#include "../System.h" #include "../common/Port.h" #include "gbGlobals.h" #include "gbMemory.h" #include "gb.h" u8 gbDaysinMonth [12] = { 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31}; const u8 gbDisabledRam [8] = {0x80, 0xff, 0xf0, 0x00, 0x30, 0xbf, 0xbf, 0xbf}; extern int gbGBCColorType; extern gbRegister PC; // for UTC offset #include "../../vbagx.h" mapperMBC1 gbDataMBC1 = { 0, // RAM enable 1, // ROM bank 0, // RAM bank 0, // memory model 0, // ROM high address 0, // RAM address 0 // Rom Bank 0 remapping }; // MBC1 ROM write registers void mapperMBC1ROM(u16 address, u8 value) { int tmpAddress = 0; switch(address & 0x6000) { case 0x0000: // RAM enable register gbDataMBC1.mapperRAMEnable = ( ( value & 0x0a) == 0x0a ? 1 : 0); break; case 0x2000: // ROM bank select // value = value & 0x1f; if ((value == 1) && (address == 0x2100)) gbDataMBC1.mapperRomBank0Remapping = 1; if((value & 0x1f) == 0) value += 1; if(value == gbDataMBC1.mapperROMBank) break; tmpAddress = value << 14; // check current model if (gbDataMBC1.mapperRomBank0Remapping == 3) { tmpAddress = (value & 0xf) << 14; tmpAddress |= (gbDataMBC1.mapperROMHighAddress & 3) << 18; } else if(gbDataMBC1.mapperMemoryModel == 0) { // model is 16/8, so we have a high address in use tmpAddress |= (gbDataMBC1.mapperROMHighAddress & 3) << 19; } tmpAddress &= gbRomSizeMask; gbDataMBC1.mapperROMBank = value; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; break; case 0x4000: // RAM bank select if(gbDataMBC1.mapperMemoryModel == 1) { if (!gbRamSize) { if (gbDataMBC1.mapperRomBank0Remapping == 3) { gbDataMBC1.mapperROMHighAddress = value & 0x03; tmpAddress = (gbDataMBC1.mapperROMHighAddress) << 18; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x00] = &gbRom[tmpAddress]; gbMemoryMap[0x01] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x02] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x03] = &gbRom[tmpAddress + 0x3000]; gbMemoryMap[0x04] = &gbRom[tmpAddress + 0x4000]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x5000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x6000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x7000]; } else gbDataMBC1.mapperRomBank0Remapping = 0; } // 4/32 model, RAM bank switching provided value = value & 0x03; if(value == gbDataMBC1.mapperRAMBank) break; tmpAddress = value << 13; tmpAddress &= gbRamSizeMask; if(gbRamSize) { gbMemoryMap[0x0a] = &gbRam[tmpAddress]; gbMemoryMap[0x0b] = &gbRam[tmpAddress + 0x1000]; } gbDataMBC1.mapperRAMBank = value; gbDataMBC1.mapperRAMAddress = tmpAddress; if (gbDataMBC1.mapperRomBank0Remapping != 3) gbDataMBC1.mapperROMHighAddress = 0; } else { // 16/8, set the high address gbDataMBC1.mapperROMHighAddress = value & 0x03; tmpAddress = gbDataMBC1.mapperROMBank << 14; tmpAddress |= (gbDataMBC1.mapperROMHighAddress) << 19; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; if(gbRamSize) { gbMemoryMap[0x0a] = &gbRam[0]; gbMemoryMap[0x0b] = &gbRam[0x1000]; } gbDataMBC1.mapperRAMBank = 0; } break; case 0x6000: // memory model select gbDataMBC1.mapperMemoryModel = value & 1; if(gbDataMBC1.mapperMemoryModel == 1) { // 4/32 model, RAM bank switching provided value = gbDataMBC1.mapperRAMBank & 0x03; tmpAddress = value << 13; tmpAddress &= gbRamSizeMask; if(gbRamSize) { gbMemoryMap[0x0a] = &gbRam[gbDataMBC1.mapperRAMAddress]; gbMemoryMap[0x0b] = &gbRam[gbDataMBC1.mapperRAMAddress + 0x1000]; gbDataMBC1.mapperRomBank0Remapping = 0; } else gbDataMBC1.mapperRomBank0Remapping |=2; gbDataMBC1.mapperRAMBank = value; gbDataMBC1.mapperRAMAddress = tmpAddress; tmpAddress = gbDataMBC1.mapperROMBank << 14; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; } else { // 16/8, set the high address tmpAddress = gbDataMBC1.mapperROMBank << 14; tmpAddress |= (gbDataMBC1.mapperROMHighAddress) << 19; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; if(gbRamSize) { gbMemoryMap[0x0a] = &gbRam[0]; gbMemoryMap[0x0b] = &gbRam[0x1000]; } } break; } } // MBC1 RAM write void mapperMBC1RAM(u16 address, u8 value) { if(gbDataMBC1.mapperRAMEnable) { if(gbRamSize) { gbMemoryMap[address >> 12][address & 0x0fff] = value; systemSaveUpdateCounter = SYSTEM_SAVE_UPDATED; } } } // MBC1 read RAM u8 mapperMBC1ReadRAM(u16 address) { if(gbDataMBC1.mapperRAMEnable) return gbMemoryMap[address>>12][address & 0x0fff]; if (!genericflashcardEnable) return 0xff; else if ((address & 0x1000) >= 0x1000) { // The value returned when reading RAM while it's disabled // is constant, exept for the GBASP hardware. // (actually, is the address that read is out of the ROM, the returned value if 0xff...) if (PC.W>=0xff80) return 0xff; else if ((gbHardware & 0x08) && (gbGBCColorType == 2)) { if (address & 1) return 0xfb; else return 0x7a; } else return 0x0a; } else return