modules/audio_processing/aec3/suppression_gain.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/suppression_gain.h"

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

 #include <algorithm>
 #include <numeric>

 #include "modules/audio_processing/aec3/dominant_nearend_detector.h"
 #include "modules/audio_processing/aec3/moving_average.h"
 #include "modules/audio_processing/aec3/subband_nearend_detector.h"
 #include "modules/audio_processing/aec3/vector_math.h"
 #include "modules/audio_processing/logging/apm_data_dumper.h"
 #include "rtc_base/checks.h"
 #include "system_wrappers/include/field_trial.h"

 namespace webrtc {
 namespace {

 void LimitLowFrequencyGains(std::array<float, kFftLengthBy2Plus1>* gain) {
   // Limit the low frequency gains to avoid the impact of the high-pass filter
   // on the lower-frequency gain influencing the overall achieved gain.
   (*gain)[0] = (*gain)[1] = std::min((*gain)[1], (*gain)[2]);
 }

 void LimitHighFrequencyGains(bool conservative_hf_suppression,
                              std::array<float, kFftLengthBy2Plus1>* gain) {
   // Limit the high frequency gains to avoid echo leakage due to an imperfect
   // filter.
   constexpr size_t kFirstBandToLimit = (64 * 2000) / 8000;
   const float min_upper_gain = (*gain)[kFirstBandToLimit];
   std::for_each(
       gain->begin() + kFirstBandToLimit + 1, gain->end(),
       [min_upper_gain](float& a) { a = std::min(a, min_upper_gain); });
   (*gain)[kFftLengthBy2] = (*gain)[kFftLengthBy2Minus1];

   if (conservative_hf_suppression) {
     // Limits the gain in the frequencies for which the adaptive filter has not
     // converged.
     // TODO(peah): Make adaptive to take the actual filter error into account.
     constexpr size_t kUpperAccurateBandPlus1 = 29;

     constexpr float oneByBandsInSum =
         1 / static_cast<float>(kUpperAccurateBandPlus1 - 20);
     const float hf_gain_bound =
         std::accumulate(gain->begin() + 20,
                         gain->begin() + kUpperAccurateBandPlus1, 0.f) *
         oneByBandsInSum;

     std::for_each(
         gain->begin() + kUpperAccurateBandPlus1, gain->end(),
         [hf_gain_bound](float& a) { a = std::min(a, hf_gain_bound); });
   }
 }

 // Scales the echo according to assessed audibility at the other end.
 void WeightEchoForAudibility(const EchoCanceller3Config& config,
                              rtc::ArrayView<const float> echo,
                              rtc::ArrayView<float> weighted_echo) {
   RTC_DCHECK_EQ(kFftLengthBy2Plus1, echo.size());
   RTC_DCHECK_EQ(kFftLengthBy2Plus1, weighted_echo.size());

   auto weigh = [](float threshold, float normalizer, size_t begin, size_t end,
                   rtc::ArrayView<const float> echo,
                   rtc::ArrayView<float> weighted_echo) {
     for (size_t k = begin; k < end; ++k) {
       if (echo[k] < threshold) {
         float tmp = (threshold - echo[k]) * normalizer;
         weighted_echo[k] = echo[k] * std::max(0.f, 1.f - tmp * tmp);
       } else {
         weighted_echo[k] = echo[k];
       }
     }
   };

   float threshold = config.echo_audibility.floor_power *
                     config.echo_audibility.audibility_threshold_lf;
   float normalizer = 1.f / (threshold - config.echo_audibility.floor_power);
   weigh(threshold, normalizer, 0, 3, echo, weighted_echo);

   threshold = config.echo_audibility.floor_power *
               config.echo_audibility.audibility_threshold_mf;
   normalizer = 1.f / (threshold - config.echo_audibility.floor_power);
   weigh(threshold, normalizer, 3, 7, echo, weighted_echo);

   threshold = config.echo_audibility.floor_power *
               config.echo_audibility.audibility_threshold_hf;
   normalizer = 1.f / (threshold - config.echo_audibility.floor_power);
   weigh(threshold, normalizer, 7, kFftLengthBy2Plus1, echo, weighted_echo);
 }

 }  // namespace

 std::atomic<int> SuppressionGain::instance_count_(0);

 float SuppressionGain::UpperBandsGain(
     rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>> echo_spectrum,
     rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
         comfort_noise_spectrum,
     const absl::optional<int>& narrow_peak_band,
     bool saturated_echo,
     const Block& render,
     const std::array<float, kFftLengthBy2Plus1>& low_band_gain) const {
   RTC_DCHECK_LT(0, render.NumBands());
   if (render.NumBands() == 1) {
     return 1.f;
   }
   const int num_render_channels = render.NumChannels();

   if (narrow_peak_band &&
       (*narrow_peak_band > static_cast<int>(kFftLengthBy2Plus1 - 10))) {
     return 0.001f;
   }

   constexpr size_t kLowBandGainLimit = kFftLengthBy2 / 2;
   const float gain_below_8_khz = *std::min_element(
       low_band_gain.begin() + kLowBandGainLimit, low_band_gain.end());

