modules/audio_processing/aec3/echo_remover.cc - src - Git at Google

 /*
  *  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/echo_remover.h"

 #include <math.h>
 #include <stddef.h>

 #include <algorithm>
 #include <array>
 #include <cmath>
 #include <memory>

 #include "api/array_view.h"
 #include "modules/audio_processing/aec3/aec3_common.h"
 #include "modules/audio_processing/aec3/aec3_fft.h"
 #include "modules/audio_processing/aec3/aec_state.h"
 #include "modules/audio_processing/aec3/comfort_noise_generator.h"
 #include "modules/audio_processing/aec3/echo_path_variability.h"
 #include "modules/audio_processing/aec3/echo_remover_metrics.h"
 #include "modules/audio_processing/aec3/fft_data.h"
 #include "modules/audio_processing/aec3/render_buffer.h"
 #include "modules/audio_processing/aec3/render_signal_analyzer.h"
 #include "modules/audio_processing/aec3/residual_echo_estimator.h"
 #include "modules/audio_processing/aec3/subtractor.h"
 #include "modules/audio_processing/aec3/subtractor_output.h"
 #include "modules/audio_processing/aec3/suppression_filter.h"
 #include "modules/audio_processing/aec3/suppression_gain.h"
 #include "modules/audio_processing/logging/apm_data_dumper.h"
 #include "rtc_base/atomic_ops.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/logging.h"

 namespace webrtc {

 namespace {

 // Maximum number of channels for which the capture channel data is stored on
 // the stack. If the number of channels are larger than this, they are stored
 // using scratch memory that is pre-allocated on the heap. The reason for this
 // partitioning is not to waste heap space for handling the more common numbers
 // of channels, while at the same time not limiting the support for higher
 // numbers of channels by enforcing the capture channel data to be stored on the
 // stack using a fixed maximum value.
 constexpr size_t kMaxNumChannelsOnStack = 2;

 // Chooses the number of channels to store on the heap when that is required due
 // to the number of capture channels being larger than the pre-defined number
 // of channels to store on the stack.
 size_t NumChannelsOnHeap(size_t num_capture_channels) {
   return num_capture_channels > kMaxNumChannelsOnStack ? num_capture_channels
                                                        : 0;
 }

 void LinearEchoPower(const FftData& E,
                      const FftData& Y,
                      std::array<float, kFftLengthBy2Plus1>* S2) {
   for (size_t k = 0; k < E.re.size(); ++k) {
     (*S2)[k] = (Y.re[k] - E.re[k]) * (Y.re[k] - E.re[k]) +
                (Y.im[k] - E.im[k]) * (Y.im[k] - E.im[k]);
   }
 }

 // Fades between two input signals using a fix-sized transition.
 void SignalTransition(rtc::ArrayView<const float> from,
                       rtc::ArrayView<const float> to,
                       rtc::ArrayView<float> out) {
   if (from == to) {
     RTC_DCHECK_EQ(to.size(), out.size());
     std::copy(to.begin(), to.end(), out.begin());
   } else {
     constexpr size_t kTransitionSize = 30;
     constexpr float kOneByTransitionSizePlusOne = 1.f / (kTransitionSize + 1);

     RTC_DCHECK_EQ(from.size(), to.size());
     RTC_DCHECK_EQ(from.size(), out.size());
     RTC_DCHECK_LE(kTransitionSize, out.size());

     for (size_t k = 0; k < kTransitionSize; ++k) {
       float a = (k + 1) * kOneByTransitionSizePlusOne;
       out[k] = a * to[k] + (1.f - a) * from[k];
     }

     std::copy(to.begin() + kTransitionSize, to.end(),
               out.begin() + kTransitionSize);
   }
 }

 // Computes a windowed (square root Hanning) padded FFT and updates the related
 // memory.
 void WindowedPaddedFft(const Aec3Fft& fft,
                        rtc::ArrayView<const float> v,
                        rtc::ArrayView<float> v_old,
                        FftData* V) {
   fft.PaddedFft(v, v_old, Aec3Fft::Window::kSqrtHanning, V);
   std::copy(v.begin(), v.end(), v_old.begin());
 }

 // Class for removing the echo from the capture signal.
 class EchoRemoverImpl final : public EchoRemover {
  public:
   EchoRemoverImpl(const EchoCanceller3Config& config,
                   int sample_rate_hz,
                   size_t num_render_channels,
                   size_t num_capture_channels);
   ~EchoRemoverImpl() override;
   EchoRemoverImpl(const EchoRemoverImpl&) = delete;
   EchoRemoverImpl& operator=(const EchoRemoverImpl&) = delete;

   void GetMetrics(EchoControl::Metrics* metrics) const override;

   // Removes the echo from a block of samples from the capture signal. The
   // supplied render signal is assumed to be pre-aligned with the capture
   // signal.
   void ProcessCapture(
       EchoPathVariability echo_path_variability,
       bool capture_signal_saturation,
       const absl::optional<DelayEstimate>& external_delay,
       RenderBuffer* render_buffer,
       std::vector<std::vector<std::vector<float>>>* linear_output,
       std::vector<std::vector<std::vector<float>>>* capture) override;

