bsnes/higan/gb/apu/square1/square1.cpp

165 lines
3.7 KiB
C++
Executable File

#ifdef APU_CPP
bool APU::Square1::dac_enable() {
return (envelope_volume || envelope_direction);
}
void APU::Square1::run() {
if(period && --period == 0) {
period = 4 * (2048 - frequency);
phase++;
switch(duty) {
case 0: duty_output = (phase == 6); break; //______-_
case 1: duty_output = (phase >= 6); break; //______--
case 2: duty_output = (phase >= 4); break; //____----
case 3: duty_output = (phase <= 5); break; //------__
}
}
uint4 sample = (duty_output ? volume : (uint4)0);
if(enable == false) sample = 0;
output = sample;
}
void APU::Square1::sweep(bool update) {
if(sweep_enable == false) return;
sweep_negate = sweep_direction;
unsigned delta = frequency_shadow >> sweep_shift;
signed freq = frequency_shadow + (sweep_negate ? -delta : delta);
if(freq > 2047) {
enable = false;
} else if(sweep_shift && update) {
frequency_shadow = freq;
frequency = freq & 2047;
period = 4 * (2048 - frequency);
}
}
void APU::Square1::clock_length() {
//if(counter && length) {
// if(--length == 0) enable = false;
//}
if(counter && enable) {
if(++length == 0) enable = false;
}
}
void APU::Square1::clock_sweep() {
if(enable && sweep_frequency && --sweep_period == 0) {
sweep_period = sweep_frequency;
sweep(1);
sweep(0);
}
}
void APU::Square1::clock_envelope() {
if(enable && envelope_frequency && --envelope_period == 0) {
envelope_period = envelope_frequency;
if(envelope_direction == 0 && volume > 0) volume--;
if(envelope_direction == 1 && volume < 15) volume++;
}
}
void APU::Square1::write(unsigned r, uint8 data) {
if(r == 0) { //$ff10 NR10
if(sweep_negate && sweep_direction && !(data & 0x08)) enable = false;
sweep_frequency = (data >> 4) & 7;
sweep_direction = data & 0x08;
sweep_shift = data & 0x07;
}
if(r == 1) { //$ff11 NR11
duty = data >> 6;
//length = 64 - (data & 0x3f);
length = data & 0x3f;
}
if(r == 2) { //$ff12 NR12
envelope_volume = data >> 4;
envelope_direction = data & 0x08;
envelope_frequency = data & 0x07;
if(dac_enable() == false) enable = false;
}
if(r == 3) { //$ff13 NR13
frequency = (frequency & 0x0700) | data;
}
if(r == 4) { //$ff14 NR14
bool initialize = data & 0x80;
counter = data & 0x40;
frequency = ((data & 7) << 8) | (frequency & 0x00ff);
if(initialize) {
enable = dac_enable();
period = 4 * (2048 - frequency);
envelope_period = envelope_frequency;
volume = envelope_volume;
frequency_shadow = frequency;
sweep_period = sweep_frequency;
sweep_enable = sweep_period || sweep_shift;
sweep_negate = false;
if(sweep_shift) sweep(0);
//if(length == 0) length = 64;
}
}
}
void APU::Square1::power() {
enable = 0;
sweep_frequency = 0;
sweep_direction = 0;
sweep_shift = 0;
sweep_negate = 0;
duty = 0;
length = 0;
envelope_volume = 0;
envelope_direction = 0;
envelope_frequency = 0;
frequency = 0;
counter = 0;
output = 0;
duty_output = 0;
phase = 0;
period = 0;
envelope_period = 0;
sweep_period = 0;
frequency_shadow = 0;
sweep_enable = 0;
volume = 0;
}
void APU::Square1::serialize(serializer &s) {
s.integer(enable);
s.integer(sweep_frequency);
s.integer(sweep_direction);
s.integer(sweep_shift);
s.integer(sweep_negate);
s.integer(duty);
s.integer(length);
s.integer(envelope_volume);
s.integer(envelope_direction);
s.integer(envelope_frequency);
s.integer(frequency);
s.integer(counter);
s.integer(output);
s.integer(duty_output);
s.integer(phase);
s.integer(period);
s.integer(envelope_period);
s.integer(sweep_period);
s.integer(frequency_shadow);
s.integer(sweep_enable);
s.integer(volume);
}
#endif