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Use SIMD acceleration for audio upsampler (#4410)

* Use SIMD acceleration for audio upsampler filter kernel for a moderate speedup

* Address formatting. Implement AVX2 fast path for high quality resampling in ResamplerHelper

* now really, are we really getting the benefit of inlining 50+ line methods?

* adding unit tests for resampler + upsampler. The upsampler ones fail for some reason

* Fixing upsampler test. Apparently this algo only works at specific ratios

---------

Co-authored-by: Logan Stromberg <lostromb@microsoft.com>
This commit is contained in:
Logan Stromberg 2023-02-21 02:44:57 -08:00 committed by GitHub
parent fc43aecbbd
commit edfd4d70c0
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4 changed files with 279 additions and 84 deletions

View file

@ -1,5 +1,6 @@
using System; using System;
using System.Linq; using System.Linq;
using System.Numerics;
using System.Runtime.CompilerServices; using System.Runtime.CompilerServices;
using System.Runtime.Intrinsics; using System.Runtime.Intrinsics;
using System.Runtime.Intrinsics.X86; using System.Runtime.Intrinsics.X86;
@ -380,7 +381,6 @@ namespace Ryujinx.Audio.Renderer.Dsp
return _normalCurveLut2F; return _normalCurveLut2F;
} }
[MethodImpl(MethodImplOptions.AggressiveInlining)]
private unsafe static void ResampleDefaultQuality(Span<float> outputBuffer, ReadOnlySpan<short> inputBuffer, float ratio, ref float fraction, int sampleCount, bool needPitch) private unsafe static void ResampleDefaultQuality(Span<float> outputBuffer, ReadOnlySpan<short> inputBuffer, float ratio, ref float fraction, int sampleCount, bool needPitch)
{ {
ReadOnlySpan<float> parameters = GetDefaultParameter(ratio); ReadOnlySpan<float> parameters = GetDefaultParameter(ratio);
@ -394,7 +394,6 @@ namespace Ryujinx.Audio.Renderer.Dsp
if (ratio == 1f) if (ratio == 1f)
{ {
fixed (short* pInput = inputBuffer) fixed (short* pInput = inputBuffer)
{
fixed (float* pOutput = outputBuffer, pParameters = parameters) fixed (float* pOutput = outputBuffer, pParameters = parameters)
{ {
Vector128<float> parameter = Sse.LoadVector128(pParameters); Vector128<float> parameter = Sse.LoadVector128(pParameters);
@ -424,14 +423,12 @@ namespace Ryujinx.Audio.Renderer.Dsp
Sse.Store(pOutput + (uint)i, Sse41.RoundToNearestInteger(mix0123)); Sse.Store(pOutput + (uint)i, Sse41.RoundToNearestInteger(mix0123));
} }
} }
}
inputBufferIndex = i; inputBufferIndex = i;
} }
else else
{ {
fixed (short* pInput = inputBuffer) fixed (short* pInput = inputBuffer)
{
fixed (float* pOutput = outputBuffer, pParameters = parameters) fixed (float* pOutput = outputBuffer, pParameters = parameters)
{ {
for (; i < (sampleCount & ~3); i += 4) for (; i < (sampleCount & ~3); i += 4)
@ -490,7 +487,6 @@ namespace Ryujinx.Audio.Renderer.Dsp
} }
} }
} }
}
for (; i < sampleCount; i++) for (; i < sampleCount; i++)
{ {
@ -526,15 +522,39 @@ namespace Ryujinx.Audio.Renderer.Dsp
return _highCurveLut2F; return _highCurveLut2F;
} }
[MethodImpl(MethodImplOptions.AggressiveInlining)] private static unsafe void ResampleHighQuality(Span<float> outputBuffer, ReadOnlySpan<short> inputBuffer, float ratio, ref float fraction, int sampleCount)
private static void ResampleHighQuality(Span<float> outputBuffer, ReadOnlySpan<short> inputBuffer, float ratio, ref float fraction, int sampleCount)
{ {
ReadOnlySpan<float> parameters = GetHighParameter(ratio); ReadOnlySpan<float> parameters = GetHighParameter(ratio);
int inputBufferIndex = 0; int inputBufferIndex = 0;
// TODO: fast path if (Avx2.IsSupported)
{
// Fast path; assumes 256-bit vectors for simplicity because the filter is 8 taps
fixed (short* pInput = inputBuffer)
fixed (float* pParameters = parameters)
{
for (int i = 0; i < sampleCount; i++)
{
int baseIndex = (int)(fraction * 128) * 8;
Vector256<int> intInput = Avx2.ConvertToVector256Int32(pInput + inputBufferIndex);
Vector256<float> floatInput = Avx.ConvertToVector256Single(intInput);
Vector256<float> parameter = Avx.LoadVector256(pParameters + baseIndex);
Vector256<float> dp = Avx.DotProduct(floatInput, parameter, control: 0xFF);
// avx2 does an 8-element dot product piecewise so we have to sum up 2 intermediate results
outputBuffer[i] = (float)Math.Round(dp[0] + dp[4]);
fraction += ratio;
inputBufferIndex += (int)MathF.Truncate(fraction);
fraction -= (int)fraction;
}
}
}
else
{
for (int i = 0; i < sampleCount; i++) for (int i = 0; i < sampleCount; i++)
{ {
int baseIndex = (int)(fraction * 128) * 8; int baseIndex = (int)(fraction * 128) * 8;
@ -556,6 +576,7 @@ namespace Ryujinx.Audio.Renderer.Dsp
fraction -= (int)fraction; fraction -= (int)fraction;
} }
} }
}
[MethodImpl(MethodImplOptions.AggressiveInlining)] [MethodImpl(MethodImplOptions.AggressiveInlining)]
public static void ResampleLowQuality(Span<float> outputBuffer, ReadOnlySpan<short> inputBuffer, float ratio, ref float fraction, int sampleCount) public static void ResampleLowQuality(Span<float> outputBuffer, ReadOnlySpan<short> inputBuffer, float ratio, ref float fraction, int sampleCount)