   // Updates the status on whether echo leakage is detected in the output of the
   // echo remover.
   void UpdateEchoLeakageStatus(bool leakage_detected) override {
     echo_leakage_detected_ = leakage_detected;
   }

   void SetCaptureOutputUsage(bool capture_output_used) override {
     capture_output_used_ = capture_output_used;
   }

  private:
   // Selects which of the coarse and refined linear filter outputs that is most
   // appropriate to pass to the suppressor and forms the linear filter output by
   // smoothly transition between those.
   void FormLinearFilterOutput(const SubtractorOutput& subtractor_output,
                               rtc::ArrayView<float> output);

   static int instance_count_;
   const EchoCanceller3Config config_;
   const Aec3Fft fft_;
   std::unique_ptr<ApmDataDumper> data_dumper_;
   const Aec3Optimization optimization_;
   const int sample_rate_hz_;
   const size_t num_render_channels_;
   const size_t num_capture_channels_;
   const bool use_coarse_filter_output_;
   Subtractor subtractor_;
   SuppressionGain suppression_gain_;
   ComfortNoiseGenerator cng_;
   SuppressionFilter suppression_filter_;
   RenderSignalAnalyzer render_signal_analyzer_;
   ResidualEchoEstimator residual_echo_estimator_;
   bool echo_leakage_detected_ = false;
   bool capture_output_used_ = true;
   AecState aec_state_;
   EchoRemoverMetrics metrics_;
   std::vector<std::array<float, kFftLengthBy2>> e_old_;
   std::vector<std::array<float, kFftLengthBy2>> y_old_;
   size_t block_counter_ = 0;
   int gain_change_hangover_ = 0;
   bool refined_filter_output_last_selected_ = true;

   std::vector<std::array<float, kFftLengthBy2>> e_heap_;
   std::vector<std::array<float, kFftLengthBy2Plus1>> Y2_heap_;
   std::vector<std::array<float, kFftLengthBy2Plus1>> E2_heap_;
   std::vector<std::array<float, kFftLengthBy2Plus1>> R2_heap_;
   std::vector<std::array<float, kFftLengthBy2Plus1>> S2_linear_heap_;
   std::vector<FftData> Y_heap_;
   std::vector<FftData> E_heap_;
   std::vector<FftData> comfort_noise_heap_;
   std::vector<FftData> high_band_comfort_noise_heap_;
   std::vector<SubtractorOutput> subtractor_output_heap_;
 };

 int EchoRemoverImpl::instance_count_ = 0;

 EchoRemoverImpl::EchoRemoverImpl(const EchoCanceller3Config& config,
                                  int sample_rate_hz,
                                  size_t num_render_channels,
                                  size_t num_capture_channels)
     : config_(config),
       fft_(),
       data_dumper_(
           new ApmDataDumper(rtc::AtomicOps::Increment(&instance_count_))),
       optimization_(DetectOptimization()),
       sample_rate_hz_(sample_rate_hz),
       num_render_channels_(num_render_channels),
       num_capture_channels_(num_capture_channels),
       use_coarse_filter_output_(
           config_.filter.enable_coarse_filter_output_usage),
       subtractor_(config,
                   num_render_channels_,
                   num_capture_channels_,
                   data_dumper_.get(),
                   optimization_),
       suppression_gain_(config_,
                         optimization_,
                         sample_rate_hz,
                         num_capture_channels),
       cng_(config_, optimization_, num_capture_channels_),
       suppression_filter_(optimization_,
                           sample_rate_hz_,
                           num_capture_channels_),
       render_signal_analyzer_(config_),
       residual_echo_estimator_(config_, num_render_channels),
       aec_state_(config_, num_capture_channels_),
       e_old_(num_capture_channels_, {0.f}),
       y_old_(num_capture_channels_, {0.f}),
       e_heap_(NumChannelsOnHeap(num_capture_channels_), {0.f}),
       Y2_heap_(NumChannelsOnHeap(num_capture_channels_)),
       E2_heap_(NumChannelsOnHeap(num_capture_channels_)),
       R2_heap_(NumChannelsOnHeap(num_capture_channels_)),
       S2_linear_heap_(NumChannelsOnHeap(num_capture_channels_)),
       Y_heap_(NumChannelsOnHeap(num_capture_channels_)),
       E_heap_(NumChannelsOnHeap(num_capture_channels_)),
       comfort_noise_heap_(NumChannelsOnHeap(num_capture_channels_)),
       high_band_comfort_noise_heap_(NumChannelsOnHeap(num_capture_channels_)),
       subtractor_output_heap_(NumChannelsOnHeap(num_capture_channels_)) {
   RTC_DCHECK(ValidFullBandRate(sample_rate_hz));
 }

 EchoRemoverImpl::~EchoRemoverImpl() = default;

 void EchoRemoverImpl::GetMetrics(EchoControl::Metrics* metrics) const {
   // Echo return loss (ERL) is inverted to go from gain to attenuation.
   metrics->echo_return_loss = -10.0 * std::log10(aec_state_.ErlTimeDomain());
   metrics->echo_return_loss_enhancement =
       Log2TodB(aec_state_.FullBandErleLog2());
 }

 void EchoRemoverImpl::ProcessCapture(
     EchoPathVariability echo_path_variability,
     bool capture_signal_saturation,
     const absl::optional<DelayEstimate>& external_delay,
     RenderBuffer* render_buffer,
     std::vector<std::vector<std::vector<float>>>* linear_output,
     std::vector<std::vector<std::vector<float>>>* capture) {
   ++block_counter_;
   const std::vector<std::vector<std::vector<float>>>& x =
       render_buffer->Block(0);
   std::vector<std::vector<std::vector<float>>>* y = capture;
   RTC_DCHECK(render_buffer);
   RTC_DCHECK(y);
   RTC_DCHECK_EQ(x.size(), NumBandsForRate(sample_rate_hz_));
   RTC_DCHECK_EQ(y->size(), NumBandsForRate(sample_rate_hz_));
   RTC_DCHECK_EQ(x[0].size(), num_render_channels_);
   RTC_DCHECK_EQ((*y)[0].size(), num_capture_channels_);
   RTC_DCHECK_EQ(x[0][0].size(), kBlockSize);
   RTC_DCHECK_EQ((*y)[0][0].size(), kBlockSize);

