// Copyright 2014 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 "base/memory/scoped_ptr.h" #include "media/base/audio_buffer.h" #include "media/base/audio_buffer_converter.h" #include "media/base/sinc_resampler.h" #include "media/base/test_helpers.h" #include "testing/gmock/include/gmock/gmock.h" #include "testing/gtest/include/gtest/gtest.h" namespace media { // Important: Use an odd buffer size here so SIMD issues are caught. const int kOutFrameSize = 441; const int kOutSampleRate = 44100; const ChannelLayout kOutChannelLayout = CHANNEL_LAYOUT_STEREO; const int kOutChannelCount = 2; static scoped_refptr MakeTestBuffer(int sample_rate, ChannelLayout channel_layout, int channel_count, int frames) { return MakeAudioBuffer(kSampleFormatU8, channel_layout, channel_count, sample_rate, 0, 1, frames, base::TimeDelta::FromSeconds(0)); } class AudioBufferConverterTest : public ::testing::Test { public: AudioBufferConverterTest() : input_frames_(0), expected_output_frames_(0.0), output_frames_(0), output_params_(AudioParameters::AUDIO_PCM_LOW_LATENCY, kOutChannelLayout, kOutSampleRate, 16, kOutFrameSize) { audio_buffer_converter_.reset(new AudioBufferConverter(output_params_)); } void Reset() { audio_buffer_converter_->Reset(); output_frames_ = expected_output_frames_ = input_frames_ = 0; } void AddInput(const scoped_refptr& in) { if (!in->end_of_stream()) { input_frames_ += in->frame_count(); expected_output_frames_ += in->frame_count() * (static_cast(output_params_.sample_rate()) / in->sample_rate()); } audio_buffer_converter_->AddInput(in); } void ConsumeOutput() { ASSERT_TRUE(audio_buffer_converter_->HasNextBuffer()); scoped_refptr out = audio_buffer_converter_->GetNextBuffer(); if (!out->end_of_stream()) { output_frames_ += out->frame_count(); EXPECT_EQ(out->sample_rate(), output_params_.sample_rate()); EXPECT_EQ(out->channel_layout(), output_params_.channel_layout()); EXPECT_EQ(out->channel_count(), output_params_.channels()); } else { EXPECT_FALSE(audio_buffer_converter_->HasNextBuffer()); } } void ConsumeAllOutput() { AddInput(AudioBuffer::CreateEOSBuffer()); while (audio_buffer_converter_->HasNextBuffer()) ConsumeOutput(); EXPECT_EQ(output_frames_, ceil(expected_output_frames_)); } protected: scoped_ptr audio_buffer_converter_; int input_frames_; double expected_output_frames_; int output_frames_; int input_buffers_; AudioParameters output_params_; }; TEST_F(AudioBufferConverterTest, PassThrough) { scoped_refptr in = MakeTestBuffer(kOutSampleRate, kOutChannelLayout, kOutChannelCount, 512); AddInput(in); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, Downsample) { scoped_refptr in = MakeTestBuffer(48000, kOutChannelLayout, kOutChannelCount, 512); AddInput(in); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, Upsample) { scoped_refptr in = MakeTestBuffer(8000, kOutChannelLayout, kOutChannelCount, 512); AddInput(in); ConsumeAllOutput(); } // Test resampling a buffer smaller than the SincResampler's kernel size. TEST_F(AudioBufferConverterTest, Resample_TinyBuffer) { AddInput(MakeTestBuffer( 48000, CHANNEL_LAYOUT_STEREO, 2, SincResampler::kKernelSize - 1)); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, Resample_DifferingBufferSizes) { const int input_sample_rate = 48000; AddInput(MakeTestBuffer( input_sample_rate, kOutChannelLayout, kOutChannelCount, 100)); AddInput(MakeTestBuffer( input_sample_rate, kOutChannelLayout, kOutChannelCount, 200)); AddInput(MakeTestBuffer( input_sample_rate, kOutChannelLayout, kOutChannelCount, 300)); AddInput(MakeTestBuffer( input_sample_rate, kOutChannelLayout, kOutChannelCount, 400)); AddInput(MakeTestBuffer( input_sample_rate, kOutChannelLayout, kOutChannelCount, 