/* * Copyright (c) 2017 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/aec_state.h" #include #include #include #include #include "absl/types/optional.h" #include "api/array_view.h" #include "modules/audio_processing/aec3/aec3_common.h" #include "modules/audio_processing/logging/apm_data_dumper.h" #include "rtc_base/atomic_ops.h" #include "rtc_base/checks.h" #include "system_wrappers/include/field_trial.h" namespace webrtc { namespace { constexpr size_t kBlocksSinceConvergencedFilterInit = 10000; constexpr size_t kBlocksSinceConsistentEstimateInit = 10000; bool DeactivateTransparentMode() { return field_trial::IsEnabled("WebRTC-Aec3TransparentModeKillSwitch"); } bool DeactivateInitialStateResetAtEchoPathChange() { return field_trial::IsEnabled( "WebRTC-Aec3DeactivateInitialStateResetKillSwitch"); } bool FullResetAtEchoPathChange() { return !field_trial::IsEnabled("WebRTC-Aec3AecStateFullResetKillSwitch"); } bool SubtractorAnalyzerResetAtEchoPathChange() { return !field_trial::IsEnabled( "WebRTC-Aec3AecStateSubtractorAnalyzerResetKillSwitch"); } void ComputeAvgRenderReverb( const SpectrumBuffer& spectrum_buffer, int delay_blocks, float reverb_decay, ReverbModel* reverb_model, rtc::ArrayView reverb_power_spectrum) { RTC_DCHECK(reverb_model); const size_t num_render_channels = spectrum_buffer.buffer[0].size(); int idx_at_delay = spectrum_buffer.OffsetIndex(spectrum_buffer.read, delay_blocks); int idx_past = spectrum_buffer.IncIndex(idx_at_delay); std::array X2_data; rtc::ArrayView X2; if (num_render_channels > 1) { auto average_channels = [](size_t num_render_channels, rtc::ArrayView> spectrum_band_0, rtc::ArrayView render_power) { std::fill(render_power.begin(), render_power.end(), 0.f); for (size_t ch = 0; ch < num_render_channels; ++ch) { for (size_t k = 0; k < kFftLengthBy2Plus1; ++k) { render_power[k] += spectrum_band_0[ch][k]; } } const float normalizer = 1.f / num_render_channels; for (size_t k = 0; k < kFftLengthBy2Plus1; ++k) { render_power[k] *= normalizer; } }; average_channels(num_render_channels, spectrum_buffer.buffer[idx_past], X2_data); reverb_model->UpdateReverbNoFreqShaping( X2_data, /*power_spectrum_scaling=*/1.0f, reverb_decay); average_channels(num_render_channels, spectrum_buffer.buffer[idx_at_delay], X2_data); X2 = X2_data; } else { reverb_model->UpdateReverbNoFreqShaping( spectrum_buffer.buffer[idx_past][/*channel=*/0], /*power_spectrum_scaling=*/1.0f, reverb_decay); X2 = spectrum_buffer.buffer[idx_at_delay][/*channel=*/0]; } rtc::ArrayView reverb_power = reverb_model->reverb(); for (size_t k = 0; k < X2.size(); ++k) { reverb_power_spectrum[k] = X2[k] + reverb_power[k]; } } } // namespace int AecState::instance_count_ = 0; void AecState::GetResidualEchoScaling( rtc::ArrayView residual_scaling) const { bool filter_has_had_time_to_converge; if (config_.filter.conservative_initial_phase) { filter_has_had_time_to_converge = strong_not_saturated_render_blocks_ >= 1.5f * kNumBlocksPerSecond; } else { filter_has_had_time_to_converge = strong_not_saturated_render_blocks_ >= 0.8f * kNumBlocksPerSecond; } echo_audibility_.GetResidualEchoScaling(filter_has_had_time_to_converge, residual_scaling); } absl::optional AecState::ErleUncertainty() const { if (SaturatedEcho()) { return 1.f; } return absl::nullopt; } AecState::AecState(const EchoCanceller3Config& config, size_t num_capture_channels) : data_dumper_( new