   // Stack allocated data to use when the number of channels is low.
   std::array<std::array<float, kFftLengthBy2>, kMaxNumChannelsOnStack> e_stack;
   std::array<std::array<float, kFftLengthBy2Plus1>, kMaxNumChannelsOnStack>
       Y2_stack;
   std::array<std::array<float, kFftLengthBy2Plus1>, kMaxNumChannelsOnStack>
       E2_stack;
   std::array<std::array<float, kFftLengthBy2Plus1>, kMaxNumChannelsOnStack>
       R2_stack;
   std::array<std::array<float, kFftLengthBy2Plus1>, kMaxNumChannelsOnStack>
       S2_linear_stack;
   std::array<FftData, kMaxNumChannelsOnStack> Y_stack;
   std::array<FftData, kMaxNumChannelsOnStack> E_stack;
   std::array<FftData, kMaxNumChannelsOnStack> comfort_noise_stack;
   std::array<FftData, kMaxNumChannelsOnStack> high_band_comfort_noise_stack;
   std::array<SubtractorOutput, kMaxNumChannelsOnStack> subtractor_output_stack;

   rtc::ArrayView<std::array<float, kFftLengthBy2>> e(e_stack.data(),
                                                      num_capture_channels_);
   rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>> Y2(
       Y2_stack.data(), num_capture_channels_);
   rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>> E2(
       E2_stack.data(), num_capture_channels_);
   rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>> R2(
       R2_stack.data(), num_capture_channels_);
   rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>> S2_linear(
       S2_linear_stack.data(), num_capture_channels_);
   rtc::ArrayView<FftData> Y(Y_stack.data(), num_capture_channels_);
   rtc::ArrayView<FftData> E(E_stack.data(), num_capture_channels_);
   rtc::ArrayView<FftData> comfort_noise(comfort_noise_stack.data(),
                                         num_capture_channels_);
   rtc::ArrayView<FftData> high_band_comfort_noise(
       high_band_comfort_noise_stack.data(), num_capture_channels_);
   rtc::ArrayView<SubtractorOutput> subtractor_output(
       subtractor_output_stack.data(), num_capture_channels_);
   if (NumChannelsOnHeap(num_capture_channels_) > 0) {
     // If the stack-allocated space is too small, use the heap for storing the
     // microphone data.
     e = rtc::ArrayView<std::array<float, kFftLengthBy2>>(e_heap_.data(),
                                                          num_capture_channels_);
     Y2 = rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>>(
         Y2_heap_.data(), num_capture_channels_);
     E2 = rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>>(
         E2_heap_.data(), num_capture_channels_);
     R2 = rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>>(
         R2_heap_.data(), num_capture_channels_);
     S2_linear = rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>>(
         S2_linear_heap_.data(), num_capture_channels_);
     Y = rtc::ArrayView<FftData>(Y_heap_.data(), num_capture_channels_);
     E = rtc::ArrayView<FftData>(E_heap_.data(), num_capture_channels_);
     comfort_noise = rtc::ArrayView<FftData>(comfort_noise_heap_.data(),
                                             num_capture_channels_);
     high_band_comfort_noise = rtc::ArrayView<FftData>(
         high_band_comfort_noise_heap_.data(), num_capture_channels_);
     subtractor_output = rtc::ArrayView<SubtractorOutput>(
         subtractor_output_heap_.data(), num_capture_channels_);
   }

   data_dumper_->DumpWav("aec3_echo_remover_capture_input", kBlockSize,
                         &(*y)[0][0][0], 16000, 1);
   data_dumper_->DumpWav("aec3_echo_remover_render_input", kBlockSize,
                         &x[0][0][0], 16000, 1);
   data_dumper_->DumpRaw("aec3_echo_remover_capture_input", (*y)[0][0]);
   data_dumper_->DumpRaw("aec3_echo_remover_render_input", x[0][0]);

   aec_state_.UpdateCaptureSaturation(capture_signal_saturation);

   if (echo_path_variability.AudioPathChanged()) {
     // Ensure that the gain change is only acted on once per frame.
     if (echo_path_variability.gain_change) {
       if (gain_change_hangover_ == 0) {
         constexpr int kMaxBlocksPerFrame = 3;
         gain_change_hangover_ = kMaxBlocksPerFrame;
         rtc::LoggingSeverity log_level =
             config_.delay.log_warning_on_delay_changes ? rtc::LS_WARNING
                                                        : rtc::LS_VERBOSE;
         RTC_LOG_V(log_level)
             << "Gain change detected at block " << block_counter_;
       } else {
         echo_path_variability.gain_change = false;
       }
     }

     subtractor_.HandleEchoPathChange(echo_path_variability);
     aec_state_.HandleEchoPathChange(echo_path_variability);

     if (echo_path_variability.delay_change !=
         EchoPathVariability::DelayAdjustment::kNone) {
       suppression_gain_.SetInitialState(true);
     }
   }
   if (gain_change_hangover_ > 0) {
     --gain_change_hangover_;
   }

   // Analyze the render signal.
   render_signal_analyzer_.Update(*render_buffer,
                                  aec_state_.MinDirectPathFilterDelay());

   // State transition.
   if (aec_state_.TransitionTriggered()) {
     subtractor_.ExitInitialState();
     suppression_gain_.SetInitialState(false);
   }

   // Perform linear echo cancellation.
   subtractor_.Process(*render_buffer, (*y)[0], render_signal_analyzer_,
                       aec_state_, subtractor_output);

   // Compute spectra.
   for (size_t ch = 0; ch < num_capture_channels_; ++ch) {
     FormLinearFilterOutput(subtractor_output[ch], e[ch]);
     WindowedPaddedFft(fft_, (*y)[0][ch], y_old_[ch], &Y[ch]);
     WindowedPaddedFft(fft_, e[ch], e_old_[ch], &E[ch]);
     LinearEchoPower(E[ch], Y[ch], &S2_linear[ch]);
     Y[ch].Spectrum(optimization_, Y2[ch]);
     E[ch].Spectrum(optimization_, E2[ch]);
   }

   // Optionally return the linear filter output.
   if (linear_output) {
     RTC_DCHECK_GE(1, linear_output->size());
     RTC_DCHECK_EQ(num_capture_channels_, linear_output[0].size());
     for (size_t ch = 0; ch < num_capture_channels_; ++ch) {
       RTC_DCHECK_EQ(kBlockSize, (*linear_output)[0][ch].size());
       std::copy(e[ch].begin(), e[ch].end(), (*linear_output)[0][ch].begin());
     }
   }

