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libtgvoip/webrtc_dsp/modules/audio_processing/echo_cancellation_impl.cc
Grishka 5caaaafa42 Updated WebRTC APM
I'm now using the entire audio processing module from WebRTC as opposed to individual DSP algorithms pulled from there before. Seems to work better this way.
2018-11-23 04:02:53 +03:00

471 lines
15 KiB
C++

/*
* Copyright (c) 2012 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/echo_cancellation_impl.h"
#include <stdint.h>
#include <string.h>
#include "modules/audio_processing/aec/aec_core.h"
#include "modules/audio_processing/aec/echo_cancellation.h"
#include "modules/audio_processing/audio_buffer.h"
#include "modules/audio_processing/include/config.h"
#include "rtc_base/checks.h"
#include "system_wrappers/include/field_trial.h"
namespace webrtc {
namespace {
int16_t MapSetting(EchoCancellationImpl::SuppressionLevel level) {
switch (level) {
case EchoCancellationImpl::kLowSuppression:
return kAecNlpConservative;
case EchoCancellationImpl::kModerateSuppression:
return kAecNlpModerate;
case EchoCancellationImpl::kHighSuppression:
return kAecNlpAggressive;
}
RTC_NOTREACHED();
return -1;
}
AudioProcessing::Error MapError(int err) {
switch (err) {
case AEC_UNSUPPORTED_FUNCTION_ERROR:
return AudioProcessing::kUnsupportedFunctionError;
case AEC_BAD_PARAMETER_ERROR:
return AudioProcessing::kBadParameterError;
case AEC_BAD_PARAMETER_WARNING:
return AudioProcessing::kBadStreamParameterWarning;
default:
// AEC_UNSPECIFIED_ERROR
// AEC_UNINITIALIZED_ERROR
// AEC_NULL_POINTER_ERROR
return AudioProcessing::kUnspecifiedError;
}
}
bool EnforceZeroStreamDelay() {
#if defined(CHROMEOS)
return !field_trial::IsEnabled("WebRTC-Aec2ZeroStreamDelayKillSwitch");
#else
return false;
#endif
}
} // namespace
struct EchoCancellationImpl::StreamProperties {
StreamProperties() = delete;
StreamProperties(int sample_rate_hz,
size_t num_reverse_channels,
size_t num_output_channels,
size_t num_proc_channels)
: sample_rate_hz(sample_rate_hz),
num_reverse_channels(num_reverse_channels),
num_output_channels(num_output_channels),
num_proc_channels(num_proc_channels) {}
const int sample_rate_hz;
const size_t num_reverse_channels;
const size_t num_output_channels;
const size_t num_proc_channels;
};
class EchoCancellationImpl::Canceller {
public:
Canceller() {
state_ = WebRtcAec_Create();
RTC_DCHECK(state_);
}
~Canceller() {
RTC_CHECK(state_);
WebRtcAec_Free(state_);
}
void* state() { return state_; }
void Initialize(int sample_rate_hz) {
// TODO(ajm): Drift compensation is disabled in practice. If restored, it
// should be managed internally and not depend on the hardware sample rate.
// For now, just hardcode a 48 kHz value.