   // Always attenuate the upper bands when there is saturated echo.
   if (saturated_echo) {
     return std::min(0.001f, gain_below_8_khz);
   }

   // Compute the upper and lower band energies.
   const auto sum_of_squares = [](float a, float b) { return a + b * b; };
   float low_band_energy = 0.f;
   for (int ch = 0; ch < num_render_channels; ++ch) {
     const float channel_energy =
         std::accumulate(render.begin(/*band=*/0, ch),
                         render.end(/*band=*/0, ch), 0.0f, sum_of_squares);
     low_band_energy = std::max(low_band_energy, channel_energy);
   }
   float high_band_energy = 0.f;
   for (int k = 1; k < render.NumBands(); ++k) {
     for (int ch = 0; ch < num_render_channels; ++ch) {
       const float energy = std::accumulate(
           render.begin(k, ch), render.end(k, ch), 0.f, sum_of_squares);
       high_band_energy = std::max(high_band_energy, energy);
     }
   }

   // If there is more power in the lower frequencies than the upper frequencies,
   // or if the power in upper frequencies is low, do not bound the gain in the
   // upper bands.
   float anti_howling_gain;
   const float activation_threshold =
       kBlockSize * config_.suppressor.high_bands_suppression
                        .anti_howling_activation_threshold;
   if (high_band_energy < std::max(low_band_energy, activation_threshold)) {
     anti_howling_gain = 1.f;
   } else {
     // In all other cases, bound the gain for upper frequencies.
     RTC_DCHECK_LE(low_band_energy, high_band_energy);
     RTC_DCHECK_NE(0.f, high_band_energy);
     anti_howling_gain =
         config_.suppressor.high_bands_suppression.anti_howling_gain *
         sqrtf(low_band_energy / high_band_energy);
   }

   float gain_bound = 1.f;
   if (!dominant_nearend_detector_->IsNearendState()) {
     // Bound the upper gain during significant echo activity.
     const auto& cfg = config_.suppressor.high_bands_suppression;
     auto low_frequency_energy = [](rtc::ArrayView<const float> spectrum) {
       RTC_DCHECK_LE(16, spectrum.size());
       return std::accumulate(spectrum.begin() + 1, spectrum.begin() + 16, 0.f);
     };
     for (size_t ch = 0; ch < num_capture_channels_; ++ch) {
       const float echo_sum = low_frequency_energy(echo_spectrum[ch]);
       const float noise_sum = low_frequency_energy(comfort_noise_spectrum[ch]);
       if (echo_sum > cfg.enr_threshold * noise_sum) {
         gain_bound = cfg.max_gain_during_echo;
         break;
       }
     }
   }

   // Choose the gain as the minimum of the lower and upper gains.
   return std::min(std::min(gain_below_8_khz, anti_howling_gain), gain_bound);
 }

 // Computes the gain to reduce the echo to a non audible level.
 void SuppressionGain::GainToNoAudibleEcho(
     const std::array<float, kFftLengthBy2Plus1>& nearend,
     const std::array<float, kFftLengthBy2Plus1>& echo,
     const std::array<float, kFftLengthBy2Plus1>& masker,
     std::array<float, kFftLengthBy2Plus1>* gain) const {
   const auto& p = dominant_nearend_detector_->IsNearendState() ? nearend_params_
                                                                : normal_params_;
   for (size_t k = 0; k < gain->size(); ++k) {
     float enr = echo[k] / (nearend[k] + 1.f);  // Echo-to-nearend ratio.
     float emr = echo[k] / (masker[k] + 1.f);   // Echo-to-masker (noise) ratio.
     float g = 1.0f;
     if (enr > p.enr_transparent_[k] && emr > p.emr_transparent_[k]) {
       g = (p.enr_suppress_[k] - enr) /
           (p.enr_suppress_[k] - p.enr_transparent_[k]);
       g = std::max(g, p.emr_transparent_[k] / emr);
     }
     (*gain)[k] = g;
   }
 }

 // Compute the minimum gain as the attenuating gain to put the signal just
 // above the zero sample values.
 void SuppressionGain::GetMinGain(
     rtc::ArrayView<const float> weighted_residual_echo,
     rtc::ArrayView<const float> last_nearend,
     rtc::ArrayView<const float> last_echo,
     bool low_noise_render,
     bool saturated_echo,
     rtc::ArrayView<float> min_gain) const {
   if (!saturated_echo) {
     const float min_echo_power =
         low_noise_render ? config_.echo_audibility.low_render_limit
                          : config_.echo_audibility.normal_render_limit;

     for (size_t k = 0; k < min_gain.size(); ++k) {
       min_gain[k] = weighted_residual_echo[k] > 0.f
                         ? min_echo_power / weighted_residual_echo[k]
                         : 1.f;
       min_gain[k] = std::min(min_gain[k], 1.f);
     }

