/* * Copyright (c) 2016 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 #include "api/array_view.h" #include "modules/audio_processing/audio_buffer.h" #include "modules/audio_processing/gain_control_impl.h" #include "modules/audio_processing/test/audio_buffer_tools.h" #include "modules/audio_processing/test/bitexactness_tools.h" #include "test/gtest.h" namespace webrtc { namespace { const int kNumFramesToProcess = 100; void ProcessOneFrame(int sample_rate_hz, AudioBuffer* render_audio_buffer, AudioBuffer* capture_audio_buffer, GainControlImpl* gain_controller) { if (sample_rate_hz > AudioProcessing::kSampleRate16kHz) { render_audio_buffer->SplitIntoFrequencyBands(); capture_audio_buffer->SplitIntoFrequencyBands(); } std::vector render_audio; GainControlImpl::PackRenderAudioBuffer(*render_audio_buffer, &render_audio); gain_controller->ProcessRenderAudio(render_audio); gain_controller->AnalyzeCaptureAudio(*capture_audio_buffer); gain_controller->ProcessCaptureAudio(capture_audio_buffer, false); if (sample_rate_hz > AudioProcessing::kSampleRate16kHz) { capture_audio_buffer->MergeFrequencyBands(); } } void SetupComponent(int sample_rate_hz, GainControl::Mode mode, int target_level_dbfs, int stream_analog_level, int compression_gain_db, bool enable_limiter, int analog_level_min, int analog_level_max, GainControlImpl* gain_controller) { gain_controller->Initialize(1, sample_rate_hz); GainControl* gc = static_cast(gain_controller); gc->set_mode(mode); gc->set_stream_analog_level(stream_analog_level); gc->set_target_level_dbfs(target_level_dbfs); gc->set_compression_gain_db(compression_gain_db); gc->enable_limiter(enable_limiter); gc->set_analog_level_limits(analog_level_min, analog_level_max); } void RunBitExactnessTest(int sample_rate_hz, size_t num_channels, GainControl::Mode mode, int target_level_dbfs, int stream_analog_level, int compression_gain_db, bool enable_limiter, int analog_level_min, int analog_level_max, int achieved_stream_analog_level_reference, rtc::ArrayView output_reference) { GainControlImpl gain_controller; SetupComponent(sample_rate_hz, mode, target_level_dbfs, stream_analog_level, compression_gain_db, enable_limiter, analog_level_min, analog_level_max, &gain_controller); const int samples_per_channel = rtc::CheckedDivExact(sample_rate_hz, 100); const StreamConfig render_config(sample_rate_hz, num_channels); AudioBuffer render_buffer( render_config.sample_rate_hz(), render_config.num_channels(), render_config.sample_rate_hz(), 1, render_config.sample_rate_hz(), 1); test::InputAudioFile render_file( test::GetApmRenderTestVectorFileName(sample_rate_hz)); std::vector render_input(samples_per_channel * num_channels); const StreamConfig capture_config(sample_rate_hz, num_channels); AudioBuffer capture_buffer( capture_config.sample_rate_hz(), capture_config.num_channels(), capture_config.sample_rate_hz(), 1, capture_config.sample_rate_hz(), 1); test::InputAudioFile capture_file( test::GetApmCaptureTestVectorFileName(sample_rate_hz)); std::vector capture_input(samples_per_channel * num_channels); for (int frame_no = 0; frame_no < kNumFramesToProcess; ++frame_no) { ReadFloatSamplesFromStereoFile(samples_per_channel, num_channels, &render_file, render_input); ReadFloatSamplesFromStereoFile(samples_per_channel, num_channels, &capture_file, capture_input); test::CopyVectorToAudioBuffer(render_config, render_input, &render_buffer); test::CopyVectorToAudioBuffer(capture_config, capture_input, &capture_buffer); ProcessOneFrame(sample_rate_hz, &render_buffer, &capture_buffer, &gain_controller); } // Extract and verify the test results. std::vector capture_output; test::ExtractVectorFromAudioBuffer(capture_config, &capture_buffer, &capture_output); EXPECT_EQ(achieved_stream_analog_level_reference, gain_controller.stream_analog_level()); // Compare the output with the reference. Only the first values of the output // from last frame processed are compared in order not having to specify all // preceeding frames as testvectors. As the algorithm being tested has a // memory, testing only the last frame implicitly also tests the preceeding // frames. const float kElementErrorBound = 1.0f / 32768.0f; EXPECT_TRUE(test::VerifyDeinterleavedArray( capture_config.num_frames(), capture_config.num_channels(), output_reference, capture_output, kElementErrorBound)); } } // namespace // TODO(peah): Activate all these tests for ARM and ARM64 once the issue on the // Chromium ARM and ARM64 boths have been identified. This is tracked in the // issue https://bugs.chromium.org/p/webrtc/issues/detail?id=5711. #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono16kHz_AdaptiveAnalog_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono16kHz_AdaptiveAnalog_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.006561f, -0.004608f, -0.002899f}; RunBitExactnessTest(16000, 1, GainControl::Mode::kAdaptiveAnalog, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Stereo16kHz_AdaptiveAnalog_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Stereo16kHz_AdaptiveAnalog_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.027313f, -0.015900f, -0.028107f, -0.027313f, -0.015900f, -0.028107f}; RunBitExactnessTest(16000, 