/* * Copyright (c) 2013 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 "modules/audio_processing/agc/agc_manager_direct.h" #include "modules/audio_processing/agc/gain_control.h" #include "modules/audio_processing/agc/mock_agc.h" #include "modules/audio_processing/include/mock_audio_processing.h" #include "test/field_trial.h" #include "test/gmock.h" #include "test/gtest.h" using ::testing::_; using ::testing::AtLeast; using ::testing::DoAll; using ::testing::Return; using ::testing::SetArgPointee; namespace webrtc { namespace { constexpr int kSampleRateHz = 32000; constexpr int kNumChannels = 1; constexpr int kSamplesPerChannel = kSampleRateHz / 100; constexpr int kInitialVolume = 128; constexpr int kClippedMin = 165; // Arbitrary, but different from the default. constexpr float kAboveClippedThreshold = 0.2f; constexpr int kMinMicLevel = 12; constexpr int kClippedLevelStep = 15; constexpr float kClippedRatioThreshold = 0.1f; constexpr int kClippedWaitFrames = 300; using ClippingPredictorConfig = AudioProcessing::Config::GainController1:: AnalogGainController::ClippingPredictor; class MockGainControl : public GainControl { public: virtual ~MockGainControl() {} MOCK_METHOD(int, set_stream_analog_level, (int level), (override)); MOCK_METHOD(int, stream_analog_level, (), (const, override)); MOCK_METHOD(int, set_mode, (Mode mode), (override)); MOCK_METHOD(Mode, mode, (), (const, override)); MOCK_METHOD(int, set_target_level_dbfs, (int level), (override)); MOCK_METHOD(int, target_level_dbfs, (), (const, override)); MOCK_METHOD(int, set_compression_gain_db, (int gain), (override)); MOCK_METHOD(int, compression_gain_db, (), (const, override)); MOCK_METHOD(int, enable_limiter, (bool enable), (override)); MOCK_METHOD(bool, is_limiter_enabled, (), (const, override)); MOCK_METHOD(int, set_analog_level_limits, (int minimum, int maximum), (override)); MOCK_METHOD(int, analog_level_minimum, (), (const, override)); MOCK_METHOD(int, analog_level_maximum, (), (const, override)); MOCK_METHOD(bool, stream_is_saturated, (), (const, override)); }; std::unique_ptr CreateAgcManagerDirect( int startup_min_level, int clipped_level_step, float clipped_ratio_threshold, int clipped_wait_frames) { return std::make_unique( /*num_capture_channels=*/1, startup_min_level, kClippedMin, /*disable_digital_adaptive=*/true, kSampleRateHz, clipped_level_step, clipped_ratio_threshold, clipped_wait_frames, ClippingPredictorConfig()); } std::unique_ptr CreateAgcManagerDirect( int startup_min_level, int clipped_level_step, float clipped_ratio_threshold, int clipped_wait_frames, const ClippingPredictorConfig& clipping_cfg) { return std::make_unique( /*num_capture_channels=*/1, startup_min_level, kClippedMin, /*disable_digital_adaptive=*/true, kSampleRateHz, clipped_level_step, clipped_ratio_threshold, clipped_wait_frames, clipping_cfg); } void CallPreProcessAudioBuffer(int num_calls, float peak_ratio, AgcManagerDirect& manager) { RTC_DCHECK_GE(1.f, peak_ratio); AudioBuffer audio_buffer(kSampleRateHz, 1, kSampleRateHz, 1, kSampleRateHz, 1); const int num_channels = audio_buffer.num_channels(); const int num_frames = audio_buffer.num_frames(); for (int ch = 0; ch < num_channels; ++ch) { for (int i = 0; i < num_frames; i += 2) { audio_buffer.channels()[ch][i] = peak_ratio * 32767.f; audio_buffer.channels()[ch][i + 1] = 0.0f; } } for (int n = 0; n < num_calls / 2; ++n) { manager.AnalyzePreProcess(&audio_buffer); } for (int ch = 0; ch < num_channels; ++ch) { for (int i = 0; i < num_frames; ++i) { audio_buffer.channels()[ch][i] = peak_ratio * 32767.f; } } for (int n = 0; n < num_calls - num_calls / 2; ++n) { manager.AnalyzePreProcess(&audio_buffer); } } } // namespace class AgcManagerDirectTest : public ::testing::Test { protected: AgcManagerDirectTest() : agc_(new MockAgc), manager_(agc_, kInitialVolume, kClippedMin, kSampleRateHz, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames, ClippingPredictorConfig()), audio(kNumChannels), audio_data(kNumChannels * kSamplesPerChannel, 