JP4590423B2 - Information processing system and authenticity determination method used therefor - Google Patents

Description

  The present invention relates to an information processing system and a true / false determination method used therefor, and more particularly to an information processing system using a plurality of types of storage media and a true / false determination method between storage media.

An example of an information processing system using two types of storage media is disclosed in Japanese Patent Application Laid-Open No. 4-303488, which is an application of the present applicant. This prior art is a technique in which program data is stored in a cartridge, other data is stored in a CD-ROM, and data in the CD-ROM is read based on the cartridge program.
JP-A-4-303488

  The above prior art has a problem that information processing cannot be performed unless a cartridge is inserted.

Therefore, an object of the present invention is to provide an information processing system with a high degree of freedom that can always perform data processing according to the connection status of storage media.
Another object of the present invention is to provide a true / false determination method capable of recognizing whether or not an operation target storage medium is authentic.

An information processing apparatus comprising: a first storage medium; a second storage medium; and an information processing apparatus that operates based on data stored in the first and / or second storage medium. A system,
The first storage medium is
A program storage area for storing a program for information processing;
A first ID data storage area storing first ID data for a first storage medium;
A first arbitrary data storage area capable of storing arbitrary data,
The second storage medium is
A data storage area for storing predetermined data for information processing;
A second ID data storage area for storing second ID data for the second storage medium;
A second arbitrary data storage area capable of storing arbitrary data,
Information processing device
Write the first ID data stored in the first storage medium to the second arbitrary data storage area of the second storage medium before using the data stored in the second storage medium for the first time And / or writing the second ID data stored in the second storage medium to the first arbitrary data storage area of the first storage medium,
When using the data stored in the second storage medium again after executing information processing in accordance with the program stored in the first storage medium and the predetermined data stored in the second storage medium Before that, whether or not the second ID data is stored in the first arbitrary data storage area of the first storage medium and / or the second arbitrary data storage area of the second storage medium. It is detected whether or not the first ID data is stored, the second ID data is stored in the first arbitrary data storage area of the first storage medium, and / or the second storage medium Only when it is detected that the first ID data is stored in the second arbitrary data storage area, the data stored in the data storage area of the second storage medium can be processed.

  As described above, according to the first invention, it is possible to realize unification of operations at the time of use and security by using a common ID information area.

According to a second invention, in the first invention,
The first and second storage media are disc-shaped storage media.

  As described above, according to the second aspect of the invention, effective security can be realized even with a disk where security is difficult.

According to a third invention, in the first invention,
The first storage medium is a semiconductor memory, and the second storage medium is a disk-shaped storage medium.
As described above, according to the third invention, effective security can be realized even with a combination of different storage media.

A fourth invention includes a program storage area storing a program for information processing, a first ID data storage area storing first ID data, and a first arbitrary data storage area capable of storing arbitrary data A first storage medium including a data storage area storing predetermined data for information processing, a second ID data storage area storing second ID data, and a second optional storage capable of storing arbitrary data Authenticity determination method used in an information processing system including a second storage medium including a data storage area and an information processing apparatus that operates based on data stored in the first and / or second storage medium Because
Write the first ID data stored in the first storage medium to the second arbitrary data storage area of the second storage medium before using the data stored in the second storage medium for the first time And / or writing the second ID data stored in the second storage medium to the first arbitrary data storage area of the first storage medium,
When using the data stored in the second storage medium again after executing information processing in accordance with the program stored in the first storage medium and the predetermined data stored in the second storage medium Before that, whether or not the second ID data is stored in the first arbitrary data storage area of the first storage medium and / or the second arbitrary data storage area of the second storage medium Whether the first ID data is stored in the first storage medium, and the second ID data is stored in the first arbitrary data storage area of the first storage medium and / or the second storage Only when it is detected that the first ID data is stored in the second arbitrary data storage area of the medium, the data stored in the data storage area of the second storage medium can be processed.

  As described above, according to the fourth aspect of the present invention, the use of a common ID information area can realize the uniformity of operations during use and can realize security.

  FIG. 1 is an external view showing a configuration of an information processing system according to an embodiment of the present invention. In FIG. 1, the information processing system of this embodiment is, for example, a video game system, and includes an information processing apparatus 10, a ROM cartridge 20 as an example of an external storage device, a disk drive 30 and a magnetic disk as an example of an external storage device. 40, a display 50 as an example of display means connected to the information processing apparatus 10, a controller 60 as an example of operation means, a RAM cartridge 70 as an example of an expansion device detachably attached to the controller 60, and an expansion RAM 80 It is comprised including.

  The information processing apparatus 10 is provided with a power switch 101, a reset switch 102, a slot 103 for inserting a ROM cartridge 20, a slot 104 for inserting a connector 301 of the disk drive 30, and a connector 191. As shown in FIG. 2 to be described later, a connector 13 and a connector 14 are provided in the slot 103 and the slot 104, and the connectors 13 and 14 are electrically connected to an internal circuit of the information processing apparatus 10. .

  The ROM cartridge 20 is provided with a connector 25. The connector 25 is connected to the connector 13 when the ROM cartridge 20 is inserted into the slot 103.

