modules/audio_processing/agc2/input_volume_controller.cc - src - Git at Google

 /*
  *  Copyright (c) 2013 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/agc2/input_volume_controller.h"

 #include <algorithm>
 #include <cmath>

 #include "api/array_view.h"
 #include "modules/audio_processing/agc2/gain_map_internal.h"
 #include "modules/audio_processing/agc2/input_volume_stats_reporter.h"
 #include "modules/audio_processing/include/audio_frame_view.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/logging.h"
 #include "rtc_base/numerics/safe_minmax.h"
 #include "system_wrappers/include/field_trial.h"
 #include "system_wrappers/include/metrics.h"

 namespace webrtc {

 namespace {

 // Amount of error we tolerate in the microphone input volume (presumably due to
 // OS quantization) before we assume the user has manually adjusted the volume.
 constexpr int kVolumeQuantizationSlack = 25;

 constexpr int kMaxInputVolume = 255;
 static_assert(kGainMapSize > kMaxInputVolume, "gain map too small");

 // Maximum absolute RMS error.
 constexpr int KMaxAbsRmsErrorDbfs = 15;
 static_assert(KMaxAbsRmsErrorDbfs > 0, "");

 using Agc1ClippingPredictorConfig = AudioProcessing::Config::GainController1::
     AnalogGainController::ClippingPredictor;

 // TODO(webrtc:7494): Hardcode clipping predictor parameters and remove this
 // function after no longer needed in the ctor.
 Agc1ClippingPredictorConfig CreateClippingPredictorConfig(bool enabled) {
   Agc1ClippingPredictorConfig config;
   config.enabled = enabled;

   return config;
 }

 // Returns an input volume in the [`min_input_volume`, `kMaxInputVolume`] range
 // that reduces `gain_error_db`, which is a gain error estimated when
 // `input_volume` was applied, according to a fixed gain map.
 int ComputeVolumeUpdate(int gain_error_db,
                         int input_volume,
                         int min_input_volume) {
   RTC_DCHECK_GE(input_volume, 0);
   RTC_DCHECK_LE(input_volume, kMaxInputVolume);
   if (gain_error_db == 0) {
     return input_volume;
   }

   int new_volume = input_volume;
   if (gain_error_db > 0) {
     while (kGainMap[new_volume] - kGainMap[input_volume] < gain_error_db &&
            new_volume < kMaxInputVolume) {
       ++new_volume;
     }
   } else {
     while (kGainMap[new_volume] - kGainMap[input_volume] > gain_error_db &&
            new_volume > min_input_volume) {
       --new_volume;
     }
   }
   return new_volume;
 }

 // Returns the proportion of samples in the buffer which are at full-scale
 // (and presumably clipped).
 float ComputeClippedRatio(const float* const* audio,
                           size_t num_channels,
                           size_t samples_per_channel) {
   RTC_DCHECK_GT(samples_per_channel, 0);
   int num_clipped = 0;
   for (size_t ch = 0; ch < num_channels; ++ch) {
     int num_clipped_in_ch = 0;
     for (size_t i = 0; i < samples_per_channel; ++i) {
       RTC_DCHECK(audio[ch]);
       if (audio[ch][i] >= 32767.0f || audio[ch][i] <= -32768.0f) {
         ++num_clipped_in_ch;
       }
     }
     num_clipped = std::max(num_clipped, num_clipped_in_ch);
   }
   return static_cast<float>(num_clipped) / (samples_per_channel);
 }

 void LogClippingMetrics(int clipping_rate) {
   RTC_LOG(LS_INFO) << "[AGC2] Input clipping rate: " << clipping_rate << "%";
   RTC_HISTOGRAM_COUNTS_LINEAR(/*name=*/"WebRTC.Audio.Agc.InputClippingRate",
                               /*sample=*/clipping_rate, /*min=*/0, /*max=*/100,
                               /*bucket_count=*/50);
 }

 // Compares `speech_level_dbfs` to the [`target_range_min_dbfs`,
 // `target_range_max_dbfs`] range and returns the error to be compensated via
 // input volume adjustment. Returns a positive value when the level is below
 // the range, a negative value when the level is above the range, zero
 // otherwise.
 int GetSpeechLevelRmsErrorDb(float speech_level_dbfs,
                              int target_range_min_dbfs,
                              int target_range_max_dbfs) {
   constexpr float kMinSpeechLevelDbfs = -90.0f;
   constexpr float kMaxSpeechLevelDbfs = 30.0f;
   RTC_DCHECK_GE(speech_level_dbfs, kMinSpeechLevelDbfs);
   RTC_DCHECK_LE(speech_level_dbfs, kMaxSpeechLevelDbfs);
   speech_level_dbfs = rtc::SafeClamp<float>(
       speech_level_dbfs, kMinSpeechLevelDbfs, kMaxSpeechLevelDbfs);

   int rms_error_db = 0;
   if (speech_level_dbfs > target_range_max_dbfs) {
     rms_error_db = std::round(target_range_max_dbfs - speech_level_dbfs);
   } else if (speech_level_dbfs < target_range_min_dbfs) {
     rms_error_db = std::round(target_range_min_dbfs - speech_level_dbfs);
   }

