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libtgvoip/webrtc_dsp/modules/audio_processing/include/audio_processing.h
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

891 lines
35 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.
*/
#ifndef MODULES_AUDIO_PROCESSING_INCLUDE_AUDIO_PROCESSING_H_
#define MODULES_AUDIO_PROCESSING_INCLUDE_AUDIO_PROCESSING_H_
// MSVC++ requires this to be set before any other includes to get M_PI.
#ifndef _USE_MATH_DEFINES
#define _USE_MATH_DEFINES
#endif
#include <math.h>
#include <stddef.h> // size_t
#include <stdio.h> // FILE
#include <string.h>
#include <vector>
#include "absl/types/optional.h"
#include "api/audio/echo_canceller3_config.h"
#include "api/audio/echo_control.h"
#include "modules/audio_processing/include/audio_generator.h"
#include "modules/audio_processing/include/audio_processing_statistics.h"
#include "modules/audio_processing/include/config.h"
#include "modules/audio_processing/include/gain_control.h"
#include "rtc_base/arraysize.h"
#include "rtc_base/deprecation.h"
#include "rtc_base/platform_file.h"
#include "rtc_base/refcount.h"
#include "rtc_base/scoped_ref_ptr.h"
#include "rtc_base/system/rtc_export.h"
namespace webrtc {
struct AecCore;
class AecDump;
class AudioBuffer;
class AudioFrame;
class StreamConfig;
class ProcessingConfig;
class EchoDetector;
class GainControl;
class LevelEstimator;
class NoiseSuppression;
class CustomAudioAnalyzer;
class CustomProcessing;
class VoiceDetection;
// Use to enable the extended filter mode in the AEC, along with robustness
// measures around the reported system delays. It comes with a significant
// increase in AEC complexity, but is much more robust to unreliable reported
// delays.
//
// Detailed changes to the algorithm:
// - The filter length is changed from 48 to 128 ms. This comes with tuning of
// several parameters: i) filter adaptation stepsize and error threshold;
// ii) non-linear processing smoothing and overdrive.
// - Option to ignore the reported delays on platforms which we deem
// sufficiently unreliable. See WEBRTC_UNTRUSTED_DELAY in echo_cancellation.c.
// - Faster startup times by removing the excessive "startup phase" processing
// of reported delays.
// - Much more conservative adjustments to the far-end read pointer. We smooth
// the delay difference more heavily, and back off from the difference more.
// Adjustments force a readaptation of the filter, so they should be avoided
// except when really necessary.
struct ExtendedFilter {
ExtendedFilter() : enabled(false) {}
explicit ExtendedFilter(bool enabled) : enabled(enabled) {}
static const ConfigOptionID identifier = ConfigOptionID::kExtendedFilter;
bool enabled;
};
// Enables the refined linear filter adaptation in the echo canceller.
// This configuration only applies to non-mobile echo cancellation.
// It can be set in the constructor or using AudioProcessing::SetExtraOptions().
struct RefinedAdaptiveFilter {
RefinedAdaptiveFilter() : enabled(false) {}
explicit RefinedAdaptiveFilter(bool enabled) : enabled(enabled) {}
static const ConfigOptionID identifier =
ConfigOptionID::kAecRefinedAdaptiveFilter;
bool enabled;
};
// Enables delay-agnostic echo cancellation. This feature relies on internally
// estimated delays between the process and reverse streams, thus not relying
// on reported system delays. This configuration only applies to non-mobile echo
// cancellation. It can be set in the constructor or using
// AudioProcessing::SetExtraOptions().
struct DelayAgnostic {
DelayAgnostic() : enabled(false) {}
explicit DelayAgnostic(bool enabled) : enabled(enabled) {}
static const ConfigOptionID identifier = ConfigOptionID::kDelayAgnostic;
bool enabled;
};
// Use to enable experimental gain control (AGC). At startup the experimental
// AGC moves the microphone volume up to |startup_min_volume| if the current
// microphone volume is set too low. The value is clamped to its operating range
// [12, 255]. Here, 255 maps to 100%.