const int error = WebRtcAec_Init(state_, sample_rate_hz, 48000);
RTC_DCHECK_EQ(0, error);
}
private:
void* state_;
};
EchoCancellationImpl::EchoCancellationImpl()
: drift_compensation_enabled_(false),
metrics_enabled_(true),
suppression_level_(kHighSuppression),
stream_drift_samples_(0),
was_stream_drift_set_(false),
stream_has_echo_(false),
delay_logging_enabled_(true),
extended_filter_enabled_(false),
delay_agnostic_enabled_(false),
enforce_zero_stream_delay_(EnforceZeroStreamDelay()) {}
EchoCancellationImpl::~EchoCancellationImpl() = default;
void EchoCancellationImpl::ProcessRenderAudio(
rtc::ArrayView<const float> packed_render_audio) {
if (!enabled_) {
return;
}
RTC_DCHECK(stream_properties_);
size_t handle_index = 0;
size_t buffer_index = 0;
const size_t num_frames_per_band =
packed_render_audio.size() / (stream_properties_->num_output_channels *
stream_properties_->num_reverse_channels);
for (size_t i = 0; i < stream_properties_->num_output_channels; i++) {
for (size_t j = 0; j < stream_properties_->num_reverse_channels; j++) {
WebRtcAec_BufferFarend(cancellers_[handle_index++]->state(),
&packed_render_audio[buffer_index],
num_frames_per_band);
buffer_index += num_frames_per_band;
}
}
}
int EchoCancellationImpl::ProcessCaptureAudio(AudioBuffer* audio,
int stream_delay_ms) {
if (!enabled_) {
return AudioProcessing::kNoError;
}
const int stream_delay_ms_use =
enforce_zero_stream_delay_ ? 0 : stream_delay_ms;
if (drift_compensation_enabled_ && !was_stream_drift_set_) {
return AudioProcessing::kStreamParameterNotSetError;
}
RTC_DCHECK(stream_properties_);
RTC_DCHECK_GE(160, audio->num_frames_per_band());
RTC_DCHECK_EQ(audio->num_channels(), stream_properties_->num_proc_channels);
int err = AudioProcessing::kNoError;
// The ordering convention must be followed to pass to the correct AEC.
size_t handle_index = 0;
stream_has_echo_ = false;
for (size_t i = 0; i < audio->num_channels(); i++) {
for (size_t j = 0; j < stream_properties_->num_reverse_channels; j++) {
err = WebRtcAec_Process(cancellers_[handle_index]->state(),
audio->split_bands_const_f(i), audio->num_bands(),
audio->split_bands_f(i),
audio->num_frames_per_band(), stream_delay_ms_use,
stream_drift_samples_);
if (err != AudioProcessing::kNoError) {
err = MapError(err);
// TODO(ajm): Figure out how to return warnings properly.
if (err != AudioProcessing::kBadStreamParameterWarning) {
return err;
}
}
int status = 0;
err = WebRtcAec_get_echo_status(cancellers_[handle_index]->state(),
&status);
if (err != AudioProcessing::kNoError) {
return MapError(err);
}
if (status == 1) {
stream_has_echo_ = true;
}
handle_index++;
}
}
was_stream_drift_set_ = false;
return AudioProcessing::kNoError;
}
int EchoCancellationImpl::Enable(bool enable) {
if (enable && !enabled_) {
enabled_ = enable; // Must be set before Initialize() is called.
// TODO(peah): Simplify once the Enable function has been removed from
// the public APM API.
RTC_DCHECK(stream_properties_);
Initialize(stream_properties_->sample_rate_hz,
stream_properties_->num_reverse_channels,
stream_properties_->num_output_channels,
stream_properties_->num_proc_channels);
} else {
enabled_ = enable;
}
return AudioProcessing::kNoError;
}
bool EchoCancellationImpl::is_enabled() const {
return enabled_;
}
int EchoCancellationImpl::set_suppression_level(SuppressionLevel level) {
if (MapSetting(level) == -1) {
return AudioProcessing::kBadParameterError;
}
suppression_level_ = level;
return Configure();
}
EchoCancellationImpl::SuppressionLevel EchoCancellationImpl::suppression_level()
const {
return suppression_level_;
}
int EchoCancellationImpl::enable_drift_compensation(bool enable) {
drift_compensation_enabled_ = enable;
return Configure();
}
bool EchoCancellationImpl::is_drift_compensation_enabled() const {
return drift_compensation_enabled_;
}
void EchoCancellationImpl::set_stream_drift_samples(int drift) {
was_stream_drift_set_ = true;
stream_drift_samples_ = drift;
}
int EchoCancellationImpl::stream_drift_samples() const {
return stream_drift_samples_;
}
int EchoCancellationImpl::enable_metrics(bool enable) {
metrics_enabled_ = enable;
return Configure();
}
bool EchoCancellationImpl::are_metrics_enabled() const {
return enabled_ && metrics_enabled_;
}
// TODO(ajm): we currently just use the metrics from the first AEC. Think more
// aboue the best way to extend this to multi-channel.