ApmDataDumper(rtc::AtomicOps::Increment(&instance_count_))), config_(config), num_capture_channels_(num_capture_channels), transparent_mode_activated_(!DeactivateTransparentMode()), deactivate_initial_state_reset_at_echo_path_change_( DeactivateInitialStateResetAtEchoPathChange()), full_reset_at_echo_path_change_(FullResetAtEchoPathChange()), subtractor_analyzer_reset_at_echo_path_change_( SubtractorAnalyzerResetAtEchoPathChange()), initial_state_(config_), delay_state_(config_, num_capture_channels_), transparent_state_(config_), filter_quality_state_(config_, num_capture_channels_), erl_estimator_(2 * kNumBlocksPerSecond), erle_estimator_(2 * kNumBlocksPerSecond, config_, num_capture_channels_), filter_analyzer_(config_, num_capture_channels_), echo_audibility_( config_.echo_audibility.use_stationarity_properties_at_init), reverb_model_estimator_(config_, num_capture_channels_), subtractor_output_analyzer_(num_capture_channels_) {} AecState::~AecState() = default; void AecState::HandleEchoPathChange( const EchoPathVariability& echo_path_variability) { const auto full_reset = [&]() { filter_analyzer_.Reset(); capture_signal_saturation_ = false; strong_not_saturated_render_blocks_ = 0; blocks_with_active_render_ = 0; if (!deactivate_initial_state_reset_at_echo_path_change_) { initial_state_.Reset(); } transparent_state_.Reset(); erle_estimator_.Reset(true); erl_estimator_.Reset(); filter_quality_state_.Reset(); }; // TODO(peah): Refine the reset scheme according to the type of gain and // delay adjustment. if (full_reset_at_echo_path_change_ && echo_path_variability.delay_change != EchoPathVariability::DelayAdjustment::kNone) { full_reset(); } else if (echo_path_variability.gain_change) { erle_estimator_.Reset(false); } if (subtractor_analyzer_reset_at_echo_path_change_) { subtractor_output_analyzer_.HandleEchoPathChange(); } } void AecState::Update( const absl::optional& external_delay, rtc::ArrayView>> adaptive_filter_frequency_responses, rtc::ArrayView> adaptive_filter_impulse_responses, const RenderBuffer& render_buffer, rtc::ArrayView> E2_refined, rtc::ArrayView> Y2, rtc::ArrayView subtractor_output) { RTC_DCHECK_EQ(num_capture_channels_, Y2.size()); RTC_DCHECK_EQ(num_capture_channels_, subtractor_output.size()); RTC_DCHECK_EQ(num_capture_channels_, adaptive_filter_frequency_responses.size()); RTC_DCHECK_EQ(num_capture_channels_, adaptive_filter_impulse_responses.size()); // Analyze the filter outputs and filters. bool any_filter_converged; bool all_filters_diverged; subtractor_output_analyzer_.Update(subtractor_output, &any_filter_converged, &all_filters_diverged); bool any_filter_consistent; float max_echo_path_gain; filter_analyzer_.Update(adaptive_filter_impulse_responses, render_buffer, &any_filter_consistent, &max_echo_path_gain); // Estimate the direct path delay of the filter. if (config_.filter.use_linear_filter) { delay_state_.Update(filter_analyzer_.FilterDelaysBlocks(), external_delay, strong_not_saturated_render_blocks_); } const std::vector>& aligned_render_block = render_buffer.Block(-delay_state_.MinDirectPathFilterDelay())[0]; // Update render counters. bool active_render = false; for (size_t ch = 0; ch < aligned_render_block.size(); ++ch) { const float render_energy = std::inner_product( aligned_render_block[ch].begin(), aligned_render_block[ch].end(), aligned_render_block[ch].begin(), 0.f); if (render_energy > (config_.render_levels.active_render_limit * config_.render_levels.active_render_limit) * kFftLengthBy2) { active_render = true; break; } } blocks_with_active_render_ += active_render ? 1 : 0; strong_not_saturated_render_blocks_ += active_render && !SaturatedCapture() ? 