third_party/chromium/media/base/audio_push_fifo_unittest.cc - cobalt - Git at Google

 // Copyright 2016 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include <limits>
 #include <memory>
 #include <vector>

 #include "base/bind.h"
 #include "base/callback_helpers.h"
 #include "base/macros.h"
 #include "media/base/audio_bus.h"
 #include "media/base/audio_push_fifo.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace media {

 namespace {

 class AudioPushFifoTest : public testing::TestWithParam<int> {
  public:
   AudioPushFifoTest() = default;

   AudioPushFifoTest(const AudioPushFifoTest&) = delete;
   AudioPushFifoTest& operator=(const AudioPushFifoTest&) = delete;

   ~AudioPushFifoTest() override = default;

   int output_chunk_size() const { return GetParam(); }

   void SetUp() final {
     fifo_ = std::make_unique<AudioPushFifo>(base::BindRepeating(
         &AudioPushFifoTest::ReceiveAndCheckNextChunk, base::Unretained(this)));
     fifo_->Reset(output_chunk_size());
     ASSERT_EQ(output_chunk_size(), fifo_->frames_per_buffer());
   }

  protected:
   struct OutputChunkResult {
     int num_frames;
     float first_sample_value;
     float last_sample_value;
     int frame_delay;
   };

   // Returns the number of output chunks that should have been emitted given the
   // number of input frames pushed so far.
   size_t GetExpectedOutputChunks(int frames_pushed) const {
     return static_cast<size_t>(frames_pushed / output_chunk_size());
   }

   // Returns the number of Push() calls to make in order to get at least 3
   // output chunks.
   int GetNumPushTestIterations(int input_chunk_size) const {
     return 3 * std::max(1, output_chunk_size() / input_chunk_size);
   }

   // Repeatedly pushes constant-sized batches of input samples and checks that
   // the input data is re-chunked correctly.
   void RunSimpleRechunkTest(int input_chunk_size) {
     const int num_iterations = GetNumPushTestIterations(input_chunk_size);

     int sample_value = 0;
     const std::unique_ptr<AudioBus> audio_bus =
         AudioBus::Create(1, input_chunk_size);

     for (int i = 0; i < num_iterations; ++i) {
       EXPECT_EQ(GetExpectedOutputChunks(i * input_chunk_size), results_.size());

       // Fill audio data with predictable values.
       for (int j = 0; j < audio_bus->frames(); ++j)
         audio_bus->channel(0)[j] = static_cast<float>(sample_value++);

       fifo_->Push(*audio_bus);
       // Note: AudioPushFifo has just called ReceiveAndCheckNextChunk() zero or
       // more times.
     }
     EXPECT_EQ(GetExpectedOutputChunks(num_iterations * input_chunk_size),
               results_.size());

     // Confirm first and last sample values that have been output are the
     // expected ones.
     ASSERT_FALSE(results_.empty());
     EXPECT_EQ(0.0f, results_.front().first_sample_value);
     const float last_value_in_last_chunk = static_cast<float>(
         GetExpectedOutputChunks(num_iterations * input_chunk_size) *
             output_chunk_size() -
         1);
     EXPECT_EQ(last_value_in_last_chunk, results_.back().last_sample_value);

     // Confirm the expected frame delays for the first output chunk (or two).
     if (input_chunk_size < output_chunk_size()) {
       const int num_queued_before_first_output =
           ((output_chunk_size() - 1) / input_chunk_size) * input_chunk_size;
       EXPECT_EQ(-num_queued_before_first_output, results_.front().frame_delay);
     } else if (input_chunk_size >= output_chunk_size()) {
       EXPECT_EQ(0, results_[0].frame_delay);
       if (input_chunk_size >= 2 * output_chunk_size()) {
         EXPECT_EQ(output_chunk_size(), results_[1].frame_delay);
       } else {
         const int num_remaining_after_first_output =
             input_chunk_size - output_chunk_size();
         EXPECT_EQ(-num_remaining_after_first_output, results_[1].frame_delay);
       }
     }

     const size_t num_results_before_flush = results_.size();
     fifo_->Flush();
     const size_t num_results_after_flush = results_.size();
     if (num_results_after_flush > num_results_before_flush) {
       EXPECT_NE(0, results_.back().frame_delay);
       EXPECT_LT(-output_chunk_size(), results_.back().frame_delay);
     }
   }

