modules/audio_processing/aec3/residual_echo_estimator.cc - mirrors/cros/chromiumos/third_party/webrtc-apm - 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/residual_echo_estimator.h"

 #include <stddef.h>
 #include <algorithm>
 #include <vector>

 #include "api/array_view.h"
 #include "modules/audio_processing/aec3/reverb_model.h"
 #include "modules/audio_processing/aec3/reverb_model_fallback.h"
 #include "rtc_base/checks.h"
 #include "system_wrappers/include/field_trial.h"

 namespace webrtc {
 namespace {

 bool EnableSoftTransparentMode() {
   return !field_trial::IsEnabled("WebRTC-Aec3SoftTransparentModeKillSwitch");
 }

 bool OverrideEstimatedEchoPathGain() {
   return !field_trial::IsEnabled("WebRTC-Aec3OverrideEchoPathGainKillSwitch");
 }

 bool UseFixedNonLinearReverbModel() {
   return field_trial::IsEnabled(
       "WebRTC-Aec3StandardNonlinearReverbModelKillSwitch");
 }

 // Computes the indexes that will be used for computing spectral power over
 // the blocks surrounding the delay.
 void GetRenderIndexesToAnalyze(
     const VectorBuffer& spectrum_buffer,
     const EchoCanceller3Config::EchoModel& echo_model,
     int filter_delay_blocks,
     bool gain_limiter_running,
     int headroom,
     int* idx_start,
     int* idx_stop) {
   RTC_DCHECK(idx_start);
   RTC_DCHECK(idx_stop);
   if (gain_limiter_running) {
     if (static_cast<size_t>(headroom) >
         echo_model.render_post_window_size_init) {
       *idx_start = spectrum_buffer.OffsetIndex(
           spectrum_buffer.read,
           -static_cast<int>(echo_model.render_post_window_size_init));
     } else {
       *idx_start = spectrum_buffer.IncIndex(spectrum_buffer.write);
     }

     *idx_stop = spectrum_buffer.OffsetIndex(
         spectrum_buffer.read, echo_model.render_pre_window_size_init);
   } else {
     size_t window_start;
     size_t window_end;
     window_start =
         std::max(0, filter_delay_blocks -
                         static_cast<int>(echo_model.render_pre_window_size));
     window_end = filter_delay_blocks +
                  static_cast<int>(echo_model.render_post_window_size);
     *idx_start =
         spectrum_buffer.OffsetIndex(spectrum_buffer.read, window_start);
     *idx_stop =
         spectrum_buffer.OffsetIndex(spectrum_buffer.read, window_end + 1);
   }
 }

 }  // namespace

 ResidualEchoEstimator::ResidualEchoEstimator(const EchoCanceller3Config& config)
     : config_(config),
       soft_transparent_mode_(EnableSoftTransparentMode()),
       override_estimated_echo_path_gain_(OverrideEstimatedEchoPathGain()),
       use_fixed_nonlinear_reverb_model_(UseFixedNonLinearReverbModel()) {
   if (config_.ep_strength.reverb_based_on_render) {
     echo_reverb_.reset(new ReverbModel());
   } else {
     echo_reverb_fallback.reset(
         new ReverbModelFallback(config_.filter.main.length_blocks));
   }
   Reset();
 }

 ResidualEchoEstimator::~ResidualEchoEstimator() = default;

 void ResidualEchoEstimator::Estimate(
     const AecState& aec_state,
     const RenderBuffer& render_buffer,
     const std::array<float, kFftLengthBy2Plus1>& S2_linear,
     const std::array<float, kFftLengthBy2Plus1>& Y2,
     std::array<float, kFftLengthBy2Plus1>* R2) {
   RTC_DCHECK(R2);

   // Estimate the power of the stationary noise in the render signal.
   RenderNoisePower(render_buffer, &X2_noise_floor_, &X2_noise_floor_counter_);

   // Estimate the residual echo power.
   if (aec_state.UsableLinearEstimate()) {
     LinearEstimate(S2_linear, aec_state.Erle(), aec_state.ErleUncertainty(),
                    R2);

     // When there is saturated echo, assume the same spectral content as is
     // present in the micropone signal.
     if (aec_state.SaturatedEcho()) {
       std::copy(Y2.begin(), Y2.end(), R2->begin());
     }