//
// Must be provided through AudioProcessingBuilder().Create(config).
#if defined(WEBRTC_CHROMIUM_BUILD)
static const int kAgcStartupMinVolume = 85;
#else
static const int kAgcStartupMinVolume = 0;
#endif // defined(WEBRTC_CHROMIUM_BUILD)
static constexpr int kClippedLevelMin = 70;
struct ExperimentalAgc {
ExperimentalAgc() = default;
explicit ExperimentalAgc(bool enabled) : enabled(enabled) {}
ExperimentalAgc(bool enabled,
bool enabled_agc2_level_estimator,
bool digital_adaptive_disabled,
bool analyze_before_aec)
: enabled(enabled),
enabled_agc2_level_estimator(enabled_agc2_level_estimator),
digital_adaptive_disabled(digital_adaptive_disabled),
analyze_before_aec(analyze_before_aec) {}
ExperimentalAgc(bool enabled, int startup_min_volume)
: enabled(enabled), startup_min_volume(startup_min_volume) {}
ExperimentalAgc(bool enabled, int startup_min_volume, int clipped_level_min)
: enabled(enabled),
startup_min_volume(startup_min_volume),
clipped_level_min(clipped_level_min) {}
static const ConfigOptionID identifier = ConfigOptionID::kExperimentalAgc;
bool enabled = true;
int startup_min_volume = kAgcStartupMinVolume;
// Lowest microphone level that will be applied in response to clipping.
int clipped_level_min = kClippedLevelMin;
bool enabled_agc2_level_estimator = false;
bool digital_adaptive_disabled = false;
// 'analyze_before_aec' is an experimental flag. It is intended to be removed
// at some point.
bool analyze_before_aec = false;
};
// Use to enable experimental noise suppression. It can be set in the
// constructor or using AudioProcessing::SetExtraOptions().
struct ExperimentalNs {
ExperimentalNs() : enabled(false) {}
explicit ExperimentalNs(bool enabled) : enabled(enabled) {}
static const ConfigOptionID identifier = ConfigOptionID::kExperimentalNs;
bool enabled;
};
// The Audio Processing Module (APM) provides a collection of voice processing
// components designed for real-time communications software.
//
// APM operates on two audio streams on a frame-by-frame basis. Frames of the
// primary stream, on which all processing is applied, are passed to
// |ProcessStream()|. Frames of the reverse direction stream are passed to
// |ProcessReverseStream()|. On the client-side, this will typically be the
// near-end (capture) and far-end (render) streams, respectively. APM should be
// placed in the signal chain as close to the audio hardware abstraction layer
// (HAL) as possible.
//
// On the server-side, the reverse stream will normally not be used, with
// processing occurring on each incoming stream.
//
// Component interfaces follow a similar pattern and are accessed through
// corresponding getters in APM. All components are disabled at create-time,
// with default settings that are recommended for most situations. New settings
// can be applied without enabling a component. Enabling a component triggers
// memory allocation and initialization to allow it to start processing the
// streams.
//
// Thread safety is provided with the following assumptions to reduce locking
// overhead:
// 1. The stream getters and setters are called from the same thread as
// ProcessStream(). More precisely, stream functions are never called
// concurrently with ProcessStream().
// 2. Parameter getters are never called concurrently with the corresponding
// setter.
//
// APM accepts only linear PCM audio data in chunks of 10 ms. The int16
// interfaces use interleaved data, while the float interfaces use deinterleaved
// data.
//
// Usage example, omitting error checking:
// AudioProcessing* apm = AudioProcessingBuilder().Create();
//
// AudioProcessing::Config config;
// config.echo_canceller.enabled = true;
// config.echo_canceller.mobile_mode = false;
// config.high_pass_filter.enabled = true;
// config.gain_controller2.enabled = true;
// apm->ApplyConfig(config)
//
// apm->noise_reduction()->set_level(kHighSuppression);
// apm->noise_reduction()->Enable(true);
//
// apm->gain_control()->set_analog_level_limits(0, 255);
// apm->gain_control()->set_mode(kAdaptiveAnalog);
// apm->gain_control()->Enable(true);
//
// apm->voice_detection()->Enable(true);
//
// // Start a voice call...
