gecko/content/media/test/test_a4_tone.html

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<!--
https://bugzilla.mozilla.org/show_bug.cgi?id=490705
-->

<head>
  <title>Media test: simple audioAvalailable event checks</title>
  <script type="text/javascript" src="/MochiKit/packed.js"></script>
  <script type="text/javascript" src="/tests/SimpleTest/SimpleTest.js"></script>
  <link rel="stylesheet" type="text/css" href="/tests/SimpleTest/test.css" />
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<a target="_blank" href="https://bugzilla.mozilla.org/show_bug.cgi?id=490705">Mozilla Bug 490705</a>

<!-- mute audio, since there is no need to hear the sound for these tests -->
<audio id='a1' controls></audio>

<pre id="test">
<script class="testbody" type="text/javascript">

/**
* FFT is a class for calculating the Discrete Fourier Transform of a signal
* with the Fast Fourier Transform algorithm.
*
* Source: github.com/corbanbrook/dsp.js; License: MIT; Copyright: Corban Brook
*
* @param {Number} bufferSize The size of the sample buffer to be computed. Must be power of 2
* @param {Number} sampleRate The sampleRate of the buffer (eg. 44100)
*
* @constructor
*/
FFT = function(bufferSize, sampleRate) {
  this.bufferSize = bufferSize;
  this.sampleRate = sampleRate;
  this.spectrum = new Float32Array(bufferSize/2);
  this.real = new Float32Array(bufferSize);
  this.imag = new Float32Array(bufferSize);

  this.reverseTable = new Uint32Array(bufferSize);

  var limit = 1;
  var bit = bufferSize >> 1;

  while ( limit < bufferSize ) {
    for ( var i = 0; i < limit; i++ ) {
      this.reverseTable[i + limit] = this.reverseTable[i] + bit;
    }

    limit = limit << 1;
    bit = bit >> 1;
  }

  this.sinTable = new Float32Array(bufferSize);
  this.cosTable = new Float32Array(bufferSize);

  for ( var i = 0; i < bufferSize; i++ ) {
    this.sinTable[i] = Math.sin(-Math.PI/i);
    this.cosTable[i] = Math.cos(-Math.PI/i);
  }
};

/**
* Performs a forward tranform on the sample buffer.
* Converts a time domain signal to frequency domain spectra.
*
* @param {Array} buffer The sample buffer. Buffer Length must be power of 2
*
* @returns The frequency spectrum array
*/
FFT.prototype.forward = function(buffer) {
  // Locally scope variables for speed up
  var bufferSize = this.bufferSize,
      cosTable = this.cosTable,
      sinTable = this.sinTable,
      reverseTable = this.reverseTable,
      real = this.real,
      imag = this.imag,
      spectrum = this.spectrum;

  var k = Math.floor(Math.log(bufferSize) / Math.LN2);
  if ( Math.pow(2, k) !== bufferSize ) {
    throw "Invalid buffer size, must be a power of 2.";
  }
  if ( bufferSize !== buffer.length ) {
    throw "Supplied buffer is not the same size as defined FFT. FFT Size: " + bufferSize + " Buffer Size: " + buffer.length;
  }

  for ( var i = 0; i < bufferSize; i++ ) {
    real[i] = buffer[reverseTable[i]];
    imag[i] = 0;
  }

  var halfSize = 1,
      phaseShiftStepReal,
      phaseShiftStepImag,
      currentPhaseShiftReal,
      currentPhaseShiftImag,
      off,
      tr,
      ti,
      tmpReal,
      i;

  while ( halfSize < bufferSize ) {
    phaseShiftStepReal = cosTable[halfSize];
    phaseShiftStepImag = sinTable[halfSize];
    currentPhaseShiftReal = 1;
    currentPhaseShiftImag = 0;

    for ( var fftStep = 0; fftStep < halfSize; fftStep++ ) {
      i = fftStep;

      while ( i < bufferSize ) {
        off = i + halfSize;
        tr = (currentPhaseShiftReal * real[off]) - (currentPhaseShiftImag * imag[off]);
        ti = (currentPhaseShiftReal * imag[off]) + (currentPhaseShiftImag * real[off]);

        real[off] = real[i] - tr;
        imag[off] = imag[i] - ti;
        real[i] += tr;
        imag[i] += ti;

        i += halfSize << 1;
      }

      tmpReal = currentPhaseShiftReal;
      currentPhaseShiftReal = (tmpReal * phaseShiftStepReal) - (currentPhaseShiftImag * phaseShiftStepImag);
      currentPhaseShiftImag = (tmpReal * phaseShiftStepImag) + (currentPhaseShiftImag * phaseShiftStepReal);
    }