500)); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, ChannelDownmix) { scoped_refptr in = MakeTestBuffer(kOutSampleRate, CHANNEL_LAYOUT_MONO, 1, 512); AddInput(in); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, ChannelUpmix) { scoped_refptr in = MakeTestBuffer(kOutSampleRate, CHANNEL_LAYOUT_5_1, 6, 512); AddInput(in); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, ResampleAndRemix) { scoped_refptr in = MakeTestBuffer(48000, CHANNEL_LAYOUT_5_1, 6, 512); AddInput(in); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, ConfigChange_SampleRate) { AddInput(MakeTestBuffer(48000, kOutChannelLayout, kOutChannelCount, 512)); AddInput(MakeTestBuffer(44100, kOutChannelLayout, kOutChannelCount, 512)); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, ConfigChange_ChannelLayout) { AddInput(MakeTestBuffer(kOutSampleRate, CHANNEL_LAYOUT_STEREO, 2, 512)); AddInput(MakeTestBuffer(kOutSampleRate, CHANNEL_LAYOUT_MONO, 1, 512)); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, ConfigChange_SampleRateAndChannelLayout) { AddInput(MakeTestBuffer(44100, CHANNEL_LAYOUT_STEREO, 2, 512)); AddInput(MakeTestBuffer(48000, CHANNEL_LAYOUT_MONO, 1, 512)); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, ConfigChange_Multiple) { AddInput(MakeTestBuffer(44100, CHANNEL_LAYOUT_STEREO, 2, 512)); AddInput(MakeTestBuffer(48000, CHANNEL_LAYOUT_MONO, 1, 512)); AddInput(MakeTestBuffer(44100, CHANNEL_LAYOUT_5_1, 6, 512)); AddInput(MakeTestBuffer(22050, CHANNEL_LAYOUT_STEREO, 2, 512)); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, Reset) { AddInput(MakeTestBuffer(44100, CHANNEL_LAYOUT_STEREO, 2, 512)); Reset(); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, ResampleThenReset) { // Resampling is likely to leave some data buffered in AudioConverter's // fifo or resampler, so make sure Reset() cleans that all up. AddInput(MakeTestBuffer(48000, CHANNEL_LAYOUT_STEREO, 2, 512)); Reset(); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, ResetThenConvert) { AddInput( MakeTestBuffer(kOutSampleRate, kOutChannelLayout, kOutChannelCount, 512)); Reset(); // Make sure we can keep using the AudioBufferConverter after we've Reset(). AddInput( MakeTestBuffer(kOutSampleRate, kOutChannelLayout, kOutChannelCount, 512)); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, DiscreteChannelLayout) { output_params_ = AudioParameters(AudioParameters::AUDIO_PCM_LOW_LATENCY, CHANNEL_LAYOUT_DISCRETE, kOutSampleRate, 16, 512); output_params_.set_channels_for_discrete(2); audio_buffer_converter_.reset(new AudioBufferConverter(output_params_)); AddInput(MakeTestBuffer(kOutSampleRate, CHANNEL_LAYOUT_STEREO, 2, 512)); ConsumeAllOutput(); } TEST_F(AudioBufferConverterTest, LargeBuffersResampling) { output_params_ = AudioParameters(AudioParameters::AUDIO_PCM_LOW_LATENCY, kOutChannelLayout, kOutSampleRate, 16, 2048); audio_buffer_converter_.reset(new AudioBufferConverter(output_params_)); const int kInputSampleRate = 48000; const int kInputFrameSize = 8192; ASSERT_NE(kInputSampleRate, kOutSampleRate); const int kInputBuffers = 3; for (int i = 0; i < kInputBuffers; ++i) { AddInput(MakeTestBuffer(kInputSampleRate, kOutChannelLayout, kOutChannelCount, kInputFrameSize)); } // Do not add an EOS packet here, as it will invoke flushing. while (audio_buffer_converter_->HasNextBuffer()) ConsumeOutput(); // Since the input buffer size is a multiple of the input request size there // should never be any frames remaining at this point. ASSERT_EQ(kInputFrameSize % audio_buffer_converter_->input_buffer_size_for_testing(), 0); EXPECT_EQ(0, audio_buffer_converter_->input_frames_left_for_testing()); } } // namespace media