     if (!initial_state_ ||
         config_.suppressor.lf_smoothing_during_initial_phase) {
       const float& dec = dominant_nearend_detector_->IsNearendState()
                              ? nearend_params_.max_dec_factor_lf
                              : normal_params_.max_dec_factor_lf;

       for (int k = 0; k <= config_.suppressor.last_lf_smoothing_band; ++k) {
         // Make sure the gains of the low frequencies do not decrease too
         // quickly after strong nearend.
         if (last_nearend[k] > last_echo[k] ||
             k <= config_.suppressor.last_permanent_lf_smoothing_band) {
           min_gain[k] = std::max(min_gain[k], last_gain_[k] * dec);
           min_gain[k] = std::min(min_gain[k], 1.f);
         }
       }
     }
   } else {
     std::fill(min_gain.begin(), min_gain.end(), 0.f);
   }
 }

 // Compute the maximum gain by limiting the gain increase from the previous
 // gain.
 void SuppressionGain::GetMaxGain(rtc::ArrayView<float> max_gain) const {
   const auto& inc = dominant_nearend_detector_->IsNearendState()
                         ? nearend_params_.max_inc_factor
                         : normal_params_.max_inc_factor;
   const auto& floor = config_.suppressor.floor_first_increase;
   for (size_t k = 0; k < max_gain.size(); ++k) {
     max_gain[k] = std::min(std::max(last_gain_[k] * inc, floor), 1.f);
   }
 }

 void SuppressionGain::LowerBandGain(
     bool low_noise_render,
     const AecState& aec_state,
     rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
         suppressor_input,
     rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>> residual_echo,
     rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>> comfort_noise,
     bool clock_drift,
     std::array<float, kFftLengthBy2Plus1>* gain) {
   gain->fill(1.f);
   const bool saturated_echo = aec_state.SaturatedEcho();
   std::array<float, kFftLengthBy2Plus1> max_gain;
   GetMaxGain(max_gain);

   for (size_t ch = 0; ch < num_capture_channels_; ++ch) {
     std::array<float, kFftLengthBy2Plus1> G;
     std::array<float, kFftLengthBy2Plus1> nearend;
     nearend_smoothers_[ch].Average(suppressor_input[ch], nearend);

     // Weight echo power in terms of audibility.
     std::array<float, kFftLengthBy2Plus1> weighted_residual_echo;
     WeightEchoForAudibility(config_, residual_echo[ch], weighted_residual_echo);

     std::array<float, kFftLengthBy2Plus1> min_gain;
     GetMinGain(weighted_residual_echo, last_nearend_[ch], last_echo_[ch],
                low_noise_render, saturated_echo, min_gain);

     GainToNoAudibleEcho(nearend, weighted_residual_echo, comfort_noise[0], &G);

     // Clamp gains.
     for (size_t k = 0; k < gain->size(); ++k) {
       G[k] = std::max(std::min(G[k], max_gain[k]), min_gain[k]);
       (*gain)[k] = std::min((*gain)[k], G[k]);
     }

     // Store data required for the gain computation of the next block.
     std::copy(nearend.begin(), nearend.end(), last_nearend_[ch].begin());
     std::copy(weighted_residual_echo.begin(), weighted_residual_echo.end(),
               last_echo_[ch].begin());
   }

   LimitLowFrequencyGains(gain);
   // Use conservative high-frequency gains during clock-drift or when not in
   // dominant nearend.
   if (!dominant_nearend_detector_->IsNearendState() || clock_drift ||
       config_.suppressor.conservative_hf_suppression) {
     LimitHighFrequencyGains(config_.suppressor.conservative_hf_suppression,
                             gain);
   }

   // Store computed gains.
   std::copy(gain->begin(), gain->end(), last_gain_.begin());

   // Transform gains to amplitude domain.
   aec3::VectorMath(optimization_).Sqrt(*gain);
 }

 SuppressionGain::SuppressionGain(const EchoCanceller3Config& config,
                                  Aec3Optimization optimization,
                                  int sample_rate_hz,
                                  size_t num_capture_channels)
     : data_dumper_(new ApmDataDumper(instance_count_.fetch_add(1) + 1)),
       optimization_(optimization),
       config_(config),
       num_capture_channels_(num_capture_channels),
       state_change_duration_blocks_(
           static_cast<int>(config_.filter.config_change_duration_blocks)),
       last_nearend_(num_capture_channels_, {0}),
       last_echo_(num_capture_channels_, {0}),
       nearend_smoothers_(
           num_capture_channels_,
           aec3::MovingAverage(kFftLengthBy2Plus1,
                               config.suppressor.nearend_average_blocks)),
       nearend_params_(config_.suppressor.last_lf_band,
                       config_.suppressor.first_hf_band,
                       config_.suppressor.nearend_tuning),
       normal_params_(config_.suppressor.last_lf_band,
                      config_.suppressor.first_hf_band,
                      config_.suppressor.normal_tuning),
       use_unbounded_echo_spectrum_(config.suppressor.dominant_nearend_detection
                                        .use_unbounded_echo_spectrum) {
   RTC_DCHECK_LT(0, state_change_duration_blocks_);
   last_gain_.fill(1.f);
   if (config_.suppressor.use_subband_nearend_detection) {
     dominant_nearend_detector_ = std::make_unique<SubbandNearendDetector>(
         config_.suppressor.subband_nearend_detection, num_capture_channels_);
   } else {
     dominant_nearend_detector_ = std::make_unique<DominantNearendDetector>(
         config_.suppressor.dominant_nearend_detection, num_capture_channels_);
   }
   RTC_DCHECK(dominant_nearend_detector_);
 }