   // Update the AEC state information.
   aec_state_.Update(external_delay, subtractor_.FilterFrequencyResponses(),
                     subtractor_.FilterImpulseResponses(), *render_buffer, E2,
                     Y2, subtractor_output);

   // Choose the linear output.
   const auto& Y_fft = aec_state_.UseLinearFilterOutput() ? E : Y;

   data_dumper_->DumpWav("aec3_output_linear", kBlockSize, &(*y)[0][0][0], 16000,
                         1);
   data_dumper_->DumpWav("aec3_output_linear2", kBlockSize, &e[0][0], 16000, 1);

   // Estimate the comfort noise.
   cng_.Compute(aec_state_.SaturatedCapture(), Y2, comfort_noise,
                high_band_comfort_noise);

   // Only do the below processing if the output of the audio processing module
   // is used.
   std::array<float, kFftLengthBy2Plus1> G;
   if (capture_output_used_) {
     // Estimate the residual echo power.
     residual_echo_estimator_.Estimate(aec_state_, *render_buffer, S2_linear, Y2,
                                       R2);

     // Suppressor nearend estimate.
     if (aec_state_.UsableLinearEstimate()) {
       // E2 is bound by Y2.
       for (size_t ch = 0; ch < num_capture_channels_; ++ch) {
         std::transform(E2[ch].begin(), E2[ch].end(), Y2[ch].begin(),
                        E2[ch].begin(),
                        [](float a, float b) { return std::min(a, b); });
       }
     }
     const auto& nearend_spectrum = aec_state_.UsableLinearEstimate() ? E2 : Y2;

     // Suppressor echo estimate.
     const auto& echo_spectrum =
         aec_state_.UsableLinearEstimate() ? S2_linear : R2;

     // Determine if the suppressor should assume clock drift.
     const bool clock_drift = config_.echo_removal_control.has_clock_drift ||
                              echo_path_variability.clock_drift;

     // Compute preferred gains.
     float high_bands_gain;
     suppression_gain_.GetGain(nearend_spectrum, echo_spectrum, R2,
                               cng_.NoiseSpectrum(), render_signal_analyzer_,
                               aec_state_, x, clock_drift, &high_bands_gain, &G);

     suppression_filter_.ApplyGain(comfort_noise, high_band_comfort_noise, G,
                                   high_bands_gain, Y_fft, y);

   } else {
     G.fill(0.f);
   }

   // Update the metrics.
   metrics_.Update(aec_state_, cng_.NoiseSpectrum()[0], G);

   // Debug outputs for the purpose of development and analysis.
   data_dumper_->DumpWav("aec3_echo_estimate", kBlockSize,
                         &subtractor_output[0].s_refined[0], 16000, 1);
   data_dumper_->DumpRaw("aec3_output", (*y)[0][0]);
   data_dumper_->DumpRaw("aec3_narrow_render",
                         render_signal_analyzer_.NarrowPeakBand() ? 1 : 0);
   data_dumper_->DumpRaw("aec3_N2", cng_.NoiseSpectrum()[0]);
   data_dumper_->DumpRaw("aec3_suppressor_gain", G);
   data_dumper_->DumpWav("aec3_output",
                         rtc::ArrayView<const float>(&(*y)[0][0][0], kBlockSize),
                         16000, 1);
   data_dumper_->DumpRaw("aec3_using_subtractor_output[0]",
                         aec_state_.UseLinearFilterOutput() ? 1 : 0);
   data_dumper_->DumpRaw("aec3_E2", E2[0]);
   data_dumper_->DumpRaw("aec3_S2_linear", S2_linear[0]);
   data_dumper_->DumpRaw("aec3_Y2", Y2[0]);
   data_dumper_->DumpRaw(
       "aec3_X2", render_buffer->Spectrum(
                      aec_state_.MinDirectPathFilterDelay())[/*channel=*/0]);
   data_dumper_->DumpRaw("aec3_R2", R2[0]);
   data_dumper_->DumpRaw("aec3_filter_delay",
                         aec_state_.MinDirectPathFilterDelay());
   data_dumper_->DumpRaw("aec3_capture_saturation",
                         aec_state_.SaturatedCapture() ? 1 : 0);
 }

 void EchoRemoverImpl::FormLinearFilterOutput(
     const SubtractorOutput& subtractor_output,
     rtc::ArrayView<float> output) {
   RTC_DCHECK_EQ(subtractor_output.e_refined.size(), output.size());
   RTC_DCHECK_EQ(subtractor_output.e_coarse.size(), output.size());
   bool use_refined_output = true;
   if (use_coarse_filter_output_) {
     // As the output of the refined adaptive filter generally should be better
     // than the coarse filter output, add a margin and threshold for when
     // choosing the coarse filter output.
     if (subtractor_output.e2_coarse < 0.9f * subtractor_output.e2_refined &&
         subtractor_output.y2 > 30.f * 30.f * kBlockSize &&
         (subtractor_output.s2_refined > 60.f * 60.f * kBlockSize ||
          subtractor_output.s2_coarse > 60.f * 60.f * kBlockSize)) {
       use_refined_output = false;
     } else {
       // If the refined filter is diverged, choose the filter output that has
       // the lowest power.
       if (subtractor_output.e2_coarse < subtractor_output.e2_refined &&
           subtractor_output.y2 < subtractor_output.e2_refined) {
         use_refined_output = false;
       }
     }
   }

   SignalTransition(refined_filter_output_last_selected_
                        ? subtractor_output.e_refined
                        : subtractor_output.e_coarse,
                    use_refined_output ? subtractor_output.e_refined
                                       : subtractor_output.e_coarse,
                    output);
   refined_filter_output_last_selected_ = use_refined_output;
 }

 }  // namespace

 EchoRemover* EchoRemover::Create(const EchoCanceller3Config& config,
                                  int sample_rate_hz,
                                  size_t num_render_channels,
                                  size_t num_capture_channels) {
   return new EchoRemoverImpl(config, sample_rate_hz, num_render_channels,
                              num_capture_channels);
 }