gbDisabledRam[address & 7]; } void memoryUpdateMapMBC1() { int tmpAddress = gbDataMBC1.mapperROMBank << 14; // check current model if (gbDataMBC1.mapperRomBank0Remapping == 3) { tmpAddress = (gbDataMBC1.mapperROMHighAddress & 3) << 18; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x00] = &gbRom[tmpAddress]; gbMemoryMap[0x01] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x02] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x03] = &gbRom[tmpAddress + 0x3000]; tmpAddress |= (gbDataMBC1.mapperROMBank & 0xf) << 14; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; } else { if(gbDataMBC1.mapperMemoryModel == 0) { // model is 16/8, so we have a high address in use tmpAddress |= (gbDataMBC1.mapperROMHighAddress & 3) << 19; } tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; } if(gbRamSize) { if(gbDataMBC1.mapperMemoryModel == 1) { gbMemoryMap[0x0a] = &gbRam[gbDataMBC1.mapperRAMAddress]; gbMemoryMap[0x0b] = &gbRam[gbDataMBC1.mapperRAMAddress + 0x1000]; } else { gbMemoryMap[0x0a] = &gbRam[0]; gbMemoryMap[0x0b] = &gbRam[0x1000]; } } } mapperMBC2 gbDataMBC2 = { 0, // RAM enable 1 // ROM bank }; // MBC2 ROM write registers void mapperMBC2ROM(u16 address, u8 value) { switch(address & 0x6000) { case 0x0000: // RAM enable if(!(address & 0x0100)) { gbDataMBC2.mapperRAMEnable = (value & 0x0f) == 0x0a; } break; case 0x2000: // ROM bank select if(address & 0x0100) { value &= 0x0f; if(value == 0) value = 1; if(gbDataMBC2.mapperROMBank != value) { gbDataMBC2.mapperROMBank = value; int tmpAddress = value << 14; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; } } break; } } // MBC2 RAM write void mapperMBC2RAM(u16 address, u8 value) { if(gbDataMBC2.mapperRAMEnable) { if(gbRamSize && address < 0xa200) { gbMemoryMap[address >> 12][address & 0x0fff] = value; systemSaveUpdateCounter = SYSTEM_SAVE_UPDATED; } } } void memoryUpdateMapMBC2() { int tmpAddress = gbDataMBC2.mapperROMBank << 14; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; } mapperMBC3 gbDataMBC3 = { 0, // RAM enable 1, // ROM bank 0, // RAM bank 0, // RAM address 0, // timer clock latch 0, // timer clock register 0, // timer seconds 0, // timer minutes 0, // timer hours 0, // timer days 0, // timer control 0, // timer latched seconds 0, // timer latched minutes 0, // timer latched hours 0, // timer latched days 0, // timer latched control (time_t)-1 // last time }; void memoryUpdateMBC3Clock() { time_t now = time(NULL) - (GCSettings.OffsetMinutesUTC*60); time_t diff = now - gbDataMBC3.mapperLastTime; if(diff > 0) { // update the clock according to the last update time gbDataMBC3.mapperSeconds += (int)(diff % 60); if(gbDataMBC3.mapperSeconds > 59) { gbDataMBC3.mapperSeconds -= 60; gbDataMBC3.mapperMinutes++; } diff /= 60; gbDataMBC3.mapperMinutes += (int)(diff % 60); if(gbDataMBC3.mapperMinutes > 59) { gbDataMBC3.mapperMinutes -= 60; gbDataMBC3.mapperHours++; } diff /= 60; gbDataMBC3.mapperHours += (int)(diff % 24); if(gbDataMBC3.mapperHours > 23) { gbDataMBC3.mapperHours -= 24; gbDataMBC3.mapperDays++; } diff /= 24; gbDataMBC3.mapperDays += (int)(diff & 0xffffffff); if(gbDataMBC3.mapperDays > 255) { if(gbDataMBC3.mapperDays > 511) { gbDataMBC3.mapperDays %= 512; gbDataMBC3.mapperControl |= 0x80; } gbDataMBC3.mapperControl = (gbDataMBC3.mapperControl & 0xfe) | (gbDataMBC3.mapperDays>255 ? 1 : 0); } } gbDataMBC3.mapperLastTime = now; } // MBC3 ROM write registers void mapperMBC3ROM(u16 address, u8 value) { int tmpAddress = 0; switch(address & 0x6000) { case 0x0000: // RAM enable register gbDataMBC3.mapperRAMEnable = ( ( value & 0x0a) == 0x0a ? 1 : 0); break; case 0x2000: // ROM bank select value = value & 0x7f; if(value == 0) value = 1; if(value == gbDataMBC3.mapperROMBank) break; tmpAddress = value << 14; tmpAddress &= gbRomSizeMask; gbDataMBC3.mapperROMBank = value; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; break; case 0x4000: // RAM bank select if(value < 8) { if(value == gbDataMBC3.mapperRAMBank) break; tmpAddress = value << 13; tmpAddress &= gbRamSizeMask; gbMemoryMap[0x0a] = &gbRam[tmpAddress]; gbMemoryMap[0x0b] = &gbRam[tmpAddress + 0x1000]; gbDataMBC3.mapperRAMBank = value; gbDataMBC3.mapperRAMAddress = tmpAddress; } else { if(gbDataMBC3.mapperRAMEnable) { gbDataMBC3.mapperRAMBank = -1; gbDataMBC3.mapperClockRegister = value; } } break; case 0x6000: // clock latch if(gbDataMBC3.mapperClockLatch == 0 && value == 1) { memoryUpdateMBC3Clock(); gbDataMBC3.mapperLSeconds = gbDataMBC3.mapperSeconds; gbDataMBC3.mapperLMinutes = gbDataMBC3.mapperMinutes; gbDataMBC3.mapperLHours = gbDataMBC3.mapperHours; gbDataMBC3.mapperLDays = gbDataMBC3.mapperDays; gbDataMBC3.mapperLControl = gbDataMBC3.mapperControl; } if(value == 0x00 || value == 0x01) gbDataMBC3.mapperClockLatch = value; break; } } // MBC3 