     // Adds the estimated unmodelled echo power to the residual echo power
     // estimate.
     if (echo_reverb_) {
       echo_reverb_->AddReverb(
           render_buffer.Spectrum(aec_state.FilterLengthBlocks() + 1),
           aec_state.GetReverbFrequencyResponse(), aec_state.ReverbDecay(), *R2);

     } else {
       RTC_DCHECK(echo_reverb_fallback);
       echo_reverb_fallback->AddEchoReverb(S2_linear,
                                           aec_state.FilterDelayBlocks(),
                                           aec_state.ReverbDecay(), R2);
     }

   } else {
     // Estimate the echo generating signal power.
     std::array<float, kFftLengthBy2Plus1> X2;

     EchoGeneratingPower(render_buffer.GetSpectrumBuffer(), config_.echo_model,
                         render_buffer.Headroom(), aec_state.FilterDelayBlocks(),
                         aec_state.IsSuppressionGainLimitActive(),
                         !aec_state.UseStationaryProperties(), &X2);

     // Subtract the stationary noise power to avoid stationary noise causing
     // excessive echo suppression.
     std::transform(X2.begin(), X2.end(), X2_noise_floor_.begin(), X2.begin(),
                    [&](float a, float b) {
                      return std::max(
                          0.f, a - config_.echo_model.stationary_gate_slope * b);
                    });

     float echo_path_gain;
     if (override_estimated_echo_path_gain_) {
       echo_path_gain = aec_state.TransparentMode() && soft_transparent_mode_
                            ? 0.01f
                            : config_.ep_strength.lf;
     } else {
       echo_path_gain = aec_state.TransparentMode() && soft_transparent_mode_
                            ? 0.01f
                            : aec_state.EchoPathGain();
     }
     NonLinearEstimate(echo_path_gain, X2, Y2, R2);

     // When there is saturated echo, assume the same spectral content as is
     // present in the micropone signal.
     if (aec_state.SaturatedEcho()) {
       std::copy(Y2.begin(), Y2.end(), R2->begin());
     }

     if (!(aec_state.TransparentMode() && soft_transparent_mode_)) {
       if (echo_reverb_) {
         echo_reverb_->AddReverbNoFreqShaping(
             render_buffer.Spectrum(aec_state.FilterDelayBlocks() + 1),
             echo_path_gain * echo_path_gain, aec_state.ReverbDecay(), *R2);
       } else {
         RTC_DCHECK(echo_reverb_fallback);
         echo_reverb_fallback->AddEchoReverb(*R2,
                                             config_.filter.main.length_blocks,
                                             aec_state.ReverbDecay(), R2);
       }
     }
   }

   if (aec_state.UseStationaryProperties()) {
     // Scale the echo according to echo audibility.
     std::array<float, kFftLengthBy2Plus1> residual_scaling;
     aec_state.GetResidualEchoScaling(residual_scaling);
     for (size_t k = 0; k < R2->size(); ++k) {
       (*R2)[k] *= residual_scaling[k];
       if (residual_scaling[k] == 0.f) {
         R2_hold_counter_[k] = 0;
       }
     }
   }
   if (!soft_transparent_mode_) {
     // If the echo is deemed inaudible, set the residual echo to zero.
     if (aec_state.TransparentMode()) {
       R2->fill(0.f);
       R2_old_.fill(0.f);
       R2_hold_counter_.fill(0.f);
     }
   }

   std::copy(R2->begin(), R2->end(), R2_old_.begin());
 }

 void ResidualEchoEstimator::Reset() {
   if (echo_reverb_) {
     echo_reverb_->Reset();
   } else {
     RTC_DCHECK(echo_reverb_fallback);
     echo_reverb_fallback->Reset();
   }
   X2_noise_floor_counter_.fill(config_.echo_model.noise_floor_hold);
   X2_noise_floor_.fill(config_.echo_model.min_noise_floor_power);
   R2_old_.fill(0.f);
   R2_hold_counter_.fill(0.f);
 }