   return rms_error_db;
 }

 }  // namespace

 MonoInputVolumeController::MonoInputVolumeController(
     int min_input_volume_after_clipping,
     int min_input_volume,
     int update_input_volume_wait_frames,
     float speech_probability_threshold,
     float speech_ratio_threshold)
     : min_input_volume_(min_input_volume),
       min_input_volume_after_clipping_(min_input_volume_after_clipping),
       max_input_volume_(kMaxInputVolume),
       update_input_volume_wait_frames_(
           std::max(update_input_volume_wait_frames, 1)),
       speech_probability_threshold_(speech_probability_threshold),
       speech_ratio_threshold_(speech_ratio_threshold) {
   RTC_DCHECK_GE(min_input_volume_, 0);
   RTC_DCHECK_LE(min_input_volume_, 255);
   RTC_DCHECK_GE(min_input_volume_after_clipping_, 0);
   RTC_DCHECK_LE(min_input_volume_after_clipping_, 255);
   RTC_DCHECK_GE(max_input_volume_, 0);
   RTC_DCHECK_LE(max_input_volume_, 255);
   RTC_DCHECK_GE(update_input_volume_wait_frames_, 0);
   RTC_DCHECK_GE(speech_probability_threshold_, 0.0f);
   RTC_DCHECK_LE(speech_probability_threshold_, 1.0f);
   RTC_DCHECK_GE(speech_ratio_threshold_, 0.0f);
   RTC_DCHECK_LE(speech_ratio_threshold_, 1.0f);
 }

 MonoInputVolumeController::~MonoInputVolumeController() = default;

 void MonoInputVolumeController::Initialize() {
   max_input_volume_ = kMaxInputVolume;
   capture_output_used_ = true;
   check_volume_on_next_process_ = true;
   frames_since_update_input_volume_ = 0;
   speech_frames_since_update_input_volume_ = 0;
   is_first_frame_ = true;
 }

 // A speeh segment is considered active if at least
 // `update_input_volume_wait_frames_` new frames have been processed since the
 // previous update and the ratio of non-silence frames (i.e., frames with a
 // `speech_probability` higher than `speech_probability_threshold_`) is at least
 // `speech_ratio_threshold_`.
 void MonoInputVolumeController::Process(absl::optional<int> rms_error_db,
                                         float speech_probability) {
   if (check_volume_on_next_process_) {
     check_volume_on_next_process_ = false;
     // We have to wait until the first process call to check the volume,
     // because Chromium doesn't guarantee it to be valid any earlier.
     CheckVolumeAndReset();
   }

   // Count frames with a high speech probability as speech.
   if (speech_probability >= speech_probability_threshold_) {
     ++speech_frames_since_update_input_volume_;
   }

   // Reset the counters and maybe update the input volume.
   if (++frames_since_update_input_volume_ >= update_input_volume_wait_frames_) {
     const float speech_ratio =
         static_cast<float>(speech_frames_since_update_input_volume_) /
         static_cast<float>(update_input_volume_wait_frames_);

     // Always reset the counters regardless of whether the volume changes or
     // not.
     frames_since_update_input_volume_ = 0;
     speech_frames_since_update_input_volume_ = 0;

     // Update the input volume if allowed.
     if (!is_first_frame_ && speech_ratio >= speech_ratio_threshold_ &&
         rms_error_db.has_value()) {
       UpdateInputVolume(*rms_error_db);
     }
   }

   is_first_frame_ = false;
 }

 void MonoInputVolumeController::HandleClipping(int clipped_level_step) {
   RTC_DCHECK_GT(clipped_level_step, 0);
   // Always decrease the maximum input volume, even if the current input volume
   // is below threshold.
   SetMaxLevel(std::max(min_input_volume_after_clipping_,
                        max_input_volume_ - clipped_level_step));
   if (log_to_histograms_) {
     RTC_HISTOGRAM_BOOLEAN("WebRTC.Audio.AgcClippingAdjustmentAllowed",
                           last_recommended_input_volume_ - clipped_level_step >=
                               min_input_volume_after_clipping_);
   }
   if (last_recommended_input_volume_ > min_input_volume_after_clipping_) {
     // Don't try to adjust the input volume if we're already below the limit. As
     // a consequence, if the user has brought the input volume above the limit,
     // we will still not react until the postproc updates the input volume.
     SetInputVolume(
         std::max(min_input_volume_after_clipping_,
                  last_recommended_input_volume_ - clipped_level_step));
     frames_since_update_input_volume_ = 0;
     speech_frames_since_update_input_volume_ = 0;
     is_first_frame_ = false;
   }
 }

 void MonoInputVolumeController::SetInputVolume(int new_volume) {
   int applied_input_volume = recommended_input_volume_;
   if (applied_input_volume == 0) {
     RTC_DLOG(LS_INFO)
         << "[AGC2] The applied input volume is zero, taking no action.";
     return;
   }
   if (applied_input_volume < 0 || applied_input_volume > kMaxInputVolume) {
     RTC_LOG(LS_ERROR) << "[AGC2] Invalid value for the applied input volume: "
                       << applied_input_volume;
     return;
   }

   // Detect manual input volume adjustments by checking if the
   // `applied_input_volume` is outside of the `[last_recommended_input_volume_ -
   // kVolumeQuantizationSlack, last_recommended_input_volume_ +
   // kVolumeQuantizationSlack]` range.
   if (applied_input_volume >
           last_recommended_input_volume_ + kVolumeQuantizationSlack ||
       applied_input_volume <
           last_recommended_input_volume_ - kVolumeQuantizationSlack) {
     RTC_DLOG(LS_INFO)
         << "[AGC2] The input volume was manually adjusted. Updating "
            "stored input volume from "
         << last_recommended_input_volume_ << " to " << applied_input_volume;
     last_recommended_input_volume_ = applied_input_volume;
     // Always allow the user to increase the volume.
     if (last_recommended_input_volume_ > max_input_volume_) {
       SetMaxLevel(last_recommended_input_volume_);
     }
     // Take no action in this case, since we can't be sure when the volume
     // was manually adjusted.
     frames_since_update_input_volume_ = 0;
     speech_frames_since_update_input_volume_ = 0;
     is_first_frame_ = false;
     return;
   }

