common_audio/audio_converter_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 2014 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include "common_audio/audio_converter.h"

 #include <algorithm>
 #include <cmath>
 #include <memory>
 #include <vector>

 #include "common_audio/channel_buffer.h"
 #include "common_audio/resampler/push_sinc_resampler.h"
 #include "rtc_base/arraysize.h"
 #include "rtc_base/format_macros.h"
 #include "test/gtest.h"

 namespace webrtc {

 typedef std::unique_ptr<ChannelBuffer<float>> ScopedBuffer;

 // Sets the signal value to increase by |data| with every sample.
 ScopedBuffer CreateBuffer(const std::vector<float>& data, size_t frames) {
   const size_t num_channels = data.size();
   ScopedBuffer sb(new ChannelBuffer<float>(frames, num_channels));
   for (size_t i = 0; i < num_channels; ++i)
     for (size_t j = 0; j < frames; ++j)
       sb->channels()[i][j] = data[i] * j;
   return sb;
 }

 void VerifyParams(const ChannelBuffer<float>& ref,
                   const ChannelBuffer<float>& test) {
   EXPECT_EQ(ref.num_channels(), test.num_channels());
   EXPECT_EQ(ref.num_frames(), test.num_frames());
 }

 // Computes the best SNR based on the error between |ref_frame| and
 // |test_frame|. It searches around |expected_delay| in samples between the
 // signals to compensate for the resampling delay.
 float ComputeSNR(const ChannelBuffer<float>& ref,
                  const ChannelBuffer<float>& test,
                  size_t expected_delay) {
   VerifyParams(ref, test);
   float best_snr = 0;
   size_t best_delay = 0;

   // Search within one sample of the expected delay.
   for (size_t delay = std::max(expected_delay, static_cast<size_t>(1)) - 1;
        delay <= std::min(expected_delay + 1, ref.num_frames()); ++delay) {
     float mse = 0;
     float variance = 0;
     float mean = 0;
     for (size_t i = 0; i < ref.num_channels(); ++i) {
       for (size_t j = 0; j < ref.num_frames() - delay; ++j) {
         float error = ref.channels()[i][j] - test.channels()[i][j + delay];
         mse += error * error;
         variance += ref.channels()[i][j] * ref.channels()[i][j];
         mean += ref.channels()[i][j];
       }
     }

     const size_t length = ref.num_channels() * (ref.num_frames() - delay);
     mse /= length;
     variance /= length;
     mean /= length;
     variance -= mean * mean;
     float snr = 100;  // We assign 100 dB to the zero-error case.
     if (mse > 0)
       snr = 10 * std::log10(variance / mse);
     if (snr > best_snr) {
       best_snr = snr;
       best_delay = delay;
     }
   }
   printf("SNR=%.1f dB at delay=%" RTC_PRIuS "\n", best_snr, best_delay);
   return best_snr;
 }

 // Sets the source to a linearly increasing signal for which we can easily
 // generate a reference. Runs the AudioConverter and ensures the output has
 // sufficiently high SNR relative to the reference.
 void RunAudioConverterTest(size_t src_channels,
                            int src_sample_rate_hz,
                            size_t dst_channels,
                            int dst_sample_rate_hz) {
   const float kSrcLeft = 0.0002f;
   const float kSrcRight = 0.0001f;
   const float resampling_factor =
       (1.f * src_sample_rate_hz) / dst_sample_rate_hz;
   const float dst_left = resampling_factor * kSrcLeft;
   const float dst_right = resampling_factor * kSrcRight;
   const float dst_mono = (dst_left + dst_right) / 2;
   const size_t src_frames = static_cast<size_t>(src_sample_rate_hz / 100);
   const size_t dst_frames = static_cast<size_t>(dst_sample_rate_hz / 100);

   std::vector<float> src_data(1, kSrcLeft);
   if (src_channels == 2)
     src_data.push_back(kSrcRight);
   ScopedBuffer src_buffer = CreateBuffer(src_data, src_frames);

   std::vector<float> dst_data(1, 0);
   std::vector<float> ref_data;
   if (dst_channels == 1) {
     if (src_channels == 1)
       ref_data.push_back(dst_left);
     else
       ref_data.push_back(dst_mono);
   } else {
     dst_data.push_back(0);
     ref_data.push_back(dst_left);
     if (src_channels == 1)
       ref_data.push_back(dst_left);
     else
       ref_data.push_back(dst_right);
   }
   ScopedBuffer dst_buffer = CreateBuffer(dst_data, dst_frames);
   ScopedBuffer ref_buffer = CreateBuffer(ref_data, dst_frames);

