the stage when the MPU 431 specifies the address "0000H" to the bus line 440, a part of the boot program is already from the NAND flash memory 534a. Since the read process has started, the MPU 431 starts reading a part of the boot program from the NAND flash memory 534a in response to the designation of the address "0000H" in the bus line 440. After designating the address "0000H" in the bus line 440, the character ROM 534 sets a part of the boot program in the buffer RAM 534c, and outputs the data (instruction code) of the specified address from the buffer RAM 534c to the MPU 431. It is possible to shorten the time until.

Therefore, since the MPU 431 can receive the instruction code corresponding to the address "0000H" in a short time after designating the address "0000H", the MPU 431 can start the main process in a short time. As a result, even if the control program is stored in the character ROM 514 configured by the NAND flash memory 514a having a slow read speed, the control of the third symbol display device 281 in the display control device 314 can be started immediately.

In addition, the pachinko machine 200 in the tenth embodiment can exhibit the same effects as the pachinko machine 200 in the seventh embodiment based on the same components as the pachinko machine 200 in the seventh embodiment.

Next, the pachinko machine 200 according to the eleventh embodiment will be described with reference to FIG. 107. In the pachinko machine 200 according to the eleventh embodiment, the character ROM 634 is provided in the display control device 314 instead of the character ROM 434 according to the seventh embodiment described above. In this character ROM 196, a first program storage area 196d is provided in the ROM controller 196b, and a part of the boot program first executed after the system reset is released in the MPU 181 of the control programs is provided in the first program storage area 196d. It is remembered. Then, when the system reset is released and the MPU181 specifies the address "0000H" for the internal bus, the ROM controller 196b of the character ROM 196 sets a part of the boot program stored in the first program storage area 196d in the buffer RAM 196c. Above, the instruction code of the specified address is read from the buffer RAM 196c and output to the MPU 181 via the internal bus.

Other configurations of the display control device 314, other configurations of the pachinko machine 200, various processes executed by the MPU 401 of the main control device 310 (see FIGS. 61 to 67), and execution by the MPU 421 of the voice lamp control device 313. The various processes performed (see FIGS. 68 to 72) and the various processes executed by the MPU 431 of the display control device 314 (see FIGS. 73 to 87) are the same as those of the pachinko machine 200 in the seventh embodiment. Hereinafter, the same elements as those in the seventh embodiment are designated by the same reference numerals, and the illustration and description thereof will be omitted.

As shown in FIG. 107, the character ROM 634 has a NAND flash memory 634a, a ROM controller 634b, and a buffer RAM 634c, and is connected to the bus line 440 like the character ROM 434 of the seventh embodiment.

Of these, the NAND type flash memory 634a, the second program storage area 634a1 and the character storage area 634a2 provided in the NAND type flash memory 634a, and the buffer RAM 634c are the NAND type flash memory 434a of the character ROM 434 in the seventh embodiment, respectively. It has the same configuration and function as the second program storage area 434a1, the character storage area 434a2, and the buffer RAM 434c provided in the NAND flash memory 434a. The data stored in the second program storage area 634a1 and the character storage area 634a2 are the same as those in the second program storage area 434a1 and the character storage area 434a2. Therefore, these explanations will be omitted below.

The ROM controller 634b is a controller for controlling the operation of the character ROM 634, like the ROM controller 434b of the character ROM 434 in the seventh embodiment, and is transmitted from, for example, the MPU 431 or the image controller 437 via the bus line 440. Based on the address, the corresponding data is read from the NAND flash memory 634a and output to the MPU 431 or the image controller 437 via the bus line 440. At this time, the ROM controller 634b is known to perform known error correction on the data read from the NAND flash memory 634a and to read / write data to / from the NAND flash memory 634a while avoiding defective data blocks. Data address conversion (see, for example, Patent Document 1) is performed.

As a result, even if the NAND flash memory 634a, in which error bits are likely to occur frequently, is used as the character ROM 634, the MPU 431 performs processing based on erroneous data, and the image controller 437 generates various images. Can be suppressed. Further, since the defective data block of the NAND flash memory 634a is analyzed by the ROM controller 634b and access to the defective data block is avoided, the MPU 431 and the image controller 437 have different defective data in each NAND flash memory 634a. Access to the character ROM 634 can be easily performed without considering the address position of the block. Therefore, even if the NAND flash memory 634a is used for the character ROM 634, it is possible to suppress the complicated access control to the character ROM 634.

On the other hand, the ROM controller 634b in the eleventh embodiment is different from the ROM controller 434b of the character ROM 434 in the seventh embodiment in that it has the first program storage area 634d. The first program storage area 634d is composed of a small-capacity ROM built in the ROM controller 634b, and is a program stored in the first program storage area 434d1 of the NOR type ROM 434d in the character ROM 434 according to the seventh embodiment. That is, a part of the boot program first executed after the system reset is released in the MPU 431 is stored in the first program storage area 634d in the eleventh embodiment.

Then, when the ROM controller 634b detects that the MPU 431 has specified the address "0000H" for the bus line 440 after the system reset is released, a part of the boot program stored in the first program storage area 634d is stored in one of the buffer RAM 634c. The instruction code of the specified address is output to the MPU 431 by setting it in the bank of. The MPU 431 fetches the instruction code received from the character ROM 634 and starts the execution of the process according to the fetched instruction to activate the main process shown in FIG. 73 and start the process. Then, as shown in FIG. 73, the main process first executes the boot process (S2201). The boot process executed here is the same as the boot process shown in FIG.

Here, since the built-in ROM can generally shorten the connection wiring, the parasitic capacitance applied to the wiring can be reduced. As a result, the wiring delay that occurs in the propagation of the signal can be reduced, so that the data read time can be shortened. In addition, the built-in ROM can be freely designed for its data bus width according to individual hardware specifications, so if the data bus width is set wide, it is possible to read a large amount of data at once. Is.

Therefore, if the first program storage area 634d is configured with such a built-in ROM, a part of the boot program that is first executed after the system reset is released in the MPU 431 is read out from the first program storage area 634d at high speed. It is set in the buffer RAM 634c, and the data (instruction code) corresponding to the address specified in the bus line 440 can be output to the MPU 431 from the set program. Therefore, since the MPU 431 can receive the instruction code corresponding to the address "0000H" in a short time after designating the address "0000H", the MPU 431 can start the main process in a short time. As a result, even if the control program is stored in the character ROM 434 configured by the NAND flash memory 434a having a slow read speed, the control of the third symbol display device 281 in the display control device 314 can be started immediately.

In addition, the pachinko machine 200 in the eleventh embodiment can exhibit the same effects as the pachinko machine 200 in the seventh embodiment based on the same components as the pachinko machine 200 in the seventh embodiment.

Next, the pachinko machine 200 according to the twelfth embodiment will be described with reference to FIG. 108. In the pachinko machine 200 of the twelfth embodiment, the character ROM 734 is provided in the display control device 314 instead of the character ROM 434 of the seventh embodiment described above, and the NOR type ROM 735 is connected to the bus line 440 in the display control device 314. Has been done. The NOR type ROM 735 is provided with at least a first program storage area 735a, and the first program storage area 735a stores a part of the boot program that is first executed after the system reset is released in the MPU 431 among the control programs. There is. Then, when the MPU 431 specifies an address (for example, "0000H" to "0400H") corresponding to a part of the boot program to be executed first after the system reset is released to the internal bus, the NOR type ROM 735 corresponds to the address. The data (instruction code) is read from the first program storage area 735a and output to the MPU 431.

Other configurations of the display control device 314, other configurations of the pachinko machine 200, various processes executed by the MPU 401 of the main control device 310 (see FIGS. 61 to 67), and execution by the MPU 421 of the voice lamp control device 313. The various processes performed (see FIGS. 68 to 72) and the various processes executed by the MPU 431 of the display control device 314 (see FIGS. 73 to 87) are the same as those of the pachinko machine 200 in the seventh embodiment. Hereinafter, the same elements as those in the seventh embodiment are designated by the same reference numerals, and the illustration and description thereof will be omitted.

As shown in FIG. 108, the character ROM 734 has a NAND flash memory 734a, a ROM controller 734b, and a buffer RAM 734c, and is connected to the bus line 440 like the character ROM 434 of the seventh embodiment.

Of these, the NAND type flash memory 734a, the second program storage area 734a1 and the character storage area 734a2 provided in the NAND type flash memory 734a, and the buffer RAM 734c are the NAND type flash memory 434a of the character ROM 434 in the seventh embodiment, respectively. It has the same configuration and function as the second program storage area 434a1, the character storage area 434a2, and the buffer RAM 434c provided in the NAND flash memory 434a. The data stored in the second program storage area 734a1 and the character storage area 734a2 are the same as those in the second program storage area 434a1 and the character storage area 434a2. Therefore, these explanations will be omitted below.

The ROM controller 734b is a controller for controlling the operation of the character ROM 734, similarly to the ROM controller 434b of the character ROM 434 in the seventh embodiment, and is transmitted from, for example, the MPU 431 or the image controller 437 via the bus line 440. Based on the address, the corresponding data is read from the NAND flash memory 734a and output to the MPU 431 or the image controller 437 via the bus line 440. At this time, the ROM controller 734b is known to perform known error correction on the data read from the NAND flash memory 734a and to read / write data to / from the NAND flash memory 734a while avoiding defective data blocks. Data address conversion (see, for example, Patent Document 1) is performed.

As a result, even if the NAND flash memory 734a, in which error bits are likely to occur frequently, is used as the character ROM 734, the MPU 431 performs processing based on erroneous data, and the image controller 437 generates various images. Can be suppressed. Further, since the defective data block of the NAND flash memory 734a is analyzed by the ROM controller 734b and access to the defective data block is avoided, the MPU 431 and the image controller 437 have different defective data in each NAND flash memory 734a. Access to the character ROM 734 can be easily performed without considering the address position of the block. Therefore, even if the NAND flash memory 734a is used for the character ROM 734, it is possible to suppress the complicated access control to the character ROM 734.

On the other hand, when the ROM controller 434b in the seventh embodiment detects that the address "0000H" is specified for the bus line 440, a part of the boot program first executed after the system reset is released in the MPU 431 is partly executed from the NOR type ROM 434d. It was configured to be read out and set in the buffer RAM 434c, but in the ROM controller 734b in the twelfth embodiment, even if it is detected that the address "0000H" is specified for the bus line 440, such an operation is performed. It differs from the ROM controller 434b in the seventh embodiment in that it is not executed.

Further, when the address of the bus line 440 is specified as the address corresponding to a part of the control program stored in the NOR type ROM 735 described later, that is, the boot program first executed after the system reset is released in the MPU 431. The ROM controller 734b is different from the ROM controller 434b in the seventh embodiment in that the data output to the bus line 440 is set to the high impedance state and the data is not output.

As a result, when the MPU 431 specifies the address corresponding to a part of the boot program to be executed first after the system reset is released to the bus line 440, the data output of the character ROM 734 is in a high impedance state. , The data (instruction code) corresponding to the address specified in the bus line 440 can be reliably output from the NOR type RAM 735 to the MPU 431. Further, in this case, since unnecessary operations are not executed in the character ROM 734, it is possible to suppress wasteful consumption of electric power in the character ROM 734.

As described above, the NOR type ROM 735 is a non-volatile memory having an extremely small capacity (for example, 2 kilobytes) connected to the bus line 440. The NOR type ROM 735 has a first program storage area 735a, and the first program storage area 735a has the same control program as the first program storage area 434d1 of the NOR type ROM 434d in the seventh embodiment, that is, the same control program. , A part of the boot program that is first executed after the system reset is released in MPU431 is stored.

In this NOR type ROM 735, the address specified by the MPU 431 to the bus line 440 is an address corresponding to a part of the boot program that the MPU 431 should execute first after the system reset is released (for example, "0000H" to "0400H"). When it is detected, the data (instruction code) corresponding to the address is read from the first program storage area 735a and output to the MPU 431.

At this time, since the data output of the character ROM 734 is set to the high impedance state as described above, the data output from the NOR type ROM 735 is surely output to the MPU 431. On the other hand, the address specified in the bus line 440 is different from the control program stored in the NOR type ROM 735, that is, the address corresponding to a part of the boot program that the MPU 431 should execute first after the system reset is released. If is a different address, the NOR type ROM 735 sets its data output to a high impedance state. As a result, when such an address is set, the data read from the memory corresponding to the address (resident video RAM 435, normal video RAM 436, character ROM 734, etc.) is surely output to the bus line 440. be able to.

Here, as in the seventh embodiment, when the system reset is released, the MPU 431 sets the value of the instruction pointer 181a to "0000H" by the hardware, and at the instruction pointer 181a with respect to the bus line 440. It is configured to specify the indicated address "0000H". On the other hand, when the NOR type ROM 735 detects that the address "0000H" is specified for the bus line 440, as described above, the NOR type ROM 735 reads out the boot program stored in the first program storage area 735a of the NOR type ROM 735 and responds. The data (instruction code) to be output is output to MPU431.

Then, the MPU 431 fetches the instruction code received from the character ROM 434 and starts the execution of the process according to the fetched instruction, thereby activating the main process shown in FIG. 73 and starting the process. Then, as shown in FIG. 73, the main process first executes the boot process (S701). The boot process executed here is the same as the boot process shown in FIG.

Here, since the NOR type ROM is a memory capable of reading data at high speed, the NOR type ROM 735 stores a part of the boot program that the MPU 431 should execute first after the system reset is released, and also By connecting this NOR type ROM 735 to the bus line 440, a part of the boot program can be read out from the NOR type ROM 735 at high speed and output to the MPU 431. Therefore, in the MPU 431, the instruction code of the boot program read at high speed can be fetched immediately, so that the main process can be started in a short time. Therefore, even if the control program is stored in the character ROM 734 configured by the NAND flash memory 734a having a slow read speed, the control of the third symbol display device 281 in the display control device 314 can be started immediately.

Further, in the display control device 314 of the twelfth embodiment, since the NOR type ROM 735 is connected to the bus line 440, the number of parts increases as compared with the seventh embodiment. In this NOR type ROM 735, the MPU 431 is a system. It is provided to store a part of the boot program that should be executed first after the reset is released, and as the capacity thereof, as described above, an extremely small one can be used. Therefore, the increase in cost due to the provision of the NOR type ROM 735 can be suppressed to a small extent.

In addition, the pachinko machine 200 in the twelfth embodiment can exert the same action and effect as the pachinko machine 200 in the seventh embodiment based on the same components as the pachinko machine 200 in the seventh embodiment.

The "drawing content" and "additional drawing content" described in the above embodiment correspond to a part of the "drawing information" and "drawing instruction information" described in the claims, and are described in the above embodiment. The "sprite type", "back surface type", and "design type offset" correspond to the "specific information" described in the claims, and the "sprite (display) data storage RAM" described in the above embodiment. "Type and address" corresponds to "image instruction information" and "part of drawing instruction information" described in the claims, and "drawing list" described in the above embodiment is described in the claims. Corresponding to the "instruction information", the "transfer data information" described in the above embodiment corresponds to the "transfer instruction information" described in the claims. In addition, "BB prize announcement production", "watermelon prize announcement production", "bell prize announcement production", "BB prize challenge production", "cherry bell prize challenge production", "cherry bell prize 7" described in the above embodiment. "Bell winning challenge effect", "variable effect", "demo effect", "confirmed display effect", and "restart effect" correspond to the "display type" described in the claims and are described in the above embodiment. The "variable effect" corresponds to the "dynamic display effect" described in the claims, and the "continuous notice effect" described in the above embodiment is changed to the "second display type" described in the claims. Correspondingly, the "display data table" described in the above embodiment corresponds to the "first provision information" described in the claims, and the "additional data table" described in the above embodiment corresponds to the claims. Corresponding to the described "second regulation information", the "transfer data table" described in the above embodiment corresponds to the "third regulation information" described in the claims. Further, the "third symbol" described in the above embodiment corresponds to the "identification information" described in the claims, and the "15R probability variation jackpot", "2R probability variation jackpot", and "time reduction" described in the above embodiment correspond to the "identification information". The "big hit" corresponds to the "predetermined game value" described in the claims. Further, the "confirmation command" described in the above embodiment corresponds to the "first command" described in the claims, and the "variation pattern command" described in the above embodiment is described in the claims. Corresponds to the "second command" of the above, and the "stop type command" described in the above embodiment corresponds to the "third command" described in the claims. Further, the "boot program" described in the above embodiment corresponds to the "boot program" described in the claims.

Although the present invention has been described above based on the above-described embodiment, the present invention is not limited to the above-described embodiment, and it is easy to make various modifications and improvements within a range that does not deviate from the gist of the present invention. It can be inferred.

For example, in each of the above embodiments, the image controllers 188,437 transfer image data from the character ROMs 187,195,196,197,434,534,634,734 to the resident video RAMs 189,435 or the normal video RAMs 190,436. The case of executing the process has been described, but the present invention is not limited to this. For example, the MPU181,431 directly accesses the character ROMs 187,195,196,197,434,534,634,734, reads the image data from the character ROMs 187,195,196,197,434,534,634,734, and reads the image data. It may be transferred to the resident video RAMs 189, 435 or the normal video RAMs 190, 436. Then, in this case, the image data read from the character ROMs 187,195,196,197,434,534,634,734 by the MPU181,431 is temporarily stored in the buffer RAMs 188a, 437a, and then the MPU181,431 is the transfer destination. It is determined whether or not the resident video RAM 189, 435 or the normal video RAM 190, 436 is unused, and if it is not used, the resident video RAM 189, 435 or the normal video to be transferred from the buffer RAMs 188a, 437a is determined. The image data may be transferred to the RAMs 190 and 436.

In this case, the image controllers 188 and 437 are accessing the resident video RAMs 189 and 435 to determine whether or not the transfer destination resident video RAMs 189, 435 or the normal video RAMs 190 and 436 are unused (the image controllers 188 and 437 are accessing the resident video RAMs 189 and 435. That is, the resident video RAM access flag (not shown) indicating that it is in use) and the image controllers 188, 437 are accessing the normal video RAM 190, 436 (that is, it is in use). A normal video RAM access flag (not shown) indicating the above may be provided in the image controllers 188, 437, and the MPU 188, 431 may confirm the access flag corresponding to the buffer RAM of the transfer destination.

Alternatively, the MPU181,431 transmits a signal transmitted / received between the image controller 188,437 and the resident video RAM 189,435, or a signal transmitted / received between the image controller 188,437 and the normal video RAM 190,436. It may be monitored and it may be confirmed whether or not the resident video RAMs 189 and 435 and the normal video RAMs 190 and 436 are unused from the state of the signal. Alternatively, when the image controllers 188,437 start access to the resident video RAMs 189,435 and the normal video RAMs 190,436, or when the access ends, the information is transmitted from the image controllers 188,437 to the MPU188 at any time. By notifying, 431, the MPU 188,431 may determine whether or not the resident video RAMs 189, 435 and the normal video RAMs 190, 436 are unused based on the notification.

Alternatively, when the image controllers 188 and 437 scan the auxiliary display unit 65 or the third symbol display device 281, the MPU 181 and 431 determine whether or not the scanning is during the blank period (see FIG. 11). , 437 is confirmed by the drive state or the notification from the image controllers 188 and 437, and if the scanning state is in the blank period, it is determined that each video RAM 189, 190, 435, 436 is unused. You may. As a result, it is possible to easily determine whether or not the image controller is unused by checking only the scanning state of the auxiliary display unit 65 of the image controllers 188 and 437 or the third symbol display device 281. can.

Further, in this case, the MPU181,431 is set in the transfer data table set in the transfer data table buffer 185 g, 433f, the composite data table set in the composite data table buffers 191f, 451d, or the display data table buffers 192f, 452d. In the set display data table, when the transfer data information other than the Null data exists at the address indicated by the pointers 185h, 191h, 192h, 433g, 451g, 452g, the character ROM 187, 195, 196 according to the transfer data information. , 197, 434, 534, 634, 734 may be read from, and the process of transferring the image data to the normal video RAMs 190, 436 may be started. Here, the transfer data of the image data to be transferred so that the image data corresponding to the predetermined sprite is stored in the normal video RAMs 190 and 436 by the time the drawing of the predetermined sprite is started according to the display data table or the like. Since the information is specified for a predetermined address, the sprite is drawn according to the display data table or the like by transferring the image data according to the transfer data information specified in this transfer data table. Image data that is not resident in the resident video RAMs 189 and 435 required for drawing can always be stored in the normal video RAMs 190 and 436. Then, using the image data stored in the normal video RAMs 190 and 436, a predetermined sprite can be drawn based on the display data table.

The process of reading image data from the character ROMs 187, 195, 196, 197, 434, 534, 634, 734 and transferring them to the normal video RAMs 190, 436 is the display main process or the main process executed by the MPU 181 or 431. It may be done in the loop of. As a result, in the MPUs 181 and 431, it is possible to execute the image data transfer processing by utilizing the time when the important processings in the display control devices 81 and 314 such as the command interrupt processing and the V interrupt processing are not performed. .. Further, since the command interrupt process and the V interrupt process are executed with priority over the display main process, the MPU 181 and 431 do not affect the command interrupt process and the V interrupt process. Image data transfer processing can be executed.

In each of the above embodiments, the MPUs 181 and 431 do not manage the respective video RAMs by using the addresses of the resident video RAMs 189, 435 and the normal video RAMs 190 and 436, but instead manage the resident video RAMs 189, 435 and the resident video RAMs 189, 435. In the address system commonly used with the normal video RAMs 190 and 436, a different address area may be allocated to each video RAM to manage each video RAM. In this way, the MPU181,431 does not directly specify the video RAM (resident video RAM 189,435 or normal video RAM 190,436) to be accessed from the image controllers 188,437, but simply assigns an address. Just by specifying, the image controllers 188,437 can determine whether the area specified by the address is for the resident video RAMs 189,435 or for the normal video RAMs 190,436. That is, when the MPU181,431 specifies the video RAM to be accessed and the address of the area of the video RAM to the image controllers 188,437, simply specify the address set in the common address system. Since it is sufficient, the structure of the instruction for specifying the specification can be simplified. For example, it is transmitted from MPU181,431 to the image controllers 188,437, and is simply set in a common address system as information indicating the storage destination of sprite data in the drawing list without including the storage RAM type. Since it is only necessary to specify the storage destination address using the address, the structure of the drawing list can be simplified.

In each of the above embodiments, the character ROMs 187,195,196,197,434,534,634,734 are directly connected to the internal bus (bus line 440) to which the MPU181, 431 and the image controllers 188,437 are connected. However, the present invention is not limited to this, and the character ROMs 187, 195, 196, 197, 434, 534, 634, 734 may be provided by directly connecting to the image controllers 188, 437. Further, a bridge circuit for converting the input / output specifications of the character ROMs 187, 195, 196, 197, 434, 534, 634, 734 into the input / output specifications of the mask ROM is provided, and the character ROMs 187, 195, 196 are provided via the bridge circuit. , 197,434,534,634,734 may be provided by connecting to an internal bus (bus line 440) or an image controller 188,437.

By providing this bridge circuit, a NAND flash memory can be used as it is by using an existing image controller 188, 437 or an internal bus (bus line 440) designed on the assumption that a general mask ROM is used as a character ROM. Character ROMs 187, 195, 196, 197, 434, 534, 634, 734 composed of 187a, 195a, 196a, 197a, 434a, 534a, 634a, 734a can be connected. Even when the character ROMs 187,195,196,197,434,534,634,734 are connected via the image controllers 188,437 and the bridge circuit, the character ROMs 187,195,196 from the MPU181,431 It may be configured to have direct access to 197,434,534,634,734.

In each of the above embodiments, the case where the character ROM 187, 195, 196, 197, 434, 534, 634, 734 is composed of the NAND flash memory 187a, 195a, 196a, 197a, 434a, 534a, 634a, 734a has been described. However, the present invention is not limited to this, and may be configured by a large-capacity and inexpensive non-volatile storage means such as a hard disk. Such a large-capacity and inexpensive storage means generally has a slow read speed, but by adopting the display control devices 81 and 314 having the configurations described in the above embodiments, the image can be displayed at the desired time. Can be displayed without.

In the first to third and seventh to ninth embodiments, the character ROMs 187 and 434 are provided with the NOR type ROMs 187d and 434d, and the first program storage areas 187d1 and 434d1 are first executed after the system reset is released in the MPU181. The case where a part of the boot program is stored has been described, but the present invention is not limited to this, and the first is a memory composed of a non-volatile storage medium capable of reading operation at a higher speed than the NAND flash memory 191a. A program storage area may be provided to store a part of the boot program that is first executed in the MPU 181 after the system reset is released. For example, instead of the NOR type ROMs 187d and 434d, FeRAM (Ferroelectric RAM), MRAM (Magnetoresistive RAM), PRAM (Phase change RAM) and the like are provided in the character ROMs 187 and 434, and a first program storage area is provided in the MPU181. It may contain a part of the boot program that is executed first after the system reset is released.

Further, in the fourth and twelfth embodiments, the NOR type ROMs 198 and 735 connected to the internal bus (bus line 440) are provided with the first program storage areas 198a and 735a, and the MPU 181 first provides the first program storage areas 198a and 735a in the area after the system reset is released. Although the case of storing a part of the boot program executed in is described, the present invention is not limited to this, and is composed of a non-volatile storage medium capable of reading operation at a higher speed than the NAND flash memory 191a. A memory is connected to an internal bus (bus line 440), a first program storage area is provided in the memory, and a part of the boot program executed first after the system reset is released in the MPU 181 is stored in the memory. May be good. For example, instead of the NOR type ROMs 198 and 735, FeRAM (Ferroelectric RAM), MRAM (Magnetoresistive RAM), PRAM (Phase change RAM), etc. are provided in the internal bus (bus line 440), and a first program storage area is provided therein. , MPU181 may store a part of the boot program that is executed first after the system reset is released.

In the first to third, fifth, seventh to ninth, and eleventh embodiments described above, the address of the internal bus (bus line 440) is designated as "0000H" in the ROM controllers 187b, 196b, 434b, and 634b. When this is detected, the boot program stored in the first program storage area 187d1,196d, 434d1,634d is set in the buffer RAMs 187c, 196c, 434c, 634c, and then the data (instruction code) corresponding to the specified address is set. ) Is read from the buffer RAMs 187c, 196c, 434c, and 634c and output to the MPU 181 and 431 via the internal bus (bus line 440). On the other hand, when the ROM controllers 187b, 196b, 434b, 634b detect that the power is turned on from the power supply devices 91, 315, the ROM controllers 187b, 196b, 434b, 634b have the first program storage areas 187d1,196d, 434d1. , The boot program stored in 634d is set in the buffer RAMs 187c, 196c, 434c, 634c, and then the address of the internal bus (bus line 440) is set to "0000H" in the ROM controllers 187b, 196b, 434b, 634b. When it detects that it has been specified, the data (instruction code) corresponding to the specified address is read from the buffer RAMs 187c, 196c, 434c, 634c and output to the MPU181,431 via the internal bus (bus line 440). May be good. In this case, if the MPU181,431 specifies the address "0000H" for the internal bus (bus line 440) after the system reset is released, the first program storage areas 187d1, 196d, 434d1, already in the buffer RAMs 187c, 196c, 434c, 634c. Since the boot program stored in 634d has been set or is in the process of being set, the character ROMs 187,196,434,634 correspond with less delay after the address "0000H" is specified by the MPU181,431. Data (command code) can be output. Therefore, since the MPUs 181 and 431 can receive the instruction code corresponding to the address "0000H" in a short time after designating the address "0000H", the MPU181, 431 can start the display main process in a short time. Can be done. As a result, even if the control program is stored in the character ROM 187, 196, 434, 634 composed of the NAND flash memories 187a, 196a, 434a, 634a having a slow read speed, the auxiliary effect unit in the display control devices 81, 314 or The control of the third symbol display device 281 can be started immediately.

Further, the ROM controllers 187b, 196b, 434b, and 634b specify a control program whose address specified in the internal bus (bus line 440) is stored in the first program storage area 187d1,196d, 434d1,634d. When it is detected, the data (instruction code) corresponding to the specified address is read directly from the first program storage area 187d1,196d, 434d1,634d, and the data (command code) corresponding to the specified address is read from the MPU181 via the internal bus (bus line 440). It may be output. As a result, the MPUs 181,431 can receive the instruction code corresponding to the address "0000H" in a short time after the address "0000H" is specified, so that the MPU181,431 starts the display main process in a short time. be able to. As a result, even if the control program is stored in the character ROM 187, 196, 434, 634 composed of the NAND flash memories 187a, 196a, 434a, 634a having a slow read speed, the auxiliary effect unit in the display control devices 81, 314 or The control of the third symbol display device 281 can be started immediately. Further, in this case, the process of setting the control program (boot program) stored in the first program storage area 187d1,196d, 434d1,634d in the buffer RAM 634c may not be performed. As a result, the power consumption of the character ROMs 187, 196, 434, 634 can be suppressed.

In each of the above embodiments, the case where the resident video RAMs 189 and 435 are connected to the image controllers 188 and 437 have been described, but the present invention is not limited to this, and the MPU 181 and 431 and the character ROM 187, 195, 196, 197 are not necessarily limited to this. , 434, 534, 634, 734 and the image controllers 188, 437 may be directly connected to the internal bus (bus line 440) to which the image controllers 188, 437 are connected. When the character ROMs 187,195,196,197,434,534,634,734 are connected to the internal bus (bus line 440) or the image controllers 188,437 via the bridge circuit, they are resident in the bridge circuit. Video RAMs 189 and 435 may be connected and provided. If the resident video RAMs 189,435 are configured to be connected to the bridge circuit, the existing image controller 188,437 or the internal bus (bus line 440) is not configured to be able to directly connect the resident video RAMs 189,435. However, the resident video RAMs 189 and 435 can be easily provided in the display control devices 81 and 314.

In each of the above embodiments, the case where one resident video RAM 189,435 and one normal video RAM 190,436 are provided in the display control devices 81, 314 has been described, but the number of various video RAMs is limited to this. More video RAM may be provided instead of one. Further, a plurality of resident video RAMs may be provided, image data corresponding to images corresponding to various modes may be resident in each, and a resident video RAM to be used may be selected according to the mode.

In each of the above embodiments, the case where the resident video RAMs 189 and 435 and the normal video RAMs 190 and 436 are configured by a 1-port type (1 port input / output port) DRAM has been described, but the present invention is not necessarily limited to this. Instead, a multi-port type RAM may be used. As a result, writing to and reading from the resident video RAMs 189 and 435 and the normal video RAMs 190 and 436 can be performed at the same time. For example, while reading image data from the normal video RAMs 190 and 436 and drawing an image, the image data can be drawn. The process of writing the image data read from the character ROMs 187, 195, 196, 197, 434, 534, 634, 734 to the normal video RAMs 190, 436 can be performed in parallel. Therefore, it is possible to suppress the possibility that the drawing process is delayed due to the writing of the image data.

Further, in each of the above embodiments, the case where the resident video RAMs 189 and 435 and the normal video RAMs 190 and 436 are configured by different memories has been described, but the present invention is not limited to this, and one RAM is used as a resident area. And the normal area may be divided, and the same contents as those of the resident video RAMs 189 and 435 and the normal video RAMs 190 and 436 may be stored in each area. When a resident area and a normal area are configured by one RAM, in order to prevent the input / output port of the memory from being occupied by one of the resident area and the normal area in the read or write process. , It is desirable to use a multi-port type RAM.

The type of image data stored in the resident video RAMs 189 and 435 in each of the above embodiments is an example, and the type is appropriately set according to the content of the image to be displayed on the auxiliary display unit 65 or the third symbol display device 281. It may be what is done. In this case, an image corresponding to an image to be immediately displayed on the auxiliary display unit 65 or the third symbol display device 281 in response to a reception command received from the main control device 101 or the voice lamp control device 313 or other external input. It is preferable to make the data resident at least in the resident video RAMs 189 and 435.

In each of the above embodiments, a case where a part of the image data stored in the character ROMs 187,195,196,197,434,534,634,734 is transferred to the resident video RAMs 189,435 and made resident has been described. All image data stored in the character ROMs 187, 195, 196, 197, 434, 534, 634, 734 may be transferred to the resident video RAMs 189, 435. In this case, since the image data stored in the non-resident character ROMs 187, 195, 196, 197, 434, 534, 634, 734 in the resident video RAMs 189, 435 does not exist, the normal video RAMs 190, 436 are the image controller 188. , 437 may be used as a dedicated memory for storing the drawn image data obtained by drawing.

In each of the above embodiments, the case where the resident video RAMs 189 and 435 are not overwritten and their contents are continuously retained while the power is turned on is described, but the present invention is not limited to this, and the main control means 101 or the audio lamp is used. Image data to be resident in the resident video RAMs 189 and 435 based on a predetermined opportunity, such as when the image to be displayed on the auxiliary display unit 65 or the third symbol display device 281 is significantly different based on the command received from the control device 313. May be overwritten and updated. In this case, a predetermined transition image may be displayed as a transition period while the image to be displayed on the auxiliary display unit 65 or the third symbol display device 281 is changed. Further, the image data corresponding to the transition image is stored in the resident video RAMs 189,435 when the power is turned on, and is retained in the resident video RAMs 189,435 without being updated even when other resident images are updated. You may try to continue. Further, while displaying the transition image, the MPU181,431 directly accesses the character ROMs 187,195,196,197,434,534,634,734, reads out the image data to be newly resident, and reads out the image data. The image data may be transferred via the buffer RAMs 188a and 437a while the resident video RAMs 189 and 435 are unused (that is, during the period when the image data corresponding to the transition image is not read). .. Alternatively, while the transition image is being displayed, the MPU 181 and 431 transmit a transfer instruction (transfer data information) for image data to be newly resident to the image controllers 188 and 437, and the image controllers 188 and 437 send a new transfer instruction (transfer data information). , Image data to be resident is read from the character ROM 187,195,196,197,434,534,634,734 according to the transfer command (transfer data information), and the resident video RAMs 189 and 435 are read via the buffer RAMs 188a and 437a. It may be transferred while it is unused (that is, during the period when the image data corresponding to the transition image is not read).

When updating the resident video RAMs 189 and 435, the image data corresponding to the transition image is transferred from the character ROMs 187, 195, 196, 197, 434, 534, 634, 734 to the normal video RAMs 190, 436 in advance. The transition image may be displayed on the auxiliary display unit 65 or the third symbol display device 281 using the image data stored in the normal video RAMs 190 and 436. Then, while the transition image is displayed, the MPU181,431 directly accesses the character ROMs 187,195,196,197,434,534,634,734, reads out the image data to be newly resident, and reads the image data. The read image data may be transferred via the buffer RAM 188a. Alternatively, the image controllers 188,437 that have received the transfer instruction of the image data to be resident from MPU181,431 access the character ROM 187,195,196,197,434,534,634,734, and the image to be newly resident. The data may be read and the read image data may be transferred via the buffer RAM 188a. By updating the contents of the resident video RAM 189 while displaying the transition image, the resident video RAM 189 can be updated without giving the player a sense of discomfort.

In each of the above embodiments, after all the image data to be resident in the resident video RAMs 189 and 435 are resident, the RAM determination value for determining whether the data in the resident video RAMs 189 and 435 is normal or not is stored when the power failure is resolved. In the display main process or main process executed by the MPU181,431 of the display control devices 81,314 after the power is turned on, the main image data at the time of power-on is stored in the character ROM 187,195,196,197,434,534. , 634, 734 Before starting the transfer to the resident video RAMs 189,435, check the RAM judgment value, and if the RAM judgment value is a normal value, the image data to be resident in the resident video RAMs 189,435 Since it means that the image data is normally stored, the image data may be configured not to be transferred to the resident video RAMs 189 and 435. In this case, by turning off the simple image display flag, the transfer of the image data to the resident video RAMs 189 and 435 may be non-executed. As a result, even if a system reset is input to the display control devices 81 and 314 due to the occurrence of a momentary power failure and the MPU181,431 starts executing the display main process or the main process, the resident video RAM 189,435 If the data of is normally stored, it is possible to prevent the image data from being unnecessarily transferred from the character ROMs 187,195,196,197,434,534,634,734 to the resident video RAMs 189,435. , The time required to recover from a power failure can be shortened. In particular, since the character ROM 187, 195, 196, 197, 434, 534, 634, 734 is composed of the character ROM 187a, 195a, 196a, 197a, 434a, 534a, 634a, 734a having a slow read speed, the character ROM 187, It takes a long time to transfer image data from 195,196,197,434,534,634,734 to the resident video RAMs 189,435. On the other hand, if the data of the resident video RAMs 189 and 435 remains normally due to a momentary power failure by storing the RAM determination value in the resident video RAMs 189 and 435 as in this modification, the image data. Since the time required for the transfer of the image can be shortened, the normal effect image can be immediately displayed on the auxiliary display unit 65 or the third symbol display device 281. Therefore, the player can immediately start the game. The RAM determination value may be, for example, a checksum value of image data stored in the resident video RAMs 189 and 435. Further, instead of this RAM determination value, the validity of the data may be determined based on whether or not the keywords written in the predetermined areas of the resident video RAMs 189 and 435 are correctly stored.

