/* * 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 "modules/audio_processing/aec3/echo_canceller3.h" #include #include #include "absl/strings/string_view.h" #include "modules/audio_processing/aec3/aec3_common.h" #include "modules/audio_processing/high_pass_filter.h" #include "modules/audio_processing/logging/apm_data_dumper.h" #include "rtc_base/experiments/field_trial_parser.h" #include "rtc_base/logging.h" #include "system_wrappers/include/field_trial.h" namespace webrtc { namespace { enum class EchoCanceller3ApiCall { kCapture, kRender }; bool DetectSaturation(rtc::ArrayView y) { for (size_t k = 0; k < y.size(); ++k) { if (y[k] >= 32700.0f || y[k] <= -32700.0f) { return true; } } return false; } // Retrieves a value from a field trial if it is available. If no value is // present, the default value is returned. If the retrieved value is beyond the // specified limits, the default value is returned instead. void RetrieveFieldTrialValue(absl::string_view trial_name, float min, float max, float* value_to_update) { const std::string field_trial_str = field_trial::FindFullName(trial_name); FieldTrialParameter field_trial_param(/*key=*/"", *value_to_update); ParseFieldTrial({&field_trial_param}, field_trial_str); float field_trial_value = static_cast(field_trial_param.Get()); if (field_trial_value >= min && field_trial_value <= max && field_trial_value != *value_to_update) { RTC_LOG(LS_INFO) << "Key " << trial_name << " changing AEC3 parameter value from " << *value_to_update << " to " << field_trial_value; *value_to_update = field_trial_value; } } void RetrieveFieldTrialValue(absl::string_view trial_name, int min, int max, int* value_to_update) { const std::string field_trial_str = field_trial::FindFullName(trial_name); FieldTrialParameter field_trial_param(/*key=*/"", *value_to_update); ParseFieldTrial({&field_trial_param}, field_trial_str); float field_trial_value = field_trial_param.Get(); if (field_trial_value >= min && field_trial_value <= max && field_trial_value != *value_to_update) { RTC_LOG(LS_INFO) << "Key " << trial_name << " changing AEC3 parameter value from " << *value_to_update << " to " << field_trial_value; *value_to_update = field_trial_value; } } void FillSubFrameView( AudioBuffer* frame, size_t sub_frame_index, std::vector>>* sub_frame_view) { RTC_DCHECK_GE(1, sub_frame_index); RTC_DCHECK_LE(0, sub_frame_index); RTC_DCHECK_EQ(frame->num_bands(), sub_frame_view->size()); RTC_DCHECK_EQ(frame->num_channels(), (*sub_frame_view)[0].size()); for (size_t band = 0; band < sub_frame_view->size(); ++band) { for (size_t channel = 0; channel < (*sub_frame_view)[0].size(); ++channel) { (*sub_frame_view)[band][channel] = rtc::ArrayView( &frame->split_bands(channel)[band][sub_frame_index * kSubFrameLength], kSubFrameLength); } } } void FillSubFrameView( bool proper_downmix_needed, std::vector>>* frame, size_t sub_frame_index, std::vector>>* sub_frame_view) { RTC_DCHECK_GE(1, sub_frame_index); RTC_DCHECK_EQ(frame->size(), sub_frame_view->size()); const size_t frame_num_channels = (*frame)[0].size(); const size_t sub_frame_num_channels = (*sub_frame_view)[0].size(); if (frame_num_channels > sub_frame_num_channels) { RTC_DCHECK_EQ(sub_frame_num_channels, 1u); if (proper_downmix_needed) { // When a proper downmix is needed (which is the case when proper stereo // is present in the echo reference signal but the echo canceller does the // processing in mono) downmix the echo reference by averaging the channel // content (otherwise downmixing is done by selecting channel 0). for (size_t band = 0; band < frame->size(); ++band) { for (size_t ch = 1; ch < frame_num_channels; ++ch) { for (size_t k = 0; k < kSubFrameLength; ++k) { (*frame)[band][/*channel=*/0] [sub_frame_index * kSubFrameLength + k] += (*frame)[band][ch][sub_frame_index * kSubFrameLength + k]; } } const float one_by_num_channels = 1.0f / frame_num_channels; for (size_t k = 0; k < kSubFrameLength; ++k) { (*frame)[band][/*channel=*/0][sub_frame_index * kSubFrameLength + k] *= one_by_num_channels; } } } for (size_t band = 0; band < frame->size(); ++band) { (*sub_frame_view)[band][/*channel=*/0] = rtc::ArrayView( &(*frame)[band][/*channel=*/0][sub_frame_index * kSubFrameLength], kSubFrameLength); } } else { RTC_DCHECK_EQ(frame_num_channels, sub_frame_num_channels); for (size_t band = 0; band < frame->size(); ++band) { for (size_t channel = 0; channel < (*frame)[band].size(); ++channel) { (*sub_frame_view)[band][channel] = rtc::ArrayView( &(*frame)[band][channel][sub_frame_index * kSubFrameLength], kSubFrameLength); } } } } void ProcessCaptureFrameContent( AudioBuffer* linear_output, AudioBuffer* capture, bool level_change, bool aec_reference_is_downmixed_stereo, bool saturated_microphone_signal, size_t sub_frame_index, FrameBlocker* capture_blocker, BlockFramer* linear_output_framer, BlockFramer* output_framer, BlockProcessor* block_processor, Block* linear_output_block, std::vector>>* linear_output_sub_frame_view, Block* capture_block, std::vector>>* capture_sub_frame_view) { FillSubFrameView(capture, sub_frame_index, capture_sub_frame_view); if (linear_output) { RTC_DCHECK(linear_output_framer); RTC_DCHECK(linear_output_block); RTC_DCHECK(linear_output_sub_frame_view); FillSubFrameView(linear_output, sub_frame_index, linear_output_sub_frame_view); } capture_blocker->InsertSubFrameAndExtractBlock(*capture_sub_frame_view, capture_block); block_processor->ProcessCapture( /*echo_path_gain_change=*/level_change || aec_reference_is_downmixed_stereo, saturated_microphone_signal, linear_output_block, capture_block); output_framer->InsertBlockAndExtractSubFrame(*capture_block, capture_sub_frame_view); if (linear_output) { RTC_DCHECK(linear_output_framer); linear_output_framer->InsertBlockAndExtractSubFrame( *linear_output_block, linear_output_sub_frame_view); } } void ProcessRemainingCaptureFrameContent(bool level_change, bool aec_reference_is_downmixed_stereo, bool saturated_microphone_signal, FrameBlocker* capture_blocker, BlockFramer* linear_output_framer, BlockFramer* output_framer, BlockProcessor* block_processor, Block* linear_output_block, Block* block) { if (!capture_blocker->IsBlockAvailable()) { return; } capture_blocker->ExtractBlock(block); block_processor->ProcessCapture( /*echo_path_gain_change=*/level_change || aec_reference_is_downmixed_stereo, saturated_microphone_signal, linear_output_block, block); output_framer->InsertBlock(*block); if (linear_output_framer) { RTC_DCHECK(linear_output_block); linear_output_framer->InsertBlock(*linear_output_block); } } void BufferRenderFrameContent( bool proper_downmix_needed, std::vector>>* render_frame, size_t sub_frame_index, FrameBlocker* render_blocker, BlockProcessor* block_processor, Block* block, std::vector>>* sub_frame_view) { FillSubFrameView(proper_downmix_needed, render_frame, sub_frame_index, sub_frame_view); render_blocker->InsertSubFrameAndExtractBlock(*sub_frame_view, block); block_processor->BufferRender(*block); } void BufferRemainingRenderFrameContent(FrameBlocker* render_blocker, BlockProcessor* block_processor, Block* block) { if (!render_blocker->IsBlockAvailable()) { return; } render_blocker->ExtractBlock(block); block_processor->BufferRender(*block); } void CopyBufferIntoFrame(const AudioBuffer& buffer, size_t num_bands, size_t num_channels, std::vector>>* frame) { RTC_DCHECK_EQ(num_bands, frame->size()); RTC_DCHECK_EQ(num_channels, (*frame)[0].size()); RTC_DCHECK_EQ(AudioBuffer::kSplitBandSize, (*frame)[0][0].size()); for (size_t band = 0; band < num_bands; ++band) { for (size_t channel = 0; channel < num_channels; ++channel) { rtc::ArrayView buffer_view( &buffer.split_bands_const(channel)[band][0], AudioBuffer::kSplitBandSize); std::copy(buffer_view.begin(), buffer_view.end(), (*frame)[band][channel].begin()); } } } } // namespace // TODO(webrtc:5298): Move this to a separate file. EchoCanceller3Config AdjustConfig(const EchoCanceller3Config& config) { EchoCanceller3Config adjusted_cfg = config; if (field_trial::IsEnabled("WebRTC-Aec3StereoContentDetectionKillSwitch")) { adjusted_cfg.multi_channel.detect_stereo_content = false; } if (field_trial::IsEnabled("WebRTC-Aec3AntiHowlingMinimizationKillSwitch")) { adjusted_cfg.suppressor.high_bands_suppression .anti_howling_activation_threshold = 25.f; adjusted_cfg.suppressor.high_bands_suppression.anti_howling_gain = 0.01f; } if (field_trial::IsEnabled("WebRTC-Aec3UseShortConfigChangeDuration")) { adjusted_cfg.filter.config_change_duration_blocks = 10; } if (field_trial::IsEnabled("WebRTC-Aec3UseZeroInitialStateDuration")) { adjusted_cfg.filter.initial_state_seconds = 0.f; } else if (field_trial::IsEnabled( "WebRTC-Aec3UseDot1SecondsInitialStateDuration")) { adjusted_cfg.filter.initial_state_seconds = .1f; } else if (field_trial::IsEnabled( "WebRTC-Aec3UseDot2SecondsInitialStateDuration")) { adjusted_cfg.filter.initial_state_seconds = .2f; } else if (field_trial::IsEnabled( "WebRTC-Aec3UseDot3SecondsInitialStateDuration")) { adjusted_cfg.filter.initial_state_seconds = .3f; } else if (field_trial::IsEnabled( "WebRTC-Aec3UseDot6SecondsInitialStateDuration")) { adjusted_cfg.filter.initial_state_seconds = .6f; } else if (field_trial::IsEnabled( "WebRTC-Aec3UseDot9SecondsInitialStateDuration")) { adjusted_cfg.filter.initial_state_seconds = .9f; } else if (field_trial::IsEnabled( "WebRTC-Aec3Use1Dot2SecondsInitialStateDuration")) { adjusted_cfg.filter.initial_state_seconds = 1.2f; } else if (field_trial::IsEnabled( "WebRTC-Aec3Use1Dot6SecondsInitialStateDuration")) { adjusted_cfg.filter.initial_state_seconds = 1.6f; } else if (field_trial::IsEnabled( "WebRTC-Aec3Use2Dot0SecondsInitialStateDuration")) { adjusted_cfg.filter.initial_state_seconds = 2.0f; } if (field_trial::IsEnabled("WebRTC-Aec3HighPassFilterEchoReference")) { adjusted_cfg.filter.high_pass_filter_echo_reference = true; } if (field_trial::IsEnabled("WebRTC-Aec3EchoSaturationDetectionKillSwitch")) { adjusted_cfg.ep_strength.echo_can_saturate = false; } const std::string use_nearend_reverb_len_tunings = field_trial::FindFullName("WebRTC-Aec3UseNearendReverbLen"); FieldTrialParameter nearend_reverb_default_len( "default_len", adjusted_cfg.ep_strength.default_len); FieldTrialParameter nearend_reverb_nearend_len( "nearend_len", adjusted_cfg.ep_strength.nearend_len); ParseFieldTrial({&nearend_reverb_default_len, &nearend_reverb_nearend_len}, use_nearend_reverb_len_tunings); float default_len = static_cast(nearend_reverb_default_len.Get()); float nearend_len = static_cast(nearend_reverb_nearend_len.Get()); if (default_len > -1 && default_len < 1 && nearend_len > -1 && nearend_len < 1) { adjusted_cfg.ep_strength.default_len = static_cast(nearend_reverb_default_len.Get()); adjusted_cfg.ep_strength.nearend_len = static_cast(nearend_reverb_nearend_len.Get()); } if (field_trial::IsEnabled("WebRTC-Aec3ConservativeTailFreqResponse")) { adjusted_cfg.ep_strength.use_conservative_tail_frequency_response = true; } if (field_trial::IsDisabled("WebRTC-Aec3ConservativeTailFreqResponse")) { adjusted_cfg.ep_strength.use_conservative_tail_frequency_response = false; } if (field_trial::IsEnabled("WebRTC-Aec3ShortHeadroomKillSwitch")) { // Two blocks headroom. adjusted_cfg.delay.delay_headroom_samples = kBlockSize * 2; } if (field_trial::IsEnabled("WebRTC-Aec3ClampInstQualityToZeroKillSwitch")) { adjusted_cfg.erle.clamp_quality_estimate_to_zero = false; } if (field_trial::IsEnabled("WebRTC-Aec3ClampInstQualityToOneKillSwitch")) { adjusted_cfg.erle.clamp_quality_estimate_to_one = false; } if (field_trial::IsEnabled("WebRTC-Aec3OnsetDetectionKillSwitch")) { adjusted_cfg.erle.onset_detection = false; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceRenderDelayEstimationDownmixing")) { adjusted_cfg.delay.render_alignment_mixing.downmix = true; adjusted_cfg.delay.render_alignment_mixing.adaptive_selection = false; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceCaptureDelayEstimationDownmixing")) { adjusted_cfg.delay.capture_alignment_mixing.downmix = true; adjusted_cfg.delay.capture_alignment_mixing.adaptive_selection = false; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceCaptureDelayEstimationLeftRightPrioritization")) { adjusted_cfg.delay.capture_alignment_mixing.prefer_first_two_channels = true; } if (field_trial::IsEnabled( "WebRTC-" "Aec3RenderDelayEstimationLeftRightPrioritizationKillSwitch")) { adjusted_cfg.delay.capture_alignment_mixing.prefer_first_two_channels = false; } if (field_trial::IsEnabled("WebRTC-Aec3SensitiveDominantNearendActivation")) { adjusted_cfg.suppressor.dominant_nearend_detection.enr_threshold = 0.5f; } else if (field_trial::IsEnabled( "WebRTC-Aec3VerySensitiveDominantNearendActivation")) { adjusted_cfg.suppressor.dominant_nearend_detection.enr_threshold = 0.75f; } if (field_trial::IsEnabled("WebRTC-Aec3TransparentAntiHowlingGain")) { adjusted_cfg.suppressor.high_bands_suppression.anti_howling_gain = 1.f; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceMoreTransparentNormalSuppressorTuning")) { adjusted_cfg.suppressor.normal_tuning.mask_lf.enr_transparent = 0.4f; adjusted_cfg.suppressor.normal_tuning.mask_lf.enr_suppress = 0.5f; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceMoreTransparentNearendSuppressorTuning")) { adjusted_cfg.suppressor.nearend_tuning.mask_lf.enr_transparent = 1.29f; adjusted_cfg.suppressor.nearend_tuning.mask_lf.enr_suppress = 1.3f; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceMoreTransparentNormalSuppressorHfTuning")) { adjusted_cfg.suppressor.normal_tuning.mask_hf.enr_transparent = 0.3f; adjusted_cfg.suppressor.normal_tuning.mask_hf.enr_suppress = 0.4f; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceMoreTransparentNearendSuppressorHfTuning")) { adjusted_cfg.suppressor.nearend_tuning.mask_hf.enr_transparent = 1.09f; adjusted_cfg.suppressor.nearend_tuning.mask_hf.enr_suppress = 1.1f; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceRapidlyAdjustingNormalSuppressorTunings")) { adjusted_cfg.suppressor.normal_tuning.max_inc_factor = 2.5f; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceRapidlyAdjustingNearendSuppressorTunings")) { adjusted_cfg.suppressor.nearend_tuning.max_inc_factor = 2.5f; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceSlowlyAdjustingNormalSuppressorTunings")) { adjusted_cfg.suppressor.normal_tuning.max_dec_factor_lf = .2f; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceSlowlyAdjustingNearendSuppressorTunings")) { adjusted_cfg.suppressor.nearend_tuning.max_dec_factor_lf = .2f; } if (field_trial::IsEnabled("WebRTC-Aec3EnforceConservativeHfSuppression")) { adjusted_cfg.suppressor.conservative_hf_suppression = true; } if (field_trial::IsEnabled("WebRTC-Aec3EnforceStationarityProperties")) { adjusted_cfg.echo_audibility.use_stationarity_properties = true; } if (field_trial::IsEnabled( "WebRTC-Aec3EnforceStationarityPropertiesAtInit")) { adjusted_cfg.echo_audibility.use_stationarity_properties_at_init = true; } if (field_trial::IsEnabled("WebRTC-Aec3EnforceLowActiveRenderLimit")) { adjusted_cfg.render_levels.active_render_limit = 50.f; } else if (field_trial::IsEnabled( "WebRTC-Aec3EnforceVeryLowActiveRenderLimit")) { adjusted_cfg.render_levels.active_render_limit = 30.f; } if (field_trial::IsEnabled("WebRTC-Aec3NonlinearModeReverbKillSwitch")) { adjusted_cfg.echo_model.model_reverb_in_nonlinear_mode = false; } // Field-trial based override for the whole suppressor tuning. const std::string suppressor_tuning_override_trial_name = field_trial::FindFullName("WebRTC-Aec3SuppressorTuningOverride"); FieldTrialParameter nearend_tuning_mask_lf_enr_transparent( "nearend_tuning_mask_lf_enr_transparent", adjusted_cfg.suppressor.nearend_tuning.mask_lf.enr_transparent); FieldTrialParameter nearend_tuning_mask_lf_enr_suppress( "nearend_tuning_mask_lf_enr_suppress", adjusted_cfg.suppressor.nearend_tuning.mask_lf.enr_suppress); FieldTrialParameter nearend_tuning_mask_hf_enr_transparent( "nearend_tuning_mask_hf_enr_transparent", adjusted_cfg.suppressor.nearend_tuning.mask_hf.enr_transparent); FieldTrialParameter nearend_tuning_mask_hf_enr_suppress( "nearend_tuning_mask_hf_enr_suppress", adjusted_cfg.suppressor.nearend_tuning.mask_hf.enr_suppress); FieldTrialParameter nearend_tuning_max_inc_factor( "nearend_tuning_max_inc_factor", adjusted_cfg.suppressor.nearend_tuning.max_inc_factor); FieldTrialParameter nearend_tuning_max_dec_factor_lf( "nearend_tuning_max_dec_factor_lf", adjusted_cfg.suppressor.nearend_tuning.max_dec_factor_lf); FieldTrialParameter normal_tuning_mask_lf_enr_transparent( "normal_tuning_mask_lf_enr_transparent", adjusted_cfg.suppressor.normal_tuning.mask_lf.enr_transparent); FieldTrialParameter normal_tuning_mask_lf_enr_suppress( "normal_tuning_mask_lf_enr_suppress", adjusted_cfg.suppressor.normal_tuning.mask_lf.enr_suppress); FieldTrialParameter normal_tuning_mask_hf_enr_transparent( "normal_tuning_mask_hf_enr_transparent", adjusted_cfg.suppressor.normal_tuning.mask_hf.enr_transparent); FieldTrialParameter normal_tuning_mask_hf_enr_suppress( "normal_tuning_mask_hf_enr_suppress", adjusted_cfg.suppressor.normal_tuning.mask_hf.enr_suppress); FieldTrialParameter normal_tuning_max_inc_factor( "normal_tuning_max_inc_factor", adjusted_cfg.suppressor.normal_tuning.max_inc_factor); FieldTrialParameter normal_tuning_max_dec_factor_lf( "normal_tuning_max_dec_factor_lf", adjusted_cfg.suppressor.normal_tuning.max_dec_factor_lf); FieldTrialParameter dominant_nearend_detection_enr_threshold( "dominant_nearend_detection_enr_threshold", adjusted_cfg.suppressor.dominant_nearend_detection.enr_threshold); FieldTrialParameter dominant_nearend_detection_enr_exit_threshold( "dominant_nearend_detection_enr_exit_threshold", adjusted_cfg.suppressor.dominant_nearend_detection.enr_exit_threshold); FieldTrialParameter dominant_nearend_detection_snr_threshold( "dominant_nearend_detection_snr_threshold", adjusted_cfg.suppressor.dominant_nearend_detection.snr_threshold); FieldTrialParameter