JP2004008807A5 - - Google Patents

Description

Gaming machine

The present invention relates to a gaming machine typified pachinko machines, and in particular relates to a gaming machine capable of preventing abuse by "hanging board" or the like.

  This kind of pachinko gaming machine is provided with a display device capable of variably displaying a plurality of types of symbols, and is configured to start the variability display when a hit ball hit into the game area passes through a symbol operation gate. . When the variable display is stopped in accordance with a predetermined combination of symbols, a big hit occurs, a predetermined game value is given to the player, and a large amount of game balls can be paid out.

The presence or absence of such a big hit is determined at the timing when the hit ball passes through the symbol operation gate. That is, a random number counter that is periodically updated by one count in a certain range (for example, every 1 ms, every 2 ms, in the range of 0 to 630) is provided, and when a hit ball passes the symbol operation gate, The value of the random number counter is read, and if the read value of the random number counter matches a predetermined value such as “7”, a big hit is generated .

However, recently, fraudulent activities using a fraudulent substrate called a “hanging substrate” have been reported. This fraudulent act involves hanging an improper board (attaching an improper “hanging board”) between a control board and a display board or the like of a display device, thereby causing an unreasonable jackpot. Specifically, a counter (a counter that is periodically updated in a predetermined range by one count) that functions similarly to the random number counter for determining the jackpot provided in the pachinko gaming machine is included in the “hanging board”. And resets (clears to 0) the value of the counter in response to the power-on of the pachinko gaming machine, thereby grasping the timing of occurrence of a jackpot in the "hanging board". Then, in accordance with the timing of the occurrence of the jackpot, the falsely generated signal for passing the gate operation symbol for the hit ball in the "hanging board" is output to the control board of the pachinko machine, thereby generating an unreasonable jackpot. It is to let. Amusement arcades and the like have suffered enormous damage due to fraudulent activities using the “hanging board”.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problem, and provides a gaming machine that makes it impossible to grasp the timing of occurrence of a jackpot and prevents fraud using a "hanging board" or the like. It is intended to be.

In order to achieve this object, the gaming machine according to claim 1 comprises a random number counter, first updating means for updating the value of the random number counter within a predetermined range, and a value of the random number counter based on a predetermined trigger. And a control means for giving a predetermined game value to the player when the value of the random number counter read by the reading means matches a predetermined value, The value of the counter makes one round by being updated a predetermined number of times by the first updating means. When the value of the random number counter makes one round, the first updating means makes one of the values within the predetermined range. And updating the next round as an initial value of the update, wherein the control means changes the update initial value of the first update means every time the value of the random number counter makes one round, The predetermined range An initial value counter which is updated in the same range and is composed of at least 2 bytes used by the changing means for changing the initial value, and a value of the initial value counter is read, the value is updated, and the updated value is updated. A second updating unit that writes one byte at a time to the initial value counter, performs a periodic process based on a periodic interrupt signal, and performs a periodic process based on a next interrupt signal after the end of the periodic process. A predetermined process is repeatedly performed until the process is performed. In the predetermined process, read, update, and write processes are performed by the second updating unit, and the control unit further performs the second process. There is provided a means for not executing the periodic processing based on the interrupt signal at the time of executing the writing processing by the updating means.

According to the gaming machine of the present invention, the initial value of the update of the random number counter for determining the jackpot is not a fixed value, but a value that is periodically changed. Even if a "hanging board" resets an internal invalid counter, the value of that counter cannot be made to match the value of the random number counter. Therefore, there is an effect that it is impossible to grasp the timing of occurrence of the jackpot due to the “hanging board” or the like, and it is possible to prevent fraudulent acts due to the “hanging board” or the like.
Moreover, the periodic processing is executed based on the periodic interrupt signal, and the predetermined processing is repeatedly executed at a time after the periodic processing. In this predetermined process, the value of the initial value counter is read and updated by the second updating means, and the updated value is written byte by byte to the initial value counter. At the time of execution, the periodic processing based on the interrupt signal is not executed. Therefore, the next periodic processing does not occur during the writing of one byte at a time to the initial value counter . Slave I, be updated repeatedly the value of the initial value counter composed of 2 bytes or more at a later time periodic process, there is an effect that the value of the counter can be maintained to a value in the original update range.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In this embodiment, a description will be given using a pachinko gaming machine as an example of a gaming machine, in particular, a first-type pachinko gaming machine. It should be noted that the present invention can be naturally applied to other gaming machines such as a third-type pachinko gaming machine and a slot machine.