1 : 0; std::array avg_render_spectrum_with_reverb; ComputeAvgRenderReverb(render_buffer.GetSpectrumBuffer(), delay_state_.MinDirectPathFilterDelay(), ReverbDecay(), &avg_render_reverb_, avg_render_spectrum_with_reverb); if (config_.echo_audibility.use_stationarity_properties) { // Update the echo audibility evaluator. echo_audibility_.Update(render_buffer, avg_render_reverb_.reverb(), delay_state_.MinDirectPathFilterDelay(), delay_state_.ExternalDelayReported()); } // Update the ERL and ERLE measures. if (initial_state_.TransitionTriggered()) { erle_estimator_.Reset(false); } erle_estimator_.Update(render_buffer, adaptive_filter_frequency_responses, avg_render_spectrum_with_reverb, Y2, E2_refined, subtractor_output_analyzer_.ConvergedFilters()); erl_estimator_.Update( subtractor_output_analyzer_.ConvergedFilters(), render_buffer.Spectrum(delay_state_.MinDirectPathFilterDelay()), Y2); // Detect and flag echo saturation. if (config_.ep_strength.echo_can_saturate) { saturation_detector_.Update(aligned_render_block, SaturatedCapture(), UsableLinearEstimate(), subtractor_output, max_echo_path_gain); } else { RTC_DCHECK(!saturation_detector_.SaturatedEcho()); } // Update the decision on whether to use the initial state parameter set. initial_state_.Update(active_render, SaturatedCapture()); // Detect whether the transparent mode should be activated. transparent_state_.Update(delay_state_.MinDirectPathFilterDelay(), any_filter_consistent, any_filter_converged, all_filters_diverged, active_render, SaturatedCapture()); // Analyze the quality of the filter. filter_quality_state_.Update(active_render, TransparentMode(), SaturatedCapture(), external_delay, any_filter_converged); // Update the reverb estimate. const bool stationary_block = config_.echo_audibility.use_stationarity_properties && echo_audibility_.IsBlockStationary(); reverb_model_estimator_.Update( filter_analyzer_.GetAdjustedFilters(), adaptive_filter_frequency_responses, erle_estimator_.GetInstLinearQualityEstimates(), delay_state_.DirectPathFilterDelays(), filter_quality_state_.UsableLinearFilterOutputs(), stationary_block); erle_estimator_.Dump(data_dumper_); reverb_model_estimator_.Dump(data_dumper_.get()); data_dumper_->DumpRaw("aec3_erl", Erl()); data_dumper_->DumpRaw("aec3_erl_time_domain", ErlTimeDomain()); data_dumper_->DumpRaw("aec3_erle", Erle()[0]); data_dumper_->DumpRaw("aec3_usable_linear_estimate", UsableLinearEstimate()); data_dumper_->DumpRaw("aec3_transparent_mode", TransparentMode()); data_dumper_->DumpRaw("aec3_filter_delay", filter_analyzer_.MinFilterDelayBlocks()); data_dumper_->DumpRaw("aec3_any_filter_consistent", any_filter_consistent); data_dumper_->DumpRaw("aec3_initial_state", initial_state_.InitialStateActive()); data_dumper_->DumpRaw("aec3_capture_saturation", SaturatedCapture()); data_dumper_->DumpRaw("aec3_echo_saturation", SaturatedEcho()); data_dumper_->DumpRaw("aec3_any_filter_converged", any_filter_converged); data_dumper_->DumpRaw("aec3_all_filters_diverged", all_filters_diverged); data_dumper_->DumpRaw("aec3_external_delay_avaliable", external_delay ? 1 : 0); data_dumper_->DumpRaw("aec3_filter_tail_freq_resp_est", GetReverbFrequencyResponse()); } AecState::InitialState::InitialState(const EchoCanceller3Config& config) : conservative_initial_phase_(config.filter.conservative_initial_phase), initial_state_seconds_(config.filter.initial_state_seconds) { Reset(); } void AecState::InitialState::InitialState::Reset() { initial_state_ = true; strong_not_saturated_render_blocks_ = 0; } void AecState::InitialState::InitialState::Update(bool active_render, bool saturated_capture) { strong_not_saturated_render_blocks_ += active_render && !saturated_capture ? 