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<!DOCTYPE html>
<html>
<head>
<title>
Test Convolver Channel Outputs for Response with 2 channels
</title>
<script src="/resources/testharness.js"></script>
<script src="/resources/testharnessreport.js"></script>
<script src="/webaudio/resources/audit-util.js"></script>
<script src="/webaudio/resources/audit.js"></script>
</head>
<body>
<script id="layout-test-code">
// Test various convolver configurations when the convolver response has
// a stereo response.
// This is somewhat arbitrary. It is the minimum value for which tests
// pass with both FFmpeg and KISS FFT implementations for 256 points.
// The value was similar for each implementation.
const absoluteThreshold = Math.pow(2, -21);
// Fairly arbitrary sample rate, except that we want the rate to be a
// power of two so that 1/sampleRate is exactly representable as a
// single-precision float.
let sampleRate = 8192;
// A fairly arbitrary number of frames, except the number of frames should
// be more than a few render quanta.
let renderFrames = 10 * 128;
let audit = Audit.createTaskRunner();
// Convolver response
let response;
audit.define(
{
label: 'initialize',
description: 'Convolver response with one channel'
},
(task, should) => {
// Convolver response
should(
() => {
response = new AudioBuffer(
{numberOfChannels: 2, length: 4, sampleRate: sampleRate});
// Each channel of the response is a simple impulse (with
// different delay) so that we can use a DelayNode to simulate
// the convolver output. Channel k is delayed by k+1 frames.
for (let k = 0; k < response.numberOfChannels; ++k) {
response.getChannelData(k)[k + 1] = 1;
}
},
'new AudioBuffer({numberOfChannels: 2, length: 4, sampleRate: ' +
sampleRate + '})')
.notThrow();
task.done();
});
audit.define(
{label: '1-channel input', description: 'produces 2-channel output'},
(task, should) => {
stereoResponseTest({numberOfInputs: 1, prefix: '1'}, should)
.then(() => task.done());
});
audit.define(
{label: '2-channel input', description: 'produces 2-channel output'},
(task, should) => {
stereoResponseTest({numberOfInputes: 2, prefix: '2'}, should)
.then(() => task.done());
});
audit.define(
{
label: '3-channel input',
description: '3->2 downmix producing 2-channel output'
},
(task, should) => {
stereoResponseTest({numberOfInputs: 3, prefix: '3'}, should)
.then(() => task.done());
});
audit.define(
{
label: '4-channel input',
description: '4->2 downmix producing 2-channel output'
},
(task, should) => {
stereoResponseTest({numberOfInputs: 4, prefix: '4'}, should)
.then(() => task.done());
});
audit.define(
{
label: '5.1-channel input',
description: '5.1->2 downmix producing 2-channel output'
},
(task, should) => {
// Scale tolerance by maximum amplitude expected in down-mix
// output.
let threshold = (1.0 + Math.sqrt(0.5) * 2) * absoluteThreshold;
stereoResponseTest({numberOfInputs: 6, prefix: '5.1',
absoluteThreshold: threshold}, should)
.then(() => task.done());
});
audit.define(
{
label: '2-channel input, explicit mode',
description: 'produces 2-channel output'
},
(task, should) => {
stereoResponseExplicitTest(
{
numberOfInputes: 2,
prefix: '2-in explicit mode'
},
should)
.then(() => task.done());
});
audit.define(
{
label: '3-channel input explicit mode',
description: '3->1 downmix producing 2-channel output'
},
(task, should) => {
stereoResponseExplicitTest(
{
numberOfInputs: 3,
prefix: '3-in explicit'
},
should)
.then(() => task.done());
});
audit.define(
{
label: '4-channel input explicit mode',
description: '4->1 downmix producing 2-channel output'
},
(task, should) => {
stereoResponseExplicitTest(
{
numberOfInputs: 4,
prefix: '4-in explicit'
},
should)
.then(() => task.done());
});
audit.define(
{
label: '5.1-channel input explicit mode',
description: '5.1->1 downmix producing 2-channel output'
},
(task, should) => {
// Scale tolerance by maximum amplitude expected in down-mix
// output.
let threshold = (Math.sqrt(0.5) * 2 + 2.0) * absoluteThreshold;
stereoResponseExplicitTest(
{
numberOfInputs: 6,
prefix: '5.1-in explicit',
absoluteThreshold: threshold
},
should)
.then(() => task.done());
});
function stereoResponseTest(options, should) {
// Create an 4-channel offline context. The first two channels are for
// the stereo output of the convolver and the next two channels are for
// the reference stereo signal.
let context = new OfflineAudioContext(4, renderFrames, sampleRate);
context.destination.channelInterpretation = 'discrete';
// Create oscillators for use as the input. The type and frequency is
// arbitrary except that oscillators must be different.
let src = new Array(options.numberOfInputs);
for (let k = 0; k < src.length; ++k) {
src[k] = new OscillatorNode(
context, {type: 'square', frequency: 440 + 220 * k});
}
// Merger to combine the oscillators into one output stream.
let srcMerger =
new ChannelMergerNode(context, {numberOfInputs: src.length});
for (let k = 0; k < src.length; ++k) {
src[k].connect(srcMerger, 0, k);
}
// Convolver under test.
let conv = new ConvolverNode(
context, {disableNormalization: true, buffer: response});
srcMerger.connect(conv);
// Splitter to get individual channels of the convolver output so we can
// feed them (eventually) to the context in the right set of channels.
let splitter = new ChannelSplitterNode(context, {numberOfOutputs: 2});
conv.connect(splitter);
// Reference graph consists of a delays node to simulate the response of
// the convolver. (The convolver response is designed this way.)