  FIG. 1 is a front view of the game board of the pachinko gaming machine P in the first embodiment. Around the game board 1, there are provided a plurality of winning ports 2 from which 5 to 15 game balls are paid out when a hit ball wins. In the center of the game board 1, a liquid crystal (LCD) display 3 for displaying a plurality of kinds of symbols as identification information is provided. The display screen of the LCD display 3 is divided into three parts in the horizontal direction, and in each of the three divided display areas, a variable display of a symbol is performed.

  A symbol operation gate (first type starting port) 4 is provided below the LCD display 3, and when the hit ball passes through the symbol operation gate 4, the above-described variable display of the LCD display 3 is started. Below the symbol operation gate 4, a specific winning opening (large winning opening) 5 is provided. When the display result after the change of the LCD display 3 matches one of the predetermined symbol combinations, the specific winning opening 5 becomes a big hit and a predetermined time (for example, 30) is set so that the hit ball can easily win. The winning opening is opened until the second elapses or until 10 hit balls are won. The specific winning opening 5 is provided with a V zone 5a. If a hit ball passes through the V zone 5a while the specific winning opening 5 is open, a continuation right is established and the specific winning opening 5 is closed. Thereafter, the specific winning opening 5 is opened again for a predetermined time (or until a predetermined number of hit balls are won in the specific winning opening 5). The opening and closing operation of the specific winning opening 5 can be repeated up to 16 times (16 rounds), and a state in which the opening and closing operation can be performed is a state in which a predetermined game value is given (a special game state). is there.

  FIG. 2 is a block diagram showing an electric configuration of the pachinko gaming machine P. The control unit C of the pachinko gaming machine P includes a CPU 11 as an arithmetic unit, a ROM 12 storing various control programs executed by the CPU 11 and fixed value data, and a memory for temporarily storing various data. And a RAM 13. 5 to 7 are stored in the ROM 12 as a part of the control program.

  The CPU 11 includes an ALU for performing calculations, an accumulator (hereinafter referred to as “Acc”) 11a, a plurality of internal registers 11b, and a flag register 11c. The value of the counter or the like provided in the RAM 13 is once loaded (read) into the internal register 11b of the CPU 11, updated in the internal register 11b, and then saved (written) into the original counter of the RAM 13. T), will be updated.

  The 68-system 8-bit CPU 11 saves (writes) a pair of 2-byte (16-bit) values of the internal register 11b to a 2-byte memory (in the RAM 13) of a continuous address with one instruction. be able to. Since the data bus of the bus line 14 is composed of 8 bits, writing in this case is performed in the order of the upper byte and the lower byte. On the other hand, in the 80-series 8-bit CPU, contrary to the 68-series CPU 11, the paired 2-byte (16-bit) internal register values are transferred to the 2-byte memory of the continuous address by the lower byte upper byte. It can be saved by one instruction in byte order.

  The RAM 13 includes a random number counter 13a, an initial value counter 13b, and an initial value memory 13c. The random number counter 13a is a counter for determining the occurrence of a jackpot, and is updated by one count every 2 ms within the range of "0 to 630 (0 to 276h)" by the random number update process (S6) in FIG. You. Therefore, the random number counter 13a is composed of 2 bytes. If the value of the random number counter 13a acquired when the hit ball passes through the symbol operation gate 4 is, for example, "7", a big hit occurs. When a big hit occurs, a big hit command is sent from the control unit C to a display device D described later. The display device D controls the variable display of the LCD display 3 to a jackpot state based on the jackpot command.

  The initial value counter 13b is a counter for counting the initial value of the update of the random number counter 13a, and is composed of 2 bytes like the random number counter 13a. The value of the initial value counter 13b is updated by one count at a time in the initial value counter update process (S21) of FIG. 7 in the same range of "0 to 630 (276h)" as the update range of the random number counter 13a.

  The update processing of the initial value counter of FIG. 7 is repeated during the remaining time in the reset interrupt processing of FIG. 5, that is, until the next reset interrupt processing occurs after the end of the sound effect processing (S19). It is executed (S21). The reset interrupt process is executed every 2 ms, but the processing time of each process from S1 to S19 executed in one reset interrupt process changes according to the game situation. The remaining time is not a fixed time but an indefinite time that changes according to the situation of the game. Since the "hanging board" cannot grasp this indefinite time, by using the value of the initial value counter 13b repeatedly updated within the indefinite time as the initial value of the update of the random number counter 13a, the "hanging board" It is impossible to grasp the timing of the jackpot occurrence by the "substrate".

