struct MMC3 : Chip { MMC3(Board& board) : Chip(board) { } auto main() -> void { if(irqDelay) irqDelay--; cpu.irqLine(irqLine); tick(); } auto irqTest(uint addr) -> void { if(!(chrAbus & 0x1000) && (addr & 0x1000)) { if(irqDelay == 0) { if(irqCounter == 0) { irqCounter = irqLatch; } else if(--irqCounter == 0) { if(irqEnable) irqLine = 1; } } irqDelay = 6; } chrAbus = addr; } auto addrPRG(uint addr) const -> uint { switch((addr >> 13) & 3) { case 0: if(prgMode == 1) return (0x3e << 13) | (addr & 0x1fff); return (prgBank[0] << 13) | (addr & 0x1fff); case 1: return (prgBank[1] << 13) | (addr & 0x1fff); case 2: if(prgMode == 0) return (0x3e << 13) | (addr & 0x1fff); return (prgBank[0] << 13) | (addr & 0x1fff); case 3: return (0x3f << 13) | (addr & 0x1fff); } } auto addrCHR(uint addr) const -> uint { if(chrMode == 0) { if(addr <= 0x07ff) return (chrBank[0] << 10) | (addr & 0x07ff); if(addr <= 0x0fff) return (chrBank[1] << 10) | (addr & 0x07ff); if(addr <= 0x13ff) return (chrBank[2] << 10) | (addr & 0x03ff); if(addr <= 0x17ff) return (chrBank[3] << 10) | (addr & 0x03ff); if(addr <= 0x1bff) return (chrBank[4] << 10) | (addr & 0x03ff); if(addr <= 0x1fff) return (chrBank[5] << 10) | (addr & 0x03ff); } else { if(addr <= 0x03ff) return (chrBank[2] << 10) | (addr & 0x03ff); if(addr <= 0x07ff) return (chrBank[3] << 10) | (addr & 0x03ff); if(addr <= 0x0bff) return (chrBank[4] << 10) | (addr & 0x03ff); if(addr <= 0x0fff) return (chrBank[5] << 10) | (addr & 0x03ff); if(addr <= 0x17ff) return (chrBank[0] << 10) | (addr & 0x07ff); if(addr <= 0x1fff) return (chrBank[1] << 10) | (addr & 0x07ff); } } auto addrCIRAM(uint addr) const -> uint { if(mirror == 0) return ((addr & 0x0400) >> 0) | (addr & 0x03ff); if(mirror == 1) return ((addr & 0x0800) >> 1) | (addr & 0x03ff); } auto readRAM(uint addr) -> uint8 { if(ramEnable) return board.prgram.data[addr & 0x1fff]; return 0x00; } auto writeRAM(uint addr, uint8 data) -> void { if(ramEnable && !ramWriteProtect) board.prgram.data[addr & 0x1fff] = data; } auto writeIO(uint addr, uint8 data) -> void { switch(addr & 0xe001) { case 0x8000: chrMode = data & 0x80; prgMode = data & 0x40; bankSelect = data & 0x07; break; case 0x8001: switch(bankSelect) { case 0: chrBank[0] = data & ~1; break; case 1: chrBank[1] = data & ~1; break; case 2: chrBank[2] = data; break; case 3: chrBank[3] = data; break; case 4: chrBank[4] = data; break; case 5: chrBank[5] = data; break; case 6: prgBank[0] = data & 0x3f; break; case 7: prgBank[1] = data & 0x3f; break; } break; case 0xa000: mirror = data & 0x01; break; case 0xa001: ramEnable = data & 0x80; ramWriteProtect = data & 0x40; break; case 0xc000: irqLatch = data; break; case 0xc001: irqCounter = 0; break; case 0xe000: irqEnable = false; irqLine = 0; break; case 0xe001: irqEnable = true; break; } } auto power() -> void { } auto reset() -> void { chrMode = 0; prgMode = 0; bankSelect = 0; prgBank[0] = 0; prgBank[1] = 0; chrBank[0] = 0; chrBank[1] = 0; chrBank[2] = 0; chrBank[3] = 0; chrBank[4] = 0; chrBank[5] = 0; mirror = 0; ramEnable = 1; ramWriteProtect = 0; irqLatch = 0; irqCounter = 0; irqEnable = false; irqDelay = 0; irqLine = 0; chrAbus = 0; } auto serialize(serializer& s) -> void { s.integer(chrMode); s.integer(prgMode); s.integer(bankSelect); s.array(prgBank); s.array(chrBank); s.integer(mirror); s.integer(ramEnable); s.integer(ramWriteProtect); s.integer(irqLatch); s.integer(irqCounter); s.integer(irqEnable); s.integer(irqDelay); s.integer(irqLine); s.integer(chrAbus); } bool chrMode; bool prgMode; uint3 bankSelect; uint8 prgBank[2]; uint8 chrBank[6]; bool mirror; bool ramEnable; bool ramWriteProtect; uint8 irqLatch; uint8 irqCounter; bool irqEnable; uint irqDelay; bool irqLine; uint16 chrAbus; };