   // The sinc resampler has a known delay, which we compute here.
   const size_t delay_frames =
       src_sample_rate_hz == dst_sample_rate_hz
           ? 0
           : static_cast<size_t>(
                 PushSincResampler::AlgorithmicDelaySeconds(src_sample_rate_hz) *
                 dst_sample_rate_hz);
   // SNR reported on the same line later.
   printf("(%" RTC_PRIuS ", %d Hz) -> (%" RTC_PRIuS ", %d Hz) ", src_channels,
          src_sample_rate_hz, dst_channels, dst_sample_rate_hz);

   std::unique_ptr<AudioConverter> converter = AudioConverter::Create(
       src_channels, src_frames, dst_channels, dst_frames);
   converter->Convert(src_buffer->channels(), src_buffer->size(),
                      dst_buffer->channels(), dst_buffer->size());

   EXPECT_LT(43.f,
             ComputeSNR(*ref_buffer.get(), *dst_buffer.get(), delay_frames));
 }

 TEST(AudioConverterTest, ConversionsPassSNRThreshold) {
   const int kSampleRates[] = {8000, 16000, 32000, 44100, 48000};
   const size_t kChannels[] = {1, 2};
   for (size_t src_rate = 0; src_rate < arraysize(kSampleRates); ++src_rate) {
     for (size_t dst_rate = 0; dst_rate < arraysize(kSampleRates); ++dst_rate) {
       for (size_t src_channel = 0; src_channel < arraysize(kChannels);
            ++src_channel) {
         for (size_t dst_channel = 0; dst_channel < arraysize(kChannels);
              ++dst_channel) {
           RunAudioConverterTest(kChannels[src_channel], kSampleRates[src_rate],
                                 kChannels[dst_channel], kSampleRates[dst_rate]);
         }
       }
     }
   }
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2014 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include "common_audio/audio_converter.h"

	#include <algorithm>
	#include <cmath>
	#include <memory>
	#include <vector>

	#include "common_audio/channel_buffer.h"
	#include "common_audio/resampler/push_sinc_resampler.h"
	#include "rtc_base/arraysize.h"
	#include "rtc_base/format_macros.h"
	#include "test/gtest.h"

	namespace webrtc {

	typedef std::unique_ptr<ChannelBuffer<float>> ScopedBuffer;

	// Sets the signal value to increase by \|data\| with every sample.
	ScopedBuffer CreateBuffer(const std::vector<float>& data, size_t frames) {
	const size_t num_channels = data.size();
	ScopedBuffer sb(new ChannelBuffer<float>(frames, num_channels));
	for (size_t i = 0; i < num_channels; ++i)
	for (size_t j = 0; j < frames; ++j)
	sb->channels()[i][j] = data[i] * j;
	return sb;
	}

	void VerifyParams(const ChannelBuffer<float>& ref,
	const ChannelBuffer<float>& test) {
	EXPECT_EQ(ref.num_channels(), test.num_channels());
	EXPECT_EQ(ref.num_frames(), test.num_frames());
	}

	// Computes the best SNR based on the error between \|ref_frame\| and
	// \|test_frame\|. It searches around \|expected_delay\| in samples between the
	// signals to compensate for the resampling delay.
	float ComputeSNR(const ChannelBuffer<float>& ref,
	const ChannelBuffer<float>& test,
	size_t expected_delay) {
	VerifyParams(ref, test);
	float best_snr = 0;
	size_t best_delay = 0;