   new_volume = std::min(new_volume, max_input_volume_);
   if (new_volume == last_recommended_input_volume_) {
     return;
   }

   recommended_input_volume_ = new_volume;
   RTC_DLOG(LS_INFO) << "[AGC2] Applied input volume: " << applied_input_volume
                     << " | last recommended input volume: "
                     << last_recommended_input_volume_
                     << " | newly recommended input volume: " << new_volume;
   last_recommended_input_volume_ = new_volume;
 }

 void MonoInputVolumeController::SetMaxLevel(int input_volume) {
   RTC_DCHECK_GE(input_volume, min_input_volume_after_clipping_);
   max_input_volume_ = input_volume;
   RTC_DLOG(LS_INFO) << "[AGC2] Maximum input volume updated: "
                     << max_input_volume_;
 }

 void MonoInputVolumeController::HandleCaptureOutputUsedChange(
     bool capture_output_used) {
   if (capture_output_used_ == capture_output_used) {
     return;
   }
   capture_output_used_ = capture_output_used;

   if (capture_output_used) {
     // When we start using the output, we should reset things to be safe.
     check_volume_on_next_process_ = true;
   }
 }

 int MonoInputVolumeController::CheckVolumeAndReset() {
   int input_volume = recommended_input_volume_;
   // Reasons for taking action at startup:
   // 1) A person starting a call is expected to be heard.
   // 2) Independent of interpretation of `input_volume` == 0 we should raise it
   // so the AGC can do its job properly.
   if (input_volume == 0 && !startup_) {
     RTC_DLOG(LS_INFO)
         << "[AGC2] The applied input volume is zero, taking no action.";
     return 0;
   }
   if (input_volume < 0 || input_volume > kMaxInputVolume) {
     RTC_LOG(LS_ERROR) << "[AGC2] Invalid value for the applied input volume: "
                       << input_volume;
     return -1;
   }
   RTC_DLOG(LS_INFO) << "[AGC2] Initial input volume: " << input_volume;

   if (input_volume < min_input_volume_) {
     input_volume = min_input_volume_;
     RTC_DLOG(LS_INFO)
         << "[AGC2] The initial input volume is too low, raising to "
         << input_volume;
     recommended_input_volume_ = input_volume;
   }

   last_recommended_input_volume_ = input_volume;
   startup_ = false;
   frames_since_update_input_volume_ = 0;
   speech_frames_since_update_input_volume_ = 0;
   is_first_frame_ = true;

   return 0;
 }

 void MonoInputVolumeController::UpdateInputVolume(int rms_error_db) {
   RTC_DLOG(LS_INFO) << "[AGC2] RMS error: " << rms_error_db << " dB";
   // Prevent too large microphone input volume changes by clamping the RMS
   // error.
   rms_error_db =
       rtc::SafeClamp(rms_error_db, -KMaxAbsRmsErrorDbfs, KMaxAbsRmsErrorDbfs);
   if (rms_error_db == 0) {
     return;
   }
   SetInputVolume(ComputeVolumeUpdate(
       rms_error_db, last_recommended_input_volume_, min_input_volume_));
 }

 InputVolumeController::InputVolumeController(int num_capture_channels,
                                              const Config& config)
     : num_capture_channels_(num_capture_channels),
       min_input_volume_(config.min_input_volume),
       capture_output_used_(true),
       clipped_level_step_(config.clipped_level_step),
       clipped_ratio_threshold_(config.clipped_ratio_threshold),
       clipped_wait_frames_(config.clipped_wait_frames),
       clipping_predictor_(CreateClippingPredictor(
           num_capture_channels,
           CreateClippingPredictorConfig(config.enable_clipping_predictor))),
       use_clipping_predictor_step_(
           !!clipping_predictor_ &&
           CreateClippingPredictorConfig(config.enable_clipping_predictor)
               .use_predicted_step),
       frames_since_clipped_(config.clipped_wait_frames),
       clipping_rate_log_counter_(0),
       clipping_rate_log_(0.0f),
       target_range_max_dbfs_(config.target_range_max_dbfs),
       target_range_min_dbfs_(config.target_range_min_dbfs),
       channel_controllers_(num_capture_channels) {
   RTC_LOG(LS_INFO)
       << "[AGC2] Input volume controller enabled. Minimum input volume: "
       << min_input_volume_;

   for (auto& controller : channel_controllers_) {
     controller = std::make_unique<MonoInputVolumeController>(
         config.clipped_level_min, min_input_volume_,
         config.update_input_volume_wait_frames,
         config.speech_probability_threshold, config.speech_ratio_threshold);
   }

   RTC_DCHECK(!channel_controllers_.empty());
   RTC_DCHECK_GT(clipped_level_step_, 0);
   RTC_DCHECK_LE(clipped_level_step_, 255);
   RTC_DCHECK_GT(clipped_ratio_threshold_, 0.0f);
   RTC_DCHECK_LT(clipped_ratio_threshold_, 1.0f);
   RTC_DCHECK_GT(clipped_wait_frames_, 0);
   channel_controllers_[0]->ActivateLogging();
 }

 InputVolumeController::~InputVolumeController() {}

 void InputVolumeController::Initialize() {
   for (auto& controller : channel_controllers_) {
     controller->Initialize();
   }
   capture_output_used_ = true;

   AggregateChannelLevels();
   clipping_rate_log_ = 0.0f;
   clipping_rate_log_counter_ = 0;

   applied_input_volume_ = absl::nullopt;
 }

 void InputVolumeController::AnalyzeInputAudio(int applied_input_volume,
                                               const AudioBuffer& audio_buffer) {
   RTC_DCHECK_GE(applied_input_volume, 0);
   RTC_DCHECK_LE(applied_input_volume, 255);

   SetAppliedInputVolume(applied_input_volume);

