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#if 1
__attribute__((hot))
static inline uint8_t memory_read(struct nes_state *state, uint32_t offset) {
state->cpu.cycles++;
ppu_tick(state);
apu_tick(state);
uint8_t result = 0;
if(offset >= 0x8000) { // MOST
result = state->mapper_function.prg_rom_read(state, offset);
} else if(offset < 0x2000) { // SECOND
result = state->ram[offset & 0x07ff];
} else if(offset < 0x4000) { // THIRD
result = ppu_read(state, offset);
} else if(offset == 0x4015) { // APU status
result = apu_read4015(state);
} else if(offset == 0x4016 || offset == 0x4017) {
uint32_t index = offset & 1;
uint8_t value = (state->ppu.input_latch[index] >> state->ppu.input_bit[index]) & 1;
state->ppu.input_bit[index]++;
result = value | 0x40; // Bit 6 open bus high, bit 7 low
} else if(offset >= 0x6000) {
result = state->mapper_function.prg_ram_read(state, offset);
}
return result;
}
#else
__attribute__((hot))
static inline uint8_t memory_read(struct nes_state *state, uint32_t offset) {
state->cpu.cycles++;
ppu_tick(state);
apu_tick(state);
uint8_t result = 0;
if(offset >= 0x8000) { // MOST
result = state->mapper_function.prg_rom_read(state, offset);
} else if(offset < 0x2000) { // SECOND
result = state->ram[offset & 0x07ff];
} else if(offset < 0x4000) { // THIRD
result = ppu_read(state, offset);
} else if(offset >= 0x6000) {
result = state->mapper_function.prg_ram_read(state, offset);
} else if(offset == 0x4016 || offset == 0x4017) {
uint32_t index = offset & 1;
uint8_t value = (state->ppu.input_latch[index] >> state->ppu.input_bit[index]) & 1;
state->ppu.input_bit[index]++;
result = value | 0x40; // Bit 6 open bus high, bit 7 low
}
return result;
}
#endif
__attribute__((hot))
static inline uint8_t memory_read_dummy(struct nes_state *state, uint32_t offset) {
state->cpu.cycles++;
ppu_tick(state);
apu_tick(state);
if(offset >= 0x2000 && offset < 0x4000) {
return ppu_read(state, offset);
}
return 0;
}
__attribute__((hot))
static inline void memory_write(struct nes_state *state, uint32_t offset, uint8_t value) {
state->cpu.cycles++;
ppu_tick(state);
apu_tick(state);
if(offset < 0x2000) {
state->ram[offset & 0x07ff] = value;
} else if(offset < 0x4000) {
ppu_write(state, offset, value);
} else if(offset < 0x4018) {
if(offset == 0x4014) {
ppu_dma_4014(state, value);
} else if(offset == 0x4016) {
// joypad strobe
uint8_t prev = state->ppu.input_strobe;
state->ppu.input_strobe = value & 1;
if(prev == 1 && (value & 1) == 0) {
state->ppu.input_latch[0] = state->ppu.input[0];
state->ppu.input_latch[1] = state->ppu.input[1];
state->ppu.input_bit[0] = 0;
state->ppu.input_bit[1] = 0;
}
} else if(offset >= 0x4010 && offset <= 0x4017) {
apu_write(state, offset, value);
}
} else if(offset >= 0x6000) { // NOTE(peter): Might need to move this upwards when we implement a mapper that has prg_ram_*
if(offset < 0x8000) {
state->mapper_function.prg_ram_write(state, offset, value);
} else {
state->mapper_function.prg_rom_write(state, offset, value);
}
}
}
__attribute__((hot, flatten))
static inline uint8_t memory_read_dma(struct nes_state *state, uint32_t offset) {
// NOTE(peter): DO NOT tick CPU/PPU/APU — caller handles timing
return state->ram[offset & 0x07ff];
}
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