    halfSize = halfSize << 1;
  }

  i = bufferSize/2;
  while(i--) {
    spectrum[i] = 2 * Math.sqrt(real[i] * real[i] + imag[i] * imag[i]) / bufferSize;
  }

  return spectrum;
};
/* end of FFT */


var testFile = "file_a4_tone.ogg";
var testFileDuration = 3.0;
var testFileChannelCount = 1;
var testFileSampleRate = 44100;
var testFileFrameBufferLength = 1024;
var signal = [{start:1.1, end: 1.9, fftBin: 10 } ];
var noSignal = [{start:0.1, end: 0.9 }, {start:2.1, end: 2.9 } ];

var undef;
var fft, fftBufferSize;
var currentSampleOffset = 0;
var spectrumMaxs = [];
var isTimePropertyValid = true;

function audioAvailable(event) {
  var buffer = event.frameBuffer;

  if(fft === undef) {
    fftBufferSize = buffer.length;
    fft = new FFT(fftBufferSize, testFileSampleRate);
  }

  fft.forward(buffer);

  var spectrum = fft.spectrum;
  // Finding pick frequency
  var maxIndex = 0, maxValue = spectrum[0];
  for(var i=0;i<spectrum.length;i++) {
    if(maxValue < spectrum[i]) {
      maxValue = spectrum[maxIndex = i];
    }
  }

  spectrumMaxs.push({ value: maxValue, index: maxIndex, time: (currentSampleOffset / testFileSampleRate) });

  if( (typeof event.time !== "number") ||
      (Math.abs(event.time - currentSampleOffset / testFileSampleRate) >= 0.001) ) {
    isTimePropertyValid = false;
  }

  currentSampleOffset += buffer.length;
}

var loadedMetadataCalled = false;
function loadedMetadata() {
  loadedMetadataCalled = true;
  var a1 = document.getElementById('a1');
  is(a1.mozChannels, testFileChannelCount, "mozChannels should be " + testFileChannelCount + ".");
  is(a1.mozSampleRate, testFileSampleRate, "mozSampleRate should be " + testFileSampleRate + ".");
  is(a1.mozFrameBufferLength, testFileFrameBufferLength, "mozFrameBufferLength should be " + testFileFrameBufferLength + ".");
}

function checkResults() {
  ok(loadedMetadataCalled, "loadedmetadata event not dispatched.");
  ok(isTimePropertyValid, "The audioAvailable event's time attribute was invalid.");

  var expectedOffset = Math.ceil(testFileDuration * testFileSampleRate);
  if(expectedOffset % fftBufferSize !== 0) { expectedOffset += (fftBufferSize - (expectedOffset % fftBufferSize)); }
  is(currentSampleOffset, expectedOffset, "Check amount of signal data processed");

  var i, j;
  var signalPresent = true;
  for(i=0;i<signal.length;++i) {
    var signalAnalysed = false;
    for(j=0;j<spectrumMaxs.length;++j) {
      if(signal[i].start <= spectrumMaxs[j].time && spectrumMaxs[j].time < signal[i].end) {
        signalAnalysed = true;
        signalPresent = spectrumMaxs[j].index == signal[i].fftBin;
      }
      if(!signalPresent) break;
    }
    if(!signalAnalysed) signalPresent = false;;
    if(!signalPresent) break;
  }
  is(signalPresent, true, "Check signal present");

  var noSignalPresent = true;
  for(i=0;i<noSignal.length;++i) {
    var signalAnalysed = false;
    for(j=0;j<spectrumMaxs.length;++j) {
      if(noSignal[i].start <= spectrumMaxs[j].time && spectrumMaxs[j].time < noSignal[i].end) {
        signalAnalysed = true;
        noSignalPresent = spectrumMaxs[j].index == 0;
      }
      if(!noSignalPresent) break;
    }
    if(!signalAnalysed) noSignalPresent = false;;
    if(!noSignalPresent) break;
  }
  is(signalPresent, true, "Check mute fragments present");

  SimpleTest.finish();
}

function audioEnded() {
  checkResults();
}

function initTest() {
  var a1 = document.getElementById('a1');
  a1.addEventListener("ended", audioEnded, false);
  a1.addEventListener("loadedmetadata", loadedMetadata, false);
  a1.addEventListener("MozAudioAvailable", audioAvailable, false);
  a1.src = testFile;
  a1.muted = true;
  a1.play();
}

window.addEventListener("load", function(e) {
  initTest();
}, false);

SimpleTest.waitForExplicitFinish();

</script>
</pre>
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