LayoutTests/webaudio/resources/waveshaper-testing.js - WebKit - Git at Google

 let context;
 let lengthInSeconds = 2;

 // Skip this many frames before comparing against reference to allow
 // a steady-state to be reached in the up-sampling filters.
 let filterStabilizeSkipFrames = 2048;

 let numberOfCurveFrames = 65536;
 let waveShapingCurve;

 let waveshaper;

 // FIXME: test at more frequencies.
 // When using the up-sampling filters (2x, 4x) any significant aliasing
 // components should be at very high frequencies near Nyquist.  These tests
 // could be improved to allow for a higher acceptable amount of aliasing near
 // Nyquist, but then become more stringent for lower frequencies.

 // These test parameters are set in runWaveShaperOversamplingTest().
 let sampleRate;
 let nyquist;
 let oversample;
 let fundamentalFrequency;
 let acceptableAliasingThresholdDecibels;

 let kScale = 0.25;

 // Chebyshev Polynomials.
 // Given an input sinusoid, returns an output sinusoid of the given frequency
 // multiple.
 function T0(x) {
   return 1;
 }
 function T1(x) {
   return x;
 }
 function T2(x) {
   return 2 * x * x - 1;
 }
 function T3(x) {
   return 4 * x * x * x - 3 * x;
 }
 function T4(x) {
   return 8 * x * x * x * x - 8 * x * x + 1;
 }

 function generateWaveShapingCurve() {
   let n = 65536;
   let n2 = n / 2;
   let curve = new Float32Array(n);

   // The shaping curve uses Chebyshev Polynomial such that an input sinusoid
   // at frequency f will generate an output of four sinusoids of frequencies:
   // f, 2*f, 3*f, 4*f
   // each of which is scaled.
   for (let i = 0; i < n; ++i) {
     let x = (i - n2) / n2;
     let y = kScale * (T1(x) + T2(x) + T3(x) + T4(x));
     curve[i] = y;
   }

   return curve;
 }

 function checkShapedCurve(buffer, should) {
   let outputData = buffer.getChannelData(0);
   let n = buffer.length;

   // The WaveShaperNode will have a processing latency if oversampling is used,
   // so we should account for it.

   // FIXME: .latency should be exposed as an attribute of the node
   // var waveShaperLatencyFrames = waveshaper.latency * sampleRate;
   // But for now we'll use the hard-coded values corresponding to the actual
   // latencies:
   let waveShaperLatencyFrames = 0;
   if (oversample == '2x')
     waveShaperLatencyFrames = 128;
   else if (oversample == '4x')
     waveShaperLatencyFrames = 192;

   let worstDeltaInDecibels = -1000;

   for (let i = waveShaperLatencyFrames; i < n; ++i) {
     let actual = outputData[i];

     // Account for the expected processing latency.
     let j = i - waveShaperLatencyFrames;

     // Compute reference sinusoids.
     let phaseInc = 2 * Math.PI * fundamentalFrequency / sampleRate;

     // Generate an idealized reference based on the four generated frequencies
     // truncated to the Nyquist rate.  Ideally, we'd like the waveshaper's
     // oversampling to perfectly remove all frequencies above Nyquist to avoid
     // aliasing.  In reality the oversampling filters are not quite perfect, so
     // there will be a (hopefully small) amount of aliasing.  We should be close
     // to the ideal.
     let reference = 0;

     // Sum in fundamental frequency.
     if (fundamentalFrequency < nyquist)
       reference += Math.sin(phaseInc * j);

     // Note that the phase of each of the expected generated harmonics is
     // different.
     if (fundamentalFrequency * 2 < nyquist)
       reference += -Math.cos(phaseInc * j * 2);
     if (fundamentalFrequency * 3 < nyquist)
       reference += -Math.sin(phaseInc * j * 3);
     if (fundamentalFrequency * 4 < nyquist)
       reference += Math.cos(phaseInc * j * 4);

     // Scale the reference the same as the waveshaping curve itself.
     reference *= kScale;

     let delta = Math.abs(actual - reference);
     let deltaInDecibels =
         delta > 0 ? 20 * Math.log(delta) / Math.log(10) : -200;

     if (j >= filterStabilizeSkipFrames) {
       if (deltaInDecibels > worstDeltaInDecibels) {
         worstDeltaInDecibels = deltaInDecibels;
       }
     }
   }