int EchoCancellationImpl::GetMetrics(Metrics* metrics) {
if (metrics == NULL) {
return AudioProcessing::kNullPointerError;
}
if (!enabled_ || !metrics_enabled_) {
return AudioProcessing::kNotEnabledError;
}
AecMetrics my_metrics;
memset(&my_metrics, 0, sizeof(my_metrics));
memset(metrics, 0, sizeof(Metrics));
const int err = WebRtcAec_GetMetrics(cancellers_[0]->state(), &my_metrics);
if (err != AudioProcessing::kNoError) {
return MapError(err);
}
metrics->residual_echo_return_loss.instant = my_metrics.rerl.instant;
metrics->residual_echo_return_loss.average = my_metrics.rerl.average;
metrics->residual_echo_return_loss.maximum = my_metrics.rerl.max;
metrics->residual_echo_return_loss.minimum = my_metrics.rerl.min;
metrics->echo_return_loss.instant = my_metrics.erl.instant;
metrics->echo_return_loss.average = my_metrics.erl.average;
metrics->echo_return_loss.maximum = my_metrics.erl.max;
metrics->echo_return_loss.minimum = my_metrics.erl.min;
metrics->echo_return_loss_enhancement.instant = my_metrics.erle.instant;
metrics->echo_return_loss_enhancement.average = my_metrics.erle.average;
metrics->echo_return_loss_enhancement.maximum = my_metrics.erle.max;
metrics->echo_return_loss_enhancement.minimum = my_metrics.erle.min;
metrics->a_nlp.instant = my_metrics.aNlp.instant;
metrics->a_nlp.average = my_metrics.aNlp.average;
metrics->a_nlp.maximum = my_metrics.aNlp.max;
metrics->a_nlp.minimum = my_metrics.aNlp.min;
metrics->divergent_filter_fraction = my_metrics.divergent_filter_fraction;
return AudioProcessing::kNoError;
}
bool EchoCancellationImpl::stream_has_echo() const {
return stream_has_echo_;
}
int EchoCancellationImpl::enable_delay_logging(bool enable) {
delay_logging_enabled_ = enable;
return Configure();
}
bool EchoCancellationImpl::is_delay_logging_enabled() const {
return enabled_ && delay_logging_enabled_;
}
bool EchoCancellationImpl::is_delay_agnostic_enabled() const {
return delay_agnostic_enabled_;
}
std::string EchoCancellationImpl::GetExperimentsDescription() {
return refined_adaptive_filter_enabled_ ? "RefinedAdaptiveFilter;" : "";
}
bool EchoCancellationImpl::is_refined_adaptive_filter_enabled() const {
return refined_adaptive_filter_enabled_;
}
bool EchoCancellationImpl::is_extended_filter_enabled() const {
return extended_filter_enabled_;
}
// TODO(bjornv): How should we handle the multi-channel case?