 SuppressionGain::~SuppressionGain() = default;

 void SuppressionGain::GetGain(
     rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
         nearend_spectrum,
     rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>> echo_spectrum,
     rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
         residual_echo_spectrum,
     rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
         residual_echo_spectrum_unbounded,
     rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
         comfort_noise_spectrum,
     const RenderSignalAnalyzer& render_signal_analyzer,
     const AecState& aec_state,
     const Block& render,
     bool clock_drift,
     float* high_bands_gain,
     std::array<float, kFftLengthBy2Plus1>* low_band_gain) {
   RTC_DCHECK(high_bands_gain);
   RTC_DCHECK(low_band_gain);

   // Choose residual echo spectrum for dominant nearend detection.
   const auto echo = use_unbounded_echo_spectrum_
                         ? residual_echo_spectrum_unbounded
                         : residual_echo_spectrum;

   // Update the nearend state selection.
   dominant_nearend_detector_->Update(nearend_spectrum, echo,
                                      comfort_noise_spectrum, initial_state_);

   // Compute gain for the lower band.
   bool low_noise_render = low_render_detector_.Detect(render);
   LowerBandGain(low_noise_render, aec_state, nearend_spectrum,
                 residual_echo_spectrum, comfort_noise_spectrum, clock_drift,
                 low_band_gain);

   // Compute the gain for the upper bands.
   const absl::optional<int> narrow_peak_band =
       render_signal_analyzer.NarrowPeakBand();

   *high_bands_gain =
       UpperBandsGain(echo_spectrum, comfort_noise_spectrum, narrow_peak_band,
                      aec_state.SaturatedEcho(), render, *low_band_gain);

   data_dumper_->DumpRaw("aec3_dominant_nearend",
                         dominant_nearend_detector_->IsNearendState());
 }

 void SuppressionGain::SetInitialState(bool state) {
   initial_state_ = state;
   if (state) {
     initial_state_change_counter_ = state_change_duration_blocks_;
   } else {
     initial_state_change_counter_ = 0;
   }
 }

 // Detects when the render signal can be considered to have low power and
 // consist of stationary noise.
 bool SuppressionGain::LowNoiseRenderDetector::Detect(const Block& render) {
   float x2_sum = 0.f;
   float x2_max = 0.f;
   for (int ch = 0; ch < render.NumChannels(); ++ch) {
     for (float x_k : render.View(/*band=*/0, ch)) {
       const float x2 = x_k * x_k;
       x2_sum += x2;
       x2_max = std::max(x2_max, x2);
     }
   }
   x2_sum = x2_sum / render.NumChannels();

   constexpr float kThreshold = 50.f * 50.f * 64.f;
   const bool low_noise_render =
       average_power_ < kThreshold && x2_max < 3 * average_power_;
   average_power_ = average_power_ * 0.9f + x2_sum * 0.1f;
   return low_noise_render;
 }

 SuppressionGain::GainParameters::GainParameters(
     int last_lf_band,
     int first_hf_band,
     const EchoCanceller3Config::Suppressor::Tuning& tuning)
     : max_inc_factor(tuning.max_inc_factor),
       max_dec_factor_lf(tuning.max_dec_factor_lf) {
   // Compute per-band masking thresholds.
   RTC_DCHECK_LT(last_lf_band, first_hf_band);
   auto& lf = tuning.mask_lf;
   auto& hf = tuning.mask_hf;
   RTC_DCHECK_LT(lf.enr_transparent, lf.enr_suppress);
   RTC_DCHECK_LT(hf.enr_transparent, hf.enr_suppress);
   for (int k = 0; k < static_cast<int>(kFftLengthBy2Plus1); k++) {
     float a;
     if (k <= last_lf_band) {
       a = 0.f;
     } else if (k < first_hf_band) {
       a = (k - last_lf_band) / static_cast<float>(first_hf_band - last_lf_band);
     } else {
       a = 1.f;
     }
     enr_transparent_[k] = (1 - a) * lf.enr_transparent + a * hf.enr_transparent;
     enr_suppress_[k] = (1 - a) * lf.enr_suppress + a * hf.enr_suppress;
     emr_transparent_[k] = (1 - a) * lf.emr_transparent + a * hf.emr_transparent;
   }
 }