let delay = new Array(2);
for (let k = 0; k < delay.length; ++k) {
delay[k] = new DelayNode(context, {
delayTime: (k + 1) / context.sampleRate,
channelCount: 1,
channelCountMode: 'explicit'
});
}
// Gain node to mix the sources to stereo in the desired way. (Could be
// done in the delay node, but let's keep the mixing separated from the
// functionality.)
let gainMixer = new GainNode(
context, {channelCount: 2, channelCountMode: 'explicit'});
srcMerger.connect(gainMixer);
// Splitter to extract the channels of the reference signal.
let refSplitter =
new ChannelSplitterNode(context, {numberOfOutputs: 2});
gainMixer.connect(refSplitter);
// Connect each channel to the delay nodes
for (let k = 0; k < delay.length; ++k) {
refSplitter.connect(delay[k], k);
}
// Final merger to bring back the individual channels from the convolver
// and the reference in the right order for the destination.
let finalMerger = new ChannelMergerNode(
context, {numberOfInputs: context.destination.channelCount});
// First two channels are for the convolver output, and the next two are
// for the reference.
splitter.connect(finalMerger, 0, 0);
splitter.connect(finalMerger, 1, 1);
delay[0].connect(finalMerger, 0, 2);
delay[1].connect(finalMerger, 0, 3);
finalMerger.connect(context.destination);
// Start the sources at last.
for (let k = 0; k < src.length; ++k) {
src[k].start();
}
return context.startRendering().then(audioBuffer => {
// Extract the various channels out
let actual0 = audioBuffer.getChannelData(0);
let actual1 = audioBuffer.getChannelData(1);
let expected0 = audioBuffer.getChannelData(2);
let expected1 = audioBuffer.getChannelData(3);
let threshold = options.absoluteThreshold ?
options.absoluteThreshold : absoluteThreshold;
// Verify that each output channel of the convolver matches
// the delayed signal from the reference
should(actual0, options.prefix + ': Channel 0')
.beCloseToArray(expected0, {absoluteThreshold: threshold});
should(actual1, options.prefix + ': Channel 1')
.beCloseToArray(expected1, {absoluteThreshold: threshold});
});
}
function stereoResponseExplicitTest(options, should) {
// Create an 4-channel offline context. The first two channels are for
// the stereo output of the convolver and the next two channels are for
// the reference stereo signal.
let context = new OfflineAudioContext(4, renderFrames, sampleRate);
context.destination.channelInterpretation = 'discrete';
// Create oscillators for use as the input. The type and frequency is
// arbitrary except that oscillators must be different.
let src = new Array(options.numberOfInputs);
for (let k = 0; k < src.length; ++k) {
src[k] = new OscillatorNode(
context, {type: 'square', frequency: 440 + 220 * k});
}
// Merger to combine the oscillators into one output stream.
let srcMerger =
new ChannelMergerNode(context, {numberOfInputs: src.length});
for (let k = 0; k < src.length; ++k) {
src[k].connect(srcMerger, 0, k);
}
// Convolver under test.
let conv = new ConvolverNode(context, {
channelCount: 1,
channelCountMode: 'explicit',
disableNormalization: true,
buffer: response
});
srcMerger.connect(conv);
// Splitter to get individual channels of the convolver output so we can
// feed them (eventually) to the context in the right set of channels.
let splitter = new ChannelSplitterNode(context, {numberOfOutputs: 2});
conv.connect(splitter);
// Reference graph consists of a delays node to simulate the response of
// the convolver. (The convolver response is designed this way.)
let delay = new Array(2);
for (let k = 0; k < delay.length; ++k) {
delay[k] = new DelayNode(context, {
delayTime: (k + 1) / context.sampleRate,
channelCount: 1,
channelCountMode: 'explicit'
});
}
// Gain node to mix the sources in the same way as the convolver.
let gainMixer = new GainNode(
context, {channelCount: 1, channelCountMode: 'explicit'});
srcMerger.connect(gainMixer);
// Connect each channel to the delay nodes
for (let k = 0; k < delay.length; ++k) {
gainMixer.connect(delay[k]);
}
// Final merger to bring back the individual channels from the convolver
// and the reference in the right order for the destination.
let finalMerger = new ChannelMergerNode(
context, {numberOfInputs: context.destination.channelCount});
// First two channels are for the convolver output, and the next two are
// for the reference.
splitter.connect(finalMerger, 0, 0);
splitter.connect(finalMerger, 1, 1);
delay[0].connect(finalMerger, 0, 2);
delay[1].connect(finalMerger, 0, 3);
finalMerger.connect(context.destination);
// Start the sources at last.
for (let k = 0; k < src.length; ++k) {
src[k].start();
}
return context.startRendering().then(audioBuffer => {
// Extract the various channels out
let actual0 = audioBuffer.getChannelData(0);
let actual1 = audioBuffer.getChannelData(1);
let expected0 = audioBuffer.getChannelData(2);
let expected1 = audioBuffer.getChannelData(3);
let threshold = options.absoluteThreshold ?
options.absoluteThreshold : absoluteThreshold;
// Verify that each output channel of the convolver matches
// the delayed signal from the reference
should(actual0, options.prefix + ': Channel 0')
.beCloseToArray(expected0, {absoluteThreshold: threshold});
should(actual1, options.prefix + ': Channel 1')
.beCloseToArray(expected1, {absoluteThreshold: threshold});
});
}
audit.run();
</script>
</body>
</html>
|