dominant_nearend_detection_hold_duration( "dominant_nearend_detection_hold_duration", adjusted_cfg.suppressor.dominant_nearend_detection.hold_duration); FieldTrialParameter dominant_nearend_detection_trigger_threshold( "dominant_nearend_detection_trigger_threshold", adjusted_cfg.suppressor.dominant_nearend_detection.trigger_threshold); ParseFieldTrial( {&nearend_tuning_mask_lf_enr_transparent, &nearend_tuning_mask_lf_enr_suppress, &nearend_tuning_mask_hf_enr_transparent, &nearend_tuning_mask_hf_enr_suppress, &nearend_tuning_max_inc_factor, &nearend_tuning_max_dec_factor_lf, &normal_tuning_mask_lf_enr_transparent, &normal_tuning_mask_lf_enr_suppress, &normal_tuning_mask_hf_enr_transparent, &normal_tuning_mask_hf_enr_suppress, &normal_tuning_max_inc_factor, &normal_tuning_max_dec_factor_lf, &dominant_nearend_detection_enr_threshold, &dominant_nearend_detection_enr_exit_threshold, &dominant_nearend_detection_snr_threshold, &dominant_nearend_detection_hold_duration, &dominant_nearend_detection_trigger_threshold}, suppressor_tuning_override_trial_name); adjusted_cfg.suppressor.nearend_tuning.mask_lf.enr_transparent = static_cast(nearend_tuning_mask_lf_enr_transparent.Get()); adjusted_cfg.suppressor.nearend_tuning.mask_lf.enr_suppress = static_cast(nearend_tuning_mask_lf_enr_suppress.Get()); adjusted_cfg.suppressor.nearend_tuning.mask_hf.enr_transparent = static_cast(nearend_tuning_mask_hf_enr_transparent.Get()); adjusted_cfg.suppressor.nearend_tuning.mask_hf.enr_suppress = static_cast(nearend_tuning_mask_hf_enr_suppress.Get()); adjusted_cfg.suppressor.nearend_tuning.max_inc_factor = static_cast(nearend_tuning_max_inc_factor.Get()); adjusted_cfg.suppressor.nearend_tuning.max_dec_factor_lf = static_cast(nearend_tuning_max_dec_factor_lf.Get()); adjusted_cfg.suppressor.normal_tuning.mask_lf.enr_transparent = static_cast(normal_tuning_mask_lf_enr_transparent.Get()); adjusted_cfg.suppressor.normal_tuning.mask_lf.enr_suppress = static_cast(normal_tuning_mask_lf_enr_suppress.Get()); adjusted_cfg.suppressor.normal_tuning.mask_hf.enr_transparent = static_cast(normal_tuning_mask_hf_enr_transparent.Get()); adjusted_cfg.suppressor.normal_tuning.mask_hf.enr_suppress = static_cast(normal_tuning_mask_hf_enr_suppress.Get()); adjusted_cfg.suppressor.normal_tuning.max_inc_factor = static_cast(normal_tuning_max_inc_factor.Get()); adjusted_cfg.suppressor.normal_tuning.max_dec_factor_lf = static_cast(normal_tuning_max_dec_factor_lf.Get()); adjusted_cfg.suppressor.dominant_nearend_detection.enr_threshold = static_cast(dominant_nearend_detection_enr_threshold.Get()); adjusted_cfg.suppressor.dominant_nearend_detection.enr_exit_threshold = static_cast(dominant_nearend_detection_enr_exit_threshold.Get()); adjusted_cfg.suppressor.dominant_nearend_detection.snr_threshold = static_cast(dominant_nearend_detection_snr_threshold.Get()); adjusted_cfg.suppressor.dominant_nearend_detection.hold_duration = dominant_nearend_detection_hold_duration.Get(); adjusted_cfg.suppressor.dominant_nearend_detection.trigger_threshold = dominant_nearend_detection_trigger_threshold.Get(); // Field trial-based overrides of individual suppressor parameters. RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNearendLfMaskTransparentOverride", 0.f, 10.f, &adjusted_cfg.suppressor.nearend_tuning.mask_lf.enr_transparent); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNearendLfMaskSuppressOverride", 0.f, 10.f, &adjusted_cfg.suppressor.nearend_tuning.mask_lf.enr_suppress); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNearendHfMaskTransparentOverride", 0.f, 10.f, &adjusted_cfg.suppressor.nearend_tuning.mask_hf.enr_transparent); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNearendHfMaskSuppressOverride", 0.f, 10.f, &adjusted_cfg.suppressor.nearend_tuning.mask_hf.enr_suppress); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNearendMaxIncFactorOverride", 0.f, 10.f, &adjusted_cfg.suppressor.nearend_tuning.max_inc_factor); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNearendMaxDecFactorLfOverride", 0.f, 10.f, &adjusted_cfg.suppressor.nearend_tuning.max_dec_factor_lf); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNormalLfMaskTransparentOverride", 0.f, 10.f, &adjusted_cfg.suppressor.normal_tuning.mask_lf.enr_transparent); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNormalLfMaskSuppressOverride", 0.f, 10.f, &adjusted_cfg.suppressor.normal_tuning.mask_lf.enr_suppress); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNormalHfMaskTransparentOverride", 0.f, 10.f, &adjusted_cfg.suppressor.normal_tuning.mask_hf.enr_transparent); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNormalHfMaskSuppressOverride", 0.f, 10.f, &adjusted_cfg.suppressor.normal_tuning.mask_hf.enr_suppress); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNormalMaxIncFactorOverride", 0.f, 10.f, &adjusted_cfg.suppressor.normal_tuning.max_inc_factor); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorNormalMaxDecFactorLfOverride", 0.f, 10.f, &adjusted_cfg.suppressor.normal_tuning.max_dec_factor_lf); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorDominantNearendEnrThresholdOverride", 0.f, 100.f, &adjusted_cfg.suppressor.dominant_nearend_detection.enr_threshold); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorDominantNearendEnrExitThresholdOverride", 0.f, 100.f, &adjusted_cfg.suppressor.dominant_nearend_detection.enr_exit_threshold); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorDominantNearendSnrThresholdOverride", 0.f, 100.f, &adjusted_cfg.suppressor.dominant_nearend_detection.snr_threshold); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorDominantNearendHoldDurationOverride", 0, 1000, &adjusted_cfg.suppressor.dominant_nearend_detection.hold_duration); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorDominantNearendTriggerThresholdOverride", 0, 1000, &adjusted_cfg.suppressor.dominant_nearend_detection.trigger_threshold); RetrieveFieldTrialValue( "WebRTC-Aec3SuppressorAntiHowlingGainOverride", 0.f, 10.f, &adjusted_cfg.suppressor.high_bands_suppression.anti_howling_gain); // Field trial-based overrides of individual delay estimator parameters. RetrieveFieldTrialValue("WebRTC-Aec3DelayEstimateSmoothingOverride", 0.f, 1.f, &adjusted_cfg.delay.delay_estimate_smoothing); RetrieveFieldTrialValue( "WebRTC-Aec3DelayEstimateSmoothingDelayFoundOverride", 0.f, 1.f, &adjusted_cfg.delay.delay_estimate_smoothing_delay_found); int max_allowed_excess_render_blocks_override = adjusted_cfg.buffering.max_allowed_excess_render_blocks; RetrieveFieldTrialValue( "WebRTC-Aec3BufferingMaxAllowedExcessRenderBlocksOverride", 0, 20, &max_allowed_excess_render_blocks_override); adjusted_cfg.buffering.max_allowed_excess_render_blocks = max_allowed_excess_render_blocks_override; return adjusted_cfg; } class EchoCanceller3::RenderWriter { public: RenderWriter(ApmDataDumper* data_dumper, const EchoCanceller3Config& config, SwapQueue>>, Aec3RenderQueueItemVerifier>* render_transfer_queue, size_t num_bands, size_t num_channels); RenderWriter() = delete; RenderWriter(const RenderWriter&) = delete; RenderWriter& operator=(const RenderWriter&) = delete; ~RenderWriter(); void Insert(const AudioBuffer& input); private: ApmDataDumper* data_dumper_; const size_t num_bands_; const size_t num_channels_; std::unique_ptr high_pass_filter_; std::vector>> render_queue_input_frame_; SwapQueue>>, Aec3RenderQueueItemVerifier>* render_transfer_queue_; }; EchoCanceller3::RenderWriter::RenderWriter( ApmDataDumper* data_dumper, const EchoCanceller3Config& config, SwapQueue>>, Aec3RenderQueueItemVerifier>* render_transfer_queue, size_t num_bands, size_t num_channels) : data_dumper_(data_dumper), num_bands_(num_bands), num_channels_(num_channels), render_queue_input_frame_( num_bands_, std::vector>( num_channels_, std::vector(AudioBuffer::kSplitBandSize, 0.f))), render_transfer_queue_(render_transfer_queue) { RTC_DCHECK(data_dumper); if (config.filter.high_pass_filter_echo_reference) { high_pass_filter_ = std::make_unique(16000, num_channels); } } EchoCanceller3::RenderWriter::~RenderWriter() = default; void EchoCanceller3::RenderWriter::Insert(const AudioBuffer& input) { RTC_DCHECK_EQ(AudioBuffer::kSplitBandSize, input.num_frames_per_band()); RTC_DCHECK_EQ(num_bands_, input.num_bands()); RTC_DCHECK_EQ(num_channels_, input.num_channels()); // TODO(bugs.webrtc.org/8759) Temporary work-around. if (num_bands_ != input.num_bands()) return; data_dumper_->DumpWav("aec3_render_input", AudioBuffer::kSplitBandSize, &input.split_bands_const(0)[0][0], 16000, 1); CopyBufferIntoFrame(input, num_bands_, num_channels_, &render_queue_input_frame_); if (high_pass_filter_) { high_pass_filter_->Process(&render_queue_input_frame_[0]); } static_cast(render_transfer_queue_->Insert(&render_queue_input_frame_)); } std::atomic EchoCanceller3::instance_count_(0); EchoCanceller3::EchoCanceller3( const EchoCanceller3Config& config, const absl::optional& multichannel_config, int sample_rate_hz, size_t num_render_channels, size_t num_capture_channels) : data_dumper_(new ApmDataDumper(instance_count_.fetch_add(1) + 