  The initial value memory 13c is a memory for storing an initial value of the update of the random number counter 13a, and is composed of 2 bytes like the random number counter 13a. In this embodiment, the initial value of the update of the random number counter 13a is changed every time the random number counter is updated. Therefore, when the updated value of the random number counter 13a matches the value of the initial value memory 13c, it means that one round of updating of the random number counter 13a has been completed, and when the values 13a and 13c match, the Is written to the random number counter 13a and the initial value memory 13c, and the updated initial value of the random number counter 13a is changed. Therefore, even if the initial value of the update of the random number counter 13a is changed, there is uniformity of the random numbers (the same value is not obtained when continuously obtained, and all values can be extracted with the same probability). You can get a random value.

  The CPU 11, the ROM 12, and the RAM 13 are connected to each other via a bus line 14, and the bus line 14 is also connected to an input / output port 15. The input / output port 15 is connected to the display device D and another input / output device 16. The control unit C sends operation commands to the display device D and other input / output devices 16 via the input / output port 15 to control those devices. The variable display on the LCD display 3 and the opening / closing operation of the specific winning opening 5 are also controlled based on this operation command.

  The display device D includes a CPU 21, a program ROM 22, a work RAM 23, a video RAM 24, a character ROM 25, an image controller 26, an input / output port 27, and the LCD display 3. The CPU 21 of the display device D performs display control (variable display) of the LCD display 3 in response to an operation command output from the control unit C. The program ROM 22 stores a program executed by the CPU 21. Have been. The work RAM 23 is a memory that stores work data used when the CPU 21 executes a program.

  The video RAM 24 is a memory in which data displayed on the LCD display 3 is stored. By rewriting the contents of the video RAM 24, the display contents of the LCD display 3 are changed. That is, the change display of the symbol in each display area is performed by rewriting the contents of the video RAM 24. The character ROM 25 is a memory for storing character data such as symbols displayed on the LCD display 3. The image controller 26 adjusts the timing of each of the CPU 21, the video RAM 24, and the input / output port 27 to intervene reading and writing of data, and to display the display data stored in the video RAM 24 at a predetermined timing with reference to the character ROM 25. This is to be displayed on the LCD display 3.

  Next, with reference to FIGS. 3 and 4, a description will be given of the timing at which a user reset interrupt that triggers the execution of the reset interrupt process of FIG. The user reset interrupt is configured to occur every 2 ms and at the timing when the operation code fetch signal is output by the CPU 11, that is, at the timing when the output of the LIR terminal of the CPU 11 changes from Hi to Low. .

  While the operation code fetch signal is being output, since the operation code is being read from the ROM 12 by the CPU 11, the writing to the RAM 13 is not performed. Therefore, by generating a user reset interrupt in synchronization with the operation code fetch signal, even if the value of the initial value counter 13b is repeatedly updated during the remaining time of the reset interrupt process, the next reset interrupt process is performed. When this occurs, the value of the initial value counter 13b is not rewritten and does not become a value outside the original update range.

  A reset IC 31 is connected to a reset terminal RES of the CPU 11. The output (A) of the reset IC 31 rises from Low to Hi when a predetermined time has elapsed after the power of the pachinko gaming machine P is turned on, and thereafter maintains Hi until the power of the pachinko gaming machine P is turned off. The CPU 11 continues the operation while the input to the reset terminal RES rises from Low to Hi and maintains Hi.

  An oscillator (clock) 32 of 8.1920 MHz is connected to the CPU 11. The output of the clock 32 is frequency-divided by 4 in the CPU 11, and a rectangular oscillation wave having a period of 488.3 ns is output from the E clock terminal (B). Further, from the ICLK terminal, a rectangular wave having a period of 2 ms obtained by dividing the E clock by 4096 is output (C).

  The output terminal of the reset IC 31 is also connected to the CLR terminal of the D flip-flop 33 composed of the HC 74. The CK terminal of the D flip-flop 33 is connected to the ICLK terminal of the CPU 11, and the PR terminal and the D terminal are connected to Vcc (+ 5V). The Q output of 33 maintains Low (G), and the Q bar output maintains Hi (D). Once the output of the ICLK terminal of the CPU 11 once rises from Low to Hi (C), the Q output of the D flip-flop 33 becomes Hi (G), the Q bar output becomes Low (D), and the D flip-flop 33 becomes the pachinko gaming machine. This output is maintained until P is powered off.

  The Q bar output terminal of the D flip-flop 33 is connected to one input terminal of a two-input OR circuit 34. Another input terminal of the OR circuit 34 is connected to the ICLK terminal of the CPU 11. Therefore, from the output terminal of the OR circuit 34, after the Q bar output of the D flip-flop 33 becomes Low (D), a rectangular wave having the same 2 ms period as the output (C) of the ICLK terminal is output (E). ).