//
// // ... Render frame arrives bound for the audio HAL ...
// apm->ProcessReverseStream(render_frame);
//
// // ... Capture frame arrives from the audio HAL ...
// // Call required set_stream_ functions.
// apm->set_stream_delay_ms(delay_ms);
// apm->gain_control()->set_stream_analog_level(analog_level);
//
// apm->ProcessStream(capture_frame);
//
// // Call required stream_ functions.
// analog_level = apm->gain_control()->stream_analog_level();
// has_voice = apm->stream_has_voice();
//
// // Repeate render and capture processing for the duration of the call...
// // Start a new call...
// apm->Initialize();
//
// // Close the application...
// delete apm;
//
class AudioProcessing : public rtc::RefCountInterface {
public:
// The struct below constitutes the new parameter scheme for the audio
// processing. It is being introduced gradually and until it is fully
// introduced, it is prone to change.
// TODO(peah): Remove this comment once the new config scheme is fully rolled
// out.
//
// The parameters and behavior of the audio processing module are controlled
// by changing the default values in the AudioProcessing::Config struct.
// The config is applied by passing the struct to the ApplyConfig method.
struct Config {
struct EchoCanceller {
bool enabled = false;
bool mobile_mode = false;
// Recommended not to use. Will be removed in the future.
// APM components are not fine-tuned for legacy suppression levels.
bool legacy_moderate_suppression_level = false;
} echo_canceller;
struct ResidualEchoDetector {
bool enabled = true;
} residual_echo_detector;
struct HighPassFilter {
bool enabled = false;
} high_pass_filter;
// Enabled the pre-amplifier. It amplifies the capture signal
// before any other processing is done.
struct PreAmplifier {
bool enabled = false;
float fixed_gain_factor = 1.f;
} pre_amplifier;
// Enables the next generation AGC functionality. This feature replaces the
// standard methods of gain control in the previous AGC. Enabling this
// submodule enables an adaptive digital AGC followed by a limiter. By
// setting |fixed_gain_db|, the limiter can be turned into a compressor that
// first applies a fixed gain. The adaptive digital AGC can be turned off by
// setting |adaptive_digital_mode=false|.
struct GainController2 {
enum LevelEstimator { kRms, kPeak };
bool enabled = false;
struct {
float gain_db = 0.f;
} fixed_digital;
struct {
bool enabled = true;
LevelEstimator level_estimator = kRms;
bool use_saturation_protector = true;
float extra_saturation_margin_db = 2.f;
} adaptive_digital;
} gain_controller2;
// Explicit copy assignment implementation to avoid issues with memory
// sanitizer complaints in case of self-assignment.
// TODO(peah): Add buildflag to ensure that this is only included for memory
// sanitizer builds.
Config& operator=(const Config& config) {
if (this != &config) {
memcpy(this, &config, sizeof(*this));
}
return *this;
}
};
// TODO(mgraczyk): Remove once all methods that use ChannelLayout are gone.
enum ChannelLayout {
kMono,
// Left, right.
kStereo,
// Mono, keyboard, and mic.
kMonoAndKeyboard,
// Left, right, keyboard, and mic.
kStereoAndKeyboard
};
// Specifies the properties of a setting to be passed to AudioProcessing at
// runtime.
class RuntimeSetting {
public:
enum class Type {
kNotSpecified,
kCapturePreGain,
kCustomRenderProcessingRuntimeSetting
};
RuntimeSetting() : type_(Type::kNotSpecified), value_(0.f) {}
~RuntimeSetting() = default;
static RuntimeSetting CreateCapturePreGain(float gain) {
RTC_DCHECK_GE(gain, 1.f) << "Attenuation is not allowed.";
return {Type::kCapturePreGain, gain};
}
static RuntimeSetting CreateCustomRenderSetting(float payload) {
return {Type::kCustomRenderProcessingRuntimeSetting, payload};
}
Type type() const { return type_; }
void GetFloat(float* value) const {
RTC_DCHECK(value);
*value = value_;
}
private:
RuntimeSetting(Type id, float value) : type_(id), value_(value) {}
Type type_;
float value_;
};
~AudioProcessing() override {}
// Initializes internal states, while retaining all user settings. This
// should be called before beginning to process a new audio stream. However,
// it is not necessary to call before processing the first stream after
// creation.