 void ResidualEchoEstimator::LinearEstimate(
     const std::array<float, kFftLengthBy2Plus1>& S2_linear,
     const std::array<float, kFftLengthBy2Plus1>& erle,
     absl::optional<float> erle_uncertainty,
     std::array<float, kFftLengthBy2Plus1>* R2) {
   std::fill(R2_hold_counter_.begin(), R2_hold_counter_.end(), 10.f);
   if (erle_uncertainty) {
     for (size_t k = 0; k < R2->size(); ++k) {
       (*R2)[k] = S2_linear[k] * *erle_uncertainty;
     }
   } else {
     std::transform(erle.begin(), erle.end(), S2_linear.begin(), R2->begin(),
                    [](float a, float b) {
                      RTC_DCHECK_LT(0.f, a);
                      return b / a;
                    });
   }
 }

 void ResidualEchoEstimator::NonLinearEstimate(
     float echo_path_gain,
     const std::array<float, kFftLengthBy2Plus1>& X2,
     const std::array<float, kFftLengthBy2Plus1>& Y2,
     std::array<float, kFftLengthBy2Plus1>* R2) {
   // Compute preliminary residual echo.
   std::transform(X2.begin(), X2.end(), R2->begin(), [echo_path_gain](float a) {
     return a * echo_path_gain * echo_path_gain;
   });

   if (use_fixed_nonlinear_reverb_model_) {
     for (size_t k = 0; k < R2->size(); ++k) {
       // Update hold counter.
       R2_hold_counter_[k] = R2_old_[k] < (*R2)[k] ? 0 : R2_hold_counter_[k] + 1;

       // Compute the residual echo by holding a maximum echo powers and an echo
       // fading corresponding to a room with an RT60 value of about 50 ms.
       (*R2)[k] =
           R2_hold_counter_[k] < config_.echo_model.nonlinear_hold
               ? std::max((*R2)[k], R2_old_[k])
               : std::min((*R2)[k] +
                              R2_old_[k] * config_.echo_model.nonlinear_release,
                          Y2[k]);
     }
   }
 }

 void ResidualEchoEstimator::EchoGeneratingPower(
     const VectorBuffer& spectrum_buffer,
     const EchoCanceller3Config::EchoModel& echo_model,
     int headroom_spectrum_buffer,
     int filter_delay_blocks,
     bool gain_limiter_running,
     bool apply_noise_gating,
     std::array<float, kFftLengthBy2Plus1>* X2) const {
   int idx_stop, idx_start;

   RTC_DCHECK(X2);
   GetRenderIndexesToAnalyze(spectrum_buffer, config_.echo_model,
                             filter_delay_blocks, gain_limiter_running,
                             headroom_spectrum_buffer, &idx_start, &idx_stop);

   X2->fill(0.f);
   for (int k = idx_start; k != idx_stop; k = spectrum_buffer.IncIndex(k)) {
     std::transform(X2->begin(), X2->end(), spectrum_buffer.buffer[k].begin(),
                    X2->begin(),
                    [](float a, float b) { return std::max(a, b); });
   }

   if (apply_noise_gating) {
     // Apply soft noise gate.
     std::for_each(X2->begin(), X2->end(), [&](float& a) {
       if (config_.echo_model.noise_gate_power > a) {
         a = std::max(0.f, a - config_.echo_model.noise_gate_slope *
                                   (config_.echo_model.noise_gate_power - a));
       }
     });
   }
 }

 void ResidualEchoEstimator::RenderNoisePower(
     const RenderBuffer& render_buffer,
     std::array<float, kFftLengthBy2Plus1>* X2_noise_floor,
     std::array<int, kFftLengthBy2Plus1>* X2_noise_floor_counter) const {
   RTC_DCHECK(X2_noise_floor);
   RTC_DCHECK(X2_noise_floor_counter);

   const auto render_power = render_buffer.Spectrum(0);
   RTC_DCHECK_EQ(X2_noise_floor->size(), render_power.size());
   RTC_DCHECK_EQ(X2_noise_floor_counter->size(), render_power.size());

   // Estimate the stationary noise power in a minimum statistics manner.
   for (size_t k = 0; k < render_power.size(); ++k) {
     // Decrease rapidly.
     if (render_power[k] < (*X2_noise_floor)[k]) {
       (*X2_noise_floor)[k] = render_power[k];
       (*X2_noise_floor_counter)[k] = 0;
     } else {
       // Increase in a delayed, leaky manner.
       if ((*X2_noise_floor_counter)[k] >=
           static_cast<int>(config_.echo_model.noise_floor_hold)) {
         (*X2_noise_floor)[k] =
             std::max((*X2_noise_floor)[k] * 1.1f,
                      config_.echo_model.min_noise_floor_power);
       } else {
         ++(*X2_noise_floor_counter)[k];
       }
     }
   }
 }