 }  // namespace webrtc
	/*
	* 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/echo_remover.h"

	#include <math.h>
	#include <stddef.h>

	#include <algorithm>
	#include <array>
	#include <cmath>
	#include <memory>

	#include "api/array_view.h"
	#include "modules/audio_processing/aec3/aec3_common.h"
	#include "modules/audio_processing/aec3/aec3_fft.h"
	#include "modules/audio_processing/aec3/aec_state.h"
	#include "modules/audio_processing/aec3/comfort_noise_generator.h"
	#include "modules/audio_processing/aec3/echo_path_variability.h"
	#include "modules/audio_processing/aec3/echo_remover_metrics.h"
	#include "modules/audio_processing/aec3/fft_data.h"
	#include "modules/audio_processing/aec3/render_buffer.h"
	#include "modules/audio_processing/aec3/render_signal_analyzer.h"
	#include "modules/audio_processing/aec3/residual_echo_estimator.h"
	#include "modules/audio_processing/aec3/subtractor.h"
	#include "modules/audio_processing/aec3/subtractor_output.h"
	#include "modules/audio_processing/aec3/suppression_filter.h"
	#include "modules/audio_processing/aec3/suppression_gain.h"
	#include "modules/audio_processing/logging/apm_data_dumper.h"
	#include "rtc_base/atomic_ops.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/logging.h"

	namespace webrtc {

	namespace {

	// Maximum number of channels for which the capture channel data is stored on
	// the stack. If the number of channels are larger than this, they are stored
	// using scratch memory that is pre-allocated on the heap. The reason for this
	// partitioning is not to waste heap space for handling the more common numbers
	// of channels, while at the same time not limiting the support for higher
	// numbers of channels by enforcing the capture channel data to be stored on the
	// stack using a fixed maximum value.
	constexpr size_t kMaxNumChannelsOnStack = 2;

	// Chooses the number of channels to store on the heap when that is required due
	// to the number of capture channels being larger than the pre-defined number
	// of channels to store on the stack.
	size_t NumChannelsOnHeap(size_t num_capture_channels) {
	return num_capture_channels > kMaxNumChannelsOnStack ? num_capture_channels
	: 0;
	}

	void LinearEchoPower(const FftData& E,
	const FftData& Y,
	std::array<float, kFftLengthBy2Plus1>* S2) {
	for (size_t k = 0; k < E.re.size(); ++k) {
	(S2)[k] = (Y.re[k] - E.re[k]) (Y.re[k] - E.re[k]) +
	(Y.im[k] - E.im[k]) * (Y.im[k] - E.im[k]);
	}
	}

	// Fades between two input signals using a fix-sized transition.
	void SignalTransition(rtc::ArrayView<const float> from,
	rtc::ArrayView<const float> to,
	rtc::ArrayView<float> out) {
	if (from == to) {
	RTC_DCHECK_EQ(to.size(), out.size());
	std::copy(to.begin(), to.end(), out.begin());
	} else {
	constexpr size_t kTransitionSize = 30;
	constexpr float kOneByTransitionSizePlusOne = 1.f / (kTransitionSize + 1);

	RTC_DCHECK_EQ(from.size(), to.size());
	RTC_DCHECK_EQ(from.size(), out.size());
	RTC_DCHECK_LE(kTransitionSize, out.size());

	for (size_t k = 0; k < kTransitionSize; ++k) {
	float a = (k + 1) * kOneByTransitionSizePlusOne;
	out[k] = a * to[k] + (1.f - a) * from[k];
	}

	std::copy(to.begin() + kTransitionSize, to.end(),
	out.begin() + kTransitionSize);
	}
	}

	// Computes a windowed (square root Hanning) padded FFT and updates the related
	// memory.
	void WindowedPaddedFft(const Aec3Fft& fft,
	rtc::ArrayView<const float> v,
	rtc::ArrayView<float> v_old,
	FftData* V) {
	fft.PaddedFft(v, v_old, Aec3Fft::Window::kSqrtHanning, V);
	std::copy(v.begin(), v.end(), v_old.begin());
	}

	// Class for removing the echo from the capture signal.
	class EchoRemoverImpl final : public EchoRemover {
	public:
	EchoRemoverImpl(const EchoCanceller3Config& config,
	int sample_rate_hz,
	size_t num_render_channels,
	size_t num_capture_channels);
	~EchoRemoverImpl() override;
	EchoRemoverImpl(const EchoRemoverImpl&) = delete;
	EchoRemoverImpl& operator=(const EchoRemoverImpl&) = delete;

	void GetMetrics(EchoControl::Metrics* metrics) const override;

	// Removes the echo from a block of samples from the capture signal. The
	// supplied render signal is assumed to be pre-aligned with the capture
	// signal.
	void ProcessCapture(
	EchoPathVariability echo_path_variability,
	bool capture_signal_saturation,
	const absl::optional<DelayEstimate>& external_delay,
	RenderBuffer* render_buffer,
	std::vector<std::vector<std::vector<float>>>* linear_output,
	std::vector<std::vector<std::vector<float>>>* capture) override;

