blob: 18d84d8a181c4b0d1d01237fb280fe9451911494 [file] [log] [blame]
/*
* 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/agc/agc_manager_direct.h"
#include <algorithm>
#include <cmath>
#include "api/array_view.h"
#include "common_audio/include/audio_util.h"
#include "modules/audio_processing/agc/gain_control.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 level (presumably due to OS
// quantization) before we assume the user has manually adjusted the microphone.
constexpr int kLevelQuantizationSlack = 25;
constexpr int kDefaultCompressionGain = 7;
constexpr int kMaxCompressionGain = 12;
constexpr int kMinCompressionGain = 2;
// Controls the rate of compression changes towards the target.
constexpr float kCompressionGainStep = 0.05f;
constexpr int kMaxMicLevel = 255;
static_assert(kGainMapSize > kMaxMicLevel, "gain map too small");
constexpr int kMinMicLevel = 12;
// Prevent very large microphone level changes.
constexpr int kMaxResidualGainChange = 15;
// Maximum additional gain allowed to compensate for microphone level
// restrictions from clipping events.
constexpr int kSurplusCompressionGain = 6;
// Target speech level (dBFs) and speech probability threshold used to compute
// the RMS error override in `GetSpeechLevelErrorDb()`. These are only used for
// computing the error override and they are not passed to `agc_`.
// TODO(webrtc:7494): Move these to a config and pass in the ctor.
constexpr float kOverrideTargetSpeechLevelDbfs = -18.0f;
constexpr float kOverrideSpeechProbabilitySilenceThreshold = 0.5f;
// The minimum number of frames between `UpdateGain()` calls.
// TODO(webrtc:7494): Move this to a config and pass in the ctor with
// kOverrideWaitFrames = 100. Default value zero needed for the unit tests.
constexpr int kOverrideWaitFrames = 0;
using AnalogAgcConfig =
AudioProcessing::Config::GainController1::AnalogGainController;
// If the "WebRTC-Audio-2ndAgcMinMicLevelExperiment" field trial is specified,
// parses it and returns a value between 0 and 255 depending on the field-trial
// string. Returns an unspecified value if the field trial is not specified, if
// disabled or if it cannot be parsed. Example:
// 'WebRTC-Audio-2ndAgcMinMicLevelExperiment/Enabled-80' => returns 80.
std::optional<int> GetMinMicLevelOverride() {
constexpr char kMinMicLevelFieldTrial[] =
"WebRTC-Audio-2ndAgcMinMicLevelExperiment";
if (!webrtc::field_trial::IsEnabled(kMinMicLevelFieldTrial)) {
return std::nullopt;
}
const auto field_trial_string =
webrtc::field_trial::FindFullName(kMinMicLevelFieldTrial);
int min_mic_level = -1;
sscanf(field_trial_string.c_str(), "Enabled-%d", &min_mic_level);
if (min_mic_level >= 0 && min_mic_level <= 255) {
return min_mic_level;
} else {
RTC_LOG(LS_WARNING) << "[agc] Invalid parameter for "
<< kMinMicLevelFieldTrial << ", ignored.";
return std::nullopt;
}
}
int LevelFromGainError(int gain_error, int level, int min_mic_level) {
RTC_DCHECK_GE(level, 0);
RTC_DCHECK_LE(level, kMaxMicLevel);
if (gain_error == 0) {
return level;
}
int new_level = level;
if (gain_error > 0) {
while (kGainMap[new_level] - kGainMap[level] < gain_error &&
new_level < kMaxMicLevel) {
++new_level;
}
} else {
while (kGainMap[new_level] - kGainMap[level] > gain_error &&
new_level > min_mic_level) {
--new_level;
}
}
return new_level;
}
// 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) << "Input clipping rate: " << clipping_rate << "%";
RTC_HISTOGRAM_COUNTS_LINEAR(/*name=*/"WebRTC.Audio.Agc.InputClippingRate",
/*sample=*/clipping_rate, /*min=*/0, /*max=*/100,
/*bucket_count=*/50);
}
// Computes the speech level error in dB. `speech_level_dbfs` is required to be
// in the range [-90.0f, 30.0f] and `speech_probability` in the range
// [0.0f, 1.0f].