	// Search within one sample of the expected delay.
	for (size_t delay = std::max(expected_delay, static_cast<size_t>(1)) - 1;
	delay <= std::min(expected_delay + 1, ref.num_frames()); ++delay) {
	float mse = 0;
	float variance = 0;
	float mean = 0;
	for (size_t i = 0; i < ref.num_channels(); ++i) {
	for (size_t j = 0; j < ref.num_frames() - delay; ++j) {
	float error = ref.channels()[i][j] - test.channels()[i][j + delay];
	mse += error * error;
	variance += ref.channels()[i][j] * ref.channels()[i][j];
	mean += ref.channels()[i][j];
	}
	}

	const size_t length = ref.num_channels() * (ref.num_frames() - delay);
	mse /= length;
	variance /= length;
	mean /= length;
	variance -= mean * mean;
	float snr = 100; // We assign 100 dB to the zero-error case.
	if (mse > 0)
	snr = 10 * std::log10(variance / mse);
	if (snr > best_snr) {
	best_snr = snr;
	best_delay = delay;
	}
	}
	printf("SNR=%.1f dB at delay=%" RTC_PRIuS "\n", best_snr, best_delay);
	return best_snr;
	}

	// Sets the source to a linearly increasing signal for which we can easily
	// generate a reference. Runs the AudioConverter and ensures the output has
	// sufficiently high SNR relative to the reference.
	void RunAudioConverterTest(size_t src_channels,
	int src_sample_rate_hz,
	size_t dst_channels,
	int dst_sample_rate_hz) {
	const float kSrcLeft = 0.0002f;
	const float kSrcRight = 0.0001f;
	const float resampling_factor =
	(1.f * src_sample_rate_hz) / dst_sample_rate_hz;
	const float dst_left = resampling_factor * kSrcLeft;
	const float dst_right = resampling_factor * kSrcRight;
	const float dst_mono = (dst_left + dst_right) / 2;
	const size_t src_frames = static_cast<size_t>(src_sample_rate_hz / 100);
	const size_t dst_frames = static_cast<size_t>(dst_sample_rate_hz / 100);

	std::vector<float> src_data(1, kSrcLeft);
	if (src_channels == 2)
	src_data.push_back(kSrcRight);
	ScopedBuffer src_buffer = CreateBuffer(src_data, src_frames);

	std::vector<float> dst_data(1, 0);
	std::vector<float> ref_data;
	if (dst_channels == 1) {
	if (src_channels == 1)
	ref_data.push_back(dst_left);
	else
	ref_data.push_back(dst_mono);
	} else {
	dst_data.push_back(0);
	ref_data.push_back(dst_left);
	if (src_channels == 1)
	ref_data.push_back(dst_left);
	else
	ref_data.push_back(dst_right);
	}
	ScopedBuffer dst_buffer = CreateBuffer(dst_data, dst_frames);
	ScopedBuffer ref_buffer = CreateBuffer(ref_data, dst_frames);

	// The sinc resampler has a known delay, which we compute here.
	const size_t delay_frames =
	src_sample_rate_hz == dst_sample_rate_hz
	? 0
	: static_cast<size_t>(
	PushSincResampler::AlgorithmicDelaySeconds(src_sample_rate_hz) *
	dst_sample_rate_hz);
	// SNR reported on the same line later.
	printf("(%" RTC_PRIuS ", %d Hz) -> (%" RTC_PRIuS ", %d Hz) ", src_channels,
	src_sample_rate_hz, dst_channels, dst_sample_rate_hz);

	std::unique_ptr<AudioConverter> converter = AudioConverter::Create(
	src_channels, src_frames, dst_channels, dst_frames);
	converter->Convert(src_buffer->channels(), src_buffer->size(),
	dst_buffer->channels(), dst_buffer->size());

	EXPECT_LT(43.f,
	ComputeSNR(ref_buffer.get(), dst_buffer.get(), delay_frames));
	}

	TEST(AudioConverterTest, ConversionsPassSNRThreshold) {
	const int kSampleRates[] = {8000, 16000, 32000, 44100, 48000};
	const size_t kChannels[] = {1, 2};
	for (size_t src_rate = 0; src_rate < arraysize(kSampleRates); ++src_rate) {
	for (size_t dst_rate = 0; dst_rate < arraysize(kSampleRates); ++dst_rate) {
	for (size_t src_channel = 0; src_channel < arraysize(kChannels);
	++src_channel) {
	for (size_t dst_channel = 0; dst_channel < arraysize(kChannels);
	++dst_channel) {
	RunAudioConverterTest(kChannels[src_channel], kSampleRates[src_rate],
	kChannels[dst_channel], kSampleRates[dst_rate]);
	}
	}
	}
	}
	}

	} // namespace webrtc