   RTC_DCHECK_EQ(audio_buffer.num_channels(), channel_controllers_.size());
   const float* const* audio = audio_buffer.channels_const();
   size_t samples_per_channel = audio_buffer.num_frames();
   RTC_DCHECK(audio);

   AggregateChannelLevels();
   if (!capture_output_used_) {
     return;
   }

   if (!!clipping_predictor_) {
     AudioFrameView<const float> frame = AudioFrameView<const float>(
         audio, num_capture_channels_, static_cast<int>(samples_per_channel));
     clipping_predictor_->Analyze(frame);
   }

   // Check for clipped samples. We do this in the preprocessing phase in order
   // to catch clipped echo as well.
   //
   // If we find a sufficiently clipped frame, drop the current microphone
   // input volume and enforce a new maximum input volume, dropped the same
   // amount from the current maximum. This harsh treatment is an effort to avoid
   // repeated clipped echo events.
   float clipped_ratio =
       ComputeClippedRatio(audio, num_capture_channels_, samples_per_channel);
   clipping_rate_log_ = std::max(clipped_ratio, clipping_rate_log_);
   clipping_rate_log_counter_++;
   constexpr int kNumFramesIn30Seconds = 3000;
   if (clipping_rate_log_counter_ == kNumFramesIn30Seconds) {
     LogClippingMetrics(std::round(100.0f * clipping_rate_log_));
     clipping_rate_log_ = 0.0f;
     clipping_rate_log_counter_ = 0;
   }

   if (frames_since_clipped_ < clipped_wait_frames_) {
     ++frames_since_clipped_;
     return;
   }

   const bool clipping_detected = clipped_ratio > clipped_ratio_threshold_;
   bool clipping_predicted = false;
   int predicted_step = 0;
   if (!!clipping_predictor_) {
     for (int channel = 0; channel < num_capture_channels_; ++channel) {
       const auto step = clipping_predictor_->EstimateClippedLevelStep(
           channel, recommended_input_volume_, clipped_level_step_,
           channel_controllers_[channel]->min_input_volume_after_clipping(),
           kMaxInputVolume);
       if (step.has_value()) {
         predicted_step = std::max(predicted_step, step.value());
         clipping_predicted = true;
       }
     }
   }

   if (clipping_detected) {
     RTC_DLOG(LS_INFO) << "[AGC2] Clipping detected (ratio: " << clipped_ratio
                       << ")";
   }

   int step = clipped_level_step_;
   if (clipping_predicted) {
     predicted_step = std::max(predicted_step, clipped_level_step_);
     RTC_DLOG(LS_INFO) << "[AGC2] Clipping predicted (volume down step: "
                       << predicted_step << ")";
     if (use_clipping_predictor_step_) {
       step = predicted_step;
     }
   }

   if (clipping_detected ||
       (clipping_predicted && use_clipping_predictor_step_)) {
     for (auto& state_ch : channel_controllers_) {
       state_ch->HandleClipping(step);
     }
     frames_since_clipped_ = 0;
     if (!!clipping_predictor_) {
       clipping_predictor_->Reset();
     }
   }

   AggregateChannelLevels();
 }

 absl::optional<int> InputVolumeController::RecommendInputVolume(
     float speech_probability,
     absl::optional<float> speech_level_dbfs) {
   // Only process if applied input volume is set.
   if (!applied_input_volume_.has_value()) {
     RTC_LOG(LS_ERROR) << "[AGC2] Applied input volume not set.";
     return absl::nullopt;
   }

   AggregateChannelLevels();
   const int volume_after_clipping_handling = recommended_input_volume_;

   if (!capture_output_used_) {
     return applied_input_volume_;
   }

   absl::optional<int> rms_error_db;
   if (speech_level_dbfs.has_value()) {
     // Compute the error for all frames (both speech and non-speech frames).
     rms_error_db = GetSpeechLevelRmsErrorDb(
         *speech_level_dbfs, target_range_min_dbfs_, target_range_max_dbfs_);
   }

   for (auto& controller : channel_controllers_) {
     controller->Process(rms_error_db, speech_probability);
   }

   AggregateChannelLevels();
   if (volume_after_clipping_handling != recommended_input_volume_) {
     // The recommended input volume was adjusted in order to match the target
     // level.
     UpdateHistogramOnRecommendedInputVolumeChangeToMatchTarget(
         recommended_input_volume_);
   }

   applied_input_volume_ = absl::nullopt;
   return recommended_input_volume();
 }

 void InputVolumeController::HandleCaptureOutputUsedChange(
     bool capture_output_used) {
   for (auto& controller : channel_controllers_) {
     controller->HandleCaptureOutputUsedChange(capture_output_used);
   }

   capture_output_used_ = capture_output_used;
 }

 void InputVolumeController::SetAppliedInputVolume(int input_volume) {
   applied_input_volume_ = input_volume;

   for (auto& controller : channel_controllers_) {
     controller->set_stream_analog_level(input_volume);
   }

   AggregateChannelLevels();
 }

 void InputVolumeController::AggregateChannelLevels() {
   int new_recommended_input_volume =
       channel_controllers_[0]->recommended_analog_level();
   channel_controlling_gain_ = 0;
   for (size_t ch = 1; ch < channel_controllers_.size(); ++ch) {
     int input_volume = channel_controllers_[ch]->recommended_analog_level();
     if (input_volume < new_recommended_input_volume) {
       new_recommended_input_volume = input_volume;
       channel_controlling_gain_ = static_cast<int>(ch);
     }
   }

   // Enforce the minimum input volume when a recommendation is made.
   if (applied_input_volume_.has_value() && *applied_input_volume_ > 0) {
     new_recommended_input_volume =
         std::max(new_recommended_input_volume, min_input_volume_);
   }

   recommended_input_volume_ = new_recommended_input_volume;
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2013 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/agc2/input_volume_controller.h"