RAM write void mapperMBC3RAM(u16 address, u8 value) { if(gbDataMBC3.mapperRAMEnable) { if(gbDataMBC3.mapperRAMBank != -1) { if(gbRamSize) { gbMemoryMap[address>>12][address & 0x0fff] = value; systemSaveUpdateCounter = SYSTEM_SAVE_UPDATED; } } else { time(&gbDataMBC3.mapperLastTime); gbDataMBC3.mapperLastTime -= (GCSettings.OffsetMinutesUTC*60); switch(gbDataMBC3.mapperClockRegister) { case 0x08: gbDataMBC3.mapperSeconds = value; break; case 0x09: gbDataMBC3.mapperMinutes = value; break; case 0x0a: gbDataMBC3.mapperHours = value; break; case 0x0b: gbDataMBC3.mapperDays = value; break; case 0x0c: if(gbDataMBC3.mapperControl & 0x80) gbDataMBC3.mapperControl = 0x80 | value; else gbDataMBC3.mapperControl = value; break; } } } } // MBC3 read RAM u8 mapperMBC3ReadRAM(u16 address) { if(gbDataMBC3.mapperRAMEnable) { if(gbDataMBC3.mapperRAMBank != -1) { return gbMemoryMap[address>>12][address & 0x0fff]; } switch(gbDataMBC3.mapperClockRegister) { case 0x08: return gbDataMBC3.mapperLSeconds; break; case 0x09: return gbDataMBC3.mapperLMinutes; break; case 0x0a: return gbDataMBC3.mapperLHours; break; case 0x0b: return gbDataMBC3.mapperLDays; break; case 0x0c: return gbDataMBC3.mapperLControl; } } if (!genericflashcardEnable) return 0xff; else if ((address & 0x1000) >= 0x1000) { // The value returned when reading RAM while it's disabled // is constant, exept for the GBASP hardware. // (actually, is the address that read is out of the ROM, the returned value if 0xff...) if (PC.W>=0xff80) return 0xff; else if ((gbHardware & 0x08) && (gbGBCColorType == 2)) { if (address & 1) return 0xfb; else return 0x7a; } else return 0x0a; } else return gbDisabledRam[address & 7]; } void memoryUpdateMapMBC3() { int tmpAddress = gbDataMBC3.mapperROMBank << 14; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; if(gbDataMBC3.mapperRAMBank >= 0 && gbRamSize) { tmpAddress = gbDataMBC3.mapperRAMBank << 13; tmpAddress &= gbRamSizeMask; gbMemoryMap[0x0a] = &gbRam[tmpAddress]; gbMemoryMap[0x0b] = &gbRam[tmpAddress + 0x1000]; } } mapperMBC5 gbDataMBC5 = { 0, // RAM enable 1, // ROM bank 0, // RAM bank 0, // ROM high address 0, // RAM address 0 // is rumble cartridge? }; // MBC5 ROM write registers void mapperMBC5ROM(u16 address, u8 value) { int tmpAddress = 0; switch(address & 0x6000) { case 0x0000: // RAM enable register gbDataMBC5.mapperRAMEnable = ( ( value & 0x0a) == 0x0a ? 1 : 0); break; case 0x2000: // ROM bank select if(address < 0x3000) { value = value & 0xff; if(value == gbDataMBC5.mapperROMBank) break; tmpAddress = (value << 14) | (gbDataMBC5.mapperROMHighAddress << 22) ; tmpAddress &= gbRomSizeMask; gbDataMBC5.mapperROMBank = value; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; } else { value = value & 1; if(value == gbDataMBC5.mapperROMHighAddress) break; tmpAddress = (gbDataMBC5.mapperROMBank << 14) | (value << 22); tmpAddress &= gbRomSizeMask; gbDataMBC5.mapperROMHighAddress = value; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; } break; case 0x4000: // RAM bank select, plus rumble // Some games support rumble, such as Disney Tarzan, but aren't on a // rumble cartridge. As long as the RAM is less than or equal to 256Kbit // we know that the last address line is not used for real RAM addresses, // so it must be a rumble signal instead. if(gbDataMBC5.isRumbleCartridge) { systemCartridgeRumble(value & 0x08); value &= 0x07; } else if (gbRamSizeMask <= 0x7FFF) { systemPossibleCartridgeRumble(value & 0x08); value &= 0x07; } else value &= 0x0f; if(value == gbDataMBC5.mapperRAMBank) break; tmpAddress = value << 13; tmpAddress &= gbRamSizeMask; if(gbRamSize) { gbMemoryMap[0x0a] = &gbRam[tmpAddress]; gbMemoryMap[0x0b] = &gbRam[tmpAddress + 0x1000]; gbDataMBC5.mapperRAMBank = value; gbDataMBC5.mapperRAMAddress = tmpAddress; } break; } } // MBC5 RAM write void mapperMBC5RAM(u16 address, u8 value) { if(gbDataMBC5.mapperRAMEnable) { if(gbRamSize) { gbMemoryMap[address >> 12][address & 0x0fff] = value; systemSaveUpdateCounter = SYSTEM_SAVE_UPDATED; } } } // MBC5 read RAM u8 mapperMBC5ReadRAM(u16 address) { if(gbDataMBC5.mapperRAMEnable) return gbMemoryMap[address>>12][address & 0x0fff]; if (!genericflashcardEnable) return 0xff; else if ((address & 0x1000) >= 0x1000) { // The value returned when reading RAM while it's disabled // is constant, exept for the GBASP hardware. // (actually, is the address that read is out of the ROM, the returned value if 0xff...) if (PC.W>=0xff80) return 0xff; else if ((gbHardware & 0x08) && (gbGBCColorType == 2)) { if (address & 1) return 0xfb; else return 0x7a; } else return 0x0a; } else return gbDisabledRam[address & 7]; } void memoryUpdateMapMBC5() { int tmpAddress = (gbDataMBC5.mapperROMBank << 14) | (gbDataMBC5.mapperROMHighAddress << 22) ; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; if(gbRamSize) { tmpAddress = gbDataMBC5.mapperRAMBank << 13; tmpAddress &= gbRamSizeMask; gbMemoryMap[0x0a] = &gbRam[tmpAddress]; gbMemoryMap[0x0b] = &gbRam[tmpAddress + 0x1000]; } } mapperMBC7 gbDataMBC7 = { 0, // RAM enable 1, // ROM bank 0, // RAM bank 0, // RAM address 0, // chip select 0, // ?? 