  The disk drive 30 is provided with a connector 301 and a slot 302. The connector 301 is connected to the connector 14 by being inserted into the slot 104. The slot 302 is a slot into which the magnetic disk 40 is inserted. Although this embodiment has only one slot for inserting a magnetic disk, a plurality of magnetic disks can be inserted, and data stored in different magnetic disks are sequentially read or written to the magnetic disk. You may be comprised so that it may fall. The magnetic disk 40 is a storage medium that can read and write data by magnetism.

  The display 50 is an image display device including an image display unit 51 and an audio output device 52, as shown in FIG.

  The controller 60 includes switches 603, 604A to 604F, 605, 606L, and 606R, a joystick 65, and a connection unit that connects the RAM cartridge 70. Controller information (switch and joystick operation data and (Including data in the RAM cartridge 70).

  The RAM cartridge 70 incorporates a RAM 71 having a capacity less than half of the maximum memory capacity that can be accessed using the address bus, and is composed of, for example, a 256 kbit RAM. The RAM 71 stores backup data related to the game. The RAM 71 receives power supplied from the battery 72 and holds the stored data even if the RAM cartridge 70 is removed from the controller 60.

  The expansion RAM 80 is provided with a RAM therein and extends a storage area accessed by the CPU.

  The external storage device stores image data and program data for information processing such as games, and stores sound data such as music and sound effects as necessary. Instead, a floppy disk, PD, zip, CD-ROM, CD-R, MO, DVD, or the like may be used. As the operation means, if the information processing system of the present invention is realized by a personal computer, an input device such as a keyboard or a mouse is used.

  FIG. 2 is a block diagram showing in more detail the configuration of the information processing system according to the embodiment of the present invention. In FIG. 2, the information processing apparatus 10 includes a central processing unit (hereinafter abbreviated as “CPU”) 11 and a coprocessor (reality media coprocessor: hereinafter abbreviated as “RCP”) 12.

  The RCP 12 is an image processing unit (Reality Signal Processor: hereinafter abbreviated as “RSP”) 122 that performs polygon coordinate conversion, light source processing, and the like, a data format that rasterizes polygon data into an image to be displayed and can be stored in a frame memory An image processing unit (reality display processor: hereinafter abbreviated as “RDP”) 123 and a bus control circuit 121 for controlling the bus. The RCP 12 is expanded via a cartridge connector 13 for detachably mounting the ROM cartridge 20, a disk drive connector 14 for detachably mounting the disk drive 30, a RAM 15, and a connector 151. The RAM 80 is connected. (The memory map of the RAM 15 will be described in detail later.) Furthermore, the RCP 12 outputs an audio signal generation circuit 16 for outputting an audio signal processed by the CPU 11 and an image signal processed by the CPU 11. Are connected to the controller control circuit 18 for serially transferring operation data of one or a plurality of controllers 60 and / or data of the RAM cartridge 70. Further, a detection circuit 112 for detecting whether or not the ROM cartridge 20 is connected to the connector 13 and / or whether or not the disk drive 30 is connected to the connector 14 is connected to the RCP 12.

  A connector 195 provided on the rear surface of the information processing apparatus 10 is connected to the audio signal generation circuit 16. A connector 196 provided on the rear surface of the information processing apparatus 10 is connected to the image signal generation circuit 17. A connector 195 is detachably connected to a connection portion of an audio output device 52 such as a television speaker. The connector 196 is detachably connected to a connection portion of the image display portion 51 such as a television CRT. In FIG. 2, the connector 195 and the connector 196 are separately shown. However, a single connecting connector may be provided by separately providing connection lines.

  Connected to the controller control circuit 18 are controller connectors (hereinafter simply referred to as “connectors”) 191 to 194 provided on the front surface of the information processing apparatus 10. The controller 60 is detachably connected to the connectors 191 to 194 via a connection jack 61. In this way, by connecting the controller 60 to the connectors 191 to 194, the controller 60 is electrically connected to the information processing apparatus 10, and data can be transmitted and received between them.

  The ROM cartridge 20 is configured by mounting a ROM 21 storing data for game processing and a response circuit 22 on a substrate, and housing the substrate in a housing. The response circuit 22 is a signal generation circuit that generates a response signal including priority order data for the detection circuit 112. The response circuit 22 is a circuit in which two terminals provided on the board are short-circuited. When the ROM cartridge 20 is attached to the connector 13, the terminals in the connector are short-circuited, and the ROM cartridge 20 is connected to the connector 13. It may be possible to detect attachment. Further, the response circuit 22 may be a sensor such as a photo interrupter or a mechanical switch that generates a signal when the ROM cartridge 20 is attached to the connector 13.

  As shown in FIG. 3, the ROM 21 in the ROM cartridge 20 includes a startup program storage area 20a, an ID information storage area 20b, an OS storage area 20c, a program storage area 20d, a sound data storage area 20e, and a graphic data storage area 20f. .

  The activation program storage area 20a is an area for storing a program for an IPL (initial program loader) to be executed first before the CPU 11 executes the program processing.

  The ID information storage area 20b is an area for storing a security number indicating that the ROM cartridge 20 is valid.