In each of the above embodiments, the case where the buffer RAMs 188a and 437a are provided inside the image controllers 188 and 437 has been described, but the present invention is not limited to this, and the buffer RAMs 188a and 437a may be provided outside the image controllers 188 and 437. For example, the buffer RAM may be configured independently and directly connected to the internal bus (bus line 440). When the character ROMs 187,195,196,197,434,534,634,734 are connected to the internal bus (bus line 440) or the image controllers 188,437 via the bridge circuit, a buffer is provided in the bridge circuit. A RAM may be provided. Further, the resident video RAMs 189 and 435 may be directly connected to the bridge circuit having the buffer RAM. In this case, image data is transferred from the character ROMs 187, 195, 196, 197, 434, 534, 634, 734 connected to the bridge circuit to the resident video RAMs 189, 435 via the buffer RAM provided in the bridge circuit. Therefore, transfer can be performed efficiently without being affected by the internal bus (bus line 440) in which many data signals are exchanged.

In each of the above embodiments, the case where the storage capacity of the buffer RAMs 188a and 437a is one block of the NAND flash memories 187a, 195a, 196a, 197a, 434a, 534a, 634a and 734a has been described, but the present invention is not necessarily limited to this. It may be set as appropriate instead of being used. For example, among the scanning periods of the display screen of the auxiliary display unit 65 or the third symbol display device 281, the period of scanning on the blank area which is the scanning area other than the display area where the actual image is displayed (blank period). ), The storage capacity of the buffer RAMs 188a, 437a may be such that the transfer of image data from the buffer RAMs 188a, 437a to the resident video RAMs 189, 435 or the normal video RAMs 190, 436 can be completed. As a result, the transfer of image data from the buffer RAMs 188a, 437a to the resident video RAMs 189, 435 or the normal video RAMs 190, 436 utilizes the unused period of each video RAM 189, 190, 435, 436 that occurs during this blank period. By doing so, it can be done reliably.

In each of the above embodiments, the case where one buffer RAM 188a and 437a is provided has been described, but the present invention is not limited to this, and two or more buffer RAMs may be provided. In this case, while the image data read from the character ROMs 187,195,196,197,434,534,634,734 is stored in one buffer RAM, the resident video RAMs 189,435 are stored in another buffer RAM. Alternatively, the image data stored in the normal video RAMs 190 and 436 may be transferred. Further, the area is divided into two or more in one buffer RAM, and the image data read from the character ROMs 187, 195, 196, 197, 434, 534, 634, 734 is stored in one area. In the meantime, the image data may be transferred from another area in which the image data is stored to the resident video RAMs 189, 435 or the normal video RAMs 190, 436. In any case, the image data read from the character ROMs 187,195,196,197,434,534,634,734 is written to the buffer RAM, and the image data written to the buffer RAM is resident. Since the transfer to the video RAM 189, 435 or the normal video RAM 190, 436 can be processed in parallel, the time required for the processing can be shortened.

In the first to sixth embodiments, the image data corresponding to the main image at power-on is transferred from the character ROMs 187, 195, 196, 197 to the main image area 189a at power-on of the resident video RAM 189 after the power is turned on. As described above, the image data corresponding to the main image at power-on may be transferred from the character ROMs 187, 195, 196, 197 to the normal video RAM 190 after the power is turned on. As a result, using the image data corresponding to the power-on main image stored in the normal video RAM 190, the auxiliary display unit 65 is resident from the character ROMs 187, 195, 196, and 197 while displaying the power-on main image. Image data to be resident can be transferred to the video RAM 189. During this period, the image data is not read from the resident video RAM 189, so that the image data can be transferred from the character ROM 187 to the resident video RAM 189 without monitoring the usage status of the resident video RAM 189. The transfer can be completed quickly and the processing can be simplified.

Similarly, in the seventh to twelfth embodiments, when the resident video RAM 435 is powered on from the character ROM 434,534,634,734 after the image data corresponding to the main image at power-on and the variable image at power-on is turned on. The case of transferring to the main image area 435a and the variable image area 435b at power-on has been described. However, the image data corresponding to the main image at power-on and the variable image at power-on is transferred to the character ROM 434,534,634,734 after the power is turned on. May be transferred to the normal video RAM 436. As a result, the character ROM 434 and the character ROM 434 while displaying the power-on image on the third symbol display device 281 using the image data corresponding to the power-on main image and the power-on fluctuation image stored in the normal video RAM 436. Image data to be resident can be transferred from 534, 634, 734 to the resident video RAM 435. During this period, the image data is not read from the resident video RAM 435, so that the image data can be transferred from the character ROM 434 to the resident video RAM 435 without monitoring the usage status of the resident video RAM 435. The transfer can be completed quickly and the processing can be simplified.

In the first to sixth embodiments, the image data corresponding to the main image at power-on is transferred from the character ROMs 187, 195, 196, 197 to the main image area 189a at power-on of the resident video RAM 189 via the buffer RAM 188a. Although the case has been described, since the image data is not read from the resident video RAM 189 while the image data corresponding to the main image at power-on is transferred, the image data corresponding to the main image at power-on is stored in the character ROM 187. , 195, 196, 197 may be directly transferred to the main image area 189a when the power of the resident video RAM 189 is turned on, without going through the buffer RAM 188a. Further, the image data corresponding to the main image at power-on is transferred from the character ROMs 187, 195, 196, 197 to the normal video RAM 190 after the power is turned on, and the image corresponding to the main image at power-on stored in the normal video RAM 190 is transferred. While the image data to be resident is transferred from the character ROM 187, 195, 196, 197 to the resident video RAM 189 by displaying the main image when the power is turned on on the auxiliary display unit 65 using the data, the resident video RAM 189 When the image data is configured not to be read out, the image data to be resident may be directly transferred from the character ROMs 187, 195, 196, 197 to the resident video RAM 189 without going through the buffer RAM 188a. As a result, the transfer of image data can be completed faster without going through the buffer RAM 188a.

Similarly, in the seventh to twelfth embodiments, the image data corresponding to the main image at power-on and the variable image at power-on is transferred from the character ROM 434,534,634,734 to the power supply of the resident video RAM 435 via the buffer RAM 437a. The case of transferring to the main image area 435a at power-on and the variable image area 435b at power-on has been described, but while the image data corresponding to the main image at power-on and the variable image at power-on is transferred from the resident video RAM 434. Since the image data is not read out, the image data corresponding to the main image at power-on and the variable image at power-on can be output from the character ROM 434,534,634,734 from the character ROM 434,534,634,734 when the power of the resident video RAM 435 is turned on without going through the buffer RAM 437a. It may be directly transferred to the main image area 435a and the variable image area 435b when the power is turned on. Further, the image data corresponding to the main image at power-on and the variable image at power-on are transferred from the character ROM 434,534,634,734 from the character ROM 434,534,634,734 to the normal video RAM 436 after the power is turned on, and at the time of power-on stored in the normal video RAM 436. By displaying the image at power-on on the third symbol display device 281 using the image data corresponding to the main image and the fluctuating image at power-on, the character ROM 434,534,634,734 is resident in the resident video RAM 435. If the image data to be resident is not read from the resident video RAM 435 while the image data to be resident is transferred, the image data to be resident is transferred from the character ROM 434,534,634,734 from the character ROM 434,534,634,734 without going through the buffer RAM 437a. May be transferred directly to the resident video RAM 435. As a result, the transfer of image data can be completed faster without going through the buffer RAM 437a.

In the first to sixth embodiments, the display control device 81 replaces the display data table and the composite data table based on the content of the command received from the main control device 101, so that the display control device 81 is displayed on the back surface of the auxiliary display unit 65. The case of changing the image has been described, but in addition to or separately from this, the slot machine 10 is provided with an operation button in which the rear image of the auxiliary display unit 65 can be changed by the player, and the operation is performed by the player. It may be configured so that the rear image is changed when the button is operated. Specifically, the output signal output from the operation button when the operation button is operated by the player is input to the input / output port 186 of the display control device 81, and the MPU 181 is input from the operation button. After confirming that the operation button has been operated by the player, it is determined to change the rear image, and the image data corresponding to the rear image to be displayed after the change stored in the rear image area 189b of the resident video RAM 189 is displayed. You may instruct the image controller 188 to draw an image using it. As a result, after the operation buttons are operated by the player, the changed rear image is immediately displayed on the auxiliary display unit 65 using the image data stored in the rear image area 189b of the resident video RAM 189. be able to. Therefore, even when the character ROMs 187, 195, 196, and 197 are configured by using the NAND flash memories 187a, 195a, 196a, and 197a having a slow read speed, the auxiliary display immediately responds to the operation of the player. The rear image after the change can be displayed on the unit 65.

On the other hand, in the seventh to twelfth embodiments, when the frame button 222 is operated by the player, the rear image change command and the frame button operation command are generated by the voice lamp control device 313, and the display control device 314 generates the rear image change command and the frame button operation command. Although the case of changing the rear image displayed on the third symbol display device 281 and the effect mode of the super reach based on the rear image change command and the frame button operation command has been described, the present invention is not limited to this. For example, the voice lamp control device 313 grasps the gaming state of the gaming machine 200 based on the content of the command received from the main control device 310, and according to the gaming state, for example, in accordance with the change of the gaming state. A rear image change command or a game state command may be generated. As a result, the display control device 314 can change the rear image and the super reach effect mode according to the game state based on the rear image change command and the game state command. Further, the display control device 314 may directly grasp the gaming state of the gaming machine 200, and the rear image or the super reach effect mode may be changed according to the gaming state. Then, the rear image after the change or the image data corresponding to at least a part of the range of the rear image corresponding to the super reach of the effect mode after the change is resident in the rear image area 435c of the resident video RAM 435. From the resident range, the back image can be immediately displayed using the image data resident in the back image area 435c.

Further, the display control devices 81 and 314 may change the rear image according to the provisions of the display data table, the transfer data table, the additional data table, and the composite data table. In this case, the image data corresponding to the changed rear image is the character ROM 187, 195, 196, 197, 434, 534, 634, according to the transfer data information described in the transfer data table, the composite data table, and the display data table. It may be configured to be pre-transferred from the 734 to the normal video RAM 436. Here, when the image data of the rear image is transferred by the transfer data information described in the transfer data table, the composite data table, or the display data table, the image storage area of the normal video RAMs 190 and 436 in which the original rear image is stored is stored. The transfer data information of the transfer data table may be specified so that a new rear image is stored in the sub-area of 190a, 436a, or the image storage area of the normal video RAM 190, 436 in which the original rear image is stored. The transfer data information of the transfer data table may be specified so that a new rear image is stored in an area different from the sub-areas of 190a and 436a. In the latter case, when the back image is returned to the original back image selected and displayed by the player, it is not necessary to transfer the image data corresponding to the original back image again, so that the display control devices 81 and 314 do not need to be transferred. It is possible to suppress an increase in the processing load of.

In the first to sixth embodiments, when the output signals of the first insertion medal detection sensor 45a and the second insertion medal detection sensor 45b are input to the main control device 101 and a sensor error is detected by the main control device 101. By transmitting an error command to the display control device 81, the display control device 81 immediately sends an error message to the auxiliary display unit 65 using the image data resident in the error message image area 189e of the resident video RAM 189. Although the case of displaying is described, the present invention is not limited to this, and the output signals of the first inserted medal detection sensor 45a and the second inserted medal detection sensor 45b are input to the display control device 81 and displayed by the display control device 81. It is configured to detect the presence or absence of a sensor error, and when a sensor error is detected in the display control device 81, the display is set by turning on the error occurrence flag and further turning on the error discrimination flag corresponding to the sensor error. When it is determined in the process (see FIG. 28) that the error occurrence flag is on, the warning image data may be expanded (S805) to immediately display the warning image on the auxiliary display unit 65. This eliminates the need to send and receive error commands from the main control device 101 to the display control device 81, so that the error message can be displayed on the auxiliary display unit 65 earlier.

Further, in the seventh to twelfth embodiments, the output signal of the vibration sensor 428 is input to the voice lamp control device 313, and when a vibration error is detected in the voice lamp control device 313, an error command is displayed in the display control device 314. Although the case where the warning image is immediately displayed on the third symbol display device 281 by the display control device 314 by transmitting to the display control device 314 is not necessarily limited to this, the output signal of the vibration sensor 428 is mainly controlled. Input to the device 310, detect a vibration error in the main control device 310, and send an error command notifying the error from the main control device 310 to either the voice lamp control device 313 or the display control device 314. You may. Then, when an error command is transmitted to the voice lamp control device 313, the voice lamp control device 313 receives the error command and further sends an error command notifying the display control device 314 of the error command. You may.

On the other hand, the output signal of the vibration sensor 428 may be input to the display control device 314, and the display control device 314 may be configured to detect the presence or absence of a vibration error. Then, when a vibration error is detected, the error occurrence flag is turned on, and further, by turning on the error discrimination flag corresponding to the vibration error, the error occurrence flag is turned on in the display setting process (see FIG. 80). By executing the warning image setting process (see FIG. 82 (b)) when the above is determined, the warning image may be immediately displayed on the third symbol display device 281. In this case, this eliminates the need to send and receive error commands from the voice lamp control device 313 to the display control device 314, so that the warning image can be displayed on the third symbol display device 281 earlier.

Further, in the seventh to twelfth embodiments described above, the case where the vibration sensor 428 is attached to the back surface of the game plate 213 has been described, but instead of the vibration sensor 428 or together with the vibration sensor 428, the magnet sensor is used for the game. It may be attached to the back surface of the plate 213. This magnet sensor is a sensor for detecting the magnetic field applied to the game board in order to suppress the intentional entry of the ball into the entry port due to the change in the flow of the ball due to the magnetic field such as a magnet. The output signal of the magnet sensor may be input to any of the main control device 310, the voice lamp control device 313, and the display control device 314. Then, when the output signal of the magnet sensor is input to the main control device 310, if it is determined that the magnetic field is applied to the game board 213 by the main control device 310 based on the output signal of the magnet sensor, the magnetic field error is detected. The error command to be transmitted may be transmitted from the main control device 310 to the display control device 314 via the voice lamp control device 313 or directly. Further, when the output signal of the magnet sensor is input to the voice lamp control device 313, if it is determined by the voice lamp control device 313 that a magnetic field is applied to the game board 213 based on the output signal of the magnet sensor, the magnetic field is determined. An error command that conveys an error may be transmitted from the voice lamp control device 313 to the display control device 314. Then, in the error message image area 435f of the resident video RAM 435 of the display control device 313, image data corresponding to the error message image for notifying the magnetic field error by the display of the third symbol display device 218 is resident. When an error command for transmitting a magnetic field error is received from the main control device 310 or the voice lamp control device 313, the display control device 313 may display the warning image on the third symbol display device 218. Further, when the output signal of the magnet sensor is input to the display control device 310, it is determined that the magnetic field is applied to the game board 213 by the display control device 314 based on the output signal of the magnet sensor, and the display control device 313. May display the warning image on the third symbol display device 218 by turning on the error occurrence flag and setting the error type flag corresponding to the magnetic field error to on. As a result, when the display control device 314 receives an error command from the main control device 310 or the voice lamp control device 313, or grasps the occurrence of a magnetic field error based on the output signal from the magnet sensor, the character ROM 434 and the character ROM 434. Even when 534,634,734 is composed of NAND flash memories 434a, 534a, 634a, 734a, the error message image resident in the error message image area 435f of the resident video RAM 425 is used without delay. An error message image for notifying a magnetic field error can be displayed on the third symbol display device 281. Therefore, when a magnetic field is applied to the game board by the player, the magnetic field error is immediately notified by the display of the error message image by the third symbol display device 281. It can be deterred.

In the first to sixth embodiments, the case where the upper lamp 63 and the speaker 64 are driven by the display control device 81 has been described, but the present invention is not limited to this, and the upper lamp 63 and the speaker 64 provide an auxiliary display. It may be configured to be driven by a voice lamp control device provided separately from the display control device 81 that drives the unit 65. In this case, the command transmitted from the main control device 101 is received by the voice lamp control device, and the display control device 81 is based on the command transmitted from the voice lamp control device based on the command from the main control device 101. The auxiliary display unit 64 may be controlled. Further, the command transmitted from the main control device 101 may be received by the display control device 81, and the display control device 81 may transmit the command to the voice lamp control device according to the received command. By separately providing the display control device 81 for driving the auxiliary display unit 65 and the audio lamp control device for driving the upper lamp 63 and the speaker 64, the display control device 81 can concentrate on the drive control of the auxiliary display unit 65. In the auxiliary display unit 65, more diverse and complicated image display can be executed, and the interest of the player can be enhanced.

In the above 1st to 6th embodiments, the configuration in which only one type of BB Nyusho is provided as a winning mode in which the privilege of shifting to the bonus state is given when the winning is established has been described, but a plurality of types of state transition winnings have been described. It may be configured to have a role. Further, the total number of medals to be paid out in the bonus state may be set to different values depending on the state transition winning combination in which the winning is established. That is, in the processing of S604 of the bonus state processing (see FIG. 20), the value set in the remaining payout number counter may be changed according to the state transition winning combination in which the winning is established. Further, in the processing of S606 of the bonus state processing (see FIG. 20), when the state command meaning that the game is a BB game is set, the type of the state transition winning combination in which the winning is established is also set. You may. As a result, in the display control device 81, it is possible to change the effect performed by the auxiliary display unit 65, the speaker 64, and the upper lamp 63 according to the state transition winning combination in which the winning is established.

In the first to sixth embodiments described above, the case where the total number of medals to be paid out in the bonus state transitioned to when the BB winning is established is set to 250 (the number of remaining medals to be paid out in S604 of FIG. 20). (Refer to the setting of the counter), the value set as the total number of medals paid out (the number of remaining payouts) is not necessarily limited to this, and may be any number within the range specified by law or the like.

In the first to sixth embodiments described above, in the JAC game performed when the gaming state is in the bonus state, the winning probabilities of the watermelon winning and the bell winning, which are small winning combinations, are set higher than those in the general gaming state. Although the case has been described, the winning probability of either the watermelon winning or the bell winning may be set higher than that in the general gaming state. Further, each winning probability in the bonus state may be determined so that the degree of increase in the winning probability of the watermelon winning with a large number of medals paid out is larger than that of the bell winning. As a result, the expected value of the number of medals to be paid out per game can be raised, so that the player can receive a large number of medals to be paid out with a small number of medals. Further, since the total number of medals to be paid out can be paid out in a short time, the operating rate of the slot machine 10 can be increased for the hall side as well. In addition, a bonus-only winning mode that is established only when the game state is in the bonus state is provided, the number of medals to be paid out is set to a large number, and the winning probability of the bonus-only winning mode is set higher than other winning modes in the bonus state. It may be configured to be. Further, the winning of this bonus-only winning mode may be established only in the case of three cards. As a result, even if the bonus game can be played with one or two cards, the player can be made to play the bonus game with three cards.

In the first to sixth embodiments, the special small winning combination is won only when the game is played with one or two medals inserted, that is, when the game is played with one or two medals. The case where the lottery table is set so that the cherry bell prize is established has been explained, but it is not necessarily limited to this, and the game is played with three medals inserted, that is, the game is played with three medals. You may also set the lottery table so that the cherry bell winning will be established. If the game is played with three medals and the cherry bell prize is established, the number of medals to be paid out may be three or any other. In addition, the winning probability of the cherry bell winning when the game is played with three cards may be set by the lottery table so as to be smaller than other BB winning, watermelon winning, bell winning, and replay winning. As a result, it becomes difficult for the cherry bell winning to be established when three cards are hung, so that it is possible to make it easier for the player to recognize that it is a special small winning combination winning.

Similarly, in the above 1st to 6th embodiments, the case where the lottery table is set so that the 7-bell prize, which is a special small winning combination prize, is established only when the game is played with one card is described. However, the lottery table is not necessarily limited to this, and the lottery table may be set so that the 7-bell prize is established even when the game is played with two or three cards. If the game is played with two or three medals and a 7-bell prize is established, the number of medals to be paid out may be two or any other. If a 7-bell prize is achieved in the case of two medals, it is more preferable to set the number of medals to be paid out to three. This is because the player can play another game using the three medals, so that the player can enjoy the game to the end without leaving any extra medals. .. Further, the winning probability of the 7-bell prize when the game is played with 3 cards may be set by the lottery table so as to be smaller than other BB prizes, watermelon prizes, bell prizes, and replay prizes. As a result, it becomes difficult for the 7-bell prize to be established when three cards are hung, so that it is possible to make it easier for the player to recognize that it is a special small role prize. On the other hand, the probability of winning a 7-bell prize when playing a game with 2 cards is such that the expected value of the number of medals to be paid out in one game is less than 2 in combination with other prizes including the cherry bell prize. It is preferable that it is set by the lottery table.

In the above 1st to 6th embodiments, when the game is played with 1 or 2 medals, and if the watermelon prize or the bell prize, which are normal small role prizes, are established, the number of medals to be paid out is 3 each. Although the case where the medals are paid out is described, the present invention is not limited to this, and other medals may be set to be paid out. In this case, a different number of medals may be set depending on the number of watermelon winning medals paid out and the number of bell winning medals paid out. In addition, the number of medals to be paid out for watermelon winning or bell winning when one or two medals are hung is configured to be larger than the maximum number of bets (3 in the above first to sixth embodiments). May be good. As a result, when the game is played with one or two medals, the player can be made to play the game while expecting the establishment of a watermelon prize or a bell prize in which many medals are paid out. Further, a multiple of the maximum number of bets (3 in the above 1st to 6th embodiments) may be set as the number of medals to be paid out for watermelon winning or bell winning when one or two medals are hung. .. As a result, if a watermelon prize or a bell prize is established, then it is expected that a large number of medals will be paid out by the establishment of the BB prize. Can be consumed, so the player can enjoy the game to the end without leaving any extra medals. Further, as the number of medals to be paid out for watermelon winning or bell winning when one or two medals are hung, 12 or 6 medals may be set as in the case of three medals. As a result, it is not necessary to change the number of medals to be paid out according to the number of bets, so that an increase in processing load can be suppressed. Further, the number of watermelon winning medals to be paid out may be set to a different number depending on whether the number of medals is one or two. Similarly, the number of medals for one or two may be different. Depending on the case, the number of bell winning medals to be paid out may be set to a different number. Further, the number of medals to be paid out at least one of the watermelon prize and the bell prize at the time of hanging one may be set to two. As a result, the player can enjoy another game while expecting to win the Cherry Bell prize by inserting the two medals and paying out three more medals. In addition, the winning probability of each winning mode is set by the lottery table so that the ratio of the expected value of the number of medals to be paid out in one game to the number of medals inserted in one or two medals is less than 100%. desirable. Further, the ratio is more preferably less than 100% and close to 100%.

In the above 1st to 6th embodiments, the case where the game is played with one or two medals and three medals are paid out when the cherry bell prize is established has been described. However, the number of medals to be paid out is not necessarily limited to this, and a multiple (for example, 6 or 9) of the maximum number of bets (3 in the above 1st to 6th embodiments) is set as the number of medals to be paid out. It may be configured as. Even with this, if the Cherry Bell prize is established, the medals can be consumed simply by playing a game (a game with 3 cards) with the maximum number of bets that can be expected with a high probability that the BB prize will be established. You can enjoy the game to the end without leaving any extra medals. On the other hand, the number of medals to be paid out may be set to 2 when the cherry bell prize is established when one piece is hung. As a result, the player can enjoy another game while expecting to win the Cherry Bell prize by inserting the two medals and paying out three more medals, without leaving any extra medals. You can enjoy the game until the end. In these cases as well, it is desirable to set the winning probability of each winning mode by the lottery table so that the ratio of the expected value of the number of medals paid out in one game to the number of medals inserted is less than 100%. Further, the ratio is more preferably less than 100% and close to 100%.

In the above 1st to 6th embodiments, a case has been described in which a game is played with one card and two medals are paid out when a 7-bell prize is established, but this is not necessarily the case. The number of medals to be paid out in this case is not limited, and may be set to be equal to or greater than the maximum number of bets, or a multiple of the maximum number of bets (3 in the first to sixth embodiments). (For example, 3 sheets, 6 sheets, 9 sheets, etc.) may be set. If the multiple of the maximum bet number is set, a game with the maximum number of bets that can be expected to pay out a large number of medals if the 7 bell prize is established and then the BB prize is established (3). Since the medals can be consumed just by playing the game (game by hanging), the player can enjoy the game to the end without leaving any extra medals. Also in this case, it is desirable that the winning probability of each winning mode is set by the lottery table so that the ratio of the expected value of the number of medals paid out in one game to the number of medals inserted is less than 100%. Further, the ratio is more preferably less than 100% and close to 100%.

In the above 1st to 6th embodiments, when the game is played with one medal, the winners of the cherry bell prize and the 7 bell prize are drawn by lottery, and if the cherry bell prize is established, three medals are drawn. The case where the medals are paid out and the 7-bell prize is established is configured so that the two medals are paid out, but this is not necessarily the case, and the cherry-bell prize is established. May be configured so that two medals are paid out and three medals are paid out when a 7-bell prize is established. As a result, if the Cherry Bell prize is established, two medals will be paid out, so the player is expected to insert the two medals and pay out three more medals. However, you can enjoy another game, and you can enjoy the game to the end without leaving any extra medals. In addition, if the 7-bell prize is established, three medals will be paid out, so the player can insert the three medals and play another game while expecting the BB prize to be established. You can enjoy the game to the end without leaving any extra medals. On the other hand, when the game is played with one piece, only the cherry bell winning may be determined. As a result, regardless of whether the number of bets is 1 to 3, the winning combination of 7 bells is not included, so that the index value IV = 5 can be omitted from the lottery table, and the lottery for storing the lottery table can be omitted. The storage capacity of the table storage area 105a can be reduced, and the processing load of the lottery process can be reduced. Further, in this case, if the number of medals to be paid out when the cherry bell prize is established is set to 3, the player inserts the three medals to be paid out when the cherry bell prize is established, and the player is able to insert the three medals. Furthermore, while expecting the establishment of the BB prize, another game can be played, and the game can be enjoyed to the end without leaving any extra medals. In addition, if the number of medals to be paid out when the cherry bell prize is established is set to 2, the player inserts two medals to be paid out when the cherry bell prize is established, and the player has three more medals. You can enjoy another game while expecting the cherry bell prize to be paid out, and you can enjoy the game to the end without leaving any extra medals. In these cases as well, it is desirable to set the winning probability of each winning mode by the lottery table so that the ratio of the expected value of the number of medals paid out in one game to the number of medals inserted is less than 100%. Further, the ratio is more preferably less than 100% and close to 100%. For example, if the 7-bell prize is not included as a special child actor prize in one piece, and only the cherry-bell prize is supported, and the number of medals to be paid out in the cherry-bell prize is set to 3, the winning probability is about 3. It may be set to 1/6, or when the number of medals to be paid out in the cherry bell winning is set to 2, the winning probability may be set to about 1 / 2.4.

In the above 1st to 6th embodiments, in the lottery table, any one of BB prize, watermelon prize, bell prize, cherry bell prize, 7 bell prize and replay prize is assigned as the prize mode corresponding to the index value IV. , In the lottery of the winning mode, the case where any one of these winning modes is set as the winning combination has been described, but the present invention is not necessarily limited to this, and these winning modes are for one index value IV. When a plurality of winning modes are assigned and the winning is confirmed at the one index value IV, the plurality of winning modes assigned to the one index value IV may be set at the same time as the winning combination. For example, by assigning a BB prize and a bell prize to one index value IV, the BB prize and the bell prize may be set at the same time as a winning combination, or a watermelon prize and a replay prize may be set to one index value IV. By assigning, the watermelon prize and the replay prize may be set as the winning combination at the same time. Here, if the BB winning that is carried over to the next game when the winning is not established and another winning mode that is not carried over to the next game (for example, a bell winning) are set as winning combinations at the same time, the next game is entered. The sliding table corresponding to another winning mode (bell winning) that cannot be carried over may be preferentially stored in the sliding table storage area 106b. As a result, it is possible to establish the winning establishment in the other winning modes, and the BB winning can be carried over to the next game to establish the winning establishment. In addition, if a watermelon prize and a replay prize are set as winners at the same time, prepare a slide table that is specified so that either the watermelon prize or the replay prize stops on the valid line, and use this as the slide table. It may be stored in the storage area 106b. As this slip table, it is possible to stop the stop symbol corresponding to the watermelon prize, which is more advantageous to the player than the replay prize, from the arrival symbol that has reached the base point position when the stop switches 42 to 44 are operated. In that case, the stop mode is specified so that it stops at the stop symbol corresponding to the watermelon prize, and if the stop symbol corresponding to the watermelon prize cannot be stopped, it stops at the stop symbol corresponding to the replay prize. It is preferable to use the one whose aspect is specified. As a result, the watermelon prize, which is more advantageous to the player than the replay prize, can be established as much as possible, and if the watermelon prize cannot be established, the replay prize can be established. Then, in this case, the player can be made to play again without inserting a medal.

In the first to sixth embodiments described above, when a game is played with one card and a 7-bell prize is established and two medals are paid out, the gaming state of the slot machine 10 remains the general gaming state. However, when the game is played with one medals and a 7-bell prize is established and two medals are paid out, the gaming state of the slot machine 10 may be shifted to the special gaming state when two medals are hung. Then, in the case of shifting to the special gaming state when two cards are hung, even if the lottery table is configured so that the winning probability of the cherry bell winning mode when two cards are hung is set higher than that in the general gaming state. good. As a result, if two medals are paid out due to the establishment of a seven-bell prize when one is hung, the player inserts the two medals and is strong in the establishment of the cherry-bell prize in which three medals are paid out. You can enjoy another game even more while having a sense of expectation.

In the first to sixth embodiments described above, when the game is in a general gaming state, the specified number of bets for medals is set to 1 to 3 and can be used for 1-card, 2-card, or 3-card. Correspondingly, the case where the game is configured to start the game has been described, but the present invention is not limited to this, and the specified number of bets for medals is set to 1 and 3, and the number of medals is set to 1 and 3. It may be configured to start the game only for three cards. As a result, if two medals remain in the player's hand, the player is expected to pay out three medals by winning the Cherry Bell prize, and the remaining medals are inserted one by one. You can entertain at least two games in total.

In addition, the specified number of bets for medals is set to 1 to 3 not only in the general game state but also in the bonus state, and it corresponds to any of 1-card, 2-card, and 3-card. And may be configured to start the game. Alternatively, even in the case of a bonus state, the specified number of bets on medals may be set to 1 and 3, and the game may be started corresponding to 1 and 3 medals. .. If the game is played with one or two cards in the bonus state, the winning probability of the cherry bell winning and the 7 bell winning is set low, or the lottery table is configured so that the winning probability is zero. May be good. Further, the lottery table may be configured so that the winning probability of the watermelon winning or the bell winning in the one-sheet and two-sheet hanging is higher than the winning probability in the general gaming state. Further, the number of watermelon winning or bell winning medals paid out in the one-sheet and two-sheet hanging may be set to be larger than the number of medals paid out in the general gaming state (3 medals). However, the winning probability of each winning mode and the number of medals to be paid out are such that the expected value of the number of medals to be paid out per game in the one-card and two-cards in the bonus state is smaller than the expected value in the three-cards. May be configured to be set. As a result, the player can be made to play the bonus game with three cards as much as possible. Further, the winning probability and the number of medals to be paid out corresponding to each winning mode when the game is played with one or two medals in the bonus state may be set to be the same as in the general gaming state. In this case, the ratio of the expected value of the number of medals to be paid out per game to the number of bets is less than 100% for both one and two medals, so if the game is repeated with one or two medals, the number of medals On the contrary, it decreases. Therefore, it is possible to make the player play a bonus game with three cards.

In the above 1st to 6th embodiments, not only the remaining number of medals in the player's hand but also the case where the game can be played by one or two medals in a general gaming state will be described. However, the present invention is not necessarily limited to this, and only when the number of virtual medals stored and stored by the credit function is less than three, the first to sixth embodiments may be carried out by one-card and two-card medals. The game may be configured to be played according to the winning mode, the winning probability, and the number of medals paid out. For example, in the process of S205 of the normal process (see FIG. 16), when determining whether or not the number of bets is a specified number, the value of the credit counter that counts the number of virtual medals is confirmed, and the value is 3. In the above case, by setting the specified number of bets to 3, the game can be played only by multiplying 3 cards, and if the value of the credit counter is less than 3, the specified number of bets is set to 1 and By setting the number of cards to two, the game may be played with the winning mode, the winning probability, and the number of medals paid out according to the first to sixth embodiments. As a result, when there are three or more virtual medals, the game can always be played only with three medals, so that the medals are consumed quickly and the operating rate of the slot machine in the hall can be surely increased. .. On the other hand, if the number of virtual medals is less than 3, the one or two medals will be used to win the Cherry Bell prize, in which three medals are paid out, or the Seven Bell prize, in which two medals are paid out. Since the player can be aimed at playing the game, the slot machine 10 can motivate the player to use up all the medals.

In the first to sixth embodiments, the winning mode, winning probability, and medal payout of the game performed by one-card and two-card medals are not limited to the remaining number of medals in the player's hand. Although the case where the number of sheets is configured to be fixed has been described, the present invention is not limited to this. For example, in the process of S206 in the normal process (FIG. 16), when it is determined that there is a start command, the value of the credit counter immediately before the start command (that is, the number of virtual medals) is temporarily held in the RAM 106. When setting a one-card lottery table (see S406) or a two-card lottery table (see S405) in the lottery table setting process (see FIG. 18), or in the reel control process (see FIG. 19), a payout determination is made. When the processing (see S513) is performed and the number of virtual medals immediately before the temporarily stored start command is 3 or more, the medal is paid out per game with 1 or 2 medals. The winning mode, winning probability, and number of medals to be paid out are set so that the expected value of the number of medals is smaller than the expected value obtained by the winning mode, winning probability, and the number of medals to be paid out as shown in FIGS. 7 and 9. It may be configured. In this case, the expected value may be reduced by setting the winning probability of the cherry bell winning or the 7 bell winning when the game is played with one or two cards low. As a result, when there are three or more virtual medals, it is possible to play the game with three medals under much more advantageous conditions than when playing the game with one or two medals. The player will play the game with three cards, and the medals will be consumed quickly. Therefore, it is possible to surely increase the operating rate of the slot machine in the hall. On the other hand, when the number of virtual medals immediately before the start command temporarily stored is less than 3, the winning mode shown in FIGS. 7 and 9 is used for a game played with one or two medals. , The winning probability and the number of medals to be paid out may be set. As a result, if the number of virtual medals is less than 3, the one or two medals will be used to win the Cherry Bell prize, in which three medals are paid out, or the Seven Bell prize, in which two medals are paid out. Since the player can be made to play the game aiming at, the slot machine 10 can give the player the motivation to use up all the medals.

Further, in addition to the above two modified examples, or separately from the above two modified examples, when the number of virtual medals stored and stored by the credit function is two, the number of virtual medals stored and stored by the credit function is two. The game may not be played based on the winning mode, winning probability, and number of medals paid out as shown in 9. In this case, the game may be configured so that the game with one card is not played at all, or the expected value of the number of medals to be paid out per game with one card is the winning mode shown in FIGS. 7 and 9. The winning mode, the winning probability, and the number of medals to be paid out may be set so as to be smaller than the expected value obtained by the winning probability and the number of medals to be paid out. In the former case, in the process of S205 of the normal process (see FIG. 16), when determining whether or not the number of bets is the specified number, the value of the credit counter that counts the number of virtual medals is confirmed, and the value thereof. If is 2, the specified number of bets may be set to 2, so that the game with one bet cannot be played. Further, in the latter case, when it is determined that there is a start command in the process of S206 in the normal process (FIG. 16), the value of the credit counter immediately before the start command (that is, the number of virtual medals) is temporarily stored in the RAM 106. In the case of setting the lottery table (see S406) at the time of hanging one medal in the lottery table setting process (see FIG. 18), or performing the payout determination process (see S513) in the reel control process (see FIG. 19). In that case, when the number of virtual medals immediately before the temporarily stored start command is two, the expected value of the number of medals to be paid out per game per game is shown in FIGS. 7 and 9. The winning mode, winning probability, and number of medals to be paid out may be set so as to be smaller than the expected value obtained by the indicated winning mode, winning probability, and number of medals to be paid out. As a result, if only two virtual medals remain, the player can play the game with two medals. Therefore, it is possible to decide whether or not three medals will be paid out in one game.

In the first to sixth embodiments described above, even if the game is played with one or two cards when the BB winning flag is carried over, the game is won with the one or two cards. Although the case where the mode and the winning probability are configured to be the same as the case where the BB winning winning flag is not carried over is described, the present invention is not necessarily limited to this. For example, when setting the one-card lottery table (see S406) or the two-card lottery table (see S405) in the lottery table setting process (see FIG. 18), the winning flag storage area 106a is carried over from the previous game. If the BB winning winning flag is set, the lottery table may be set so that the probability of losing is high. As a result, if the result of the lottery is out of order, only the BB winning winning flag carried over is set in the winning flag storage area 106a, so that the slip table setting executed by S310 of the lottery process (see FIG. 17) is set. In the process, the slip table corresponding to the BB winning can be stored. Therefore, it is possible to increase the probability that the BB prize will be established.

