auto APU::Square2::dacEnable() const -> bool { return (envelopeVolume || envelopeDirection); } auto APU::Square2::run() -> void { if(period && --period == 0) { period = 2 * (2048 - frequency); phase++; switch(duty) { case 0: dutyOutput = (phase == 6); break; //______-_ case 1: dutyOutput = (phase >= 6); break; //______-- case 2: dutyOutput = (phase >= 4); break; //____---- case 3: dutyOutput = (phase <= 5); break; //------__ } } uint4 sample = dutyOutput ? (uint)volume : 0; if(!enable) sample = 0; output = sample; } auto APU::Square2::clockLength() -> void { if(counter) { if(length && --length == 0) enable = false; } } auto APU::Square2::clockEnvelope() -> void { if(enable && envelopeFrequency && --envelopePeriod == 0) { envelopePeriod = envelopeFrequency ? (uint)envelopeFrequency : 8; if(envelopeDirection == 0 && volume > 0) volume--; if(envelopeDirection == 1 && volume < 15) volume++; } } auto APU::Square2::read(uint16 addr) -> uint8 { if(addr == 0xff15) { //NR20 return 0xff; } if(addr == 0xff16) { //NR21 return duty << 6 | 0x3f; } if(addr == 0xff17) { //NR22 return envelopeVolume << 4 | envelopeDirection << 3 | envelopeFrequency; } if(addr == 0xff18) { //NR23 return 0xff; } if(addr == 0xff19) { //NR24 return 0x80 | counter << 6 | 0x3f; } return 0xff; } auto APU::Square2::write(uint16 addr, uint8 data) -> void { if(addr == 0xff16) { //NR21 duty = data.bits(7,6); length = 64 - data.bits(5,0); } if(addr == 0xff17) { //NR22 envelopeVolume = data.bits(7,4); envelopeDirection = data.bit (3); envelopeFrequency = data.bits(2,0); if(!dacEnable()) enable = false; } if(addr == 0xff18) { //NR23 frequency.bits(7,0) = data; } if(addr == 0xff19) { //NR24 if(apu.phase.bit(0) && !counter && data.bit(6)) { if(length && --length == 0) enable = false; } counter = data.bit(6); frequency.bits(10,8) = data.bits(2,0); if(data.bit(7)) { enable = dacEnable(); period = 2 * (2048 - frequency); envelopePeriod = envelopeFrequency ? (uint)envelopeFrequency : 8; volume = envelopeVolume; if(!length) { length = 64; if(apu.phase.bit(0) && counter) length--; } } } } auto APU::Square2::power(bool initializeLength) -> void { enable = 0; duty = 0; envelopeVolume = 0; envelopeDirection = 0; envelopeFrequency = 0; frequency = 0; counter = 0; output = 0; dutyOutput = 0; phase = 0; period = 0; envelopePeriod = 0; volume = 0; if(initializeLength) length = 64; } auto APU::Square2::serialize(serializer& s) -> void { s.integer(enable); s.integer(duty); s.integer(length); s.integer(envelopeVolume); s.integer(envelopeDirection); s.integer(envelopeFrequency); s.integer(frequency); s.integer(counter); s.integer(output); s.integer(dutyOutput); s.integer(phase); s.integer(period); s.integer(envelopePeriod); s.integer(volume); }