0, // mapper state 0, // buffer for receiving serial data 0, // idle state 0, // count of bits received 0, // command received 0, // address received 0, // write enable 0, // value to return on ram }; // MBC7 ROM write registers void mapperMBC7ROM(u16 address, u8 value) { int tmpAddress = 0; switch(address & 0x6000) { case 0x0000: break; case 0x2000: // ROM bank select value = value & 0x7f; if(value == 0) value = 1; if(value == gbDataMBC7.mapperROMBank) break; tmpAddress = (value << 14); tmpAddress &= gbRomSizeMask; gbDataMBC7.mapperROMBank = value; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; break; case 0x4000: // RAM bank select/enable if(value < 8) { tmpAddress = (value&3) << 13; tmpAddress &= gbRamSizeMask; gbMemoryMap[0x0a] = &gbMemory[0xa000]; gbMemoryMap[0x0b] = &gbMemory[0xb000]; gbDataMBC7.mapperRAMBank = value; gbDataMBC7.mapperRAMAddress = tmpAddress; gbDataMBC7.mapperRAMEnable = 0; } else { gbDataMBC7.mapperRAMEnable = 0; } break; } } // MBC7 read RAM u8 mapperMBC7ReadRAM(u16 address) { switch(address & 0xa0f0) { case 0xa000: case 0xa010: case 0xa060: case 0xa070: return 0; case 0xa020: // sensor X low byte return systemGetSensorX() & 255; case 0xa030: // sensor X high byte return systemGetSensorX() >> 8; case 0xa040: // sensor Y low byte return systemGetSensorY() & 255; case 0xa050: // sensor Y high byte return systemGetSensorY() >> 8; case 0xa080: return gbDataMBC7.value; } if (!genericflashcardEnable) return 0xff; else if ((address & 0x1000) >= 0x1000) { // The value returned when reading RAM while it's disabled // is constant, exept for the GBASP hardware. // (actually, is the address that read is out of the ROM, the returned value if 0xff...) if (PC.W>=0xff80) return 0xff; else if ((gbHardware & 0x08) && (gbGBCColorType == 2)) { if (address & 1) return 0xfb; else return 0x7a; } else return 0x0a; } else return gbDisabledRam[address & 7]; } // MBC7 RAM write void mapperMBC7RAM(u16 address, u8 value) { if(address == 0xa080) { // special processing needed int oldCs = gbDataMBC7.cs,oldSk=gbDataMBC7.sk; gbDataMBC7.cs=value>>7; gbDataMBC7.sk=(value>>6)&1; if(!oldCs && gbDataMBC7.cs) { if(gbDataMBC7.state==5) { if(gbDataMBC7.writeEnable) { gbMemory[0xa000+gbDataMBC7.address*2]=gbDataMBC7.buffer>>8; gbMemory[0xa000+gbDataMBC7.address*2+1]=gbDataMBC7.buffer&0xff; systemSaveUpdateCounter = SYSTEM_SAVE_UPDATED; } gbDataMBC7.state=0; gbDataMBC7.value=1; } else { gbDataMBC7.idle=true; gbDataMBC7.state=0; } } if(!oldSk && gbDataMBC7.sk) { if(gbDataMBC7.idle) { if(value & 0x02) { gbDataMBC7.idle=false; gbDataMBC7.count=0; gbDataMBC7.state=1; } } else { switch(gbDataMBC7.state) { case 1: // receiving command gbDataMBC7.buffer <<= 1; gbDataMBC7.buffer |= (value & 0x02)?1:0; gbDataMBC7.count++; if(gbDataMBC7.count==2) { // finished receiving command gbDataMBC7.state=2; gbDataMBC7.count=0; gbDataMBC7.code=gbDataMBC7.buffer & 3; } break; case 2: // receive address gbDataMBC7.buffer <<= 1; gbDataMBC7.buffer |= (value&0x02)?1:0; gbDataMBC7.count++; if(gbDataMBC7.count==8) { // finish receiving gbDataMBC7.state=3; gbDataMBC7.count=0; gbDataMBC7.address=gbDataMBC7.buffer&0xff; if(gbDataMBC7.code==0) { if((gbDataMBC7.address>>6)==0) { gbDataMBC7.writeEnable=0; gbDataMBC7.state=0; } else if((gbDataMBC7.address>>6) == 3) { gbDataMBC7.writeEnable=1; gbDataMBC7.state=0; } } } break; case 3: gbDataMBC7.buffer <<= 1; gbDataMBC7.buffer |= (value&0x02)?1:0; gbDataMBC7.count++; switch(gbDataMBC7.code) { case 0: if(gbDataMBC7.count==16) { if((gbDataMBC7.address>>6)==0) { gbDataMBC7.writeEnable = 0; gbDataMBC7.state=0; } else if((gbDataMBC7.address>>6)==1) { if (gbDataMBC7.writeEnable) { for(int i=0;i<256;i++) { gbMemory[0xa000+i*2] = gbDataMBC7.buffer >> 8; gbMemory[0xa000+i*2+1] = gbDataMBC7.buffer & 0xff; systemSaveUpdateCounter = SYSTEM_SAVE_UPDATED; } } gbDataMBC7.state=5; } else if((gbDataMBC7.address>>6) == 2) { if (gbDataMBC7.writeEnable) { for(int i=0;i<256;i++) WRITE16LE((u16 *)&gbMemory[0xa000+i*2], 0xffff); systemSaveUpdateCounter = SYSTEM_SAVE_UPDATED; } gbDataMBC7.state=5; } else if((gbDataMBC7.address>>6)==3) { gbDataMBC7.writeEnable = 1; gbDataMBC7.state=0; } gbDataMBC7.count=0; } break; case 1: if(gbDataMBC7.count==16) { gbDataMBC7.count=0; gbDataMBC7.state=5; gbDataMBC7.value=0; } break; case 2: if(gbDataMBC7.count==1) { gbDataMBC7.state=4; gbDataMBC7.count=0; gbDataMBC7.buffer = (gbMemory[0xa000+gbDataMBC7.address*2]<<8)| (gbMemory[0xa000+gbDataMBC7.address*2+1]); } break; case 3: if(gbDataMBC7.count==16) { gbDataMBC7.count=0; gbDataMBC7.state=5; gbDataMBC7.value=0; gbDataMBC7.buffer=0xffff; } break; } break; } } } if (oldSk && !gbDataMBC7.sk) { if (gbDataMBC7.state==4) { gbDataMBC7.value = (gbDataMBC7.buffer & 0x8000)?1:0; gbDataMBC7.buffer <<= 1; gbDataMBC7.count++; if (gbDataMBC7.count==16) { gbDataMBC7.count=0; gbDataMBC7.state=0; } } } } } void memoryUpdateMapMBC7() { int tmpAddress = (gbDataMBC7.mapperROMBank << 14); tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; } mapperHuC1 gbDataHuC1 = { 0, // RAM enable 1, // ROM bank 0, // RAM bank 0, // memory model 0, // ROM high address 0 // RAM address }; // HuC1 ROM write registers void mapperHuC1ROM(u16 address, u8 value) { int tmpAddress = 0; switch(address & 0x6000) { case 0x0000: // RAM enable register gbDataHuC1.mapperRAMEnable = ( ( value & 0x0a) == 0x0a ? 1 : 0); break; case 0x2000: // ROM bank select value = value & 0x3f; if(value == 0) value = 1; if(value == gbDataHuC1.mapperROMBank) break; tmpAddress = value << 14; tmpAddress &= gbRomSizeMask; gbDataHuC1.mapperROMBank = value; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; break; case 0x4000: // RAM bank select if(gbDataHuC1.mapperMemoryModel == 1) { // 4/32 model, RAM bank switching provided value = value & 0x03; if(value == gbDataHuC1.mapperRAMBank) break; tmpAddress = value << 13; tmpAddress &= gbRamSizeMask; gbMemoryMap[0x0a] = &gbRam[tmpAddress]; gbMemoryMap[0x0b] = &gbRam[tmpAddress + 0x1000]; gbDataHuC1.mapperRAMBank = value; gbDataHuC1.mapperRAMAddress = tmpAddress; } else { // 16/8, set the high address gbDataHuC1.mapperROMHighAddress = value & 0x03; tmpAddress = gbDataHuC1.mapperROMBank << 14; tmpAddress |= (gbDataHuC1.mapperROMHighAddress) << 19; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; } break; case 0x6000: // memory model select gbDataHuC1.mapperMemoryModel = value & 1; break; } } // HuC1 RAM write void mapperHuC1RAM(u16 address, u8 value) { if(gbDataHuC1.mapperRAMEnable) { if(gbRamSize) { gbMemoryMap[address >> 12][address & 0x0fff] = value; systemSaveUpdateCounter = SYSTEM_SAVE_UPDATED; } } } void memoryUpdateMapHuC1() { int tmpAddress = gbDataHuC1.mapperROMBank << 14; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; if(gbRamSize) { tmpAddress = gbDataHuC1.mapperRAMBank << 13; tmpAddress &= gbRamSizeMask; gbMemoryMap[0x0a] = &gbRam[tmpAddress]; gbMemoryMap[0x0b] = &gbRam[tmpAddress + 0x1000]; } } mapperHuC3 gbDataHuC3 = { 0, // RAM enable 1, // ROM bank 0, // RAM bank 0, // RAM address 0, // RAM flag 0 // RAM read value }; // HuC3 ROM write registers void mapperHuC3ROM(u16 address, u8 value) { int tmpAddress = 0; switch(address & 0x6000) { case 0x0000: // RAM enable register gbDataHuC3.mapperRAMEnable = ( value == 0x0a ? 1 : 0); gbDataHuC3.mapperRAMFlag = value; if(gbDataHuC3.mapperRAMFlag != 0x0a) gbDataHuC3.mapperRAMBank = -1; break; case 0x2000: // ROM bank select value = value & 0x7f; if(value == 0) value = 1; if(value == gbDataHuC3.mapperROMBank) break; tmpAddress = value << 14; tmpAddress &= gbRomSizeMask; gbDataHuC3.mapperROMBank = value; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; break; case 0x4000: // RAM bank select value = value & 0x03; if(value == gbDataHuC3.mapperRAMBank) break; tmpAddress = value << 13; tmpAddress &= gbRamSizeMask; gbMemoryMap[0x0a] = &gbRam[tmpAddress]; gbMemoryMap[0x0b] = &gbRam[tmpAddress + 0x1000]; gbDataHuC3.mapperRAMBank = value; gbDataHuC3.mapperRAMAddress = tmpAddress; break; case 0x6000: // nothing to do! break; } } // HuC3 read RAM u8 mapperHuC3ReadRAM(u16 address) { if(gbDataHuC3.mapperRAMFlag > 0x0b && gbDataHuC3.mapperRAMFlag < 0x0e) { if(gbDataHuC3.mapperRAMFlag != 0x0c) return 1; return gbDataHuC3.mapperRAMValue; } else return gbMemoryMap[address >> 12][address & 0x0fff]; } // HuC3 RAM write void mapperHuC3RAM(u16 address, u8 value) { int *p; if(gbDataHuC3.mapperRAMFlag < 0x0b || gbDataHuC3.mapperRAMFlag > 0x0e) { if(gbDataHuC3.mapperRAMEnable) { if(gbRamSize) { gbMemoryMap[address >> 12][address & 0x0fff] = value; systemSaveUpdateCounter = SYSTEM_SAVE_UPDATED; } } } else { if(gbDataHuC3.mapperRAMFlag == 0x0b) { if(value == 0x62) { gbDataHuC3.mapperRAMValue = 1; } else { switch(value & 0xf0) { case 0x10: p = &gbDataHuC3.mapperRegister2; gbDataHuC3.mapperRAMValue = *(p+gbDataHuC3.mapperRegister1++); if(gbDataHuC3.mapperRegister1 > 6) gbDataHuC3.mapperRegister1 = 0; break; case 0x30: p = &gbDataHuC3.mapperRegister2; *(p+gbDataHuC3.mapperRegister1++) = value & 0x0f; if(gbDataHuC3.mapperRegister1 > 6) gbDataHuC3.mapperRegister1 = 0; gbDataHuC3.mapperAddress = (gbDataHuC3.mapperRegister6 << 24) | (gbDataHuC3.mapperRegister5 << 16) | (gbDataHuC3.mapperRegister4 << 8) | (gbDataHuC3.mapperRegister3 << 4) | (gbDataHuC3.mapperRegister2); break; case 0x40: gbDataHuC3.mapperRegister1 = (gbDataHuC3.mapperRegister1 & 0xf0) | (value & 0x0f); gbDataHuC3.mapperRegister2 = (gbDataHuC3.mapperAddress & 0x0f); gbDataHuC3.mapperRegister3 = ((gbDataHuC3.mapperAddress>>4)&0x0f); gbDataHuC3.mapperRegister4 = ((gbDataHuC3.mapperAddress>>8)&0x0f); gbDataHuC3.mapperRegister5 = ((gbDataHuC3.mapperAddress>>16)&0x0f); gbDataHuC3.mapperRegister6 = ((gbDataHuC3.mapperAddress>>24)&0x0f); gbDataHuC3.mapperRegister7 = 0; gbDataHuC3.mapperRegister8 = 0; gbDataHuC3.mapperRAMValue = 0; break; case 0x50: gbDataHuC3.mapperRegister1 = (gbDataHuC3.mapperRegister1 & 0x0f) | ((value << 4)&0x0f); break; default: gbDataHuC3.mapperRAMValue = 1; break; } } } } } void memoryUpdateMapHuC3() { int tmpAddress = gbDataHuC3.mapperROMBank << 14; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; if(gbRamSize) { tmpAddress = gbDataHuC3.mapperRAMBank << 13; tmpAddress &= gbRamSizeMask; gbMemoryMap[0x0a] = &gbRam[tmpAddress]; gbMemoryMap[0x0b] = &gbRam[tmpAddress + 0x1000]; } } // TAMA5 (for Tamagotchi 3 (gb)). // Very basic (and ugly :p) support, only rom bank switching is actually working... mapperTAMA5 gbDataTAMA5 = { 1, // RAM enable 1, // ROM bank 0, // RAM bank 0, // RAM address 0, // RAM Byte select 0, // mapper command number 0, // mapper last command; { 0, // commands 0x0 0, // commands 0x1 0, // commands 0x2 0, // commands 0x3 0, // commands 0x4 0, // commands 0x5 0, // commands 0x6 0, // commands 0x7 0, // commands 0x8 0, // commands 0x9 0, // commands 0xa 0, // commands 0xb 0, // commands 0xc 0, // commands 0xd 0, // commands 0xe 0 // commands 0xf }, 0, // register 0, // timer clock latch 0, // timer clock register 0, // timer seconds 0, // timer minutes 0, // timer hours 0, // timer days 0, // timer months 0, // timer years 0, // timer control 0, // timer latched seconds 0, // timer latched minutes 0, // timer latched hours 0, // timer latched days 0, // timer latched months 0, // timer latched years 0, // timer latched control (time_t)-1 // last time }; void memoryUpdateTAMA5Clock() { if ((gbDataTAMA5.mapperYears & 3) == 0) gbDaysinMonth[1] = 29; else gbDaysinMonth[1] = 28; time_t now = time(NULL) - (GCSettings.OffsetMinutesUTC*60); time_t diff = now - gbDataTAMA5.mapperLastTime; if(diff > 0) { // update the clock according to the last update time gbDataTAMA5.mapperSeconds += (int)(diff % 60); if(gbDataTAMA5.mapperSeconds > 59) { gbDataTAMA5.mapperSeconds -= 60; gbDataTAMA5.mapperMinutes++; } diff /= 60; gbDataTAMA5.mapperMinutes += (int)(diff % 60); if(gbDataTAMA5.mapperMinutes > 59) { gbDataTAMA5.mapperMinutes -= 60; gbDataTAMA5.mapperHours++; } diff /= 60; gbDataTAMA5.mapperHours += (int)(diff % 24); diff /= 24; if(gbDataTAMA5.mapperHours > 23) { gbDataTAMA5.mapperHours -= 24; diff++; } time_t days = diff; while (days) { gbDataTAMA5.mapperDays++; days--; if (gbDataTAMA5.mapperDays>gbDaysinMonth[gbDataTAMA5.mapperMonths-1]) { gbDataTAMA5.mapperDays = 1; gbDataTAMA5.mapperMonths++; if (gbDataTAMA5.mapperMonths>12) { gbDataTAMA5.mapperMonths = 1; gbDataTAMA5.mapperYears++; if ((gbDataTAMA5.mapperYears & 3) == 0) gbDaysinMonth[1] = 29; else gbDaysinMonth[1] = 28; } } } } gbDataTAMA5.mapperLastTime = now; } // TAMA5 RAM write void mapperTAMA5RAM(u16 address, u8 value) { if ((address & 0xffff) <= 0xa001) { switch (address & 1) { case 0: // 'Values' Register { value &= 0xf; gbDataTAMA5.mapperCommands[gbDataTAMA5.mapperCommandNumber] = value; gbMemoryMap[0xa][0] = value; /* int test = gbDataTAMA5.mapperCommands[gbDataTAMA5.mapperCommandNumber & 0x0e] | (gbDataTAMA5.mapperCommands[(gbDataTAMA5.mapperCommandNumber & 0x0e) +1]<<4);*/ if ((gbDataTAMA5.mapperCommandNumber & 0xe) == 0) // Read Command !!! { gbDataTAMA5.mapperROMBank = gbDataTAMA5.mapperCommands[0] | (gbDataTAMA5.mapperCommands[1]<<4); int tmpAddress = (gbDataTAMA5.mapperROMBank << 14); tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; gbDataTAMA5.mapperCommands[0x0f] = 0; } else if ((gbDataTAMA5.mapperCommandNumber & 0xe) == 4) { gbDataTAMA5.mapperCommands[0x0f] = 1; if (gbDataTAMA5.mapperCommandNumber == 4) gbDataTAMA5.mapperCommands[5] =0; // correct ? } else if ((gbDataTAMA5.mapperCommandNumber & 0xe) == 6) { gbDataTAMA5.mapperRamByteSelect = (gbDataTAMA5.mapperCommands[7]<<4) | (gbDataTAMA5.mapperCommands[6]&0x0f); // Write Commands !!! if (gbDataTAMA5.mapperCommands[0x0f] && (gbDataTAMA5.mapperCommandNumber == 7)) { int data = (gbDataTAMA5.mapperCommands[0x04] & 0x0f) | (gbDataTAMA5.mapperCommands[0x05] <<4); // Not sure when the write command should reset... // but it doesn't seem to matter. // gbDataTAMA5.mapperCommands[0x0f] = 0; if (gbDataTAMA5.mapperRamByteSelect == 0x8) // Timer stuff { switch (data & 