   // Returns a "random" integer in the range [begin,end).
   int GetRandomInRange(int begin, int end) {
     const int len = end - begin;
     const int rand_offset = (len == 0) ? 0 : (NextRandomInt() % (end - begin));
     return begin + rand_offset;
   }

   std::unique_ptr<AudioPushFifo> fifo_;
   std::vector<OutputChunkResult> results_;

  private:
   // Called by |fifo_| to deliver another chunk of audio.  Sanity checks
   // the sample values are as expected, and without any dropped/duplicated, and
   // adds a result to |results_|.
   void ReceiveAndCheckNextChunk(const AudioBus& audio_bus, int frame_delay) {
     OutputChunkResult result;
     result.num_frames = audio_bus.frames();
     result.first_sample_value = audio_bus.channel(0)[0];
     result.last_sample_value = audio_bus.channel(0)[audio_bus.frames() - 1];
     result.frame_delay = frame_delay;

     // Check that each sample value is the previous sample value plus one.
     for (int i = 1; i < audio_bus.frames(); ++i) {
       const float expected_value = result.first_sample_value + i;
       const float actual_value = audio_bus.channel(0)[i];
       if (actual_value != expected_value) {
         if (actual_value == 0.0f) {
           // This chunk is probably being emitted by a Flush().  If that's true
           // then the frame_delay will be negative and the rest of the
           // |audio_bus| should be all zeroes.
           ASSERT_GT(0, frame_delay);
           for (int j = i + 1; j < audio_bus.frames(); ++j)
             ASSERT_EQ(0.0f, audio_bus.channel(0)[j]);
           break;
         } else {
           ASSERT_EQ(expected_value, actual_value) << "Sample at offset " << i
                                                   << " is incorrect.";
         }
       }
     }

     results_.push_back(result);
   }

   // Note: Not using base::RandInt() because it is horribly slow on debug
   // builds.  The following is a very simple, deterministic LCG:
   int NextRandomInt() {
     rand_seed_ = (1103515245 * rand_seed_ + 12345) % (1 << 31);
     return static_cast<int>(rand_seed_);
   }

   uint32_t rand_seed_ = 0x7e110;
 };

 // Tests an atypical edge case: Push()ing one frame at a time.
 TEST_P(AudioPushFifoTest, PushOneFrameAtATime) {
   RunSimpleRechunkTest(1);
 }

 // Tests that re-chunking the audio from common platform input chunk sizes
 // works.
 TEST_P(AudioPushFifoTest, Push128FramesAtATime) {
   RunSimpleRechunkTest(128);
 }
 TEST_P(AudioPushFifoTest, Push512FramesAtATime) {
   RunSimpleRechunkTest(512);
 }

 // Tests that re-chunking the audio from common "10 ms" input chunk sizes
 // works (44100 Hz * 10 ms = 441, and 48000 Hz * 10 ms = 480).
 TEST_P(AudioPushFifoTest, Push441FramesAtATime) {
   RunSimpleRechunkTest(441);
 }
 TEST_P(AudioPushFifoTest, Push480FramesAtATime) {
   RunSimpleRechunkTest(480);
 }

 // Tests that re-chunking when input audio is provided in varying chunk sizes
 // works.
 TEST_P(AudioPushFifoTest, PushArbitraryNumbersOfFramesAtATime) {
   // The loop below will run until both: 1) kMinNumIterations loops have
   // occurred; and 2) there are at least 3 entries in |results_|.
   const int kMinNumIterations = 30;

   int sample_value = 0;
   int frames_pushed_so_far = 0;
   for (int i = 0; i < kMinNumIterations || results_.size() < 3; ++i) {
     EXPECT_EQ(GetExpectedOutputChunks(frames_pushed_so_far), results_.size());