  The OS storage area 20c is a storage area for storing a program used as an OS (Operating System), and includes a storage area for storing sound microcode, graphic microcode, a CPU library, and the like. The sound microcode is a program for allowing the RSP 122 to perform sound processing by being loaded into the RSP 122. The graphic microcode is a program for allowing the RSP 122 to perform graphic processing by being loaded into the RSP 122. The CPU library is a collection of many subroutine programs for the CPU 11 to perform a predetermined operation.

  The program storage area 20d is an area for storing a program to be processed by the CPU 11. This program includes an image display program, a sound generation program, a security number comparison program, a game processing program, a magnetic disk data reading program, data A transfer program, a controller data reading program, a microcode writing program, a serial number reading program, a serial number writing program, a font data reading program, a RAM area detection program, a RAM area setting program, and the like are included.

  The sound data storage area 20e is a storage area for storing wave data, sequence data, and the like.

  The wave data is sound source data representing a sound waveform. The sequence data is data representing music data representing the melody of the music.

  The graphic data storage area 20f is a storage area for storing model data, texture data, sprite data, and the like. The model data is data including coordinate data of an object composed of polygons. The texture data is data composed of a pattern to be attached to a polygon, color data representing a material feeling, and the like. Sprite data is data composed of coordinate data and color data of an object drawn in a plane.

  The disk drive 30 is a disk-shaped storage medium storing data to be stored in an external ROM (a disk-shaped storage medium such as magnetic or optical: for example, floppy disk, PD, zip, CD-ROM, CD-R, MO, A device for reading data from a DVD or the like. In this embodiment, an example using a writable magnetic disk is shown.

  FIG. 4 is a detailed block diagram of the disk drive 30. In FIG. 4, the disk drive 30 has a connector, and is configured to be electrically connected to the information processing apparatus 10 by connecting this connector to the connector 14 provided in the slot of the information processing apparatus 10. Has been.

  When the disk drive 30 and the information processing apparatus 10 are electrically connected, the response circuit 312, the drive ROM 314, and the interface circuit 316 are connected to the bus control circuit 121 included in the information processing apparatus 10. The response circuit 312 is connected to the detection circuit 112 via the bus control circuit 121, and generates a response signal according to the signal from the detection circuit 112. The detection circuit 112 detects the connection state of the disk drive 30 by detecting this response signal. The drive ROM 314 stores a startup program for the disk drive 30 and is accessed by the CPU 11 via the bus control circuit 121.

  FIG. 5 is a memory map of the drive ROM 314. In FIG. 5, the drive ROM 314 includes a startup program storage area 314a, an ID information storage area 314b, an OS storage area 314c, a sound data storage area 314d, and a graphic data storage area 314e. The activation program storage area 314a is an area for storing a program for IPL to be executed first before the CPU 11 executes the program processing. The ID information storage area 314b is an area that stores a security number indicating that the magnetic disk 40 is legitimate. The OS storage area 314c is a storage area for storing a program used as an OS (operating system), and is an area for storing sound microcode, graphic microcode, a CPU library, and the like. The sound data storage area 314d is a storage area for storing wave data, sequence data, and the like. The graphic data storage area 20f is a storage area for storing model data, texture data, sprite data, font data, and the like. The font data is graphic data representing the shape (font) of characters and symbols.

  The interface circuit 316 is an interface circuit for connecting the bus control circuit 121, the servo CPU 318, the spindle motor driver 320, the linear motor driver 322, and the disk controller 324 via a bus.

  The servo CPU 318 outputs a command to the spindle motor driver 320, the linear motor driver 322, and the disk controller 324 in accordance with the command from the CPU 11. As a result, the servo CPU 318 can control each device.

  The spindle motor driver 320 is connected to the spindle motor 326 and controls the rotation of the spindle motor 326. The spindle motor 326 is a motor that rotates the magnetic disk 40. The spindle motor 326 includes a sensor for knowing the position of the magnetic disk 40, and can accurately detect the current position of the magnetic disk.

  The linear motor driver 322 is connected to the linear motor 328 and is used to drive and control the linear motor 328. The linear motor 328 is a motor for operating the R / W head 330. The R / W head 330 is a head for reading (READ) and writing (WRITE) data to the magnetic disk 40.

  The disk controller 324 is for outputting an R / W signal (read signal and write signal) to the R / W head 330. The amplifier 332 amplifies the R / W signal and outputs it to the R / W head 330. When the amplified signal is a read signal, the R / W head 330 performs a data read operation on the disk, and when the amplified signal is a write signal, the R / W head 330 performs data read on the disk. The write operation is performed.

  FIG. 6 is a memory map of the magnetic disk 40. In FIG. 6, the magnetic disk 40 includes an ID information storage area 40a, an OS (operating system) storage area 40b, a program storage area 40c, a sound data storage area 40d, a graphic data storage area 40e, and a serial number storage area 40f.