0xf) { case 0x7: gbDataTAMA5.mapperDays = ((gbDataTAMA5.mapperDays)/10)*10 + (data >> 4); break; case 0x8: gbDataTAMA5.mapperDays = (gbDataTAMA5.mapperDays%10) + (data >>4)*10; break; case 0x9: gbDataTAMA5.mapperMonths = ((gbDataTAMA5.mapperMonths)/10)*10 + (data >> 4); break; case 0xa: gbDataTAMA5.mapperMonths = (gbDataTAMA5.mapperMonths%10) + (data >>4)*10; break; case 0xb: gbDataTAMA5.mapperYears = ((gbDataTAMA5.mapperYears)%1000) + (data >> 4)*1000; break; case 0xc: gbDataTAMA5.mapperYears = (gbDataTAMA5.mapperYears%100) + (gbDataTAMA5.mapperYears/1000)*1000 + (data >>4)*100; break; default : break; } } else if (gbDataTAMA5.mapperRamByteSelect == 0x18) // Timer stuff again { memoryUpdateTAMA5Clock(); gbDataTAMA5.mapperLSeconds = gbDataTAMA5.mapperSeconds; gbDataTAMA5.mapperLMinutes = gbDataTAMA5.mapperMinutes; gbDataTAMA5.mapperLHours = gbDataTAMA5.mapperHours; gbDataTAMA5.mapperLDays = gbDataTAMA5.mapperDays; gbDataTAMA5.mapperLMonths = gbDataTAMA5.mapperMonths; gbDataTAMA5.mapperLYears = gbDataTAMA5.mapperYears; gbDataTAMA5.mapperLControl = gbDataTAMA5.mapperControl; int seconds = (gbDataTAMA5.mapperLSeconds / 10)*16 + gbDataTAMA5.mapperLSeconds %10; int secondsL = (gbDataTAMA5.mapperLSeconds % 10); int secondsH = (gbDataTAMA5.mapperLSeconds / 10); int minutes = (gbDataTAMA5.mapperLMinutes / 10)*16 + gbDataTAMA5.mapperLMinutes %10; int hours = (gbDataTAMA5.mapperLHours / 10)*16 + gbDataTAMA5.mapperLHours %10; int DaysL = gbDataTAMA5.mapperLDays % 10; int DaysH = gbDataTAMA5.mapperLDays /10; int MonthsL = gbDataTAMA5.mapperLMonths % 10; int MonthsH = gbDataTAMA5.mapperLMonths / 10; int Years3 = (gbDataTAMA5.mapperLYears / 100) % 10; int Years4 = (gbDataTAMA5.mapperLYears / 1000); switch (data & 0x0f) { // I guess cases 0 and 1 are used for secondsL and secondsH // so the game would update the timer values on screen when // the seconds reset to 0... ? case 0x0: gbTAMA5ram[gbDataTAMA5.mapperRamByteSelect] = secondsL; break; case 0x1: gbTAMA5ram[gbDataTAMA5.mapperRamByteSelect] = secondsH; break; case 0x7: gbTAMA5ram[gbDataTAMA5.mapperRamByteSelect] = DaysL; // days low break; case 0x8: gbTAMA5ram[gbDataTAMA5.mapperRamByteSelect] = DaysH; // days high break; case 0x9: gbTAMA5ram[gbDataTAMA5.mapperRamByteSelect] = MonthsL; // month low break; case 0xa: gbTAMA5ram[gbDataTAMA5.mapperRamByteSelect] = MonthsH; // month high break; case 0xb: gbTAMA5ram[gbDataTAMA5.mapperRamByteSelect] = Years4; // years 4th digit break; case 0xc: gbTAMA5ram[gbDataTAMA5.mapperRamByteSelect] = Years3; // years 3rd digit break; default : break; } gbTAMA5ram[0x54] = seconds; // incorrect ? (not used by the game) ? gbTAMA5ram[0x64] = minutes; gbTAMA5ram[0x74] = hours; gbTAMA5ram[0x84] = DaysH*16+DaysL; // incorrect ? (not used by the game) ? gbTAMA5ram[0x94] = MonthsH*16+MonthsL; // incorrect ? (not used by the game) ? time(&gbDataTAMA5.mapperLastTime); gbDataMBC3.mapperLastTime -= (GCSettings.OffsetMinutesUTC*60); gbMemoryMap[0xa][0] = 1; } else if (gbDataTAMA5.mapperRamByteSelect == 0x28) // Timer stuff again { if ((data & 0xf) == 0xb) gbDataTAMA5.mapperYears = ((gbDataTAMA5.mapperYears>>2)<<2) + (data & 3); } else if (gbDataTAMA5.mapperRamByteSelect == 0x44) { gbDataTAMA5.mapperMinutes = (data/16)*10 + data%16; } else if (gbDataTAMA5.mapperRamByteSelect == 0x54) { gbDataTAMA5.mapperHours = (data/16)*10 + data%16; } else { gbTAMA5ram[gbDataTAMA5.mapperRamByteSelect] = data; } } } } break; case 1: // 'Commands' Register { gbMemoryMap[0xa][1] = gbDataTAMA5.mapperCommandNumber = value; // This should be only a 'is the flashrom ready ?' command. // However as I couldn't find any 'copy' command // (that seems to be needed for the saving system to work) // I put it there... if (value == 0x0a) { for (int i = 0; i<0x10; i++) for (int j = 0; j<0x10; j++) if (!(j&2)) gbTAMA5ram[((i*0x10)+j) | 2] = gbTAMA5ram[(i*0x10)+j]; // Enable this to see the content of the flashrom in 0xe000 /*for (int k = 0; k<0x100; k++) gbMemoryMap[0xe][k] = gbTAMA5ram[k];*/ gbMemoryMap[0xa][0] = gbDataTAMA5.mapperRAMEnable = 1; } else { if ((value & 0x0e) == 0x0c) { gbDataTAMA5.mapperRamByteSelect = gbDataTAMA5.mapperCommands[6] | (gbDataTAMA5.mapperCommands[7]<<4); u8 byte = gbTAMA5ram[gbDataTAMA5.mapperRamByteSelect]; gbMemoryMap[0xa][0] = (value & 1) ? byte >> 4 : byte & 0x0f; gbDataTAMA5.mapperCommands[0x0f] = 0; } } break; } } } else { if(gbDataTAMA5.mapperRAMEnable) { if(gbDataTAMA5.mapperRAMBank != -1) { if(gbRamSize) { gbMemoryMap[address>>12][address & 0x0fff] = value; systemSaveUpdateCounter = SYSTEM_SAVE_UPDATED; } } } } } // TAMA5 read RAM u8 mapperTAMA5ReadRAM(u16 address) { return gbMemoryMap[address>>12][address & 0xfff]; } void memoryUpdateMapTAMA5() { int tmpAddress = (gbDataTAMA5.mapperROMBank << 14); tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; if(gbRamSize) { tmpAddress = 0 << 13; tmpAddress &= gbRamSizeMask; gbMemoryMap[0x0a] = &gbRam[tmpAddress]; gbMemoryMap[0x0b] = &gbRam[tmpAddress + 0x1000]; } } // MMM01 Used in Momotarou collection (however the rom is corrupted) mapperMMM01 gbDataMMM01 ={ 0, // RAM enable 1, // ROM bank 0, // RAM bank 0, // memory model 0, // ROM high address 0, // RAM address 0 // Rom Bank 0 remapping }; // MMM01 ROM write registers void mapperMMM01ROM(u16 address, u8 value) { int tmpAddress = 0; switch(address & 0x6000) { case 0x0000: // RAM enable register gbDataMMM01.mapperRAMEnable = ( ( value & 0x0a) == 0x0a ? 