  On the other hand, the E clock terminal of the CPU 11 is connected to the input terminal of the inverter 35, and the output terminal of the inverter 35 is connected to the CK terminal of the D flip-flop 36 constituted by the HC 74 and one input terminal of the two-input OR circuit 37. Have been. The PR terminal of the D flip-flop 36 is connected to Vcc, the CLR terminal is connected to the Q output terminal of the D flip-flop 33, the D terminal is connected to the Q7 output terminal of the binary counter 38 composed of HC4020, and the Q output terminal is connected to the OR circuit 37. Are connected respectively to the input terminals. Further, the output terminal of the OR circuit 37 is connected to the CK terminal of the counter 38.

  The Q output of the D flip-flop 33, which is input to the CLR terminal of the D flip-flop 36, once maintains the output of the ICLK terminal of the CPU 11 from Low to Hi (C), and thereafter maintains Hi (G). Since Vcc is input to the PR terminal of the D flip-flop 36, thereafter, the output is input to the D terminal every time the output (F) of the inverter 35 inverting the output (B) of the E clock terminal of the CPU 11 is inverted. The state of the Q7 output (I) of the counter 38 is output from the Q terminal of the D flip-flop 36 (J). Therefore, while the output of the Q terminal of the D flip-flop 36 is Low (J), the OR circuit 37 outputs the inverted output (F) of the E clock (H), and the output of the Q terminal of the D flip-flop 36 is output. During Hi, (J), Hi is output (H).

  The Q7 terminal of the counter 38 is connected to the D terminal of the D flip-flop 36 and also to one input terminal of a two-input OR circuit 39. The output terminal of the OR circuit 34 is connected to the other input terminal of the OR circuit 39. The Q7 output of the counter 38 maintains Low (I) while the output to the CLR terminal is Hi (E). When the output to the CLR terminal is low (E), when the falling clock is input to the CK terminal 64 times (H), the output becomes high (I), and the Hi output of the Q7 terminal is the CLR. It is maintained until Hi is input to the terminal (E, I).

  When both the output of the OR circuit 34 and the output Q7 of the counter 38 are Low (E, I), the OR circuit 39 outputs Low (K). Therefore, the output of the OR circuit 39 maintains the Low output until the output of the OR circuit 34 becomes Low (E) and then the falling clock is input to the CK terminal of the counter 64 times 64 times (H) (H). K). That is, the OR circuit 39 outputs Low every 2 ms (C, E) until the falling clock is input to the CK terminal of the counter 38 64 times (H) (H).

  In the prior art, the output terminal of the OR circuit 39 is connected to the URES terminal of the CPU 11, so that a user reset interrupt is generated at the timing when the OR circuit 39 outputs LOW. Therefore, the period in which the output of the OR circuit 39 maintains Low is (K), which is the period for determining the occurrence of the user reset interrupt.

  The output terminal of the OR circuit 39 is connected to the input terminal of the inverter 41 of the timing circuit 40 and the D terminal of the D flip-flop 42 composed of the HC 74. The timing circuit 40 is a circuit for generating a user reset interrupt at a timing synchronized with the operation code fetch. Since Low is output from the OR circuit 39 every 2 ms (K), the timing circuit 40 outputs Low to the URES terminal of the CPU 11 at the timing of the first operation code fetch after inputting the Low output (N). ), Causing a user reset interrupt.

  As described above, the input terminal of the inverter 41 of the timing circuit 40 is connected to the output terminal of the OR circuit 39, and the output terminal of the inverter 41 is connected to the PR terminal of the D flip-flop 42. Since the CLR terminal of the D flip-flop 42 is connected to Vcc, Hi is output from the Q terminal of the D flip-flop 42 connected to the URES terminal of the CPU 11 while the OR circuit 39 outputs Hi (K). Output (N), no user reset interrupt occurs.

  The LIR terminal of the CPU 11 is connected to the input terminal of the inverter 43, and the output terminal of the inverter 43 is connected to the CK terminal of the D flip-flop 42. When there is an operation code fetch, the output of the LIR terminal falls from Hi to Low. Therefore, every time the operation code is fetched, a rising signal from Low to Hi is output from the inverter 43 to the CK terminal of the D flip-flop 42 (M). .

  Here, when Low is output from the OR circuit 39 (K), Hi is input to the PR terminal of the D flip-flop 42 (L). Since Vcc is input to the CLR terminal, when the operation code fetch signal is output from the CPU 11 and the output of the LIR terminal falls from Hi to Low, the input to the CK terminal of the D flip-flop 42 rises from Low to Hi ( M), the Low output being input to the D terminal at that time (K) is output from the Q terminal of the D flip-flop 42 (N), and is input to the URES terminal of the CPU 11. As a result, a user reset interrupt occurs at the timing of the operation code fetch.