   // console.log("worstDeltaInDecibels: " + worstDeltaInDecibels);

   should(
       worstDeltaInDecibels,
       oversample + ' WaveshaperNode oversampling error (in dBFS)')
       .beLessThan(acceptableAliasingThresholdDecibels);
 }

 function createImpulseBuffer(context, sampleFrameLength) {
   let audioBuffer =
       context.createBuffer(1, sampleFrameLength, context.sampleRate);
   let n = audioBuffer.length;
   let dataL = audioBuffer.getChannelData(0);

   for (let k = 0; k < n; ++k)
     dataL[k] = 0;

   dataL[0] = 1;

   return audioBuffer;
 }

 function runWaveShaperOversamplingTest(testParams) {
   sampleRate = testParams.sampleRate;
   nyquist = 0.5 * sampleRate;
   oversample = testParams.oversample;
   fundamentalFrequency = testParams.fundamentalFrequency;
   acceptableAliasingThresholdDecibels =
       testParams.acceptableAliasingThresholdDecibels;

   let audit = Audit.createTaskRunner();

   audit.define(
       {label: 'test', description: testParams.description},
       function(task, should) {

         // Create offline audio context.
         let numberOfRenderFrames = sampleRate * lengthInSeconds;
         context = new OfflineAudioContext(1, numberOfRenderFrames, sampleRate);

         // source -> waveshaper -> destination
         let source = context.createBufferSource();
         source.buffer =
             createToneBuffer(context, fundamentalFrequency, lengthInSeconds, 1);

         // Apply a non-linear distortion curve.
         waveshaper = context.createWaveShaper();
         waveshaper.curve = generateWaveShapingCurve();
         waveshaper.oversample = oversample;

         source.connect(waveshaper);
         waveshaper.connect(context.destination);

         source.start(0);

         context.startRendering()
             .then(buffer => checkShapedCurve(buffer, should))
             .then(() => task.done());
       });

   audit.run();
 }
	let context;
	let lengthInSeconds = 2;

	// Skip this many frames before comparing against reference to allow
	// a steady-state to be reached in the up-sampling filters.
	let filterStabilizeSkipFrames = 2048;

	let numberOfCurveFrames = 65536;
	let waveShapingCurve;

	let waveshaper;

	// FIXME: test at more frequencies.
	// When using the up-sampling filters (2x, 4x) any significant aliasing
	// components should be at very high frequencies near Nyquist. These tests
	// could be improved to allow for a higher acceptable amount of aliasing near
	// Nyquist, but then become more stringent for lower frequencies.

	// These test parameters are set in runWaveShaperOversamplingTest().
	let sampleRate;
	let nyquist;
	let oversample;
	let fundamentalFrequency;
	let acceptableAliasingThresholdDecibels;

	let kScale = 0.25;

	// Chebyshev Polynomials.
	// Given an input sinusoid, returns an output sinusoid of the given frequency
	// multiple.
	function T0(x) {
	return 1;
	}
	function T1(x) {
	return x;
	}
	function T2(x) {
	return 2 * x * x - 1;
	}
	function T3(x) {
	return 4 * x * x * x - 3 * x;
	}
	function T4(x) {
	return 8 * x * x * x * x - 8 * x * x + 1;
	}

	function generateWaveShapingCurve() {
	let n = 65536;
	let n2 = n / 2;
	let curve = new Float32Array(n);

	// The shaping curve uses Chebyshev Polynomial such that an input sinusoid
	// at frequency f will generate an output of four sinusoids of frequencies:
	// f, 2f, 3f, 4*f
	// each of which is scaled.
	for (let i = 0; i < n; ++i) {
	let x = (i - n2) / n2;
	let y = kScale * (T1(x) + T2(x) + T3(x) + T4(x));
	curve[i] = y;
	}

	return curve;
	}

	function checkShapedCurve(buffer, should) {
	let outputData = buffer.getChannelData(0);
	let n = buffer.length;

	// The WaveShaperNode will have a processing latency if oversampling is used,
	// so we should account for it.