int GetSpeechLevelErrorDb(float speech_level_dbfs, float speech_probability) {
constexpr float kMinSpeechLevelDbfs = -90.0f;
constexpr float kMaxSpeechLevelDbfs = 30.0f;
RTC_DCHECK_GE(speech_level_dbfs, kMinSpeechLevelDbfs);
RTC_DCHECK_LE(speech_level_dbfs, kMaxSpeechLevelDbfs);
RTC_DCHECK_GE(speech_probability, 0.0f);
RTC_DCHECK_LE(speech_probability, 1.0f);
if (speech_probability < kOverrideSpeechProbabilitySilenceThreshold) {
return 0;
}
const float speech_level = rtc::SafeClamp<float>(
speech_level_dbfs, kMinSpeechLevelDbfs, kMaxSpeechLevelDbfs);
return std::round(kOverrideTargetSpeechLevelDbfs - speech_level);
}
} // namespace
MonoAgc::MonoAgc(ApmDataDumper* data_dumper,
int clipped_level_min,
bool disable_digital_adaptive,
int min_mic_level)
: min_mic_level_(min_mic_level),
disable_digital_adaptive_(disable_digital_adaptive),
agc_(std::make_unique<Agc>()),
max_level_(kMaxMicLevel),
max_compression_gain_(kMaxCompressionGain),
target_compression_(kDefaultCompressionGain),
compression_(target_compression_),
compression_accumulator_(compression_),
clipped_level_min_(clipped_level_min) {}
MonoAgc::~MonoAgc() = default;
void MonoAgc::Initialize() {
max_level_ = kMaxMicLevel;
max_compression_gain_ = kMaxCompressionGain;
target_compression_ = disable_digital_adaptive_ ? 0 : kDefaultCompressionGain;
compression_ = disable_digital_adaptive_ ? 0 : target_compression_;
compression_accumulator_ = compression_;
capture_output_used_ = true;
check_volume_on_next_process_ = true;
frames_since_update_gain_ = 0;
is_first_frame_ = true;
}
void MonoAgc::Process(rtc::ArrayView<const int16_t> audio,
std::optional<int> rms_error_override) {
new_compression_to_set_ = std::nullopt;
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();
}
agc_->Process(audio);
// Always check if `agc_` has a new error available. If yes, `agc_` gets
// reset.
// TODO(webrtc:7494) Replace the `agc_` call `GetRmsErrorDb()` with `Reset()`
// if an error override is used.
int rms_error = 0;
bool update_gain = agc_->GetRmsErrorDb(&rms_error);
if (rms_error_override.has_value()) {
if (is_first_frame_ || frames_since_update_gain_ < kOverrideWaitFrames) {
update_gain = false;
} else {
rms_error = *rms_error_override;
update_gain = true;
}
}
if (update_gain) {
UpdateGain(rms_error);
}
if (!disable_digital_adaptive_) {
UpdateCompressor();
}
is_first_frame_ = false;
if (frames_since_update_gain_ < kOverrideWaitFrames) {
++frames_since_update_gain_;
}
}
void MonoAgc::HandleClipping(int clipped_level_step) {
RTC_DCHECK_GT(clipped_level_step, 0);
// Always decrease the maximum level, even if the current level is below
// threshold.
SetMaxLevel(std::max(clipped_level_min_, max_level_ - clipped_level_step));
if (log_to_histograms_) {
RTC_HISTOGRAM_BOOLEAN("WebRTC.Audio.AgcClippingAdjustmentAllowed",
level_ - clipped_level_step >= clipped_level_min_);
}
if (level_ > clipped_level_min_) {
// Don't try to adjust the level if we're already below the limit. As
// a consequence, if the user has brought the level above the limit, we
// will still not react until the postproc updates the level.
SetLevel(std::max(clipped_level_min_, level_ - clipped_level_step));
// Reset the AGCs for all channels since the level has changed.
agc_->Reset();
frames_since_update_gain_ = 0;
is_first_frame_ = false;
}
}
void MonoAgc::SetLevel(int new_level) {
int voe_level = recommended_input_volume_;
if (voe_level == 0) {
RTC_DLOG(LS_INFO)
<< "[agc] VolumeCallbacks returned level=0, taking no action.";
return;
}
if (voe_level < 0 || voe_level > kMaxMicLevel) {
RTC_LOG(LS_ERROR) << "VolumeCallbacks returned an invalid level="
<< voe_level;
return;
}
// Detect manual input volume adjustments by checking if the current level
// `voe_level` is outside of the `[level_ - kLevelQuantizationSlack, level_ +
// kLevelQuantizationSlack]` range where `level_` is the last input volume
// known by this gain controller.
if (voe_level > level_ + kLevelQuantizationSlack ||
voe_level < level_ - kLevelQuantizationSlack) {
RTC_DLOG(LS_INFO) << "[agc] Mic volume was manually adjusted. Updating "
"stored level from "
<< level_ << " to " << voe_level;
level_ = voe_level;
// Always allow the user to increase the volume.