1 : 0); break; case 0x2000: // ROM bank select // value = value & 0x1f; if(value == 0) value = 1; if(value == gbDataMMM01.mapperROMBank) break; tmpAddress = value << 14; // check current model if(gbDataMMM01.mapperMemoryModel == 0) { // model is 16/8, so we have a high address in use tmpAddress |= (gbDataMMM01.mapperROMHighAddress) << 19; } else tmpAddress |= gbDataMMM01.mapperRomBank0Remapping << 18; tmpAddress &= gbRomSizeMask; gbDataMMM01.mapperROMBank = value; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; break; case 0x4000: // RAM bank select if(gbDataMMM01.mapperMemoryModel == 1) { // 4/32 model, RAM bank switching provided value = value & 0x03; if(value == gbDataMBC1.mapperRAMBank) break; tmpAddress = value << 13; tmpAddress &= gbRamSizeMask; gbMemoryMap[0x0a] = &gbRam[tmpAddress]; gbMemoryMap[0x0b] = &gbRam[tmpAddress + 0x1000]; gbDataMMM01.mapperRAMBank = value; gbDataMMM01.mapperRAMAddress = tmpAddress; } else { // 16/8, set the high address gbDataMMM01.mapperROMHighAddress = value & 0x03; tmpAddress = gbDataMMM01.mapperROMBank << 14; tmpAddress |= (gbDataMMM01.mapperROMHighAddress) << 19; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; gbDataMMM01.mapperRomBank0Remapping = ((value<<1) | (value & 0x40 ? 1 : 0)) & 0xff; tmpAddress = gbDataMMM01.mapperRomBank0Remapping << 18; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x00] = &gbRom[tmpAddress]; gbMemoryMap[0x01] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x02] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x03] = &gbRom[tmpAddress + 0x3000]; } break; case 0x6000: // memory model select gbDataMMM01.mapperMemoryModel = value & 1; break; } } // MMM01 RAM write void mapperMMM01RAM(u16 address, u8 value) { if(gbDataMMM01.mapperRAMEnable) { if(gbRamSize) { gbMemoryMap[address >> 12][address & 0x0fff] = value; systemSaveUpdateCounter = SYSTEM_SAVE_UPDATED; } } } void memoryUpdateMapMMM01() { int tmpAddress = gbDataMMM01.mapperROMBank << 14; // check current model if(gbDataMMM01.mapperMemoryModel == 1) { // model is 16/8, so we have a high address in use tmpAddress |= (gbDataMMM01.mapperROMHighAddress) << 19; } tmpAddress &= gbRomSizeMask; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x06] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x07] = &gbRom[tmpAddress + 0x3000]; tmpAddress = gbDataMMM01.mapperRomBank0Remapping << 18; tmpAddress &= gbRomSizeMask; gbMemoryMap[0x00] = &gbRom[tmpAddress]; gbMemoryMap[0x01] = &gbRom[tmpAddress + 0x1000]; gbMemoryMap[0x02] = &gbRom[tmpAddress + 0x2000]; gbMemoryMap[0x03] = &gbRom[tmpAddress + 0x3000]; if(gbRamSize) { gbMemoryMap[0x0a] = &gbRam[gbDataMMM01.mapperRAMAddress]; gbMemoryMap[0x0b] = &gbRam[gbDataMMM01.mapperRAMAddress + 0x1000]; } } // GameGenie ROM write registers void mapperGGROM(u16 address, u8 value) { switch(address & 0x6000) { case 0x0000: // RAM enable register break; case 0x2000: // GameGenie has only a half bank break; case 0x4000: // GameGenie has no RAM if ((address >=0x4001) && (address <= 0x4020)) // GG Hardware Registers gbMemoryMap[address >> 12][address & 0x0fff] = value; break; case 0x6000: // GameGenie has only a half bank break; } } // GS3 Used to emulate the GS V3.0 rom bank switching mapperGS3 gbDataGS3 = { 1 }; // ROM bank void mapperGS3ROM(u16 address, u8 value) { int tmpAddress = 0; switch(address & 0x6000) { case 0x0000: // GS has no ram break; case 0x2000: // GS has no 'classic' ROM bank select break; case 0x4000: // GS has no ram break; case 0x6000: // 0x6000 area is RW, and used for GS hardware registers if (address == 0x7FE1) // This is the (half) ROM bank select register { if(value == gbDataGS3.mapperROMBank) break; tmpAddress = value << 13; tmpAddress &= gbRomSizeMask; gbDataGS3.mapperROMBank = value; gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; } else gbMemoryMap[address>>12][address & 0x0fff] = value; break; } } void memoryUpdateMapGS3() { int tmpAddress = gbDataGS3.mapperROMBank << 13; tmpAddress &= gbRomSizeMask; // GS can only change a half ROM bank gbMemoryMap[0x04] = &gbRom[tmpAddress]; gbMemoryMap[0x05] = &gbRom[tmpAddress + 0x1000]; }