//
// It is also not necessary to call if the audio parameters (sample
// rate and number of channels) have changed. Passing updated parameters
// directly to |ProcessStream()| and |ProcessReverseStream()| is permissible.
// If the parameters are known at init-time though, they may be provided.
virtual int Initialize() = 0;
// The int16 interfaces require:
// - only |NativeRate|s be used
// - that the input, output and reverse rates must match
// - that |processing_config.output_stream()| matches
// |processing_config.input_stream()|.
//
// The float interfaces accept arbitrary rates and support differing input and
// output layouts, but the output must have either one channel or the same
// number of channels as the input.
virtual int Initialize(const ProcessingConfig& processing_config) = 0;
// Initialize with unpacked parameters. See Initialize() above for details.
//
// TODO(mgraczyk): Remove once clients are updated to use the new interface.
virtual int Initialize(int capture_input_sample_rate_hz,
int capture_output_sample_rate_hz,
int render_sample_rate_hz,
ChannelLayout capture_input_layout,
ChannelLayout capture_output_layout,
ChannelLayout render_input_layout) = 0;
// TODO(peah): This method is a temporary solution used to take control
// over the parameters in the audio processing module and is likely to change.
virtual void ApplyConfig(const Config& config) = 0;
// Pass down additional options which don't have explicit setters. This
// ensures the options are applied immediately.
virtual void SetExtraOptions(const webrtc::Config& config) = 0;
// TODO(ajm): Only intended for internal use. Make private and friend the
// necessary classes?
virtual int proc_sample_rate_hz() const = 0;
virtual int proc_split_sample_rate_hz() const = 0;
virtual size_t num_input_channels() const = 0;
virtual size_t num_proc_channels() const = 0;
virtual size_t num_output_channels() const = 0;
virtual size_t num_reverse_channels() const = 0;
// Set to true when the output of AudioProcessing will be muted or in some
// other way not used. Ideally, the captured audio would still be processed,
// but some components may change behavior based on this information.
// Default false.
virtual void set_output_will_be_muted(bool muted) = 0;
// Enqueue a runtime setting.
virtual void SetRuntimeSetting(RuntimeSetting setting) = 0;
// Processes a 10 ms |frame| of the primary audio stream. On the client-side,
// this is the near-end (or captured) audio.
//
// If needed for enabled functionality, any function with the set_stream_ tag
// must be called prior to processing the current frame. Any getter function
// with the stream_ tag which is needed should be called after processing.
//
// The |sample_rate_hz_|, |num_channels_|, and |samples_per_channel_|
// members of |frame| must be valid. If changed from the previous call to this
// method, it will trigger an initialization.
virtual int ProcessStream(AudioFrame* frame) = 0;
// Accepts deinterleaved float audio with the range [-1, 1]. Each element
// of |src| points to a channel buffer, arranged according to
// |input_layout|. At output, the channels will be arranged according to
// |output_layout| at |output_sample_rate_hz| in |dest|.
//
// The output layout must have one channel or as many channels as the input.
// |src| and |dest| may use the same memory, if desired.
//
// TODO(mgraczyk): Remove once clients are updated to use the new interface.
virtual int ProcessStream(const float* const* src,
size_t samples_per_channel,
int input_sample_rate_hz,
ChannelLayout input_layout,
int output_sample_rate_hz,
ChannelLayout output_layout,
float* const* dest) = 0;
// Accepts deinterleaved float audio with the range [-1, 1]. Each element of
// |src| points to a channel buffer, arranged according to |input_stream|. At
// output, the channels will be arranged according to |output_stream| in
// |dest|.