In the first to sixth embodiments, the case where the information regarding the number of bets is included in the start command and transmitted from the main control device 101 to the display control device 81 has been described, but the present invention is not limited to this, and the start command and the start command are used. May transmit information about the number of bets from the main control device 101 to the display control device 81 by another command. For example, the information regarding the number of bets may be transmitted by a dedicated command (hereinafter, referred to as "bet number notification command"), or may be included in the lottery result command and transmitted. When the bet number notification command is prepared, the command received from the main control device 101 is stored in the command buffer areas 185a, 191a, 192a in the main process executed by the MPU181 of the display control device 81, and the command is stored. If the bet number notification command is used, the bet number notification command processing is executed, the bet number notification command processing extracts information on the bet number included in the bet number notification command, and the extracted bet number information is bet. It may be stored in the number storage areas 185b, 191b, 192b. When the lottery result command includes information on the number of bets, the information on the number of bets is extracted from the lottery result command before the processing of S761 is performed in the lottery result command processing, and the bet number storage areas 185b, 191b, It may be stored in 192b. When the information regarding the number of bets is transmitted from the main control device 101 to the display control device 81 by a command different from the start command and the lottery result command, the timing of transmitting the command is the lottery result command after the start command is transmitted. It is preferable that it is before the transmission of. As a result, in the display control device 81, based on the number of bets placed on the game started by the operation of the start lever 41 and the result of the lottery performed for the game, the auxiliary effect unit (upper lamp 63, The mode of various effects performed by the speaker 64 and the auxiliary display unit 65) can be determined, and the player can play the game with various expectations by the effects of the auxiliary effect unit.

In the first to sixth embodiments, the winning combination notified by the lottery result command when the number of bets is one or two in the lottery result command processing executed by the MPU181 of the display control device 81 is BB. If there are multiple winning combinations including the winning mode, the auxiliary production unit (upper lamp 63, speaker 64, auxiliary) is given priority to start the BB winning combination notification effect that announces that the BB winning mode is the winning combination. The case of controlling the display unit 65) has been described (see S763 and S764 in FIG. 26), but when the winning combination notified by the lottery result command is the BB winning mode and the watermelon winning mode, the BB winning mode is used. The auxiliary production unit may be controlled to start the "BB winning / watermelon winning notification effect" that announces that the two modes, the mode and the watermelon winning mode, are set as winning combinations. In addition, when the winning combination notified by the lottery result command is the BB winning mode and the bell winning mode, it is announced that the BB winning mode and the bell winning mode are set as the winning combination. You may control to start "BB prize / bell prize announcement production" in the auxiliary production unit. As a result, when the "BB winning / watermelon winning notification effect" or "BB winning / bell winning notification effect" is executed in the auxiliary production unit, the player can simultaneously perform the BB winning mode and the watermelon winning mode or the bell winning mode. It is possible to grasp that it is set as a winning combination. Therefore, for the game in which the notification effect is performed, the player can be directed to operate the stop switches 42 to 44 in order to establish the watermelon winning mode or the bell winning mode, and the BB winning mode can be performed in the subsequent games. It is possible to let the player continue the game with a sense of expectation that the above will be established.

In the first to sixth embodiments, the winning combination notified by the lottery result command when the number of bets is one or two in the lottery result command processing executed by the MPU181 of the display control device 81 is BB. In the case of the winning mode, the case of performing the BB winning notification effect of notifying that the BB winning mode is the winning combination has been described, but it is special as a candidate for the winning combination when the number of bets is one or two. When a plurality of types of state transition winning combinations that give a privilege to transition to the gaming state are provided, the winning combination notified by the lottery result command in the lottery result command processing executed by the MPU181 of the display control device 81 is provided. If it is determined that a predetermined state transition winning combination is included, an auxiliary effect unit (upper lamp 63, speaker 64, auxiliary display unit) announces that the predetermined state transition winning combination is a winning combination. It may be controlled to execute 65). It should be noted that the predetermined state transition winning combination for which the notification effect is performed may be a partial winning combination among a plurality of types of state transition winning combinations, or may be all winning combinations.

Further, in the first to sixth embodiments, in the lottery result command processing executed by the MPU181 of the display control device 81, the winning combination notified by the lottery result command when the number of bets is one or two. In the case of the watermelon winning mode or the bell winning mode, the case where the watermelon winning mode or the bell winning mode announcing that the winning combination is performed is performed, but the number of bets is 1. If there is another winning combination that may be missed depending on the operation timing of the player's stop switches 42 to 44 as a candidate for the winning combination when the number of cards is two or two, the display control device. In the lottery result command processing executed by the MPU 181 of 81, if it is determined that the winning combination notified by the lottery result command is a winning combination that may be missed, it is determined that the winning combination is the winning combination. The notification effect of notification may be controlled to be executed by the auxiliary effect unit (upper lamp 63, speaker 64, auxiliary display unit 65). If there are multiple prize-winning titles that may be missed, the notification effect may be executed only when some of the prize-winning titles become winners. On the other hand, when the winning combination is won, the announcement effect may be executed.

The stop symbol of each winning form in the first to sixth embodiments is an example, and is not limited to the stop symbol. However, it is desirable that the symbols that are not missed are set as the stop symbols for the cherry bell prize and the 7 bell prize.

The probability of winning each winning form in the first to sixth embodiments is an example, and is not limited to the winning probability. Further, the number of medals paid out for watermelon winning and bell winning in the first to sixth embodiments is an example, and is not limited to the number of medals paid out. However, it is desirable that the probability of winning the cherry bell winning or the 7 bell winning is set to be higher than that of other winning modes in the one-card or two-card hanging. In addition, the winning probability and the number of medals to be paid out for each winning mode are set so that the ratio of the expected value of the number of medals to be paid out to the number of bets is less than 100% and close to 100% in the case of one or two medals. It is desirable to do.

In the above 1st to 6th embodiments, a slot machine having 3 reels in parallel and 5 lines as effective lines has been described, but the present invention is not limited to this configuration, and for example, 5 reels are arranged in parallel. It may be a slot machine provided with the above, or a slot machine having three effective lines. Further, the valid line may be changed according to the number of bets. For example, if the number of bets is 3, the valid line is set to 5 lines, if the number of bets is 2, the valid line is set to 3 lines, and if the number of bets is 1, the valid line is set. May be set to one line. When setting the effective lines to 3 lines, for example, the upper line L1, the middle line L2, and the lower line L3 shown in FIG. 6 may be set, or the middle line L2 and the lower right line L4. The upper right line L5 may be set.

In the first to sixth embodiments described above, the case where the maximum number of bets is three has been described, but the present invention is not limited to this, and the maximum number of bets may be set to any value of two or more. .. For example, the maximum number of bets may be four. In this case, if the game is played with a bet number less than the maximum bet number, the winning probability of each winning mode should be set so that the winning mode in which the medal payout of the maximum bet number (or a multiple thereof) is won has a high probability. Just do it. In addition, if the maximum number of bets is four and the game is played with one medal, for example, the winning mode in which two medals are paid out is won with a high probability. If you set the probability and play the game with 2 medals, for example, set the winning probability of each winning mode in 2 medals so that the winning mode in which 3 medals are paid out will be won with high probability, and 3 medals. When the game is played by hanging, for example, the winning probability of each winning mode in the three medals may be set so that the winning mode in which four medals are paid out is won with a high probability. In this way, when the number of bets is small, the ratio of the expected value of the number of medals to be paid out to the number of bets is less than 100% by setting the number of medals to be paid out in the winning mode with a high probability to be small. Even when the winning probability is set, the winning probability of the winning mode can be increased. It is desirable to set the winning probability and the number of medals to be paid out in each winning mode so that the ratio of the expected value of the number of medals to be paid out to the number of bets is less than 100% and close to 100%.

In the seventh to twelfth embodiments, as the additional data table and the display data table, the drawing contents for adding and displaying the continuous advance notice effect which is not normally displayed in the variable effect to the third symbol display device 281 are defined. Although the case has been described, the present invention is not limited to this, and the additional data table or the display data table is added to one effect displayed by the display data table selected based on the command from the main controller 310. Drawing contents for drawing various effects to be displayed on the third symbol display device 281 may be defined. Further, in the additional data table or the display data table, in order to add and display an image that is not normally displayed for one effect displayed by the display data table selected based on the command from the main control device 310. Instead of defining the required drawing content, or in addition to defining such drawing content, the drawing content required to change a part or all of the color tone in the one production, or one. The drawing contents necessary for changing and displaying the image displayed in the effect of the above may be defined.

When the drawing contents necessary for changing the color tone of a part or all in one effect are specified by the additional data table or the display data table, the additional data table or the display data table is 1 in the third symbol display device 281. The type of sprite that changes the color tone in the time corresponding to the address expressed in units of the time (20 milliseconds in this embodiment) in which the image for the frame is displayed, and the type of sprite after the change in the sprite. It may specify the color information that specifies the color tone. Then, the MPU 431 is an additional data table set in the additional data table buffer 433e, an additional data table area of the synthetic data table set in the synthetic data table buffer 451d, or a display data table set in the display data table buffer 452d. When the type of sprite that changes the color tone to the address indicated by the pointers 433g, 451g, 452g and the color information that specifies the color tone after the change in the sprite are specified in the additional drawing contents specified in In the drawing content specified in the display data table set in the table buffer 433d, the display data table area of the composite data table set in the composite data table buffer 451d, or the display data table set in the display data table buffer 452d. The color information of the corresponding sprite type specified by the address indicated by the pointers 433g, 451g, and 452g is the color specified by the additional data table, the additional data table area of the composite data table, or the additional drawing content of the display data table. It may be replaced with information to create a drawing list. As a result, the image controller 437 can draw an image while changing the color tone of the sprite based on the color information defined by the additional data table.

In addition, when the drawing content required to change and display the image displayed in one effect is specified by the additional data table or display data table, the additional data table or display data table displays the third symbol. Corresponds to the address represented by the time (20 milliseconds in this embodiment) in which the image for one frame is displayed in the device 281 as one unit, and in that time, the sprite type to be replaced and the sprite type to be newly displayed are newly displayed. It may specify the sprite type to be output and the drawing information of the sprite to be newly displayed. Then, the MPU 431 is an additional data table set in the additional data table buffer 433e, an additional data table area of the synthetic data table set in the synthetic data table buffer 451d, or a display data table set in the display data table buffer 452d. In the additional drawing contents specified in, the sprite type to be replaced, the sprite type to be newly displayed, and the drawing information of the sprite to be newly displayed are specified at the addresses indicated by the pointers 433g, 451g, and 452g. If so, the display data table set in the display data table buffer 433d, the display data table area of the composite data table set in the composite data table buffer 451d, or the display data table set in the display data table buffer 452d. Of the various sprites specified at the addresses indicated by the pointers 433g, 451g, and 452g in the drawing content specified in the above, the sprite type to be newly displayed instead of the sprite to be replaced, and the drawing information of the sprite. May be included in the drawing list. As a result, the image controller 437 can draw an image including a sprite to be newly displayed.

In the seventh, eighth, tenth to twelfth embodiments described above, the case where the transfer data table is prepared corresponding to each display data table has been described, but in addition, the transfer data corresponding to each additional data table has been described. An additional transfer data table, which is a table, may be prepared. This additional transfer data table corresponds to the address specified in the additional data table (or display data table) and is used in the corresponding additional data table, and the sprite that should start the transfer at the time indicated by that address. Transfer data information of image data may be described.

In this case, for example, in the seventh, tenth to twelfth embodiments, an additional transfer data table buffer is provided in the work RAM 433 of the display control device 281, and one additional data table is set in the additional data table buffer 433e. In this case, in addition to the transfer data table corresponding to the display data table, the additional transfer data table corresponding to the one additional data table may be set in the additional transfer data table buffer. Then, if the transfer data information is described at the address indicated by the pointer 433g in the additional transfer data table set in the additional transfer data table buffer, the MPU 431 adds the transfer data information to the drawing list. You may do it. Further, in the eighth embodiment, when the synthetic data table is provided with the additional transfer data table area and the synthetic data table is generated from the display data table and the transfer data table, the Null data is stored in the additional transfer data table area. When the contents of the additional data table are added to the additional data table area of the synthetic data table after writing, the contents of the additional transfer data table corresponding to the additional data table are added to the synthetic data table together with the addition. It may be added to the transfer data table area. Then, if the transfer data information is described in the additional transfer data table area provided at the address indicated by the pointer 451g in the composite data table buffer set in the composite data table buffer 451d, the MPU 431 is the transfer data. Information may be added to the drawing list.

Thereby, the image controller 437 can transfer the image data of the sprite used by the additional data table to the normal video RAM 436 in advance before the image data is used according to the drawing list. Therefore, even if the character ROM 434,534,634,734 is configured by the NAND flash memory 434a, 534a, 634a, 734a having a slow read speed, the effect specified by the additional data table is easily and surely displayed. It can be displayed on the device 281. Further, by using the additional transfer data table corresponding to the additional data table, it is possible to transfer the necessary image data to the normal video RAM 436 while instructing the drawing of the image based on the additional data table. Additional data tables allow you to specify the drawing of many sprites. Therefore, even if the character ROM 434, 534, 634, 734 is configured by the NAND flash memory 434a, 534a, 634a, 734a having a slow read speed, various kinds of effects can be displayed on the third symbol display device 281.

Further, in the eighth embodiment, the case where the display data table includes the transfer data information of the image data necessary for drawing the image according to the drawing contents specified in the display data table has been described. Further, the transfer data information (additional transfer data information) of the image data required for drawing the image according to the additional drawing contents specified in the display data table may be included. In this case, the additional transfer data information is added for each address in association with the identification information (“additional effect 1”, “additional effect 2”, etc.) for identifying the effect that can be additionally displayed. It may be defined together with the drawing content or separately from the additional drawing content. Then, when the MPU 431 determines an effect to be additionally displayed, the MPU 431 creates a drawing list including additional drawing contents and additional transfer data information associated with the identification information corresponding to the determined effect. It may be configured in.

Thereby, in the image controller 437, the image data of the sprite used for drawing according to the additional drawing contents can be transferred to the normal video RAM 436 in advance before the image data is used according to the drawing list. Therefore, even if the character ROM 434 is configured by the NAND flash memory 434a having a slow read speed, the effect to be additionally displayed can be easily and surely displayed on the third symbol display device 281. Further, by using the additional transfer data information specified in the display data table, it is possible to transfer the necessary image data to the normal video RAM 436 while instructing the drawing of the image based on the additional drawing contents. The drawing of many sprites can be specified by the additional drawing contents. Therefore, even if the character ROM 434, 534, 634, 734 is configured by the NAND flash memory 434a, 534a, 634a, 734a having a slow read speed, various kinds of effects can be displayed on the third symbol display device 281.

In the seventh, eighth, tenth to twelfth embodiments described above, in the display table corresponding to the variation pattern that causes the player to select the super reach, the drawing contents corresponding to all the super reach that can be selected by the player are displayed. The case where only the drawing content corresponding to the super reach selected by the player is specified in the data table has been described, but it is not necessarily limited to this, and each super reach is additionally displayed. As a production, prepare an additional data table corresponding to each super reach, and set an additional data table corresponding to the super reach selected by the player in the additional data table buffer 433e, or add the additional data. The contents of the table may be added to the synthetic data table set in the synthetic data table buffer 451d. Further, the drawing contents corresponding to the selected super reach may be added to the display data table. Thereby, the drawing content of the super reach selected by the player can be easily specified. Further, since it is not necessary to specify the drawing contents corresponding to all the super reach in the display data table, it is possible to suppress the increase in the data size of the display data table.

In the ninth embodiment, the case where the display data table includes the drawing content, the transfer data information, and the additional drawing content has been described, but the present invention is not limited to this, and the display data table includes the drawing content. And the transfer data information are specified, and the additional drawing content of the effect to be additionally displayed may be specified in the additional data table as in the seventh embodiment. In this case, the work RAM 452 is provided with an additional data table buffer, and when an effect to be additionally displayed is determined as in the seventh embodiment, an additional data table corresponding to the effect is added to the additional data table buffer. You may set it. Further, even if the additional data table includes not only the additional drawing contents but also the transfer data information (additional transfer data information) of the image data necessary for drawing the image performed according to the additional drawing contents. good. As a result, it is possible to specify the drawing content of the effect to be added and displayed using the additional data table and the transfer data information of the image required for the drawing, so that the additional data table and the additional transfer data table can be used. Compared with the case of specifying the drawing content and the transferred data information, the load of processing required for the specification can be reduced.

In the seventh to twelfth embodiments described above, the case where the display control device 314 prepares the display data table for each variation pattern indicated by the variation pattern command for display has been described, but the present invention is not limited to this, and the variation is not necessarily limited to this. A display data table is prepared for each element such as "variable start-up", "high-speed fluctuation", "notice production", "normal reach", and "super reach", and the fluctuation shown in the display fluctuation pattern command is prepared. After specifying the elements required for the variation effect according to the pattern, the display data table corresponding to the paper required for the specified variation effect is put together into one, and the final periodic display corresponding to the variation pattern is displayed. A data table may be generated. In many cases, "variable start-up", "high-speed fluctuation", "normal reach", etc. are displayed in common with each fluctuation pattern. Therefore, by elementizing the variation effect in this way and preparing a display data table corresponding to each element, it is possible to efficiently have the data table.

In the seventh, tenth to twelfth embodiments described above, in the display data table, the additional data table, and the transfer data table, a common pointer 433 g is used, and the drawing content and the transfer data information are specified from the address indicated by the pointer 433 g. Although the case of doing so has been described, a pointer may be prepared for each data table.

In the seventh to twelfth embodiments, the image controller 437 sends a V interrupt signal to the MPU 431 at every display interval (every 20 milliseconds in the above embodiment) of an image for one frame at which the drawing process is completed. Although the case of transmission has been described, the image controller 437 may transmit this V interrupt signal to the MPU 431 every time the third symbol display device 281 is driven to display an image for one frame. good. Since the third symbol display device 281 is always driven so that the images for one frame are always displayed at equal time intervals (20 milliseconds intervals), the V interrupt signal is displayed for each display of the images for one frame. By sending, it is possible to keep the time interval accurate without timing.

In the seventh to twelfth embodiments, the image controller 437 specifies the frame buffer in which the drawn image should be expanded based on the drawing target buffer information transmitted from the MPU 431, and the other frame buffer comes first. The case where the expanded image information is read out and transmitted to the third symbol display device 281 has been described, but the present invention is not limited to this, and every time the image controller 437 receives the drawing list, the drawn image is displayed. Even if the frame buffers to be expanded are selected alternately, the previously expanded image information is read from the frame buffer different from the selected frame buffer and transmitted to the third symbol display device 281. good. Further, every time the image controller 437 transmits image information for one frame to the third symbol display device 281, the image information is output to the frame buffer for expanding the drawn image and the third symbol display device 281. It may be replaced with the frame buffer to be used.

In the seventh to twelfth embodiments, the synthetic data table generated after the definite display data table corresponding to the definite display effect is set in the display data table buffers 433d and 452d or based on the definite display data table. Is set in the composite data table buffer 451d, and by the time the final display effect is completed, the fluctuation pattern command (variation pattern command for display) and the demo command (display) are transmitted from the main control device 310 via the voice lamp control device 313. When none of the demo commands) are received, the case where the demo display data table corresponding to the demo effect is set in the display data table buffer 433d has been described, but this is confirmed again corresponding to the confirmed display effect. The display data table may be set in the display data table buffers 433d and 452d, or the synthetic data table generated based on the confirmed display data table may be set in the synthetic data table buffer 451d. Further, in this case, the definite display effect is displayed until either the fluctuation pattern command (variation pattern command for display) or the demo command (demo command for display) is received from the main control device 310 via the voice lamp control device 313. Each time it ends, the definite display data table corresponding to the definite display effect is reset to the display data table buffer 433d, or the synthetic data table generated based on the definite display data table is set to the synthetic data table buffer 451d. You may do so. As a result, the third symbol display device 281 can continue to display the definite display effect until the variation pattern command or the demo command is received from the main control device 310.

In the seventh to twelfth embodiments described above, the demonstration effect changes the rear image and stops and displays the third symbol consisting of the main symbols without the numbers "0" to "9". As described above, the present invention is not limited to this, and the third symbol consisting of the main symbol with a number or the main symbol without a number may be stopped and displayed in a semi-transparent state. Further, only the rear image may be changed without displaying the third symbol. Further, a character or a back image completely different from the third symbol or the back image used in the variable display may be displayed.

In the seventh to twelfth embodiments, in the display control means 314, after the power is turned on, the image data corresponding to the main image when the power is turned on and the variable image when the power is turned on is first transferred from the character ROM 434,534,634,734 to the resident video RAM 435. The main image area 435a at power-on and the variable image area 435b at power-on are transferred, and after the transfer is completed, the main image at power-on is displayed on the third symbol display device 281, and then the remaining image data to be resident is displayed. Although the case of transferring from the character ROM 434,534,634,734 to the resident video RAM 435 has been described, the present invention is not limited to this. For example, in the display control means 314, after the power is turned on, only the image data corresponding to the main image at power on is first transferred from the character ROM 434,534,634,734 to the main image area 435a at power on of the resident video RAM 435. After the transfer is completed, the main image at power-on is displayed on the third symbol display device 281, and then the image data to be resident including the image data corresponding to the variable image at power-on is resident from the character ROM 434,534,634,734. It may be transferred to the video RAM 435. As a result, the main image at the time of turning on the power can be displayed on the third symbol display device 281 earlier after the power is turned on. You can immediately confirm that the operation has started without any problem when the power is turned on.

Further, in this case, the MPU 431 may monitor the completion of transfer of the image data corresponding to the power-on variable image to the power-on variable image area 435b. As a result, if the display variation pattern command is received from the voice lamp control device 313 after the image data corresponding to the power-on variation image is stored in the power-on variation image area 435b, the display variation pattern command is received. Based on the above, a simple fluctuation display can be displayed on the third symbol display device 281 by using the image data corresponding to the power-on fluctuation image stored in the power-on fluctuation image area 435b. It is desirable that the image data corresponding to the power-on variation image is transferred to the power-on variation image area 435b immediately after the main image at power-on is displayed on the third symbol display device 281. As a result, it is possible to speed up the fluctuation display by the fluctuation image when the power is turned on.

In the seventh to twelfth embodiments, the display data table, the additional data table, the transfer data table, and the composite data table correspond to the time expressed in units of 20 milliseconds, and the image to be drawn at that time corresponds to the time. The case of defining the content (drawing content) and the information of the image data to be transferred at that time (transfer data information) has been described, but the present invention is not limited to this, and the display content is defined at each predetermined time interval. Anything that does. This predetermined time interval may be set according to the frame rate of the third symbol display device 281. For example, when the frame rate of the third symbol display device 281 is 30 fps, that is, when the third symbol display device 281 displays an image of 30 frames per second, the third symbol display device 281 is 1/30. Since one frame of image is displayed every second, the display data table may specify the display contents at 1/30 second intervals.

Further, in the display data table and the additional data table, the image data corresponding to the sprite type is stored instead of instructing the sprite type itself as the sprite type to be drawn specified at a predetermined time interval. It may specify the address of the character ROM 434,534,634,734. In the display control device 314, since the image data corresponding to the sprite type to be displayed on the third symbol display device 281 is read from the character ROM 434,534,634,734, the image data of the sprite type is associated with each sprite type. Manages the address of the character ROM 434,534,634,734 in which the character ROM is stored. Therefore, in the display data table, if the address of the character ROM 434, 534, 634, 734 in which the image data corresponding to the sprite type is stored is specified as the display content specified for each predetermined time interval, each sprite type is specified. Since it is not necessary to manage both the information for specifying the sprite and the address of the character ROM 434,534,634,734 in association with the above, the processing load can be reduced.

In the seventh to twelfth embodiments, the storage image discrimination flags 433j, 451j, 452j are provided in the work RAM 433, 451 and 452 of the display control device 314, and the corresponding image data is stored in the image of the normal video RAM 436 for each sprite. Although the case of storing whether or not the image is stored in the area 436a has been described, instead of this, the work RAM 433, 451 and 452 may store the information indicating the sprite type stored in the image storage area 436a. .. In this case, when the MPU 431 instructs to transfer the image data of a predetermined sprite type, the MPU 431 refers to the information indicating the sprite type stored in the image storage area 436a stored in the work RAM 433, 451 and 452, and the information thereof is referred to. It is determined whether or not the predetermined image data is already stored in the image storage area 436a, and if it is not stored, the transfer instruction of the image data of the predetermined sprite type may be set. Further, when the transfer instruction of the image data of a predetermined sprite type is set, the MPU 431 stores the information indicating the sprite type in which the transfer instruction is set in the work RAM 433, 451 and 452, and the image data of the sprite type. The information indicating the sprite type stored in the sub-area of the image storage area 436a in which the image is stored may be deleted.

In the seventh to twelfth embodiments, when the image data of a predetermined sprite type is transferred from the character ROM 434,534,634,734 to the normal video RAM 436, the stored image discrimination flags 433j, 451j, 452j are used. It is determined whether or not the image data of the sprite type is stored in the normal video RAM 437, and if the image data of the predetermined sprite type is stored in the normal video RAM 436, the transfer process is not executed. Although the case where the MPU 431 performs the processing is described, the image controller 437 may perform this processing. In this case, a flag equivalent to the stored image discrimination flags 433j, 451j, 452j is prepared in the work RAM provided in the image controller 437, and the corresponding image data is stored in the normal video RAM 436 for each sprite. You may remember whether or not you are there. Further, the work RAM provided in the image controller 437 may store the sprite type stored in the image storage area 436a of the normal video RAM 436. In this case, the MPU 431 is concerned with the storage state of the image data in the normal video RAM 436 if it is necessary to transfer the image data of a predetermined sprite type from the character ROM 434,534,634,734 to the normal video RAM 436. Instead, the transfer data information of the image data may be transmitted to the image controller 437.

In the seventh to twelfth embodiments described above, a case where only the image data corresponding to the “back surface A” among the plurality of back images is resident in the back image area 435c of the resident video RAM 435 has been described, but this is not always the case. Image data corresponding to two or more back images may be made resident in the back image area 435c of the resident video RAM 435. For example, the image data of the rear image used in some super reach may be resident in the rear image area 435c of the resident video RAM 435. In particular, by resident the rear image of the super reach that appears frequently or is expected to be high in the rear image area 435c of the resident video RAM 435, the transfer process of the image data from the character ROM 737 to the normal video RAM 536 is executed. It is possible to suppress the number of times.

In the seventh to twelfth embodiments, the transfer data table or the display data table defines a transfer command for image data in association with the addresses indicated by the pointers 433 g, 451 g, and 452 g, and the MPU 431 is defined by the display pointer. The case where the image controller 437 is controlled to transfer the image data instructed by the transfer command from the character ROM 434,534,634,734 to the normal video RAM 436 at a predetermined time is described, but it is not always limited to this. Information about the sprite type required in the display data table is described at the head of the display data table, and the MPU 431 is required image data based on the information described at the head of the display data table. The image controller 437 may be controlled to transfer data from the character ROMs 434, 534, 634, 734 to the normal video RAM 436. Alternatively, based on the command received from the voice lamp control device 313, the MPU 431 determines the sprite type to be displayed on the third symbol display device 281 in response to the command, and outputs the image data of the image type to the character ROM 434,534. , 634,734 may control the image controller 437 to transfer to the normal video RAM 436.

In the seventh to twelfth embodiments described above, the case where the color tone of a part of the image changes with time in the back surface C, which is the back image of the “island stage”, has been described, but the color tone of the entire image changes with time. It may be a thing. Further, as a rear image, not only an object that scrolls or changes in color tone with the passage of time, but also an object (for example, a person) that appears with the passage of time instead of such a rear image. It may be something that moves or changes.

In the seventh to twelfth embodiments described above, the case where the continuous advance notice effect is also executed by the third symbol display device 281 on which the variation effect is performed has been described, but the present invention is not necessarily limited to this, and the pachinko machine 200 is the third. By providing a fourth symbol display device separate from the symbol display device 281 and displaying the fourth symbol on the fourth symbol display device together with the variation effect executed by the third symbol display device 281, a continuous advance notice effect is produced. May be executed. In this case, the control of the fourth symbol display device may be performed by the display control device 314 or the voice lamp control device 313. Further, the pachinko machine 200 may be provided with an accessory that operates according to various effects, and the accessory may be operated in a predetermined manner together with the variable effect to execute the continuous advance notice effect. Further, the continuous advance notice effect may be executed by outputting the sound for the continuous advance notice effect from the audio output device 426 of the pachinko machine 200 under the control of the voice lamp control device 313, or the illumination unit of the pachinko machine 200 may be executed. A continuous advance notice effect may be executed by lighting or blinking 229 to 233 together with the variable effect.

As a result, every time the third symbol display device 281 (and the first symbol display device 237) performs a variation effect, the symbol is continuously displayed on the fourth symbol display device, or the accessory operates in a predetermined mode. However, the sound is output from the sound output device 426, or the illumination units 229 to 233 are lit or blinking, so that the player can have a feeling of expectation of a big hit. Further, the player usually keeps an eye on the third symbol display device 281 on which the variation effect is performed, and continues the game, but displays the symbol by the fourth symbol display device different from the third symbol display device 281. , The operation of the accessory, the voice output from the voice output device 426, or the lighting / blinking of the illumination units 229 to 233, the continuous warning effect is performed, so that the player is given an unusual effect. It can be easily recognized. In addition, continuous notice production can be easily performed with simple controls such as symbol display by the 4th symbol display device, operation of accessories, voice output from the voice output device 426, or lighting / blinking of the illumination units 229 to 233. It is possible to make a notice production.

Further, if the continuous notice effect is performed by the voice output from the voice output device 426 or the lighting or blinking of the lighting units 229 to 233, the continuous notice effect is controlled by the voice lamp control device 313, so that the start winning prize is obtained. The pachinko machine 200 continuously performs the hit / fail determination and the lottery process at the start of the fluctuation in the main control device 310, causes the voice lamp control device 313 to perform the continuous advance notice effect, and causes the display control device 314 to perform the variation effect. When performing the advance notice effect, each control device can share each process. Therefore, since it is possible to prevent the load from being concentrated on one control device, the performance required for the MPU of each control device can be suppressed to a low level.

It should be noted that the display of the symbol for the continuous advance notice effect in the third symbol display device 281, the display of the symbol for the continuous advance notice effect in the fourth symbol display device, the operation in a predetermined mode of the accessory, the voice from the voice output device 426. A continuous advance notice effect may be executed by combining at least two or more of the output and the lighting or blinking of the illumination units 229 to 233 and controlling each of them in conjunction with each other. This makes it possible to execute a wider variety of continuous notice effects. Further, a method of executing the continuous notice effect (display by the third symbol display device 281, display by the fourth symbol display device, operation of the accessory, voice output from the voice output device 426, lighting or blinking of the illumination units 229 to 233). Or, by changing the combination thereof), even if a plurality of continuous notice effect modes selected according to the game state (15R probability variation jackpot, 2R probability variation jackpot, time saving jackpot, loss) after the end of the continuous advance notice effect are prepared. good.

Further, in the seventh to twelfth embodiments described above, when the continuous advance notice effect is performed, the case where an image for the continuous advance notice effect different from the variable effect is displayed on the third symbol display device 281 has been described. The present invention is not necessarily limited to this, and the continuous advance notice effect may be performed by displaying a so-called "chance eye", which is a combination of predetermined symbols, as a stop symbol displayed when the variable effect is completed. .. In this case, in the continuous advance notice command processing (see FIG. 78) of the command determination processing executed by the MPU 421 of the display control device 313, the stop symbol discrimination flag corresponding to the chance eye is turned on, and other stop symbol discrimination is performed. You may want to set the flag off. In the command judgment processing, since the continuous advance notice command processing is executed after the stop identification command processing, the chance eye is set as the stop symbol instead of the stop symbol set by receiving the display stop identification command, so that the variable stop is performed. Sometimes the chance eye can be confirmed and displayed. Then, in the third symbol display device 281, if the chance eyes are continuously displayed as stop symbols for each variation effect, the player can be expected to finally obtain a big hit.

In the seventh to twelfth embodiments, the main control device 310 notifies the voice lamp control device of various counters (random number counter C1 per first, type counter C2 per first, stop pattern selection) acquired at the time of starting winning. The case where the information of the counter C3) is included in the reserved ball count command has been described, but the present invention is not limited to this, and various counters (first random counter C1, first) acquired at the time of starting winning by another command are used. The information of the hit type counter C2 and the stop pattern selection counter C3) may be notified to the voice lamp control device 313.

In the seventh to twelfth embodiments, the main control device 310 sends various counters (first random number counter C1, first hit type counter C2, stop pattern selection counter C3) acquired at the time of starting winning to the hold ball number command. After including the information of, the reserved ball number command is transmitted to the voice lamp control device 313, and the voice lamp control device 313 sets the hold ball number command according to the values of various counters included in the hold ball number command. Estimates the result of the lottery performed corresponding to the reserved ball held at the time of transmission and the stop type after the fluctuation effect, and based on the estimated result and the number of held balls held at that time, The case of deciding whether or not to perform continuous advance notice production has been described, but the present invention is not necessarily limited to this. For example, the main control device 310 estimates the result of the lottery corresponding to the start prize and the stop type after the fluctuation effect from the values of various counters acquired at the time of the start prize, and at least a part of the estimated result is the number of reserved balls. The voice lamp control device 313 may be notified by including it in the command, and the voice lamp control device 313 may decide whether or not to perform the continuous advance notice effect based on the notified estimation result. Further, whether or not the main control device 310 may perform continuous advance notice effect based on the result of the lottery corresponding to the start winning and the stop type after the variation effect, which is estimated from the values of various counters acquired at the time of the start winning. Whether or not at least the judgment result is included in the hold ball number command and notified to the voice lamp control device 313, and the voice lamp control device 313 finally performs a continuous advance notice effect based on the judgment result. May be determined. Further, the main control device 310 determines whether or not to perform the continuous advance notice effect, includes the determination result in the hold ball number command and notifies the voice lamp control device 313, and the voice lamp control device 313 performs the continuous notice effect. Only the production mode may be determined. As information to be included in the hold ball number command, information on the result of the lottery corresponding to the estimated start winning prize, information on the stop type after the fluctuation effect, information on whether or not continuous advance notice effect can be performed, or continuous advance notice effect is performed. By using the information as to whether or not, the command size of the reserved ball number command can be reduced as compared with the case where the values of various counters are included. In addition, the information on the result of the lottery corresponding to the estimated start winning prize, the information on the stop type after the fluctuation effect, the information on whether or not the continuous advance notice effect may be performed, or the information on whether or not the continuous advance notice effect is performed can be obtained. It may be transmitted from the main control device 310 to the voice lamp control device 313 by a command different from the hold ball number command.

In the seventh to twelfth embodiments, when a continuous notice command is transmitted from the voice lamp control device 313 to the display control device 314, the continuous notice image indicated by the continuous notice command in the display control device 314. The case where the transfer instruction is given to transfer the image data corresponding to the type from the character ROM 434, 534, 634, 734 to the normal video RAM 436 has been described, but the continuous notice image type indicated by the continuous notice command is the same production type. When the continuous advance notice effect is configured, the image data corresponding to the continuous advance notice image type indicated by the continuous notice command is once transferred from the character ROM 434,534,634,734 to the normal video RAM 436, and then continuously. It may be controlled so as not to be overwritten by other image data until the advance notice effect is completed. This makes it possible to suppress the repeated transfer of the same image data.

Further, when the continuous advance notice image type indicated by the continuous advance notice command constitutes a step-up type continuous advance notice effect, not only the image data corresponding to the continuous advance notice image type indicated by the continuous advance notice command but also the step. The image data corresponding to all the continuous advance notice image types used in the up-type continuous advance notice effect may be instructed to be transferred from the character ROM 434,534,634,734 to the normal video RAM 436. Further, also in this case, the image data corresponding to these continuous advance notice image types once transferred to the normal video RAM 436 is controlled so as not to be overwritten by other image data until the continuous advance notice effect is completed. May be good. Thereby, before the image data corresponding to the continuous advance notice image type is used by the continuous advance notice effect, the image data can be surely stored in the normal video RAM 436. In addition, it is possible to suppress the repeated transfer of the same image data.

Further, in the voice lamp control device 313, the execution of the continuous advance notice effect is determined by the continuous advance notice determination process (S2009) executed in the command determination process (see FIG. 71), and the continuous advance notice effect mode is determined. At this stage, a command for notifying the display control device 314 of the decision to execute the continuous notice effect and the mode of the continuous notice effect may be transmitted to the display control device 314. Then, in the display control device 314, upon receiving this command, the image data of the continuous notice image type used in the continuous notice mode is transferred from the character ROM 434,534,634,734 to the normal video RAM 436. Transmission instructions may be set. As a result, even before the variable effect in which the continuous advance notice effect is performed is started, the image data of the continuous advance notice image type used in the continuous advance notice mode is transferred from the character ROM 434,534,634,734 to the normal video RAM 436. Since it can be started, the image data can be reliably stored in the normal video RAM 436 before the image data corresponding to the continuous advance notice image type is used by the continuous notice effect.

Further, the display control device 314 may store the image data used in the continuous advance notice effect in a sub area dedicated to the continuous advance notice effect image provided in the image storage area 436a of the normal video RAM 436. As a result, it is possible to prevent the image data used in the continuous advance notice effect from being overwritten by other image data, so that the image data corresponding to the desired continuous advance notice image type is stored in the normal video RAM 436. The probability can be increased. Therefore, it is possible to prevent the image data used in the continuous advance notice effect from being repeatedly transferred.

Further, the continuous advance notice command transmitted from the display control device 314 may include a signal notifying that the variable effect is the last continuous advance notice effect for which the variation effect is set. As a result, the display control device 314 can recognize that the display of the continuous advance notice effect is the last, and therefore, while the continuous advance notice effect is being performed, it is stored in the normal video RAM 436 used in the continuous advance notice effect. When the control is performed so that the image data is not overwritten, the overwriting control can be easily canceled.