	#include <algorithm>
	#include <cmath>

	#include "api/array_view.h"
	#include "modules/audio_processing/agc2/gain_map_internal.h"
	#include "modules/audio_processing/agc2/input_volume_stats_reporter.h"
	#include "modules/audio_processing/include/audio_frame_view.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/logging.h"
	#include "rtc_base/numerics/safe_minmax.h"
	#include "system_wrappers/include/field_trial.h"
	#include "system_wrappers/include/metrics.h"

	namespace webrtc {

	namespace {

	// Amount of error we tolerate in the microphone input volume (presumably due to
	// OS quantization) before we assume the user has manually adjusted the volume.
	constexpr int kVolumeQuantizationSlack = 25;

	constexpr int kMaxInputVolume = 255;
	static_assert(kGainMapSize > kMaxInputVolume, "gain map too small");

	// Maximum absolute RMS error.
	constexpr int KMaxAbsRmsErrorDbfs = 15;
	static_assert(KMaxAbsRmsErrorDbfs > 0, "");

	using Agc1ClippingPredictorConfig = AudioProcessing::Config::GainController1::
	AnalogGainController::ClippingPredictor;

	// TODO(webrtc:7494): Hardcode clipping predictor parameters and remove this
	// function after no longer needed in the ctor.
	Agc1ClippingPredictorConfig CreateClippingPredictorConfig(bool enabled) {
	Agc1ClippingPredictorConfig config;
	config.enabled = enabled;

	return config;
	}

	// Returns an input volume in the [`min_input_volume`, `kMaxInputVolume`] range
	// that reduces `gain_error_db`, which is a gain error estimated when
	// `input_volume` was applied, according to a fixed gain map.
	int ComputeVolumeUpdate(int gain_error_db,
	int input_volume,
	int min_input_volume) {
	RTC_DCHECK_GE(input_volume, 0);
	RTC_DCHECK_LE(input_volume, kMaxInputVolume);
	if (gain_error_db == 0) {
	return input_volume;
	}

	int new_volume = input_volume;
	if (gain_error_db > 0) {
	while (kGainMap[new_volume] - kGainMap[input_volume] < gain_error_db &&
	new_volume < kMaxInputVolume) {
	++new_volume;
	}
	} else {
	while (kGainMap[new_volume] - kGainMap[input_volume] > gain_error_db &&
	new_volume > min_input_volume) {
	--new_volume;
	}
	}
	return new_volume;
	}

	// Returns the proportion of samples in the buffer which are at full-scale
	// (and presumably clipped).
	float ComputeClippedRatio(const float* const* audio,
	size_t num_channels,
	size_t samples_per_channel) {
	RTC_DCHECK_GT(samples_per_channel, 0);
	int num_clipped = 0;
	for (size_t ch = 0; ch < num_channels; ++ch) {
	int num_clipped_in_ch = 0;
	for (size_t i = 0; i < samples_per_channel; ++i) {
	RTC_DCHECK(audio[ch]);
	if (audio[ch][i] >= 32767.0f \|\| audio[ch][i] <= -32768.0f) {
	++num_clipped_in_ch;
	}
	}
	num_clipped = std::max(num_clipped, num_clipped_in_ch);
	}
	return static_cast<float>(num_clipped) / (samples_per_channel);
	}

	void LogClippingMetrics(int clipping_rate) {
	RTC_LOG(LS_INFO) << "[AGC2] Input clipping rate: " << clipping_rate << "%";
	RTC_HISTOGRAM_COUNTS_LINEAR(/name=/"WebRTC.Audio.Agc.InputClippingRate",
	/sample=/clipping_rate, /min=/0, /max=/100,
	/bucket_count=/50);
	}

	// Compares `speech_level_dbfs` to the [`target_range_min_dbfs`,
	// `target_range_max_dbfs`] range and returns the error to be compensated via
	// input volume adjustment. Returns a positive value when the level is below
	// the range, a negative value when the level is above the range, zero
	// otherwise.
	int GetSpeechLevelRmsErrorDb(float speech_level_dbfs,
	int target_range_min_dbfs,
	int target_range_max_dbfs) {
	constexpr float kMinSpeechLevelDbfs = -90.0f;
	constexpr float kMaxSpeechLevelDbfs = 30.0f;
	RTC_DCHECK_GE(speech_level_dbfs, kMinSpeechLevelDbfs);
	RTC_DCHECK_LE(speech_level_dbfs, kMaxSpeechLevelDbfs);
	speech_level_dbfs = rtc::SafeClamp<float>(
	speech_level_dbfs, kMinSpeechLevelDbfs, kMaxSpeechLevelDbfs);

	int rms_error_db = 0;
	if (speech_level_dbfs > target_range_max_dbfs) {
	rms_error_db = std::round(target_range_max_dbfs - speech_level_dbfs);
	} else if (speech_level_dbfs < target_range_min_dbfs) {
	rms_error_db = std::round(target_range_min_dbfs - speech_level_dbfs);
	}

	return rms_error_db;
	}

	} // namespace

	MonoInputVolumeController::MonoInputVolumeController(
	int min_input_volume_after_clipping,
	int min_input_volume,
	int update_input_volume_wait_frames,
	float speech_probability_threshold,
	float speech_ratio_threshold)
	: min_input_volume_(min_input_volume),
	min_input_volume_after_clipping_(min_input_volume_after_clipping),
	max_input_volume_(kMaxInputVolume),
	update_input_volume_wait_frames_(
	std::max(update_input_volume_wait_frames, 1)),
	speech_probability_threshold_(speech_probability_threshold),
	speech_ratio_threshold_(speech_ratio_threshold) {
	RTC_DCHECK_GE(min_input_volume_, 0);
	RTC_DCHECK_LE(min_input_volume_, 255);
	RTC_DCHECK_GE(min_input_volume_after_clipping_, 0);
	RTC_DCHECK_LE(min_input_volume_after_clipping_, 255);
	RTC_DCHECK_GE(max_input_volume_, 0);
	RTC_DCHECK_LE(max_input_volume_, 255);
	RTC_DCHECK_GE(update_input_volume_wait_frames_, 0);
	RTC_DCHECK_GE(speech_probability_threshold_, 0.0f);
	RTC_DCHECK_LE(speech_probability_threshold_, 1.0f);
	RTC_DCHECK_GE(speech_ratio_threshold_, 0.0f);
	RTC_DCHECK_LE(speech_ratio_threshold_, 1.0f);
	}