  The ID information storage area 40a includes an area for storing a security number, disk usage, serial number, initial code, version number, and disk number. The security number is a number indicating that the magnetic disk 40 is valid. The disk usage is code data representing the usage of the magnetic disk 40. For example, 0 indicates a magnetic disk that stores a program, 1 indicates a magnetic disk that stores data such as game data, image data, and audio data, and 2 indicates a general purpose that does not specify a particular use. Represents a magnetic disk. The serial number is a unique number that is different for each magnetic disk. The initial code is code data representing the name of a program stored in the magnetic disk 40. The version number is code data representing a version at the time of mass production. The disk number is code data indicating the number of disks when a program is executed using a plurality of magnetic disks.

  The OS storage area 40b is a storage area for storing a program used as an OS (operating system), and is an area for storing sound microcode, graphic microcode, a CPU library, and the like.

  The program storage area 40c is an area for storing a program to be processed by the CPU 11. The program includes an image display program, a sound generation program, a security number comparison program, a game processing program, a magnetic disk data reading program, data A transfer program, a controller data read program, a microcode write program, a serial number read program, a serial number write program, a serial number read program, a font data read program, a RAM area detection program, a RAM area setting program, and the like are included.

  The sound data storage area 40d is a storage area for storing wave data, sequence data, and the like.

  The graphic data storage area 40e is a storage area for storing model data, texture data, sprite data, and the like.

  The serial number storage area 40f is an area for storing the serial number stored in the ID information storage area of another magnetic disk.

  The memory map of other magnetic disks 41 to be described later is substantially the same as the memory map of the magnetic disk 40. In particular, if the ID information storage area and the serial number storage area are set to the same address, comparison of serial numbers between magnetic disks can be facilitated.

  Next, the flow of data on the bus is shown. The bus control circuit 121 of the RCP 12 receives a command output as a parallel signal from the CPU 11 via the bus, performs parallel-serial conversion, outputs a command to the controller control circuit 18 as a serial signal, and the controller control circuit 18. The serial signal data input from is converted into a parallel signal and output to the bus. The bus control circuit 121 of the RCP 12 controls transmission / reception of address signals and data signals between the CPU 11 and the ROM cartridge 20, the disk drive 30, and the expansion RAM 80. As described above, the data output by the bus control circuit 121 of the RCP 12 is processed by the CPU 11 or stored in the RAM 15, for example. The RAM 15 stores the data output to the bus in this way, and writing / reading processing is performed by the CPU 11, RSP 122 or RDP 123.

  FIG. 7 is a memory map showing areas of each memory in the RAM 15. In FIG. 7, the memory space accessible by the CPU 11 via the bus control circuit 121 and / or the memory area of the RAM 15 accessible directly by the RCP 12 are an OS storage area 15a, a program storage area 15b, a sound data storage area 15c, and a graphic data storage area. 15d and buffer area 15e.

  The OS storage area 15a is an area for temporarily storing data stored in the OS storage areas of the ROM 21, the magnetic disk 40, and the drive ROM 314, and stores sound microcode, graphic microcode, and CPU library, and It includes an OS variable storage area for storing variables generated during OS execution.

  The program storage area 15b is an area for temporarily storing data stored in the program storage areas of the ROM 21 and the magnetic disk 40. The program storage area 15b stores a program and stores variables and the like generated during program execution. Includes area.

  The sound data storage area 15c is an area for temporarily storing data stored in the sound data storage area of the ROM 21, the magnetic disk 40, and the drive ROM 314, and stores wave data and sequence data. It includes a sound buffer area that is used to temporarily store sound data when it is generated.

  The graphic data storage area 15d is an area for temporarily storing data stored in the graphic data storage areas of the ROM 21, magnetic disk 40 and drive ROM 314, and stores model data, texture data, sprite data and font data. And a display list, and includes a frame buffer area and a Z buffer area. The display list is a list of polygon types and positions to be processed. The frame buffer area corresponds to an image displayed on the image display unit 51, and is an area for storing color data for each dot of an image created by the RSP 122 and RDP 123 of the RCP 12. The Z buffer area corresponds to the color data stored in the frame buffer area, and is an area for storing depth data for each dot of an image created by the RSP 122 and RDP 123 of the RCP 12.

  The buffer area 15e includes a disk buffer area and a controller data storage area. The disk buffer area is an area for temporarily storing data stored in the magnetic disk 40. The controller data storage area is a storage area for storing controller data transmitted from the controller 60. The controller data includes data indicating whether or not the switches 603, 604A to 604F, 605, 606L, and 606R are pressed, joystick data indicating the amount of inclination of the joystick 65 in the X-axis direction and the amount of inclination in the Y-axis direction, and RAM Data from electronic devices (e.g., RAM, vibrating elements, indicators, temperature sensors, humidity sensors, etc.) within the cartridge 70.

Next, a schematic operation of the information processing system according to the present embodiment will be described.
(1) When ROM cartridge 20 is connected to connector 13 and disk drive 30 is not connected to connector 14 When power switch 101 is pressed, detection circuit 112 first generates a response signal for each response circuit. To instruct. Although the response circuit 22 outputs a response signal to the detection circuit 112, the response circuit 312 is not connected, and therefore cannot output a response signal. Therefore, the detection circuit 112 detects that the cartridge is connected to the connector 13 and makes the CPU 11 accessible to the ROM 21. The CPU 11 executes a startup program stored in the ROM 21.