if (level_ > max_level_) {
SetMaxLevel(level_);
}
// Take no action in this case, since we can't be sure when the volume
// was manually adjusted. The compressor will still provide some of the
// desired gain change.
agc_->Reset();
frames_since_update_gain_ = 0;
is_first_frame_ = false;
return;
}
new_level = std::min(new_level, max_level_);
if (new_level == level_) {
return;
}
recommended_input_volume_ = new_level;
RTC_DLOG(LS_INFO) << "[agc] voe_level=" << voe_level << ", level_=" << level_
<< ", new_level=" << new_level;
level_ = new_level;
}
void MonoAgc::SetMaxLevel(int level) {
RTC_DCHECK_GE(level, clipped_level_min_);
max_level_ = level;
// Scale the `kSurplusCompressionGain` linearly across the restricted
// level range.
max_compression_gain_ =
kMaxCompressionGain + std::floor((1.f * kMaxMicLevel - max_level_) /
(kMaxMicLevel - clipped_level_min_) *
kSurplusCompressionGain +
0.5f);
RTC_DLOG(LS_INFO) << "[agc] max_level_=" << max_level_
<< ", max_compression_gain_=" << max_compression_gain_;
}
void MonoAgc::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 MonoAgc::CheckVolumeAndReset() {
int level = 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 `level` == 0 we should raise it so the
// AGC can do its job properly.
if (level == 0 && !startup_) {
RTC_DLOG(LS_INFO)
<< "[agc] VolumeCallbacks returned level=0, taking no action.";
return 0;
}
if (level < 0 || level > kMaxMicLevel) {
RTC_LOG(LS_ERROR) << "[agc] VolumeCallbacks returned an invalid level="
<< level;
return -1;
}
RTC_DLOG(LS_INFO) << "[agc] Initial GetMicVolume()=" << level;
if (level < min_mic_level_) {
level = min_mic_level_;
RTC_DLOG(LS_INFO) << "[agc] Initial volume too low, raising to " << level;
recommended_input_volume_ = level;
}
agc_->Reset();
level_ = level;
startup_ = false;
frames_since_update_gain_ = 0;
is_first_frame_ = true;
return 0;
}
// Distributes the required gain change between the digital compression stage
// and volume slider. We use the compressor first, providing a slack region
// around the current slider position to reduce movement.
//
// If the slider needs to be moved, we check first if the user has adjusted
// it, in which case we take no action and cache the updated level.
void MonoAgc::UpdateGain(int rms_error_db) {
int rms_error = rms_error_db;
// Always reset the counter regardless of whether the gain is changed
// or not. This matches with the bahvior of `agc_` where the histogram is
// reset every time an RMS error is successfully read.
frames_since_update_gain_ = 0;
// The compressor will always add at least kMinCompressionGain. In effect,
// this adjusts our target gain upward by the same amount and rms_error
// needs to reflect that.
rms_error += kMinCompressionGain;
// Handle as much error as possible with the compressor first.
int raw_compression =
rtc::SafeClamp(rms_error, kMinCompressionGain, max_compression_gain_);
// Deemphasize the compression gain error. Move halfway between the current
// target and the newly received target. This serves to soften perceptible
// intra-talkspurt adjustments, at the cost of some adaptation speed.
if ((raw_compression == max_compression_gain_ &&
target_compression_ == max_compression_gain_ - 1) ||
(raw_compression == kMinCompressionGain &&
target_compression_ == kMinCompressionGain + 1)) {
// Special case to allow the target to reach the endpoints of the
// compression range. The deemphasis would otherwise halt it at 1 dB shy.
target_compression_ = raw_compression;
} else {
target_compression_ =
(raw_compression - target_compression_) / 2 + target_compression_;
}
// Residual error will be handled by adjusting the volume slider. Use the
// raw rather than deemphasized compression here as we would otherwise
// shrink the amount of slack the compressor provides.
const int residual_gain =
rtc::SafeClamp(rms_error - raw_compression, -kMaxResidualGainChange,
kMaxResidualGainChange);
RTC_DLOG(LS_INFO) << "[agc] rms_error=" << rms_error
<< ", target_compression=" << target_compression_
<< ", residual_gain=" << residual_gain;
if (residual_gain == 0)
return;
int old_level = level_;
SetLevel(LevelFromGainError(residual_gain, level_, min_mic_level_));
if (old_level != level_) {
// Reset the AGC since the level has changed.
agc_->Reset();
}
}
void MonoAgc::UpdateCompressor() {
if (compression_ == target_compression_) {
return;
}
// Adapt the compression gain slowly towards the target, in order to avoid
// highly perceptible changes.