	MonoInputVolumeController::~MonoInputVolumeController() = default;

	void MonoInputVolumeController::Initialize() {
	max_input_volume_ = kMaxInputVolume;
	capture_output_used_ = true;
	check_volume_on_next_process_ = true;
	frames_since_update_input_volume_ = 0;
	speech_frames_since_update_input_volume_ = 0;
	is_first_frame_ = true;
	}

	// A speeh segment is considered active if at least
	// `update_input_volume_wait_frames_` new frames have been processed since the
	// previous update and the ratio of non-silence frames (i.e., frames with a
	// `speech_probability` higher than `speech_probability_threshold_`) is at least
	// `speech_ratio_threshold_`.
	void MonoInputVolumeController::Process(absl::optional<int> rms_error_db,
	float speech_probability) {
	if (check_volume_on_next_process_) {
	check_volume_on_next_process_ = false;
	// We have to wait until the first process call to check the volume,
	// because Chromium doesn't guarantee it to be valid any earlier.
	CheckVolumeAndReset();
	}

	// Count frames with a high speech probability as speech.
	if (speech_probability >= speech_probability_threshold_) {
	++speech_frames_since_update_input_volume_;
	}

	// Reset the counters and maybe update the input volume.
	if (++frames_since_update_input_volume_ >= update_input_volume_wait_frames_) {
	const float speech_ratio =
	static_cast<float>(speech_frames_since_update_input_volume_) /
	static_cast<float>(update_input_volume_wait_frames_);

	// Always reset the counters regardless of whether the volume changes or
	// not.
	frames_since_update_input_volume_ = 0;
	speech_frames_since_update_input_volume_ = 0;

	// Update the input volume if allowed.
	if (!is_first_frame_ && speech_ratio >= speech_ratio_threshold_ &&
	rms_error_db.has_value()) {
	UpdateInputVolume(*rms_error_db);
	}
	}

	is_first_frame_ = false;
	}

	void MonoInputVolumeController::HandleClipping(int clipped_level_step) {
	RTC_DCHECK_GT(clipped_level_step, 0);
	// Always decrease the maximum input volume, even if the current input volume
	// is below threshold.
	SetMaxLevel(std::max(min_input_volume_after_clipping_,
	max_input_volume_ - clipped_level_step));
	if (log_to_histograms_) {
	RTC_HISTOGRAM_BOOLEAN("WebRTC.Audio.AgcClippingAdjustmentAllowed",
	last_recommended_input_volume_ - clipped_level_step >=
	min_input_volume_after_clipping_);
	}
	if (last_recommended_input_volume_ > min_input_volume_after_clipping_) {
	// Don't try to adjust the input volume if we're already below the limit. As
	// a consequence, if the user has brought the input volume above the limit,
	// we will still not react until the postproc updates the input volume.
	SetInputVolume(
	std::max(min_input_volume_after_clipping_,
	last_recommended_input_volume_ - clipped_level_step));
	frames_since_update_input_volume_ = 0;
	speech_frames_since_update_input_volume_ = 0;
	is_first_frame_ = false;
	}
	}

	void MonoInputVolumeController::SetInputVolume(int new_volume) {
	int applied_input_volume = recommended_input_volume_;
	if (applied_input_volume == 0) {
	RTC_DLOG(LS_INFO)
	<< "[AGC2] The applied input volume is zero, taking no action.";
	return;
	}
	if (applied_input_volume < 0 \|\| applied_input_volume > kMaxInputVolume) {
	RTC_LOG(LS_ERROR) << "[AGC2] Invalid value for the applied input volume: "
	<< applied_input_volume;
	return;
	}

	// Detect manual input volume adjustments by checking if the
	// `applied_input_volume` is outside of the `[last_recommended_input_volume_ -
	// kVolumeQuantizationSlack, last_recommended_input_volume_ +
	// kVolumeQuantizationSlack]` range.
	if (applied_input_volume >
	last_recommended_input_volume_ + kVolumeQuantizationSlack \|\|
	applied_input_volume <
	last_recommended_input_volume_ - kVolumeQuantizationSlack) {
	RTC_DLOG(LS_INFO)
	<< "[AGC2] The input volume was manually adjusted. Updating "
	"stored input volume from "
	<< last_recommended_input_volume_ << " to " << applied_input_volume;
	last_recommended_input_volume_ = applied_input_volume;
	// Always allow the user to increase the volume.
	if (last_recommended_input_volume_ > max_input_volume_) {
	SetMaxLevel(last_recommended_input_volume_);
	}
	// Take no action in this case, since we can't be sure when the volume
	// was manually adjusted.
	frames_since_update_input_volume_ = 0;
	speech_frames_since_update_input_volume_ = 0;
	is_first_frame_ = false;
	return;
	}

	new_volume = std::min(new_volume, max_input_volume_);
	if (new_volume == last_recommended_input_volume_) {
	return;
	}

