auto CPU::readIWRAM(uint mode, uint32 addr) -> uint32 { if(memory.disable) return cpu.pipeline.fetch.instruction; if(mode & Word) return readIWRAM(Half, addr &~ 2) << 0 | readIWRAM(Half, addr | 2) << 16; if(mode & Half) return readIWRAM(Byte, addr &~ 1) << 0 | readIWRAM(Byte, addr | 1) << 8; return iwram[addr & 0x7fff]; } auto CPU::writeIWRAM(uint mode, uint32 addr, uint32 word) -> void { if(memory.disable) return; if(mode & Word) { writeIWRAM(Half, addr &~2, word >> 0); writeIWRAM(Half, addr | 2, word >> 16); return; } if(mode & Half) { writeIWRAM(Byte, addr &~1, word >> 0); writeIWRAM(Byte, addr | 1, word >> 8); return; } iwram[addr & 0x7fff] = word; } auto CPU::readEWRAM(uint mode, uint32 addr) -> uint32 { if(memory.disable) return cpu.pipeline.fetch.instruction; if(!memory.ewram) return readIWRAM(mode, addr); if(mode & Word) return readEWRAM(Half, addr &~ 2) << 0 | readEWRAM(Half, addr | 2) << 16; if(mode & Half) return readEWRAM(Byte, addr &~ 1) << 0 | readEWRAM(Byte, addr | 1) << 8; return ewram[addr & 0x3ffff]; } auto CPU::writeEWRAM(uint mode, uint32 addr, uint32 word) -> void { if(memory.disable) return; if(!memory.ewram) return writeIWRAM(mode, addr, word); if(mode & Word) { writeEWRAM(Half, addr &~2, word >> 0); writeEWRAM(Half, addr | 2, word >> 16); return; } if(mode & Half) { writeEWRAM(Byte, addr &~1, word >> 0); writeEWRAM(Byte, addr | 1, word >> 8); return; } ewram[addr & 0x3ffff] = word; }