bsnes/higan/md/vdp/io.cpp

336 lines
7.3 KiB
C++

auto VDP::read(uint24 addr) -> uint16 {
switch(addr & 0xc0001e) {
//data port
case 0xc00000: case 0xc00002: {
return readDataPort();
}
//control port
case 0xc00004: case 0xc00006: {
return readControlPort();
}
//counter
case 0xc00008: case 0xc0000a: case 0xc0000c: case 0xc0000e: {
auto vcounter = state.vcounter;
if(io.interlaceMode.bit(0)) {
if(io.interlaceMode.bit(1)) vcounter <<= 1;
vcounter.bit(0) = vcounter.bit(8);
}
return vcounter << 8 | (state.hdot >> 1) << 0;
}
}
return 0x0000;
}
auto VDP::write(uint24 addr, uint16 data) -> void {
switch(addr & 0xc0001e) {
//data port
case 0xc00000: case 0xc00002: {
return writeDataPort(data);
}
//control port
case 0xc00004: case 0xc00006: {
return writeControlPort(data);
}
}
}
//
auto VDP::readDataPort() -> uint16 {
io.commandPending = false;
//VRAM read
if(io.command.bits(0,3) == 0) {
auto address = io.address.bits(1,15);
auto data = vram.read(address);
io.address += io.dataIncrement;
return data;
}
//VSRAM read
if(io.command.bits(0,3) == 4) {
auto address = io.address.bits(1,6);
auto data = vsram.read(address);
io.address += io.dataIncrement;
return data;
}
//CRAM read
if(io.command.bits(0,3) == 8) {
auto address = io.address.bits(1,6);
auto data = cram.read(address);
io.address += io.dataIncrement;
return data.bits(0,2) << 1 | data.bits(3,5) << 5 | data.bits(6,8) << 9;
}
return 0x0000;
}
auto VDP::writeDataPort(uint16 data) -> void {
io.commandPending = false;
//DMA VRAM fill
if(dma.io.wait) {
dma.io.wait = false;
dma.io.fill = data >> 8;
//falls through to memory write
//causes extra transfer to occur on VRAM fill operations
}
//VRAM write
if(io.command.bits(0,3) == 1) {
auto address = io.address.bits(1,15);
if(io.address.bit(0)) data = data >> 8 | data << 8;
vram.write(address, data);
io.address += io.dataIncrement;
return;
}
//VSRAM write
if(io.command.bits(0,3) == 5) {
auto address = io.address.bits(1,6);
//data format: ---- --yy yyyy yyyy
vsram.write(address, data.bits(0,9));
io.address += io.dataIncrement;
return;
}
//CRAM write
if(io.command.bits(0,3) == 3) {
auto address = io.address.bits(1,6);
//data format: ---- bbb- ggg- rrr-
cram.write(address, data.bits(1,3) << 0 | data.bits(5,7) << 3 | data.bits(9,11) << 6);
io.address += io.dataIncrement;
return;
}
}
//
auto VDP::readControlPort() -> uint16 {
io.commandPending = false;
uint16 result;
result.bit( 0) = Region::PAL();
result.bit( 1) = io.command.bit(5); //DMA active
result.bit( 2) = state.hcounter >= 1280; //horizontal blank
result.bit( 3) = state.vcounter >= screenHeight(); //vertical blank
result.bit( 4) = io.interlaceMode.bit(0) && state.field;
result.bit( 5) = 0; //SCOL
result.bit( 6) = 0; //SOVR
result.bit( 7) = io.vblankIRQ;
result.bit( 8) = 0; //FIFO full
result.bit( 9) = 1; //FIFO empty
result.bit(10) = 1; //constants (bits 10-15)
result.bit(11) = 0;
result.bit(12) = 1;
result.bit(13) = 1;
result.bit(14) = 0;
result.bit(15) = 0;
return result;
}
auto VDP::writeControlPort(uint16 data) -> void {
//print("[VDPC] ", hex(data, 4L), "\n");
//command write (lo)
if(io.commandPending) {
io.commandPending = false;
io.command.bits(2,5) = data.bits(4,7);
io.address.bits(14,15) = data.bits(0,1);
if(!dma.io.enable) io.command.bit(5) = 0;
if(dma.io.mode == 3) dma.io.wait = false;
return;
}
//command write (hi)