  Even if the generation timing of the user reset interrupt is delayed until the timing of the first operation code fetch, the OR circuit 39 reliably outputs the Low signal every 2 ms (K). Minutes do not accumulate. Therefore, the user reset interrupt can be executed every 2 ms.

  Next, each processing executed in the pachinko gaming machine P configured as described above will be described with reference to flowcharts of FIGS. FIG. 5 is a flowchart of a reset interrupt process executed every 2 ms in the control unit C of the pachinko gaming machine P. The main control of the pachinko gaming machine P is executed by this reset interrupt processing. This reset interrupt processing is executed when a reset interrupt occurs when the power is turned on and when the above-described user reset interrupt occurs.

  In the reset interrupt processing, first, a stack pointer is set (S1), and a pattern written in a predetermined area of the RAM 13 is checked (S2). As a result of the check, if the predetermined pattern is written in the predetermined area, the RAM 13 is normal without any abnormality (S2: normal), and the process proceeds to S3. On the other hand, as a result of the check in S2, if the predetermined pattern is not written in the predetermined area, it is the reset interrupt processing executed first by the reset interrupt after the power is turned on, or the RAM 13 has an abnormality. (S2: Abnormal) In this case, the process proceeds to S22, where the contents of the RAM 13 are temporarily cleared, and the initial value is written into the RAM 13 (S22), and the next reset interrupt process is awaited. I do.

  In the process of S3, the timer interrupt is set (S3). The timer interrupt set here includes a timer interrupt for generating a strobe signal for transmitting a command for controlling the display on the LCD display 3 to the display device D. After the setting of the timer interrupt, each interrupt is enabled (S4). After the interruption is permitted, the output data updated in the previous reset interrupt processing is simultaneously processed by the special symbol change processing (S15), the display data creation processing (S17), the ramp / information processing (S18), and the like. A port output process for outputting to a port is executed (S5). After the execution of the port output processing, a random number update processing (S6) described later is executed to update the value of the random number counter 13a by "+1", and further, a storage timer subtraction processing is executed (S7). The storage timer subtraction process shortens the symbol change display time when the number of reserved balls for the jackpot determination is equal to or more than a predetermined number and the symbol display is being displayed on the LCD display 3.

  In the switch reading process (S8), the value of each switch is read, whereby the hit ball 2 hit into the game area 1 wins the winning opening 2 or the big winning opening 5 (including the V zone 5a), and the symbol operation gate 4 This is a process for detecting a passing ball and a prize ball or a lending ball. The count abnormality monitoring process (S9) is a process for monitoring whether there is an abnormality in the switch data read by the switch reading process of S8. For example, even if the special winning opening 5 is opened and the hit ball is detected by the V count switch for detecting the passing of the hit ball through the V zone 5a, the winning in the special winning opening 5 other than the V zone 5a is detected. If a single ball cannot be detected by the count switch, the 10 count switch has some sort of abnormality such as being pulled out or malfunctioning. In addition, if one prize ball is not paid out even though the motor for paying out the prize ball is driven, some abnormality has occurred in the prize ball payout device. As described above, in the count abnormality monitoring process (S9), the presence or absence of the above-described abnormality is monitored based on the switch data read in the switch reading process (S8).

  In the symbol counter updating process (S10), a counter updating process for determining a symbol to be stopped and displayed as a result of the variable display performed on the LCD display 3 is performed. Further, in the symbol check process (S11), based on the value of the counter updated in the symbol counter update process (S10), a big hit symbol used in the special symbol variation process (S15), a lost symbol, and a reach symbol. Is determined.

  In the processing from S3 to S11, if no error has occurred (S12: normal), the variable display of the 7-segment LED is performed by the ordinary symbol fluctuation processing (S13), and a hit has occurred as a result of the fluctuation display. In such a case, a hitting process is performed to open the electric accessory (not shown) for a predetermined time. Thereafter, the state flag is checked (S14). If the symbol is being displayed on the LCD display 3 while the symbol is being changed (S14: symbol is being changed), the timing at which the hit ball passes through the symbol operation gate 4 by the special symbol changing process (S15). Based on the value of the random number counter 13a read in step (1), it is determined whether or not a big hit has occurred, and a process of changing the display symbol on the LCD display 3 is executed. On the other hand, as a result of checking the state flag, if a big hit is being made (S14: big hit), a big hit process (S16) such as opening the big winning opening 5 is executed. Further, as a result of checking the state flag, if the symbol is not fluctuating or a big hit (S14: other), the processing of S15 and S16 is skipped, and the process proceeds to the display data creation processing of S17. When an error is confirmed in the process of S12 (S12: error), the processes of S13 to S16 are skipped, and the process proceeds to the display data creation process of S17.