0.f) { ExpectInitialize(); manager_.Initialize(); manager_.SetupDigitalGainControl(&gctrl_); for (size_t ch = 0; ch < kNumChannels; ++ch) { audio[ch] = &audio_data[ch * kSamplesPerChannel]; } } void FirstProcess() { EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); EXPECT_CALL(*agc_, GetRmsErrorDb(_)).WillOnce(Return(false)); CallProcess(1); } void SetVolumeAndProcess(int volume) { manager_.set_stream_analog_level(volume); FirstProcess(); } void ExpectCheckVolumeAndReset(int volume) { manager_.set_stream_analog_level(volume); EXPECT_CALL(*agc_, Reset()); } void ExpectInitialize() { EXPECT_CALL(gctrl_, set_mode(GainControl::kFixedDigital)); EXPECT_CALL(gctrl_, set_target_level_dbfs(2)); EXPECT_CALL(gctrl_, set_compression_gain_db(7)); EXPECT_CALL(gctrl_, enable_limiter(true)); } void CallProcess(int num_calls) { for (int i = 0; i < num_calls; ++i) { EXPECT_CALL(*agc_, Process(_, _, _)).WillOnce(Return()); manager_.Process(nullptr); absl::optional new_digital_gain = manager_.GetDigitalComressionGain(); if (new_digital_gain) { gctrl_.set_compression_gain_db(*new_digital_gain); } } } void CallPreProc(int num_calls, float clipped_ratio) { RTC_DCHECK_GE(1.f, clipped_ratio); const int num_clipped = kSamplesPerChannel * clipped_ratio; std::fill(audio_data.begin(), audio_data.end(), 0.f); for (size_t ch = 0; ch < kNumChannels; ++ch) { for (int k = 0; k < num_clipped; ++k) { audio[ch][k] = 32767.f; } } for (int i = 0; i < num_calls; ++i) { manager_.AnalyzePreProcess(audio.data(), kSamplesPerChannel); } } void CallPreProcForChangingAudio(int num_calls, float peak_ratio) { RTC_DCHECK_GE(1.f, peak_ratio); std::fill(audio_data.begin(), audio_data.end(), 0.f); for (size_t ch = 0; ch < kNumChannels; ++ch) { for (size_t k = 0; k < kSamplesPerChannel; k += 2) { audio[ch][k] = peak_ratio * 32767.f; } } for (int i = 0; i < num_calls / 2; ++i) { manager_.AnalyzePreProcess(audio.data(), kSamplesPerChannel); } for (size_t ch = 0; ch < kNumChannels; ++ch) { for (size_t k = 0; k < kSamplesPerChannel; ++k) { audio[ch][k] = peak_ratio * 32767.f; } } for (int i = 0; i < num_calls - num_calls / 2; ++i) { manager_.AnalyzePreProcess(audio.data(), kSamplesPerChannel); } } MockAgc* agc_; MockGainControl gctrl_; AgcManagerDirect manager_; std::vector audio; std::vector audio_data; }; TEST_F(AgcManagerDirectTest, StartupMinVolumeConfigurationIsRespected) { FirstProcess(); EXPECT_EQ(kInitialVolume, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, MicVolumeResponseToRmsError) { FirstProcess(); // Compressor default; no residual error. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(5), Return(true))); CallProcess(1); // Inside the compressor's window; no change of volume. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(10), Return(true))); CallProcess(1); // Above the compressor's window; volume should be increased. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(11), Return(true))); CallProcess(1); EXPECT_EQ(130, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(20), Return(true))); CallProcess(1); EXPECT_EQ(168, manager_.stream_analog_level()); // Inside the compressor's window; no change of volume. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(5), Return(true))); CallProcess(1); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(0), Return(true))); CallProcess(1); // Below the compressor's window; volume should be decreased. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-1), Return(true))); CallProcess(1); EXPECT_EQ(167, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-1), Return(true))); CallProcess(1); EXPECT_EQ(163, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-9), Return(true))); CallProcess(1); EXPECT_EQ(129, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, MicVolumeIsLimited) { FirstProcess(); // Maximum upwards change is limited. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(30), Return(true))); CallProcess(1); EXPECT_EQ(183, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(30), Return(true))); CallProcess(1); EXPECT_EQ(243, manager_.stream_analog_level()); // Won't go higher than the maximum. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(30), Return(true))); CallProcess(1); EXPECT_EQ(255, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-1), Return(true))); CallProcess(1); EXPECT_EQ(254, manager_.stream_analog_level()); // Maximum downwards change is limited. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-40), Return(true))); CallProcess(1); EXPECT_EQ(194, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-40), Return(true))); CallProcess(1); EXPECT_EQ(137, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-40), Return(true))); CallProcess(1); EXPECT_EQ(88, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-40), Return(true))); CallProcess(1); EXPECT_EQ(54, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-40), Return(true))); CallProcess(1); EXPECT_EQ(33, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-40), Return(true))); CallProcess(1); EXPECT_EQ(18, manager_.stream_analog_level()); // Won't go lower than the minimum. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-40), Return(true))); CallProcess(1); EXPECT_EQ(12, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, CompressorStepsTowardsTarget) { FirstProcess(); // Compressor default; no call to set_compression_gain_db. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(5), Return(true))) .WillRepeatedly(Return(false)); EXPECT_CALL(gctrl_, set_compression_gain_db(_)).Times(0); CallProcess(20); // Moves slowly upwards. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(9), Return(true))) .WillRepeatedly(Return(false)); EXPECT_CALL(gctrl_, set_compression_gain_db(_)).Times(0); CallProcess(19); EXPECT_CALL(gctrl_, set_compression_gain_db(8)).WillOnce(Return(0)); CallProcess(1); EXPECT_CALL(gctrl_, set_compression_gain_db(_)).Times(0); CallProcess(19); EXPECT_CALL(gctrl_, set_compression_gain_db(9)).WillOnce(Return(0)); CallProcess(1); EXPECT_CALL(gctrl_, set_compression_gain_db(_)).Times(0); CallProcess(20); // Moves slowly downward, then reverses before reaching the original target. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(5), Return(true))) .WillRepeatedly(Return(false)); EXPECT_CALL(gctrl_, set_compression_gain_db(_)).Times(0); CallProcess(19); EXPECT_CALL(gctrl_, set_compression_gain_db(8)).WillOnce(Return(0)); CallProcess(1); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(9), Return(true))) .WillRepeatedly(Return(false)); EXPECT_CALL(gctrl_, set_compression_gain_db(_)).Times(0); CallProcess(19); EXPECT_CALL(gctrl_, set_compression_gain_db(9)).WillOnce(Return(0)); CallProcess(1); EXPECT_CALL(gctrl_, set_compression_gain_db(_)).Times(0); CallProcess(20); } TEST_F(AgcManagerDirectTest, CompressorErrorIsDeemphasized) { FirstProcess(); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(10), Return(true))) .WillRepeatedly(Return(false)); CallProcess(19); EXPECT_CALL(gctrl_, set_compression_gain_db(8)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(9)).WillOnce(Return(0)); CallProcess(1); EXPECT_CALL(gctrl_, set_compression_gain_db(_)).Times(0); CallProcess(20); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(0), Return(true))) .WillRepeatedly(Return(false)); CallProcess(19); EXPECT_CALL(gctrl_, set_compression_gain_db(8)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(7)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(6)).WillOnce(Return(0)); CallProcess(1); EXPECT_CALL(gctrl_, set_compression_gain_db(_)).Times(0); CallProcess(20); } TEST_F(AgcManagerDirectTest, CompressorReachesMaximum) { FirstProcess(); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(10), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(10), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(10), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(10), Return(true))) .WillRepeatedly(Return(false)); CallProcess(19); EXPECT_CALL(gctrl_, set_compression_gain_db(8)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(9)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(10)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(11)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