#include #define SDD1_CPP namespace SuperFamicom { SDD1 sdd1; #include "decomp.cpp" #include "serialization.cpp" void SDD1::init() { } void SDD1::load() { //hook S-CPU DMA MMIO registers to gather information for struct dma[]; //buffer address and transfer size information for use in SDD1::mcu_read() bus.map({&SDD1::read, &sdd1}, {&SDD1::write, &sdd1}, 0x00, 0x3f, 0x4300, 0x437f); bus.map({&SDD1::read, &sdd1}, {&SDD1::write, &sdd1}, 0x80, 0xbf, 0x4300, 0x437f); } void SDD1::unload() { rom.reset(); ram.reset(); } void SDD1::power() { } void SDD1::reset() { sdd1_enable = 0x00; xfer_enable = 0x00; dma_ready = false; mmc[0] = 0 << 20; mmc[1] = 1 << 20; mmc[2] = 2 << 20; mmc[3] = 3 << 20; for(unsigned i = 0; i < 8; i++) { dma[i].addr = 0; dma[i].size = 0; } } uint8 SDD1::read(unsigned addr) { addr &= 0xffff; if((addr & 0x4380) == 0x4300) { return cpu.mmio_read(addr); } switch(addr) { case 0x4804: return mmc[0] >> 20; case 0x4805: return mmc[1] >> 20; case 0x4806: return mmc[2] >> 20; case 0x4807: return mmc[3] >> 20; } return cpu.regs.mdr; } void SDD1::write(unsigned addr, uint8 data) { addr &= 0xffff; if((addr & 0x4380) == 0x4300) { unsigned channel = (addr >> 4) & 7; switch(addr & 15) { case 2: dma[channel].addr = (dma[channel].addr & 0xffff00) + (data << 0); break; case 3: dma[channel].addr = (dma[channel].addr & 0xff00ff) + (data << 8); break; case 4: dma[channel].addr = (dma[channel].addr & 0x00ffff) + (data << 16); break; case 5: dma[channel].size = (dma[channel].size & 0xff00) + (data << 0); break; case 6: dma[channel].size = (dma[channel].size & 0x00ff) + (data << 8); break; } return cpu.mmio_write(addr, data); } switch(addr) { case 0x4800: sdd1_enable = data; break; case 0x4801: xfer_enable = data; break; case 0x4804: mmc[0] = data << 20; break; case 0x4805: mmc[1] = data << 20; break; case 0x4806: mmc[2] = data << 20; break; case 0x4807: mmc[3] = data << 20; break; } } uint8 SDD1::mmc_read(unsigned addr) { return rom.read(mmc[(addr >> 20) & 3] + (addr & 0x0fffff)); } //SDD1::mcu_read() is mapped to $c0-ff:0000-ffff //the design is meant to be as close to the hardware design as possible, thus this code //avoids adding S-DD1 hooks inside S-CPU::DMA emulation. // //the real S-DD1 cannot see $420b (DMA enable) writes, as they are not placed on the bus. //however, $43x0-$43xf writes (DMAx channel settings) most likely do appear on the bus. //the S-DD1 also requires fixed addresses for transfers, which wouldn't be necessary if //it could see $420b writes (eg it would know when the transfer should begin.) // //the hardware needs a way to distinguish program code after $4801 writes from DMA //decompression that follows soon after. // //the only plausible design for hardware would be for the S-DD1 to spy on DMAx settings, //and begin spooling decompression on writes to $4801 that activate a channel. after that, //it feeds decompressed data only when the ROM read address matches the DMA channel address. // //the actual S-DD1 transfer can occur on any channel, but it is most likely limited to //one transfer per $420b write (for spooling purposes). however, this is not known for certain. uint8 SDD1::mcurom_read(unsigned addr) { if(addr < 0x400000) { //(addr & 0x408000) == 0x008000) { //$00-3f|80-bf:8000-ffff return rom.read(addr); //addr = ((addr & 0x7f0000) >> 1) | (addr & 0x7fff); //return rom.read(addr); } //$40-7f|c0-ff:0000-ffff (MMC) if(sdd1_enable & xfer_enable) { //at least one channel has S-DD1 decompression enabled ... for(unsigned i = 0; i < 8; i++) { if(sdd1_enable & xfer_enable & (1 << i)) { //S-DD1 always uses fixed transfer mode, so address will not change during transfer if(addr == dma[i].addr) { if(!dma_ready) { //prepare streaming decompression decomp.init(addr); dma_ready = true; } //fetch a decompressed byte; once finished, disable channel and invalidate buffer uint8 data = decomp.read(); if(--dma[i].size == 0) { dma_ready = false; xfer_enable &= ~(1 << i); } return data; } //address matched } //channel enabled } //channel loop } //S-DD1 decompressor enabled //S-DD1 decompression mode inactive; return ROM data return mmc_read(addr); } void SDD1::mcurom_write(unsigned addr, uint8 data) { } uint8 SDD1::mcuram_read(unsigned addr) { if((addr & 0x60e000) == 0x006000) { //$00-3f|80-bf:6000-7fff return ram.read(addr & 0x1fff); } if((addr & 0xf08000) == 0x700000) { //$70-7f:0000-7fff return ram.read(addr & 0x1fff); } return cpu.regs.mdr; } void SDD1::mcuram_write(unsigned addr, uint8 data) { if((addr & 0x60e000) == 0x006000) { //$00-3f|80-bf:6000-7fff return ram.write(addr & 0x1fff, data); } if((addr & 0xf08000) == 0x700000) { //$70-7f:0000-7fff return ram.write(addr & 0x1fff, data); } } }