  In the display data creation process (S17), demonstration data to be displayed on the LCD display 3 and display data of a 7-segment LED are created in addition to the symbol change display. Various lamp data including data are created. In the sound effect processing (S19), sound effect data according to the game situation is created. The display data and the sound effect data are output to each device by the port output process (S5) and the timer interrupt process described above.

  After the end of the sound effect processing (S19), the symbol counter updating processing (S20), which is the same processing as that of S10, and the initial value counter updating processing (S21) during the remaining time until the next reset interrupt processing occurs. ) Is repeatedly executed. Since the execution time of each processing of S1 to S19 changes according to the state of the game, the remaining time until the next reset interrupt processing (the next user reset interrupt) occurs is not a fixed time but a game time. It changes according to the state of. Therefore, by repeatedly executing the symbol counter updating process (S20) using the remaining time, the stopped symbols can be changed at random. Further, by repeatedly executing the initial value counter update processing (S21) using the remaining time, the value of the initial value counter 13b, which is the initial value of the update of the random number counter 13a, cannot be grasped by the "hanging board". can do.

  FIG. 6 is a flowchart of the random number update process. In the random number update process (S6), the value of the random number counter 13a is updated by "+1" in the range of "0 to 630 (0 to 276h)" via the internal register 11b of the CPU 11 and used by the control unit C. Other random numbers are being updated.

  First, the value of the random number counter 13a composed of 2 bytes is written into the 2-byte internal register 11b (S31). The value of the internal register 11b is incremented by 1 (S32), and it is checked whether or not the value of the internal register 11b after the addition is equal to or more than "631", that is, whether or not the value exceeds the value of the update range of the random number counter 13a. (S33). If the value of the internal register 11b after the addition is equal to or more than "631" (S33: Yes), the value of the internal register 11b is cleared to "0" because it exceeds the value of the update range (S34). On the other hand, if the value of the internal register 11b after the addition is equal to or less than “630” (S33: No), since the value is within the update range, the process of S34 is skipped and the process proceeds to S35.

  In the process of S35, the updated value of the internal register 11b is compared with the value of the initial value memory 13c. Since the initial value memory 13c stores the initial value of the update of the random number counter 13a, if both values are equal (S35: Yes), it means that the update of the random number counter 13a has been completed once. Therefore, in such a case, the value of the 2-byte initial value counter 13b is written to the internal register 11b (S36), and the value of the internal register 11b is written to the initial value memory 13c and the random number counter 13a (S37, S38). The initial value of the update of the random number counter 13a is changed.

  On the other hand, if the updated value of the internal register 11b is not equal to the value of the initial value memory 13c (S35: No), the updating of the random number counter 13a has not been completed yet, so the processing of S36 and S37 is performed. Is skipped, the value of the internal register 11b updated in the processing from S32 to S34 is written to the random number counter 13a (S38), and the random number counter 13a is updated. After that, another random number update process used by the control unit C is performed (S39), and this random number update process ends.

  FIG. 7 is a flowchart of the initial value counter updating process repeatedly executed during the remaining time of the reset interrupt process. In the initial value counter update processing (S21), the value of the initial value counter 13b for counting the initial value of the update of the random number counter 13a is set to "0-630 ( 0 to 276 h) ”in the range“ +1 ”.

  First, the value of the 2-byte initial value counter 13b is written to the 2-byte internal register 11b (S41). The value of the internal register 11b is incremented by 1 (S42), and it is checked whether or not the value of the internal register 11b after the addition is equal to or more than "631", that is, whether or not the value exceeds the value of the update range of the random number counter 13a. (S43). If the value of the internal register 11b after the addition is equal to or more than "631" (S43: Yes), the value of the internal register 11b is cleared to "0" because it exceeds the update range value of the random number counter 13a (S44). . On the other hand, if the value of the internal register 11b after the addition is equal to or less than “630” (S43: No), since the value is within the update range of the random number counter 13a, the process of S44 is skipped and the process proceeds to S45. I do. In the process of S45, the updated value of the internal register 11b is written to the initial value counter 13b in the order of the upper byte and the lower byte by the 2-byte write command of the 68 CPU 11.

  As described above, the initial value counter updating process is repeatedly executed in the reset interrupt process during the remaining time until the next reset interrupt occurs (S21). Therefore, after the upper byte of the internal register 11b is written to the initial value counter 13b by the process of S45 and before the writing of the lower byte, 2 ms elapses, and the timing at which the next user reset interrupt occurs comes. May be. The user reset interrupt is a non-maskable interrupt in which the priority of the interrupt is the highest and the start of the interrupt process cannot be prohibited. However, as described above, the occurrence of the user reset interrupt is delayed by the timing circuit 40 until the timing of the first opcode fetch after the lapse of 2 ms. Does not occur and the reset interrupt processing is not executed. Therefore, even if the value of the initial value counter 13b is repeatedly updated during the remaining time of the reset interrupt processing, the value of the initial value counter 13b is changed to "0-630 (0-276h )).