if(data.bits(14,15) != 2) {
io.commandPending = true;
io.command.bits(0,1) = data.bits(14,15);
io.address.bits(0,13) = data.bits(0,13);
return;
}
//register write (d13 is ignored)
if(data.bits(14,15) == 2)
switch(data.bits(8,12)) {
//mode register 1
case 0x00: {
io.displayOverlayEnable = data.bit(0);
io.counterLatch = data.bit(1);
io.horizontalBlankInterruptEnable = data.bit(4);
io.leftColumnBlank = data.bit(5);
return;
}
//mode register 2
case 0x01: {
io.videoMode = data.bit(2);
io.overscan = data.bit(3);
dma.io.enable = data.bit(4);
io.verticalBlankInterruptEnable = data.bit(5);
io.displayEnable = data.bit(6);
io.externalVRAM = data.bit(7);
if(!dma.io.enable) io.command.bit(5) = 0;
return;
}
//plane A name table location
case 0x02: {
planeA.io.nametableAddress = data.bits(3,6) << 12;
return;
}
//window name table location
case 0x03: {
window.io.nametableAddress = data.bits(1,6) << 10;
return;
}
//plane B name table location
case 0x04: {
planeB.io.nametableAddress = data.bits(0,3) << 12;
return;
}
//sprite attribute table location
case 0x05: {
sprite.io.attributeAddress = data.bits(0,7) << 8;
return;
}
//sprite pattern base address
case 0x06: {
sprite.io.nametableAddressBase = data.bit(5);
return;
}
//background color
case 0x07: {
io.backgroundColor = data.bits(0,5);
return;
}
//horizontal interrupt counter
case 0x0a: {
io.horizontalInterruptCounter = data.bits(0,7);
return;
}
//mode register 3
case 0x0b: {
planeA.io.horizontalScrollMode = data.bits(0,1);
planeB.io.horizontalScrollMode = data.bits(0,1);
planeA.io.verticalScrollMode = data.bit(2);
planeB.io.verticalScrollMode = data.bit(2);
io.externalInterruptEnable = data.bit(3);
return;
}
//mode register 4
case 0x0c: {
io.displayWidth = data.bit(0) | data.bit(7) << 1;
io.interlaceMode = data.bits(1,2);
io.shadowHighlightEnable = data.bit(3);
io.externalColorEnable = data.bit(4);
io.horizontalSync = data.bit(5);
io.verticalSync = data.bit(6);
return;
}
//horizontal scroll data location
case 0x0d: {
planeA.io.horizontalScrollAddress = data.bits(0,6) << 9;
planeB.io.horizontalScrollAddress = data.bits(0,6) << 9;
return;
}
//nametable pattern base address
case 0x0e: {
io.nametableBasePatternA = data.bit(0);
io.nametableBasePatternB = data.bit(1);
return;
}
//data port auto-increment value
case 0x0f: {
io.dataIncrement = data.bits(0,7);
return;
}
//plane size
case 0x10: {
planeA.io.nametableWidth = data.bits(0,1);
planeB.io.nametableWidth = data.bits(0,1);
planeA.io.nametableHeight = data.bits(4,5);
planeB.io.nametableHeight = data.bits(4,5);
return;
}
//window plane horizontal position
case 0x11: {
window.io.horizontalDirection = data.bit(7);
window.io.horizontalOffset = data.bits(0,4) << 4;
return;
}
//window plane vertical position
case 0x12: {
window.io.verticalDirection = data.bit(7);
window.io.verticalOffset = data.bits(0,4) << 3;
return;
}
//DMA length
case 0x13: {
dma.io.length.bits(0,7) = data.bits(0,7);
return;
}
//DMA length
case 0x14: {
dma.io.length.bits(8,15) = data.bits(0,7);
return;
}
//DMA source
case 0x15: {
dma.io.source.bits(0,7) = data.bits(0,7);
return;
}
//DMA source
case 0x16: {
dma.io.source.bits(8,15) = data.bits(0,7);
return;
}
//DMA source
case 0x17: {
dma.io.source.bits(16,21) = data.bits(0,5);
dma.io.mode = data.bits(6,7);
dma.io.wait = dma.io.mode.bit(1);
return;
}
//unused
default: {
return;
}
}
}