int EchoCancellationImpl::GetDelayMetrics(int* median, int* std) {
float fraction_poor_delays = 0;
return GetDelayMetrics(median, std, &fraction_poor_delays);
}
int EchoCancellationImpl::GetDelayMetrics(int* median,
int* std,
float* fraction_poor_delays) {
if (median == NULL) {
return AudioProcessing::kNullPointerError;
}
if (std == NULL) {
return AudioProcessing::kNullPointerError;
}
if (!enabled_ || !delay_logging_enabled_) {
return AudioProcessing::kNotEnabledError;
}
const int err = WebRtcAec_GetDelayMetrics(cancellers_[0]->state(), median,
std, fraction_poor_delays);
if (err != AudioProcessing::kNoError) {
return MapError(err);
}
return AudioProcessing::kNoError;
}
struct AecCore* EchoCancellationImpl::aec_core() const {
if (!enabled_) {
return NULL;
}
return WebRtcAec_aec_core(cancellers_[0]->state());
}
void EchoCancellationImpl::Initialize(int sample_rate_hz,
size_t num_reverse_channels,
size_t num_output_channels,
size_t num_proc_channels) {
stream_properties_.reset(
new StreamProperties(sample_rate_hz, num_reverse_channels,
num_output_channels, num_proc_channels));
if (!enabled_) {
return;
}
const size_t num_cancellers_required =
NumCancellersRequired(stream_properties_->num_output_channels,
stream_properties_->num_reverse_channels);
if (num_cancellers_required > cancellers_.size()) {
const size_t cancellers_old_size = cancellers_.size();
cancellers_.resize(num_cancellers_required);
for (size_t i = cancellers_old_size; i < cancellers_.size(); ++i) {
cancellers_[i].reset(new Canceller());
}
}
for (auto& canceller : cancellers_) {
canceller->Initialize(sample_rate_hz);
}
Configure();
}
int EchoCancellationImpl::GetSystemDelayInSamples() const {
RTC_DCHECK(enabled_);
// Report the delay for the first AEC component.
return WebRtcAec_system_delay(WebRtcAec_aec_core(cancellers_[0]->state()));
}
void EchoCancellationImpl::PackRenderAudioBuffer(
const AudioBuffer* audio,
size_t num_output_channels,
size_t num_channels,
std::vector<float>* packed_buffer) {
RTC_DCHECK_GE(160, audio->num_frames_per_band());
RTC_DCHECK_EQ(num_channels, audio->num_channels());
packed_buffer->clear();
// The ordering convention must be followed to pass the correct data.
for (size_t i = 0; i < num_output_channels; i++) {
for (size_t j = 0; j < audio->num_channels(); j++) {
// Buffer the samples in the render queue.
packed_buffer->insert(packed_buffer->end(),
audio->split_bands_const_f(j)[kBand0To8kHz],
(audio->split_bands_const_f(j)[kBand0To8kHz] +
audio->num_frames_per_band()));
}
}
}
void EchoCancellationImpl::SetExtraOptions(const webrtc::Config& config) {
{
extended_filter_enabled_ = config.Get<ExtendedFilter>().enabled;
delay_agnostic_enabled_ = config.Get<DelayAgnostic>().enabled;
refined_adaptive_filter_enabled_ =
config.Get<RefinedAdaptiveFilter>().enabled;
}
Configure();
}
int EchoCancellationImpl::Configure() {
AecConfig config;
config.metricsMode = metrics_enabled_;
config.nlpMode = MapSetting(suppression_level_);
config.skewMode = drift_compensation_enabled_;
config.delay_logging = delay_logging_enabled_;
int error = AudioProcessing::kNoError;
for (auto& canceller : cancellers_) {
WebRtcAec_enable_extended_filter(WebRtcAec_aec_core(canceller->state()),
extended_filter_enabled_ ? 1 : 0);
WebRtcAec_enable_delay_agnostic(WebRtcAec_aec_core(canceller->state()),
delay_agnostic_enabled_ ? 1 : 0);
WebRtcAec_enable_refined_adaptive_filter(
WebRtcAec_aec_core(canceller->state()),
refined_adaptive_filter_enabled_);
const int handle_error = WebRtcAec_set_config(canceller->state(), config);
if (handle_error != AudioProcessing::kNoError) {
error = AudioProcessing::kNoError;
}
}
return error;
}
size_t EchoCancellationImpl::NumCancellersRequired(
size_t num_output_channels,
size_t num_reverse_channels) {
return num_output_channels * num_reverse_channels;
}
} // namespace webrtc