2, GainControl::Mode::kAdaptiveAnalog, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono32kHz_AdaptiveAnalog_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono32kHz_AdaptiveAnalog_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.010162f, -0.009155f, -0.008301f}; RunBitExactnessTest(32000, 1, GainControl::Mode::kAdaptiveAnalog, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono48kHz_AdaptiveAnalog_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono48kHz_AdaptiveAnalog_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.010162f, -0.009155f, -0.008301f}; RunBitExactnessTest(32000, 1, GainControl::Mode::kAdaptiveAnalog, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono16kHz_AdaptiveDigital_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono16kHz_AdaptiveDigital_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.003967f, -0.002777f, -0.001770f}; RunBitExactnessTest(16000, 1, GainControl::Mode::kAdaptiveDigital, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Stereo16kHz_AdaptiveDigital_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Stereo16kHz_AdaptiveDigital_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.015411f, -0.008972f, -0.015839f, -0.015411f, -0.008972f, -0.015839f}; RunBitExactnessTest(16000, 2, GainControl::Mode::kAdaptiveDigital, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono32kHz_AdaptiveDigital_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono32kHz_AdaptiveDigital_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.006134f, -0.005524f, -0.005005f}; RunBitExactnessTest(32000, 1, GainControl::Mode::kAdaptiveDigital, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono48kHz_AdaptiveDigital_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono48kHz_AdaptiveDigital_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.006134f, -0.005524f, -0.005005}; RunBitExactnessTest(32000, 1, GainControl::Mode::kAdaptiveDigital, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono16kHz_FixedDigital_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono16kHz_FixedDigital_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.011749f, -0.008270f, -0.005219f}; RunBitExactnessTest(16000, 1, GainControl::Mode::kFixedDigital, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Stereo16kHz_FixedDigital_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Stereo16kHz_FixedDigital_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.048896f, -0.028479f, -0.050345f, -0.048896f, -0.028479f, -0.050345f}; RunBitExactnessTest(16000, 2, GainControl::Mode::kFixedDigital, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono32kHz_FixedDigital_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono32kHz_FixedDigital_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.018158f, -0.016357f, -0.014832f}; RunBitExactnessTest(32000, 1, GainControl::Mode::kFixedDigital, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono48kHz_FixedDigital_Tl10_SL50_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono48kHz_FixedDigital_Tl10_SL50_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 50; const float kOutputReference[] = {-0.018158f, -0.016357f, -0.014832f}; RunBitExactnessTest(32000, 1, GainControl::Mode::kFixedDigital, 10, 50, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono16kHz_AdaptiveAnalog_Tl10_SL10_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono16kHz_AdaptiveAnalog_Tl10_SL10_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 12; const float kOutputReference[] = {-0.006561f, -0.004608f, -0.002899f}; RunBitExactnessTest(16000, 1, GainControl::Mode::kAdaptiveAnalog, 10, 10, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono16kHz_AdaptiveAnalog_Tl10_SL100_CG5_Lim_AL70_80) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono16kHz_AdaptiveAnalog_Tl10_SL100_CG5_Lim_AL70_80) { #endif const int kStreamAnalogLevelReference = 100; const float kOutputReference[] = {-0.003998f, -0.002808f, -0.001770f}; RunBitExactnessTest(16000, 1, GainControl::Mode::kAdaptiveAnalog, 10, 100, 5, true, 70, 80, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono16kHz_AdaptiveDigital_Tl10_SL100_CG5_NoLim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono16kHz_AdaptiveDigital_Tl10_SL100_CG5_NoLim_AL0_100) { #endif const int kStreamAnalogLevelReference = 100; const float kOutputReference[] = {-0.004028f, -0.002838f, -0.001770f}; RunBitExactnessTest(16000, 1, GainControl::Mode::kAdaptiveDigital, 10, 100, 5, false, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono16kHz_AdaptiveDigital_Tl40_SL100_CG5_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono16kHz_AdaptiveDigital_Tl40_SL100_CG5_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 100; const float kOutputReference[] = {-0.008728f, -0.006134f, -0.003845f}; RunBitExactnessTest(16000, 1, GainControl::Mode::kAdaptiveDigital, 40, 100, 5, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } #if !(defined(WEBRTC_ARCH_ARM64) || defined(WEBRTC_ARCH_ARM) || \ defined(WEBRTC_ANDROID)) TEST(GainControlBitExactnessTest, Mono16kHz_AdaptiveDigital_Tl10_SL100_CG30_Lim_AL0_100) { #else TEST(GainControlBitExactnessTest, DISABLED_Mono16kHz_AdaptiveDigital_Tl10_SL100_CG30_Lim_AL0_100) { #endif const int kStreamAnalogLevelReference = 100; const float kOutputReference[] = {-0.005859f, -0.004120f, -0.002594f}; RunBitExactnessTest(16000, 1, GainControl::Mode::kAdaptiveDigital, 10, 100, 30, true, 0, 100, kStreamAnalogLevelReference, kOutputReference); } } // namespace webrtc