mirror of
https://github.com/classilla/tenfourfox.git
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210 lines
6.7 KiB
JavaScript
210 lines
6.7 KiB
JavaScript
var sampleRate = 48000.0;
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var numberOfChannels = 1;
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// Time step when each panner node starts.
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var timeStep = 0.001;
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// Length of the impulse signal.
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var pulseLengthFrames = Math.round(timeStep * sampleRate);
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// How many panner nodes to create for the test
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var nodesToCreate = 100;
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// Be sure we render long enough for all of our nodes.
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var renderLengthSeconds = timeStep * (nodesToCreate + 1);
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// These are global mostly for debugging.
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var context;
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var impulse;
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var bufferSource;
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var panner;
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var position;
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var time;
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var renderedBuffer;
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var renderedLeft;
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var renderedRight;
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function createGraph(context, nodeCount) {
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bufferSource = new Array(nodeCount);
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panner = new Array(nodeCount);
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position = new Array(nodeCount);
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time = new Array(nodeCount);
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// Angle between panner locations. (nodeCount - 1 because we want
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// to include both 0 and 180 deg.
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var angleStep = Math.PI / (nodeCount - 1);
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if (numberOfChannels == 2) {
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impulse = createStereoImpulseBuffer(context, pulseLengthFrames);
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}
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else
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impulse = createImpulseBuffer(context, pulseLengthFrames);
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for (var k = 0; k < nodeCount; ++k) {
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bufferSource[k] = context.createBufferSource();
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bufferSource[k].buffer = impulse;
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panner[k] = context.createPanner();
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panner[k].panningModel = "equalpower";
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panner[k].distanceModel = "linear";
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var angle = angleStep * k;
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position[k] = {angle : angle, x : Math.cos(angle), z : Math.sin(angle)};
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panner[k].setPosition(position[k].x, 0, position[k].z);
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bufferSource[k].connect(panner[k]);
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panner[k].connect(context.destination);
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// Start the source
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time[k] = k * timeStep;
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bufferSource[k].start(time[k]);
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}
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}
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function createTestAndRun(context, nodeCount, numberOfSourceChannels) {
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numberOfChannels = numberOfSourceChannels;
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createGraph(context, nodeCount);
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context.oncomplete = checkResult;
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context.startRendering();
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}
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// Map our position angle to the azimuth angle (in degrees).
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//
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// An angle of 0 corresponds to an azimuth of 90 deg; pi, to -90 deg.
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function angleToAzimuth(angle) {
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return 90 - angle * 180 / Math.PI;
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}
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// The gain caused by the EQUALPOWER panning model
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function equalPowerGain(angle) {
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var azimuth = angleToAzimuth(angle);
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if (numberOfChannels == 1) {
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var panPosition = (azimuth + 90) / 180;
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var gainL = Math.cos(0.5 * Math.PI * panPosition);
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var gainR = Math.sin(0.5 * Math.PI * panPosition);
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return { left : gainL, right : gainR };
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} else {
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if (azimuth <= 0) {
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var panPosition = (azimuth + 90) / 90;
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var gainL = 1 + Math.cos(0.5 * Math.PI * panPosition);
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var gainR = Math.sin(0.5 * Math.PI * panPosition);
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return { left : gainL, right : gainR };
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} else {
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var panPosition = azimuth / 90;
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var gainL = Math.cos(0.5 * Math.PI * panPosition);
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var gainR = 1 + Math.sin(0.5 * Math.PI * panPosition);
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return { left : gainL, right : gainR };
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}
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}
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}
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function checkResult(event) {
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renderedBuffer = event.renderedBuffer;
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renderedLeft = renderedBuffer.getChannelData(0);
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renderedRight = renderedBuffer.getChannelData(1);
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// The max error we allow between the rendered impulse and the
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// expected value. This value is experimentally determined. Set
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// to 0 to make the test fail to see what the actual error is.
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var maxAllowedError = 1.3e-6;
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var success = true;
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// Number of impulses found in the rendered result.
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var impulseCount = 0;
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// Max (relative) error and the index of the maxima for the left
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// and right channels.
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var maxErrorL = 0;
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var maxErrorIndexL = 0;
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var maxErrorR = 0;
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var maxErrorIndexR = 0;
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// Number of impulses that don't match our expected locations.
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var timeCount = 0;
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// Locations of where the impulses aren't at the expected locations.
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var timeErrors = new Array();
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for (var k = 0; k < renderedLeft.length; ++k) {
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// We assume that the left and right channels start at the same instant.
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if (renderedLeft[k] != 0 || renderedRight[k] != 0) {
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// The expected gain for the left and right channels.
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var pannerGain = equalPowerGain(position[impulseCount].angle);
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var expectedL = pannerGain.left;
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var expectedR = pannerGain.right;
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// Absolute error in the gain.
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var errorL = Math.abs(renderedLeft[k] - expectedL);
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var errorR = Math.abs(renderedRight[k] - expectedR);
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if (Math.abs(errorL) > maxErrorL) {
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maxErrorL = Math.abs(errorL);
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maxErrorIndexL = impulseCount;
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}
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if (Math.abs(errorR) > maxErrorR) {
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maxErrorR = Math.abs(errorR);
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maxErrorIndexR = impulseCount;
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}
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// Keep track of the impulses that didn't show up where we
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// expected them to be.
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var expectedOffset = timeToSampleFrame(time[impulseCount], sampleRate);
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if (k != expectedOffset) {
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timeErrors[timeCount] = { actual : k, expected : expectedOffset};
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++timeCount;
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}
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++impulseCount;
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}
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}
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if (impulseCount == nodesToCreate) {
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testPassed("Number of impulses matches the number of panner nodes.");
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} else {
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testFailed("Number of impulses is incorrect. (Found " + impulseCount + " but expected " + nodesToCreate + ")");
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success = false;
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}
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if (timeErrors.length > 0) {
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success = false;
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testFailed(timeErrors.length + " timing errors found in " + nodesToCreate + " panner nodes.");
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for (var k = 0; k < timeErrors.length; ++k) {
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testFailed("Impulse at sample " + timeErrors[k].actual + " but expected " + timeErrors[k].expected);
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}
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} else {
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testPassed("All impulses at expected offsets.");
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}
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if (maxErrorL <= maxAllowedError) {
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testPassed("Left channel gain values are correct.");
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} else {
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testFailed("Left channel gain values are incorrect. Max error = " + maxErrorL + " at time " + time[maxErrorIndexL] + " (threshold = " + maxAllowedError + ")");
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success = false;
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}
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if (maxErrorR <= maxAllowedError) {
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testPassed("Right channel gain values are correct.");
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} else {
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testFailed("Right channel gain values are incorrect. Max error = " + maxErrorR + " at time " + time[maxErrorIndexR] + " (threshold = " + maxAllowedError + ")");
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success = false;
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}
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if (success) {
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testPassed("EqualPower panner test passed");
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} else {
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testFailed("EqualPower panner test failed");
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}
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finishJSTest();
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}
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