 }  // 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/suppression_gain.h"

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

	#include <algorithm>
	#include <numeric>

	#include "modules/audio_processing/aec3/dominant_nearend_detector.h"
	#include "modules/audio_processing/aec3/moving_average.h"
	#include "modules/audio_processing/aec3/subband_nearend_detector.h"
	#include "modules/audio_processing/aec3/vector_math.h"
	#include "modules/audio_processing/logging/apm_data_dumper.h"
	#include "rtc_base/checks.h"
	#include "system_wrappers/include/field_trial.h"

	namespace webrtc {
	namespace {

	void LimitLowFrequencyGains(std::array<float, kFftLengthBy2Plus1>* gain) {
	// Limit the low frequency gains to avoid the impact of the high-pass filter
	// on the lower-frequency gain influencing the overall achieved gain.
	(gain)[0] = (gain)[1] = std::min((gain)[1], (gain)[2]);
	}

	void LimitHighFrequencyGains(bool conservative_hf_suppression,
	std::array<float, kFftLengthBy2Plus1>* gain) {
	// Limit the high frequency gains to avoid echo leakage due to an imperfect
	// filter.
	constexpr size_t kFirstBandToLimit = (64 * 2000) / 8000;
	const float min_upper_gain = (*gain)[kFirstBandToLimit];
	std::for_each(
	gain->begin() + kFirstBandToLimit + 1, gain->end(),
	[min_upper_gain](float& a) { a = std::min(a, min_upper_gain); });
	(gain)[kFftLengthBy2] = (gain)[kFftLengthBy2Minus1];

	if (conservative_hf_suppression) {
	// Limits the gain in the frequencies for which the adaptive filter has not
	// converged.
	// TODO(peah): Make adaptive to take the actual filter error into account.
	constexpr size_t kUpperAccurateBandPlus1 = 29;

	constexpr float oneByBandsInSum =
	1 / static_cast<float>(kUpperAccurateBandPlus1 - 20);
	const float hf_gain_bound =
	std::accumulate(gain->begin() + 20,
	gain->begin() + kUpperAccurateBandPlus1, 0.f) *
	oneByBandsInSum;

	std::for_each(
	gain->begin() + kUpperAccurateBandPlus1, gain->end(),
	[hf_gain_bound](float& a) { a = std::min(a, hf_gain_bound); });
	}
	}

	// Scales the echo according to assessed audibility at the other end.
	void WeightEchoForAudibility(const EchoCanceller3Config& config,
	rtc::ArrayView<const float> echo,
	rtc::ArrayView<float> weighted_echo) {
	RTC_DCHECK_EQ(kFftLengthBy2Plus1, echo.size());
	RTC_DCHECK_EQ(kFftLengthBy2Plus1, weighted_echo.size());

	auto weigh = [](float threshold, float normalizer, size_t begin, size_t end,
	rtc::ArrayView<const float> echo,
	rtc::ArrayView<float> weighted_echo) {
	for (size_t k = begin; k < end; ++k) {
	if (echo[k] < threshold) {
	float tmp = (threshold - echo[k]) * normalizer;
	weighted_echo[k] = echo[k] * std::max(0.f, 1.f - tmp * tmp);
	} else {
	weighted_echo[k] = echo[k];
	}
	}
	};

	float threshold = config.echo_audibility.floor_power *
	config.echo_audibility.audibility_threshold_lf;
	float normalizer = 1.f / (threshold - config.echo_audibility.floor_power);
	weigh(threshold, normalizer, 0, 3, echo, weighted_echo);

	threshold = config.echo_audibility.floor_power *
	config.echo_audibility.audibility_threshold_mf;
	normalizer = 1.f / (threshold - config.echo_audibility.floor_power);
	weigh(threshold, normalizer, 3, 7, echo, weighted_echo);

	threshold = config.echo_audibility.floor_power *
	config.echo_audibility.audibility_threshold_hf;
	normalizer = 1.f / (threshold - config.echo_audibility.floor_power);
	weigh(threshold, normalizer, 7, kFftLengthBy2Plus1, echo, weighted_echo);
	}

	} // namespace

	std::atomic<int> SuppressionGain::instance_count_(0);

	float SuppressionGain::UpperBandsGain(
	rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>> echo_spectrum,
	rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
	comfort_noise_spectrum,
	const absl::optional<int>& narrow_peak_band,
	bool saturated_echo,
	const Block& render,
	const std::array<float, kFftLengthBy2Plus1>& low_band_gain) const {
	RTC_DCHECK_LT(0, render.NumBands());
	if (render.NumBands() == 1) {
	return 1.f;
	}
	const int num_render_channels = render.NumChannels();

	if (narrow_peak_band &&
	(*narrow_peak_band > static_cast<int>(kFftLengthBy2Plus1 - 10))) {
	return 0.001f;
	}

	constexpr size_t kLowBandGainLimit = kFftLengthBy2 / 2;
	const float gain_below_8_khz = *std::min_element(
	low_band_gain.begin() + kLowBandGainLimit, low_band_gain.end());