if (target_compression_ > compression_) {
compression_accumulator_ += kCompressionGainStep;
} else {
compression_accumulator_ -= kCompressionGainStep;
}
// The compressor accepts integer gains in dB. Adjust the gain when
// we've come within half a stepsize of the nearest integer. (We don't
// check for equality due to potential floating point imprecision).
int new_compression = compression_;
int nearest_neighbor = std::floor(compression_accumulator_ + 0.5);
if (std::fabs(compression_accumulator_ - nearest_neighbor) <
kCompressionGainStep / 2) {
new_compression = nearest_neighbor;
}
// Set the new compression gain.
if (new_compression != compression_) {
compression_ = new_compression;
compression_accumulator_ = new_compression;
new_compression_to_set_ = compression_;
}
}
std::atomic<int> AgcManagerDirect::instance_counter_(0);
AgcManagerDirect::AgcManagerDirect(
const AudioProcessing::Config::GainController1::AnalogGainController&
analog_config,
Agc* agc)
: AgcManagerDirect(/*num_capture_channels=*/1, analog_config) {
RTC_DCHECK(channel_agcs_[0]);
RTC_DCHECK(agc);
channel_agcs_[0]->set_agc(agc);
}
AgcManagerDirect::AgcManagerDirect(int num_capture_channels,
const AnalogAgcConfig& analog_config)
: analog_controller_enabled_(analog_config.enabled),
min_mic_level_override_(GetMinMicLevelOverride()),
data_dumper_(new ApmDataDumper(instance_counter_.fetch_add(1) + 1)),
num_capture_channels_(num_capture_channels),
disable_digital_adaptive_(!analog_config.enable_digital_adaptive),
frames_since_clipped_(analog_config.clipped_wait_frames),
capture_output_used_(true),
clipped_level_step_(analog_config.clipped_level_step),
clipped_ratio_threshold_(analog_config.clipped_ratio_threshold),
clipped_wait_frames_(analog_config.clipped_wait_frames),
channel_agcs_(num_capture_channels),
new_compressions_to_set_(num_capture_channels),
clipping_predictor_(
CreateClippingPredictor(num_capture_channels,
analog_config.clipping_predictor)),
use_clipping_predictor_step_(
!!clipping_predictor_ &&
analog_config.clipping_predictor.use_predicted_step),
clipping_rate_log_(0.0f),
clipping_rate_log_counter_(0) {
RTC_LOG(LS_INFO) << "[agc] analog controller enabled: "
<< (analog_controller_enabled_ ? "yes" : "no");
const int min_mic_level = min_mic_level_override_.value_or(kMinMicLevel);
RTC_LOG(LS_INFO) << "[agc] Min mic level: " << min_mic_level
<< " (overridden: "
<< (min_mic_level_override_.has_value() ? "yes" : "no")
<< ")";
for (size_t ch = 0; ch < channel_agcs_.size(); ++ch) {
ApmDataDumper* data_dumper_ch = ch == 0 ? data_dumper_.get() : nullptr;
channel_agcs_[ch] = std::make_unique<MonoAgc>(
data_dumper_ch, analog_config.clipped_level_min,
disable_digital_adaptive_, min_mic_level);
}
RTC_DCHECK(!channel_agcs_.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_agcs_[0]->ActivateLogging();
}
AgcManagerDirect::~AgcManagerDirect() {}
void AgcManagerDirect::Initialize() {
RTC_DLOG(LS_INFO) << "AgcManagerDirect::Initialize";
data_dumper_->InitiateNewSetOfRecordings();
for (size_t ch = 0; ch < channel_agcs_.size(); ++ch) {
channel_agcs_[ch]->Initialize();
}
capture_output_used_ = true;
AggregateChannelLevels();
clipping_rate_log_ = 0.0f;
clipping_rate_log_counter_ = 0;
}
void AgcManagerDirect::SetupDigitalGainControl(
GainControl& gain_control) const {
if (gain_control.set_mode(GainControl::kFixedDigital) != 0) {
RTC_LOG(LS_ERROR) << "set_mode(GainControl::kFixedDigital) failed.";
}
const int target_level_dbfs = disable_digital_adaptive_ ? 0 : 2;
if (gain_control.set_target_level_dbfs(target_level_dbfs) != 0) {
RTC_LOG(LS_ERROR) << "set_target_level_dbfs() failed.";
}
const int compression_gain_db =
disable_digital_adaptive_ ? 0 : kDefaultCompressionGain;
if (gain_control.set_compression_gain_db(compression_gain_db) != 0) {
RTC_LOG(LS_ERROR) << "set_compression_gain_db() failed.";
}
const bool enable_limiter = !disable_digital_adaptive_;
if (gain_control.enable_limiter(enable_limiter) != 0) {
RTC_LOG(LS_ERROR) << "enable_limiter() failed.";
}
}
void AgcManagerDirect::AnalyzePreProcess(const AudioBuffer& audio_buffer) {
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, as the AGC has difficulty detecting pitch
// under clipping distortion. 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 level
// and enforce a new maximum level, dropped the same amount from the current
// maximum. This harsh treatment is an effort to avoid repeated clipped echo
// events. As compensation for this restriction, the maximum compression
// gain is increased, through SetMaxLevel().
