Adding upstream version 1:115.7.0.upstream/1%115.7.0upstream

Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>

1 files changed, 149 insertions, 0 deletions

diff --git a/testing/web-platform/tests/webaudio/the-audio-api/the-convolvernode-interface/realtime-conv.html b/testing/web-platform/tests/webaudio/the-audio-api/the-convolvernode-interface/realtime-conv.html
new file mode 100644
index 0000000000..8668e9d5ac
--- /dev/null
+++ b/testing/web-platform/tests/webaudio/the-audio-api/the-convolvernode-interface/realtime-conv.html
@@ -0,0 +1,149 @@
+<!DOCTYPE html>
+<html>
+  <head>
+    <title>
+      Test Convolver on Real-time Context
+    </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>
+    <script src="/webaudio/resources/convolution-testing.js"></script>
+  </head>
+  <body>
+    <script id="layout-test-code">
+      const audit = Audit.createTaskRunner();
+      // Choose a length that is larger enough to cause multiple threads to be
+      // used in the convolver.  For browsers that don't support this, this
+      // value doesn't matter.
+      const pulseLength = 16384;
+
+      // The computed SNR should be at least this large.  This value depends on
+      // teh platform and browser.  Don't set this value to be to much lower
+      // than this. It probably indicates a fairly inaccurate convolver or
+      // constant source node automations that should be fixed instead.
+      const minRequiredSNR = 77.03;
+
+      // To test the real-time convolver, we convolve two square pulses together
+      // to produce a triangular pulse.  To verify the result is correct we
+      // compare it against a constant source node configured to generate the
+      // expected ramp.
+      audit.define(
+          {label: 'test', description: 'Test convolver with real-time context'},
+          (task, should) => {
+            // Use a power of two for the sample rate to eliminate round-off in
+            // computing times from frames.
+            const context = new AudioContext({sampleRate: 16384});
+
+            // Square pulse for the convolver impulse response.
+            const squarePulse = new AudioBuffer(
+                {length: pulseLength, sampleRate: context.sampleRate});
+            squarePulse.getChannelData(0).fill(1);
+
+            const convolver = new ConvolverNode(
+                context, {buffer: squarePulse, disableNormalization: true});
+
+            // Square pulse for testing
+            const srcSquare = new ConstantSourceNode(context, {offset: 0});
+            srcSquare.connect(convolver);
+
+            // Reference ramp.  Automations on this constant source node will
+            // generate the desired ramp.
+            const srcRamp = new ConstantSourceNode(context, {offset: 0});
+
+            // Use these gain nodes to compute the difference between the
+            // convolver output and the expected ramp to create the error
+            // signal.
+            const inverter = new GainNode(context, {gain: -1});
+            const sum = new GainNode(context, {gain: 1});
+            convolver.connect(sum);
+            srcRamp.connect(inverter).connect(sum);
+
+            // Square the error signal using this gain node.
+            const squarer = new GainNode(context, {gain: 0});
+            sum.connect(squarer);
+            sum.connect(squarer.gain);
+
+            // Merge the error signal and the square source so we can integrate
+            // the error signal to find an SNR.
+            const merger = new ChannelMergerNode(context, {numberOfInputs: 2});
+
+            squarer.connect(merger, 0, 0);
+            srcSquare.connect(merger, 0, 1);
+
+            // For simplicity, use a ScriptProcessor to integrate the error
+            // signal. The square pulse signal is used as a gate over which the
+            // integration is done.  When the pulse ends, the SNR is computed
+            // and the test ends.
+
+            // |doSum| is used to determine when to integrate and when it
+            // becomes false, it signals the end of integration.
+            let doSum = false;
+
+            // |signalSum| is the energy in the square pulse.  |errorSum| is the
+            // energy in the error signal.
+            let signalSum = 0;
+            let errorSum = 0;
+
+            let spn = context.createScriptProcessor(0, 2, 1);
+            spn.onaudioprocess = (event) => {
+              // Sum the values on the first channel when the second channel is
+              // not zero.  When the second channel goes from non-zero to 0,
+              // dump the value out and terminate the test.
+              let c0 = event.inputBuffer.getChannelData(0);
+              let c1 = event.inputBuffer.getChannelData(1);
+
+              for (let k = 0; k < c1.length; ++k) {
+                if (c1[k] == 0) {
+                  if (doSum) {
+                    doSum = false;
+                    // Square wave is now silent and we were integration, so we
+                    // can stop now and verify the SNR.
+                    should(10 * Math.log10(signalSum / errorSum), 'SNR')
+                        .beGreaterThanOrEqualTo(minRequiredSNR);
+                    spn.onaudioprocess = null;
+                    task.done();
+                  }
+                } else {
+                  // Signal is non-zero so sum up the values.
+                  doSum = true;
+                  errorSum += c0[k];
+                  signalSum += c1[k] * c1[k];
+                }
+              }
+            };
+
+            merger.connect(spn).connect(context.destination);
+
+            // Schedule everything to start a bit in the futurefrom now, and end
+            // pulseLength frames later.
+            let now = context.currentTime;
+
+            // |startFrame| is the number of frames to schedule ahead for
+            // testing.
+            const startFrame = 512;
+            const startTime = startFrame / context.sampleRate;
+            const pulseDuration = pulseLength / context.sampleRate;
+
+            // Create a square pulse in the constant source node.
+            srcSquare.offset.setValueAtTime(1, now + startTime);
+            srcSquare.offset.setValueAtTime(0, now + startTime + pulseDuration);
+
+            // Create the reference ramp.
+            srcRamp.offset.setValueAtTime(1, now + startTime);
+            srcRamp.offset.linearRampToValueAtTime(
+                pulseLength,
+                now + startTime + pulseDuration - 1 / context.sampleRate);
+            srcRamp.offset.linearRampToValueAtTime(
+                0,
+                now + startTime + 2 * pulseDuration - 1 / context.sampleRate);
+
+            // Start the ramps!
+            srcRamp.start();
+            srcSquare.start();
+          });
+
+      audit.run();
+    </script>
+  </body>
+</html>