#include "synth.hpp" namespace synth { uint32_t prng_xorshift_state = 0x32B71700; uint32_t prng_xorshift_next() { uint32_t x = prng_xorshift_state; x ^= x << 13; x ^= x >> 17; x ^= x << 5; prng_xorshift_state = x; return x; } int32_t prng_normal() { // rough approximation of a normal distribution uint32_t r0 = prng_xorshift_next(); uint32_t r1 = prng_xorshift_next(); uint32_t n = ((r0 & 0xffff) + (r1 & 0xffff) + (r0 >> 16) + (r1 >> 16)) / 2; return n - 0xffff; } uint16_t volume = 0xffff; const int16_t sine_waveform[256] = {-32768,-32758,-32729,-32679,-32610,-32522,-32413,-32286,-32138,-31972,-31786,-31581,-31357,-31114,-30853,-30572,-30274,-29957,-29622,-29269,-28899,-28511,-28106,-27684,-27246,-26791,-26320,-25833,-25330,-24812,-24279,-23732,-23170,-22595,-22006,-21403,-20788,-20160,-19520,-18868,-18205,-17531,-16846,-16151,-15447,-14733,-14010,-13279,-12540,-11793,-11039,-10279,-9512,-8740,-7962,-7180,-6393,-5602,-4808,-4011,-3212,-2411,-1608,-804,0,804,1608,2411,3212,4011,4808,5602,6393,7180,7962,8740,9512,10279,11039,11793,12540,13279,14010,14733,15447,16151,16846,17531,18205,18868,19520,20160,20788,21403,22006,22595,23170,23732,24279,24812,25330,25833,26320,26791,27246,27684,28106,28511,28899,29269,29622,29957,30274,30572,30853,31114,31357,31581,31786,31972,32138,32286,32413,32522,32610,32679,32729,32758,32767,32758,32729,32679,32610,32522,32413,32286,32138,31972,31786,31581,31357,31114,30853,30572,30274,29957,29622,29269,28899,28511,28106,27684,27246,26791,26320,25833,25330,24812,24279,23732,23170,22595,22006,21403,20788,20160,19520,18868,18205,17531,16846,16151,15447,14733,14010,13279,12540,11793,11039,10279,9512,8740,7962,7180,6393,5602,4808,4011,3212,2411,1608,804,0,-804,-1608,-2411,-3212,-4011,-4808,-5602,-6393,-7180,-7962,-8740,-9512,-10279,-11039,-11793,-12540,-13279,-14010,-14733,-15447,-16151,-16846,-17531,-18205,-18868,-19520,-20160,-20788,-21403,-22006,-22595,-23170,-23732,-24279,-24812,-25330,-25833,-26320,-26791,-27246,-27684,-28106,-28511,-28899,-29269,-29622,-29957,-30274,-30572,-30853,-31114,-31357,-31581,-31786,-31972,-32138,-32286,-32413,-32522,-32610,-32679,-32729,-32758}; bool is_audio_playing() { if(volume == 0) { return false; } bool any_channel_playing = false; for(int c = 0; c < CHANNEL_COUNT; c++) { if(channels[c].volume > 0 && channels[c].adsr_phase != ADSRPhase::OFF) { any_channel_playing = true; } } return any_channel_playing; } int16_t get_audio_frame() { int32_t sample = 0; // used to combine channel output for(int c = 0; c < CHANNEL_COUNT; c++) { auto &channel = channels[c]; // increment the waveform position counter. this provides an // Q16 fixed point value representing how far through // the current waveform we are channel.waveform_offset += ((channel.frequency * 256) << 8) / sample_rate; if(channel.adsr_phase == ADSRPhase::OFF) { continue; } if ((channel.adsr_frame >= channel.adsr_end_frame) && (channel.adsr_phase != ADSRPhase::SUSTAIN)) { switch (channel.adsr_phase) { case ADSRPhase::ATTACK: channel.trigger_decay(); break; case ADSRPhase::DECAY: channel.trigger_sustain(); break; case ADSRPhase::RELEASE: channel.off(); break; default: break; } } channel.adsr += channel.adsr_step; channel.adsr_frame++; if(channel.waveform_offset & 0x10000) { // if the waveform offset overflows then generate a new // random noise sample channel.noise = prng_normal(); } channel.waveform_offset &= 0xffff; // check if any waveforms are active for this channel if(channel.waveforms) { uint8_t waveform_count = 0; int32_t channel_sample = 0; if(channel.waveforms & Waveform::NOISE) { channel_sample += channel.noise; waveform_count++; } if(channel.waveforms & Waveform::SAW) { channel_sample += (int32_t)channel.waveform_offset - 0x7fff; waveform_count++; } // creates a triangle wave of ^ if (channel.waveforms & Waveform::TRIANGLE) { if (channel.waveform_offset < 0x7fff) { // initial quarter up slope channel_sample += int32_t(channel.waveform_offset * 2) - int32_t(0x7fff); } else { // final quarter up slope channel_sample += int32_t(0x7fff) - ((int32_t(channel.waveform_offset) - int32_t(0x7fff)) * 2); } waveform_count++; } if (channel.waveforms & Waveform::SQUARE) { channel_sample += (channel.waveform_offset < channel.pulse_width) ? 0x7fff : -0x7fff; waveform_count++; } if(channel.waveforms & Waveform::SINE) { // the sine_waveform sample contains 256 samples in // total so we'll just use the most significant bits // of the current waveform position to index into it channel_sample += sine_waveform[channel.waveform_offset >> 8]; waveform_count++; } if(channel.waveforms & Waveform::WAVE) { channel_sample += channel.wave_buffer[channel.wave_buf_pos]; if (++channel.wave_buf_pos == 64) { channel.wave_buf_pos = 0; if(channel.wave_buffer_callback) channel.wave_buffer_callback(channel); } waveform_count++; } channel_sample = channel_sample / waveform_count; channel_sample = (int64_t(channel_sample) * int32_t(channel.adsr >> 8)) >> 16; // apply channel volume channel_sample = (int64_t(channel_sample) * int32_t(channel.volume)) >> 16; // apply channel filter //if (channel.filter_enable) { //float filter_epow = 1 - expf(-(1.0f / 22050.0f) * 2.0f * pi * int32_t(channel.filter_cutoff_frequency)); //channel_sample += (channel_sample - channel.filter_last_sample) * filter_epow; //} //channel.filter_last_sample = channel_sample; // combine channel sample into the final sample sample += channel_sample; } } sample = (int64_t(sample) * int32_t(volume)) >> 16; // clip result to 16-bit sample = sample <= -0x8000 ? -0x8000 : (sample > 0x7fff ? 0x7fff : sample); return sample; } }