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_agcs_[channel]->min_mic_level(), kMaxMicLevel);
if (step.has_value()) {
predicted_step = std::max(predicted_step, step.value());
clipping_predicted = true;
}
}
}
if (clipping_detected) {
RTC_DLOG(LS_INFO) << "[agc] Clipping detected. clipped_ratio="
<< clipped_ratio;
}
int step = clipped_level_step_;
if (clipping_predicted) {
predicted_step = std::max(predicted_step, clipped_level_step_);
RTC_DLOG(LS_INFO) << "[agc] Clipping predicted. 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_agcs_) {
state_ch->HandleClipping(step);
}
frames_since_clipped_ = 0;
if (!!clipping_predictor_) {
clipping_predictor_->Reset();
}
}
AggregateChannelLevels();
}
void AgcManagerDirect::Process(const AudioBuffer& audio_buffer) {
Process(audio_buffer, /*speech_probability=*/std::nullopt,
/*speech_level_dbfs=*/std::nullopt);
}
void AgcManagerDirect::Process(const AudioBuffer& audio_buffer,
std::optional<float> speech_probability,
std::optional<float> speech_level_dbfs) {
AggregateChannelLevels();
const int volume_after_clipping_handling = recommended_input_volume_;
if (!capture_output_used_) {
return;
}
const size_t num_frames_per_band = audio_buffer.num_frames_per_band();
std::optional<int> rms_error_override = std::nullopt;
if (speech_probability.has_value() && speech_level_dbfs.has_value()) {
rms_error_override =
GetSpeechLevelErrorDb(*speech_level_dbfs, *speech_probability);
}
for (size_t ch = 0; ch < channel_agcs_.size(); ++ch) {
std::array<int16_t, AudioBuffer::kMaxSampleRate / 100> audio_data;
int16_t* audio_use = audio_data.data();
FloatS16ToS16(audio_buffer.split_bands_const_f(ch)[0], num_frames_per_band,
audio_use);
channel_agcs_[ch]->Process({audio_use, num_frames_per_band},
rms_error_override);
new_compressions_to_set_[ch] = channel_agcs_[ch]->new_compression();
}
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_);
}
}
std::optional<int> AgcManagerDirect::GetDigitalComressionGain() {
return new_compressions_to_set_[channel_controlling_gain_];
}
void AgcManagerDirect::HandleCaptureOutputUsedChange(bool capture_output_used) {
for (size_t ch = 0; ch < channel_agcs_.size(); ++ch) {
channel_agcs_[ch]->HandleCaptureOutputUsedChange(capture_output_used);
}
capture_output_used_ = capture_output_used;
}
float AgcManagerDirect::voice_probability() const {
float max_prob = 0.f;
for (const auto& state_ch : channel_agcs_) {
max_prob = std::max(max_prob, state_ch->voice_probability());
}
return max_prob;
}
void AgcManagerDirect::set_stream_analog_level(int level) {
if (!analog_controller_enabled_) {
recommended_input_volume_ = level;
}
for (size_t ch = 0; ch < channel_agcs_.size(); ++ch) {
channel_agcs_[ch]->set_stream_analog_level(level);
}
AggregateChannelLevels();
}
void AgcManagerDirect::AggregateChannelLevels() {
int new_recommended_input_volume =
channel_agcs_[0]->recommended_analog_level();
channel_controlling_gain_ = 0;
for (size_t ch = 1; ch < channel_agcs_.size(); ++ch) {
int level = channel_agcs_[ch]->recommended_analog_level();
if (level < new_recommended_input_volume) {
new_recommended_input_volume = level;
channel_controlling_gain_ = static_cast<int>(ch);
}
}
if (min_mic_level_override_.has_value() && new_recommended_input_volume > 0) {
new_recommended_input_volume =
std::max(new_recommended_input_volume, *min_mic_level_override_);
}
if (analog_controller_enabled_) {
recommended_input_volume_ = new_recommended_input_volume;
}
}
} // namespace webrtc