Further, in the seventh to twelfth embodiments, the case where the voice lamp control device 313 notifies the display control device 314 of the execution of the continuous notice effect and the continuous notice image type by the continuous notice command has been described. May be included in the display variation pattern command. That is, in the variation display process (see FIG. 72) executed by the voice lamp control device 313, when the variation pattern command for display is generated (S2104), it is determined whether or not to perform the continuous advance notice effect, and the sequence is continuous. When performing the advance notice effect, the information regarding the execution and the continuous advance notice image type may be included in the display variation pattern command. Then, in the display control device 314, when the received display variation pattern command includes information regarding the execution of the continuous advance notice effect and the continuous advance notice image type, the character ROM 434 of the image data corresponding to the continuous advance notice image type is included. In addition to instructing transfer from 534, 634, 734 to the normal video RAM 436, an additional data table corresponding to the continuous preview image type can be set in the additional data table buffer 433e, and the additional data table and the variation pattern for display can be set. A synthetic data table may be generated from the fluctuation data table corresponding to the fluctuation pattern indicated by the command and the transfer data table corresponding to the fluctuation data table, and set in the composite data table buffer 451d. Further, in the ninth embodiment, when the received display variation pattern command includes information regarding the implementation of the continuous advance notice effect and the continuous advance notice image type, the additional data flag corresponding to the continuous advance notice image type is turned on. By setting to, the additional drawing content of the effect corresponding to the continuous preview image type may be specified from the display data table corresponding to the fluctuation pattern indicated by the display fluctuation pattern command. As a result, the number of commands is reduced, so that the processing can be simplified.

Further, in the seventh, eighth, tenth to twelfth embodiments, when the display variation pattern command includes information regarding the implementation of the continuous advance notice effect and the continuous advance notice image type, the continuous advance notice image is used for each variation pattern. A non-compliant display data table and a display data table corresponding to each continuous advance notice image type are prepared, and the display control device 314 responds to the variation pattern indicated by the display variation pattern command and the continuous advance notice image type. The corresponding display data table may be set in the display data table buffer 433d. That is, the display data table may include both the drawing content corresponding to the variation pattern and the drawing content of the continuous advance notice effect corresponding to the continuous advance notice image type. In this case, it is not necessary to set an additional data table corresponding to the continuous notice type. Therefore, since the number of data tables to be set can be reduced, an increase in processing load can be suppressed. In this case, the transfer instruction of the image data corresponding to the continuous advance notice image type may be given in accordance with the reception of the display variation pattern command. As a result, it is sufficient to prepare one transfer data table for each fluctuation pattern, so that it is possible to suppress an increase in the data table.

In the seventh to twelfth embodiments described above, the stop symbol of the variable effect in which the continuous advance notice effect is performed is based on the stop symbol (front / rear disengagement reach, non-front / rear disengagement reach, complete disengagement reach) determined by the main control device 310. , The case where the setting is made by the voice lamp control device 313 has been described, but the present invention is not limited to this, and the last variation reserved when the voice lamp control device 313 determines to execute the continuous advance notice effect. If the stop symbol of the effect is not a big hit, the stop symbol of the last variable effect may be set by replacing it with the stop symbol of the front-back off reach mode instead of the stop symbol defined by the main control device 310. As a result, the stop symbol of the final variable effect in which the continuous advance notice effect is performed is not the stop symbol defined by the main control device 310, but always reaches the front and back, so that the player has a high expectation. be able to.

In the 7th to 12th embodiments, when the continuous advance notice effect is performed together with all the reserved variation effects, each variation effect is performed in an effect mode based on the lottery result performed at the start of each change. However, in this case, it may be configured to change the effect mode of the variation effect other than the last reserved variation effect to the out-of-order variation effect. Then, by the process of generating the display variation pattern command in the voice lamp control device 313 (see S2104 in FIG. 72), the variation pattern is changed according to the setting status of the continuous advance notice effect and the number of executions of the continuous advance notice effect. You may. If the stop symbol after the variation effect is a big hit, the effect mode of the variation effect is not updated, and the effect mode of the variation effect is displayed as it is based on the variation pattern determined by the main control device 310. You may. Here, even if the continuous advance notice effect is continuously performed, if the situation in which the jackpot does not appear as a result even though the corresponding variation effect mode is, for example, the super reach variation effect, the player's expectation However, the continuous advance notice effect is continuously performed, and the variable effect other than the last executed variable effect is continuously performed in the off-variable effect, so that the variable effect is executed last. It is possible to give the player a higher expectation for the variable production.

In the seventh to twelfth embodiments described above, the case where the continuous advance notice effect is always executed on the third symbol display device 281 when the execution of the continuous advance notice effect is determined has been described, but the present invention is not necessarily limited to this. For example, when the frame button 222 is pressed by the player in a situation where the execution of the continuous advance notice effect is determined, the continuous advance notice effect may be executed on the third symbol display device 281.

In the seventh to twelfth embodiments described above, a case where all symbols Z1 to Z3 are scrolled at a high speed to the extent that the player cannot see them is displayed when the variation effect is executed. However, the high-speed variation is described. Instead of displaying, all symbols Z1 to Z3 are reduced to an invisible degree and displayed, or all symbols Z1 to Z3 are displayed as a snow noise-like image in which a large number of white dots are randomly displayed. You may.

In the seventh to twelfth embodiments described above, the case where one first entry slot 264, in which a big hit lottery is started when a ball enters, is arranged in the game board 213 has been described, but this is not necessarily the case. The game board 213 may be provided with a plurality of (for example, two) first ball entrances in which the ball entry is independently detected and the jackpot lottery is started. In this case, when there is a hold at each first ball entry port, the hold ball number command transmitted by the main control device 310 to the voice lamp control device 313 indicates which first ball entry port is the hold. Information may be included. Further, even if the fluctuation pattern command transmitted by the main control device 310 to the voice lamp control device 313 when the fluctuation is started includes information indicating which fluctuation effect is held by the first ball entry port. good. As a result, in the voice lamp control device 313, a hold ball number counter is prepared for each first ball entry port, and when a hold ball number command is received, the first ball entry indicated in the hold ball number command is received. When the number of reserved balls is set in the reserved ball number counter for the mouth and the fluctuation pattern command is received, if the reserved ball number counter for the first entry port indicated in the fluctuation pattern command is decremented by 1, the first entry port The number of reserved balls can be counted for each.

Further, when a plurality of first ball entrances are provided, when the voice lamp control device 313 decides to start the continuous advance notice effect when the reserved ball number command is received, all the first ball entrances are made at that time. A continuous advance notice effect may be executed over the variable effect (reserved ball) held by the mouth. Further, in a pachinko machine in which a plurality of first ball entrances are provided and the variation effect held in one first entry port is preferentially executed, the variation effect is preferentially executed. The start of the continuous notice effect may be decided only when the ball is entered into the first entrance. As a result, the continuous advance notice effect is not started for the variable effect held at the first entrance with a low priority, so that the continuous advance notice effect is given to the variable effect held at the first entrance with a low priority. Is started, and when the variable effect is continuously suspended at the first entrance with high priority, it is possible to prevent the situation where the continuous advance notice effect does not end easily.

In the seventh to twelfth embodiments, when the voice lamp control device 313 receives the fluctuation pattern command transmitted from the main control device 310, the value of the hold ball number counter 423a is reduced by 1 (see S2105 in FIG. 72). However, it is not always limited to this. For example, in the variation processing executed by the MPU 401 of the main controller 310 (see FIG. 62), the number of reserved balls of the main controller 310 subtracted when the variation pattern command is set by the variation start processing (S1207). A hold ball number command is set so that the value (N) of the counter 403a is transmitted from the main control device 310 to the voice lamp control device 313 (see S1205 in FIG. 62), and the hold ball number command is a variation pattern. The command may be transmitted from the main control device 310 to the voice lamp control device 313 together with the transmission of the command. In this case, S2105 in FIG. 72 is omitted. When the value (N) of the subtracted number of reserved balls counter 403a of the main control device 310 is transmitted, the information indicating that the number of reserved balls is the number of reserved balls after the subtraction (that is, the start winning prize) is sent to the reserved ball number command. The reserved ball number command may be generated without including the values of various counters acquired with the start winning, including information indicating that the number of reserved balls is not added in accordance with the above. Then, since the determination as to whether or not to allow the continuous advance notice effect is performed when there is a start winning prize, the voice lamp control device 313 uses the reserved ball number command in the command determination process (see FIG. 71). When reception is detected, if the number of reserved balls indicated by the reserved ball number command is the number of reserved balls after subtraction, that is, if it is not the number of reserved balls added with the start winning, the continuous notice determination process. You may want to skip the execution of.

In the seventh to twelfth embodiments, when the voice lamp control device 313 determines to start the continuous advance notice effect when the reserved ball number command is received, all the variable effects held at that time are continuously performed. The case of executing the advance notice effect has been described, but the present invention is not limited to this, and when the start of the continuous advance notice effect is decided, it is further decided whether or not to execute the continuous advance notice effect in each variable effect. You may. As a result, the continuous advance notice effect may or may not appear for each variable effect, so that the player can have a sense of expectation for the appearance of the continuous advance notice effect, and the effect that does not make the player bored is performed. Can be done. In this case, it is updated every time the variation display process (see FIG. 72) is executed by the MPU 421 of the voice lamp control device 313, and a counter is provided for determining whether or not to execute the continuous advance notice effect in each variation effect. You may. Then, in the variable display processing, when the continuous advance notice effect is performed (S2107: Yes), the value of the counter for determining whether or not to execute the continuous advance notice effect in each variable effect is limited to a predetermined value. A continuous notice command may be set (S2108). Further, in this case, the number (range) of a predetermined value of the counter for setting the continuous advance notice effect execution for the corresponding variable effect may be changed according to the conditions. As this condition, for example, the value of the reserved ball number counter 423a when determining whether or not to start the continuous advance notice effect, the number of executions of the remaining continuous advance notice effect, the variation pattern of the variable effect for which the determination is made, and the series. The game state after the end of the continuous advance notice production (15R probability variation jackpot, 2R probability variation jackpot, time saving jackpot, miss), or a combination of two or more of these can be mentioned. As a result, the probability that the execution of the continuous advance notice effect is determined in each variable effect is changed according to the conditions, so that the player can pay attention to the appearance ratio of the continuous advance notice effect in each variable effect. ..

In the seventh to twelfth embodiments, each command is transmitted from the main control device 310 to the voice lamp control device 313, and the voice lamp control device 313 gives a display instruction to the display control device 314. Although configured, the command may be directly transmitted from the main control device 310 to the display control device 314. Further, a voice lamp control device may be connected to the display control device, and a command for instructing the output of each voice and lighting of the lamp may be transmitted from the display control device to the voice lamp control device. Further, the voice lamp control device and the display control device may be configured as one control device. When the voice lamp control device and the display control device are configured as one control device, the continuous warning command and the error occurrence command are replaced with the commands generated by the voice lamp control device 313 and notified to the display control device 314. Generates various flags such as flags and error occurrence flags, and displays display data table, transfer data table, additional data table and synthetic data table based on the flags. Data table buffers 433d, 452d, transfer data table buffer 433f, additional data. It may be set in the table buffer 433e or the composite data table buffer 451d, various image data such as a warning image may be generated, and a transfer instruction of necessary image data may be set.

In the seventh to twelfth embodiments described above, the winning of the first ball opening 264 and the passage of the second ball opening 267 are each suspended up to four times, but the maximum number of reserved balls is The number of times is not limited to 4, but may be set to 3 times or less, or 5 times or more (for example, 8 times). In addition, the number of reserved balls for variable display based on the winning of the first ball opening 264 is set by a number in a part of the third symbol display device 281, or the area divided into four is divided into four areas by the number of reserved balls. It may be displayed in a different mode (for example, a color or a lighting pattern), and a light emitting member such as a lamp is provided separately from the first symbol display device 237, and the light emitting member notifies the number of reserved balls. It may be configured as.

Further, as shown in the seventh to twelfth embodiments, the variable display, which is a kind of dynamic display, scrolls the symbol as identification information in the vertical direction on the display screen of the third symbol display device 281. The design is not limited to this, and the design may be moved and displayed along a predetermined route such as a vertical direction or an L-shape. Further, the dynamic display of the identification information is not limited to the variable display of the symbol, for example, one or a plurality of characters are displayed together with the symbol, or a wide variety of motion display or change display is performed separately from the symbol. It also includes the effect display. In this case, one or more characters are used as the third symbol.

In the first embodiment, in addition to one effect displayed by the display data table selected based on the command from the main control device 81, various effects to be displayed on the auxiliary display unit 65 are drawn. An additional data table as described in the seventh embodiment, in which drawing contents are defined, may be stored in the data table storage area 185d for each of the various effects. Then, as in the seventh embodiment, when an additional data table buffer is prepared in the work RAM 185 and an effect to be additionally displayed is determined for the display data table set in the display data table buffer 185f in the MPU 181. The additional data table corresponding to the determined effect is set in the additional data table buffer, the display data table set in the display data table buffer 185f, the transfer data table set in the transfer data table buffer 185 g, and the additional data table. A drawing list may be created from the additional data table set in the buffer, and the drawing list may be transmitted to the image controller 187. As a result, the image controller 187 adds the drawing contents specified by the additional data table, and draws an image for one frame. In this way, by simply setting the additional data table corresponding to the effect to be additionally displayed in the additional data table buffer, the additional display of the effect can be easily performed, so that there are various modes regardless of the processing capacity of the display control device 81. The effect image can be displayed on the auxiliary display unit 65. In the additional data table, the drawing contents required to add and display an image that is not normally displayed for one effect displayed by the display data table selected based on the command from the main control device 81. In place of or in addition to defining such drawing content, the drawing content required to change the color tone of part or all of the one effect, or the display in one effect. The drawing content required to change and display the image to be displayed may be the default one.

Further, also in the second embodiment, various effects to be displayed on the auxiliary display unit 65 are drawn in addition to one effect displayed by the display data table selected based on the command from the main control device 81. An additional data table as described in the seventh embodiment, in which drawing contents are defined, may be stored in the data table storage area 191d for each of the various effects. Then, as in the eighth embodiment, when the effect to be additionally displayed is determined for the display data table used to generate the synthetic data table set in the synthetic data table buffer 191f in the MPU 181 is determined. The contents of the additional data table corresponding to the effect are added to the additional data table area provided in the synthetic data table set in the synthetic data table buffer 191f, and the display data table area of the synthetic data table and the transfer data table are added. A drawing list may be created from the area and the additional data table area, and the drawing list may be transmitted to the image controller 187. As a result, the image controller 187 adds the drawing contents specified by the additional data table, and draws an image for one frame. In this way, the additional display of the effect can be easily performed by simply adding the additional data table corresponding to the effect to be additionally displayed to the composite data table, so that various effects can be produced regardless of the processing capacity of the display control device 81. The image can be displayed on the auxiliary display unit 65. It should be noted that this additional data table is also necessary for adding and displaying an image that is not normally displayed for one effect displayed by the display data table selected based on the command from the main control device 81. Instead of defining the drawing content, or in addition to defining such drawing content, the drawing content required to change the color tone of part or all of the one effect, or one effect. The drawing content required to change and display the image displayed in the above may be the default.

Further, in the third embodiment, various effects to be displayed on the auxiliary display unit 65 are drawn in addition to one effect displayed by the display data table selected based on the command from the main control device 81. A display data table as described in the ninth embodiment, in which additional drawing contents for the purpose are defined, may be stored in the data table storage area 192d. Then, as in the ninth embodiment, when the MPU 181 determines an effect to be additionally displayed for the display data table set in the display data table buffer 192f, the drawing contents and the transfer specified in the display data table are determined. In addition to the data information, a drawing list may be created from the additional drawing contents corresponding to the determined effect, and the drawing list may be transmitted to the image controller 187. As a result, the image controller 187 adds the additional drawing contents defined by the display data table, and draws an image for one frame. In this way, since the additional drawing content specified in the display data table can be easily used to additionally display the effect, various types of effect images can be displayed on the auxiliary display unit regardless of the processing capacity of the display control device 81. It can be displayed on 65. It should be noted that even in this additional drawing content, it is necessary to add and display an image that is not normally displayed for one effect displayed by the display data table selected based on the command from the main control device 81. Instead of defining the drawing content, or in addition to defining such drawing content, the drawing content required to change the color tone of part or all of the one effect, or one effect. The drawing content required to change and display the image displayed in the above may be the default.

The invention described in the fourth to sixth embodiments may be carried out in the second and third embodiments. That is, the character ROM 187 in the second and third embodiments is replaced with the character ROM 195 described in the fourth embodiment and the character ROM 196 described in the fifth embodiment to configure the display control device 81. May be good. Alternatively, the character ROM 187 in the second and third embodiments is replaced with the character ROM 197 described in the sixth embodiment, and the NOR type ROM 198 described in the sixth embodiment is connected to the internal bus to control the display. 81 may be configured.

Further, the invention described in the tenth to twelfth embodiments may be carried out in the eighth and ninth embodiments. That is, the character ROM 434 in the eighth and ninth embodiments is replaced with the character ROM 534 described in the tenth embodiment and the character ROM 634 described in the eleventh embodiment to configure the display control device 314. You may. Alternatively, the character ROM 434 in the eighth and ninth embodiments is replaced with the character ROM 734 described in the twelfth embodiment, and the NOR type ROM 735 described in the twelfth embodiment is connected to the bus line 440 for display control. The device 314 may be configured.

The present invention may be implemented in a slot machine of a type different from the so-called A type slot machine described in the first to sixth embodiments. For example, the present invention may be applied to any slot machine such as B type, C type, A type and C type composite type, B type and C type composite type, and a type equipped with a CT game. In any case, it is clear that the same action and effect as those of the above-mentioned first to sixth embodiments are obtained. Examples of the bonus winning in each of these types include BB winning, RB winning, SB winning, and CT winning.

Further, the present invention may be implemented in a pachinko machine or the like of a type different from the above 7th to 12th embodiments. For example, once a big hit is made, a pachinko machine (commonly known as a two-time right item or a three-time right item) that raises the expected value of the big hit until multiple (for example, two or three times) big hits occur. It may be carried out as). Further, after the jackpot symbol is displayed, it may be implemented as a pachinko machine that generates a special game that gives a player a predetermined game value on the condition that a ball is won in a predetermined area. Further, it may be carried out on a pachinko machine that has a winning device having a special area such as a V zone and is in a special gaming state on the condition that a ball is won in the special area. Further, in addition to the slot machine and the pachinko machine, it may be implemented as various gaming machines such as an ale-pachi, a sparrow ball, a so-called pachinko machine and a slot machine fused with the slot machine.

As a specific example of a gaming machine in which a pachinko machine and a slot machine are fused, a display device for displaying a variable display of a symbol sequence consisting of a plurality of symbols and then confirming the symbol is provided, and a handle for launching a ball is not provided. Things can be mentioned. In this case, after a predetermined amount of balls are thrown in based on a predetermined operation (button operation), the fluctuation of the symbol is started due to, for example, the operation of the operation lever, and for example, due to the operation of the stop switch or a predetermined amount. With the passage of time, the fluctuation of the symbol is stopped, and a special game is generated in which the player is given a predetermined game value on the condition that the confirmed symbol at the time of the stop is a so-called jackpot symbol. Is for paying out a large amount of balls to the lower saucer. If such a gaming machine is used instead of a slot machine, only the ball can be treated as a gaming value in the gaming hall, which is a gaming value seen in the current gaming hall where pachinko machines and slot machines coexist. It is possible to solve problems such as the burden on equipment and restrictions on the location of gaming machines due to the separate handling of medals and balls.

Hereinafter, in addition to the slot machine and the gaming machine of the present invention, the concepts of various inventions included in the above-described embodiments will be shown.

It includes a main control means that performs the main control of the game, a sub-control means that operates based on a command transmitted from the main control means, and an image display means that displays an image based on the control by the sub-control means. The sub-control means is an image drawing means for drawing an image for one screen to be displayed on the image display means, and a command received from the main control means from a plurality of display modes. The first display determining means for determining the display type to be displayed and the drawing information provided for each of the plurality of display types and indicating the information necessary for drawing the image to be displayed in the display type are defined for each screen. The first selection of the first specified information storage means for storing the first specified information and the first specified information corresponding to the display type determined by the first display determining means from the first specified information storage means. Each time the means, the first pointer means updated every time, and the first pointer means are updated, the means is updated based on the first specified information selected by the first selection means. Based on the drawing information specifying means for specifying the drawing information for one screen corresponding to the first pointer means and the drawing information for the one screen specified by the drawing information specifying means, 1 for the image drawing means. A drawing instruction information generating means for generating drawing instruction information for instructing drawing of an image for a screen is provided, and the image drawing means has one screen based on the drawing instruction information generated by the drawing instruction information generating means. A slot machine 1 characterized by drawing a minute image.

According to the slot machine 1, in the sub-control means, the first defined information storage means is provided for each of a plurality of display types, and drawing information indicating information necessary for drawing an image to be displayed in the display type is 1 The first specified information specified for each screen is stored, and the first display type corresponding to the command received from the main control means determined from the plurality of display modes by the first display determining means. The specified information is selected from the first specified information storage means by the first selection means. Further, the first pointer means is updated every time the time elapses, and each time the update is performed, the first pointer means corresponding to the updated first pointer means is based on the first specified information selected by the first selection means. The drawing information for the screen is specified by the drawing information specifying means, and the drawing instruction information for instructing the image drawing means to draw the image for one screen is drawn based on the specified drawing information for one screen. It is generated by the instruction information generation means. Then, based on the drawing instruction information generated by the drawing instruction information generation means, an image for one screen is drawn by the drawing image means. As a result, when the display type to be displayed for the command received from the main control means changes, the display can be easily performed by simply selecting the first specified information corresponding to the display type from the first specified information storage means. Images according to the type can be generated and displayed on the image display means. Therefore, it is possible to easily diversify the display modes displayed on the image display means.

It is provided with a main control means that performs the main control of the game, a sub-control means that operates based on a command transmitted from the main control means, and an image display means that displays an image based on the control by the sub-control means. The sub-control means is a slot machine, and the sub-control means stores a program executed by the arithmetic processing means together with an arithmetic processing means and image information for displaying an image on the image display means, when the power is turned off. It also has a first storage means capable of holding information, and the arithmetic processing means is generated at the start of power supply and a pointer means for designating an address that specifies an instruction of a program to be executed by the arithmetic processing means. A pointer initialization that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first based on the reset signal receiving means that receives the reset signal and the reset signal received by the reset receiving means. The first storage means includes a first storage control means for controlling the operation of the first storage means, a first sub-storage means for storing the image information and the program, and a first sub-storage means thereof. It is possible to read out at a higher speed than the sub storage means, and it is a part or all of the predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means, and is a part or all of the predetermined program. A second sub-storage means for storing a program including the first instruction and a temporary storage means for temporarily storing a predetermined set of information read from the first sub-storage means or the second sub-storage means are provided. The first storage control means receives an address in which one of the information stored in the first sub-storage means and the second sub-storage means is stored, and an address receiving means thereof. By an information storage means for reading a predetermined set of information including information stored in a stored address from the first sub storage means or the second sub storage means and storing the information in the temporary storage means, and the information storage means thereof. The first storage control means includes the information output means for reading and outputting the information specified by the address received by the address receiving means from the information stored in the temporary storage means, and the first storage control means has the arithmetic processing. Prior to the fact that the pointer means specified an address specifying the first instruction of the predetermined program to be executed first by the initialization by the pointer initialization means of the means. When it is received by the address receiving means, a part or all of the predetermined program including the first instruction is read from the second sub storage means, and the read program is temporarily stored in the temporary storage means. The slot machine 2 is characterized in that it controls the information storage means as described above.

According to the slot machine 2, the sub-control means can hold the information even when the power is turned off to store the program executed by the arithmetic processing means together with the arithmetic processing means and the image information for displaying the image on the image display means. It has a first storage means. Further, the arithmetic processing means includes a pointer means for designating an address for specifying an instruction of a program to be executed by the arithmetic processing means, a reset signal receiving means for receiving a reset signal generated at the start of power supply, and a reset receiving means thereof. Based on the reset signal received by the means, the first storage means has a pointer initialization means that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first. A first storage control means for controlling the operation of the first storage means, a first sub storage means for storing image information and a program, and a read operation at a higher speed than the first sub storage means are possible, and arithmetic processing is possible. A second sub-storage means for storing a program that is a part or all of a predetermined program to be executed first based on the reception of the reset signal in the means and includes the first instruction of the predetermined program, and a first sub-storage. It has a temporary storage means for temporarily storing a predetermined set of information read from the means or the second sub storage means. Further, the first storage control means is received by an address receiving means that receives an address in which one of the information stored in the first sub storage means and the second sub storage means is stored, and an address receiving means thereof. An information storage means that reads a predetermined set of information including the information stored in the address from the first sub storage means or the second sub storage means and stores the information in the temporary storage means, and the information storage means in the temporary storage means. It has an information output means for reading and outputting information specified by an address received by the address receiving means from the stored information.

Here, the first storage control means receives an address that the pointer means specifies an address that specifies the first instruction of a predetermined program to be executed first by the initialization by the pointer initialization means of the arithmetic processing means. When accepted by the means, an information storage means is provided so as to read a part or all of a predetermined program including the first instruction from the second sub-storage means and temporarily store the read program in the temporary storage means. It is configured to control. Then, as described above, since the second sub-storage means can perform the read operation at a higher speed than the first sub-storage means, a predetermined program to be executed first by the initialization by the pointer initialization means of the arithmetic processing means. When the address that identifies the first instruction of is specified by the pointer means, a part or all of a predetermined program including the first instruction executed by the arithmetic processing means after receiving the reset signal is immediately stored in the temporary storage means. After storing it, it can be output to the arithmetic processing means. Therefore, even when the program is stored together with the image information in the first sub storage means having a slow reading speed, the program to be executed can be immediately read and the execution of the process can be started.

It includes a main control means that performs the main control of the game, a sub-control means that operates based on a command transmitted from the main control means, and an image display means that displays an image based on the control by the sub-control means. In the slot machine, the sub-control means stores a program executed by the arithmetic processing means together with an arithmetic processing means and image information for displaying an image on the image display means, when the power is turned off. It also has a first storage means capable of holding information, and the arithmetic processing means is generated at the start of power supply and a pointer means for designating an address that specifies an instruction of a program to be executed by the arithmetic processing means. A pointer initialization that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first based on the reset signal receiving means that receives the reset signal and the reset signal received by the reset receiving means. The first storage means includes a first storage control means for controlling the operation of the first storage means, a first sub-storage means for storing the image information and the program, and a first sub-storage means thereof. The first storage control means includes a temporary storage means for temporarily storing a predetermined set of information read from the sub storage means, and the first storage control means contains one piece of information stored in the first sub storage means. A predetermined set of information including the address receiving means for receiving the stored address and the information stored in the address received by the address receiving means is read from the first sub storage means and stored in the temporary storage means. The information storage means, the information output means for reading and outputting the information specified by the address received by the address receiving means from the information stored in the temporary storage means by the information storage means, and the power supply are started. The first storage control means is provided with a power supply detecting means for detecting that the power supply has been performed, and when it is detected that the power supply is started by the power supply detection, the first storage control means is used in the arithmetic processing means. A program including a part or all of the predetermined program to be executed first based on the reception of the reset signal and including the first instruction of the predetermined program is read from the first sub storage means and the program thereof is read out. The slot machine 3 is characterized in that the information storage means is controlled so that the read program is temporarily stored in the temporary storage means.

According to the slot machine 3, the sub-control means can hold the information even when the power is turned off to store the program executed by the arithmetic processing means together with the arithmetic processing means and the image information for displaying the image on the image display means. It has a first storage means. Further, the arithmetic processing means includes a pointer means for designating an address for specifying an instruction of a program to be executed by the arithmetic processing means, a reset signal receiving means for receiving a reset signal generated at the start of power supply, and a reset receiving means thereof. Based on the reset signal received by the means, the first storage means has a pointer initialization means that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first. A first storage control means for controlling the operation of the first storage means, a first sub storage means for storing image information and a program, and a predetermined set of information read from the first sub storage means are temporarily stored. It has a temporary storage means to be used. Further, the first storage control means is stored in an address receiving means that receives an address in which one of the information stored in the first sub storage means is stored, and an address received by the address receiving means. The address receiving means receives a predetermined set of information including information from the information storage means that reads out from the first sub storage means and stores it in the temporary storage means, and the information stored in the temporary storage means by the information storage means. It has an information output means for reading and outputting the information specified by the address, and a power supply detecting means for detecting that the power supply has been started.

Here, the first storage control means is a part of a predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means when it is detected that the power supply is started by the power supply detection. Or, the information storage means is controlled so as to read the program including the first instruction of the predetermined program from the first sub storage means and temporarily store the read program in the temporary storage means. It is configured as follows. As a result, when the pointer means is initialized by the pointer initialization means by receiving the reset signal, it is a part or all of a predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means. , Since the program including the first instruction of the predetermined program is already stored in the temporary storage means or is in the stage of being stored in the temporary storage means, it is initialized by the pointer initialization means of the arithmetic processing means. Specifies from the pointer means an address that identifies the first instruction of a given program to be executed first, a portion of the given program containing the first instruction executed by the arithmetic processing means after the reset signal is received. Alternatively, all of them can be immediately output from the temporary storage means to the arithmetic processing means. Therefore, even when the program is stored together with the image information in the first sub storage means having a slow reading speed, the program to be executed can be immediately read and the execution of the process can be started.

It includes a main control means that performs the main control of the game, a sub-control means that operates based on a command transmitted from the main control means, and an image display means that displays an image based on the control by the sub-control means. In the slot machine, the sub-control means stores a program executed by the arithmetic processing means together with an arithmetic processing means and image information for displaying an image on the image display means, when the power is turned off. It also has a first storage means capable of holding information, and the arithmetic processing means is generated at the start of power supply and a pointer means for designating an address that specifies an instruction of a program to be executed by the arithmetic processing means. A pointer initialization that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first based on the reset signal receiving means that receives the reset signal and the reset signal received by the reset receiving means. The first storage means includes a first storage control means for controlling the operation of the first storage means, a first sub-storage means for storing the image information and the program, and a first sub-storage means thereof. It is possible to read out at a higher speed than the sub storage means, and it is a part or all of the predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means, and is a part or all of the predetermined program. A second sub-storage means for storing a program including the first instruction and a temporary storage means for temporarily storing a predetermined set of information read from the first sub-storage means or the second sub-storage means are provided. The first storage control means receives an address in which one of the information stored in the first sub-storage means and the second sub-storage means is stored, and an address receiving means thereof. An information storage means for reading a predetermined set of information including information stored in a stored address from the first sub-storage means or the second sub-storage means and storing the information in the temporary storage means, and the information storage means thereof. An information output means for reading and outputting information specified by an address received by the address receiving means from the information stored in the temporary storage means, and a power supply detecting means for detecting that power supply has started. When the power supply detection detects that the power supply has been started, the first storage control means has the reset signal in the arithmetic processing means. A program that is a part or all of the predetermined program to be executed first based on the acceptance of the program and includes the first instruction of the predetermined program is read from the second sub storage means, and the read program is read. The slot machine 4 is characterized in that the information storage means is controlled so as to temporarily store the information in the temporary storage means.

According to the slot machine 4, the sub-control means can hold the information even when the power is turned off to store the program executed by the arithmetic processing means together with the arithmetic processing means and the image information for displaying the image on the image display means. It has a first storage means. Further, the arithmetic processing means includes a pointer means for designating an address for specifying an instruction of a program to be executed by the arithmetic processing means, a reset signal receiving means for receiving a reset signal generated at the start of power supply, and a reset receiving means thereof. Based on the reset signal received by the means, the first storage means has a pointer initialization means that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first. A first storage control means for controlling the operation of the first storage means, a first sub storage means for storing image information and a program, and a read operation at a higher speed than the first sub storage means are possible, and arithmetic processing is possible. A second sub-storage means for storing a program that is a part or all of a predetermined program to be executed first based on the reception of the reset signal in the means and includes the first instruction of the predetermined program, and a first sub-storage. It has a temporary storage means for temporarily storing a predetermined set of information read from the means or the second sub storage means. Further, the first storage control means is received by an address receiving means that receives an address in which one of the information stored in the first sub storage means and the second sub storage means is stored, and an address receiving means thereof. An information storage means that reads a predetermined set of information including the information stored in the address from the first sub storage means or the second sub storage means and stores the information in the temporary storage means, and the information storage means in the temporary storage means. It has an information output means for reading and outputting information specified by an address received by the address receiving means from the stored information, and a power supply detecting means for detecting that the power supply has started. ..

Here, the first storage control means is a part of a predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means when it is detected that the power supply is started by the power supply detection. Or, the information storage means is controlled so as to read the program including the first instruction of the predetermined program from the second sub storage means and temporarily store the read program in the temporary storage means. It is configured as follows. As described above, since the second sub storage means can perform a read operation at a higher speed than the first sub storage means, it is stored in the second sub storage means when the start of power supply is detected. If the program is read out and stored in the temporary storage means, when the pointer means is initialized by the pointer initialization means by receiving the reset signal, the arithmetic processing means should first execute the program based on the reception of the reset signal. A part or all of the program of the above, and the program including the first instruction of the predetermined program is already stored in the temporary storage means or is being stored in the temporary storage means. Therefore, when the pointer means specifies an address that specifies the first instruction of a predetermined program to be executed first by the initialization by the pointer initialization means of the arithmetic processing means, the arithmetic processing means executes it after receiving the reset signal. A part or all of a predetermined program including the first instruction to be executed can be immediately output from the temporary storage means to the arithmetic processing means. Therefore, even when the program is stored together with the image information in the first sub storage means having a slow reading speed, the program to be executed can be immediately read and the execution of the process can be started.

It is provided with a main control means that performs the main control of the game, a sub-control means that operates based on a command transmitted from the main control means, and an image display means that displays an image based on the control by the sub-control means. The sub-control means is a slot machine, and the sub-control means stores a program executed by the arithmetic processing means together with an arithmetic processing means and image information for displaying an image on the image display means, when the power is turned off. A first storage means capable of holding information, and a predetermined program that can be read out at a higher speed than the first storage means and is first executed by the arithmetic processing means, and is a predetermined program of the predetermined program. The arithmetic processing means includes a program storage means that stores a part or all of the predetermined program including the first instruction and can retain information even when the power is turned off, and the arithmetic processing means is a program to be executed by the arithmetic processing means. A predetermined pointer to be executed first based on a pointer means for designating an address specifying an instruction, a reset signal receiving means for receiving a reset signal generated at the start of power supply, and a reset signal received by the reset receiving means. A pointer initialization means for initializing the pointer means is provided at an address specifying the first instruction of the program, and the program storage means is a predetermined program first executed by the arithmetic processing means. When an address specifying an instruction included in a part or all of the predetermined program including the first instruction of the predetermined program is specified by the pointer means, the instruction specified by the address specified by the pointer means is specified. The slot machine 5 is characterized in that the program is read and output.

According to Slot Machinen 5, the sub-control means retains the information even when the power is turned off, which stores the program executed by the arithmetic processing means together with the arithmetic processing means and the image information for displaying the image on the image display means. A possible first storage means and a predetermined program that can be read out at a higher speed than the first storage means and is executed first by the arithmetic processing means, and includes the first instruction of the predetermined program. It has a program storage means that stores a part or all of a predetermined program and can retain information even when the power is turned off. Further, the arithmetic processing means includes a pointer means for designating an address for specifying an instruction of a program to be executed by the arithmetic processing means, a reset signal receiving means for receiving a reset signal generated at the start of power supply, and a reset receiving means thereof. It has a pointer initialization means that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first based on the reset signal received by the means.

Here, the program storage means is an address that is a predetermined program that is first executed by the arithmetic processing means and specifies an instruction included in a part or all of a predetermined program including the first instruction of the predetermined program. Is configured to read and output the instruction specified by the address specified by the pointer means when is specified by the pointer means. Then, as described above, the program storage means can perform a read operation at a higher speed than the first storage means, so that the predetermined program to be executed first is initialized by the pointer initialization means of the arithmetic processing means. When the address that identifies the first instruction is specified by the pointer means, a part or all of a predetermined program including the first instruction executed by the arithmetic processing means after receiving the reset signal is immediately read from the program storage means. It can be output to the arithmetic processing means. Therefore, even when the program is stored together with the image information in the first storage means having a slow reading speed, the program to be executed can be immediately read out and the execution of the process can be started.

It includes a main control means that performs the main control of the game, a sub-control means that operates based on a command transmitted from the main control means, and an image display means that displays an image based on the control by the sub-control means. The sub-control means is an image drawing means for drawing an image for one screen to be displayed on the image display means, and a command received from the main control means from a plurality of display modes. The first display determining means for determining the display type to be displayed and the drawing information provided for each of the plurality of display types and indicating the information necessary for drawing the image to be displayed in the display type are defined for each screen. The first selection of the first specified information storage means for storing the first specified information and the first specified information corresponding to the display type determined by the first display determining means from the first specified information storage means. Each time the means, the first pointer means updated every time, and the first pointer means are updated, the first pointer means is updated based on the first specified information selected by the first selection means. 1 for the image drawing means based on the drawing information specifying means for specifying the drawing information for one screen corresponding to the first pointer means and the drawing information for the one screen specified by the drawing information specifying means. The image drawing means includes a drawing instruction information generating means for generating drawing instruction information for instructing drawing of an image for a screen, and the image drawing means has one screen based on the drawing instruction information generated by the drawing instruction information generating means. A game machine A1 characterized in that it draws an image of a minute.