     // Create an AudioBus of a random length, populated with sample values.
     const int input_chunk_size = GetRandomInRange(1, 1920);
     const std::unique_ptr<AudioBus> audio_bus =
         AudioBus::Create(1, input_chunk_size);
     for (int j = 0; j < audio_bus->frames(); ++j)
       audio_bus->channel(0)[j] = static_cast<float>(sample_value++);

     fifo_->Push(*audio_bus);
     // Note: AudioPushFifo has just called ReceiveAndCheckNextChunk() zero or
     // more times.

     frames_pushed_so_far += input_chunk_size;
   }
   EXPECT_EQ(GetExpectedOutputChunks(frames_pushed_so_far), results_.size());

   ASSERT_FALSE(results_.empty());
   EXPECT_EQ(0.0f, results_.front().first_sample_value);
   const float last_value_in_last_chunk = static_cast<float>(
       GetExpectedOutputChunks(frames_pushed_so_far) * output_chunk_size() - 1);
   EXPECT_EQ(last_value_in_last_chunk, results_.back().last_sample_value);

   const size_t num_results_before_flush = results_.size();
   fifo_->Flush();
   const size_t num_results_after_flush = results_.size();
   if (num_results_after_flush > num_results_before_flush) {
     EXPECT_NE(0, results_.back().frame_delay);
     EXPECT_LT(-output_chunk_size(), results_.back().frame_delay);
   }
 }

 INSTANTIATE_TEST_SUITE_P(All,
                          AudioPushFifoTest,
                          ::testing::Values(
                              // 1 ms output chunks at common sample rates.
                              16,  // 16000 Hz
                              22,  // 22050 Hz
                              44,  // 44100 Hz
                              48,  // 48000 Hz

                              // 10 ms output chunks at common sample rates.
                              160,  // 16000 Hz
                              220,  // 22050 Hz
                              441,  // 44100 Hz
                              480,  // 48000 Hz

                              // 60 ms output chunks at common sample rates.
                              960,   // 16000 Hz
                              1323,  // 22050 Hz
                              2646,  // 44100 Hz
                              2880   // 48000 Hz
                              ));

 }  // namespace

 }  // namespace media
	// Copyright 2016 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include <limits>
	#include <memory>
	#include <vector>

	#include "base/bind.h"
	#include "base/callback_helpers.h"
	#include "base/macros.h"
	#include "media/base/audio_bus.h"
	#include "media/base/audio_push_fifo.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace media {

	namespace {

	class AudioPushFifoTest : public testing::TestWithParam<int> {
	public:
	AudioPushFifoTest() = default;

	AudioPushFifoTest(const AudioPushFifoTest&) = delete;
	AudioPushFifoTest& operator=(const AudioPushFifoTest&) = delete;

	~AudioPushFifoTest() override = default;

	int output_chunk_size() const { return GetParam(); }

	void SetUp() final {
	fifo_ = std::make_unique<AudioPushFifo>(base::BindRepeating(
	&AudioPushFifoTest::ReceiveAndCheckNextChunk, base::Unretained(this)));
	fifo_->Reset(output_chunk_size());
	ASSERT_EQ(output_chunk_size(), fifo_->frames_per_buffer());
	}

	protected:
	struct OutputChunkResult {
	int num_frames;
	float first_sample_value;
	float last_sample_value;
	int frame_delay;
	};

	// Returns the number of output chunks that should have been emitted given the
	// number of input frames pushed so far.
	size_t GetExpectedOutputChunks(int frames_pushed) const {
	return static_cast<size_t>(frames_pushed / output_chunk_size());
	}

	// Returns the number of Push() calls to make in order to get at least 3
	// output chunks.
	int GetNumPushTestIterations(int input_chunk_size) const {
	return 3 * std::max(1, output_chunk_size() / input_chunk_size);
	}

	// Repeatedly pushes constant-sized batches of input samples and checks that
	// the input data is re-chunked correctly.
	void RunSimpleRechunkTest(int input_chunk_size) {
	const int num_iterations = GetNumPushTestIterations(input_chunk_size);

	int sample_value = 0;
	const std::unique_ptr<AudioBus> audio_bus =
	AudioBus::Create(1, input_chunk_size);

	for (int i = 0; i < num_iterations; ++i) {
	EXPECT_EQ(GetExpectedOutputChunks(i * input_chunk_size), results_.size());