	// Always attenuate the upper bands when there is saturated echo.
	if (saturated_echo) {
	return std::min(0.001f, gain_below_8_khz);
	}

	// Compute the upper and lower band energies.
	const auto sum_of_squares = [](float a, float b) { return a + b * b; };
	float low_band_energy = 0.f;
	for (int ch = 0; ch < num_render_channels; ++ch) {
	const float channel_energy =
	std::accumulate(render.begin(/band=/0, ch),
	render.end(/band=/0, ch), 0.0f, sum_of_squares);
	low_band_energy = std::max(low_band_energy, channel_energy);
	}
	float high_band_energy = 0.f;
	for (int k = 1; k < render.NumBands(); ++k) {
	for (int ch = 0; ch < num_render_channels; ++ch) {
	const float energy = std::accumulate(
	render.begin(k, ch), render.end(k, ch), 0.f, sum_of_squares);
	high_band_energy = std::max(high_band_energy, energy);
	}
	}

	// If there is more power in the lower frequencies than the upper frequencies,
	// or if the power in upper frequencies is low, do not bound the gain in the
	// upper bands.
	float anti_howling_gain;
	const float activation_threshold =
	kBlockSize * config_.suppressor.high_bands_suppression
	.anti_howling_activation_threshold;
	if (high_band_energy < std::max(low_band_energy, activation_threshold)) {
	anti_howling_gain = 1.f;
	} else {
	// In all other cases, bound the gain for upper frequencies.
	RTC_DCHECK_LE(low_band_energy, high_band_energy);
	RTC_DCHECK_NE(0.f, high_band_energy);
	anti_howling_gain =
	config_.suppressor.high_bands_suppression.anti_howling_gain *
	sqrtf(low_band_energy / high_band_energy);
	}

	float gain_bound = 1.f;
	if (!dominant_nearend_detector_->IsNearendState()) {
	// Bound the upper gain during significant echo activity.
	const auto& cfg = config_.suppressor.high_bands_suppression;
	auto low_frequency_energy = [](rtc::ArrayView<const float> spectrum) {
	RTC_DCHECK_LE(16, spectrum.size());
	return std::accumulate(spectrum.begin() + 1, spectrum.begin() + 16, 0.f);
	};
	for (size_t ch = 0; ch < num_capture_channels_; ++ch) {
	const float echo_sum = low_frequency_energy(echo_spectrum[ch]);
	const float noise_sum = low_frequency_energy(comfort_noise_spectrum[ch]);
	if (echo_sum > cfg.enr_threshold * noise_sum) {
	gain_bound = cfg.max_gain_during_echo;
	break;
	}
	}
	}

	// Choose the gain as the minimum of the lower and upper gains.
	return std::min(std::min(gain_below_8_khz, anti_howling_gain), gain_bound);
	}

	// Computes the gain to reduce the echo to a non audible level.
	void SuppressionGain::GainToNoAudibleEcho(
	const std::array<float, kFftLengthBy2Plus1>& nearend,
	const std::array<float, kFftLengthBy2Plus1>& echo,
	const std::array<float, kFftLengthBy2Plus1>& masker,
	std::array<float, kFftLengthBy2Plus1>* gain) const {
	const auto& p = dominant_nearend_detector_->IsNearendState() ? nearend_params_
	: normal_params_;
	for (size_t k = 0; k < gain->size(); ++k) {
	float enr = echo[k] / (nearend[k] + 1.f); // Echo-to-nearend ratio.
	float emr = echo[k] / (masker[k] + 1.f); // Echo-to-masker (noise) ratio.
	float g = 1.0f;
	if (enr > p.enr_transparent_[k] && emr > p.emr_transparent_[k]) {
	g = (p.enr_suppress_[k] - enr) /
	(p.enr_suppress_[k] - p.enr_transparent_[k]);
	g = std::max(g, p.emr_transparent_[k] / emr);
	}
	(*gain)[k] = g;
	}
	}

	// Compute the minimum gain as the attenuating gain to put the signal just
	// above the zero sample values.
	void SuppressionGain::GetMinGain(
	rtc::ArrayView<const float> weighted_residual_echo,
	rtc::ArrayView<const float> last_nearend,
	rtc::ArrayView<const float> last_echo,
	bool low_noise_render,
	bool saturated_echo,
	rtc::ArrayView<float> min_gain) const {
	if (!saturated_echo) {
	const float min_echo_power =
	low_noise_render ? config_.echo_audibility.low_render_limit
	: config_.echo_audibility.normal_render_limit;

	for (size_t k = 0; k < min_gain.size(); ++k) {
	min_gain[k] = weighted_residual_echo[k] > 0.f
	? min_echo_power / weighted_residual_echo[k]
	: 1.f;
	min_gain[k] = std::min(min_gain[k], 1.f);
	}