According to the gaming machine A1, in the sub-control means, the first defined information storage means is provided for each of a plurality of display types, and drawing information indicating information necessary for drawing an image to be displayed in the display type is 1 The first specified information specified for each screen is stored, and the first display type corresponding to the command received from the main control means determined from the plurality of display modes by the first display determining means. The specified information is selected from the first specified information storage means by the first selection means. Further, the first pointer means is updated every time the time elapses, and each time the update is performed, the first pointer means corresponding to the updated first pointer means is based on the first specified information selected by the first selection means. The drawing information for the screen is specified by the drawing information specifying means, and the drawing instruction information for instructing the image drawing means to draw the image for one screen is drawn based on the specified drawing information for one screen. It is generated by the instruction information generation means. Then, based on the drawing instruction information generated by the drawing instruction information generation means, an image for one screen is drawn by the drawing image means. As a result, when the display type to be displayed for the command received from the main control means changes, the display can be easily performed by simply selecting the first specified information corresponding to the display type from the first specified information storage means. Images according to the type can be generated and displayed on the image display means. Therefore, it is possible to easily diversify the display modes displayed on the image display means.

In the game machine A1, the sub-control means includes a first image information storage means for storing a plurality of image information used for drawing an image by the image drawing means, and is defined for each screen in the first specified information. The drawing information includes specific information for specifying image information necessary for drawing an image for one screen, and the drawing instruction information generating means is for one screen specified by the drawing information specifying means. Based on the drawing information of, the drawing instruction information including the image instruction information for instructing the image information necessary for drawing the image for one screen is generated from the specific information included in the drawing information, and the image drawing means , Based on the drawing instruction information generated by the drawing instruction information generation means, the image instruction information included in the drawing instruction information among the plurality of image information stored in the first image information storage means is instructed. The gaming machine A2 is characterized in that an image for one screen is drawn by using the image information obtained.

According to the gaming machine A2, in the sub-control means, the first image information storage means stores a plurality of image information used for drawing an image by the image drawing means. Further, the drawing information specified for each screen in the first specified information includes specific information for specifying the image information necessary for drawing the image for the one screen, and the drawing information specifying means is used. Based on the specified drawing information for one screen, the drawing instruction information including the image instruction information for instructing the image information necessary for drawing the image for the one screen is drawn from the specific information included in the drawing information. It is generated by the instruction information generation means. Then, based on the generated drawing instruction information, the image information designated by the image instruction information included in the drawing instruction information among the plurality of image information stored in the first image information storage means by the image drawing means. Is used to draw an image for one screen. As a result, various image types can be supported by simply specifying the image information necessary for drawing the image for one screen by the specific information included in the drawing information specified for each screen in the first specified information. An image can be drawn and displayed on the image display means. Therefore, it is possible to more easily diversify the display modes displayed on the image display means.

In the game machine A2, the sub-control means can read out at a higher speed than the first image storage means, stores the image information stored in the first image storage means, and stores the image information. The image drawing means is provided with a second image storage means capable of rewriting the image, and the image drawing means draws an image to be displayed on the image display means based on at least the image information stored in the second image storage means. When the sub-control means further uses one image information for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the first image information is used before the image information is used. The gaming machine A3 comprising a first transfer control means for controlling the transfer of the one image information from the image storage means to the second image storage means.

According to the game machine A3, the sub-control means can read out at a higher speed than the first image storage means, stores the image information stored in the first image storage means, and stores the stored image. A second image storage means capable of rewriting information is provided, and the image drawing means draws an image to be displayed on the image display means at least based on the image information stored in the second image storage means. It is configured. When one image information is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the one is controlled by the first transfer control means before the image information is used. The image information of is transferred from the first image storage means to the second image storage means. As a result, even if a memory having a slow reading speed is used for the first image storage means, the image drawing means uses at least predetermined image information transferred to the second storage means capable of high-speed reading operation to obtain an image. Since the image to be displayed on the display means is drawn, the image can be displayed at the desired time without any problem. Therefore, even if a memory having a slow reading speed is used as the first image storage means, various kinds of effects can be immediately displayed on the image display means.

In the game machine A3, the first transfer control means obtains the one image information before the one image information is used for drawing the image by the image drawing means according to the image instruction information included in the drawing instruction information. The transfer instruction information instructing the image drawing means to transfer from the first image storage means to the second image storage means is generated, and the sub-control means is generated by the drawing instruction information generation means. The image drawing means includes instruction information generating means for generating instruction information including the drawing instruction information and the transfer instruction information generated by the first transfer control means, and the image drawing means is generated by the instruction information generation means. An image for one screen is drawn based on the drawing instruction information included in the instruction information, and the first image storage means to the second image storage means based on the transfer instruction information included in the instruction information. A game machine A4 characterized in that one of them is for transferring image information.

According to the gaming machine A4, in the sub-control means, one image is used before one image information is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information by the first transfer control means. Transfer instruction information instructing the image drawing means to transfer the information from the first image storage means to the second image storage means is generated, and the drawing instruction information generated by the drawing instruction information generation means and the first transfer control means. Instruction information including the generated transfer instruction information is generated by the instruction information generation means. Then, the image drawing means draws an image for one screen based on the drawing instruction information included in the instruction information generated by the instruction information generation means, and at the same time, draws an image for one screen based on the transfer instruction information included in the instruction information. It is configured to transfer the one image information from one image storage means to a second image storage means. As a result, before one image information is used for drawing an image by the image drawing means based on the image instruction information included in the drawing instruction information, the image drawing means is instructed by the transfer instruction information included in the instruction information. Since the image information can be transferred from the first image storage means to the second image storage means, even if a memory having a slow read speed is used for the first image storage means, the image drawing means can be performed at high speed. It is possible to reliably draw an image to be displayed on the image display means by using at least predetermined image information transferred to the second storage means capable of reading operation.

In any of the gaming machines A1 to A4, the first specified information storage means stores the first specified information for each element in which the display mode of each display type is subdivided, and the sub-control means is the above-mentioned sub-control means. The element specifying means for specifying the element constituting the display mode of the display type determined by the first display determining means is provided, and the first selection means corresponds to the display type determined by the first display determining means. As the first specified information, the gaming machine A5 is characterized in that all the first specified information corresponding to the element specified by the element specifying means is selected from the first specified information storage means.

According to the gaming machine A5, the first specified information storage means stores the first specified information for each element in which the display mode of each display type is subdivided. Here, in the display mode of each display type, generally, many elements that are common to the images displayed in each are included, and the drawing information necessary for drawing the image to be displayed in the common elements is obtained. , It is not necessary to include it in the 1st regulation information corresponding to each display type, but it is sufficient to include it only in the 1st regulation information corresponding to the element, so that the 1st regulation information can be efficiently stored in the 1st regulation information storage means. Can be memorized. On the other hand, even if the first specified information is stored for each element, in the sub-control means, the element constituting the display mode of the display type determined by the first display determining means is specified by the element specifying means, and the first selection means. As the first specified information corresponding to the display type determined by the first display determining means, all the first specified information corresponding to the element specified by the element specifying means is selected from the first specified information storage means. .. As a result, it is only necessary to identify the element constituting the display mode of the display type determined for the command received from the main control means, and select the first specified information corresponding to the element from the first specified information storage means. , An image corresponding to the display type can be easily drawn and displayed on the image display means. Therefore, it is possible to easily diversify the display modes displayed on the image display means while efficiently storing the first specified information.

In any of the gaming machines A1 to A5, the display type includes a plurality of dynamic display effects that cause the image display means to dynamically display identification information in an effect mode set based on the command, and the gaming machine. Is to give a predetermined game value to the player when the predetermined identification information appears by the dynamic display effect, and the first specified information storage means is the first specified information. However, the gaming machine A6 is characterized in that it is stored for each of the plurality of dynamic display effects.

According to the gaming machine A6, a dynamic display effect for dynamically displaying identification information in an effect mode set based on a command is displayed on the image display means, and predetermined identification information appears by the dynamic display effect. If so, the player is given a predetermined game value. By this dynamic display effect, it is possible to give the player a sense of expectation that a predetermined game value is given, and by variously changing the effect mode of this dynamic display effect, it corresponds to the effect mode. It is possible to give the player a sense of expectation. Here, since the first specified information is stored in the first specified information storage means for each of a plurality of dynamic display effects, one effect mode for the image display means based on the command by the first display determining means. When it is decided to display the dynamic display effect of the above, the first selection means selects the first specified information corresponding to the dynamic display effect of the one effect mode from the first specified information storage means. As a result, in the dynamic display effect that gives the player various expectations, the first specified information corresponding to the dynamic display effect of one effect mode set based on the command is selected from the first specified information storage means. By simply doing so, an image corresponding to the effect mode can be easily drawn and displayed on the image display means. Therefore, since it is possible to easily diversify the dynamic display effect displayed on the image display means, it is possible to further improve the interest of the player by the dynamic display effect.

In any of the game machines A1 to A6, the sub-control means determines a second display type to be displayed for an image of the display type determined by the first display determination means from among a plurality of display modes. The second display determining means and the second specified information provided for each of the plurality of the second display types and defining the drawing information indicating the information necessary for drawing the image to be displayed in the second display type for each screen. The second specified information storage means for storing the image, and the second selection means for selecting the second specified information corresponding to the second display type determined by the second display determining means from the second specified information storage means. The drawing information specifying means is selected by the first selection means every time the first pointer means is updated. Based on the first specified information, drawing information for one screen corresponding to the updated first pointer means is specified, and updated based on the second specified information selected by the second selection means. The gaming machine B1 is characterized in that the drawing information required for the entire image is specified by specifying the drawing information of the image to be displayed on the one screen corresponding to the second pointer means.

According to the gaming machine B1, in the sub-control means, the second display type to be displayed for the image of the display type determined by the first display determination means is determined by the second display determination means from among the plurality of display modes. It is determined. Further, the second specified information storage means is provided for each of a plurality of second display types, and drawing information indicating information necessary for drawing an image to be displayed in the second display type is defined for each screen. 2 Regulation information is stored. Here, the second specified information corresponding to the second display type determined by the second display determining means is selected from the second specified information storage means by the second selection means. Further, the second pointer means is updated together with the update of the first pointer means. Then, every time the first pointer means is updated, the drawing information specifying means is for one screen corresponding to the updated first pointer means based on the first specified information selected by the first selection means. By specifying the drawing information and specifying the drawing information of the image to be displayed on one screen corresponding to the updated second pointer means based on the second regulation information selected by the second selection means. It is configured to specify the required drawing information for the entire image. As a result, when displaying the image of the second display type for the image of the display type for the command received from the main control means, the second specified information corresponding to the second display type is selected from the second specified information storage means. The image of the second display type can be easily displayed only by doing so. Therefore, it is possible to easily diversify the display modes displayed on the image display means.

In the gaming machine B1, the display type includes a plurality of dynamic display effects for dynamically displaying identification information on the image display means in an effect mode set based on the command, and the gaming machine is such a dynamic. When a predetermined identification information appears by the display effect, a predetermined game value is given to the player, and the sub-control means is the dynamic display effect displayed by the image display means. The second display determining means is provided with a waiting number storage means for storing the number of waiting times, and the second display determining means is used for the dynamic display effect in each of the dynamic display effects for the number of waiting times stored in the waiting number storage means. The gaming machine B2 is characterized in that it determines to display an image of the second display type.

According to the gaming machine B2, a dynamic display effect for dynamically displaying identification information in an effect mode set based on a command is displayed on the image display means, and predetermined identification information appears by the dynamic display effect. If so, the player is given a predetermined game value. By this dynamic display effect, it is possible to give the player a sense of expectation that a predetermined game value is given, and by variously changing the effect mode of this dynamic display effect, it corresponds to the effect mode. It is possible to give the player a sense of expectation. Further, in the sub-control means, the waiting number of the dynamic display effect displayed by the image display means is stored in the waiting number storage means, and the standby is stored in the waiting number storage means based on the command from the main control device. In each of the dynamic display effects for the number of times, it is determined by the second display determination means to display the image of the second display type for the dynamic display effect. As a result, the image of the second display type can be continuously displayed over a plurality of dynamic display effects. As a result, it is possible to give various expectations to the player who visually recognizes that the images of the second display type are continuously displayed. Then, even if the images of the second display type are continuously displayed for the dynamic display effect, the second regulation information corresponding to the second display type is specified by the configuration described in the gaming machine B1. The image of the second display type can be easily displayed for the dynamic display effect only by selecting from the information storage means. Therefore, it is possible to easily diversify the effects displayed on the image display means.

In the gaming machine B1 or B2, the second display determining means determines whether or not the image display means displays an image of the second display type, and the second selection means is the second display. When the determination means decides to hide the image of the second display type, the image of the display type determined by the first display determination means is displayed instead of the second specified information. The gaming machine B3, characterized in that information indicating that there is no image of the second display type to be output is selected.

According to the gaming machine B3, when it is decided to hide the image of the second display type by the second display determining means, the display type determined by the first display determining means is used instead of the second specified information. Information indicating that there is no second display type image to be displayed for the image of is selected by the second selection means. Thereby, every time the first pointer means is updated by the drawing information specifying means, it corresponds to the updated first pointer means specified based on the first specified information selected by the first selection means. With respect to the drawing information for one screen, the drawing information required for the entire image is specified without considering the drawing information related to the second display type. Therefore, even when the image of the second display type is displayed or hidden, the display / non-display of the image of the second display type can be easily switched. Therefore, it is possible to easily diversify the effects displayed on the image display means.

In any of the gaming machines B1 to B3, the second display determining means is selected by the first selection means every time the first pointer means is updated by the drawing information specifying means. When the drawing information for one screen corresponding to the updated first pointer means is specified based on the information, the display type determined by the first display determining means from among the plurality of display modes. The second display type to be displayed for the image is determined, and the drawing information specifying means displays the image of the display type determined by the first display determining means by the second display determining means. (2) When the display type is determined, each time the first pointer means is updated, the updated first pointer means corresponds to the updated first pointer means based on the first specified information selected by the first selection means. The drawing information for one screen is specified, and the image to be displayed on the one screen corresponding to the updated second pointer means based on the second specified information selected by the second selection means. A gaming machine B4 characterized in that drawing information required for the entire image is specified by specifying drawing information.

According to the gaming machine B4, every time the first pointer means is updated by the drawing information specifying means, the updated first pointer means is supported based on the first specified information selected by the first selection means. When the drawing information for one screen is specified, the second display type to be displayed for the image of the display type determined by the first display determination means is determined from the plurality of display modes. Determined by means. Then, when the second display determining means determines the second display type to be displayed for the image of the display type determined by the first display determining means, the drawing information specifying means updates the first pointer means. Each time, based on the first specified information selected by the first selection means, the drawing information for one screen corresponding to the updated first pointer means is specified, and the drawing information is selected by the second selection means. It is configured to specify the drawing information required for the entire image by specifying the drawing information of the image to be displayed on one screen corresponding to the updated second pointer means based on the second specified information. There is. As a result, if it is determined to display the image of the second display type even while the image of the display type is displayed for the command received from the main control means, the second display type is supported. By simply selecting the second specified information from the second specified information storage means, it is possible to easily display the image of the second display type with respect to the image of the display type that has already been displayed. Therefore, it is possible to easily diversify the effects displayed on the image display means.

In any of the gaming machines B1 to B4, the gaming machine B5 is characterized in that the first pointer means also serves as the second pointer means.

According to the gaming machine B5, since the first pointer means also serves as the second pointer means, the drawing information specifying means is the first rule selected by the first selection means every time the first pointer means is updated. Based on the information, the drawing information for one screen corresponding to the updated first pointer means is specified, and the first pointer means is supported based on the second specified information selected by the second selection means. By specifying the drawing information to be displayed on one screen, the drawing information required for the entire image can be specified, and only one pointer means can be used to easily display the entire image from each specified information. It is possible to specify the required drawing information.

In any of the gaming machines B1 to B5, the second specified information adds an image of the second display type corresponding to the second specified information to the image of the display type determined by the first display determining means. A gaming machine B6, characterized in that it contains drawing information for displaying.

According to the gaming machine B6, the second specified information is for displaying an image of the second display type corresponding to the second specified information in addition to the image of the display type determined by the first display determining means. Since the drawing information of the above is included, the image of the second display type can be added and displayed with respect to the display of the image of the display type for the command received from the main control means. Therefore, it is possible to more easily diversify the display modes displayed on the image display means.

In any of the gaming machines B1 to B6, the second specified information is an image of the second display type corresponding to the second specified information as a part of the image of the display type determined by the first display determining means. The gaming machine B7, which includes drawing information for displaying instead.

According to the gaming machine B7, the second specified information displays an image of the second display type corresponding to the second specified information in place of a part of the image of the display type determined by the first display determining means. Since the drawing information of the above is included, the image of the second display type can be displayed instead of the image of a part of the display type for the command received from the main control means. Therefore, it is possible to more easily diversify the display modes displayed on the image display means.

In any of the gaming machines B1 to B7, the second specified information is an image of a part of the display type determined by the first display determining means by the image of the second display type corresponding to the second specified information. The gaming machine B8, which includes drawing information for changing the color tone of the machine.

According to the gaming machine B8, the second specified information changes the color tone of a part of the image of the display type determined by the first display determining means by the image of the second display type corresponding to the second specified information. Since the drawing information for the purpose is included, the color tone of a part of the image of the display type for the command received from the main control means can be changed by the image of the second display type. Therefore, it is possible to more easily diversify the display modes displayed on the image display means.

In any of the game machines A1 to A6, the sub-control means determines a second display type to be displayed for an image of the display type determined by the first display determination means from a plurality of display modes. The second display determining means and the second specified information provided for each of the plurality of the second display types and defining the drawing information indicating the information necessary for drawing the image to be displayed in the second display type for each screen. The second specified information storage means for storing the image, and the second selection means for selecting the second specified information corresponding to the second display type determined by the second display determining means from the second specified information storage means. , The drawing information of the image to be displayed specified by the second specified information selected by the second selection means is added to the first specified information selected by the first selection means for each screen. The drawing information specifying means is provided with a first specified information generating means for generating new specified information, and the drawing information specifying means is newly generated by the first specified information generating means every time the first pointer means is updated. A gaming machine C1 characterized in that drawing information for one screen corresponding to the updated first pointer means is specified based on the specified information.

According to the gaming machine C1, in the sub-control means, the second display type to be displayed for the image of the display type determined by the first display determination means is determined by the second display determination means from among the plurality of display modes. It is determined. Further, the second specified information storage means is provided for each of a plurality of second display types, and drawing information indicating information necessary for drawing an image to be displayed in the second display type is defined for each screen. 2 Regulation information is stored. Here, the second specified information corresponding to the second display type determined by the second display determining means is selected from the second specified information storage means by the second selection means. Further, for the first specified information selected by the first selection means by the first specified information generation means, the drawing information of the image to be displayed specified by the second specified information selected by the second selection means is obtained. By adding each screen, new regulation information is generated. Then, every time the first pointer means is updated by the drawing information specifying means, one screen corresponding to the updated first pointer means is obtained based on the new specified information generated by the first specified information generating means. The drawing information for the minute is specified. As a result, when displaying the image of the second display type for the image of the display type for the command received from the main control means, the second specified information corresponding to the second display type is selected from the second specified information storage means. Then, the image of the second display type can be easily displayed. Therefore, it is possible to easily diversify the display modes displayed on the image display means.

In the gaming machine C1, the display type includes a plurality of dynamic display effects for dynamically displaying identification information on the image display means in an effect mode set based on the command, and the gaming machine is such a dynamic. When a predetermined identification information appears by the display effect, a predetermined game value is given to the player, and the sub-control means is the dynamic display effect displayed by the image display means. The second display determining means is provided with a waiting number storage means for storing the number of waiting times, and the second display determining means is used for the dynamic display effect in each of the dynamic display effects for the number of waiting times stored in the waiting number storage means. The gaming machine C2 is characterized in that it determines to display an image of the second display type.

According to the gaming machine C2, a dynamic display effect for dynamically displaying identification information in an effect mode set based on a command is displayed on the image display means, and predetermined identification information appears by the dynamic display effect. If so, the player is given a predetermined game value. By this dynamic display effect, it is possible to give the player a sense of expectation that a predetermined game value is given, and by variously changing the effect mode of this dynamic display effect, it corresponds to the effect mode. It is possible to give the player a sense of expectation. Further, in the sub-control means, the waiting number of the dynamic display effect displayed by the image display means is stored in the waiting number storage means, and the standby is stored in the waiting number storage means based on the command from the main control device. In each of the dynamic display effects for the number of times, it is determined by the second display determination means to display the image of the second display type for the dynamic display effect. As a result, the image of the second display type can be continuously displayed over a plurality of dynamic display effects. As a result, it is possible to give various expectations to the player who visually recognizes that the images of the second display type are continuously displayed. Then, even if the image of the second display type is continuously displayed for the dynamic display effect, the second regulation information corresponding to the second display type is specified by the configuration described in the gaming machine C1. The image of the second display type can be easily displayed for the dynamic display effect only by selecting from the information storage means. Therefore, it is possible to easily diversify the effects displayed on the image display means.

In the gaming machine C1 or C2, the second display determining means determines whether or not the image display means displays an image of the second display type, and the drawing information specifying means is the second display. When the determination means decides to hide the image of the second display type, it corresponds to the updated first pointer means based on the first specified information selected by the first selection means. A gaming machine C3 characterized in that it specifies drawing information for one screen.

According to the gaming machine C3, when the second display determining means decides to hide the image of the second display type, the drawing information specifying means is the first specified information selected by the first selection means. Based on this, it is configured to specify the drawing information for one screen corresponding to the updated first pointer means. Therefore, even when the image of the second display type is displayed or hidden, the display / non-display of the image of the second display type can be easily switched. Therefore, it is possible to easily diversify the effects displayed on the image display means.

In any of the gaming machines C1 to C3, the second display determining means is selected by the first selection means every time the first pointer means is updated by the drawing information specifying means. When the drawing information for one screen corresponding to the updated first pointer means is specified based on the information, the display type determined by the first display determining means from among the plurality of display modes. The second display type to be displayed for the image is determined, and the drawing information specifying means displays the image of the display type determined by the first display determining means by the second display determining means. 2 When the display type is determined, each time the first pointer means is updated, the updated first pointer means is supported based on the new specified information generated by the first specified information generating means. A gaming machine C4 characterized by specifying drawing information for one screen.

According to the gaming machine C4, every time the first pointer means is updated by the drawing information specifying means, the updated first pointer means is supported based on the first specified information selected by the first selection means. When the drawing information for one screen is specified, the second display type to be displayed for the image of the display type determined by the first display determination means is determined from the plurality of display modes. Determined by means. Then, when the second display determining means determines the second display type to be displayed for the image of the display type determined by the first display determining means, the drawing information specifying means updates the first pointer means. Each time, based on the new specified information generated by the first specified information generating means, the drawing information for one screen corresponding to the updated first pointer means is specified. As a result, if it is determined to display the image of the second display type even while the image of the display type is displayed for the command received from the main control means, the second display type is supported. By simply selecting the second specified information from the second specified information storage means, it is easy to display the image of the display type that has already been displayed based on the new specified information generated by the first specified information generating means. The image of the second display type can be displayed. Therefore, it is possible to easily diversify the effects displayed on the image display means.

In any of the gaming machines C1 to C4, the second specified information adds an image of the second display type corresponding to the second specified information to the image of the display type determined by the first display determining means. The gaming machine C5, characterized in that it contains drawing information for displaying.

According to the gaming machine C5, the second specified information is for displaying an image of the second display type corresponding to the second specified information in addition to the image of the display type determined by the first display determining means. Since the drawing information of the above is included, the image of the second display type can be added and displayed with respect to the display of the image of the display type for the command received from the main control means. Therefore, it is possible to more easily diversify the display modes displayed on the image display means.

In any of the gaming machines C1 to C5, the second specified information is an image of the second display type corresponding to the second specified information as a part of the image of the display type determined by the first display determining means. A gaming machine C6 characterized by including drawing information for displaying instead.

According to the gaming machine C6, the second specified information displays an image of the second display type corresponding to the second specified information in place of a part of the image of the display type determined by the first display determining means. Since the drawing information of the above is included, the image of the second display type can be displayed instead of the image of a part of the display type for the command received from the main control means. Therefore, it is possible to more easily diversify the display modes displayed on the image display means.

In any of the gaming machines C1 to C6, the second specified information is an image of a part of the display type determined by the first display determining means by the image of the second display type corresponding to the second specified information. The gaming machine C7, characterized in that it contains drawing information for changing the color tone of the machine.

According to the gaming machine C7, the second specified information changes the color tone of a part of the image of the display type determined by the first display determining means by the image of the second display type corresponding to the second specified information. Since the drawing information for the purpose is included, the color tone of a part of the image of the display type for the command received from the main control means can be changed by the image of the second display type. Therefore, it is possible to more easily diversify the display modes displayed on the image display means.

In any of the game machines A1 to A6, the sub-control means determines a second display type to be displayed for the display type determined by the first display determining means from among a plurality of display modes. The first specified information stored in the first specified information storage means is provided in the image of the display type in addition to the drawing information necessary for drawing the image of the corresponding display type. The drawing information necessary for drawing the image of the second display type to be displayed is defined for each screen, and the drawing information specifying means is described every time the first pointer means is updated. Based on the first specified information selected by the first selection means, the drawing information for one screen corresponding to the updated first pointer means is specified, and the second display determination means determines the drawing information. 2. The gaming machine D1 characterized in that the drawing information required for the entire image is specified by specifying the drawing information of the image to be displayed on the one screen corresponding to the display type.

According to the gaming machine D1, in the sub-control means, the second display type to be displayed for the image of the display type determined by the first display determination means is determined by the second display determination means from among the plurality of display modes. It is determined. Further, according to the first specified information stored in the first specified information storage means, in addition to the drawing information necessary for drawing the image of the corresponding display type, the second display type displayed for the image of the display type is displayed. The drawing information required for drawing the image is specified for each screen, and each time the first pointer means is updated by the drawing information specifying means, it is based on the first specified information selected by the first selection means. Then, the drawing information for one screen corresponding to the updated first pointer means is specified, and the drawing of the image to be displayed on one screen corresponding to the second display type determined by the second display determination means is specified. The information is specified and the drawing information required for the entire image is specified. As a result, when displaying the image of the second display type for the image of the display type for the command received from the main control means, the drawing information of the second display type to be displayed is specified from the selected first specified information. Then, the image of the second display type can be easily displayed. Therefore, it is possible to easily diversify the display modes displayed on the image display means.

In the gaming machine D1, the display type includes a plurality of dynamic display effects for dynamically displaying identification information on the image display means in an effect mode set based on the command, and the gaming machine is such a dynamic. When a predetermined identification information appears by the display effect, a predetermined game value is given to the player, and the sub-control means is the dynamic display effect displayed by the image display means. The second display determining means is provided with a waiting number storage means for storing the number of waiting times, and the second display determining means is used for the dynamic display effect in each of the dynamic display effects for the number of waiting times stored in the waiting number storage means. The gaming machine D2 is characterized in that it determines to display an image of the second display type.

According to the gaming machine D2, a dynamic display effect for dynamically displaying identification information in an effect mode set based on a command is displayed on the image display means, and predetermined identification information appears by the dynamic display effect. If so, the player is given a predetermined game value. By this dynamic display effect, it is possible to give the player a sense of expectation that a predetermined game value is given, and by variously changing the effect mode of this dynamic display effect, it corresponds to the effect mode. It is possible to give the player a sense of expectation. Further, in the sub-control means, the waiting number of the dynamic display effect displayed by the image display means is stored in the waiting number storage means, and the standby is stored in the waiting number storage means based on the command from the main control device. In each of the dynamic display effects for the number of times, it is determined by the second display determination means to display the image of the second display type for the dynamic display effect. As a result, the image of the second display type can be continuously displayed over a plurality of dynamic display effects. As a result, it is possible to give various expectations to the player who visually recognizes that the images of the second display type are continuously displayed. Then, even if the images of the second display type are continuously displayed for the dynamic display effect, the second regulation information corresponding to the second display type is specified by the configuration described in the gaming machine D1. The image of the second display type can be easily displayed for the dynamic display effect only by selecting from the information storage means. Therefore, it is possible to easily diversify the effects displayed on the image display means.

In the gaming machine D1 or D2, the second display determining means determines whether or not the image display means displays an image of the second display type, and the drawing information specifying means is the second display. When the determination means decides to hide the image of the second display type, it corresponds to the updated first pointer means based on the first specified information selected by the first selection means. The gaming machine D3 is characterized in that the drawing information for one screen is specified and the drawing information of the image of the second display type specified in the first specified information is not referred to.

According to the gaming machine D3, when the second display determining means decides to hide the image of the second display type, the drawing information specifying means is the first specified information selected by the first selection means. Based on this, the drawing information for one screen corresponding to the updated first pointer means is specified, and the drawing information of the image of the second display type specified in the first specified information is not referenced. Has been done. Therefore, even when the image of the second display type is displayed or hidden, the display / non-display of the image of the second display type can be easily switched. Therefore, it is possible to easily diversify the effects displayed on the image display means.

In any of the gaming machines D1 to D3, the second display determining means is selected by the first selection means every time the first pointer means is updated by the drawing information specifying means. Based on the information, the drawing information for one screen corresponding to the updated first pointer means is specified, and the drawing information of the image of the second display type specified in the first specified information is not referenced. The second display type to be displayed for the image of the display type determined by the first display determination means is determined from the plurality of display modes, and the drawing information specifying means is described as described above. When the second display type is determined by the second display determining means for the image of the display type determined by the first display determining means, the first pointer means is updated every time the first pointer means is updated. 1 Based on the first specified information selected by the selection means, the drawing information for one screen corresponding to the updated first pointer means is specified, and the second display determination means determines the drawing information. The gaming machine D4, characterized in that the drawing information required for the entire image is specified by specifying the drawing information of the image to be displayed on the one screen corresponding to the display type.

According to the gaming machine D4, every time the first pointer means is updated by the drawing information specifying means, the updated first pointer means is supported based on the first specified information selected by the first selection means. When the drawing information for one screen is specified and the drawing information of the image of the second display type specified in the first specified information is not referenced, the first of the plurality of display modes is selected. 1 The second display type to be displayed for the image of the display type determined by the display determination means is determined by the second display determination means. Then, when the second display determining means determines the second display type to be displayed for the image of the display type determined by the first display determining means, the drawing information specifying means updates the first pointer means. Each time, based on the first specified information selected by the first selection means, the drawing information for one screen corresponding to the updated first pointer means is specified, and the drawing information is determined by the second display determination means. It is configured to specify the drawing information of the image to be displayed on one screen corresponding to the second display type. As a result, if it is determined to display the image of the second display type even while the image of the display type is being displayed for the command received from the main control means, the first specified information is included. By specifying the drawing information of the image to be displayed on one screen corresponding to the two display types, it is possible to easily display the image of the second display type with respect to the image of the display type that has already been displayed. can. Therefore, it is possible to easily diversify the effects displayed on the image display means.

In any of the gaming machines D1 to D4, the first specified information is, in addition to the drawing information necessary for drawing the image of the corresponding display type, a plurality of second displays that can be displayed for the image of the display type. The drawing information required for drawing the type of image is defined for each screen for each second display type, and the drawing information specifying means is described every time the first pointer means is updated. Based on the first specified information selected by the first selection means, the drawing information for one screen corresponding to the updated first pointer means is specified, and the drawing information for one screen is specified, and the above is described from the plurality of second display types. It is characterized in that drawing information of an image to be displayed on the one screen corresponding to the second display type determined by the second display determining means is selected and specified, and drawing information required for the entire image is specified. Game machine D5.

According to the gaming machine D5, according to the first specified information, in addition to the drawing information necessary for drawing the image of the corresponding display type, a plurality of images of the second display type that can be displayed for the image of the display type are displayed. The drawing information required for drawing is defined for each screen for each second display type. Then, every time the first pointer means is updated by the drawing information specifying means, one screen corresponding to the updated first pointer means is obtained based on the first specified information selected by the first selection means. The drawing information is specified, and the drawing information of the image to be displayed on one screen corresponding to the second display type determined by the second display determination means is selected and specified from the plurality of second display types. The required drawing information is specified for the entire image. As a result, the drawing information of one second display type is selected and specified from the plurality of second display types by the first specified information selected for the image of the display type for the command received from the main control means. Therefore, it is possible to easily display an image of one second display type determined from a plurality of display modes. Therefore, it is possible to easily diversify the display modes displayed on the image display means.

In any of the gaming machines D1 to D5, the first specified information is a drawing for additionally displaying an image of the second display type with respect to an image of the display type determined by the first display determining means. A gaming machine D6 characterized by containing information.

According to the gaming machine D6, the first specified information includes drawing information for adding and displaying the image of the second display type to the image of the display type determined by the first display determining means. , An image of the second display type can be added and displayed to the display of the image of the display type for the command received from the main control means. Therefore, it is possible to more easily diversify the display modes displayed on the image display means.

In any of the gaming machines D1 to D6, the first specified information is a drawing for displaying the image of the second display type in place of a part of the image of the display type determined by the first display determining means. A gaming machine D7 characterized by containing information.

According to the gaming machine D7, the first specified information includes drawing information for displaying an image of the second display type in place of a part of the image of the display type determined by the first display determining means. , An image of the second display type can be displayed instead of a part of the image of the display type for the command received from the main control means. Therefore, it is possible to more easily diversify the display modes displayed on the image display means.

In any of the gaming machines D1 to D7, the first specified information is for changing the color tone of a part of the display type determined by the first display determining means by the image of the second display type. A gaming machine D8 characterized by containing drawing information.

According to the gaming machine D8, the first specified information includes drawing information for changing the color tone of a part of the image of the display type determined by the first display determining means by the image of the second display type. Therefore, the color tone of a part of the image of the display type for the command received from the main control means can be changed by the image of the second display type. Therefore, it is possible to more easily diversify the display modes displayed on the image display means.

In the game machine A3 or A4, the sub-control means can read out at a higher speed than the first image storage means, and the third image storage means for storing the image information stored in the first image storage means. The image drawing means draws an image to be displayed on the image display means based on at least the image information stored in the third image storage means and the image information stored in the second image storage means. Further, the sub-control means controls to transfer a part of the image information stored in the first image storage means to the third image storage means at the time of starting up by turning on the power. The third image storage means is provided with two transfer control means, and the image information transferred by the control of the second transfer control means is held by the third image storage means at least until a predetermined trigger is taken, and the first transfer control means When image information not held in the third image storage means is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the first image information is used before the image information is used. The gaming machine E1 is characterized in that it controls the transfer of the image information from the image storage means to the second image storage means.

According to the game machine E1, the sub-control means can read out at a higher speed than the first image storage means, and has a third image storage means for storing the image information stored in the first image storage means. The image drawing means is provided, and the image drawing means draws an image to be displayed on the image display means based on at least the image information stored in the third image storage means and the image information stored in the second image storage means. It is configured as follows. Here, a part of the image information stored in the first image storage means is transferred to the third image storage means under the control of the second transfer control means at the time of startup by turning on the power, and is transferred to the third image storage means. Holds the image information transferred by the control of the second transfer control means at least until a predetermined opportunity is reached. On the other hand, when the image information not held in the third image storage means is used for image control by the image drawing means according to the image instruction information included in the drawing instruction information, the first transfer control means is used before the image information is used. The image information is transferred from the first image storage means to the second image storage means by the control of.

As a result, even if a memory having a slow read speed of the first storage means is used, the image drawing means transfers the image information held in the third image storage means capable of high-speed reading operation to the second image storage means. Since the image to be displayed on the image display means is drawn using the obtained image information, the image can be displayed at a desired time without any problem. Further, since the image information held in the third image storage means is held until at least a predetermined opportunity is reached, the image information transferred from the first image storage means to the second image storage means should be reduced. Can be done. Therefore, it is possible to suppress the load applied to the transfer of image information from the first image storage means to the second image storage means. Therefore, since the image can be drawn by using more image information within the range where the load applied to the transfer can be tolerated, it is possible to further diversify the display modes displayed on the image display means. can.

In the game machine E1, the third image storage means stores a determination value for determining whether or not the image information stored in the third image storage means is normal information together with the image information. However, when the sub-control means is started up by turning on the power, the image information stored in the third image storage means is normal information based on the determination value stored in the third image storage means. When the image information determination means is provided with an image information determination means for determining whether or not the image information stored in the third image storage means is determined to be normal information, the second transfer control means is used. The gaming machine E2 is characterized in that the control of transferring a part of the image information stored in the first image storage means to the third image storage means is not executed.

According to the game machine E2, in the third image storage means, a determination value for determining whether or not the image information stored in the third image storage means is normal information is combined with the image information. Is remembered. Then, at the time of startup by turning on the power, the image information determination means determines whether the image information stored in the third image storage means is normal information based on the determination value stored in the third image storage means. When the determination is made and the image information stored in the third image storage means is determined to be normal information, a part of the image information stored in the first image storage means by the second transfer control means is the first. 3 The control to transfer to the image storage means is not executed. As a result, if normal image information is already stored in the third image storage means at the time of startup by turning on the power, the image information stored in the third image storage means is immediately used for the image. Since the image to be displayed on the display means can be drawn by the image drawing means, for example, when a momentary power failure occurs, the image can be immediately displayed on the image display means.

In the gaming machine E1 or E2, the image information held in the third image storage means is the image information for displaying an image frequently displayed by the image displaying means.

According to the game machine E3, image information for displaying an image frequently displayed by the image display means is held in the third image storage means, so that every time the image display means displays the image, the third image is displayed. Since it is not necessary to read the image information from the image storage means, the frequently displayed image can be surely displayed at a desired time.