(12)).WillOnce(Return(0)); CallProcess(1); } TEST_F(AgcManagerDirectTest, CompressorReachesMinimum) { FirstProcess(); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(0), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(0), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(0), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(0), Return(true))) .WillRepeatedly(Return(false)); CallProcess(19); EXPECT_CALL(gctrl_, set_compression_gain_db(6)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(5)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(4)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(3)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(2)).WillOnce(Return(0)); CallProcess(1); } TEST_F(AgcManagerDirectTest, NoActionWhileMuted) { manager_.HandleCaptureOutputUsedChange(false); manager_.Process(nullptr); absl::optional new_digital_gain = manager_.GetDigitalComressionGain(); if (new_digital_gain) { gctrl_.set_compression_gain_db(*new_digital_gain); } } TEST_F(AgcManagerDirectTest, UnmutingChecksVolumeWithoutRaising) { FirstProcess(); manager_.HandleCaptureOutputUsedChange(false); manager_.HandleCaptureOutputUsedChange(true); ExpectCheckVolumeAndReset(127); // SetMicVolume should not be called. EXPECT_CALL(*agc_, GetRmsErrorDb(_)).WillOnce(Return(false)); CallProcess(1); EXPECT_EQ(127, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, UnmutingRaisesTooLowVolume) { FirstProcess(); manager_.HandleCaptureOutputUsedChange(false); manager_.HandleCaptureOutputUsedChange(true); ExpectCheckVolumeAndReset(11); EXPECT_CALL(*agc_, GetRmsErrorDb(_)).WillOnce(Return(false)); CallProcess(1); EXPECT_EQ(12, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, ManualLevelChangeResultsInNoSetMicCall) { FirstProcess(); // Change outside of compressor's range, which would normally trigger a call // to SetMicVolume. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(11), Return(true))); // When the analog volume changes, the gain controller is reset. EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); // GetMicVolume returns a value outside of the quantization slack, indicating // a manual volume change. ASSERT_NE(manager_.stream_analog_level(), 154); manager_.set_stream_analog_level(154); CallProcess(1); EXPECT_EQ(154, manager_.stream_analog_level()); // Do the same thing, except downwards now. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-1), Return(true))); manager_.set_stream_analog_level(100); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallProcess(1); EXPECT_EQ(100, manager_.stream_analog_level()); // And finally verify the AGC continues working without a manual change. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-1), Return(true))); CallProcess(1); EXPECT_EQ(99, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, RecoveryAfterManualLevelChangeFromMax) { FirstProcess(); // Force the mic up to max volume. Takes a few steps due to the residual // gain limitation. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillRepeatedly(DoAll(SetArgPointee<0>(30), Return(true))); CallProcess(1); EXPECT_EQ(183, manager_.stream_analog_level()); CallProcess(1); EXPECT_EQ(243, manager_.stream_analog_level()); CallProcess(1); EXPECT_EQ(255, manager_.stream_analog_level()); // Manual change does not result in SetMicVolume call. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-1), Return(true))); manager_.set_stream_analog_level(50); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallProcess(1); EXPECT_EQ(50, manager_.stream_analog_level()); // Continues working as usual afterwards. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(20), Return(true))); CallProcess(1); EXPECT_EQ(69, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, RecoveryAfterManualLevelChangeBelowMin) { FirstProcess(); // Manual change below min. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-1), Return(true))); // Don't set to zero, which will cause AGC to take no action. manager_.set_stream_analog_level(1); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallProcess(1); EXPECT_EQ(1, manager_.stream_analog_level()); // Continues working as usual afterwards. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(11), Return(true))); CallProcess(1); EXPECT_EQ(2, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(30), Return(true))); CallProcess(1); EXPECT_EQ(11, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(20), Return(true))); CallProcess(1); EXPECT_EQ(18, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, NoClippingHasNoImpact) { FirstProcess(); CallPreProc(100, 0); EXPECT_EQ(128, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, ClippingUnderThresholdHasNoImpact) { FirstProcess(); CallPreProc(1, 0.099); EXPECT_EQ(128, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, ClippingLowersVolume) { SetVolumeAndProcess(255); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallPreProc(1, 0.2); EXPECT_EQ(240, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, WaitingPeriodBetweenClippingChecks) { SetVolumeAndProcess(255); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallPreProc(1, kAboveClippedThreshold); EXPECT_EQ(240, manager_.stream_analog_level()); EXPECT_CALL(*agc_, Reset()).Times(0); CallPreProc(300, kAboveClippedThreshold); EXPECT_EQ(240, manager_.stream_analog_level()); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallPreProc(1, kAboveClippedThreshold); EXPECT_EQ(225, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, ClippingLoweringIsLimited) { SetVolumeAndProcess(180); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallPreProc(1, kAboveClippedThreshold); EXPECT_EQ(kClippedMin, manager_.stream_analog_level()); EXPECT_CALL(*agc_, Reset()).Times(0); CallPreProc(1000, kAboveClippedThreshold); EXPECT_EQ(kClippedMin, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, ClippingMaxIsRespectedWhenEqualToLevel) { SetVolumeAndProcess(255); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallPreProc(1, kAboveClippedThreshold); EXPECT_EQ(240, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillRepeatedly(DoAll(SetArgPointee<0>(30), Return(true))); CallProcess(10); EXPECT_EQ(240, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, ClippingMaxIsRespectedWhenHigherThanLevel) { SetVolumeAndProcess(200); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallPreProc(1, kAboveClippedThreshold); EXPECT_EQ(185, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillRepeatedly(DoAll(SetArgPointee<0>(40), Return(true))); CallProcess(1); EXPECT_EQ(240, manager_.stream_analog_level()); CallProcess(10); EXPECT_EQ(240, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, MaxCompressionIsIncreasedAfterClipping) { SetVolumeAndProcess(210); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallPreProc(1, kAboveClippedThreshold); EXPECT_EQ(195, manager_.stream_analog_level()); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(11), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(11), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(11), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(11), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(11), Return(true))) .WillRepeatedly(Return(false)); CallProcess(19); EXPECT_CALL(gctrl_, set_compression_gain_db(8)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(9)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(10)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(11)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(12)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(13)).WillOnce(Return(0)); CallProcess(1); // Continue clipping until we hit the maximum surplus compression. CallPreProc(300, kAboveClippedThreshold); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallPreProc(1, kAboveClippedThreshold); EXPECT_EQ(180, manager_.stream_analog_level()); CallPreProc(300, kAboveClippedThreshold); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallPreProc(1, kAboveClippedThreshold); EXPECT_EQ(kClippedMin, manager_.stream_analog_level()); // Current level is now at the minimum, but the maximum allowed level still // has more