	if (!initial_state_ \|\|
	config_.suppressor.lf_smoothing_during_initial_phase) {
	const float& dec = dominant_nearend_detector_->IsNearendState()
	? nearend_params_.max_dec_factor_lf
	: normal_params_.max_dec_factor_lf;

	for (int k = 0; k <= config_.suppressor.last_lf_smoothing_band; ++k) {
	// Make sure the gains of the low frequencies do not decrease too
	// quickly after strong nearend.
	if (last_nearend[k] > last_echo[k] \|\|
	k <= config_.suppressor.last_permanent_lf_smoothing_band) {
	min_gain[k] = std::max(min_gain[k], last_gain_[k] * dec);
	min_gain[k] = std::min(min_gain[k], 1.f);
	}
	}
	}
	} else {
	std::fill(min_gain.begin(), min_gain.end(), 0.f);
	}
	}

	// Compute the maximum gain by limiting the gain increase from the previous
	// gain.
	void SuppressionGain::GetMaxGain(rtc::ArrayView<float> max_gain) const {
	const auto& inc = dominant_nearend_detector_->IsNearendState()
	? nearend_params_.max_inc_factor
	: normal_params_.max_inc_factor;
	const auto& floor = config_.suppressor.floor_first_increase;
	for (size_t k = 0; k < max_gain.size(); ++k) {
	max_gain[k] = std::min(std::max(last_gain_[k] * inc, floor), 1.f);
	}
	}

	void SuppressionGain::LowerBandGain(
	bool low_noise_render,
	const AecState& aec_state,
	rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
	suppressor_input,
	rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>> residual_echo,
	rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>> comfort_noise,
	bool clock_drift,
	std::array<float, kFftLengthBy2Plus1>* gain) {
	gain->fill(1.f);
	const bool saturated_echo = aec_state.SaturatedEcho();
	std::array<float, kFftLengthBy2Plus1> max_gain;
	GetMaxGain(max_gain);

	for (size_t ch = 0; ch < num_capture_channels_; ++ch) {
	std::array<float, kFftLengthBy2Plus1> G;
	std::array<float, kFftLengthBy2Plus1> nearend;
	nearend_smoothers_[ch].Average(suppressor_input[ch], nearend);

	// Weight echo power in terms of audibility.
	std::array<float, kFftLengthBy2Plus1> weighted_residual_echo;
	WeightEchoForAudibility(config_, residual_echo[ch], weighted_residual_echo);

	std::array<float, kFftLengthBy2Plus1> min_gain;
	GetMinGain(weighted_residual_echo, last_nearend_[ch], last_echo_[ch],
	low_noise_render, saturated_echo, min_gain);

	GainToNoAudibleEcho(nearend, weighted_residual_echo, comfort_noise[0], &G);

	// Clamp gains.
	for (size_t k = 0; k < gain->size(); ++k) {
	G[k] = std::max(std::min(G[k], max_gain[k]), min_gain[k]);
	(gain)[k] = std::min((gain)[k], G[k]);
	}

	// Store data required for the gain computation of the next block.
	std::copy(nearend.begin(), nearend.end(), last_nearend_[ch].begin());
	std::copy(weighted_residual_echo.begin(), weighted_residual_echo.end(),
	last_echo_[ch].begin());
	}

	LimitLowFrequencyGains(gain);
	// Use conservative high-frequency gains during clock-drift or when not in
	// dominant nearend.
	if (!dominant_nearend_detector_->IsNearendState() \|\| clock_drift \|\|
	config_.suppressor.conservative_hf_suppression) {
	LimitHighFrequencyGains(config_.suppressor.conservative_hf_suppression,
	gain);
	}

	// Store computed gains.
	std::copy(gain->begin(), gain->end(), last_gain_.begin());

	// Transform gains to amplitude domain.
	aec3::VectorMath(optimization_).Sqrt(*gain);
	}

	SuppressionGain::SuppressionGain(const EchoCanceller3Config& config,
	Aec3Optimization optimization,
	int sample_rate_hz,
	size_t num_capture_channels)
	: data_dumper_(new ApmDataDumper(instance_count_.fetch_add(1) + 1)),
	optimization_(optimization),
	config_(config),
	num_capture_channels_(num_capture_channels),
	state_change_duration_blocks_(
	static_cast<int>(config_.filter.config_change_duration_blocks)),
	last_nearend_(num_capture_channels_, {0}),
	last_echo_(num_capture_channels_, {0}),
	nearend_smoothers_(
	num_capture_channels_,
	aec3::MovingAverage(kFftLengthBy2Plus1,
	config.suppressor.nearend_average_blocks)),
	nearend_params_(config_.suppressor.last_lf_band,
	config_.suppressor.first_hf_band,
	config_.suppressor.nearend_tuning),
	normal_params_(config_.suppressor.last_lf_band,
	config_.suppressor.first_hf_band,
	config_.suppressor.normal_tuning),
	use_unbounded_echo_spectrum_(config.suppressor.dominant_nearend_detection
	.use_unbounded_echo_spectrum) {
	RTC_DCHECK_LT(0, state_change_duration_blocks_);
	last_gain_.fill(1.f);
	if (config_.suppressor.use_subband_nearend_detection) {
	dominant_nearend_detector_ = std::make_unique<SubbandNearendDetector>(
	config_.suppressor.subband_nearend_detection, num_capture_channels_);
	} else {
	dominant_nearend_detector_ = std::make_unique<DominantNearendDetector>(
	config_.suppressor.dominant_nearend_detection, num_capture_channels_);
	}
	RTC_DCHECK(dominant_nearend_detector_);
	}