	// Updates the status on whether echo leakage is detected in the output of the
	// echo remover.
	void UpdateEchoLeakageStatus(bool leakage_detected) override {
	echo_leakage_detected_ = leakage_detected;
	}

	void SetCaptureOutputUsage(bool capture_output_used) override {
	capture_output_used_ = capture_output_used;
	}

	private:
	// Selects which of the coarse and refined linear filter outputs that is most
	// appropriate to pass to the suppressor and forms the linear filter output by
	// smoothly transition between those.
	void FormLinearFilterOutput(const SubtractorOutput& subtractor_output,
	rtc::ArrayView<float> output);

	static int instance_count_;
	const EchoCanceller3Config config_;
	const Aec3Fft fft_;
	std::unique_ptr<ApmDataDumper> data_dumper_;
	const Aec3Optimization optimization_;
	const int sample_rate_hz_;
	const size_t num_render_channels_;
	const size_t num_capture_channels_;
	const bool use_coarse_filter_output_;
	Subtractor subtractor_;
	SuppressionGain suppression_gain_;
	ComfortNoiseGenerator cng_;
	SuppressionFilter suppression_filter_;
	RenderSignalAnalyzer render_signal_analyzer_;
	ResidualEchoEstimator residual_echo_estimator_;
	bool echo_leakage_detected_ = false;
	bool capture_output_used_ = true;
	AecState aec_state_;
	EchoRemoverMetrics metrics_;
	std::vector<std::array<float, kFftLengthBy2>> e_old_;
	std::vector<std::array<float, kFftLengthBy2>> y_old_;
	size_t block_counter_ = 0;
	int gain_change_hangover_ = 0;
	bool refined_filter_output_last_selected_ = true;

	std::vector<std::array<float, kFftLengthBy2>> e_heap_;
	std::vector<std::array<float, kFftLengthBy2Plus1>> Y2_heap_;
	std::vector<std::array<float, kFftLengthBy2Plus1>> E2_heap_;
	std::vector<std::array<float, kFftLengthBy2Plus1>> R2_heap_;
	std::vector<std::array<float, kFftLengthBy2Plus1>> S2_linear_heap_;
	std::vector<FftData> Y_heap_;
	std::vector<FftData> E_heap_;
	std::vector<FftData> comfort_noise_heap_;
	std::vector<FftData> high_band_comfort_noise_heap_;
	std::vector<SubtractorOutput> subtractor_output_heap_;
	};

	int EchoRemoverImpl::instance_count_ = 0;

	EchoRemoverImpl::EchoRemoverImpl(const EchoCanceller3Config& config,
	int sample_rate_hz,
	size_t num_render_channels,
	size_t num_capture_channels)
	: config_(config),
	fft_(),
	data_dumper_(
	new ApmDataDumper(rtc::AtomicOps::Increment(&instance_count_))),
	optimization_(DetectOptimization()),
	sample_rate_hz_(sample_rate_hz),
	num_render_channels_(num_render_channels),
	num_capture_channels_(num_capture_channels),
	use_coarse_filter_output_(
	config_.filter.enable_coarse_filter_output_usage),
	subtractor_(config,
	num_render_channels_,
	num_capture_channels_,
	data_dumper_.get(),
	optimization_),
	suppression_gain_(config_,
	optimization_,
	sample_rate_hz,
	num_capture_channels),
	cng_(config_, optimization_, num_capture_channels_),
	suppression_filter_(optimization_,
	sample_rate_hz_,
	num_capture_channels_),
	render_signal_analyzer_(config_),
	residual_echo_estimator_(config_, num_render_channels),
	aec_state_(config_, num_capture_channels_),
	e_old_(num_capture_channels_, {0.f}),
	y_old_(num_capture_channels_, {0.f}),
	e_heap_(NumChannelsOnHeap(num_capture_channels_), {0.f}),
	Y2_heap_(NumChannelsOnHeap(num_capture_channels_)),
	E2_heap_(NumChannelsOnHeap(num_capture_channels_)),
	R2_heap_(NumChannelsOnHeap(num_capture_channels_)),
	S2_linear_heap_(NumChannelsOnHeap(num_capture_channels_)),
	Y_heap_(NumChannelsOnHeap(num_capture_channels_)),
	E_heap_(NumChannelsOnHeap(num_capture_channels_)),
	comfort_noise_heap_(NumChannelsOnHeap(num_capture_channels_)),
	high_band_comfort_noise_heap_(NumChannelsOnHeap(num_capture_channels_)),
	subtractor_output_heap_(NumChannelsOnHeap(num_capture_channels_)) {
	RTC_DCHECK(ValidFullBandRate(sample_rate_hz));
	}

	EchoRemoverImpl::~EchoRemoverImpl() = default;

	void EchoRemoverImpl::GetMetrics(EchoControl::Metrics* metrics) const {
	// Echo return loss (ERL) is inverted to go from gain to attenuation.
	metrics->echo_return_loss = -10.0 * std::log10(aec_state_.ErlTimeDomain());
	metrics->echo_return_loss_enhancement =
	Log2TodB(aec_state_.FullBandErleLog2());
	}

	void EchoRemoverImpl::ProcessCapture(
	EchoPathVariability echo_path_variability,
	bool capture_signal_saturation,
	const absl::optional<DelayEstimate>& external_delay,
	RenderBuffer* render_buffer,
	std::vector<std::vector<std::vector<float>>>* linear_output,
	std::vector<std::vector<std::vector<float>>>* capture) {
	++block_counter_;
	const std::vector<std::vector<std::vector<float>>>& x =
	render_buffer->Block(0);
	std::vector<std::vector<std::vector<float>>>* y = capture;
	RTC_DCHECK(render_buffer);
	RTC_DCHECK(y);
	RTC_DCHECK_EQ(x.size(), NumBandsForRate(sample_rate_hz_));
	RTC_DCHECK_EQ(y->size(), NumBandsForRate(sample_rate_hz_));
	RTC_DCHECK_EQ(x[0].size(), num_render_channels_);
	RTC_DCHECK_EQ((*y)[0].size(), num_capture_channels_);
	RTC_DCHECK_EQ(x[0][0].size(), kBlockSize);
	RTC_DCHECK_EQ((*y)[0][0].size(), kBlockSize);