to decrease. CallPreProc(300, kAboveClippedThreshold); CallPreProc(1, kAboveClippedThreshold); CallPreProc(300, kAboveClippedThreshold); CallPreProc(1, kAboveClippedThreshold); CallPreProc(300, kAboveClippedThreshold); CallPreProc(1, kAboveClippedThreshold); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(16), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(16), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(16), Return(true))) .WillOnce(DoAll(SetArgPointee<0>(16), Return(true))) .WillRepeatedly(Return(false)); CallProcess(19); EXPECT_CALL(gctrl_, set_compression_gain_db(14)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(15)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(16)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(17)).WillOnce(Return(0)); CallProcess(20); EXPECT_CALL(gctrl_, set_compression_gain_db(18)).WillOnce(Return(0)); CallProcess(1); } TEST_F(AgcManagerDirectTest, UserCanRaiseVolumeAfterClipping) { SetVolumeAndProcess(225); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallPreProc(1, kAboveClippedThreshold); EXPECT_EQ(210, manager_.stream_analog_level()); // High enough error to trigger a volume check. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(14), Return(true))); // User changed the volume. manager_.set_stream_analog_level(250); EXPECT_CALL(*agc_, Reset()).Times(AtLeast(1)); CallProcess(1); EXPECT_EQ(250, manager_.stream_analog_level()); // Move down... EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(-10), Return(true))); CallProcess(1); EXPECT_EQ(210, manager_.stream_analog_level()); // And back up to the new max established by the user. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(40), Return(true))); CallProcess(1); EXPECT_EQ(250, manager_.stream_analog_level()); // Will not move above new maximum. EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillOnce(DoAll(SetArgPointee<0>(30), Return(true))); CallProcess(1); EXPECT_EQ(250, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, ClippingDoesNotPullLowVolumeBackUp) { SetVolumeAndProcess(80); EXPECT_CALL(*agc_, Reset()).Times(0); int initial_volume = manager_.stream_analog_level(); CallPreProc(1, kAboveClippedThreshold); EXPECT_EQ(initial_volume, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, TakesNoActionOnZeroMicVolume) { FirstProcess(); EXPECT_CALL(*agc_, GetRmsErrorDb(_)) .WillRepeatedly(DoAll(SetArgPointee<0>(30), Return(true))); manager_.set_stream_analog_level(0); CallProcess(10); EXPECT_EQ(0, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, ClippingDetectionLowersVolume) { SetVolumeAndProcess(255); EXPECT_EQ(255, manager_.stream_analog_level()); CallPreProcForChangingAudio(/*num_calls=*/100, /*peak_ratio=*/0.99f); EXPECT_EQ(255, manager_.stream_analog_level()); CallPreProcForChangingAudio(/*num_calls=*/100, /*peak_ratio=*/1.0f); EXPECT_EQ(240, manager_.stream_analog_level()); } TEST_F(AgcManagerDirectTest, DisabledClippingPredictorDoesNotLowerVolume) { SetVolumeAndProcess(255); EXPECT_FALSE(manager_.clipping_predictor_enabled()); EXPECT_EQ(255, manager_.stream_analog_level()); CallPreProcForChangingAudio(/*num_calls=*/100, /*peak_ratio=*/0.99f); EXPECT_EQ(255, manager_.stream_analog_level()); CallPreProcForChangingAudio(/*num_calls=*/100, /*peak_ratio=*/0.99f); EXPECT_EQ(255, manager_.stream_analog_level()); } TEST(AgcManagerDirectStandaloneTest, DisableDigitalDisablesDigital) { auto agc = std::unique_ptr(new ::testing::NiceMock()); MockGainControl gctrl; EXPECT_CALL(gctrl, set_mode(GainControl::kFixedDigital)); EXPECT_CALL(gctrl, set_target_level_dbfs(0)); EXPECT_CALL(gctrl, set_compression_gain_db(0)); EXPECT_CALL(gctrl, enable_limiter(false)); std::unique_ptr manager = CreateAgcManagerDirect(kInitialVolume, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames); manager->Initialize(); manager->SetupDigitalGainControl(&gctrl); } TEST(AgcManagerDirectStandaloneTest, AgcMinMicLevelExperiment) { std::unique_ptr manager = CreateAgcManagerDirect(kInitialVolume, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames); EXPECT_EQ(manager->channel_agcs_[0]->min_mic_level(), kMinMicLevel); EXPECT_EQ(manager->channel_agcs_[0]->startup_min_level(), kInitialVolume); } TEST(AgcManagerDirectStandaloneTest, AgcMinMicLevelExperimentDisabled) { test::ScopedFieldTrials field_trial( "WebRTC-Audio-AgcMinMicLevelExperiment/Disabled/"); std::unique_ptr manager = CreateAgcManagerDirect(kInitialVolume, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames); EXPECT_EQ(manager->channel_agcs_[0]->min_mic_level(), kMinMicLevel); EXPECT_EQ(manager->channel_agcs_[0]->startup_min_level(), kInitialVolume); } // Checks that a field-trial parameter outside of the valid range [0,255] is // ignored. TEST(AgcManagerDirectStandaloneTest, AgcMinMicLevelExperimentOutOfRangeAbove) { test::ScopedFieldTrials field_trial( "WebRTC-Audio-AgcMinMicLevelExperiment/Enabled-256/"); std::unique_ptr manager = CreateAgcManagerDirect(kInitialVolume, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames); EXPECT_EQ(manager->channel_agcs_[0]->min_mic_level(), kMinMicLevel); EXPECT_EQ(manager->channel_agcs_[0]->startup_min_level(), kInitialVolume); } // Checks that a field-trial parameter outside of the valid range [0,255] is // ignored. TEST(AgcManagerDirectStandaloneTest, AgcMinMicLevelExperimentOutOfRangeBelow) { test::ScopedFieldTrials field_trial( "WebRTC-Audio-AgcMinMicLevelExperiment/Enabled--1/"); std::unique_ptr manager = CreateAgcManagerDirect(kInitialVolume, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames); EXPECT_EQ(manager->channel_agcs_[0]->min_mic_level(), kMinMicLevel); EXPECT_EQ(manager->channel_agcs_[0]->startup_min_level(), kInitialVolume); } // Verifies that a valid experiment changes the minimum microphone level. The // start volume is larger than the min level and should therefore not be // changed. TEST(AgcManagerDirectStandaloneTest, AgcMinMicLevelExperimentEnabled50) { test::ScopedFieldTrials field_trial( "WebRTC-Audio-AgcMinMicLevelExperiment/Enabled-50/"); std::unique_ptr manager = CreateAgcManagerDirect(kInitialVolume, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames); EXPECT_EQ(manager->channel_agcs_[0]->min_mic_level(), 50); EXPECT_EQ(manager->channel_agcs_[0]->startup_min_level(), kInitialVolume); } // Uses experiment to reduce the default minimum microphone level, start at a // lower level and ensure that the startup level is increased to the min level // set by the experiment. TEST(AgcManagerDirectStandaloneTest, AgcMinMicLevelExperimentEnabledAboveStartupLevel) { test::ScopedFieldTrials field_trial( "WebRTC-Audio-AgcMinMicLevelExperiment/Enabled-50/"); std::unique_ptr manager = CreateAgcManagerDirect(/*startup_min_level=*/30, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames); EXPECT_EQ(manager->channel_agcs_[0]->min_mic_level(), 50); EXPECT_EQ(manager->channel_agcs_[0]->startup_min_level(), 50); } // TODO(bugs.webrtc.org/12774): Test the bahavior of `clipped_level_step`. // TODO(bugs.webrtc.org/12774): Test the bahavior of `clipped_ratio_threshold`. // TODO(bugs.webrtc.org/12774): Test the bahavior of `clipped_wait_frames`. // Verifies that configurable clipping parameters are initialized as intended. TEST(AgcManagerDirectStandaloneTest, ClippingParametersVerified) { std::unique_ptr manager = CreateAgcManagerDirect(kInitialVolume, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames); manager->Initialize(); EXPECT_EQ(manager->clipped_level_step_, kClippedLevelStep); EXPECT_EQ(manager->clipped_ratio_threshold_, kClippedRatioThreshold); EXPECT_EQ(manager->clipped_wait_frames_, kClippedWaitFrames); std::unique_ptr manager_custom = CreateAgcManagerDirect(kInitialVolume, /*clipped_level_step=*/10, /*clipped_ratio_threshold=*/0.2f, /*clipped_wait_frames=*/50); manager_custom->Initialize(); EXPECT_EQ(manager_custom->clipped_level_step_, 10); EXPECT_EQ(manager_custom->clipped_ratio_threshold_, 0.2f); EXPECT_EQ(manager_custom->clipped_wait_frames_, 50); } TEST(AgcManagerDirectStandaloneTest, DisableClippingPredictorDisablesClippingPredictor) { ClippingPredictorConfig