	SuppressionGain::~SuppressionGain() = default;

	void SuppressionGain::GetGain(
	rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
	nearend_spectrum,
	rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>> echo_spectrum,
	rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
	residual_echo_spectrum,
	rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
	residual_echo_spectrum_unbounded,
	rtc::ArrayView<const std::array<float, kFftLengthBy2Plus1>>
	comfort_noise_spectrum,
	const RenderSignalAnalyzer& render_signal_analyzer,
	const AecState& aec_state,
	const Block& render,
	bool clock_drift,
	float* high_bands_gain,
	std::array<float, kFftLengthBy2Plus1>* low_band_gain) {
	RTC_DCHECK(high_bands_gain);
	RTC_DCHECK(low_band_gain);

	// Choose residual echo spectrum for dominant nearend detection.
	const auto echo = use_unbounded_echo_spectrum_
	? residual_echo_spectrum_unbounded
	: residual_echo_spectrum;

	// Update the nearend state selection.
	dominant_nearend_detector_->Update(nearend_spectrum, echo,
	comfort_noise_spectrum, initial_state_);

	// Compute gain for the lower band.
	bool low_noise_render = low_render_detector_.Detect(render);
	LowerBandGain(low_noise_render, aec_state, nearend_spectrum,
	residual_echo_spectrum, comfort_noise_spectrum, clock_drift,
	low_band_gain);

	// Compute the gain for the upper bands.
	const absl::optional<int> narrow_peak_band =
	render_signal_analyzer.NarrowPeakBand();

	*high_bands_gain =
	UpperBandsGain(echo_spectrum, comfort_noise_spectrum, narrow_peak_band,
	aec_state.SaturatedEcho(), render, *low_band_gain);

	data_dumper_->DumpRaw("aec3_dominant_nearend",
	dominant_nearend_detector_->IsNearendState());
	}

	void SuppressionGain::SetInitialState(bool state) {
	initial_state_ = state;
	if (state) {
	initial_state_change_counter_ = state_change_duration_blocks_;
	} else {
	initial_state_change_counter_ = 0;
	}
	}

	// Detects when the render signal can be considered to have low power and
	// consist of stationary noise.
	bool SuppressionGain::LowNoiseRenderDetector::Detect(const Block& render) {
	float x2_sum = 0.f;
	float x2_max = 0.f;
	for (int ch = 0; ch < render.NumChannels(); ++ch) {
	for (float x_k : render.View(/band=/0, ch)) {
	const float x2 = x_k * x_k;
	x2_sum += x2;
	x2_max = std::max(x2_max, x2);
	}
	}
	x2_sum = x2_sum / render.NumChannels();

	constexpr float kThreshold = 50.f * 50.f * 64.f;
	const bool low_noise_render =
	average_power_ < kThreshold && x2_max < 3 * average_power_;
	average_power_ = average_power_ * 0.9f + x2_sum * 0.1f;
	return low_noise_render;
	}

	SuppressionGain::GainParameters::GainParameters(
	int last_lf_band,
	int first_hf_band,
	const EchoCanceller3Config::Suppressor::Tuning& tuning)
	: max_inc_factor(tuning.max_inc_factor),
	max_dec_factor_lf(tuning.max_dec_factor_lf) {
	// Compute per-band masking thresholds.
	RTC_DCHECK_LT(last_lf_band, first_hf_band);
	auto& lf = tuning.mask_lf;
	auto& hf = tuning.mask_hf;
	RTC_DCHECK_LT(lf.enr_transparent, lf.enr_suppress);
	RTC_DCHECK_LT(hf.enr_transparent, hf.enr_suppress);
	for (int k = 0; k < static_cast<int>(kFftLengthBy2Plus1); k++) {
	float a;
	if (k <= last_lf_band) {
	a = 0.f;
	} else if (k < first_hf_band) {
	a = (k - last_lf_band) / static_cast<float>(first_hf_band - last_lf_band);
	} else {
	a = 1.f;
	}
	enr_transparent_[k] = (1 - a) * lf.enr_transparent + a * hf.enr_transparent;
	enr_suppress_[k] = (1 - a) * lf.enr_suppress + a * hf.enr_suppress;
	emr_transparent_[k] = (1 - a) * lf.emr_transparent + a * hf.emr_transparent;
	}
	}

	} // namespace webrtc