1 : 0; // Flag whether the initial state is still active. bool prev_initial_state = initial_state_; if (conservative_initial_phase_) { initial_state_ = strong_not_saturated_render_blocks_ < 5 * kNumBlocksPerSecond; } else { initial_state_ = strong_not_saturated_render_blocks_ < initial_state_seconds_ * kNumBlocksPerSecond; } // Flag whether the transition from the initial state has started. transition_triggered_ = !initial_state_ && prev_initial_state; } AecState::FilterDelay::FilterDelay(const EchoCanceller3Config& config, size_t num_capture_channels) : delay_headroom_samples_(config.delay.delay_headroom_samples), filter_delays_blocks_(num_capture_channels, 0) {} void AecState::FilterDelay::Update( rtc::ArrayView analyzer_filter_delay_estimates_blocks, const absl::optional& external_delay, size_t blocks_with_proper_filter_adaptation) { // Update the delay based on the external delay. if (external_delay && (!external_delay_ || external_delay_->delay != external_delay->delay)) { external_delay_ = external_delay; external_delay_reported_ = true; } // Override the estimated delay if it is not certain that the filter has had // time to converge. const bool delay_estimator_may_not_have_converged = blocks_with_proper_filter_adaptation < 2 * kNumBlocksPerSecond; if (delay_estimator_may_not_have_converged && external_delay_) { int delay_guess = delay_headroom_samples_ / kBlockSize; std::fill(filter_delays_blocks_.begin(), filter_delays_blocks_.end(), delay_guess); } else { RTC_DCHECK_EQ(filter_delays_blocks_.size(), analyzer_filter_delay_estimates_blocks.size()); std::copy(analyzer_filter_delay_estimates_blocks.begin(), analyzer_filter_delay_estimates_blocks.end(), filter_delays_blocks_.begin()); } min_filter_delay_ = *std::min_element(filter_delays_blocks_.begin(), filter_delays_blocks_.end()); } AecState::TransparentMode::TransparentMode(const EchoCanceller3Config& config) : bounded_erl_(config.ep_strength.bounded_erl), linear_and_stable_echo_path_( config.echo_removal_control.linear_and_stable_echo_path), active_blocks_since_sane_filter_(kBlocksSinceConsistentEstimateInit), non_converged_sequence_size_(kBlocksSinceConvergencedFilterInit) {} void AecState::TransparentMode::Reset() { non_converged_sequence_size_ = kBlocksSinceConvergencedFilterInit; diverged_sequence_size_ = 0; strong_not_saturated_render_blocks_ = 0; if (linear_and_stable_echo_path_) { recent_convergence_during_activity_ = false; } } void AecState::TransparentMode::Update(int filter_delay_blocks, bool any_filter_consistent, bool any_filter_converged, bool all_filters_diverged, bool active_render, bool saturated_capture) { ++capture_block_counter_; strong_not_saturated_render_blocks_ += active_render && !saturated_capture ? 1 : 0; if (any_filter_consistent && filter_delay_blocks < 5) { sane_filter_observed_ = true; active_blocks_since_sane_filter_ = 0; } else if (active_render) { ++active_blocks_since_sane_filter_; } bool sane_filter_recently_seen; if (!sane_filter_observed_) { sane_filter_recently_seen = capture_block_counter_ <= 5 * kNumBlocksPerSecond; } else { sane_filter_recently_seen = active_blocks_since_sane_filter_ <= 30 * kNumBlocksPerSecond; } if (any_filter_converged) { recent_convergence_during_activity_ = true; active_non_converged_sequence_size_ = 0; non_converged_sequence_size_ = 0; ++num_converged_blocks_; } else { if (++non_converged_sequence_size_ > 20 * kNumBlocksPerSecond) { num_converged_blocks_ = 0; } if (active_render && ++active_non_converged_sequence_size_ > 60 * kNumBlocksPerSecond) { recent_convergence_during_activity_ = false; } } if (!all_filters_diverged) { diverged_sequence_size_ = 0; } else if (++diverged_sequence_size_ >= 60) { // TODO(peah): Change these lines to ensure proper triggering of usable // filter. non_converged_sequence_size_ = kBlocksSinceConvergencedFilterInit; } if (active_non_converged_sequence_size_ > 60 * kNumBlocksPerSecond) { finite_erl_recently_detected_ = false; } if (num_converged_blocks_ > 50) { finite_erl_recently_detected_ = true; } if (bounded_erl_) { transparency_activated_ = false; } else if (finite_erl_recently_detected_) { transparency_activated_ = false; } else if (sane_filter_recently_seen && recent_convergence_during_activity_) { transparency_activated_ = false; } else { const bool filter_should_have_converged = strong_not_saturated_render_blocks_ > 6 * kNumBlocksPerSecond; transparency_activated_ = filter_should_have_converged; } } AecState::FilteringQualityAnalyzer::FilteringQualityAnalyzer( const EchoCanceller3Config& config, size_t num_capture_channels) : use_linear_filter_(config.filter.use_linear_filter), usable_linear_filter_estimates_(num_capture_channels, false) {} void AecState::FilteringQualityAnalyzer::Reset() { std::fill(usable_linear_filter_estimates_.begin(), usable_linear_filter_estimates_.end(), false); overall_usable_linear_estimates_ = false; filter_update_blocks_since_reset_ = 0; } void AecState::FilteringQualityAnalyzer::Update( bool active_render, bool transparent_mode, bool saturated_capture, const absl::optional& external_delay, bool any_filter_converged) { // Update blocks counter. const bool filter_update = active_render && !saturated_capture; filter_update_blocks_since_reset_ += filter_update ? 1 : 0; filter_update_blocks_since_start_ += filter_update ? 1 : 0; // Store convergence flag when observed. convergence_seen_ = convergence_seen_ || any_filter_converged; // Verify requirements for achieving a decent filter. The requirements for // filter adaptation at call startup are more restrictive than after an // in-call reset. const bool sufficient_data_to_converge_at_startup = filter_update_blocks_since_start_ > kNumBlocksPerSecond * 0.4f; const bool sufficient_data_to_converge_at_reset = sufficient_data_to_converge_at_startup && filter_update_blocks_since_reset_ > kNumBlocksPerSecond * 0.2f; // The linear filter can only be used if it has had time to converge. overall_usable_linear_estimates_ = sufficient_data_to_converge_at_startup && sufficient_data_to_converge_at_reset; // The linear filter can only be used if an external delay or convergence have // been identified overall_usable_linear_estimates_ = overall_usable_linear_estimates_ && (external_delay || convergence_seen_); // If transparent mode is on, deactivate usign the linear filter. overall_usable_linear_estimates_ = overall_usable_linear_estimates_ && !transparent_mode; if (use_linear_filter_) { std::fill(usable_linear_filter_estimates_.begin(), usable_linear_filter_estimates_.end(), overall_usable_linear_estimates_); } } void AecState::SaturationDetector::Update( rtc::ArrayView> x, bool saturated_capture, bool usable_linear_estimate, rtc::ArrayView subtractor_output, float echo_path_gain) { saturated_echo_ = false; if (!saturated_capture) { return; } if (usable_linear_estimate) { constexpr float kSaturationThreshold = 20000.f; for (size_t ch = 0; ch < subtractor_output.size(); ++ch) { saturated_echo_ = saturated_echo_ || (subtractor_output[ch].s_refined_max_abs > kSaturationThreshold || subtractor_output[ch].s_coarse_max_abs > kSaturationThreshold); } } else { float max_sample = 0.f; for (auto& channel : x) { for (float sample : channel) { max_sample = std::max(max_sample, fabsf(sample)); } } const float kMargin = 10.f; float peak_echo_amplitude = max_sample * echo_path_gain * kMargin; saturated_echo_ = saturated_echo_ || peak_echo_amplitude > 32000; } } } // namespace webrtc