1)), config_(AdjustConfig(config)), sample_rate_hz_(sample_rate_hz), num_bands_(NumBandsForRate(sample_rate_hz_)), num_render_input_channels_(num_render_channels), num_capture_channels_(num_capture_channels), config_selector_(AdjustConfig(config), multichannel_config, num_render_input_channels_), multichannel_content_detector_( config_selector_.active_config().multi_channel.detect_stereo_content, num_render_input_channels_, config_selector_.active_config() .multi_channel.stereo_detection_threshold, config_selector_.active_config() .multi_channel.stereo_detection_timeout_threshold_seconds, config_selector_.active_config() .multi_channel.stereo_detection_hysteresis_seconds), output_framer_(num_bands_, num_capture_channels_), capture_blocker_(num_bands_, num_capture_channels_), render_transfer_queue_( kRenderTransferQueueSizeFrames, std::vector>>( num_bands_, std::vector>( num_render_input_channels_, std::vector(AudioBuffer::kSplitBandSize, 0.f))), Aec3RenderQueueItemVerifier(num_bands_, num_render_input_channels_, AudioBuffer::kSplitBandSize)), render_queue_output_frame_( num_bands_, std::vector>( num_render_input_channels_, std::vector(AudioBuffer::kSplitBandSize, 0.f))), render_block_(num_bands_, num_render_input_channels_), capture_block_(num_bands_, num_capture_channels_), capture_sub_frame_view_( num_bands_, std::vector>(num_capture_channels_)) { RTC_DCHECK(ValidFullBandRate(sample_rate_hz_)); if (config_selector_.active_config().delay.fixed_capture_delay_samples > 0) { block_delay_buffer_.reset(new BlockDelayBuffer( num_capture_channels_, num_bands_, AudioBuffer::kSplitBandSize, config_.delay.fixed_capture_delay_samples)); } render_writer_.reset(new RenderWriter( data_dumper_.get(), config_selector_.active_config(), &render_transfer_queue_, num_bands_, num_render_input_channels_)); RTC_DCHECK_EQ(num_bands_, std::max(sample_rate_hz_, 16000) / 16000); RTC_DCHECK_GE(kMaxNumBands, num_bands_); if (config_selector_.active_config().filter.export_linear_aec_output) { linear_output_framer_.reset( new BlockFramer(/*num_bands=*/1, num_capture_channels_)); linear_output_block_ = std::make_unique(/*num_bands=*/1, num_capture_channels_), linear_output_sub_frame_view_ = std::vector>>( 1, std::vector>(num_capture_channels_)); } Initialize(); RTC_LOG(LS_INFO) << "AEC3 created with sample rate: " << sample_rate_hz_ << " Hz, num render channels: " << num_render_input_channels_ << ", num capture channels: " << num_capture_channels_; } EchoCanceller3::~EchoCanceller3() = default; void EchoCanceller3::Initialize() { RTC_DCHECK_RUNS_SERIALIZED(&capture_race_checker_); num_render_channels_to_aec_ = multichannel_content_detector_.IsProperMultiChannelContentDetected() ? num_render_input_channels_ : 1; config_selector_.Update( multichannel_content_detector_.IsProperMultiChannelContentDetected()); render_block_.SetNumChannels(num_render_channels_to_aec_); render_blocker_.reset( new FrameBlocker(num_bands_, num_render_channels_to_aec_)); block_processor_.reset(BlockProcessor::Create( config_selector_.active_config(), sample_rate_hz_, num_render_channels_to_aec_, num_capture_channels_)); render_sub_frame_view_ = std::vector>>( num_bands_, std::vector>(num_render_channels_to_aec_)); } void EchoCanceller3::AnalyzeRender(const AudioBuffer& render) { RTC_DCHECK_RUNS_SERIALIZED(&render_race_checker_); RTC_DCHECK_EQ(render.num_channels(), num_render_input_channels_); data_dumper_->DumpRaw("aec3_call_order", static_cast(EchoCanceller3ApiCall::kRender)); return render_writer_->Insert(render); } void EchoCanceller3::AnalyzeCapture(const AudioBuffer& capture) { RTC_DCHECK_RUNS_SERIALIZED(&capture_race_checker_); data_dumper_->DumpWav("aec3_capture_analyze_input", capture.num_frames(), capture.channels_const()[0], sample_rate_hz_, 1); saturated_microphone_signal_ = false; for (size_t channel = 0; channel < capture.num_channels(); ++channel) { saturated_microphone_signal_ |= DetectSaturation(rtc::ArrayView( capture.channels_const()[channel], capture.num_frames())); if (saturated_microphone_signal_) { break; } } } void EchoCanceller3::ProcessCapture(AudioBuffer* capture, bool level_change) { ProcessCapture(capture, nullptr, level_change); } void EchoCanceller3::ProcessCapture(AudioBuffer* capture, AudioBuffer* linear_output, bool level_change) { RTC_DCHECK_RUNS_SERIALIZED(&capture_race_checker_); RTC_DCHECK(capture); RTC_DCHECK_EQ(num_bands_, capture->num_bands()); RTC_DCHECK_EQ(AudioBuffer::kSplitBandSize, capture->num_frames_per_band()); RTC_DCHECK_EQ(capture->num_channels(), num_capture_channels_); data_dumper_->DumpRaw("aec3_call_order", static_cast(EchoCanceller3ApiCall::kCapture)); if (linear_output && !linear_output_framer_) { RTC_LOG(LS_ERROR) << "Trying to retrieve the linear AEC output without " "properly configuring AEC3."; RTC_DCHECK_NOTREACHED(); } // Report capture call in the metrics and periodically update API call // metrics. api_call_metrics_.ReportCaptureCall(); // Optionally delay the capture signal. if (config_selector_.active_config().delay.fixed_capture_delay_samples > 0) { RTC_DCHECK(block_delay_buffer_); block_delay_buffer_->DelaySignal(capture); } rtc::ArrayView capture_lower_band = rtc::ArrayView( &capture->split_bands(0)[0][0], AudioBuffer::kSplitBandSize); data_dumper_->DumpWav("aec3_capture_input", capture_lower_band, 16000, 1); EmptyRenderQueue(); ProcessCaptureFrameContent( linear_output, capture, level_change, multichannel_content_detector_.IsTemporaryMultiChannelContentDetected(), saturated_microphone_signal_, 0, &capture_blocker_, linear_output_framer_.get(), &output_framer_, block_processor_.get(), linear_output_block_.get(), &linear_output_sub_frame_view_, &capture_block_, &capture_sub_frame_view_); ProcessCaptureFrameContent( linear_output, capture, level_change, multichannel_content_detector_.IsTemporaryMultiChannelContentDetected(), saturated_microphone_signal_, 1, &capture_blocker_, linear_output_framer_.get(), &output_framer_, block_processor_.get(), linear_output_block_.get(), &linear_output_sub_frame_view_, &capture_block_, &capture_sub_frame_view_); ProcessRemainingCaptureFrameContent( level_change, multichannel_content_detector_.IsTemporaryMultiChannelContentDetected(), saturated_microphone_signal_, &capture_blocker_, linear_output_framer_.get(), &output_framer_, block_processor_.get(), linear_output_block_.get(), &capture_block_); data_dumper_->DumpWav("aec3_capture_output", AudioBuffer::kSplitBandSize, &capture->split_bands(0)[0][0], 16000, 1); } EchoControl::Metrics EchoCanceller3::GetMetrics() const { RTC_DCHECK_RUNS_SERIALIZED(&capture_race_checker_); Metrics metrics; block_processor_->GetMetrics(&metrics); return metrics; } void EchoCanceller3::SetAudioBufferDelay(int delay_ms) { RTC_DCHECK_RUNS_SERIALIZED(&capture_race_checker_); block_processor_->SetAudioBufferDelay(delay_ms); } void EchoCanceller3::SetCaptureOutputUsage(bool capture_output_used) { RTC_DCHECK_RUNS_SERIALIZED(&capture_race_checker_); block_processor_->SetCaptureOutputUsage(capture_output_used); } bool EchoCanceller3::ActiveProcessing() const { return true; } EchoCanceller3Config EchoCanceller3::CreateDefaultMultichannelConfig() { EchoCanceller3Config cfg; // Use shorter and more rapidly adapting coarse filter to compensate for // thge increased number of total filter parameters to adapt. cfg.filter.coarse.length_blocks = 11; cfg.filter.coarse.rate = 0.95f; cfg.filter.coarse_initial.length_blocks = 11; cfg.filter.coarse_initial.rate = 0.95f; // Use more concervative suppressor behavior for non-nearend speech. cfg.suppressor.normal_tuning.max_dec_factor_lf = 0.35f; cfg.suppressor.normal_tuning.max_inc_factor = 1.5f; return cfg; } void EchoCanceller3::SetBlockProcessorForTesting( std::unique_ptr block_processor) { RTC_DCHECK_RUNS_SERIALIZED(&capture_race_checker_); RTC_DCHECK(block_processor); block_processor_ = std::move(block_processor); } void EchoCanceller3::EmptyRenderQueue() { RTC_DCHECK_RUNS_SERIALIZED(&capture_race_checker_); bool frame_to_buffer = render_transfer_queue_.Remove(&render_queue_output_frame_); while (frame_to_buffer) { // Report render call in the metrics. api_call_metrics_.ReportRenderCall(); if (multichannel_content_detector_.UpdateDetection( render_queue_output_frame_)) { // Reinitialize the AEC when proper stereo is detected. Initialize(); } // Buffer frame content. BufferRenderFrameContent( /*proper_downmix_needed=*/multichannel_content_detector_ .IsTemporaryMultiChannelContentDetected(), &render_queue_output_frame_, 0, render_blocker_.get(), block_processor_.get(), &render_block_, &render_sub_frame_view_); BufferRenderFrameContent( /*proper_downmix_needed=*/multichannel_content_detector_ .IsTemporaryMultiChannelContentDetected(), &render_queue_output_frame_, 1, render_blocker_.get(), block_processor_.get(), &render_block_, &render_sub_frame_view_); BufferRemainingRenderFrameContent(render_blocker_.get(), block_processor_.get(), &render_block_); frame_to_buffer = render_transfer_queue_.Remove(&render_queue_output_frame_); } } } // namespace webrtc