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@ -2,6 +2,7 @@ using Ryujinx.Audio.Renderer.Server.Upsampler;
using Ryujinx.Common.Memory; using Ryujinx.Common.Memory;
using System; using System;
using System.Diagnostics; using System.Diagnostics;
using System.Numerics;
using System.Runtime.CompilerServices; using System.Runtime.CompilerServices;
namespace Ryujinx.Audio.Renderer.Dsp namespace Ryujinx.Audio.Renderer.Dsp
@ -70,16 +71,32 @@ namespace Ryujinx.Audio.Renderer.Dsp
return; return;
} }
[MethodImpl(MethodImplOptions.AggressiveInlining)]
float DoFilterBank(ref UpsamplerBufferState state, in Array20<float> bank) float DoFilterBank(ref UpsamplerBufferState state, in Array20<float> bank)
{ {
float result = 0.0f; float result = 0.0f;
Debug.Assert(state.History.Length == HistoryLength); Debug.Assert(state.History.Length == HistoryLength);
Debug.Assert(bank.Length == FilterBankLength); Debug.Assert(bank.Length == FilterBankLength);
for (int j = 0; j < FilterBankLength; j++)
int curIdx = 0;
if (Vector.IsHardwareAccelerated)
{ {
result += bank[j] * state.History[j]; // Do SIMD-accelerated block operations where possible.
// Only about a 2x speedup since filter bank length is short
int stopIdx = FilterBankLength - (FilterBankLength % Vector<float>.Count);
while (curIdx < stopIdx)
{
result += Vector.Dot(
new Vector<float>(bank.AsSpan().Slice(curIdx, Vector<float>.Count)),
new Vector<float>(state.History.AsSpan().Slice(curIdx, Vector<float>.Count)));
curIdx += Vector<float>.Count;
}
}
while (curIdx < FilterBankLength)
{
result += bank[curIdx] * state.History[curIdx];
curIdx++;
} }
return result; return result;

