bsnes/higan/sfc/cpu/timing.cpp

161 lines
4.2 KiB
C++

auto CPU::dmaCounter() const -> uint {
return (status.dmaCounter + hcounter()) & 7;
}
auto CPU::step(uint clocks) -> void {
status.irqLock = false;
uint ticks = clocks >> 1;
while(ticks--) {
tick();
if(hcounter() & 2) pollInterrupts();
}
smp.clock -= clocks * (uint64)smp.frequency;
ppu.clock -= clocks;
for(auto coprocessor : coprocessors) {
coprocessor->clock -= clocks * (uint64)coprocessor->frequency;
}
for(auto peripheral : peripherals) {
peripheral->clock -= clocks * (uint64)peripheral->frequency;
}
synchronizePeripherals();
status.autoJoypadClock += clocks;
if(status.autoJoypadClock >= 256) {
status.autoJoypadClock -= 256;
stepAutoJoypadPoll();
}
if(!status.dramRefreshed && hcounter() >= status.dramRefreshPosition) {
status.dramRefreshed = true;
step(40);
}
#if defined(DEBUGGER)
synchronizeSMP();
synchronizePPU();
synchronizeCoprocessors();
#endif
}
//called by ppu.tick() when Hcounter=0
auto CPU::scanline() -> void {
status.dmaCounter = (status.dmaCounter + status.lineClocks) & 7;
status.lineClocks = lineclocks();
//forcefully sync S-CPU to other processors, in case chips are not communicating
synchronizeSMP();
synchronizePPU();
synchronizeCoprocessors();
if(vcounter() == 0) {
//HDMA init triggers once every frame
status.hdmaInitPosition = (version == 1 ? 12 + 8 - dmaCounter() : 12 + dmaCounter());
status.hdmaInitTriggered = false;
status.autoJoypadCounter = 0;
}
//DRAM refresh occurs once every scanline
if(version == 2) status.dramRefreshPosition = 530 + 8 - dmaCounter();
status.dramRefreshed = false;
//HDMA triggers once every visible scanline
if(vcounter() < ppu.vdisp()) {
status.hdmaPosition = 1104;
status.hdmaTriggered = false;
}
}
auto CPU::aluEdge() -> void {
if(alu.mpyctr) {
alu.mpyctr--;
if(io.rddiv & 1) io.rdmpy += alu.shift;
io.rddiv >>= 1;
alu.shift <<= 1;
}
if(alu.divctr) {
alu.divctr--;
io.rddiv <<= 1;
alu.shift >>= 1;
if(io.rdmpy >= alu.shift) {
io.rdmpy -= alu.shift;
io.rddiv |= 1;
}
}
}
auto CPU::dmaEdge() -> void {
//H/DMA pending && DMA inactive?
//.. Run one full CPU cycle
//.. HDMA pending && HDMA enabled ? DMA sync + HDMA run
//.. DMA pending && DMA enabled ? DMA sync + DMA run
//.... HDMA during DMA && HDMA enabled ? DMA sync + HDMA run
//.. Run one bus CPU cycle
//.. CPU sync
if(status.dmaActive) {
if(status.hdmaPending) {
status.hdmaPending = false;
if(hdmaEnabledChannels()) {
if(!dmaEnabledChannels()) {
dmaStep(8 - dmaCounter());
}
status.hdmaMode == 0 ? hdmaInit() : hdmaRun();
if(!dmaEnabledChannels()) {
step(status.clockCount - (status.dmaClocks % status.clockCount));
status.dmaActive = false;
}
}
}
if(status.dmaPending) {
status.dmaPending = false;
if(dmaEnabledChannels()) {
dmaStep(8 - dmaCounter());
dmaRun();
step(status.clockCount - (status.dmaClocks % status.clockCount));
status.dmaActive = false;
}
}
}
if(!status.hdmaInitTriggered && hcounter() >= status.hdmaInitPosition) {
status.hdmaInitTriggered = true;
hdmaInitReset();
if(hdmaEnabledChannels()) {
status.hdmaPending = true;
status.hdmaMode = 0;
}
}
if(!status.hdmaTriggered && hcounter() >= status.hdmaPosition) {
status.hdmaTriggered = true;
if(hdmaActiveChannels()) {
status.hdmaPending = true;
status.hdmaMode = 1;
}
}
if(!status.dmaActive) {
if(status.dmaPending || status.hdmaPending) {
status.dmaClocks = 0;
status.dmaActive = true;
}
}
}
//used to test for NMI/IRQ, which can trigger on the edge of every opcode.
//test one cycle early to simulate two-stage pipeline of x816 CPU.
//
//status.irq_lock is used to simulate hardware delay before interrupts can
//trigger during certain events (immediately after DMA, writes to $4200, etc)
auto CPU::lastCycle() -> void {
if(!status.irqLock) {
status.nmiPending |= nmiTest();
status.irqPending |= irqTest();
status.interruptPending = (status.nmiPending || status.irqPending);
}
}