	// FIXME: .latency should be exposed as an attribute of the node
	// var waveShaperLatencyFrames = waveshaper.latency * sampleRate;
	// But for now we'll use the hard-coded values corresponding to the actual
	// latencies:
	let waveShaperLatencyFrames = 0;
	if (oversample == '2x')
	waveShaperLatencyFrames = 128;
	else if (oversample == '4x')
	waveShaperLatencyFrames = 192;

	let worstDeltaInDecibels = -1000;

	for (let i = waveShaperLatencyFrames; i < n; ++i) {
	let actual = outputData[i];

	// Account for the expected processing latency.
	let j = i - waveShaperLatencyFrames;

	// Compute reference sinusoids.
	let phaseInc = 2 * Math.PI * fundamentalFrequency / sampleRate;

	// Generate an idealized reference based on the four generated frequencies
	// truncated to the Nyquist rate. Ideally, we'd like the waveshaper's
	// oversampling to perfectly remove all frequencies above Nyquist to avoid
	// aliasing. In reality the oversampling filters are not quite perfect, so
	// there will be a (hopefully small) amount of aliasing. We should be close
	// to the ideal.
	let reference = 0;

	// Sum in fundamental frequency.
	if (fundamentalFrequency < nyquist)
	reference += Math.sin(phaseInc * j);

	// Note that the phase of each of the expected generated harmonics is
	// different.
	if (fundamentalFrequency * 2 < nyquist)
	reference += -Math.cos(phaseInc * j * 2);
	if (fundamentalFrequency * 3 < nyquist)
	reference += -Math.sin(phaseInc * j * 3);
	if (fundamentalFrequency * 4 < nyquist)
	reference += Math.cos(phaseInc * j * 4);

	// Scale the reference the same as the waveshaping curve itself.
	reference *= kScale;

	let delta = Math.abs(actual - reference);
	let deltaInDecibels =
	delta > 0 ? 20 * Math.log(delta) / Math.log(10) : -200;

	if (j >= filterStabilizeSkipFrames) {
	if (deltaInDecibels > worstDeltaInDecibels) {
	worstDeltaInDecibels = deltaInDecibels;
	}
	}
	}

	// console.log("worstDeltaInDecibels: " + worstDeltaInDecibels);

	should(
	worstDeltaInDecibels,
	oversample + ' WaveshaperNode oversampling error (in dBFS)')
	.beLessThan(acceptableAliasingThresholdDecibels);
	}

	function createImpulseBuffer(context, sampleFrameLength) {
	let audioBuffer =
	context.createBuffer(1, sampleFrameLength, context.sampleRate);
	let n = audioBuffer.length;
	let dataL = audioBuffer.getChannelData(0);

	for (let k = 0; k < n; ++k)
	dataL[k] = 0;

	dataL[0] = 1;

	return audioBuffer;
	}

	function runWaveShaperOversamplingTest(testParams) {
	sampleRate = testParams.sampleRate;
	nyquist = 0.5 * sampleRate;
	oversample = testParams.oversample;
	fundamentalFrequency = testParams.fundamentalFrequency;
	acceptableAliasingThresholdDecibels =
	testParams.acceptableAliasingThresholdDecibels;

	let audit = Audit.createTaskRunner();

	audit.define(
	{label: 'test', description: testParams.description},
	function(task, should) {

	// Create offline audio context.
	let numberOfRenderFrames = sampleRate * lengthInSeconds;
	context = new OfflineAudioContext(1, numberOfRenderFrames, sampleRate);

	// source -> waveshaper -> destination
	let source = context.createBufferSource();
	source.buffer =
	createToneBuffer(context, fundamentalFrequency, lengthInSeconds, 1);

	// Apply a non-linear distortion curve.
	waveshaper = context.createWaveShaper();
	waveshaper.curve = generateWaveShapingCurve();
	waveshaper.oversample = oversample;

	source.connect(waveshaper);
	waveshaper.connect(context.destination);

	source.start(0);

	context.startRendering()
	.then(buffer => checkShapedCurve(buffer, should))
	.then(() => task.done());
	});

	audit.run();
	}