	// Fill audio data with predictable values.
	for (int j = 0; j < audio_bus->frames(); ++j)
	audio_bus->channel(0)[j] = static_cast<float>(sample_value++);

	fifo_->Push(*audio_bus);
	// Note: AudioPushFifo has just called ReceiveAndCheckNextChunk() zero or
	// more times.
	}
	EXPECT_EQ(GetExpectedOutputChunks(num_iterations * input_chunk_size),
	results_.size());

	// Confirm first and last sample values that have been output are the
	// expected ones.
	ASSERT_FALSE(results_.empty());
	EXPECT_EQ(0.0f, results_.front().first_sample_value);
	const float last_value_in_last_chunk = static_cast<float>(
	GetExpectedOutputChunks(num_iterations * input_chunk_size) *
	output_chunk_size() -
	1);
	EXPECT_EQ(last_value_in_last_chunk, results_.back().last_sample_value);

	// Confirm the expected frame delays for the first output chunk (or two).
	if (input_chunk_size < output_chunk_size()) {
	const int num_queued_before_first_output =
	((output_chunk_size() - 1) / input_chunk_size) * input_chunk_size;
	EXPECT_EQ(-num_queued_before_first_output, results_.front().frame_delay);
	} else if (input_chunk_size >= output_chunk_size()) {
	EXPECT_EQ(0, results_[0].frame_delay);
	if (input_chunk_size >= 2 * output_chunk_size()) {
	EXPECT_EQ(output_chunk_size(), results_[1].frame_delay);
	} else {
	const int num_remaining_after_first_output =
	input_chunk_size - output_chunk_size();
	EXPECT_EQ(-num_remaining_after_first_output, results_[1].frame_delay);
	}
	}

	const size_t num_results_before_flush = results_.size();
	fifo_->Flush();
	const size_t num_results_after_flush = results_.size();
	if (num_results_after_flush > num_results_before_flush) {
	EXPECT_NE(0, results_.back().frame_delay);
	EXPECT_LT(-output_chunk_size(), results_.back().frame_delay);
	}
	}

	// Returns a "random" integer in the range [begin,end).
	int GetRandomInRange(int begin, int end) {
	const int len = end - begin;
	const int rand_offset = (len == 0) ? 0 : (NextRandomInt() % (end - begin));
	return begin + rand_offset;
	}

	std::unique_ptr<AudioPushFifo> fifo_;
	std::vector<OutputChunkResult> results_;

	private:
	// Called by \|fifo_\| to deliver another chunk of audio. Sanity checks
	// the sample values are as expected, and without any dropped/duplicated, and
	// adds a result to \|results_\|.
	void ReceiveAndCheckNextChunk(const AudioBus& audio_bus, int frame_delay) {
	OutputChunkResult result;
	result.num_frames = audio_bus.frames();
	result.first_sample_value = audio_bus.channel(0)[0];
	result.last_sample_value = audio_bus.channel(0)[audio_bus.frames() - 1];
	result.frame_delay = frame_delay;

	// Check that each sample value is the previous sample value plus one.
	for (int i = 1; i < audio_bus.frames(); ++i) {
	const float expected_value = result.first_sample_value + i;
	const float actual_value = audio_bus.channel(0)[i];
	if (actual_value != expected_value) {
	if (actual_value == 0.0f) {
	// This chunk is probably being emitted by a Flush(). If that's true
	// then the frame_delay will be negative and the rest of the
	// \|audio_bus\| should be all zeroes.
	ASSERT_GT(0, frame_delay);
	for (int j = i + 1; j < audio_bus.frames(); ++j)
	ASSERT_EQ(0.0f, audio_bus.channel(0)[j]);
	break;
	} else {
	ASSERT_EQ(expected_value, actual_value) << "Sample at offset " << i
	<< " is incorrect.";
	}
	}
	}

	results_.push_back(result);
	}

	// Note: Not using base::RandInt() because it is horribly slow on debug
	// builds. The following is a very simple, deterministic LCG:
	int NextRandomInt() {
	rand_seed_ = (1103515245 * rand_seed_ + 12345) % (1 << 31);
	return static_cast<int>(rand_seed_);
	}

	uint32_t rand_seed_ = 0x7e110;
	};