	recommended_input_volume_ = new_volume;
	RTC_DLOG(LS_INFO) << "[AGC2] Applied input volume: " << applied_input_volume
	<< " \| last recommended input volume: "
	<< last_recommended_input_volume_
	<< " \| newly recommended input volume: " << new_volume;
	last_recommended_input_volume_ = new_volume;
	}

	void MonoInputVolumeController::SetMaxLevel(int input_volume) {
	RTC_DCHECK_GE(input_volume, min_input_volume_after_clipping_);
	max_input_volume_ = input_volume;
	RTC_DLOG(LS_INFO) << "[AGC2] Maximum input volume updated: "
	<< max_input_volume_;
	}

	void MonoInputVolumeController::HandleCaptureOutputUsedChange(
	bool capture_output_used) {
	if (capture_output_used_ == capture_output_used) {
	return;
	}
	capture_output_used_ = capture_output_used;

	if (capture_output_used) {
	// When we start using the output, we should reset things to be safe.
	check_volume_on_next_process_ = true;
	}
	}

	int MonoInputVolumeController::CheckVolumeAndReset() {
	int input_volume = recommended_input_volume_;
	// Reasons for taking action at startup:
	// 1) A person starting a call is expected to be heard.
	// 2) Independent of interpretation of `input_volume` == 0 we should raise it
	// so the AGC can do its job properly.
	if (input_volume == 0 && !startup_) {
	RTC_DLOG(LS_INFO)
	<< "[AGC2] The applied input volume is zero, taking no action.";
	return 0;
	}
	if (input_volume < 0 \|\| input_volume > kMaxInputVolume) {
	RTC_LOG(LS_ERROR) << "[AGC2] Invalid value for the applied input volume: "
	<< input_volume;
	return -1;
	}
	RTC_DLOG(LS_INFO) << "[AGC2] Initial input volume: " << input_volume;

	if (input_volume < min_input_volume_) {
	input_volume = min_input_volume_;
	RTC_DLOG(LS_INFO)
	<< "[AGC2] The initial input volume is too low, raising to "
	<< input_volume;
	recommended_input_volume_ = input_volume;
	}

	last_recommended_input_volume_ = input_volume;
	startup_ = false;
	frames_since_update_input_volume_ = 0;
	speech_frames_since_update_input_volume_ = 0;
	is_first_frame_ = true;

	return 0;
	}

	void MonoInputVolumeController::UpdateInputVolume(int rms_error_db) {
	RTC_DLOG(LS_INFO) << "[AGC2] RMS error: " << rms_error_db << " dB";
	// Prevent too large microphone input volume changes by clamping the RMS
	// error.
	rms_error_db =
	rtc::SafeClamp(rms_error_db, -KMaxAbsRmsErrorDbfs, KMaxAbsRmsErrorDbfs);
	if (rms_error_db == 0) {
	return;
	}
	SetInputVolume(ComputeVolumeUpdate(
	rms_error_db, last_recommended_input_volume_, min_input_volume_));
	}

	InputVolumeController::InputVolumeController(int num_capture_channels,
	const Config& config)
	: num_capture_channels_(num_capture_channels),
	min_input_volume_(config.min_input_volume),
	capture_output_used_(true),
	clipped_level_step_(config.clipped_level_step),
	clipped_ratio_threshold_(config.clipped_ratio_threshold),
	clipped_wait_frames_(config.clipped_wait_frames),
	clipping_predictor_(CreateClippingPredictor(
	num_capture_channels,
	CreateClippingPredictorConfig(config.enable_clipping_predictor))),
	use_clipping_predictor_step_(
	!!clipping_predictor_ &&
	CreateClippingPredictorConfig(config.enable_clipping_predictor)
	.use_predicted_step),
	frames_since_clipped_(config.clipped_wait_frames),
	clipping_rate_log_counter_(0),
	clipping_rate_log_(0.0f),
	target_range_max_dbfs_(config.target_range_max_dbfs),
	target_range_min_dbfs_(config.target_range_min_dbfs),
	channel_controllers_(num_capture_channels) {
	RTC_LOG(LS_INFO)
	<< "[AGC2] Input volume controller enabled. Minimum input volume: "
	<< min_input_volume_;

	for (auto& controller : channel_controllers_) {
	controller = std::make_unique<MonoInputVolumeController>(
	config.clipped_level_min, min_input_volume_,
	config.update_input_volume_wait_frames,
	config.speech_probability_threshold, config.speech_ratio_threshold);
	}

	RTC_DCHECK(!channel_controllers_.empty());
	RTC_DCHECK_GT(clipped_level_step_, 0);
	RTC_DCHECK_LE(clipped_level_step_, 255);
	RTC_DCHECK_GT(clipped_ratio_threshold_, 0.0f);
	RTC_DCHECK_LT(clipped_ratio_threshold_, 1.0f);
	RTC_DCHECK_GT(clipped_wait_frames_, 0);
	channel_controllers_[0]->ActivateLogging();
	}

	InputVolumeController::~InputVolumeController() {}

	void InputVolumeController::Initialize() {
	for (auto& controller : channel_controllers_) {
	controller->Initialize();
	}
	capture_output_used_ = true;

	AggregateChannelLevels();
	clipping_rate_log_ = 0.0f;
	clipping_rate_log_counter_ = 0;

	applied_input_volume_ = absl::nullopt;
	}

	void InputVolumeController::AnalyzeInputAudio(int applied_input_volume,
	const AudioBuffer& audio_buffer) {
	RTC_DCHECK_GE(applied_input_volume, 0);
	RTC_DCHECK_LE(applied_input_volume, 255);

	SetAppliedInputVolume(applied_input_volume);