  Next, a timing circuit 50 according to a second embodiment will be described with reference to FIGS. The timing circuit 40 of the first embodiment is configured to generate a user reset interrupt using an operation code fetch signal (output of the LIR terminal), but the timing circuit 50 of the second embodiment is configured to generate a read signal (R / The user reset interrupt is generated using the W bar terminal (Hi output).

  Here, the read signal is a signal output when data stored in a memory such as the ROM 12 or the RAM 13 is being read by the CPU 11, and is output as a Hi signal from the R / W bar terminal. On the other hand, the write signal is a signal output when data is being written to a memory such as the RAM 13 by the CPU 11, and is output as a Low signal from the R / W bar terminal. Specifically, when the output of the E clock terminal is at the Hi level, the read signal and the write signal are valid. For this reason, in the present embodiment, the output of the E clock terminal and the R / W bar terminal is ANDed by the AND circuit 53 and input to the CK terminal of the D flip-flop 54 (see FIG. 8). ).

  Therefore, while the read signal is being output (while the Hi signal is being output from the AND circuit 53), the data in the ROM 12 and the RAM 13 is read by the CPU 11, and the writing to the RAM 13 is not performed. . Accordingly, by generating a user reset interrupt in synchronization with the read signal, even if the value of the initial value counter 13b is repeatedly updated during the remaining time of the reset interrupt process (S21 in FIG. 5), When the reset interrupt processing described above occurs, the value of the initial value counter 13b is not rewritten and does not become a value outside the original update range. The same portions as those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted. Only different portions will be described.

  The output terminal of the OR circuit 39 is connected to the input terminal of the inverter 51 of the timing circuit 50 and the D terminal of the D flip-flop 52 composed of the HC 74. The timing circuit 50 is a circuit for generating a user reset interrupt while the read signal is being output. In other words, the timing circuit 50 is also a circuit for inhibiting generation of a user reset interrupt while the write signal is being output.

  As described above, the input terminal of the inverter 51 of the timing circuit 50 is connected to the output terminal of the OR circuit 39, and the output terminal of the inverter 51 is connected to the PR terminal of the D flip-flop 52. Since the CLR terminal of the D flip-flop 52 is connected to Vcc, Hi is output from the Q terminal of the D flip-flop 52 connected to the URES terminal of the CPU 11 while the OR circuit 39 outputs Hi (K). Output (Q), no user reset interrupt occurs.

  The R / W bar terminal of the CPU 11 is connected to one input terminal of the two-input AND circuit 53, and the other input terminal of the AND circuit 53 is connected to the E clock terminal of the CPU 11. Further, the output terminal of the AND circuit 53 is connected to the CK terminal of the D flip-flop 52. When the output of the E clock rises from Low to Hi in the state where the read signal is output from the CPU 11 and the output of the R / W bar terminal becomes Hi (B), the AND circuit 53 sends Low to the CK terminal of the D flip-flop 52. Is output (P).

  Here, when Low is output from the OR circuit 39 (K), Hi is input to the PR terminal of the D flip-flop 52 (L). Since Vcc is input to the CLR terminal, when the output of the E clock rises from Low to Hi while Hi is output from the R / W bar terminal (B), the input to the CK terminal of the D flip-flop 52 is input. Rises from Low to Hi (P), and the Low output input to the D terminal at that time is output from the Q terminal of the D flip-flop 52 to the URES terminal of the CPU 11 (Q). As a result, a user reset interrupt occurs at the timing when the read signal is output. Therefore, the execution of the next reset interrupt process is not started during the writing to the initial value counter 13b.

  It should be noted that the timing of the occurrence of the user reset interrupt is delayed until the output of the OR circuit 39 becomes Low, the first read signal is output, and the output of the E clock terminal rises. Even with such a configuration, the OR circuit 39 reliably outputs the Low signal every 2 ms (K), so that the delay does not accumulate. Therefore, also in the second embodiment, the user reset interrupt can be generated every 2 ms, and the reset interrupt process can be executed every 2 ms.

In each of the above embodiments, the periodic processing described in claim 1 corresponds to the processing from S1 to S19 in the non-maskable reset interrupt processing (FIG. 5) , and the predetermined processing corresponds to the processing in S20 and S21. . The first updating means corresponds to the processing from S31 to S34 and S38 of the random number updating processing (S6) in FIG. The second updating means corresponds to the initial value counter updating processing in S21, and the changing means corresponds to the processing from S35 to S38.