(2) When the ROM cartridge 20 is not connected to the connector 13 and the disk drive 30 is connected to the connector 14 When the power switch 101 is pressed, the detection circuit 112 first generates a response signal for each response circuit. To instruct. Although the response circuit 312 outputs a response signal to the detection circuit 112, the response circuit 22 cannot be output because the response circuit 22 is not connected. Therefore, the detection circuit 112 detects that the disk drive 30 is connected to the connector 14 and makes the CPU 11 accessible to the drive ROM 314. The CPU 11 executes the startup program stored in the startup program storage area 314a of the drive ROM 314. More specifically, the CPU 11 performs processing for image display based on the model data, texture data, sprite data, and font data stored in the graphic data storage area 314e. For example, characters such as “Please insert disc” are displayed. Further, the CPU 11 performs processing for generating sound based on the wave data and sequence data stored in the sound data storage area 314d. For example, a sound such as “Please insert a disc” is generated.

(3) When ROM cartridge 20 is connected to connector 13 and disk drive 30 is connected to connector 14 When power switch 101 is pressed, detection circuit 112 first generates a response signal for each response circuit. To instruct. Both the response circuit 22 and the response circuit 312 output a response signal to the detection circuit 112. First, the detection circuit 112 detects that a cartridge having a high priority is connected to the connector 13 and makes the CPU 11 accessible to the ROM 21 accordingly. The CPU 11 executes a startup program stored in the ROM 21. In this case, the priority order is determined beforehand that the ROM cartridge 20 is higher than the magnetic disk 40, and the detection circuit 112 preferentially detects the ROM cartridge 20. As another method, the detection circuit 112 may detect the priority order data generated from each response circuit, and the storage means to which the response circuit with the higher priority is connected may be activated.

Next, the principle of the authenticity determination method in this embodiment will be described.
In the authenticity determination method in the present embodiment, when information processing using at least two magnetic disks (first disk and second disk) is performed in the disk drive 30, the first disk used first and the next This is a method of clarifying the correspondence relationship of the second disk to be used and prohibiting the use of the second disk unrelated to the first disk.

  First, when the first magnetic disk is inserted into the disk drive, the CPU 11 stores the serial number stored in the ID information storage area 40 a of the magnetic disk 40 in the work area of the RAM 15. Next, when the second disk is inserted into the disk drive 30, the CPU 11 writes the serial number in the serial number storage area 40f of the second disk. In this way, by writing the serial number to the second disk, the first disk and the second disk become disks storing the same serial number. The CPU 11 determines whether or not the serial number is the same as the serial number of the first disk every time the second disk is inserted, and if not, does not access the second disk as an illegal disk. Therefore, the second disk cannot be used with any other than the determined first disk. Specifically, when a plurality of types of second disks are possessed, use of the wrong disk can be prevented.

  As another authenticity determination method, when information processing using at least one magnetic disk is performed for the ROM cartridge 20 and the disk drive 30, the correspondence between the ROM cartridge 20 and the first disk used first is clarified. There is a method for prohibiting the use of the first disk unrelated to the ROM cartridge 20.

  First, when the first disk is first inserted into the disk drive, the CPU 11 reads the authenticity determination information (not shown) stored in the ID information storage area 20b of the ROM cartridge 20 to read the first Write to a magnetic disk. In this way, by writing the authenticity determination information to the first disk, the ROM cartridge 20 and the first disk become storage means for storing the same authenticity determination information. The CPU 11 determines whether the authenticity determination information is the same as the authenticity determination information of the ROM cartridge 20 every time the first disk is inserted, and if different, does not access the first disk as an illegal disk. Accordingly, the first disk cannot be used with a device other than the determined ROM cartridge 20. Specifically, when a plurality of types of disks are possessed, use of the wrong disk can be prevented.

8 to 10 are flowcharts showing the operation of the information processing system according to this embodiment. The operation of the information processing system according to this embodiment will be described below with reference to FIGS.
First, in step (shown with “S” in FIG. 8) 1 of FIG. 8, the detection circuit 112 detects whether the response circuit 22 of the ROM cartridge 20 generates a response signal including predetermined priority order data. . If the detection circuit 112 detects a response signal, the process proceeds to step 2. If the detection circuit 112 does not detect a response signal, the process proceeds to step 7. In step 2, the CPU 11 starts information processing based on the startup program stored in the startup program storage area 20a of the ROM 21 of the ROM cartridge 20, and executes the program based on the program stored in the program storage area 20d. Execute. Next, in step 3, if the currently executed information processing (for example, video game) is information processing using a magnetic disk, the process proceeds to step 5, and the currently executed information processing uses a magnetic disk. If it is not information processing, the process proceeds to step 4. In step 4, the game program is executed based on the program stored in the program area 20d until the game program ends. In step 5, the CPU 11 stores the security number stored in the ID information storage area 20 b of the ROM cartridge 20, the security number stored in the ID information storage area 314 b of the drive ROM 314, and the ID information storage area 40 a of the magnetic disk 40. The stored security number is compared, and if it is the same number, the process proceeds to step 11 in FIG. 9, and if it is a different number, the process proceeds to step 6. In step 6, the CPU 11 causes the RCP 12 to create image data and causes the image signal generation circuit 17 to output an image signal, thereby displaying an error on the display 50. This error display is a message that informs the user that an error has occurred, such as “Error ???” or “Your disc is not the correct disc” on the display 50. After displaying the error, the operation of the information processing apparatus 10 is terminated. As another embodiment, the process may wait until the correct magnetic disk is inserted, and proceed to Step 11 when the correct magnetic disk is inserted.