	// Tests an atypical edge case: Push()ing one frame at a time.
	TEST_P(AudioPushFifoTest, PushOneFrameAtATime) {
	RunSimpleRechunkTest(1);
	}

	// Tests that re-chunking the audio from common platform input chunk sizes
	// works.
	TEST_P(AudioPushFifoTest, Push128FramesAtATime) {
	RunSimpleRechunkTest(128);
	}
	TEST_P(AudioPushFifoTest, Push512FramesAtATime) {
	RunSimpleRechunkTest(512);
	}

	// Tests that re-chunking the audio from common "10 ms" input chunk sizes
	// works (44100 Hz * 10 ms = 441, and 48000 Hz * 10 ms = 480).
	TEST_P(AudioPushFifoTest, Push441FramesAtATime) {
	RunSimpleRechunkTest(441);
	}
	TEST_P(AudioPushFifoTest, Push480FramesAtATime) {
	RunSimpleRechunkTest(480);
	}

	// Tests that re-chunking when input audio is provided in varying chunk sizes
	// works.
	TEST_P(AudioPushFifoTest, PushArbitraryNumbersOfFramesAtATime) {
	// The loop below will run until both: 1) kMinNumIterations loops have
	// occurred; and 2) there are at least 3 entries in \|results_\|.
	const int kMinNumIterations = 30;

	int sample_value = 0;
	int frames_pushed_so_far = 0;
	for (int i = 0; i < kMinNumIterations \|\| results_.size() < 3; ++i) {
	EXPECT_EQ(GetExpectedOutputChunks(frames_pushed_so_far), results_.size());

	// Create an AudioBus of a random length, populated with sample values.
	const int input_chunk_size = GetRandomInRange(1, 1920);
	const std::unique_ptr<AudioBus> audio_bus =
	AudioBus::Create(1, input_chunk_size);
	for (int j = 0; j < audio_bus->frames(); ++j)
	audio_bus->channel(0)[j] = static_cast<float>(sample_value++);

	fifo_->Push(*audio_bus);
	// Note: AudioPushFifo has just called ReceiveAndCheckNextChunk() zero or
	// more times.

	frames_pushed_so_far += input_chunk_size;
	}
	EXPECT_EQ(GetExpectedOutputChunks(frames_pushed_so_far), results_.size());

	ASSERT_FALSE(results_.empty());
	EXPECT_EQ(0.0f, results_.front().first_sample_value);
	const float last_value_in_last_chunk = static_cast<float>(
	GetExpectedOutputChunks(frames_pushed_so_far) * output_chunk_size() - 1);
	EXPECT_EQ(last_value_in_last_chunk, results_.back().last_sample_value);

	const size_t num_results_before_flush = results_.size();
	fifo_->Flush();
	const size_t num_results_after_flush = results_.size();
	if (num_results_after_flush > num_results_before_flush) {
	EXPECT_NE(0, results_.back().frame_delay);
	EXPECT_LT(-output_chunk_size(), results_.back().frame_delay);
	}
	}

	INSTANTIATE_TEST_SUITE_P(All,
	AudioPushFifoTest,
	::testing::Values(
	// 1 ms output chunks at common sample rates.
	16, // 16000 Hz
	22, // 22050 Hz
	44, // 44100 Hz
	48, // 48000 Hz

	// 10 ms output chunks at common sample rates.
	160, // 16000 Hz
	220, // 22050 Hz
	441, // 44100 Hz
	480, // 48000 Hz

	// 60 ms output chunks at common sample rates.
	960, // 16000 Hz
	1323, // 22050 Hz
	2646, // 44100 Hz
	2880 // 48000 Hz
	));

	} // namespace

	} // namespace media