  As described above, the present invention has been described based on the embodiments. However, the present invention is not limited to the above embodiments, and it is easily understood that various improvements and modifications can be made without departing from the spirit of the present invention. It can be inferred.

  Hereinafter, modified examples of the present invention will be described. 2. The control device for a gaming machine according to claim 1, further comprising a CPU that controls a game, wherein the prohibition unit prohibits a new occurrence of the interrupt processing while a write signal is being output from the CPU. A game machine control device 1 characterized by the following.

  2. The control device for a gaming machine according to claim 1, further comprising a CPU that controls a game, and wherein the prohibition unit permits a new generation of the interrupt processing while the CPU outputs a read signal. A control device 2 for a gaming machine. While the read signal is being output, the CPU reads the memory and does not write to the memory. Therefore, it is possible to prohibit a new occurrence of the interrupt processing during execution of the write processing in the interrupt processing.

  2. The control device for a gaming machine according to claim 1, further comprising: a CPU that controls a game, wherein the prohibition unit permits a new generation of the interrupt processing while the CPU outputs an operation code fetch signal. A control device 3 for a gaming machine. While the operation code fetch signal is being output, the operation code is read by the CPU and writing to the memory is not performed. Therefore, it is possible to prohibit a new occurrence of the interrupt processing during execution of the write processing in the interrupt processing.

  2. The control device for a gaming machine according to claim 1, wherein the interrupt process comprises a non-maskable reset interrupt process or a non-maskable user reset interrupt process. Gaming machine control device 4.

  A control device for a gaming machine according to claim 1, or a control device for a gaming machine, wherein the random number counter, a first updating means for updating the value of the random number counter by the interrupt processing, and a predetermined trigger Reading means for reading the value of the random number counter, and when the value of the random number counter read by the reading means matches one of predetermined values, the player An initial value memory for storing an initial value of the random number counter being updated, and a value to be written in the initial value memory and the random number counter, the initial value of the next update of the random number counter. An initial value counter composed of at least 2 bytes to be counted, and a value of the initial value counter read out and updated within the range of updating the random number counter, and the updated value Second updating means for writing the initial value counter; and repetition means for repeatedly executing the second updating means during the remaining time until the next interrupt processing occurs by the interrupt processing. A control device 5 for a gaming machine.

  In the gaming machine control device 5, the value of the initial value counter is written to the random number counter and the initial value memory when the value of the random number counter matches the value of the initial value memory. Machine control device 6.

It is a front view of the game board of the pachinko gaming machine in the first embodiment of the present invention. It is a block diagram showing the electrical configuration of the pachinko gaming machine. FIG. 9 is a block diagram of a circuit that generates a user reset interrupt at an interval of 2 ms. 4 is a timing chart of the circuit of FIG. 9 is a flowchart illustrating a reset interrupt process. 9 is a flowchart illustrating a random number update process. 9 is a flowchart illustrating an initial value counter update process. FIG. 11 is a block diagram of a circuit that generates a user reset interrupt at an interval of 2 ms according to the second embodiment. 9 is a timing chart of the circuit of FIG.

Explanation of reference numerals

11 CPU of control unit
13 RAM of control unit
13a random number counter 13b initial value counter 13c initial value memory 40, 50 timing circuit (prohibiting means)
C control unit (control means )
P Pachinko machines (game machines)

Claims (1)

A random number counter, first updating means for updating the value of the random number counter within a predetermined range, reading means for reading the value of the random number counter on a predetermined occasion, and the random number read by the reading means When the value of the counter matches a predetermined value, in a gaming machine having control means for giving a predetermined game value to a player,
The value of the random number counter makes one round by being updated a predetermined number of times by the first updating means,
When the value of the random number counter makes one cycle, the first updating means updates the next cycle with any value within the predetermined range as an initial value of update,
The control means,
Changing means for changing the initial value of the update of the first updating means every time the value of the random number counter makes one round;
An initial value counter that is updated in the same range as the predetermined range and is configured by at least 2 bytes used by the changing unit to change an initial value;
Second updating means for reading the value of the initial value counter, updating the value, and writing the updated value to the initial value counter byte by byte.
While performing the periodic processing based on the periodic interrupt signal, after the end of the periodic processing, the predetermined processing is repeatedly performed during a period until the periodic processing based on the next interrupt signal is performed,
In the predetermined process, reading, updating, and writing processes are performed by the second updating unit,
The control means further comprises:
A gaming machine comprising: means for non-execution of periodic processing based on the interrupt signal when the writing processing is performed by the second updating means.