  In step 7, the detection circuit 112 detects whether the response circuit 312 of the disk drive 30 generates a response signal including predetermined priority order data. If the detection circuit 112 detects a response signal, the process proceeds to step 9, and if the detection circuit 112 does not detect a response signal, the process proceeds to step 8. In step 8, the CPU 11 causes the RCP 12 to create image data and causes the image signal generation circuit 17 to output an image signal, thereby displaying on the display 50 a prompt to insert the magnetic disk 40 into the slot 302. This display is a message such as “A disc is not inserted” or “Please insert a disc” on the display 50. When the operation of step 8 ends, the process returns to step 7. In step 9, the CPU 11 compares the security number stored in the ID information storage area 314 b of the drive ROM 314 with the security number stored in the ID information storage area 40 a of the magnetic disk 40. Proceed to step 10. If the number is different, proceed to step 6. In step 10, the CPU 11 starts information processing based on the activation program stored in the activation program storage area 314 a of the drive ROM 314.

  In step 1 to step 10, in this embodiment, among the priority data output from the response circuit 22 and the response circuit 312, the priority data output from the response circuit 22 has a higher priority. However, the priority of the response circuit 312 may be higher than that of the response circuit 22. In this case, the magnetic disk 40 preferentially activates the activation program stored in the activation program storage area 20a of the ROM cartridge 20. Further, when the priority order is not determined, the priority data output from the respective response circuits are compared, and the activation is performed according to the activation program stored in the storage medium provided with the response circuit having the higher priority order. You may do it.

  In step 11 of FIG. 9, the CPU 11 determines whether to use a plurality of magnetic disks based on the program stored in the program storage area 40 c of the magnetic disk 40. If the CPU 11 determines that the game uses a plurality of magnetic disks (information processing), the process proceeds to step 12. If the CPU 11 determines that the game does not use a plurality of magnetic disks, the process proceeds to step 20. In step 12, the CPU 11 determines whether or not to execute the program stored in the program storage area 20d of the ROM 21 of the ROM cartridge 20 based on the program being executed. If the CPU 11 executes the program of the ROM cartridge 20, the process proceeds to step 14. If the CPU 11 does not execute the program of the ROM cartridge 20, the process proceeds to step 13. In step 13, the CPU 11 executes the program based on the program stored in the program storage area 40 c of the magnetic disk 40 or executes the program based on the stored data, and proceeds to step 15. In step 14, the CPU 11 executes the program stored in the program storage area 20d, and proceeds to step 15. In step 15, the CPU 11 determines whether it is necessary to replace the magnetic disk 40 with another magnetic disk. If the CPU 11 determines that the magnetic disk needs to be replaced, the process proceeds to step 16, and if it determines that the magnetic disk does not need to be replaced, the process returns to step 12. In step 16, the CPU 11 performs a process for causing the display 50 to display “Please replace the disk”. In step 17, the user takes out the magnetic disk 40 from the slot 302 and inserts another magnetic disk 41 into the slot 302. Next, in step 18, the information processing system according to the present embodiment performs a process of determining the relationship between the replaced magnetic disk 41 and the magnetic disk 40 that has been previously inserted. The magnetic disk 41 includes a storage area similar to that of the magnetic disk 40. (Hereafter, the reference number of the storage area of the magnetic disk 41 is given the same number as the reference number of the storage area of the magnetic disk 40.)

  On the other hand, in step 20, the CPU 11 determines whether or not to execute the program stored in the program storage area 20d of the ROM 21 of the ROM cartridge 20 based on the program being executed. If the CPU 11 executes the program of the ROM cartridge 20, the process proceeds to step 22. If the CPU 11 does not execute the program of the ROM cartridge 20, the process proceeds to step 21. In step 21, the CPU 11 executes the program based on the program stored in the program storage area 40 c of the magnetic disk 40 and proceeds to step 23. In step 22, the CPU 11 executes the program stored in the program storage area 20 d and proceeds to step 23. In step 23, if the program to be processed by CPU 11 has been completed, the process is terminated. If the program to be processed by CPU 11 has not been completed, the process returns to step 20.