	// Stack allocated data to use when the number of channels is low.
	std::array<std::array<float, kFftLengthBy2>, kMaxNumChannelsOnStack> e_stack;
	std::array<std::array<float, kFftLengthBy2Plus1>, kMaxNumChannelsOnStack>
	Y2_stack;
	std::array<std::array<float, kFftLengthBy2Plus1>, kMaxNumChannelsOnStack>
	E2_stack;
	std::array<std::array<float, kFftLengthBy2Plus1>, kMaxNumChannelsOnStack>
	R2_stack;
	std::array<std::array<float, kFftLengthBy2Plus1>, kMaxNumChannelsOnStack>
	S2_linear_stack;
	std::array<FftData, kMaxNumChannelsOnStack> Y_stack;
	std::array<FftData, kMaxNumChannelsOnStack> E_stack;
	std::array<FftData, kMaxNumChannelsOnStack> comfort_noise_stack;
	std::array<FftData, kMaxNumChannelsOnStack> high_band_comfort_noise_stack;
	std::array<SubtractorOutput, kMaxNumChannelsOnStack> subtractor_output_stack;

	rtc::ArrayView<std::array<float, kFftLengthBy2>> e(e_stack.data(),
	num_capture_channels_);
	rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>> Y2(
	Y2_stack.data(), num_capture_channels_);
	rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>> E2(
	E2_stack.data(), num_capture_channels_);
	rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>> R2(
	R2_stack.data(), num_capture_channels_);
	rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>> S2_linear(
	S2_linear_stack.data(), num_capture_channels_);
	rtc::ArrayView<FftData> Y(Y_stack.data(), num_capture_channels_);
	rtc::ArrayView<FftData> E(E_stack.data(), num_capture_channels_);
	rtc::ArrayView<FftData> comfort_noise(comfort_noise_stack.data(),
	num_capture_channels_);
	rtc::ArrayView<FftData> high_band_comfort_noise(
	high_band_comfort_noise_stack.data(), num_capture_channels_);
	rtc::ArrayView<SubtractorOutput> subtractor_output(
	subtractor_output_stack.data(), num_capture_channels_);
	if (NumChannelsOnHeap(num_capture_channels_) > 0) {
	// If the stack-allocated space is too small, use the heap for storing the
	// microphone data.
	e = rtc::ArrayView<std::array<float, kFftLengthBy2>>(e_heap_.data(),
	num_capture_channels_);
	Y2 = rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>>(
	Y2_heap_.data(), num_capture_channels_);
	E2 = rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>>(
	E2_heap_.data(), num_capture_channels_);
	R2 = rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>>(
	R2_heap_.data(), num_capture_channels_);
	S2_linear = rtc::ArrayView<std::array<float, kFftLengthBy2Plus1>>(
	S2_linear_heap_.data(), num_capture_channels_);
	Y = rtc::ArrayView<FftData>(Y_heap_.data(), num_capture_channels_);
	E = rtc::ArrayView<FftData>(E_heap_.data(), num_capture_channels_);
	comfort_noise = rtc::ArrayView<FftData>(comfort_noise_heap_.data(),
	num_capture_channels_);
	high_band_comfort_noise = rtc::ArrayView<FftData>(
	high_band_comfort_noise_heap_.data(), num_capture_channels_);
	subtractor_output = rtc::ArrayView<SubtractorOutput>(
	subtractor_output_heap_.data(), num_capture_channels_);
	}

	data_dumper_->DumpWav("aec3_echo_remover_capture_input", kBlockSize,
	&(*y)[0][0][0], 16000, 1);
	data_dumper_->DumpWav("aec3_echo_remover_render_input", kBlockSize,
	&x[0][0][0], 16000, 1);
	data_dumper_->DumpRaw("aec3_echo_remover_capture_input", (*y)[0][0]);
	data_dumper_->DumpRaw("aec3_echo_remover_render_input", x[0][0]);

	aec_state_.UpdateCaptureSaturation(capture_signal_saturation);

	if (echo_path_variability.AudioPathChanged()) {
	// Ensure that the gain change is only acted on once per frame.
	if (echo_path_variability.gain_change) {
	if (gain_change_hangover_ == 0) {
	constexpr int kMaxBlocksPerFrame = 3;
	gain_change_hangover_ = kMaxBlocksPerFrame;
	rtc::LoggingSeverity log_level =
	config_.delay.log_warning_on_delay_changes ? rtc::LS_WARNING
	: rtc::LS_VERBOSE;
	RTC_LOG_V(log_level)
	<< "Gain change detected at block " << block_counter_;
	} else {
	echo_path_variability.gain_change = false;
	}
	}

	subtractor_.HandleEchoPathChange(echo_path_variability);
	aec_state_.HandleEchoPathChange(echo_path_variability);

	if (echo_path_variability.delay_change !=
	EchoPathVariability::DelayAdjustment::kNone) {
	suppression_gain_.SetInitialState(true);
	}
	}
	if (gain_change_hangover_ > 0) {
	--gain_change_hangover_;
	}

	// Analyze the render signal.
	render_signal_analyzer_.Update(*render_buffer,
	aec_state_.MinDirectPathFilterDelay());

	// State transition.
	if (aec_state_.TransitionTriggered()) {
	subtractor_.ExitInitialState();
	suppression_gain_.SetInitialState(false);
	}

	// Perform linear echo cancellation.
	subtractor_.Process(render_buffer, (y)[0], render_signal_analyzer_,
	aec_state_, subtractor_output);

	// Compute spectra.
	for (size_t ch = 0; ch < num_capture_channels_; ++ch) {
	FormLinearFilterOutput(subtractor_output[ch], e[ch]);
	WindowedPaddedFft(fft_, (*y)[0][ch], y_old_[ch], &Y[ch]);
	WindowedPaddedFft(fft_, e[ch], e_old_[ch], &E[ch]);
	LinearEchoPower(E[ch], Y[ch], &S2_linear[ch]);
	Y[ch].Spectrum(optimization_, Y2[ch]);
	E[ch].Spectrum(optimization_, E2[ch]);
	}

	// Optionally return the linear filter output.
	if (linear_output) {
	RTC_DCHECK_GE(1, linear_output->size());
	RTC_DCHECK_EQ(num_capture_channels_, linear_output[0].size());
	for (size_t ch = 0; ch < num_capture_channels_; ++ch) {
	RTC_DCHECK_EQ(kBlockSize, (*linear_output)[0][ch].size());
	std::copy(e[ch].begin(), e[ch].end(), (*linear_output)[0][ch].begin());
	}
	}