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@ -0,0 +1,93 @@
using NUnit.Framework;
using Ryujinx.Audio.Renderer.Dsp;
using Ryujinx.Audio.Renderer.Parameter;
using Ryujinx.Audio.Renderer.Server.Upsampler;
using System;
using System.Collections.Generic;
using System.IO;
using System.Linq;
using System.Runtime.CompilerServices;
using System.Text;
using System.Threading.Tasks;
namespace Ryujinx.Tests.Audio.Renderer.Dsp
{
class ResamplerTests
{
[Test]
[TestCase(VoiceInParameter.SampleRateConversionQuality.Low)]
[TestCase(VoiceInParameter.SampleRateConversionQuality.Default)]
[TestCase(VoiceInParameter.SampleRateConversionQuality.High)]
public void TestResamplerConsistencyUpsampling(VoiceInParameter.SampleRateConversionQuality quality)
{
DoResamplingTest(44100, 48000, quality);
}
[Test]
[TestCase(VoiceInParameter.SampleRateConversionQuality.Low)]
[TestCase(VoiceInParameter.SampleRateConversionQuality.Default)]
[TestCase(VoiceInParameter.SampleRateConversionQuality.High)]
public void TestResamplerConsistencyDownsampling(VoiceInParameter.SampleRateConversionQuality quality)
{
DoResamplingTest(48000, 44100, quality);
}
/// <summary>
/// Generates a 1-second sine wave sample at input rate, resamples it to output rate, and
/// ensures that it resampled at the expected rate with no discontinuities
/// </summary>
/// <param name="inputRate">The input sample rate to test</param>
/// <param name="outputRate">The output sample rate to test</param>
/// <param name="quality">The resampler quality to use</param>
private static void DoResamplingTest(int inputRate, int outputRate, VoiceInParameter.SampleRateConversionQuality quality)
{
float inputSampleRate = (float)inputRate;
float outputSampleRate = (float)outputRate;
int inputSampleCount = inputRate;
int outputSampleCount = outputRate;
short[] inputBuffer = new short[inputSampleCount + 100]; // add some safety buffer at the end
float[] outputBuffer = new float[outputSampleCount + 100];
for (int sample = 0; sample < inputBuffer.Length; sample++)
{
// 440 hz sine wave with amplitude = 0.5f at input sample rate
inputBuffer[sample] = (short)(32767 * MathF.Sin((440 / inputSampleRate) * (float)sample * MathF.PI * 2f) * 0.5f);
}
float fraction = 0;
ResamplerHelper.Resample(
outputBuffer.AsSpan(),
inputBuffer.AsSpan(),
inputSampleRate / outputSampleRate,
ref fraction,
outputSampleCount,
quality,
false);
float[] expectedOutput = new float[outputSampleCount];
float sumDifference = 0;
int delay = quality switch
{
VoiceInParameter.SampleRateConversionQuality.High => 3,
VoiceInParameter.SampleRateConversionQuality.Default => 1,
_ => 0
};
for (int sample = 0; sample < outputSampleCount; sample++)
{
outputBuffer[sample] /= 32767;
// 440 hz sine wave with amplitude = 0.5f at output sample rate
expectedOutput[sample] = MathF.Sin((440 / outputSampleRate) * (float)(sample + delay) * MathF.PI * 2f) * 0.5f;
float thisDelta = Math.Abs(expectedOutput[sample] - outputBuffer[sample]);
// Ensure no discontinuities
Assert.IsTrue(thisDelta < 0.1f);
sumDifference += thisDelta;
}
sumDifference = sumDifference / (float)outputSampleCount;
// Expect the output to be 99% similar to the expected resampled sine wave
Assert.IsTrue(sumDifference < 0.01f);
}
}
}

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@ -0,0 +1,64 @@
using NUnit.Framework;
using Ryujinx.Audio.Renderer.Dsp;
using Ryujinx.Audio.Renderer.Parameter;
using Ryujinx.Audio.Renderer.Server.Upsampler;
using System;
using System.Collections.Generic;
using System.IO;
using System.Linq;
using System.Runtime.CompilerServices;
using System.Text;
using System.Threading.Tasks;
namespace Ryujinx.Tests.Audio.Renderer.Dsp
{
class UpsamplerTests
{
[Test]
public void TestUpsamplerConsistency()
{
UpsamplerBufferState bufferState = new UpsamplerBufferState();
int inputBlockSize = 160;
int numInputSamples = 32000;
int numOutputSamples = 48000;
float inputSampleRate = numInputSamples;
float outputSampleRate = numOutputSamples;
float[] inputBuffer = new float[numInputSamples + 100];
float[] outputBuffer = new float[numOutputSamples + 100];
for (int sample = 0; sample < inputBuffer.Length; sample++)
{
// 440 hz sine wave with amplitude = 0.5f at input sample rate
inputBuffer[sample] = MathF.Sin((440 / inputSampleRate) * (float)sample * MathF.PI * 2f) * 0.5f;
}
int inputIdx = 0;
int outputIdx = 0;
while (inputIdx + inputBlockSize < numInputSamples)
{
int outputBufLength = (int)Math.Round((float)(inputIdx + inputBlockSize) * outputSampleRate / inputSampleRate) - outputIdx;
UpsamplerHelper.Upsample(
outputBuffer.AsSpan(outputIdx),
inputBuffer.AsSpan(inputIdx),
outputBufLength,
inputBlockSize,
ref bufferState);
inputIdx += inputBlockSize;
outputIdx += outputBufLength;
}
float[] expectedOutput = new float[numOutputSamples];
float sumDifference = 0;
for (int sample = 0; sample < numOutputSamples; sample++)
{
// 440 hz sine wave with amplitude = 0.5f at output sample rate with an offset of 15
expectedOutput[sample] = MathF.Sin((440 / outputSampleRate) * (float)(sample - 15) * MathF.PI * 2f) * 0.5f;
sumDifference += Math.Abs(expectedOutput[sample] - outputBuffer[sample]);
}
sumDifference = sumDifference / (float)expectedOutput.Length;
// Expect the output to be 98% similar to the expected resampled sine wave
Assert.IsTrue(sumDifference < 0.02f);
}
}
}