auto VDC::vramRead(uint16 addr) -> uint16 { if(addr.bit(15)) return 0x00; return vram[addr]; } auto VDC::vramWrite(uint16 addr, uint16 data) -> void { if(addr.bit(15)) return; vram[addr] = data; } auto VDC::read(uint11 addr) -> uint8 { bool a0 = addr.bit(0); if(!addr.bit(10)) { //VDC if(addr.bit(1) == 0) { //SR if(a0) return 0x00; uint8 data; data.bit(0) = irq.pendingCollision; data.bit(1) = irq.pendingOverflow; data.bit(2) = irq.pendingLineCoincidence; data.bit(3) = irq.pendingTransferSATB; data.bit(4) = irq.pendingTransferVRAM; data.bit(5) = irq.pendingVblank; irq.lower(); return data; } if(addr.bit(1) == 1) { if(io.address == 0x02) { //VRR uint8 data = io.vramDataRead.byte(a0); if(a0) { io.vramAddressRead += io.vramAddressIncrement; io.vramDataRead = vramRead(io.vramAddressRead); } return data; } } } else { //VCE if(addr.bits(0,2) == 0x04) { //CTR uint8 data = cram[io.colorAddress].bits(0,7); return data; } if(addr.bits(0,2) == 0x05) { //CTR uint8 data = cram[io.colorAddress].bit(0); io.colorAddress++; return data; } } return 0x00; } auto VDC::write(uint11 addr, uint8 data) -> void { bool a0 = addr.bit(0); if(!addr.bit(10)) { //VDC if(addr.bit(1) == 0) { //AR if(a0) return; io.address = data.bits(0,4); return; } if(addr.bit(1) == 1) { if(io.address == 0x00) { //MAWR io.vramAddressWrite.byte(a0) = data; return; } if(io.address == 0x01) { //MARR io.vramAddressRead.byte(a0) = data; io.vramDataRead = vramRead(io.vramAddressRead); return; } if(io.address == 0x02) { //VWR io.vramDataWrite.byte(a0) = data; if(a0) { vramWrite(io.vramAddressWrite, io.vramDataWrite); io.vramAddressWrite += io.vramAddressIncrement; } return; } if(io.address == 0x05) { //CR if(!a0) { irq.enableCollision = data.bit(0); irq.enableOverflow = data.bit(1); irq.enableLineCoincidence = data.bit(2); irq.enableVblank = data.bit(3); io.externalSync = data.bits(4,5); sprite.blank = data.bit(6); background.blank = data.bit(7); } else { io.displayOutput = data.bits(0,1); io.dramRefresh = data.bit(2); if(data.bits(3,4) == 0) io.vramAddressIncrement = 0x01; if(data.bits(3,4) == 1) io.vramAddressIncrement = 0x20; if(data.bits(3,4) == 2) io.vramAddressIncrement = 0x40; if(data.bits(3,4) == 3) io.vramAddressIncrement = 0x80; } return; } if(io.address == 0x06) { //RCR io.lineCoincidence.byte(a0) = data; return; } if(io.address == 0x07) { //BXR background.hscroll.byte(a0) = data; return; } if(io.address == 0x08) { //BYR background.vscroll.byte(a0) = data; return; } if(io.address == 0x09) { //MWR if(a0) return; io.vramAccess = data.bits(0,1); io.spriteAccess = data.bits(2,3); if(data.bits(4,5) == 0) background.width = 32; if(data.bits(4,5) == 1) background.width = 64; if(data.bits(4,5) == 2) background.width = 128; if(data.bits(4,5) == 3) background.width = 128; if(data.bit(6) == 0) background.height = 32; if(data.bit(6) == 1) background.height = 64; io.cgMode = data.bit(7); return; } if(io.address == 0x0a) { //HSR if(!a0) { io.horizontalSyncWidth = data.bits(0,4); } else { io.horizontalDisplayStart = data.bits(0,6); } return; } if(io.address == 0x0b) { //HDR if(!a0) { io.horizontalDisplayWidth = data.bits(0,6); } else { io.horizontalDisplayEnd = data.bits(0,6); } return; } if(io.address == 0x0c) { //VPR if(!a0) { io.verticalSyncWidth = data.bits(0,4); } else { io.verticalDisplayStart = data.bits(0,7); } return; } if(io.address == 0x0d) { //VDR io.verticalDisplayWidth.byte(a0) = data; return; } if(io.address == 0x0e) { //VCR if(a0) return; io.verticalDisplayEnd = data.bits(0,7); return; } if(io.address == 0x0f) { //DCR if(a0) return; irq.enableTransferVRAM = data.bit(0); irq.enableTransferSATB = data.bit(1); dma.sourceIncrementMode = data.bit(2); dma.targetIncrementMode = data.bit(3); dma.satbRepeat = data.bit(4); return; } if(io.address == 0x10) { //SOUR dma.source.byte(a0) = data; return; } if(io.address == 0x11) { //DESR dma.target.byte(a0) = data; return; } if(io.address == 0x12) { //LENR dma.length.byte(a0) = data; if(a0) dma.vramStart(); return; } if(io.address == 0x13) { //DVSSR dma.satbSource.byte(a0) = data; if(a0) dma.satbQueue(); return; } } } else { //VCE if(addr.bits(0,2) == 0x00) { //CR io.divisionRatio = data.bits(0,1); io.colorBlur = data.bit(2); io.grayscale = data.bit(7); return; } if(addr.bits(0,2) == 0x02) { //CTA io.colorAddress.bits(0,7) = data.bits(0,7); return; } if(addr.bits(0,2) == 0x03) { //CTA io.colorAddress.bit(8) = data.bit(0); return; } if(addr.bits(0,2) == 0x04) { //CTW cram[io.colorAddress].bits(0,7) = data.bits(0,7); return; } if(addr.bits(0,2) == 0x05) { //CTW cram[io.colorAddress].bit(8) = data.bit(0); io.colorAddress++; return; } } }