default_config; EXPECT_FALSE(default_config.enabled); std::unique_ptr manager = CreateAgcManagerDirect( kInitialVolume, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames, default_config); manager->Initialize(); EXPECT_FALSE(manager->clipping_predictor_enabled()); EXPECT_FALSE(manager->use_clipping_predictor_step()); } TEST(AgcManagerDirectStandaloneTest, ClippingPredictorDisabledByDefault) { constexpr ClippingPredictorConfig kDefaultConfig; EXPECT_FALSE(kDefaultConfig.enabled); } TEST(AgcManagerDirectStandaloneTest, EnableClippingPredictorEnablesClippingPredictor) { // TODO(bugs.webrtc.org/12874): Use designated initializers one fixed. ClippingPredictorConfig config; config.enabled = true; config.use_predicted_step = true; std::unique_ptr manager = CreateAgcManagerDirect( kInitialVolume, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames, config); manager->Initialize(); EXPECT_TRUE(manager->clipping_predictor_enabled()); EXPECT_TRUE(manager->use_clipping_predictor_step()); } TEST(AgcManagerDirectStandaloneTest, DisableClippingPredictorDoesNotLowerVolume) { // TODO(bugs.webrtc.org/12874): Use designated initializers one fixed. constexpr ClippingPredictorConfig kConfig{/*enabled=*/false}; AgcManagerDirect manager(new ::testing::NiceMock(), kInitialVolume, kClippedMin, kSampleRateHz, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames, kConfig); manager.Initialize(); manager.set_stream_analog_level(/*level=*/255); EXPECT_FALSE(manager.clipping_predictor_enabled()); EXPECT_FALSE(manager.use_clipping_predictor_step()); EXPECT_EQ(manager.stream_analog_level(), 255); manager.Process(nullptr); CallPreProcessAudioBuffer(/*num_calls=*/10, /*peak_ratio=*/0.99f, manager); EXPECT_EQ(manager.stream_analog_level(), 255); CallPreProcessAudioBuffer(/*num_calls=*/300, /*peak_ratio=*/0.99f, manager); EXPECT_EQ(manager.stream_analog_level(), 255); CallPreProcessAudioBuffer(/*num_calls=*/10, /*peak_ratio=*/0.99f, manager); EXPECT_EQ(manager.stream_analog_level(), 255); } TEST(AgcManagerDirectStandaloneTest, EnableClippingPredictorWithUnusedPredictedStepDoesNotLowerVolume) { // TODO(bugs.webrtc.org/12874): Use designated initializers one fixed. ClippingPredictorConfig config; config.enabled = true; config.use_predicted_step = false; AgcManagerDirect manager(new ::testing::NiceMock(), kInitialVolume, kClippedMin, kSampleRateHz, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames, config); manager.Initialize(); manager.set_stream_analog_level(/*level=*/255); EXPECT_TRUE(manager.clipping_predictor_enabled()); EXPECT_FALSE(manager.use_clipping_predictor_step()); EXPECT_EQ(manager.stream_analog_level(), 255); manager.Process(nullptr); CallPreProcessAudioBuffer(/*num_calls=*/10, /*peak_ratio=*/0.99f, manager); EXPECT_EQ(manager.stream_analog_level(), 255); CallPreProcessAudioBuffer(/*num_calls=*/300, /*peak_ratio=*/0.99f, manager); EXPECT_EQ(manager.stream_analog_level(), 255); CallPreProcessAudioBuffer(/*num_calls=*/10, /*peak_ratio=*/0.99f, manager); EXPECT_EQ(manager.stream_analog_level(), 255); } TEST(AgcManagerDirectStandaloneTest, EnableClippingPredictorLowersVolume) { // TODO(bugs.webrtc.org/12874): Use designated initializers one fixed. ClippingPredictorConfig config; config.enabled = true; config.use_predicted_step = true; AgcManagerDirect manager(new ::testing::NiceMock(), kInitialVolume, kClippedMin, kSampleRateHz, kClippedLevelStep, kClippedRatioThreshold, kClippedWaitFrames, config); manager.Initialize(); manager.set_stream_analog_level(/*level=*/255); EXPECT_TRUE(manager.clipping_predictor_enabled()); EXPECT_TRUE(manager.use_clipping_predictor_step()); EXPECT_EQ(manager.stream_analog_level(), 255); manager.Process(nullptr); CallPreProcessAudioBuffer(/*num_calls=*/10, /*peak_ratio=*/0.99f, manager); EXPECT_EQ(manager.stream_analog_level(), 240); CallPreProcessAudioBuffer(/*num_calls=*/300, /*peak_ratio=*/0.99f, manager); EXPECT_EQ(manager.stream_analog_level(), 240); CallPreProcessAudioBuffer(/*num_calls=*/10, /*peak_ratio=*/0.99f, manager); EXPECT_EQ(manager.stream_analog_level(), 225); } } // namespace webrtc