In any of the game machines E1 to E3, the image information held in the third image storage means is the sub-control means based on a command transmitted from the main control means or a signal input to the sub-control means. The gaming machine E4 is characterized in that it is image information for displaying an image to be immediately displayed on the image display means by the control of the above.

The signal input to the sub-control means may be an input signal from various sensors such as a vibration sensor provided in the game machine and a game medium detection sensor for detecting the game medium input to the game machine. It may be an input signal from a button operated by the player. Further, the image to be immediately displayed by the image display means may be, for example, an image for notifying an error or a back image displayed by the image display means.

According to the gaming machine E4, an image for displaying an image to be immediately displayed by the image display means under the control of the sub control means based on a command transmitted from the main control means or a signal input to the sub control means. Since the information is held in the third image storage means, an image for displaying an image to be displayed immediately after a command transmitted from the main control means or a signal input to the sub control means is input. The image can be controlled by the image control means using the image information held in the third image storage means without reading the information from the first image storage means. Therefore, the image to be displayed immediately can be surely displayed at a desired time.

A gaming machine E4, wherein in any of the gaming machines A3, A4 and E1 to E4, the first image storage means is composed of a NAND flash memory.

According to the gaming machine E5, the first image storage means is configured by a NAND flash memory. Here, the NAND flash memory is characterized in that a large storage capacity can be obtained in a small area and is inexpensive. Therefore, the capacity of the first image storage means is increased while suppressing an increase in cost. be able to. Therefore, since a large amount of image information for displaying an image on the image display means can be stored in the first image storage means, it is possible to make various forms of images to be displayed on the image display means, and the interest of the player can be enhanced. Can be improved. On the other hand, the NAND flash memory is characterized in that the read speed is slower than that of other memories. However, according to the configuration described in any of the gaming machines A3, A4 and E1 to E4, the image drawing means can be used as an image drawing means. Since the image to be displayed on the image display means is drawn using the image information transferred to the second image storage means capable of reading at least at high speed, even if the first image storage means is configured by the NAND flash memory, the image is drawn. A predetermined image can be displayed at a desired time without any problem. Therefore, it is possible to display a predetermined image at a desired time without any problem while diversifying the images to be displayed on the image display means.

In any of the game machines A3, A4 and E1 to E5, the sub-control means corresponds to the first specified information, and among the image information necessary for drawing the image specified by the first specified information, the said The third specified information storage means that stores the third specified information that defines the image information to be transferred to the second image storage means, and the third specified information corresponding to the first specified information selected by the first selection means. Is specified by the third selection means selected from the third specified information storage means and the image information to be transferred to the second image storage means based on the third specified information selected by the third selection means. The first transfer control means includes transfer information specifying means, and the first transfer control means obtains the image information to be transferred specified by the transfer information specifying means, according to the image instruction information whose image information is included in the drawing instruction information. The gaming machine F1 is characterized in that it is controlled to be transferred from the first image storage means to the second image storage means before being used for drawing an image by the drawing means.

According to the game machine F1, in the sub-control means, among the image information necessary for drawing the image specified by the first specified information in correspondence with the first specified information, the image to be transferred to the second image storage means. The third specified information that defines the information is stored in the third specified information storage means. Here, by the third selection means, the third regulation information corresponding to the first regulation information selected by the first selection means is selected from the third regulation information storage means, and based on the selected third regulation information. , The image information to be transferred to the second image storage area is specified by the transfer information specifying means. Then, before the specified image information to be transferred by the first transfer control means is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the first image storage means is used. 2 Transferred to the image storage means. Thereby, with respect to the selected first specified information, among the image information necessary for drawing the image specified by the first specified information, the image information to be transferred to the second image storage means can be easily specified. Therefore, it is possible to reliably draw an image to be displayed based on the first specified information and display it on the image display means.

In any of the game machines E1 to E4, the sub-control means corresponds to the first specified information, and among the image information necessary for drawing the image specified by the first specified information, the third image storage. The third specified information storage means in which the third specified information defined as the image information to be transferred to the second image storage means is stored, and the first selected by the first selection means. 1 The second image storage based on the third selection means for selecting the third specified information corresponding to the specified information from the third specified information storage means and the third specified information selected by the third selection means. The first transfer control means includes transfer information specifying means for specifying image information to be transferred to the means, and the first transfer control means obtains image information to be transferred specified by the transfer information specifying means, and the image information is the drawing instruction information. The gaming machine F2 is characterized in that it is controlled to be transferred from the first image storage means to the second image storage means before being used for drawing an image by the image drawing means according to the image instruction information included in the image drawing means. ..

According to the game machine F2, among the image information necessary for drawing the image specified by the first specified information in the sub-control means in correspondence with the first specified information, the image not held in the third image storage means. The third specified information defined as the image information to be transferred to the second image storage means is stored in the third specified information storage means. Here, by the third selection means, the third regulation information corresponding to the first regulation information selected by the first selection means is selected from the third regulation information storage means, and based on the selected third regulation information. , The image information to be transferred to the second image storage area is specified by the transfer information specifying means. Then, before the specified image information to be transferred by the first transfer control means is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the first image storage means is used. 2 Transferred to the image storage means. As a result, with respect to the selected first specified information, among the image information necessary for drawing the image specified by the first specified information, the second image storage is not held by the third image storage means. Since the image information to be transferred to the means can be easily specified, the image to be displayed based on the first specified information can be reliably drawn and displayed on the image display means.

In the gaming machine F1 or F2, the sub-control means includes a third pointer means that is updated in conjunction with the update of the first pointer means, and the transfer information specifying means corresponds to the updated third pointer means. The gaming machine F3 is characterized in that the image information to be transferred to the second image storage means is specified based on the third specified information selected by the third selection means.

According to the gaming machine F3, the third pointer means is updated together with the update of the first pointer means, and is selected by the transfer information specifying means by the third selection means corresponding to the updated third pointer means. Based on the third regulation information, the image information to be transferred to the second image storage means is specified. As a result, the transfer of predetermined image information can be started from the first image storage area to the second image storage area in accordance with the update of the first pointer means, and the timing of the transfer can be easily set.

In the gaming machine F3, the third defined information defines image information to be transferred to the second image storage means at each unit time when an image for one screen is displayed on the image displaying means. A gaming machine F4 characterized by being a thing.

According to the game machine F4, the third defined information defines the image information to be transferred to the second image storage means every unit time. Therefore, the transfer information specifying means is the third pointer means. In accordance with the update (that is, the update of the first pointer means), the image information to be transferred to the second image storage area can be easily specified.

In any of the game machines F1 to F4, in the third specified information storage means, among the image information necessary for drawing the image specified by the first specified information, the image information to be transferred to the second image storage means is If it does not exist, the third specified information corresponding to the first specified information is not stored, and the transfer information specifying means includes the third specified information corresponding to the first specified information selected by the first specified means. When it is determined by the third selection means that the information is not stored in the third specified information storage means, it is characterized in that it specifies that the image information to be transferred to the second image storage area does not exist. The game machine F5.

According to the game machine F5, when the image information to be transferred to the second image storage means does not exist among the image information necessary for drawing the image specified by the first specified information, it corresponds to the first specified information. The third specified information is not stored in the third specified information storage means. Then, when the transfer image specifying means determines by the third selection means that the third specified information corresponding to the first specified information selected by the first specified means is not stored in the third specified information storage means. , It is specified that there is no image information to be transferred to the second image storage area. This makes it easy to determine whether or not there is image information to be transferred to the second image storage means among the image information necessary for drawing the image specified by the first specified information, depending on the presence or absence of the third specified information. Therefore, it is possible to reduce the processing. Further, since it is possible to suppress the storage of unnecessary third specified information in the third specified information storage means, it is possible to suppress an increase in the storage capacity of the storage means.

In any of the game machines A3, A4 and E1 to E5, the sub-control means displays a second display for an image of a display type determined by the first display determining means from among a plurality of display modes. A second display determining means for determining the type and drawing information provided for each of the plurality of the second display types and indicating information necessary for drawing an image to be displayed in the second display type are defined for each screen. A second specified information storage means for storing the second specified information and the second specified information corresponding to the second display type determined by the second display determining means are selected from the second specified information storage means. The drawing information specifying means includes a second selection means and a second pointer means that is updated in conjunction with the update of the first pointer means, and the drawing information specifying means is the first selection means every time the first pointer means is updated. Based on the first specified information selected by the above, the drawing information for one screen corresponding to the updated first pointer means is specified, and the second specified information selected by the second selection means is used. Based on this, by specifying the drawing information of the image to be displayed on the one screen corresponding to the updated second pointer means, the drawing information required for the entire image is specified, and the sub-control means further , The fourth image information to be transferred to the second image storage means among the image information necessary for drawing the image to be displayed specified by the second specified information in correspondence with the second specified information. A fourth specified information storage means in which the specified information is stored, and a fourth selection means for selecting the fourth specified information corresponding to the second specified information selected by the second selected means from the fourth specified information storage means. The first transfer control means includes transfer information specifying means for specifying image information to be transferred to the second image storage means based on the fourth specified information selected by the fourth selection means. The first image before the image information to be transferred specified by the transfer information specifying means is used in drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information. The gaming machine F6, characterized in that it is controlled to transfer from the storage means to the second image storage means.

According to the gaming machine F6, in the sub-control means, the second display type to be displayed for the image of the display type determined by the first display determination means is determined by the second display determination means from among the plurality of display modes. It is determined. Further, the second specified information storage means is provided for each of a plurality of second display types, and drawing information indicating information necessary for drawing an image to be displayed in the second display type is defined for each screen. 2 Regulation information is stored. Here, the second specified information corresponding to the second display type determined by the second display determining means is selected from the second specified information storage means by the second selection means. Further, the second pointer means is updated together with the update of the first pointer means. Then, every time the first pointer means is updated, the drawing information specifying means is for one screen corresponding to the updated first pointer means based on the first specified information selected by the first selection means. By specifying the drawing information and specifying the drawing information of the image to be displayed on one screen corresponding to the updated second pointer means based on the second regulation information selected by the second selection means. It is configured to specify the required drawing information for the entire image. As a result, when displaying the image of the second display type for the image of the display type for the command received from the main control means, the second specified information corresponding to the second display type is selected from the second specified information storage means. The image of the second display type can be easily displayed only by doing so. Therefore, it is possible to easily diversify the display modes displayed on the image display means.

Further, in the sub-control means, among the image information necessary for drawing the image to be displayed specified by the second specified information in correspondence with the second specified information, the image information to be transferred to the second image storage means is transferred. The specified 4th specified information is stored in the 4th specified information storage means. Here, by the 4th selection means, the 4th regulation information corresponding to the 2nd regulation information selected by the 2nd selection means is selected from the 4th regulation information storage means, and based on the selected 4th regulation information. , The image information to be transferred to the second image storage area is specified by the transfer information specifying means. Then, before the specified image information to be transferred by the first transfer control means is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the first image storage means is used. 2 Transferred to the image storage means. As a result, with respect to the selected second specified information, among the image information necessary for drawing the image to be displayed specified by the second specified information, the image information to be transferred to the second image storage means can be easily transferred. Since it can be specified, an image to be displayed can be reliably drawn based on the second specified information and displayed by the image display means.

In any of the game machines A3, A4 and E1 to E5, the sub-control means corresponds to the first specified information, and among the image information necessary for drawing the image specified by the first specified information, the said The third specified information storage means in which the third specified information that defines the image information to be transferred to the second image storage means is stored, and the third specified information corresponding to the first specified information selected by the first selection means. Is specified by the third selection means selected by the third selection means, the first regulation information selected by the first selection means, and the third regulation information selected by the third selection means. Based on the second regulation information generation means that adds image information to be transferred to the second image storage means and generates new regulation information, and the new regulation information generated by the second regulation information generation means. The drawing information specifying means includes transfer information specifying means for specifying image information to be transferred to the second image storage means, and the drawing information specifying means is provided with the second specified information generating means every time the first pointer means is updated. The drawing information for one screen corresponding to the updated first pointer means is specified based on the new specified information generated by the first transfer control means, and the first transfer control means is specified by the transfer information specifying means. The image information to be transferred is transferred from the first image storage means to the second image storage means before the image information is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information. A game machine G1 characterized in that it is controlled to be transferred to.

According to the game machine G1, in the sub-control means, among the image information necessary for drawing the image specified by the first specified information in correspondence with the first specified information, the image to be transferred to the second image storage means. The third specified information that defines the information is stored in the third specified information storage means. Here, the third specified information corresponding to the first specified information selected by the first selection means is selected from the third specified information storage means by the third selection means, and is defined by the selected third specified information. The image information to be transferred to the second image storage means is added to the first specified information selected by the first selection means by the second specified information generating means, and new specified information is generated. Then, every time the first pointer means is updated, the drawing information specifying means specifies the image information for one screen corresponding to the updated first pointer means based on the newly generated specified information. At the same time, the image information to be transferred to the second image storage area is specified by the transfer information specifying means based on the newly generated specified information. Before the specified image information to be transferred is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the first image storage means to the second image by the first transfer control means. Transferred to storage means. As a result, the image information necessary for drawing the image specified by the first specified information is easily specified for the selected first specified information, and it is necessary for drawing the image specified by the first specified information. Since the image information to be transferred to the second image storage means can be easily specified among the various image information, the image displayed based on the first specified information is surely drawn and displayed on the image display means. Can be made to.

In any of the game machines E1 to E4, the sub-control means corresponds to the first specified information, and among the image information necessary for drawing the image specified by the first specified information, the third image storage. The third specified information storage means in which the third specified information defined as the image information to be transferred to the second image storage means is stored, and the first selected by the first selection means. 1 The third selection means for selecting the third specified information corresponding to the specified information from the third specified information storage means and the first specified information selected by the first selection means are selected by the third selection means. By the second regulation information generation means for generating new regulation information by adding the image information to be transferred to the second image storage means defined by the third regulation information and the second regulation information generation means. A transfer information specifying means for specifying image information to be transferred to the second image storage means is provided based on the new specified information generated, and the drawing information specifying means is updated with the first pointer means. Each time, based on the new regulation information generated by the second regulation information generation means, the drawing information for one screen corresponding to the updated first pointer means is specified, and the first transfer control means The first image information to be transferred specified by the transfer information specifying means is used in drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information. The gaming machine G2, characterized in that it is controlled to transfer from the image storage means to the second image storage means.

According to the gaming machine G2, among the image information necessary for drawing the image specified by the first specified information in the sub-control means, the image is not held in the third image storage means. The third specified information defined as the image information to be transferred to the second image storage means is stored in the third specified information storage means. Here, the third specified information corresponding to the first specified information selected by the first selection means is selected from the third specified information storage means by the third selection means, and is defined by the selected third specified information. The image information to be transferred to the second image storage means is added to the first specified information selected by the first selection means by the second specified information generating means, and new specified information is generated. Then, every time the first pointer means is updated, the drawing information specifying means specifies the image information for one screen corresponding to the updated first pointer means based on the newly generated specified information. At the same time, the image information to be transferred to the second image storage area is specified by the transfer information specifying means based on the newly generated specified information. Before the specified image information to be transferred is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the first image storage means to the second image by the first transfer control means. Transferred to storage means. As a result, the image information necessary for drawing the image specified by the first specified information is easily specified for the selected first specified information, and it is necessary for drawing the image specified by the first specified information. Of the various image information, the image information to be transferred to the second image storage means can be easily specified because it is not retained by the third image storage means, so that the image information is displayed based on the first specified information. The image can be reliably drawn and displayed on the image display means.

In the gaming machine G1 or G2, the third specified information defines image information to be transferred to the second image storage means every unit time when an image for one screen is displayed on the image displaying means. The gaming machine G3 characterized by being.

According to the game machine G3, the third specified information defines the image information to be transferred to the second image storage means every unit time when the image for one screen is displayed on the image display means. Therefore, the second specified information generation means should start the transfer in one unit time of the image information to be transferred to the second image storage means specified by the third specified information selected by the third selection means. The image information can be added to the drawing information for one screen to be displayed in the one unit time specified in the first specified information, and new specified information can be easily generated.

In any of the game machines G1 to G3, in the third specified information storage means, among the image information necessary for drawing the image specified by the first specified information, the image information to be transferred to the second image storage means is If it does not exist, the third specified information corresponding to the first specified information is not stored, and the transfer information specifying means includes the third specified information corresponding to the first specified information selected by the first specified means. When it is determined by the third selection means that the information is not stored in the third specified information storage means, it is characterized in that it specifies that the image information to be transferred to the second image storage area does not exist. The game machine G4.

According to the game machine G4, when the image information to be transferred to the second image storage means does not exist among the image information necessary for drawing the image specified by the first specified information, it corresponds to the first specified information. The third specified information is not stored in the third specified information storage means. Then, when the transfer image specifying means determines by the third selection means that the third specified information corresponding to the first specified information selected by the first specified means is not stored in the third specified information storage means. , It is specified that there is no image information to be transferred to the second image storage area. This makes it easy to determine whether or not there is image information to be transferred to the second image storage means among the image information necessary for drawing the image specified by the first specified information, depending on the presence or absence of the third specified information. Therefore, it is possible to reduce the processing. Further, since it is possible to suppress the storage of unnecessary third specified information in the third specified information storage means, it is possible to suppress an increase in the storage capacity of the storage means.

In any of the game machines A3, A4 and E1 to E5, the sub-control means displays a second display for an image of a display type determined by the first display determining means from among a plurality of display modes. A second display determining means for determining the type and drawing information provided for each of the plurality of the second display types and indicating information necessary for drawing an image to be displayed in the second display type are defined for each screen. Of the second specified information storage means for storing the second specified information and the image information necessary for drawing the image to be displayed specified by the second specified information in correspondence with the second specified information, the second. The fourth specified information storage means in which the fourth specified information that defines the image information to be transferred to the image storage means is stored, and the second specification corresponding to the second display type determined by the second display determining means. The second selection means for selecting information from the second specified information storage means and the fourth specified information corresponding to the second specified information selected by the second selection means are selected from the fourth specified information storage means. 4 For the selection means and the first specified information selected by the first selection means, drawing information of an image to be displayed specified by the second specified information selected by the second selection means is displayed on one screen. The third provision to generate new regulation information by adding the image information to be transferred to the second image storage means specified by the fourth regulation information selected by the fourth selection means. The drawing information is provided with an information generation means and a transfer information specifying means for specifying image information to be transferred to the second image storage means based on new specified information generated by the third specified information generating means. Each time the first pointer means is updated, the specific means is for one screen corresponding to the updated first pointer means based on the new specified information generated by the third specified information generating means. The drawing information is specified, and the first transfer control means refers to the image information to be transferred specified by the transfer information specifying means according to the image instruction information whose image information is included in the drawing instruction information. The gaming machine G5 is characterized in that it is controlled to be transferred from the first image storage means to the second image storage means before being used for drawing an image.

According to the gaming machine G5, in the sub-control means, the second display type to be displayed for the image of the display type determined by the first display determination means is determined by the second display determination means from among the plurality of display modes. It is determined. Further, the second specified information storage means is provided for each of a plurality of second display types, and drawing information indicating information necessary for drawing an image to be displayed in the second display type is defined for each screen. 2 Regulation information is stored. Here, the second specified information corresponding to the second display type determined by the second display determining means is selected from the second specified information storage means by the second selection means. Further, the drawing information of the image to be displayed specified by the second specified information selected by the second selection means is obtained with respect to the first specified information selected by the first selection means by the third specified information generating means. By adding each screen, new regulation information is generated. Then, every time the first pointer means is updated by the drawing information specifying means, one screen corresponding to the updated first pointer means is obtained based on the new specified information generated by the first specified information generating means. The drawing information for the minute is specified. As a result, when displaying the image of the second display type for the image of the display type for the command received from the main control means, the second specified information corresponding to the second display type is selected from the second specified information storage means. Then, the image of the second display type can be easily displayed. Therefore, it is possible to easily diversify the display modes displayed on the image display means.

Further, in the sub-control means, the image information to be transferred to the second image storage means is defined among the image information necessary for drawing the image specified by the second specified information in correspondence with the second specified information. 4 The specified information is stored in the 4th specified information storage means. Here, by the 4th selection means, the 4th regulation information corresponding to the 2nd regulation information selected by the 2nd selection means is selected from the 4th regulation information storage means, and is defined by the selected 4th regulation information. The image information to be transferred to the second image storage means is specified by the third specified information generation means together with the drawing information for each screen of the image to be displayed specified by the second specified information selected by the second selection means. , New regulation information is generated in addition to the first regulation information selected by the first selection means. Then, every time the first pointer means is updated, the drawing information specifying means specifies the image information for one screen corresponding to the updated first pointer means based on the newly generated specified information. At the same time, the image information to be transferred to the second image storage area is specified by the transfer information specifying means based on the newly generated specified information. Before the specified image information to be transferred is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the first image storage means to the second image by the first transfer control means. Transferred to storage means. As a result, the image information necessary for drawing the image specified by the second specified information is easily specified for the selected second specified information, and it is necessary for drawing the image specified by the second specified information. Since the image information to be transferred to the second image storage means can be easily specified among the various image information, the image displayed based on the second specified information is surely drawn and displayed on the image display means. Can be made to.

In any of the game machines A3, A4 and E1 to E5, the first specified information stored in the first specified information storage means is, in addition to the drawing information necessary for drawing an image of the corresponding display type, the drawing information thereof. Of the image information necessary for drawing an image of a display type, the image information to be transferred to the second image storage means is defined, and the drawing information specifying means is updated every time the first pointer means is updated. , The drawing information for one screen corresponding to the updated first pointer means is specified based on the first specified information selected by the first selection means, and the sub-control means is the first selection means. The transfer information specifying means for specifying the image information to be transferred to the second image storage area is provided based on the first specified information selected by the above-mentioned first transfer control means, and the first transfer control means is specified by the transfer information specifying means. The image information to be transferred is stored from the first image storage means to the second image before the image information is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information. A gaming machine H1 characterized in that it is controlled to be transferred to a means.

According to the game machine H1, the first specified information stored in the first specified information storage means is necessary for drawing the image of the display type in addition to the drawing information necessary for drawing the image of the corresponding display type. Of the various image information, the image information to be transferred to the second image storage means is specified. Then, every time the first pointer means is updated by the drawing information specifying means, one screen corresponding to the updated first pointer means is obtained based on the first specified information selected by the first selection means. The drawing information is specified, and the transfer information specifying means specifies the image information to be transferred to the second image storage area based on the first defined information selected by the first selection means. Before the specified image information to be transferred is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the first image storage means to the second image by the first transfer control means. Transferred to storage means. Thereby, the image information necessary for the selected first specified information and to be transferred to the second image storage means can be easily determined and transferred to the second image storage means. Therefore, the image to be displayed based on the first specified information can be reliably drawn and displayed by the image display means.

In any of the game machines E1 to E4, the first specified information stored in the first specified information storage means is the image of the display type in addition to the drawing information necessary for drawing the image of the corresponding display type. Of the image information necessary for drawing, the image information that is not retained in the third image storage means and should be transferred to the second image storage means is defined, and the drawing information specifying means is the first. Every time the pointer means is updated, drawing information for one screen corresponding to the updated first pointer means is specified based on the first specified information selected by the first selection means, and the sub-control The means includes transfer information specifying means for specifying image information to be transferred to the second image storage area based on the first specified information selected by the first selection means, and the first transfer control means includes. The first image before the image information to be transferred specified by the transfer information specifying means is used in drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information. The gaming machine H2, characterized in that it is controlled to transfer from the storage means to the second image storage means.

According to the game machine H2, the first specified information stored in the first specified information storage means is necessary for drawing the image of the display type in addition to the drawing information necessary for drawing the image of the corresponding display type. Of the image information, the image information that is not retained in the third image storage means and should be transferred to the second image storage means is defined. Then, every time the first pointer means is updated by the drawing information specifying means, one screen corresponding to the updated first pointer means is obtained based on the first specified information selected by the first selection means. The drawing information is specified, and the transfer information specifying means specifies the image information to be transferred to the second image storage area based on the first defined information selected by the first selection means. Before the specified image information to be transferred is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the first image storage means to the second image by the first transfer control means. Transferred to storage means. As a result, it is possible to easily determine the image information necessary for the selected first specified information and which should be transferred to the second image storage means because it is not held by the third image storage means. Since the image can be transferred to the second image storage means, the image to be displayed based on the first specified information can be reliably drawn and displayed by the image display means.

In the game machine H1 or H2, the first specified information is image information to be transferred to the second image storage means for each screen in which drawing information necessary for drawing an image of a corresponding display type is specified. The transfer information specifying means corresponds to the updated first pointer means based on the first specified information selected by the first selection means every time the first pointer means is updated. The gaming machine H3 is characterized in that the image information to be transferred to the second image storage area is specified.

According to the game machine H3, the first specified information defines the image information to be transferred to the second image storage means for each screen in which the drawing information necessary for drawing the image of the corresponding display type is specified. Each time the first pointer means is updated by the transfer information specifying means, the updated first pointer means is corresponded to the updated first pointer means based on the first specified information selected by the first selection means. The image information to be transferred to the second image storage area is specified. As a result, the image information to be transferred to the second image storage means can be easily started to be transferred to the second image storage means at a predetermined timing in accordance with the update of the first pointer means. When drawing an image to be displayed based on the above, the image information necessary for the drawing can be reliably transferred to the second image storage means.

In the game machine H1 or H2, the first specified information defines the image information to be transferred to the second image storage means before the drawing information necessary for drawing the image of the corresponding display type, and the transfer information. The specific means should be transferred to the second image storage area based on the first specified information selected by the first selection means before the drawing information for one screen is specified by the drawing information specifying means. A gaming machine H4 characterized in that it specifies image information.

According to the game machine H4, the first defined information defines the image information to be transferred to the second image storage means before the drawing information necessary for drawing the image of the corresponding display type. Based on the first specified information selected by the first selection means, the drawing information for one screen is transferred to the second image storage area by the transfer information specifying means before the drawing information for one screen is specified by the drawing information specifying means. The image information to be used is specified. As a result, the image information to be transferred to the second image storage means can be specified in advance before the drawing information is specified by the drawing information specifying means, so that the image to be displayed is drawn based on the first specified information. Before this, the image information used for drawing the image can be reliably transferred to the second image storage means.

In any of the game machines A3, A4 and E1 to E5, the sub-control means displays a second display mode for a display type determined by the first display determination means from among a plurality of display modes. The first specified information stored in the first specified information storage means is provided with a second display determining means for determining a display type, and the first specified information is displayed in addition to drawing information necessary for drawing an image of the corresponding display type. The drawing information necessary for drawing the image of the second display type displayed for the image of the type is specified for each screen, and the second image storage means among the image information necessary for drawing those images is specified. The image information to be transferred to is specified, and the drawing information specifying means is based on the first specified information selected by the first selection means every time the first pointer means is updated. The drawing information for one screen corresponding to the updated first pointer means is specified, and the drawing information of the image to be displayed on the one screen corresponding to the second display type determined by the second display determining means is specified. By specifying, the drawing information required for the entire image should be specified, and the sub-control means should be transferred to the second image storage area based on the first defined information selected by the first selection means. The first transfer control means includes transfer information specifying means for specifying image information, and the first transfer control means includes the image information to be transferred specified by the transfer information specifying means, and the image information included in the drawing instruction information. The gaming machine H5 is characterized in that it is controlled to be transferred from the first image storage means to the second image storage means before being used for drawing an image by the image drawing means according to information.

According to the gaming machine H5, in the sub-control means, the second display type to be displayed for the image of the display type determined by the first display determination means is determined by the second display determination means from among the plurality of display modes. It is determined. Further, according to the first specified information stored in the first specified information storage means, in addition to the drawing information necessary for drawing the image of the corresponding display type, the second display type displayed for the image of the display type is displayed. The drawing information required for drawing the image is specified for each screen, and each time the first pointer means is updated by the drawing information specifying means, it is based on the first specified information selected by the first selection means. Then, the drawing information for one screen corresponding to the updated first pointer means is specified, and the drawing of the image to be displayed on one screen corresponding to the second display type determined by the second display determination means is specified. The information is specified and the drawing information required for the entire image is specified. As a result, when displaying the image of the second display type for the image of the display type for the command received from the main control means, the drawing information of the second display type to be displayed is specified from the selected first specified information. Then, the image of the second display type can be easily displayed. Therefore, it is possible to easily diversify the display modes displayed on the image display means.

Further, in the sub-control means, the first specified information stored in the first specified information storage means includes the drawing information necessary for drawing the image and the second image among the image information necessary for drawing the image. The image information to be transferred to the storage means is defined, and the transfer information specifying means specifies the image information to be transferred to the second image storage area based on the first specified information selected by the first selection means. Before the specified image information to be transferred is used for drawing an image by the image drawing means according to the image instruction information included in the drawing instruction information, the first image storage means to the second image by the first transfer control means. Transferred to storage means. Thereby, the image information necessary for the selected first specified information and to be transferred to the second image storage means can be easily determined and transferred to the second image storage means. Therefore, even when the image of the second display type is displayed for the image displayed based on the first specified information, the image can be reliably drawn and displayed by the image display means.

In the gaming machine A6, the main control means sub-controls a first command generation means for generating a first command for determining the identification information displayed by the dynamic display effect, and various generated commands. The sub-control means includes a command transmitting means for transmitting to the means, and the sub-control means determines the identification information displayed by the dynamic display effect based on receiving the first command from the main control means. A first time lapse determination means for determining whether a predetermined time has elapsed for the dynamic display effect and a first time lapse determination for the dynamic display effect since the display of the dynamic display effect is started. The means includes a second time lapse determination means for determining whether or not a predetermined time has elapsed since the determination that the time has elapsed, and the first display determination means is the predetermined time lapse determination means by the second display determination means. If the reception of the first command is not yet recognized at the stage when it is determined that the time has elapsed, the identification information is dynamically displayed again as the display type to be displayed by the image display means. The gaming machine I1 characterized in that it determines the production.

According to the gaming machine I1, in the sub-control means, the identification information displayed by the dynamic display effect is determined by the determination means based on the reception of the first command by the main control means. Based on the determined identification information, the gaming machine imparts a predetermined gaming value to the player if it is predetermined identification information. On the other hand, it is determined by the first time lapse determination means whether or not a predetermined time has elapsed for the dynamic display effect after the display of the dynamic display effect is started, and the time is determined by the first time lapse determination means. It is determined by the second time lapse determination means whether or not a predetermined time has elapsed since it was determined that the lapse of time has elapsed. Then, the first display determining means causes the image display means to display the first command when the second time elapsed determining means determines that the predetermined time has elapsed and the reception of the first command is not yet recognized. As a display type, it is configured to determine a re-dynamic display effect for dynamically displaying the identification information again. As a result, the first specified information corresponding to the finely tuned display effect is selected from the first specified information storage means by the first selection means, so that the display in the image display means can be easily switched to the redynamic display effect. Can be done. Further, if the identification information cannot be determined because the reception of the first command is not recognized from the main control means even though the dynamic display effect is completed, the identification information is dynamically displayed again. , It is possible to make the player recognize that the identification information has not been determined.

In the gaming machine I1, the first specified information corresponding to the re-dynamic display effect is displayed on the image display means in a display mode of the restart display effect, which is different from the display mode of the dynamic display effect. As described above, the gaming machine I2 is characterized in that it defines image information necessary for drawing an image.

According to the gaming machine I2, the first specified information corresponding to the re-dynamic display effect is displayed on the image display means in the display mode of the restart display effect, which is different from the display mode of the dynamic display effect. Since the image information necessary for drawing the image is specified, the player should clearly recognize that the re-dynamic display effect has been started without the identification information being determined in the dynamic display effect. Can be done.

In the gaming machine I1 or I2, when the drawing information specifying means determines the redynamic display effect as the first effect by the first display determination means, the first display corresponding to the redynamic display effect. When the image information required for drawing an image is specified over the entire screen specified in the specified information, it recurses to the first screen specified in the first specified information and is required for drawing an image for each screen. A gaming machine I3 characterized by specifying image information.

According to the gaming machine I3, when the drawing information specifying means determines the re-dynamic display effect as the first effect by the first display determination means, it is defined in the first specified information corresponding to the re-dynamic display effect. When the image information necessary for drawing an image is specified over the entire screen, the image information required for drawing an image is specified for each screen by recursing to the first screen specified in the first specified information. It is configured to do. As a result, the re-dynamic display can be repeatedly displayed even if the image information required for drawing the image is specified only for a small number of screens as the first specified information corresponding to the re-dynamic display.

In the gaming machine I3, the first specified information corresponding to the redynamic display effect is such that the display mode of the restart display effect is such that the identification information swings at least once with respect to a predetermined position. The gaming machine I4, which defines image information necessary for drawing an image so as to be displayed on the image display means.

According to the gaming machine I4, the first specified information corresponding to the redynamic display effect is an image display in such a manner that the display mode of the restart display effect is such that the identification information swings at least once around a predetermined position. Since the image information necessary for drawing the image is defined so as to be displayed by the means, the image display means in which the identification information vibrates as a redynamic display effect when the image information is repeatedly displayed. Can be displayed in.

In any of the gaming machines I1 to I4, the determining means specifies drawing information for one screen by the drawing information specifying means based on the first defined information corresponding to the redynamic display effect. In this case, when the first command is received from the main control means, the identification information displayed by the dynamic display performed before the re-dynamic display effect is fixed. Gaming machine I5.

According to the gaming machine I5, when the drawing information for one screen is specified by the drawing information specifying means based on the first specified information corresponding to the redynamic display effect, the first control means is used. When the command is received, the identification information displayed by the dynamic display performed before the re-dynamic display effect is determined by the determination means. As a result, even if the redynamic display effect is displayed on the image display means without receiving the first command, if the first command is received, it is before the redynamic display effect. The identification information that appears by the dynamic display performed can be fixed.

In any of the gaming machines I1 to I5, the first display determining means specifies drawing information for one screen by the drawing information specifying means based on the first specified information corresponding to the redynamic display effect. If a command indicating the start of a new dynamic display effect is received from the main control means, the display type to be displayed on the image display means corresponds to the effect mode type indicated by the received command. A gaming machine I6 characterized in that it determines a dynamic display effect to be performed.

According to the gaming machine I6, when the drawing information for one screen is specified by the drawing information specifying means based on the first specified information corresponding to the redynamic display effect, a new operation is performed from the main control means. When a command indicating the start of the target display effect is received, the dynamic display effect corresponding to the effect mode indicated by the received command is determined by the first display determination means as the display type to be displayed on the image display means. .. As a result, even if the redynamic display effect is displayed on the image display means without receiving the first command, if the command indicating the start of the dynamic display effect is received, the dynamic display effect is displayed. Can be displayed on the image display means, and the control state of the game performed by the main control means can be reflected on the image display means.

In the game machine A6, the main control means has an effect type of the dynamic display effect according to the type of identification information to be displayed by the dynamic display effect and the identification information to be displayed by the dynamic display effect. A dynamic display effect determining means for determining the above, a second command generating means for generating a second command for notifying the effect mode type of the dynamic display effect determined by the dynamic display effect determining means, and the above. A third command generation means for generating a third command for notifying the type of identification information to be displayed by the dynamic display effect determined by the dynamic display effect determination means, and various generated commands as sub-control means. The first display determining means includes a command transmitting means for transmitting, and the first display determining means has a second command as a display type to be displayed on the image display means based on receiving the second command from the main control device. The dynamic display effect corresponding to the effect mode type notified by the user is determined, and the sub control means is recognized based on the third command received from the main control device. The dynamic display determining means for determining whether the identification information displayed by the first display determining means and the dynamic display effect determined by the first display determining means are appropriate, and the dynamic display determining means thereof. When it is determined that the identification information and the dynamic display effect are unsuitable, predetermined identification information is set as the identification information to appear by the dynamic display effect regardless of the third command. The first display determining means includes the identification information setting means, and when the dynamic display determining means determines that the identification information and the dynamic display effect are disproportionate to each other, the main control A gaming machine J1 characterized in that the dynamic display effect determined based on receiving the second command from the device is changed to a dynamic display effect of a predetermined effect mode.

According to the gaming machine J1, in the main control means, the type of the identification information to be displayed by the dynamic display effect and the type of the effect mode of the dynamic display effect according to the identification information to be displayed by the dynamic display effect. Is determined by the dynamic display effect determining means. Then, the second command generation means generates a second command for notifying the effect type of the dynamic display effect determined by the dynamic display effect determination means, and the third command generation means dynamically generates a second command. A third command for notifying the type of identification information to be displayed by the dynamic display effect determined by the display effect determining means is generated, and these commands are transmitted to the sub-control means by the command transmitting means. On the other hand, in the sub control means, based on receiving the second command from the main control device, the effect mode type notified by the second command as the display type to be displayed on the image display means by the first display determination means. The dynamic display effect corresponding to is determined. Further, the identification information displayed by the dynamic display effect recognized based on the third command received from the main control device and the dynamic display effect determined by the first display determination means are appropriate. If it is determined by the dynamic display determination means and it is determined that the identification information and the dynamic display effect are disproportionate, the identification information to be displayed by the dynamic display effect by the identification information setting means. Is set to predetermined identification information regardless of the third command, and a dynamic display effect determined based on receiving a second command from the main control unit by the first display determining means is predetermined. It is changed to the dynamic display effect of the effect mode. Here, if the identification information displayed by the dynamic display effect recognized based on the third command and the dynamic display effect determined by the first display determination means are unsuitable, it is correct. The command may not have been received. Then, when the image display means is displayed in the dynamic display effect while following the received command and the identification information is displayed, the identification information different from the identification information expected by the player appears due to the dynamic display effect. As a result, there is a risk that the player may feel distrust. On the other hand, according to the gaming machine J1, in such a case, regardless of the command received from the main control device, the image display means displays a dynamic display effect of a predetermined mode, and a predetermined mode is displayed. Since the identification information appears, the dynamic display effect and the identification information can be made appropriate, and the player can continue the game with peace of mind.

