import { midiToFreq, noteToMidi } from './util.mjs'; import { registerSound, getAudioContext } from './superdough.mjs'; import { gainNode, getEnvelope, getExpEnvelope } from './helpers.mjs'; const mod = (freq, range = 1, type = 'sine') => { const ctx = getAudioContext(); const osc = ctx.createOscillator(); osc.type = type; osc.frequency.value = freq; osc.start(); const g = new GainNode(ctx, { gain: range }); osc.connect(g); // -range, range return { node: g, stop: (t) => osc.stop(t) }; }; const fm = (osc, harmonicityRatio, modulationIndex, wave = 'sine') => { const carrfreq = osc.frequency.value; const modfreq = carrfreq * harmonicityRatio; const modgain = modfreq * modulationIndex; return mod(modfreq, modgain, wave); }; export function registerSynthSounds() { ['sine', 'square', 'triangle', 'sawtooth'].forEach((wave) => { registerSound( wave, (t, value, onended) => { // destructure adsr here, because the default should be different for synths and samples let { attack = 0.001, decay = 0.05, sustain = 0.6, release = 0.01, fmh: fmHarmonicity = 1, fmi: fmModulationIndex, fmenv: fmEnvelopeType = 'lin', fmattack: fmAttack, fmdecay: fmDecay, fmsustain: fmSustain, fmrelease: fmRelease, fmvelocity: fmVelocity, fmwave: fmWaveform = 'sine', } = value; let { n, note, freq } = value; // with synths, n and note are the same thing note = note || 36; if (typeof note === 'string') { note = noteToMidi(note); // e.g. c3 => 48 } // get frequency if (!freq && typeof note === 'number') { freq = midiToFreq(note); // + 48); } // maybe pull out the above frequency resolution?? (there is also getFrequency but it has no default) // make oscillator const { node: o, stop } = getOscillator({ t, s: wave, freq, partials: n }); // FM + FM envelope let stopFm, fmEnvelope; if (fmModulationIndex) { const { node: modulator, stop } = fm(o, fmHarmonicity, fmModulationIndex, fmWaveform); if (![fmAttack, fmDecay, fmSustain, fmRelease, fmVelocity].find((v) => v !== undefined)) { // no envelope by default modulator.connect(o.frequency); } else { fmAttack = fmAttack ?? 0.001; fmDecay = fmDecay ?? 0.001; fmSustain = fmSustain ?? 1; fmRelease = fmRelease ?? 0.001; fmVelocity = fmVelocity ?? 1; fmEnvelope = getEnvelope(fmAttack, fmDecay, fmSustain, fmRelease, fmVelocity, t); if (fmEnvelopeType === 'exp') { fmEnvelope = getExpEnvelope(fmAttack, fmDecay, fmSustain, fmRelease, fmVelocity, t); fmEnvelope.node.maxValue = fmModulationIndex * 2; fmEnvelope.node.minValue = 0.00001; } modulator.connect(fmEnvelope.node); fmEnvelope.node.connect(o.frequency); } stopFm = stop; } // turn down const g = gainNode(0.3); // gain envelope const { node: envelope, stop: releaseEnvelope } = getEnvelope(attack, decay, sustain, release, 1, t); o.onended = () => { o.disconnect(); g.disconnect(); onended(); }; return { node: o.connect(g).connect(envelope), stop: (releaseTime) => { releaseEnvelope(releaseTime); fmEnvelope?.stop(releaseTime); let end = releaseTime + release; stop(end); stopFm?.(end); }, }; }, { type: 'synth', prebake: true }, ); }); } export function waveformN(partials, type) { const real = new Float32Array(partials + 1); const imag = new Float32Array(partials + 1); const ac = getAudioContext(); const osc = ac.createOscillator(); const amplitudes = { sawtooth: (n) => 1 / n, square: (n) => (n % 2 === 0 ? 0 : 1 / n), triangle: (n) => (n % 2 === 0 ? 0 : 1 / (n * n)), }; if (!amplitudes[type]) { throw new Error(`unknown wave type ${type}`); } real[0] = 0; // dc offset imag[0] = 0; let n = 1; while (n <= partials) { real[n] = amplitudes[type](n); imag[n] = 0; n++; } const wave = ac.createPeriodicWave(real, imag); osc.setPeriodicWave(wave); return osc; } export function getOscillator({ s, freq, t, partials }) { // make oscillator let o; if (!partials || s === 'sine') { o = getAudioContext().createOscillator(); o.type = s || 'triangle'; } else { o = waveformN(partials, s); } o.frequency.value = Number(freq); o.start(t); //o.stop(t + duration + release); const stop = (time) => o.stop(time); return { node: o, stop }; }