	RTC_DCHECK_EQ(audio_buffer.num_channels(), channel_controllers_.size());
	const float* const* audio = audio_buffer.channels_const();
	size_t samples_per_channel = audio_buffer.num_frames();
	RTC_DCHECK(audio);

	AggregateChannelLevels();
	if (!capture_output_used_) {
	return;
	}

	if (!!clipping_predictor_) {
	AudioFrameView<const float> frame = AudioFrameView<const float>(
	audio, num_capture_channels_, static_cast<int>(samples_per_channel));
	clipping_predictor_->Analyze(frame);
	}

	// Check for clipped samples. We do this in the preprocessing phase in order
	// to catch clipped echo as well.
	//
	// If we find a sufficiently clipped frame, drop the current microphone
	// input volume and enforce a new maximum input volume, dropped the same
	// amount from the current maximum. This harsh treatment is an effort to avoid
	// repeated clipped echo events.
	float clipped_ratio =
	ComputeClippedRatio(audio, num_capture_channels_, samples_per_channel);
	clipping_rate_log_ = std::max(clipped_ratio, clipping_rate_log_);
	clipping_rate_log_counter_++;
	constexpr int kNumFramesIn30Seconds = 3000;
	if (clipping_rate_log_counter_ == kNumFramesIn30Seconds) {
	LogClippingMetrics(std::round(100.0f * clipping_rate_log_));
	clipping_rate_log_ = 0.0f;
	clipping_rate_log_counter_ = 0;
	}

	if (frames_since_clipped_ < clipped_wait_frames_) {
	++frames_since_clipped_;
	return;
	}

	const bool clipping_detected = clipped_ratio > clipped_ratio_threshold_;
	bool clipping_predicted = false;
	int predicted_step = 0;
	if (!!clipping_predictor_) {
	for (int channel = 0; channel < num_capture_channels_; ++channel) {
	const auto step = clipping_predictor_->EstimateClippedLevelStep(
	channel, recommended_input_volume_, clipped_level_step_,
	channel_controllers_[channel]->min_input_volume_after_clipping(),
	kMaxInputVolume);
	if (step.has_value()) {
	predicted_step = std::max(predicted_step, step.value());
	clipping_predicted = true;
	}
	}
	}

	if (clipping_detected) {
	RTC_DLOG(LS_INFO) << "[AGC2] Clipping detected (ratio: " << clipped_ratio
	<< ")";
	}

	int step = clipped_level_step_;
	if (clipping_predicted) {
	predicted_step = std::max(predicted_step, clipped_level_step_);
	RTC_DLOG(LS_INFO) << "[AGC2] Clipping predicted (volume down step: "
	<< predicted_step << ")";
	if (use_clipping_predictor_step_) {
	step = predicted_step;
	}
	}

	if (clipping_detected \|\|
	(clipping_predicted && use_clipping_predictor_step_)) {
	for (auto& state_ch : channel_controllers_) {
	state_ch->HandleClipping(step);
	}
	frames_since_clipped_ = 0;
	if (!!clipping_predictor_) {
	clipping_predictor_->Reset();
	}
	}

	AggregateChannelLevels();
	}

	absl::optional<int> InputVolumeController::RecommendInputVolume(
	float speech_probability,
	absl::optional<float> speech_level_dbfs) {
	// Only process if applied input volume is set.
	if (!applied_input_volume_.has_value()) {
	RTC_LOG(LS_ERROR) << "[AGC2] Applied input volume not set.";
	return absl::nullopt;
	}

	AggregateChannelLevels();
	const int volume_after_clipping_handling = recommended_input_volume_;

	if (!capture_output_used_) {
	return applied_input_volume_;
	}

	absl::optional<int> rms_error_db;
	if (speech_level_dbfs.has_value()) {
	// Compute the error for all frames (both speech and non-speech frames).
	rms_error_db = GetSpeechLevelRmsErrorDb(
	*speech_level_dbfs, target_range_min_dbfs_, target_range_max_dbfs_);
	}

	for (auto& controller : channel_controllers_) {
	controller->Process(rms_error_db, speech_probability);
	}

	AggregateChannelLevels();
	if (volume_after_clipping_handling != recommended_input_volume_) {
	// The recommended input volume was adjusted in order to match the target
	// level.
	UpdateHistogramOnRecommendedInputVolumeChangeToMatchTarget(
	recommended_input_volume_);
	}

	applied_input_volume_ = absl::nullopt;
	return recommended_input_volume();
	}

	void InputVolumeController::HandleCaptureOutputUsedChange(
	bool capture_output_used) {
	for (auto& controller : channel_controllers_) {
	controller->HandleCaptureOutputUsedChange(capture_output_used);
	}

	capture_output_used_ = capture_output_used;
	}

	void InputVolumeController::SetAppliedInputVolume(int input_volume) {
	applied_input_volume_ = input_volume;

	for (auto& controller : channel_controllers_) {
	controller->set_stream_analog_level(input_volume);
	}

	AggregateChannelLevels();
	}

	void InputVolumeController::AggregateChannelLevels() {
	int new_recommended_input_volume =
	channel_controllers_[0]->recommended_analog_level();
	channel_controlling_gain_ = 0;
	for (size_t ch = 1; ch < channel_controllers_.size(); ++ch) {
	int input_volume = channel_controllers_[ch]->recommended_analog_level();
	if (input_volume < new_recommended_input_volume) {
	new_recommended_input_volume = input_volume;
	channel_controlling_gain_ = static_cast<int>(ch);
	}
	}

	// Enforce the minimum input volume when a recommendation is made.
	if (applied_input_volume_.has_value() && *applied_input_volume_ > 0) {
	new_recommended_input_volume =
	std::max(new_recommended_input_volume, min_input_volume_);
	}

	recommended_input_volume_ = new_recommended_input_volume;
	}

	} // namespace webrtc