Step 18 is represented by a subroutine as shown in FIG.
In step 181 of FIG. 10, the CPU 11 reads the disk usage stored in the ID information storage area 40a of the replaced magnetic disk 41, and determines whether or not the magnetic disk 41 is a general-purpose data disk. If the magnetic disk 41 is a general-purpose data disk, the process returns to step 12 (at this time, if the format of the magnetic disk 41 is a format incapable of storing data, it is converted into a format in which data can be stored). If is not a general-purpose data disk, the process proceeds to step 182. In step 182, the CPU 11 reads the disk usage stored in the ID information storage area 40 a of the replaced magnetic disk 41 and determines whether the magnetic disk 41 is a data disk. If the magnetic disk 41 is a data disk, the process proceeds to step 183. If the magnetic disk 41 is not a data disk, the process proceeds to step 185. In step 183, the CPU 11 reads the initial code, game version, disk number, and the like stored in the ID information storage area 40 a of the replaced magnetic disk 41, and the magnetic corresponding to the initial code stored in the magnetic disk 40. Determine if it is a disk. If the magnetic disk 41 is a magnetic disk corresponding to the initial code stored in the magnetic disk 40, the process returns to step 12, and the magnetic disk 41 is not a magnetic disk corresponding to the initial code stored in the magnetic disk 40. If so, go to Step 184. In step 184, the CPU 11 causes the RCP 12 to create image data and causes the image signal generation circuit 17 to output an image signal, thereby displaying on the display 50 that the magnetic disk 41 is an unauthorized magnetic disk. This display may be the same as the display in step 6 described above. After the display, the process returns to step 17.

  In step 185, the CPU 11 reads the initial code stored in the ID information storage area 40 a of the replaced magnetic disk 41 and determines whether it is the same as the initial code stored in the magnetic disk 40. If the initial code of the magnetic disk 41 and the initial code of the magnetic disk 40 are the same, the process proceeds to step 186, and if the initial code of the magnetic disk 41 and the initial code of the magnetic disk 40 are not the same, the process proceeds to step 184. . In step 186, the CPU 11 reads the disk number stored in the ID information storage area 40 a of the replaced magnetic disk 41 and determines whether or not it corresponds to the disk number stored in the magnetic disk 40. For example, when the disk number of the magnetic disk 40 indicates the first magnetic disk and the disk number of the magnetic disk 41 indicates the second magnetic disk, it is determined that the disk number corresponds. However, what number the disk number of the magnetic disk 41 indicates can be determined as a corresponding disk, depending on the program being executed. If the disk number of the magnetic disk 41 corresponds to the disk number of the magnetic disk 40, the process proceeds to step 187. If the disk number of the magnetic disk 41 does not correspond to the disk number of the magnetic disk 40, the process proceeds to step 184. In step 187, the CPU 11 determines whether or not the magnetic disk 41 is an unused disk. If the magnetic disk 41 is an unused disk, the process proceeds to step 188. If the magnetic disk 41 is not an unused disk, the process proceeds to step 189.

  In step 188, the CPU 11 writes the serial number stored in the ID information storage area 40 a of the magnetic disk 40 into the serial number storage area 40 f of the magnetic disk 41. In step 189, the CPU 11 reads the serial number stored in the serial number storage area 40f of the replaced magnetic disk 41, and has a predetermined relationship with the data stored in the ID information storage area 40a of the magnetic disk 40. It is discriminated whether or not there is. For example, the CPU 11 determines whether or not the serial number stored in the serial number storage area 40 f of the magnetic disk 41 is the same as the serial number stored in the magnetic disk 40. Further, each data may be scrambled (or data converted based on a predetermined calculation formula), and the CPU 11 may compare and judge the data. If the serial number stored in the magnetic disk 41 and the data stored in the ID information storage area 40a of the magnetic disk 40 have a predetermined relationship, the process returns to step 12 and is stored in the magnetic disk 41. If the serial number and the data stored in the ID information storage area 40a of the magnetic disk 40 are not in a predetermined relationship, the process proceeds to step 184.

Next, specific examples of information processing using a plurality of types of storage media will be described.
(First information processing; role-playing game with two discs)
The example which implement | achieved the game which a hero character travels in the several world using this invention is given. Here, it is assumed that the first disk stores the first world program and image data, and the second disk stores the second world program and image data. First, before starting the game, the serial number stored in the first disc is transferred to a predetermined location on the second disc. Thereafter, the user plays a game based on the program and image data stored on the first disc, and plays the game while writing data on the disc as necessary. When the user plays the first world game for a while, a scene of transition to the second world game comes. Then, for example, a message such as “Please insert the second disc” is displayed on the display. When the user inserts the second disk, it is determined whether or not the serial number stored in the first disk is stored in the second disk, and only if the second number is stored. The world game begins. Thereafter, the user plays the game of the second world, and plays the game while writing data to the disc as necessary.
In this way, once the first disc is played using the second disc, the first disc and the second disc are linked, so it cannot be combined with other discs. It becomes. As a result, it is possible to prevent the wrong disks from being used in combination.

(Second information processing; cartridge version racing game + game using additional course data disc)
The example which realized the game which races various courses with various kinds of cars using this invention is given. First, a race game program and basic course data are put in a cartridge, and additional course data (and / or additional vehicle type data) are put in a disc.
The user will play a game with a single cartridge. However, the user gets bored with the game if he plays all cars and all courses. Therefore, by purchasing an additional course data disk and inserting it into a disk drive for execution, the user can play the course (and / or vehicle type) stored in the additional course data disk. At this time, the CPU can write the authenticity determination information stored in the cartridge to the additional course disk so that the additional course disk cannot be used without the cartridge.