In the gaming machine J1, when the dynamic display determining means determines that the identification information and the dynamic display effect are disproportionate to each other, the first display determining means is said by the main control device. The dynamic display effect determined based on the reception of the second command is continuously displayed in a dynamic display invisible to the player until the identification information is determined. A game machine J2 characterized by being changed to.

The dynamic display invisible to the player is, for example, a state in which the identification information is dynamically displayed at a high speed to the extent that the player cannot see it, or a state in which the identification information is reduced to the extent that the identification information cannot be seen. In addition, it includes various states such as a state in which a snow noise-like image in which a large number of white dots are randomly displayed so as to cover the identification information is displayed.

According to the gaming machine J2, when the dynamic display discriminating means determines that the identification information and the dynamic display effect are disproportionate, it is based on receiving a second command from the main control device. The determined dynamic display effect is changed to a dynamic display effect of an effect mode in which the dynamic display invisible to the player is continuously performed by the first display determination means until the identification information is determined. As a result, the dynamic display effect can be displayed without giving the player a special feeling of expectation, so that the player can continue the game with peace of mind.

In the gaming machine J1 or J2, when the dynamic display determining means determines that the identification information and the dynamic display effect are disproportionate to each other, the first display determining means is the main control device. The dynamic display effect determined based on the reception of the second command has a longer effect time than the effect time required for the dynamic display effect performed based on the second command. A game machine J3 characterized by being changed to.

According to the gaming machine J3, when the dynamic display discriminating means determines that the identification information and the dynamic display effect are disproportionate, it is based on receiving a second command from the main control device. The determined dynamic display effect is changed to a dynamic display effect of an effect mode having an effect time longer than the effect time required for the dynamic display effect performed based on the second command. As a result, the dynamic display effect can always be displayed on the image display means during the time required for the dynamic display effect of the effect mode determined by the main control means, so that the player can play the game with peace of mind. You can let it continue.

In any of the gaming machines J1 to J3, the identification information setting means moves when the dynamic display determination means determines that the identification information and the dynamic display effect are disproportionate. The gaming machine J4 is characterized in that identification information that does not give a predetermined gaming value to the player is set as the identification information that is displayed by the target display effect.

According to the gaming machine J4, when the dynamic display discrimination means determines that the identification information and the dynamic display effect are disproportionate, the identification information setting means causes the identification to appear by the dynamic display effect. The information is set to identification information that does not give the player a predetermined gaming value. Here, such a situation may be caused by the command not being received correctly, and it is unclear whether or not a predetermined game value is actually given to the player. .. On the other hand, according to the gaming machine J4, the identification information to be displayed by the dynamic display effect is set to the identification information that does not give a predetermined game value, so that the player can see the identification information after the final display of the dynamic display effect. If the predetermined game value is not given, the player can be convinced of the result and continue the game, and even if the player is given the predetermined game value, the player is willing to play the game. Can be continued.

In any of the gaming machines J1 to J4, the identification information setting means moves when the dynamic display determination means determines that the identification information and the dynamic display effect are disproportionate. The gaming machine J5 is characterized in that identification information that does not normally appear is set as the identification information that appears by the target display effect.

According to the gaming machine J5, when the dynamic display discrimination means determines that the identification information and the dynamic display effect are disproportionate, the identification information setting means causes the identification to appear by the dynamic display effect. The information is set to identification information that normally does not appear. Here, such a situation may be caused by the command not being received correctly, and it is unclear whether or not a predetermined game value is actually given to the player. .. On the other hand, according to the gaming machine J5, the identification information that appears by the dynamic display effect is set to the identification information that does not normally appear, so that the game given to the player by the identification information. Even if the value does not reach a predetermined game value, the player can be convinced and the player can continue the game with peace of mind.

In the gaming machine J5, the gaming machine causes the image display means to display and display a plurality of identification information in the final display of the dynamic display effect, and is a combination of the displayed identification information. Is a combination of predetermined identification information, the player is given a predetermined game value, and the identification information setting means has the identification information and the dynamic display by the dynamic display determination means. When it is determined that the effect is unsuitable, the combination of the identification information to be displayed by the dynamic display effect is not the combination of the predetermined identification information and is not normally displayed. A gaming machine J6 characterized in that a combination of information is set.

According to the gaming machine J6, when the dynamic display discrimination means determines that the identification information and the dynamic display effect are disproportionate, the identification information setting means causes the identification to appear by the dynamic display effect. As a combination of information, a combination of identification information that is not normally displayed and is not a predetermined combination of identification information that gives the player a predetermined game value is set. Here, such a situation may be caused by the command not being received correctly, and it is unclear whether or not a predetermined game value is actually given to the player. .. On the other hand, according to the gaming machine J6, the combination of identification information to be displayed by the dynamic display effect is not a combination of predetermined identification information that gives the player a predetermined gaming value, and is usually Since a combination of identification information that does not appear at times is set, if the player is not given a predetermined game value after the final display of the dynamic display effect, the player is convinced of the result and continues the game. Further, even if the player is given a predetermined game value, the player can happily continue the game by recognizing that the combination of the identification information is special.

In the gaming machine A6, the first specified information corresponding to the dynamic display effect defines the offset information from the predetermined identification information as the information for specifying the identification information to be displayed for each screen. In the sub-control means, the drawing information specifying means is the predetermined identification information when the first specified information selected by the first selection means is the first specified information corresponding to the dynamic display effect. The gaming machine K1 characterized in that the identification information to be displayed on one screen is specified based on the offset information specified by the first specified information.

According to the gaming machine K1, the first specified information corresponding to the dynamic display effect is configured to specify offset information from the predetermined identification information as information for specifying the identification information to be displayed for each screen. ing. On the other hand, the drawing information specifying means is defined by the predetermined identification information and the first specified information when the first specified information selected by the first selection means is the first specified information corresponding to the dynamic display effect. It is configured to specify the identification information to be displayed on one screen based on the offset information. As a result, in the dynamic display effect in which the display mode is the same even if the identification information to be displayed is different, the image display means can display the o. Therefore, if there is one first specified information using fuset information for the dynamic display effect of the same effect mode, the first specified information is prepared for each of the dynamic display effect for each identification information and the identification information to be displayed. Since it is not necessary, it is possible to suppress an increase in the storage capacity of the first specified information storage means for storing the first specified information, and it corresponds to a larger number of production modes as long as the capacity is permissible. 1 The specified information can be stored.

In the gaming machine K1, the first specified information corresponding to the dynamic display effect is dynamically displayed immediately before as the predetermined identification information up to the predetermined screen as information for specifying the identification information to be displayed for each screen. The sub-control means defines the offset information from the identification information that appears in the effect, and the sub-control means stores the identification information that stores the previous identification information that identifies the identification information that appeared in the immediately preceding dynamic display effect. The drawing information specifying means includes means, and when the first specified information selected by the first selection means is the first specified information corresponding to the dynamic display effect, the modified first pointer is provided. Up to the predetermined screen corresponding to the means, the previous identification information stored in the identification information storage means and the identification information displayed in the immediately preceding dynamic display effect defined by the first specified information are used. The gaming machine K2, characterized in that the identification information to be displayed on one screen is specified based on the offset information.

According to the gaming machine K2, the first specified information corresponding to the dynamic display effect is displayed in the immediately preceding dynamic display effect up to the predetermined screen as information for specifying the identification information to be displayed for each screen. It is configured to specify offset information from the identification information. Then, in the sub-control means, the previous identification information for specifying the identification information displayed in the immediately preceding dynamic display effect is stored in the identification information storage means, and the drawing information specifying means is selected by the first selection means. 1 When the specified information is the first specified information corresponding to the dynamic display effect, the previous identification information stored in the identification information storage means and the previous identification information stored in the identification information storage means up to the predetermined screen corresponding to the changed first pointer means. It is configured to specify the identification information to be displayed on one screen based on the offset information from the identification information displayed in the dynamic display effect immediately before defined by the first regulation information. Here, in the dynamic display effect, it is common to start from the identification information displayed in the immediately preceding dynamic display effect, but the gaming machine K2 dynamically displays the pachinko machine K2 by one first specified information. The dynamic display of the identification information in the effect can be started based on the identification information displayed by the immediately preceding dynamic display effect.

In the gaming machines K1 or K2, the first specified information corresponding to the dynamic display effect is the information for specifying the identification information to be displayed for each screen, and the predetermined screen and thereafter are the predetermined identification information. 1 The offset information from the identification information that appears in the dynamic display effect performed based on the specified information is specified, and the sub control means is a dynamic display effect based on a command from the main control means. The drawing information specifying means includes the identification information determining means for determining the identification information to be displayed by the first selection means, in which the first specified information selected by the first selection means corresponds to the dynamic display effect. In this case, after the predetermined screen corresponding to the changed first pointer means, the identification information determined by the identification information determining means and the first specified information specified by the first specified information are used. The gaming machine K3 is characterized in that the identification information to be displayed on one screen is specified based on the offset information from the identification information displayed in the dynamic display effect performed based on the above.

According to the gaming machine K3, the first specified information corresponding to the dynamic display effect is information for specifying the identification information to be displayed for each screen, and after the predetermined screen, the first specified information is performed based on the first specified information. It is configured to specify the offset information from the identification information that appears in the dynamic display effect. Then, in the sub control means, the identification information to be displayed by the dynamic display effect is determined by the identification information determining means based on the command from the main control means, and the drawing information specifying means is selected by the first selection means. When the first specified information is the first specified information corresponding to the dynamic display effect, the identification information determined by the identification information determining means and the identification information after the predetermined screen corresponding to the changed first pointer means are used. Identify the identification information to be displayed on one screen based on the offset information from the identification information that appears in the dynamic display effect performed based on the first regulation information specified by the first regulation information. It is configured in. Thereby, the dynamic display effect can be terminated based on the identification information determined based on the command from the main control device by one first specified information.

In the gaming machine K2 or K3, as information for specifying the identification information to be displayed for each screen in the first specified information corresponding to the dynamic display effect, the predetermined screen is invisible to the player. A gaming machine K2 characterized in that it is set on a screen displayed during a period in which information is dynamically displayed.

The dynamic display invisible to the player is, for example, a state in which the identification information is dynamically displayed at a high speed to the extent that the player cannot see it, or a state in which the identification information is reduced to the extent that the identification information cannot be seen. In addition, it includes various states such as a state in which a snow noise-like image in which a large number of white dots are randomly displayed so as to cover the identification information is displayed.

According to the gaming machine K4, in the first specified information corresponding to the dynamic display effect, as information for specifying the identification information to be displayed for each screen, the predetermined screen is dynamically invisible to the player. Since the screen is set to be displayed during the period in which the display is made, it is possible to prevent the player from visually recognizing that the identification information changes significantly before and after the predetermined screen due to the switching of the offset information on the predetermined screen. be able to. Therefore, the player can continue the game without any discomfort.

In any of the gaming machines K1 to K4, the identification information is attached with a unique number, and the number attached to the predetermined identification information and the identification information to be displayed on the corresponding one screen. The gaming machine K5, characterized in that it indicates a difference from the numbers attached to.

According to the gaming machine K5, unique numbers are attached to the identification information, and the difference between the numbers attached to the predetermined identification information and the numbers attached to the identification information to be displayed on the corresponding one screen is Since it is shown, by managing the identification information by the number attached to the identification information, it is possible to easily specify the identification information to be displayed from the offset information.

It is provided with a main control means that performs the main control of the game, a sub-control means that operates based on a command transmitted from the main control means, and an image display means that displays an image based on the control by the sub-control means. In the gaming machine, the sub-control means stores a program executed by the arithmetic processing means together with an arithmetic processing means and image information for displaying an image on the image display means, when the power is turned off. It also has a first storage means capable of holding information, and the arithmetic processing means is generated at the start of power supply and a pointer means for designating an address that specifies an instruction of a program to be executed by the arithmetic processing means. A pointer initialization that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first based on the reset signal receiving means that receives the reset signal and the reset signal received by the reset receiving means. The first storage means includes a first storage control means for controlling the operation of the first storage means, a first sub-storage means for storing the image information and the program, and a first sub-storage means thereof. It is possible to read out at a higher speed than the sub storage means, and it is a part or all of the predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means, and is a part or all of the predetermined program. A second sub-storage means for storing a program including the first instruction and a temporary storage means for temporarily storing a predetermined set of information read from the first sub-storage means or the second sub-storage means are provided. The first storage control means receives an address in which one of the information stored in the first sub-storage means and the second sub-storage means is stored, and an address receiving means thereof. By an information storage means for reading a predetermined set of information including information stored in a stored address from the first sub storage means or the second sub storage means and storing the information in the temporary storage means, and the information storage means thereof. The first storage control means includes the information output means for reading and outputting the information specified by the address received by the address receiving means from the information stored in the temporary storage means, and the first storage control means has the arithmetic processing. The address that the pointer means has specified an address that specifies the first instruction of the predetermined program to be executed first by the initialization of the means by the pointer initialization means. When it is received by the receiving means, a part or all of the predetermined program including the first instruction is read from the second sub storage means, and the read program is temporarily stored in the temporary storage means. The gaming machine L1 is characterized in that it controls the information storage means.

According to the game machine L1, the sub-control means can hold the information even when the power is turned off to store the program executed by the arithmetic processing means together with the arithmetic processing means and the image information for displaying the image on the image display means. It has a first storage means. Further, the arithmetic processing means includes a pointer means for designating an address for specifying an instruction of a program to be executed by the arithmetic processing means, a reset signal receiving means for receiving a reset signal generated at the start of power supply, and a reset receiving means thereof. Based on the reset signal received by the means, the first storage means has a pointer initialization means that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first. A first storage control means for controlling the operation of the first storage means, a first sub storage means for storing image information and a program, and a read operation at a higher speed than the first sub storage means are possible, and arithmetic processing is possible. A second sub-storage means for storing a program that is a part or all of a predetermined program to be executed first based on the reception of the reset signal in the means and includes the first instruction of the predetermined program, and a first sub-storage. It has a temporary storage means for temporarily storing a predetermined set of information read from the means or the second sub storage means. Further, the first storage control means is received by an address receiving means that receives an address in which one of the information stored in the first sub storage means and the second sub storage means is stored, and an address receiving means thereof. An information storage means that reads a predetermined set of information including the information stored in the address from the first sub storage means or the second sub storage means and stores the information in the temporary storage means, and the information storage means in the temporary storage means. It has an information output means for reading and outputting information specified by an address received by an address receiving means from the stored information.

Here, the first storage control means receives an address that the pointer means specifies an address that specifies the first instruction of a predetermined program to be executed first by the initialization by the pointer initialization means of the arithmetic processing means. When accepted by the means, an information storage means is provided so as to read a part or all of a predetermined program including the first instruction from the second sub-storage means and temporarily store the read program in the temporary storage means. It is configured to control. Then, as described above, since the second sub-storage means can perform the read operation at a higher speed than the first sub-storage means, a predetermined program to be executed first by the initialization by the pointer initialization means of the arithmetic processing means. When the address that identifies the first instruction of is specified by the pointer means, a part or all of a predetermined program including the first instruction executed by the arithmetic processing means after receiving the reset signal is immediately stored in the temporary storage means. After storing it, it can be output to the arithmetic processing means. Therefore, even when the program is stored together with the image information in the first sub storage means having a slow reading speed, the program to be executed can be immediately read and the execution of the process can be started.

The gaming machine L1 is characterized in that the predetermined program is a starting program for executing a starting process for enabling the operation processing means to execute various controls in the sub-control means.

According to the game machine L2, the predetermined program executed by the arithmetic processing means after receiving the reset signal is an activation program that executes the activation processing for enabling the arithmetic processing means to execute various controls in the sub-control means. Therefore, after receiving the reset signal, the start program is immediately read out and executed by the arithmetic processing means, so that various controls can be quickly executed by the sub-control means.

In the game machine L2, the sub-control means is readable and writable by the arithmetic processing means, is capable of reading operation at a higher speed than the first sub-storage means, and cannot hold information when the power is turned off. The activation program transfers the program stored in the first sub-storage means to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means. The gaming machine L3 comprising an instruction for executing a process set in the address of the second storage means in which an instruction to be executed first among the programs is stored.

According to the game machine L3, when the start program is first executed by the arithmetic processing means of the sub control means after receiving the reset signal, the program stored in the first sub storage means can be read out at high speed. The program is transferred to the second storage means, and after the transfer is completed, the pointer means is set to the address of the second storage means in which the instruction to be executed first among the programs transferred to the second storage means is stored. As a result, the arithmetic processing means can subsequently read the instruction from the second storage means and execute the processing, so that even when the first sub storage means having a slow reading speed stores the program together with the image information, the speed is high. Instructions can be read out.

In the game machine L3, the second sub storage means stores a part of the start program including the first instruction in the start program, and the first sub storage means is the second sub of the start program. Various programs are stored including the remaining start programs that are not stored in the storage means, and the start program stored in the second sub storage means is stored in the first sub storage means. Among various programs, a predetermined amount of programs including a part or all of the remaining startup programs are transferred to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means. The gaming machine L4 comprising an instruction to execute a process set in the address of the second storage means in which an instruction to be executed first among the remaining startup programs is stored.

According to the game machine L4, the second sub storage means stores a part of the start program including the first instruction in the start program, while the first sub storage means stores the second of the start programs. Various programs are stored in the sub-storage means, including the remaining startup programs that are not stored. Then, the start program stored in the second sub storage means is a part or all of the remaining start programs that are not stored in the second sub storage means among the various programs stored in the first sub storage means. A predetermined amount of programs including It contains an instruction to execute a process to be set in the address of the second storage means. As a result, even if only a part of the start programs including the first instruction of the start programs is stored in the second sub storage means, the start program stored by the second sub storage means can be used for the first step. Of the various programs stored in the sub-storage means, a predetermined amount of programs including a part or all of the remaining activation programs that are not stored in the second sub-storage means are transferred to the second storage means, and the transfer thereof. Is completed, the pointer means is set to the address of the second storage means in which the instruction to be executed first among the remaining start programs transferred to the second storage means is stored, so that the second storage means is used. You can be sure that some or all of the remaining startup programs that have been transferred will be executed. Therefore, since it is not necessary to store all the activation programs in the second sub storage means, the storage capacity of the second sub storage means can be suppressed to a small capacity.

In the game machine L4, a predetermined amount of programs including a part of the remaining activation programs among various programs stored in the first sub storage means by the activation program stored in the second sub storage means. Is transferred to the second storage means, the partial activation program transferred to the second storage means is the second storage among various programs stored in the first sub storage means. A predetermined amount of programs including a part or all of the remaining start programs that are not transferred to the means are transferred to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means by the latest transfer process. (2) A gaming machine comprising an instruction to execute a process set in the address of the second storage means in which an instruction to be executed first among the remaining start programs transferred to the storage means is stored. L5.

According to the game machine L5, among the various programs stored in the first sub storage means by the start program stored in the second sub storage means, the remaining start programs that are not stored in the second sub storage means. When a predetermined amount of programs including a part of the above are transferred to the second storage means, the part of the activation program transferred to the second storage means is among various programs stored in the first sub storage means. , A predetermined amount of programs including a part or all of the remaining non-transferred start-up program is transferred to the second storage means, and after the transfer is completed, the pointer means is transferred by the latest transfer process. (2) Among the remaining startup programs transferred to the storage means, the instruction to execute the process set in the address of the second storage means in which the instruction to be executed first is stored is included. As a result, a part of the activation program transferred to the second storage means executes a process of further transferring the non-transferred activation program to the second storage means, and after the transfer is completed, the transfer is performed to the second storage means. Execution can be started from the first instruction of the stored startup program. Therefore, even when the program size of the start program is large, the arithmetic processing means transfers the start program excluding the start program stored in the second sub storage means from the first sub storage means to the second storage means. Above, it can be reliably executed from the second storage means.

In the game machine L5, among the various programs stored in the first sub-storage means by the partial activation program transferred to the second storage means, the rest of the programs not transferred to the second storage means. When a predetermined amount of programs including a part of the start program is transferred to the second storage means, the part of the start program newly transferred to the second storage means is transferred to the first sub storage means. Among the various stored programs, a predetermined amount of programs including a part or all of the remaining activation programs that are not transferred to the second storage means are transferred to the second storage means, and the transfer is completed. Later, a process of setting the pointer means to the address of the second storage means in which the instruction to be executed first among the remaining start-up programs transferred to the second storage means by the latest transfer process is executed is executed. A gaming machine L6 characterized by including a command to be executed.

According to the game machine L6, among the various programs stored in the first sub storage means by some of the activation programs transferred to the second storage means, the remaining programs that are not stored in the second sub storage means. When a predetermined amount of the program including a part of the start program is transferred to the second storage means, the part of the start program newly transferred to the second storage means is stored in the first sub storage means. Of the various programs, a predetermined amount of programs including a part or all of the remaining non-transferred startup programs are transferred to the second storage means, and after the transfer is completed, the pointer means is immediately moved to the second storage means. It includes an instruction to execute a process of setting to the address of the second storage means in which the instruction to be executed first among the remaining start programs transferred to the second storage means by the transfer process is stored. As a result, a part of the activation program transferred to the second storage means executes a process of further transferring the non-transferred activation program to the second storage means, and after the transfer is completed, the transfer is performed to the second storage means. Execution can be started from the first instruction of the stored startup program. Therefore, even if the program size of the start program is very large, the arithmetic processing means changes the start program excluding the start program stored in the second sub storage means from the first sub storage means to the second sub storage means. After transferring, it can be reliably executed from the second storage means.

In the gaming machines L3 to L6, the program stored in the second storage means is programmed so that the pointer means is always set to an address specifying an instruction included in the program stored in the second storage means. The gaming machine L7, which is characterized by being

According to the game machine L7, the program stored in the second storage means is programmed so that the pointer means is always set to the address specifying the instruction included in the program stored in the second storage means. Therefore, once the pointer means is set to the address that specifies the instruction included in the program stored in the second storage means, the arithmetic processing means always reads the instruction from the second storage means and executes the process. be able to. Here, the start program transfers the program stored in the first sub-storage means to the second storage means, and then the pointer means gives an instruction to be executed first among the programs transferred to the second storage means. Is set to the address of the second storage means in which the is stored, so that after the program stored in the first sub storage means is transferred to the second storage means, the arithmetic processing means is transferred to the second storage means. It is possible to always read the instruction from the program and execute the process. That is, since the arithmetic processing means can always read an instruction from the program stored in the second storage means having a high read speed and execute the process, the program is stored together with the image information in the first sub storage means having a slow read speed. Even if the program is to be transferred, the program stored in the first sub storage means is transferred to the second storage means, and then the program stored in the second storage means is immediately read out and the process is executed. Can be done.

In the gaming machines L1 to L7, the gaming machine L8 is characterized in that the first sub storage means is configured by a NAND flash memory.

According to the gaming machine L8, the first sub storage means is configured by a NAND flash memory. Here, the NAND flash memory is characterized in that a large storage capacity can be obtained in a small area and is inexpensive. Therefore, the capacity of the first storage means should be increased while suppressing the increase in cost. Can be done. Therefore, not only the image information but also the program can be easily stored in the first storage means, so that another storage means for storing the program can be unnecessary, and the cost can be reduced. Can be done. On the other hand, the NAND flash memory is characterized in that the read speed is slower than that of other memories. However, according to the configuration described in any of the gaming machines L1 to L7, the NAND flash memory having a slow read speed is used. Even when the program is stored together with the image information in the configured first sub-storage means, the program to be executed can be immediately read out and the execution of the process can be started.

In the gaming machines L1 to L8, the gaming machine L9 is characterized in that the second sub storage means is configured by a NOR type ROM.

According to the gaming machine L9, the second sub storage means is configured by a NOR type ROM. Here, since the NOR type ROM is characterized in that it can be read out at high speed, it is a part or all of a predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means. By storing the program including the first instruction of the predetermined program in this NOR type ROM, the reset signal is accepted even when the program is stored together with the image information in the first sub storage means having a slow read speed. After that, the program to be executed can be immediately read from the NOR type ROM, stored in the temporary storage means, and then output to the arithmetic processing means. Therefore, the arithmetic processing means can immediately start the execution of the processing.

In the gaming machines L1 to L8, the gaming machine L9 is characterized in that the second sub-storage means is built in the first storage control means.

According to the gaming machine L10, since the second sub storage means is built in the first storage control means, the first storage control means can perform a high-speed reading operation from the second sub storage means. .. Therefore, a part or all of a predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means, and the program including the first instruction of the predetermined program is stored in the second sub storage means. Therefore, even when the program is stored together with the image information in the first sub storage means having a slow read speed, the program to be executed after receiving the reset signal is immediately read from the second sub storage means and temporarily stored. After storing in, the program can be output to the arithmetic processing means. Therefore, the arithmetic processing means can immediately start the execution of the processing.

It includes a main control means that performs the main control of the game, a sub-control means that operates based on a command transmitted from the main control means, and an image display means that displays an image based on the control by the sub-control means. In the gaming machine, the sub-control means stores a program executed by the arithmetic processing means together with an arithmetic processing means and image information for displaying an image on the image display means, when the power is turned off. It also has a first storage means capable of holding information, and the arithmetic processing means is generated at the start of power supply and a pointer means for designating an address that specifies an instruction of a program to be executed by the arithmetic processing means. A pointer initialization that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first based on the reset signal receiving means that receives the reset signal and the reset signal received by the reset receiving means. The first storage means includes a first storage control means for controlling the operation of the first storage means, a first sub-storage means for storing the image information and the program, and a first sub-storage means thereof. The first storage control means includes a temporary storage means for temporarily storing a predetermined set of information read from the sub storage means, and the first storage control means contains one piece of information stored in the first sub storage means. A predetermined set of information including the address receiving means for receiving the stored address and the information stored in the address received by the address receiving means is read from the first sub storage means and stored in the temporary storage means. The information storage means, the information output means for reading and outputting the information specified by the address received by the address receiving means from the information stored in the temporary storage means by the information storage means, and the power supply are started. The first storage control means is provided with a power supply detecting means for detecting that the power supply has been performed, and when it is detected that the power supply is started by the power supply detection, the first storage control means is used in the arithmetic processing means. A program including a part or all of the predetermined program to be executed first based on the reception of the reset signal and including the first instruction of the predetermined program is read from the first sub storage means and the program thereof is read out. The gaming machine M1 is characterized in that the information storage means is controlled so that the read program is temporarily stored in the temporary storage means.

According to the game machine M1, the sub-control means can hold the information even when the power is turned off to store the program executed by the arithmetic processing means together with the arithmetic processing means and the image information for displaying the image on the image display means. It has a first storage means. Further, the arithmetic processing means includes a pointer means for designating an address for specifying an instruction of a program to be executed by the arithmetic processing means, a reset signal receiving means for receiving a reset signal generated at the start of power supply, and a reset receiving means thereof. Based on the reset signal received by the means, the first storage means has a pointer initialization means that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first. A first storage control means for controlling the operation of the first storage means, a first sub storage means for storing image information and a program, and a predetermined set of information read from the first sub storage means are temporarily stored. It has a temporary storage means to be used. Further, the first storage control means is stored in an address receiving means that receives an address in which one of the information stored in the first sub storage means is stored, and an address received by the address receiving means. The address receiving means receives a predetermined set of information including information from the information storage means that reads out from the first sub storage means and stores it in the temporary storage means, and the information stored in the temporary storage means by the information storage means. It has an information output means for reading and outputting the information specified by the address, and a power supply detecting means for detecting that the power supply has been started.

Here, the first storage control means is a part of a predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means when it is detected that the power supply is started by the power supply detection. Or, the information storage means is controlled so as to read the program including the first instruction of the predetermined program from the first sub storage means and temporarily store the read program in the temporary storage means. It is configured as follows. As a result, when the pointer means is initialized by the pointer initialization means by receiving the reset signal, it is a part or all of a predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means. , Since the program including the first instruction of the predetermined program is already stored in the temporary storage means or is in the stage of being stored in the temporary storage means, it is initialized by the pointer initialization means of the arithmetic processing means. Specifies from the pointer means an address that identifies the first instruction of a given program to be executed first, a portion of the given program containing the first instruction executed by the arithmetic processing means after the reset signal is received. Alternatively, all of them can be immediately output from the temporary storage means to the arithmetic processing means. Therefore, even when the program is stored together with the image information in the first sub storage means having a slow reading speed, the program to be executed can be immediately read and the execution of the process can be started.

The gaming machine M2 is characterized in that, in the gaming machine M1, the predetermined program is a starting program that executes a starting process for enabling the operation processing means to execute various controls in the sub-control means.

According to the game machine M2, the predetermined program executed by the arithmetic processing means after receiving the reset signal is an activation program that executes the activation processing for enabling the arithmetic processing means to execute various controls in the sub-control means. Therefore, after receiving the reset signal, the start program is immediately read out and executed by the arithmetic processing means, so that various controls can be quickly executed by the sub-control means.

In the game machine M2, the sub-control means is readable and writable by the arithmetic processing means, is capable of reading operation at a higher speed than the first sub-storage means, and cannot hold information when the power is turned off. The activation program transfers the program stored in the first sub-storage means to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means. The gaming machine M3 is characterized by including an instruction for executing a process set in the address of the second storage means in which an instruction to be executed first is stored in the program.

According to the game machine M3, when the start program is first executed by the arithmetic processing means of the sub control means after receiving the reset signal, the program stored in the first sub storage means can be read out at high speed. The program is transferred to the second storage means, and after the transfer is completed, the pointer means is set to the address of the second storage means in which the instruction to be executed first among the programs transferred to the second storage means is stored. As a result, the arithmetic processing means can subsequently read the instruction from the second storage means and execute the processing, so that even when the first sub storage means having a slow reading speed stores the program together with the image information, the speed is high. Instructions can be read out.

In the game machine M3, when it is detected by the power supply detection that the power supply is started, the predetermined program stored in the temporary storage means is its activation including the first instruction in the activation program. A part of the program, and a part of the start program is the rest of the various programs stored in the first sub storage means that are not stored in the temporary storage means when the power supply is started. A predetermined amount of the program including a part or all of the start programs of the above is transferred to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means, and the remaining start programs are transferred. The gaming machine M4 is characterized by including an instruction for executing a process set in the address of the second storage means in which the instruction to be executed first is stored.

According to the gaming machine M4, when it is detected that the power supply is started by the power supply detection, the predetermined program stored in the temporary storage means is one of the start programs including the first instruction in the start program. It is a department. Then, it is a predetermined amount including a part or all of the remaining start-up programs that are not stored in the temporary storage means due to the start of power supply among the various programs stored in the first sub storage means. A second storage means in which a program is transferred to the second storage means, and after the transfer is completed, an instruction to be executed first among the remaining start programs transferred to the second storage means is stored. It contains an instruction to execute the process to set the address. As a result, even if the temporary storage means stores only a part of the start programs including the first instruction of the start programs, the start programs stored by the temporary storage means store the start programs in the first sub storage means. A predetermined amount of programs including a part or all of the remaining start programs that are not stored in the temporary storage means are transferred to the second storage means, and after the transfer is completed, the pointer means is used. Of the remaining startup programs transferred to the second storage means, the instruction to be executed first is set to the address of the second storage means, so that the remaining startup programs transferred to the second storage means are set. You can certainly do some or all of it. Therefore, even if the program size of the boot program is large, it is not necessary to store all the boot programs in the temporary storage means, so that the storage capacity of the temporary storage means can be suppressed to a small capacity.

Various types stored in the first sub storage means by the activation program stored in the temporary storage means when it is detected in the game machine M4 that the power supply is started by the power supply detection. When a predetermined amount of a program including a part of the remaining start-up program is transferred to the second storage means, the part of the start-up program transferred to the second storage means is the power supply. Of the various programs stored in the first sub-storage means excluding the start program stored in the temporary storage means immediately after the supply of the program is started, the remaining start-ups that are not transferred to the second storage means. A predetermined amount of the program including a part or all of the program is transferred to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means by the latest transfer process. The gaming machine M5 is characterized by including an instruction for executing a process set in the address of the second storage means in which an instruction to be executed first is stored in the start program of the above.

According to the game machine M5, among various programs stored in the first sub storage means by the activation program stored in the temporary storage means when it is detected that the power supply is started by the power supply detection. When a predetermined amount of programs including a part of the remaining start programs are transferred to the second storage means, some start programs transferred to the second storage means are immediately after the power supply is started. Of the various programs stored in the first sub storage means excluding the start program stored in the temporary storage means, a predetermined amount of programs including a part or all of the remaining non-transferred start programs are stored in the second storage means. The second storage means is transferred to the second storage means, and after the transfer is completed, the instruction to be executed first among the remaining start-up programs transferred to the second storage means by the latest transfer process is stored. It contains an instruction to execute a process to be set in the address of the storage means. As a result, a part of the activation program transferred to the second storage means executes a process of further transferring the non-transferred activation program to the second storage means, and after the transfer is completed, the transfer is performed to the second storage means. Execution can be started from the first instruction of the stored startup program. Therefore, even if the program size of the start program is large, the arithmetic processing means transfers the start program excluding the start program stored in the temporary storage means immediately after the power supply is started from the first sub storage means. After transferring to the two storage means, it can be reliably executed from the second storage means.

In the game machine M5, among various programs stored in the first sub storage means by the partial activation program transferred to the second storage means, the rest of the programs not transferred to the second storage means. When a predetermined amount of programs including a part of the start program is transferred to the second storage means, the power supply to the part of the start program newly transferred to the second storage means is started. Of the various programs stored in the first sub-storage means excluding the start program stored in the temporary storage means immediately after, a part of the remaining start programs not transferred to the second storage means or Of the remaining start-up programs in which a predetermined amount of programs including all of them are transferred to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means by the latest transfer process. The gaming machine M6 comprising an instruction for executing a process set in the address of the second storage means in which an instruction to be executed first is stored.

According to the game machine M6, among the various programs stored in the first sub storage means by some of the start programs transferred to the second storage means, the remaining start programs not transferred to the second storage means. When a predetermined amount of the program including a part is transferred to the second storage means, the part of the start program newly transferred to the second storage means is transferred to the temporary storage means immediately after the power supply is started. Of the various programs stored in the first sub storage means excluding the stored start program, a predetermined amount of programs including a part or all of the remaining start programs not transferred to the second storage means is stored in the second storage means. The address of the second storage means in which the instruction to be executed first among the remaining start-up programs transferred to the second storage means by the latest transfer process after the transfer is completed is stored. Contains an instruction to execute the process set in. As a result, a part of the activation program transferred to the second storage means executes a process of further transferring the non-transferred activation program to the second storage means, and after the transfer is completed, the transfer is performed to the second storage means. Execution can be started from the first instruction of the stored startup program. Therefore, even if the program size of the boot program is very large, the arithmetic processing means stores the boot program excluding the boot program stored in the temporary storage means immediately after the power supply is started as the first sub storage means. Can be reliably executed from the second storage means after being transferred from the second storage means.

In the gaming machines M3 to M6, the program stored in the second storage means is programmed so that the pointer means is always set to an address specifying an instruction included in the program stored in the second storage means. A gaming machine M7 characterized by being

According to the game machine M7, the program stored in the second storage means is programmed so that the pointer means is always set to the address specifying the instruction included in the program stored in the second storage means. Therefore, once the pointer means is set to the address that specifies the instruction included in the program stored in the second storage means, the arithmetic processing means always reads the instruction from the second storage means and executes the process. be able to. Here, the start program transfers the program stored in the first sub-storage means to the second storage means, and then the pointer means gives an instruction to be executed first among the programs transferred to the second storage means. Is set to the address of the second storage means in which the is stored, so that after the program stored in the first sub storage means is transferred to the second storage means, the arithmetic processing means is transferred to the second storage means. It is possible to always read the instruction from the program and execute the process. That is, since the arithmetic processing means can always read an instruction from the program stored in the second storage means having a high read speed and execute the process, the program is stored together with the image information in the first sub storage means having a slow read speed. Even if the program is to be transferred, the program stored in the first sub storage means is transferred to the second storage means, and then the program stored in the second storage means is immediately read out and the process is executed. Can be done.

In the gaming machines M1 to M7, the gaming machine M8 is characterized in that the first sub storage means is configured by a NAND flash memory.

According to the gaming machine M8, the first sub storage means is configured by a NAND flash memory. Here, the NAND flash memory is characterized in that a large storage capacity can be obtained in a small area and is inexpensive. Therefore, the capacity of the first storage means should be increased while suppressing the increase in cost. Can be done. Therefore, not only the image information but also the program can be easily stored in the first storage means, so that another storage means for storing the program can be unnecessary, and the cost can be reduced. Can be done. On the other hand, the NAND flash memory is characterized in that the read speed is slower than that of other memories. However, according to the configuration described in any of the gaming machines M1 to M7, the NAND flash memory having a slow read speed is used. Even when the program is stored together with the image information in the configured first sub-storage means, the program to be executed can be immediately read out and the execution of the process can be started.