	// Update the AEC state information.
	aec_state_.Update(external_delay, subtractor_.FilterFrequencyResponses(),
	subtractor_.FilterImpulseResponses(), *render_buffer, E2,
	Y2, subtractor_output);

	// Choose the linear output.
	const auto& Y_fft = aec_state_.UseLinearFilterOutput() ? E : Y;

	data_dumper_->DumpWav("aec3_output_linear", kBlockSize, &(*y)[0][0][0], 16000,
	1);
	data_dumper_->DumpWav("aec3_output_linear2", kBlockSize, &e[0][0], 16000, 1);

	// Estimate the comfort noise.
	cng_.Compute(aec_state_.SaturatedCapture(), Y2, comfort_noise,
	high_band_comfort_noise);

	// Only do the below processing if the output of the audio processing module
	// is used.
	std::array<float, kFftLengthBy2Plus1> G;
	if (capture_output_used_) {
	// Estimate the residual echo power.
	residual_echo_estimator_.Estimate(aec_state_, *render_buffer, S2_linear, Y2,
	R2);

	// Suppressor nearend estimate.
	if (aec_state_.UsableLinearEstimate()) {
	// E2 is bound by Y2.
	for (size_t ch = 0; ch < num_capture_channels_; ++ch) {
	std::transform(E2[ch].begin(), E2[ch].end(), Y2[ch].begin(),
	E2[ch].begin(),
	[](float a, float b) { return std::min(a, b); });
	}
	}
	const auto& nearend_spectrum = aec_state_.UsableLinearEstimate() ? E2 : Y2;

	// Suppressor echo estimate.
	const auto& echo_spectrum =
	aec_state_.UsableLinearEstimate() ? S2_linear : R2;

	// Determine if the suppressor should assume clock drift.
	const bool clock_drift = config_.echo_removal_control.has_clock_drift \|\|
	echo_path_variability.clock_drift;

	// Compute preferred gains.
	float high_bands_gain;
	suppression_gain_.GetGain(nearend_spectrum, echo_spectrum, R2,
	cng_.NoiseSpectrum(), render_signal_analyzer_,
	aec_state_, x, clock_drift, &high_bands_gain, &G);

	suppression_filter_.ApplyGain(comfort_noise, high_band_comfort_noise, G,
	high_bands_gain, Y_fft, y);

	} else {
	G.fill(0.f);
	}

	// Update the metrics.
	metrics_.Update(aec_state_, cng_.NoiseSpectrum()[0], G);

	// Debug outputs for the purpose of development and analysis.
	data_dumper_->DumpWav("aec3_echo_estimate", kBlockSize,
	&subtractor_output[0].s_refined[0], 16000, 1);
	data_dumper_->DumpRaw("aec3_output", (*y)[0][0]);
	data_dumper_->DumpRaw("aec3_narrow_render",
	render_signal_analyzer_.NarrowPeakBand() ? 1 : 0);
	data_dumper_->DumpRaw("aec3_N2", cng_.NoiseSpectrum()[0]);
	data_dumper_->DumpRaw("aec3_suppressor_gain", G);
	data_dumper_->DumpWav("aec3_output",
	rtc::ArrayView<const float>(&(*y)[0][0][0], kBlockSize),
	16000, 1);
	data_dumper_->DumpRaw("aec3_using_subtractor_output[0]",
	aec_state_.UseLinearFilterOutput() ? 1 : 0);
	data_dumper_->DumpRaw("aec3_E2", E2[0]);
	data_dumper_->DumpRaw("aec3_S2_linear", S2_linear[0]);
	data_dumper_->DumpRaw("aec3_Y2", Y2[0]);
	data_dumper_->DumpRaw(
	"aec3_X2", render_buffer->Spectrum(
	aec_state_.MinDirectPathFilterDelay())[/channel=/0]);
	data_dumper_->DumpRaw("aec3_R2", R2[0]);
	data_dumper_->DumpRaw("aec3_filter_delay",
	aec_state_.MinDirectPathFilterDelay());
	data_dumper_->DumpRaw("aec3_capture_saturation",
	aec_state_.SaturatedCapture() ? 1 : 0);
	}

	void EchoRemoverImpl::FormLinearFilterOutput(
	const SubtractorOutput& subtractor_output,
	rtc::ArrayView<float> output) {
	RTC_DCHECK_EQ(subtractor_output.e_refined.size(), output.size());
	RTC_DCHECK_EQ(subtractor_output.e_coarse.size(), output.size());
	bool use_refined_output = true;
	if (use_coarse_filter_output_) {
	// As the output of the refined adaptive filter generally should be better
	// than the coarse filter output, add a margin and threshold for when
	// choosing the coarse filter output.
	if (subtractor_output.e2_coarse < 0.9f * subtractor_output.e2_refined &&
	subtractor_output.y2 > 30.f * 30.f * kBlockSize &&
	(subtractor_output.s2_refined > 60.f * 60.f * kBlockSize \|\|
	subtractor_output.s2_coarse > 60.f * 60.f * kBlockSize)) {
	use_refined_output = false;
	} else {
	// If the refined filter is diverged, choose the filter output that has
	// the lowest power.
	if (subtractor_output.e2_coarse < subtractor_output.e2_refined &&
	subtractor_output.y2 < subtractor_output.e2_refined) {
	use_refined_output = false;
	}
	}
	}

	SignalTransition(refined_filter_output_last_selected_
	? subtractor_output.e_refined
	: subtractor_output.e_coarse,
	use_refined_output ? subtractor_output.e_refined
	: subtractor_output.e_coarse,
	output);
	refined_filter_output_last_selected_ = use_refined_output;
	}

	} // namespace

	EchoRemover* EchoRemover::Create(const EchoCanceller3Config& config,
	int sample_rate_hz,
	size_t num_render_channels,
	size_t num_capture_channels) {
	return new EchoRemoverImpl(config, sample_rate_hz, num_render_channels,
	num_capture_channels);
	}

	} // namespace webrtc