(Third information processing: Paint game using disc version paint tool (first disc) + dedicated disc (second disc) + general disc (third disc))
An example in which a paint game in which a lot of data created by a user must be stored is realized using the present invention will be described. First, a paint game program and image data are put on the first disk, and the second disk is formatted so that the image data can be stored.
The user first inserts the first disk into the disk drive and causes the paint tool program to be executed. Next, the user executes a paint game and freely creates an image on the display using a controller or a mouse. When the user wants to save an image during or after the image creation, the user uses an image data saving function added as a paint game function. Specifically, a save icon displayed on the display is clicked using an input device such as a controller or a mouse. Then, a message such as “Please insert the storage disk” appears on the display. Therefore, the user inserts a disk in which image data is to be stored into the disk drive. When it is confirmed that the second disc is inserted into the disc drive, image data is written on the inserted disc. If the inserted disc is not a dedicated disc but a general-purpose third disc is inserted, it is formatted as a dedicated disc and image data is written. However, as long as the general-purpose disc can write image data, a new format is not required. If there is sufficient free space on the first disk, the image data may be written to the first disk.
As described above, since image data can be written on any disk, a large amount of image data can be freely stored.

(Fourth information processing; music creation game using disc version music tool (first disc) + dedicated disc (second disc) + general disc (third disc)) Third information processing creates image data In contrast to the process, the fourth information process is a music data creation process. The storage method on the disk is almost the same as the third information processing.
Further, by examining the initial code stored on the disk, the disk of another corresponding tool can be recognized. Accordingly, it is possible to use the disk storing the image data in association with the disk storing the music data. Specifically, by writing music data created using this music tool onto the above-described third information processing paint tool disk, image data containing music can be stored on the paint tool disk. It will be possible. Therefore, animation, picture-story show, etc. can be displayed on the display, and sound corresponding to that can be generated from the speaker.

1 is an external view showing a configuration of an information processing system according to an embodiment of the present invention. The block diagram which shows the structure of the information processing system of one Embodiment of this invention in detail Memory map showing the memory area of the ROM 21 of the ROM cartridge 20 Detailed block diagram of the disk drive 30 Memory map showing memory area of drive ROM 314 Memory map showing memory area of magnetic disk 40 Memory map showing memory area of RAM15 The flowchart which shows the first half part of operation | movement of one Embodiment of this invention. The flowchart which shows the latter half part of operation | movement of one Embodiment of this invention. A flowchart showing in detail the subroutine step 18 of the flowchart of FIG.

Explanation of symbols

10 ... Information processing device 11 ... CPU (Central Processing Unit)
12 ... RCP
15 ... RAM
18 ... Controller control circuit 20 ... ROM cartridge 21 ... ROM
DESCRIPTION OF SYMBOLS 22 ... Response circuit 30 ... Disk drive 40 ... Magnetic disk 50 ... Display apparatus 60 ... Controller 70 ... RAM cartridge 80 ... Expansion RAM
102 ... Detection circuit 103 ... Slot (with connector)
104 ... Slot (with connector)
301 ... Connector 302 ... Slot

Claims (4)

An information processing system comprising a first storage medium, a second storage medium, and an information processing apparatus that operates based on data stored in the first and / or second storage medium,
The first storage medium is
A program storage area for storing a program for information processing;
And a I D data storage area which stores I D data for the first storage medium,
The second storage medium is
A data storage area for storing predetermined data for information processing;
And a storable arbitrary data storage area of any data,
The information processing apparatus includes:
Before using the data stored in the second storage medium to the first, writes the I D data that have been stored in the first storage medium to the arbitrary data storage area of the second storage medium,
When using the data stored in the second storage medium again after executing information processing in accordance with the program stored in the first storage medium and the predetermined data stored in the second storage medium It is before that, ID data is detected whether or not it is stored for a first storage medium to the arbitrary data storage area of the second storage medium, the data storage arbitrary second storage medium when the ID data for the first storage medium is detected to be stored in the area, and capable of processing data stored in the data storage area of the second storage medium, the information processing system.   The information processing system according to claim 1, wherein the first and second storage media are disk-shaped storage media.   The information processing system according to claim 1, wherein the first storage medium is a semiconductor memory, and the second storage medium is a disk-shaped storage medium. Program storage area for storing a program for information processing, a first storage medium comprising a I D data storage area for storing the ID data for the first storage medium, the predetermined data for information processing data storage area that stores a second storage medium including arbitrary data storage area capable of storing arbitrary data you and, based on the data stored in the first and / or second storage medium An authenticity determination method used in an information processing system including an information processing apparatus that operates,
Before using the data stored in the second storage medium to the first, writes the I D data that have been stored in the first storage medium to the arbitrary data storage area of the second storage medium,
When using the data stored in the second storage medium again after executing information processing in accordance with the program stored in the first storage medium and the predetermined data stored in the second storage medium is before that, a second ID data for the first storage medium in any data storage area of the storage medium to detect whether it is stored, arbitrary data of the second storage medium when the ID data for the first storage medium in the storage area is detected to be stored, and can process data stored in the data storage area of the second storage medium, authenticity discrimination method .

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