 }  // 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/residual_echo_estimator.h"

	#include <stddef.h>
	#include <algorithm>
	#include <vector>

	#include "api/array_view.h"
	#include "modules/audio_processing/aec3/reverb_model.h"
	#include "modules/audio_processing/aec3/reverb_model_fallback.h"
	#include "rtc_base/checks.h"
	#include "system_wrappers/include/field_trial.h"

	namespace webrtc {
	namespace {

	bool EnableSoftTransparentMode() {
	return !field_trial::IsEnabled("WebRTC-Aec3SoftTransparentModeKillSwitch");
	}

	bool OverrideEstimatedEchoPathGain() {
	return !field_trial::IsEnabled("WebRTC-Aec3OverrideEchoPathGainKillSwitch");
	}

	bool UseFixedNonLinearReverbModel() {
	return field_trial::IsEnabled(
	"WebRTC-Aec3StandardNonlinearReverbModelKillSwitch");
	}

	// Computes the indexes that will be used for computing spectral power over
	// the blocks surrounding the delay.
	void GetRenderIndexesToAnalyze(
	const VectorBuffer& spectrum_buffer,
	const EchoCanceller3Config::EchoModel& echo_model,
	int filter_delay_blocks,
	bool gain_limiter_running,
	int headroom,
	int* idx_start,
	int* idx_stop) {
	RTC_DCHECK(idx_start);
	RTC_DCHECK(idx_stop);
	if (gain_limiter_running) {
	if (static_cast<size_t>(headroom) >
	echo_model.render_post_window_size_init) {
	*idx_start = spectrum_buffer.OffsetIndex(
	spectrum_buffer.read,
	-static_cast<int>(echo_model.render_post_window_size_init));
	} else {
	*idx_start = spectrum_buffer.IncIndex(spectrum_buffer.write);
	}

	*idx_stop = spectrum_buffer.OffsetIndex(
	spectrum_buffer.read, echo_model.render_pre_window_size_init);
	} else {
	size_t window_start;
	size_t window_end;
	window_start =
	std::max(0, filter_delay_blocks -
	static_cast<int>(echo_model.render_pre_window_size));
	window_end = filter_delay_blocks +
	static_cast<int>(echo_model.render_post_window_size);
	*idx_start =
	spectrum_buffer.OffsetIndex(spectrum_buffer.read, window_start);
	*idx_stop =
	spectrum_buffer.OffsetIndex(spectrum_buffer.read, window_end + 1);
	}
	}

	} // namespace

	ResidualEchoEstimator::ResidualEchoEstimator(const EchoCanceller3Config& config)
	: config_(config),
	soft_transparent_mode_(EnableSoftTransparentMode()),
	override_estimated_echo_path_gain_(OverrideEstimatedEchoPathGain()),
	use_fixed_nonlinear_reverb_model_(UseFixedNonLinearReverbModel()) {
	if (config_.ep_strength.reverb_based_on_render) {
	echo_reverb_.reset(new ReverbModel());
	} else {
	echo_reverb_fallback.reset(
	new ReverbModelFallback(config_.filter.main.length_blocks));
	}
	Reset();
	}

	ResidualEchoEstimator::~ResidualEchoEstimator() = default;

	void ResidualEchoEstimator::Estimate(
	const AecState& aec_state,
	const RenderBuffer& render_buffer,
	const std::array<float, kFftLengthBy2Plus1>& S2_linear,
	const std::array<float, kFftLengthBy2Plus1>& Y2,
	std::array<float, kFftLengthBy2Plus1>* R2) {
	RTC_DCHECK(R2);

	// Estimate the power of the stationary noise in the render signal.
	RenderNoisePower(render_buffer, &X2_noise_floor_, &X2_noise_floor_counter_);

	// Estimate the residual echo power.
	if (aec_state.UsableLinearEstimate()) {
	LinearEstimate(S2_linear, aec_state.Erle(), aec_state.ErleUncertainty(),
	R2);

	// When there is saturated echo, assume the same spectral content as is
	// present in the micropone signal.
	if (aec_state.SaturatedEcho()) {
	std::copy(Y2.begin(), Y2.end(), R2->begin());
	}