It includes a main control means that performs the main control of the game, a sub-control means that operates based on a command transmitted from the main control means, and an image display means that displays an image based on the control by the sub-control means. In the gaming machine, the sub-control means stores a program executed by the arithmetic processing means together with an arithmetic processing means and image information for displaying an image on the image display means, when the power is turned off. It also has a first storage means capable of holding information, and the arithmetic processing means is generated at the start of power supply and a pointer means for designating an address that specifies an instruction of a program to be executed by the arithmetic processing means. A pointer initialization that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first based on the reset signal receiving means that receives the reset signal and the reset signal received by the reset receiving means. The first storage means includes a first storage control means for controlling the operation of the first storage means, a first sub-storage means for storing the image information and the program, and a first sub-storage means thereof. It is possible to read out at a higher speed than the sub storage means, and it is a part or all of the predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means, and is a part or all of the predetermined program. A second sub-storage means for storing a program including the first instruction and a temporary storage means for temporarily storing a predetermined set of information read from the first sub-storage means or the second sub-storage means are provided. The first storage control means receives an address in which one of the information stored in the first sub-storage means and the second sub-storage means is stored, and an address receiving means thereof. An information storage means for reading a predetermined set of information including information stored in a stored address from the first sub-storage means or the second sub-storage means and storing the information in the temporary storage means, and the information storage means thereof. An information output means for reading and outputting information specified by an address received by the address receiving means from the information stored in the temporary storage means, and a power supply detecting means for detecting that power supply has started. When the power supply detection detects that the power supply has been started, the first storage control means receives the reset signal in the arithmetic processing means. A part or all of the predetermined program to be executed first, and the program including the first instruction of the predetermined program is read from the second sub storage means, and the read program is read. The gaming machine N1 is characterized in that the information storage means is controlled so as to be temporarily stored in the temporary storage means.

According to the game machine N1, the sub-control means can hold the information even when the power is turned off to store the program executed by the arithmetic processing means together with the arithmetic processing means and the image information for displaying the image on the image display means. It has a first storage means. Further, the arithmetic processing means includes a pointer means for designating an address for specifying an instruction of a program to be executed by the arithmetic processing means, a reset signal receiving means for receiving a reset signal generated at the start of power supply, and a reset receiving means thereof. Based on the reset signal received by the means, the first storage means has a pointer initialization means that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first. A first storage control means for controlling the operation of the first storage means, a first sub storage means for storing image information and a program, and a read operation at a higher speed than the first sub storage means are possible, and arithmetic processing is possible. A second sub-storage means for storing a program that is a part or all of a predetermined program to be executed first based on the reception of the reset signal in the means and includes the first instruction of the predetermined program, and a first sub-storage. It has a temporary storage means for temporarily storing a predetermined set of information read from the means or the second sub storage means. Further, the first storage control means is received by an address receiving means that receives an address in which one of the information stored in the first sub storage means and the second sub storage means is stored, and an address receiving means thereof. An information storage means that reads a predetermined set of information including the information stored in the address from the first sub storage means or the second sub storage means and stores the information in the temporary storage means, and the information storage means in the temporary storage means. It has an information output means for reading and outputting information specified by an address received by the address receiving means from the stored information, and a power supply detecting means for detecting that the power supply has started. ..

Here, the first storage control means is a part of a predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means when it is detected that the power supply is started by the power supply detection. Or, the information storage means is controlled so as to read the program including the first instruction of the predetermined program from the second sub storage means and temporarily store the read program in the temporary storage means. It is configured as follows. As described above, since the second sub storage means can perform a read operation at a higher speed than the first sub storage means, it is stored in the second sub storage means when the start of power supply is detected. If the program is read out and stored in the temporary storage means, when the pointer means is initialized by the pointer initialization means by receiving the reset signal, the arithmetic processing means should first execute the program based on the reception of the reset signal. A part or all of the program of the above, and the program including the first instruction of the predetermined program is already stored in the temporary storage means or is being stored in the temporary storage means. Therefore, when the pointer means specifies an address that specifies the first instruction of a predetermined program to be executed first by the initialization by the pointer initialization means of the arithmetic processing means, the arithmetic processing means executes it after receiving the reset signal. A part or all of a predetermined program including the first instruction to be executed can be immediately output from the temporary storage means to the arithmetic processing means. Therefore, even when the program is stored together with the image information in the first sub storage means having a slow reading speed, the program to be executed can be immediately read and the execution of the process can be started.

The gaming machine N1 is characterized in that the predetermined program is a starting program for executing a starting process for enabling the operation processing means to execute various controls in the sub-control means.

According to the game machine N2, the predetermined program executed by the arithmetic processing means after receiving the reset signal is an activation program that executes the activation processing for enabling the arithmetic processing means to execute various controls in the sub-control means. Therefore, after receiving the reset signal, the start program is immediately read out and executed by the arithmetic processing means, so that various controls can be quickly executed by the sub-control means.

In the game machine N2, the sub-control means is readable and writable by the arithmetic processing means, is capable of reading operation at a higher speed than the first sub-storage means, and cannot hold information when the power is turned off. The activation program transfers the program stored in the first sub-storage means to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means. The gaming machine N3 comprising an instruction for executing a process set in the address of the second storage means in which an instruction to be executed first among the programs is stored.

According to the game machine N3, when the start program is first executed by the arithmetic processing means of the sub control means after receiving the reset signal, the program stored in the first sub storage means can be read out at high speed. The program is transferred to the second storage means, and after the transfer is completed, the pointer means is set to the address of the second storage means in which the instruction to be executed first among the programs transferred to the second storage means is stored. As a result, the arithmetic processing means can subsequently read the instruction from the second storage means and execute the processing, so that even when the first sub storage means having a slow reading speed stores the program together with the image information, the speed is high. Instructions can be read out.

In the game machine N3, the second sub storage means stores a part of the start program including the first instruction in the start program, and the first sub storage means is the second sub of the start program. Various programs are stored including the remaining start programs that are not stored in the storage means, and the start program stored in the second sub storage means is stored in the first sub storage means. Among various programs, a predetermined amount of programs including a part or all of the remaining startup programs are transferred to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means. The gaming machine N4 comprising an instruction to execute a process set in the address of the second storage means in which an instruction to be executed first among the remaining startup programs is stored.

According to the game machine N4, the second sub storage means stores a part of the start program including the first instruction in the start program, while the first sub storage means stores the second of the start programs. Various programs are stored in the sub-storage means, including the remaining startup programs that are not stored. Then, the start program stored in the second sub storage means is a part or all of the remaining start programs that are not stored in the second sub storage means among the various programs stored in the first sub storage means. A predetermined amount of programs including It contains an instruction to execute a process to be set in the address of the second storage means. As a result, even if only a part of the start programs including the first instruction of the start programs is stored in the second sub storage means, the start program stored by the second sub storage means can be used for the first step. Of the various programs stored in the sub-storage means, a predetermined amount of programs including a part or all of the remaining activation programs that are not stored in the second sub-storage means are transferred to the second storage means, and the transfer thereof. Is completed, the pointer means is set to the address of the second storage means in which the instruction to be executed first among the remaining start programs transferred to the second storage means is stored, so that the second storage means is used. You can be sure that some or all of the remaining startup programs that have been transferred will be executed. Therefore, since it is not necessary to store all the activation programs in the second sub storage means, the storage capacity of the second sub storage means can be suppressed to a small capacity.

In the game machine N4, a predetermined amount of programs including a part of the remaining activation programs among various programs stored in the first sub storage means by the activation program stored in the second sub storage means. Is transferred to the second storage means, the partial activation program transferred to the second storage means is the second storage among various programs stored in the first sub storage means. A predetermined amount of programs including a part or all of the remaining start programs that are not transferred to the means are transferred to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means by the latest transfer process. (2) A gaming machine comprising an instruction to execute a process set in the address of the second storage means in which an instruction to be executed first among the remaining start programs transferred to the storage means is stored. N5.

According to the game machine N5, among the various programs stored in the first sub storage means by the start program stored in the second sub storage means, the remaining start programs that are not stored in the second sub storage means. When a predetermined amount of programs including a part of the above are transferred to the second storage means, the part of the activation program transferred to the second storage means is among various programs stored in the first sub storage means. , A predetermined amount of programs including a part or all of the remaining non-transferred start-up program is transferred to the second storage means, and after the transfer is completed, the pointer means is transferred by the latest transfer process. (2) Among the remaining startup programs transferred to the storage means, the instruction to execute the process set in the address of the second storage means in which the instruction to be executed first is stored is included. As a result, a part of the activation program transferred to the second storage means executes a process of further transferring the non-transferred activation program to the second storage means, and after the transfer is completed, the transfer is performed to the second storage means. Execution can be started from the first instruction of the stored startup program. Therefore, even when the program size of the start program is large, the arithmetic processing means transfers the start program excluding the start program stored in the second sub storage means from the first sub storage means to the second storage means. Above, it can be reliably executed from the second storage means.

In the game machine N5, among the various programs stored in the first sub-storage means by the partial activation program transferred to the second storage means, the rest of the programs not transferred to the second storage means. When a predetermined amount of programs including a part of the start program is transferred to the second storage means, the part of the start program newly transferred to the second storage means is transferred to the first sub storage means. Among the various stored programs, a predetermined amount of programs including a part or all of the remaining activation programs that are not transferred to the second storage means are transferred to the second storage means, and the transfer is completed. Later, a process of setting the pointer means to the address of the second storage means in which the instruction to be executed first among the remaining start-up programs transferred to the second storage means by the latest transfer process is executed is executed. A game machine N6 characterized by including a command to be executed.

According to the game machine N6, among the various programs stored in the first sub storage means by some of the activation programs transferred to the second storage means, the remaining programs that are not stored in the second sub storage means. When a predetermined amount of the program including a part of the start program is transferred to the second storage means, the part of the start program newly transferred to the second storage means is stored in the first sub storage means. Of the various programs, a predetermined amount of programs including a part or all of the remaining non-transferred startup programs are transferred to the second storage means, and after the transfer is completed, the pointer means is immediately moved to the second storage means. It includes an instruction to execute a process of setting to the address of the second storage means in which the instruction to be executed first among the remaining start programs transferred to the second storage means by the transfer process is stored. As a result, a part of the activation program transferred to the second storage means executes a process of further transferring the non-transferred activation program to the second storage means, and after the transfer is completed, the transfer is performed to the second storage means. Execution can be started from the first instruction of the stored startup program. Therefore, even when the program size of the start program is very large, the arithmetic processing means changes the start program excluding the start program stored in the second sub storage means from the first sub storage means to the second sub storage means. After transferring, it can be reliably executed from the second storage means.

In the gaming machines N3 to N6, the program stored in the second storage means is programmed so that the pointer means is always set to an address specifying an instruction included in the program stored in the second storage means. The gaming machine N7, which is characterized by being

According to the game machine N7, the program stored in the second storage means is programmed so that the pointer means is always set to the address specifying the instruction included in the program stored in the second storage means. Therefore, once the pointer means is set to the address that specifies the instruction included in the program stored in the second storage means, the arithmetic processing means always reads the instruction from the second storage means and executes the process. be able to. Here, the start program transfers the program stored in the first sub-storage means to the second storage means, and then the pointer means gives an instruction to be executed first among the programs transferred to the second storage means. Is set to the address of the second storage means in which the is stored, so that after the program stored in the first sub storage means is transferred to the second storage means, the arithmetic processing means is transferred to the second storage means. It is possible to always read the instruction from the program and execute the process. That is, since the arithmetic processing means can always read an instruction from the program stored in the second storage means having a high read speed and execute the process, the program is stored together with the image information in the first sub storage means having a slow read speed. Even if the program is to be transferred, the program stored in the first sub storage means is transferred to the second storage means, and then the program stored in the second storage means is immediately read out and the process is executed. Can be done.

In the gaming machines N1 to N7, the gaming machine N8 is characterized in that the first sub storage means is configured by a NAND flash memory.

According to the gaming machine N8, the first sub storage means is configured by a NAND flash memory. Here, the NAND flash memory is characterized in that a large storage capacity can be obtained in a small area and is inexpensive. Therefore, the capacity of the first storage means should be increased while suppressing an increase in cost. Can be done. Therefore, not only the image information but also the program can be easily stored in the first storage means, so that another storage means for storing the program can be unnecessary, and the cost can be reduced. Can be done. On the other hand, the NAND flash memory is characterized in that the read speed is slower than that of other memories. However, according to the configuration described in any of the gaming machines N1 to N7, the NAND flash memory having a slow read speed is used. Even when the program is stored together with the image information in the configured first sub-storage means, the program to be executed can be immediately read out and the execution of the process can be started.

In the gaming machines N1 to N8, the gaming machine N9 is characterized in that the second sub storage means is configured by a NOR type ROM.

According to the gaming machine N9, the second sub storage means is configured by a NOR type ROM. Here, since the NOR type ROM is characterized in that it can perform a read operation at high speed, it is a part or all of a predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means. By storing the program including the first instruction of the predetermined program in this NOR type ROM, the reset signal is accepted even when the program is stored together with the image information in the first sub storage means having a slow read speed. A program to be executed later can be immediately read from the NOR type ROM when the power supply is detected, stored in the temporary storage means, and then output to the arithmetic processing means. Therefore, the arithmetic processing means can immediately start the execution of the processing.

In the gaming machines N1 to N8, the gaming machine N10 is characterized in that the second sub-storage means is built in the first storage control means.

According to the gaming machine N10, since the second sub storage means is built in the first storage control means, the first storage control means can perform a high-speed reading operation from the second sub storage means. .. Therefore, a part or all of a predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means, and the program including the first instruction of the predetermined program is stored in the second sub storage means. Therefore, even when the program is stored together with the image information in the first sub storage means having a slow read speed, the program to be executed after receiving the reset signal is triggered by the detection of the power supply. 2. The program can be immediately read from the sub-storage means, stored in the temporary storage means, and then output to the arithmetic processing means. Therefore, the arithmetic processing means can immediately start the execution of the processing.

It is provided with a main control means that performs the main control of the game, a sub-control means that operates based on a command transmitted from the main control means, and an image display means that displays an image based on the control by the sub-control means. In the gaming machine, the sub-control means stores a program executed by the arithmetic processing means together with an arithmetic processing means and image information for displaying an image on the image display means, when the power is turned off. A first storage means capable of holding information, and a predetermined program that can be read out at a higher speed than the first storage means and is first executed by the arithmetic processing means, and is a predetermined program of the predetermined program. The arithmetic processing means includes a program storage means that stores a part or all of the predetermined program including the first instruction and can retain information even when the power is turned off, and the arithmetic processing means is a program to be executed by the arithmetic processing means. A predetermined pointer to be executed first based on a pointer means for designating an address specifying an instruction, a reset signal receiving means for receiving a reset signal generated at the start of power supply, and a reset signal received by the reset receiving means. A pointer initialization means for initializing the pointer means is provided at an address specifying the first instruction of the program, and the program storage means is a predetermined program first executed by the arithmetic processing means. When an address specifying an instruction included in a part or all of the predetermined program including the first instruction of the predetermined program is specified by the pointer means, the instruction specified by the address specified by the pointer means is specified. A game machine O1 characterized in that the program is read and output.

According to the game machine O1, the sub-control means can hold the information even when the power is turned off to store the program executed by the arithmetic processing means together with the arithmetic processing means and the image information for displaying the image on the image display means. A predetermined program that can be read out at a higher speed than that of the first storage means and the first storage means, and is first executed by the arithmetic processing means, and includes the first instruction of the predetermined program. It has a program storage means that stores a part or all of the program and can retain information even when the power is turned off. Further, the arithmetic processing means includes a pointer means for designating an address for specifying an instruction of a program to be executed by the arithmetic processing means, a reset signal receiving means for receiving a reset signal generated at the start of power supply, and a reset receiving means thereof. It has a pointer initialization means that initializes the pointer means to an address that specifies the first instruction of a predetermined program to be executed first based on the reset signal received by the means.

Here, the program storage means is an address that is a predetermined program that is first executed by the arithmetic processing means and specifies an instruction included in a part or all of a predetermined program including the first instruction of the predetermined program. Is configured to read and output the instruction specified by the address specified by the pointer means when is specified by the pointer means. Then, as described above, the program storage means can perform a read operation at a higher speed than the first storage means, so that the predetermined program to be executed first is initialized by the pointer initialization means of the arithmetic processing means. When the address that identifies the first instruction is specified by the pointer means, a part or all of a predetermined program including the first instruction executed by the arithmetic processing means after receiving the reset signal is immediately read from the program storage means. It can be output to the arithmetic processing means. Therefore, even when the program is stored together with the image information in the first storage means having a slow reading speed, the program to be executed can be immediately read out and the execution of the process can be started.

The gaming machine O2 is characterized in that, in the gaming machine O1, the predetermined program is a starting program that executes a starting process for enabling various controls in the sub-control means in the arithmetic processing means.

According to the game machine O2, the predetermined program executed by the arithmetic processing means after receiving the reset signal is an activation program that executes the activation processing for enabling the arithmetic processing means to execute various controls in the sub-control means. Therefore, after receiving the reset signal, the start program is immediately read out and executed by the arithmetic processing means, so that various controls can be quickly executed by the sub-control means.

In the game machine O2, the sub-control means can read and write by the arithmetic processing means, can read out at a higher speed than the first storage means, and cannot hold information when the power is turned off. In addition, the activation program transfers the program stored in the first storage means to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means. The gaming machine O3 is characterized by including an instruction for executing a process set in the address of the second storage means in which the instruction to be executed first is stored.

According to the game machine O3, when the start program is first executed by the arithmetic processing means of the sub-control means after receiving the reset signal, the program stored in the first storage means can be read out at high speed. It is transferred to the second storage means, and after the transfer is completed, the pointer means is set to the address of the second storage means in which the instruction to be executed first among the programs transferred to the second storage means is stored. As a result, when the program stored in the first storage means is transferred to the second storage means capable of high-speed reading operation, the arithmetic processing means subsequently reads an instruction from the second storage means. Therefore, even when the program is stored together with the image information in the first storage means having a slow reading speed, the instruction can be read at high speed.

In the game machine O3, the program storage means stores a part of the start program including the first instruction in the start program, and the first storage means does not store the start program in the program storage means. Various programs are stored including the remaining start-up program, and the start-up program stored in the program storage means is the remaining of the various programs stored in the first storage means. A predetermined amount of the program including a part or all of the start program is transferred to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means of the remaining start program. The gaming machine O4 is characterized by including an instruction for executing a process set in the address of the second storage means in which the instruction to be executed first is stored.

According to the game machine O4, the program storage means stores a part of the start program including the first instruction in the start program, while the first storage means is not the program storage means of the start program. Various programs are stored, including the remaining startup programs that are stored. The start program stored in the program storage means is a predetermined amount including a part or all of the remaining start programs that are not stored in the program storage means among the various programs stored in the first storage means. A second storage means in which a program is transferred to the second storage means, and after the transfer is completed, an instruction to be executed first among the remaining start programs transferred to the second storage means is stored. It contains an instruction to execute the process to set the address. As a result, even if the program storage means stores only a part of the start programs including the first instruction of the start programs, the start program stored by the program storage means stores the start programs in the first storage means. A predetermined amount of programs including a part or all of the remaining start programs that are not stored in the program storage means are transferred to the second storage means, and after the transfer is completed, the pointer means is used. Is set to the address of the second storage means in which the instruction to be executed first among the remaining start programs transferred to the second storage means is stored, so that the remaining start program transferred to the second storage means is set. You can reliably execute some or all of. Therefore, since it is not necessary to store all the startup programs in the program storage means, the storage capacity of the program storage means can be suppressed to a small capacity.

In the game machine O4, among the various programs stored in the first storage means by the activation program stored in the program storage means, a predetermined amount of programs including a part of the remaining activation program is the first. 2 When transferred to the storage means, the partial activation program transferred to the second storage means is not transferred to the second storage means among various programs stored in the first storage means. A predetermined amount of programs including a part or all of the remaining start-up programs are transferred to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means by the latest transfer process. The gaming machine O5 comprising an instruction to execute a process set in the address of the second storage means in which an instruction to be executed first among the transferred remaining activation programs is stored.

According to the game machine O5, among various programs stored in the first storage means by the start program stored in the program storage means, a part of the remaining start programs that are not stored in the program storage means is included. When a predetermined amount of programs are transferred to the second storage means, some of the activation programs transferred to the second storage means are transferred to the second storage means among various programs stored in the first storage means. A predetermined amount of programs including a part or all of the remaining non-transferred start programs are transferred to the second storage means, and after the transfer is completed, the pointer means is transferred to the second storage means by the latest transfer process. It contains an instruction to execute a process to be set in the address of the second storage means in which the instruction to be executed first among the remaining startup programs is stored. As a result, a part of the activation program transferred to the second storage means executes a process of further transferring the non-transferred activation program to the second storage means, and after the transfer is completed, the transfer is performed to the second storage means. Execution can be started from the first instruction of the stored startup program. Therefore, even if the program size of the boot program is large, the arithmetic processing means transfers all the boot programs except the boot program stored in the program storage means from the first storage means to the second storage means. Then, it can be surely executed from the second storage means.

In the game machine O5, among the various programs stored in the first storage means by the partial activation program transferred to the second storage means, the remaining activation not transferred to the second storage means. When a predetermined amount of the program including a part of the program is transferred to the second storage means, the part of the activation program newly transferred to the second storage means is stored in the first storage means. Of the various programs, a predetermined amount of programs including a part or all of the remaining start programs that are not transferred to the second storage means are transferred to the second storage means, and after the transfer is completed, the transfer is completed. An instruction to execute a process of setting the pointer means to the address of the second storage means in which an instruction to be executed first among the remaining activation programs transferred to the second storage means by the latest transfer process is stored. A game machine O6 characterized by containing.

According to the game machine O6, among the various programs stored in the first storage means by some of the start programs transferred to the second storage means, the remaining start-ups that are not stored in the second sub-storage means. When a predetermined amount of programs including a part of the program is transferred to the second storage means, the part of the activation program newly transferred to the second storage means is various programs stored in the first storage means. Of these, a predetermined amount of programs including a part or all of the remaining non-transferred start-up programs are transferred to the second storage means, and after the transfer is completed, the pointer means is immediately transferred. Of the remaining start-up programs transferred to the second storage means, the instruction to be executed first includes an instruction to execute a process set in the address of the second storage means in which the instruction to be executed is stored. As a result, a part of the activation program transferred to the second storage means executes a process of further transferring the non-transferred activation program to the second storage means, and after the transfer is completed, the transfer is performed to the second storage means. Execution can be started from the first instruction of the stored startup program. Therefore, even if the program size of the start program is very large, the arithmetic processing means transfers the start program excluding the start program stored in the second sub storage means from the first storage means to the second storage means. Then, it can be surely executed from the second storage means.

In the gaming machines O3 to O6, the program stored in the second storage means is programmed so that the pointer means is always set to an address specifying an instruction included in the program stored in the second storage means. The gaming machine O7 characterized by being

According to the game machine O7, the program stored in the second storage means is programmed so that the pointer means is always set to the address specifying the instruction included in the program stored in the second storage means. Therefore, once the pointer means is set to the address that specifies the instruction included in the program stored in the second storage means, the arithmetic processing means always reads the instruction from the second storage means and executes the process. be able to. Here, the start program transfers the program stored in the first storage means to the second storage means, and then the pointer means receives the instruction to be executed first among the programs transferred to the second storage means. Since it is set to the address of the stored second storage means, after the program stored in the first storage means is transferred to the second storage means, the arithmetic processing means is the program transferred to the second storage means. It is possible to always read the instruction from and execute the process. That is, since the arithmetic processing means can always read an instruction from the program stored in the second storage means having a high read speed and execute the process, the first storage means having a slow read speed stores the program together with the image information. Even in this case, the program stored in the first storage means can be transferred to the second storage means, and then the program stored in the second storage means can be immediately read out and the process can be executed. ..

In the gaming machines O1 to O7, the gaming machine O7 is characterized in that the first storage means is configured by a NAND flash memory.

According to the gaming machine O8, the first storage means is configured by a NAND flash memory. Here, the NAND flash memory is characterized in that a large storage capacity can be obtained in a small area and is inexpensive. Therefore, the capacity of the first storage means should be increased while suppressing an increase in cost. Can be done. Therefore, not only the image information but also the program can be easily stored in the first storage means. On the other hand, the NAND flash memory is characterized in that the read speed is slower than that of other memories. However, according to the configuration described in any of the gaming machines O1 to O7, the NAND flash memory having a slow read speed is used. Even when the first storage means configured stores the program together with the image information, the program to be executed can be immediately read out and the execution of the process can be started.

In the gaming machines O1 to O8, the gaming machine O9 is characterized in that the program storage means is configured by a NOR type ROM.

According to the gaming machine O9, the program storage means is configured by a NOR type ROM. Here, since the NOR type ROM is characterized in that it can perform a read operation at high speed, it is a part or all of a predetermined program to be executed first based on the reception of the reset signal in the arithmetic processing means. By storing the program including the first instruction of the predetermined program in this NOR type ROM, even when the program is stored together with the image information in the first storage means having a slow read speed, after receiving the reset signal. The program to be executed can be immediately read from the NOR type ROM, and the program can be output to the arithmetic processing means. Therefore, the arithmetic processing means can immediately start the execution of the processing.

A1 to A6, B1 to B8, C1 to C7, D1 to D8, E1 to E5, F1 to F6, G1 to G5, H1 to H5, I1 to I6, J6 to J6, K1 to K5, L1 to L10, A gaming machine P1 characterized in that the gaming machine is a slot machine in any of M1 to M8, N1 to N10, and O1 to O9. Among them, the basic configuration of the slot machine is "provided with a variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming the display of the identification information, and for operating a starting operation means (for example, an operation lever). Due to this, the dynamic display of the identification information is started, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (stop button) or after a predetermined time has elapsed, and at the time of the stop. It is a gaming machine provided with a special gaming state generating means for generating a special gaming state advantageous to the player, provided that the definite identification information of the above is the specific identification information. In this case, coins, medals, and the like are typical examples of the game medium.

A1 to A6, B1 to B8, C1 to C7, D1 to D8, E1 to E5, F1 to F6, G1 to G5, H1 to H5, I1 to I6, J6 to J6, K1 to K5, L1 to L10, A gaming machine P2, wherein the gaming machine is a pachinko gaming machine in any of M1 to M8, N1 to N10, and O1 to O9. Among them, the basic configuration of the pachinko gaming machine is provided with an operation handle, and the ball is launched into a predetermined game area according to the operation of the operation handle, and the ball is placed in a predetermined position in the game area. The identification information dynamically displayed on the display device is fixedly stopped after a predetermined time, provided that the prize is won (or passed through the operating port). Further, when a special gaming state occurs, a variable winning device (specific winning opening) arranged at a predetermined position in the gaming area is opened in a predetermined manner to enable a ball to be won, and is valuable according to the number of winnings. Some are given value (including not only prize balls but also data written on a magnetic card).

A1 to A6, B1 to B8, C1 to C7, D1 to D8, E1 to E5, F1 to F6, G1 to G5, H1 to H5, I1 to I6, J6 to J6, K1 to K5, L1 to L10, A gaming machine P3 characterized in that, in any one of M1 to M8, N1 to N10, and O1 to O9, the gaming machine is a fusion of a pachinko gaming machine and a slot machine. Among them, as a basic configuration of the fused gaming machine, "a variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming and displaying the identification information is provided, and a starting operation means (for example, an operation lever). The fluctuation of the identification information is started due to the operation of, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (for example, the stop button) or after a predetermined time elapses. A special gaming state generating means for generating a special gaming state advantageous to the player is provided on the condition that the definite identification information at the time of stopping is the specific identification information, the ball is used as the game medium, and the identification information is described. A game machine that requires a predetermined number of balls to start the dynamic display of, and is configured to pay out a large number of balls when a special gaming state occurs. "
(others)
Conventionally, in a gaming machine such as a slot machine, various production images are displayed on a display device such as a liquid crystal display device to improve the interest of the game. In such a game machine, generally, the image information of the image to be displayed on the display device is stored in the storage means in advance, and when the image is displayed, the corresponding image information is read from the storage means and the image processing is performed. After applying the image, the image is displayed on a display device (for example, Patent Document 1: Japanese Patent Application Laid-Open No. 2006-223598).
By the way, in recent gaming machines, images displayed on display devices have become diversified and complicated in order to further enhance the interest of players. As a storage means for storing image information of such an image, there is a demand that a large storage capacity can be obtained in a small area and an inexpensive one can be used.
Further, when an inexpensive storage means for storing image information is used, which can obtain a large storage capacity in a small area, the storage means also stores a program for controlling a display device or the like together with the image information. There may be a desire to let them do it.
However, some inexpensive storage means that can obtain a large storage capacity in a small area have a slow speed for reading information (reading speed), and when the program is stored in such a storage means, for example, execution is performed. There was a possibility that the program to be read could not be read immediately and the execution of the process could not be started.
The present technical idea was made to solve the above-exemplified problems and the like, and while storing the program in the storage means for storing the image information, the program to be executed is immediately read out and the processing is executed. The purpose is to provide a gaming machine that can be started.

10 slot machine (game machine)
65 Auxiliary display unit (image display means)
81 Display control device (secondary control means)
101 Main control device (main control means)
181 MPU (arithmetic processing means, reset signal receiving means, pointer initialization means)
181a Command pointer (pointer means)
185 work RAM (second storage means)
185d Data table storage area (1st specified information storage means, 3rd specified information storage means)
185h pointer (first pointer means)
187 Character ROM (1st image information storage means, 1st storage means)
187a NAND flash memory (first sub storage means)
187b ROM controller (first storage control means, address reception means, information storage means, information output means)
187c Buffer RAM (temporary storage means)
187d NOR type ROM (second sub storage means)
188 Image controller (image drawing means)
189 Resident video RAM (third image information storage means)
190 Normal video RAM (second image information storage means)
191d Data table storage area (1st specified information storage means, 3rd specified information storage means)
192d Data table storage area (1st regulation information storage means)
195 Character ROM (1st image information storage means, 1st storage means)
195a NAND flash memory (first sub storage means)
195b ROM controller (first storage control means, address reception means, information storage means, information output means, power supply detection means)
195c buffer RAM (temporary storage means)
196 Character ROM (1st image information storage means, 1st storage means)
196a NAND flash memory (first sub storage means)
196b ROM controller (first storage control means, address reception means, information storage means, information output means)
196c Buffer RAM (temporary storage means)
196d NOR type ROM (second sub storage means)
197 Character ROM (1st image information storage means, 1st storage means)
198 NOR type ROM (program storage means)
200 Pachinko machine (game machine)
281 Third symbol display device (image display means)
310 Main controller (main control means)
313 Voice lamp control device (part of sub control means)
314 Display control device (part of sub control means)
423a Number of reserved balls counter (means for storing the number of waiting times)
431 MPU (arithmetic processing means, reset signal receiving means, pointer initialization means)
431a Command pointer (pointer means)
433 Work RAM (second storage means)
433b Data table storage area (1st specified information storage means, 2nd specified information storage means, 3rd specified information storage means)
434 Character ROM (1st image information storage means, 1st storage means)
434a NAND flash memory (first sub storage means)
434b ROM controller (first storage control means, address reception means, information storage means, information output means)
434c Buffer RAM (temporary storage means)
434d NOR type ROM (second sub storage means)
435 Resident video RAM (third image information storage means)
436 Normal video RAM (second image information storage means)
437 image controller (image drawing means)
451b Data table storage area (1st specified information storage means, 2nd specified information storage means, 3rd specified information storage means)
452b Data table storage area (1st regulation information storage means)
534 Character ROM (first image information storage means, first storage means)
534a NAND flash memory (first sub storage means)
534b ROM controller (first storage control means, address reception means, information storage means, information output means, power supply detection means)
534c Buffer RAM (temporary storage means)
634 Character ROM (first image information storage means, first storage means)
634a NAND flash memory (first sub storage means)
634b ROM controller (first storage control means, address reception means, information storage means, information output means)
634c Buffer RAM (temporary storage means)
634d NOR type ROM (second sub storage means)
734 Character ROM (1st image information storage means, 1st storage means)
735 NOR type ROM (program storage means)
S701 Boot processing (starting processing)
S703 (part of the second transfer control means)
S738 (part of the first display determination means)
S740 (part of the first display determination means)
S772 (part of the first selection means, part of the third selection means)
S783 (part of the first selection means, part of the third selection means)
S806, S810, S812 (1st pointer means, 3rd pointer means)
S808 (part of the first display determining means)
S809 (part of the first selection means)
S813 (means for specifying drawing information)
S817 Resident image transfer setting process (part of the second transfer control means)
S818 Normal image transfer setting process (first transfer control means)
S833 (Transfer information identification means)
S851 (drawing instruction information generation means, instruction information generation means)
S901 (part of the first selection means, part of the third selection means, part of the second specified information generation means)
S903 (part of the first selection means, part of the third selection means, part of the second specified information generation means)
S906 (part of the first display determination means)
S907 (part of the first selection means)
S910 (means for specifying drawing information)
S921 (part of the first selection means)
S922 (part of the first selection means)
S923 (part of the first selection means)
S1213 (first command generation means)
S1302 to S1305 (Dynamic display effect determination means)
S1306 (second command generation means)
S1307 (third command generation means)
S1701 (command transmission means)
S2201 Boot processing (starting processing)
S2203, S2204 (part of the second transfer control means)
S2507 Confirmation command processing (confirmation means)
S2508 (part of the first display determination means)
S2510 (part of the first display determination means)
S2515 (second display determining means)
S2621 (part of the first selection means)
S2622 (part of the second selection means, part of the third selection means)
S2631 (part of the first selection means)
S2632 (part of the third selection means)
S2633 (part of the second selection means)
S2641 (Identification information determination means)
S2652 (part of the second selection means)
S2711 Pointer update process (first pointer means, second pointer means, third pointer means)
S2712 (means for specifying drawing information)
S2714 (Means for determining the passage of time in the first time)
S2715 (part of the first display determination means)
S2716 (part of the first selection means, part of the second selection means, part of the third selection means)
S2721 (Identification information storage means)
S2722 (part of the first display determination means)
S2724 (part of the first selection means)
S2730 (second time elapsed determination means, part of first display determination means)
S2731 (Part of the first selection means, part of the second selection means, part of the third selection means)
S2783 (Part of the first display determining means, dynamic display determining means)
S2784 (part of the first selection means, part of the second selection means, part of the third selection means)
S2785 (Identification information setting means)
S3002 Resident image transfer setting process (part of the second transfer control means)
S3003 Normal image transfer setting process (first transfer control means)
S3203 (Transfer information identification means)
S3301 (Drawing instruction information generation means, instruction information generation means)
S3621 (part of the first selection means)
S3631 (part of the first selection means)
S3652 (second selection means, first regulation information generation means)
S3712 (means for specifying drawing information)
S3716 (part of the first selection means)
S3724 (part of the first selection means)
S3731 (part of the first selection means)
S3784 (part of the first selection means)
S5712 to S5714 (means for specifying drawing information)
S5716 (part of the first selection means)
S5724 (part of the first selection means)
S5731 (part of the first selection means)
S5784 (part of the first selection means)

Claims (1)

The main control means that performs the main control of the game, the main display means that is display-controlled by the main control means, the sub-control means that operates based on the command transmitted from the main control means, and the sub-control means thereof. A gaming machine equipped with an image display means for displaying an image based on control.
The sub-control means
An image drawing means for drawing an image for one screen to be displayed on the image display means, and an image drawing means.
A first image storage means for storing a plurality of image information used for drawing an image by the image drawing means, and a first image storage means.
A first display specifying means for specifying a predetermined display mode for dynamically displaying identification information on the image display means from a plurality of display modes in response to a predetermined command received from the main control means.
A first-defined information storage means for storing first-defined information that defines drawing information indicating information necessary for drawing each display mode for each screen, and
The first specifying means for specifying the first specified information corresponding to the predetermined display mode specified by the first display specifying means, and
Update means that are updated every predetermined time elapsed, and
Every time the update means is updated, drawing instruction information for instructing the image drawing means to draw an image for one screen based on the drawing information for one screen corresponding to the updated update means. Drawing instruction information generation means to generate
Equipped with a measuring means that can measure time,
The image drawing means draws an image for one screen using the image information based on the drawing instruction information generated by the drawing instruction information generating means.
In the display mode for dynamically displaying the identification information on the image display means, the time required from the start to the end of the dynamic display is predetermined for each display mode.
The sub-control means
When the required time has elapsed since the display was started in the predetermined display mode specified by the first display specifying means, the first specified information used for the dynamic continuous display of the identification information to be continuously displayed is specified. Equipped with a second specific means,
When the command transmitted from the main control means is the predetermined command, the sub control means that has received the predetermined command displays the dynamic display of the identification information of the time corresponding to the predetermined command by the first display specifying means. It is executed in the predetermined display mode specified by
There are multiple times corresponding to the predetermined command,
Even if the predetermined display mode specified by the first display specifying means is a display mode in which the required time is different, the display of the dynamic continuous display of the identification information that is continuously displayed when the required time has elapsed. The modes are the same display mode,
The sub-control means
When a predetermined command is received from the main control means during the dynamic continuous display period of the identification information, the dynamic display of the identification information that was executed before the dynamic continuous display of the identification information is confirmed and displayed. Instead, the image display means is provided with a dynamic display control means for initiating the dynamic display of the identification information based on the predetermined display mode specified by the first display specifying means for the received predetermined command.
The main control means
The main display means is made to execute a predetermined switching display for a time corresponding to the predetermined command transmitted to the sub control means, and when the time elapses, the dynamic continuous display of the identification information is executed in the image display means. Regardless of the above, the gaming machine is provided with a main display control means for controlling the main display means to be fixedly displayed.

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