bsnes/sfc/cpu/cpu.cpp

158 lines
3.9 KiB
C++

#include <sfc/sfc.hpp>
#define CPU_CPP
namespace SuperFamicom {
CPU cpu;
#include "serialization.cpp"
#include "dma/dma.cpp"
#include "memory/memory.cpp"
#include "mmio/mmio.cpp"
#include "timing/timing.cpp"
void CPU::step(unsigned clocks) {
smp.clock -= clocks * (uint64)smp.frequency;
ppu.clock -= clocks;
for(unsigned i = 0; i < coprocessors.size(); i++) {
auto& chip = *coprocessors[i];
chip.clock -= clocks * (uint64)chip.frequency;
}
device.controllerPort1->clock -= clocks * (uint64)device.controllerPort1->frequency;
device.controllerPort2->clock -= clocks * (uint64)device.controllerPort2->frequency;
synchronize_controllers();
}
void CPU::synchronize_smp() {
if(SMP::Threaded == true) {
if(smp.clock < 0) co_switch(smp.thread);
} else {
while(smp.clock < 0) smp.enter();
}
}
void CPU::synchronize_ppu() {
if(PPU::Threaded == true) {
if(ppu.clock < 0) co_switch(ppu.thread);
} else {
while(ppu.clock < 0) ppu.enter();
}
}
void CPU::synchronize_coprocessors() {
for(unsigned i = 0; i < coprocessors.size(); i++) {
auto& chip = *coprocessors[i];
if(chip.clock < 0) co_switch(chip.thread);
}
}
void CPU::synchronize_controllers() {
if(device.controllerPort1->clock < 0) co_switch(device.controllerPort1->thread);
if(device.controllerPort2->clock < 0) co_switch(device.controllerPort2->thread);
}
void CPU::Enter() { cpu.enter(); }
void CPU::enter() {
while(true) {
if(scheduler.sync == Scheduler::SynchronizeMode::CPU) {
scheduler.sync = Scheduler::SynchronizeMode::All;
scheduler.exit(Scheduler::ExitReason::SynchronizeEvent);
}
if(status.interrupt_pending) {
status.interrupt_pending = false;
if(status.nmi_pending) {
status.nmi_pending = false;
regs.vector = (regs.e == false ? 0xffea : 0xfffa);
op_irq();
debugger.op_nmi();
} else if(status.irq_pending) {
status.irq_pending = false;
regs.vector = (regs.e == false ? 0xffee : 0xfffe);
op_irq();
debugger.op_irq();
} else if(status.reset_pending) {
status.reset_pending = false;
add_clocks(186);
regs.pc.l = bus.read(0xfffc);
regs.pc.h = bus.read(0xfffd);
}
}
op_step();
}
}
void CPU::op_step() {
debugger.op_exec(regs.pc.d);
op_exec();
}
void CPU::enable() {
function<uint8 (unsigned)> reader = {&CPU::mmio_read, (CPU*)&cpu};
function<void (unsigned, uint8)> writer = {&CPU::mmio_write, (CPU*)&cpu};
bus.map(reader, writer, 0x00, 0x3f, 0x2140, 0x2183);
bus.map(reader, writer, 0x80, 0xbf, 0x2140, 0x2183);
bus.map(reader, writer, 0x00, 0x3f, 0x4016, 0x4017);
bus.map(reader, writer, 0x80, 0xbf, 0x4016, 0x4017);
bus.map(reader, writer, 0x00, 0x3f, 0x4200, 0x421f);
bus.map(reader, writer, 0x80, 0xbf, 0x4200, 0x421f);
bus.map(reader, writer, 0x00, 0x3f, 0x4300, 0x437f);
bus.map(reader, writer, 0x80, 0xbf, 0x4300, 0x437f);
reader = [](unsigned addr) { return cpu.wram[addr]; };
writer = [](unsigned addr, uint8 data) { cpu.wram[addr] = data; };
bus.map(reader, writer, 0x00, 0x3f, 0x0000, 0x1fff, 0x002000);
bus.map(reader, writer, 0x80, 0xbf, 0x0000, 0x1fff, 0x002000);
bus.map(reader, writer, 0x7e, 0x7f, 0x0000, 0xffff, 0x020000);
}
void CPU::power() {
for(auto& byte : wram) byte = random(0x55);
regs.a = regs.x = regs.y = 0x0000;
regs.s = 0x01ff;
mmio_power();
dma_power();
timing_power();
}
void CPU::reset() {
create(Enter, system.cpuFrequency());
coprocessors.reset();
PPUcounter::reset();
//note: some registers are not fully reset by SNES
regs.pc = 0x000000;
regs.x.h = 0x00;
regs.y.h = 0x00;
regs.s.h = 0x01;
regs.d = 0x0000;
regs.db = 0x00;
regs.p = 0x34;
regs.e = 1;
regs.mdr = 0x00;
regs.wai = false;
regs.vector = 0xfffc; //reset vector address
mmio_reset();
dma_reset();
timing_reset();
}
CPU::CPU() {
PPUcounter::scanline = {&CPU::scanline, this};
}
CPU::~CPU() {
}
}