	// Adds the estimated unmodelled echo power to the residual echo power
	// estimate.
	if (echo_reverb_) {
	echo_reverb_->AddReverb(
	render_buffer.Spectrum(aec_state.FilterLengthBlocks() + 1),
	aec_state.GetReverbFrequencyResponse(), aec_state.ReverbDecay(), *R2);

	} else {
	RTC_DCHECK(echo_reverb_fallback);
	echo_reverb_fallback->AddEchoReverb(S2_linear,
	aec_state.FilterDelayBlocks(),
	aec_state.ReverbDecay(), R2);
	}

	} else {
	// Estimate the echo generating signal power.
	std::array<float, kFftLengthBy2Plus1> X2;

	EchoGeneratingPower(render_buffer.GetSpectrumBuffer(), config_.echo_model,
	render_buffer.Headroom(), aec_state.FilterDelayBlocks(),
	aec_state.IsSuppressionGainLimitActive(),
	!aec_state.UseStationaryProperties(), &X2);

	// Subtract the stationary noise power to avoid stationary noise causing
	// excessive echo suppression.
	std::transform(X2.begin(), X2.end(), X2_noise_floor_.begin(), X2.begin(),
	[&](float a, float b) {
	return std::max(
	0.f, a - config_.echo_model.stationary_gate_slope * b);
	});

	float echo_path_gain;
	if (override_estimated_echo_path_gain_) {
	echo_path_gain = aec_state.TransparentMode() && soft_transparent_mode_
	? 0.01f
	: config_.ep_strength.lf;
	} else {
	echo_path_gain = aec_state.TransparentMode() && soft_transparent_mode_
	? 0.01f
	: aec_state.EchoPathGain();
	}
	NonLinearEstimate(echo_path_gain, X2, Y2, R2);

	// When there is saturated echo, assume the same spectral content as is
	// present in the micropone signal.
	if (aec_state.SaturatedEcho()) {
	std::copy(Y2.begin(), Y2.end(), R2->begin());
	}

	if (!(aec_state.TransparentMode() && soft_transparent_mode_)) {
	if (echo_reverb_) {
	echo_reverb_->AddReverbNoFreqShaping(
	render_buffer.Spectrum(aec_state.FilterDelayBlocks() + 1),
	echo_path_gain * echo_path_gain, aec_state.ReverbDecay(), *R2);
	} else {
	RTC_DCHECK(echo_reverb_fallback);
	echo_reverb_fallback->AddEchoReverb(*R2,
	config_.filter.main.length_blocks,
	aec_state.ReverbDecay(), R2);
	}
	}
	}

	if (aec_state.UseStationaryProperties()) {
	// Scale the echo according to echo audibility.
	std::array<float, kFftLengthBy2Plus1> residual_scaling;
	aec_state.GetResidualEchoScaling(residual_scaling);
	for (size_t k = 0; k < R2->size(); ++k) {
	(R2)[k] = residual_scaling[k];
	if (residual_scaling[k] == 0.f) {
	R2_hold_counter_[k] = 0;
	}
	}
	}
	if (!soft_transparent_mode_) {
	// If the echo is deemed inaudible, set the residual echo to zero.
	if (aec_state.TransparentMode()) {
	R2->fill(0.f);
	R2_old_.fill(0.f);
	R2_hold_counter_.fill(0.f);
	}
	}

	std::copy(R2->begin(), R2->end(), R2_old_.begin());
	}

	void ResidualEchoEstimator::Reset() {
	if (echo_reverb_) {
	echo_reverb_->Reset();
	} else {
	RTC_DCHECK(echo_reverb_fallback);
	echo_reverb_fallback->Reset();
	}
	X2_noise_floor_counter_.fill(config_.echo_model.noise_floor_hold);
	X2_noise_floor_.fill(config_.echo_model.min_noise_floor_power);
	R2_old_.fill(0.f);
	R2_hold_counter_.fill(0.f);
	}

	void ResidualEchoEstimator::LinearEstimate(
	const std::array<float, kFftLengthBy2Plus1>& S2_linear,
	const std::array<float, kFftLengthBy2Plus1>& erle,
	absl::optional<float> erle_uncertainty,
	std::array<float, kFftLengthBy2Plus1>* R2) {
	std::fill(R2_hold_counter_.begin(), R2_hold_counter_.end(), 10.f);
	if (erle_uncertainty) {
	for (size_t k = 0; k < R2->size(); ++k) {
	(R2)[k] = S2_linear[k] *erle_uncertainty;
	}
	} else {
	std::transform(erle.begin(), erle.end(), S2_linear.begin(), R2->begin(),
	[](float a, float b) {
	RTC_DCHECK_LT(0.f, a);
	return b / a;
	});
	}
	}

	void ResidualEchoEstimator::NonLinearEstimate(
	float echo_path_gain,
	const std::array<float, kFftLengthBy2Plus1>& X2,
	const std::array<float, kFftLengthBy2Plus1>& Y2,
	std::array<float, kFftLengthBy2Plus1>* R2) {
	// Compute preliminary residual echo.
	std::transform(X2.begin(), X2.end(), R2->begin(), [echo_path_gain](float a) {
	return a * echo_path_gain * echo_path_gain;
	});

	if (use_fixed_nonlinear_reverb_model_) {
	for (size_t k = 0; k < R2->size(); ++k) {
	// Update hold counter.
	R2_hold_counter_[k] = R2_old_[k] < (*R2)[k] ? 0 : R2_hold_counter_[k] + 1;

	// Compute the residual echo by holding a maximum echo powers and an echo
	// fading corresponding to a room with an RT60 value of about 50 ms.
	(*R2)[k] =
	R2_hold_counter_[k] < config_.echo_model.nonlinear_hold
	? std::max((*R2)[k], R2_old_[k])
	: std::min((*R2)[k] +
	R2_old_[k] * config_.echo_model.nonlinear_release,
	Y2[k]);
	}
	}
	}

	void ResidualEchoEstimator::EchoGeneratingPower(
	const VectorBuffer& spectrum_buffer,
	const EchoCanceller3Config::EchoModel& echo_model,
	int headroom_spectrum_buffer,
	int filter_delay_blocks,
	bool gain_limiter_running,
	bool apply_noise_gating,
	std::array<float, kFftLengthBy2Plus1>* X2) const {
	int idx_stop, idx_start;

	RTC_DCHECK(X2);
	GetRenderIndexesToAnalyze(spectrum_buffer, config_.echo_model,
	filter_delay_blocks, gain_limiter_running,
	headroom_spectrum_buffer, &idx_start, &idx_stop);

	X2->fill(0.f);
	for (int k = idx_start; k != idx_stop; k = spectrum_buffer.IncIndex(k)) {
	std::transform(X2->begin(), X2->end(), spectrum_buffer.buffer[k].begin(),
	X2->begin(),
	[](float a, float b) { return std::max(a, b); });
	}

	if (apply_noise_gating) {
	// Apply soft noise gate.
	std::for_each(X2->begin(), X2->end(), [&](float& a) {
	if (config_.echo_model.noise_gate_power > a) {
	a = std::max(0.f, a - config_.echo_model.noise_gate_slope *
	(config_.echo_model.noise_gate_power - a));
	}
	});
	}
	}

	void ResidualEchoEstimator::RenderNoisePower(
	const RenderBuffer& render_buffer,
	std::array<float, kFftLengthBy2Plus1>* X2_noise_floor,
	std::array<int, kFftLengthBy2Plus1>* X2_noise_floor_counter) const {
	RTC_DCHECK(X2_noise_floor);
	RTC_DCHECK(X2_noise_floor_counter);

	const auto render_power = render_buffer.Spectrum(0);
	RTC_DCHECK_EQ(X2_noise_floor->size(), render_power.size());
	RTC_DCHECK_EQ(X2_noise_floor_counter->size(), render_power.size());

	// Estimate the stationary noise power in a minimum statistics manner.
	for (size_t k = 0; k < render_power.size(); ++k) {
	// Decrease rapidly.
	if (render_power[k] < (*X2_noise_floor)[k]) {
	(*X2_noise_floor)[k] = render_power[k];
	(*X2_noise_floor_counter)[k] = 0;
	} else {
	// Increase in a delayed, leaky manner.
	if ((*X2_noise_floor_counter)[k] >=
	static_cast<int>(config_.echo_model.noise_floor_hold)) {
	(*X2_noise_floor)[k] =
	std::max((X2_noise_floor)[k] 1.1f,
	config_.echo_model.min_noise_floor_power);
	} else {
	++(*X2_noise_floor_counter)[k];
	}
	}
	}
	}

	} // namespace webrtc