//
// The output must have one channel or as many channels as the input. |src|
// and |dest| may use the same memory, if desired.
virtual int ProcessStream(const float* const* src,
const StreamConfig& input_config,
const StreamConfig& output_config,
float* const* dest) = 0;
// Processes a 10 ms |frame| of the reverse direction audio stream. The frame
// may be modified. On the client-side, this is the far-end (or to be
// rendered) audio.
//
// It is necessary to provide this if echo processing is enabled, as the
// reverse stream forms the echo reference signal. It is recommended, but not
// necessary, to provide if gain control is enabled. On the server-side this
// typically will not be used. If you're not sure what to pass in here,
// chances are you don't need to use it.
//
// The |sample_rate_hz_|, |num_channels_|, and |samples_per_channel_|
// members of |frame| must be valid.
virtual int ProcessReverseStream(AudioFrame* frame) = 0;
// Accepts deinterleaved float audio with the range [-1, 1]. Each element
// of |data| points to a channel buffer, arranged according to |layout|.
// TODO(mgraczyk): Remove once clients are updated to use the new interface.
virtual int AnalyzeReverseStream(const float* const* data,
size_t samples_per_channel,
int sample_rate_hz,
ChannelLayout layout) = 0;
// Accepts deinterleaved float audio with the range [-1, 1]. Each element of
// |data| points to a channel buffer, arranged according to |reverse_config|.
virtual int ProcessReverseStream(const float* const* src,
const StreamConfig& input_config,
const StreamConfig& output_config,
float* const* dest) = 0;
// This must be called if and only if echo processing is enabled.
//
// Sets the |delay| in ms between ProcessReverseStream() receiving a far-end
// frame and ProcessStream() receiving a near-end frame containing the
// corresponding echo. On the client-side this can be expressed as
// delay = (t_render - t_analyze) + (t_process - t_capture)
// where,
// - t_analyze is the time a frame is passed to ProcessReverseStream() and
// t_render is the time the first sample of the same frame is rendered by
// the audio hardware.
// - t_capture is the time the first sample of a frame is captured by the
// audio hardware and t_process is the time the same frame is passed to
// ProcessStream().
virtual int set_stream_delay_ms(int delay) = 0;
virtual int stream_delay_ms() const = 0;
virtual bool was_stream_delay_set() const = 0;
// Call to signal that a key press occurred (true) or did not occur (false)
// with this chunk of audio.
virtual void set_stream_key_pressed(bool key_pressed) = 0;
// Sets a delay |offset| in ms to add to the values passed in through
// set_stream_delay_ms(). May be positive or negative.
//
// Note that this could cause an otherwise valid value passed to
// set_stream_delay_ms() to return an error.
virtual void set_delay_offset_ms(int offset) = 0;
virtual int delay_offset_ms() const = 0;
// Attaches provided webrtc::AecDump for recording debugging
// information. Log file and maximum file size logic is supposed to
// be handled by implementing instance of AecDump. Calling this
// method when another AecDump is attached resets the active AecDump
// with a new one. This causes the d-tor of the earlier AecDump to
// be called. The d-tor call may block until all pending logging
// tasks are completed.
virtual void AttachAecDump(std::unique_ptr<AecDump> aec_dump) = 0;
// If no AecDump is attached, this has no effect. If an AecDump is
// attached, it's destructor is called. The d-tor may block until
// all pending logging tasks are completed.
virtual void DetachAecDump() = 0;
// Attaches provided webrtc::AudioGenerator for modifying playout audio.
// Calling this method when another AudioGenerator is attached replaces the
// active AudioGenerator with a new one.
virtual void AttachPlayoutAudioGenerator(
std::unique_ptr<AudioGenerator> audio_generator) = 0;
// If no AudioGenerator is attached, this has no effect. If an AecDump is
// attached, its destructor is called.
virtual void DetachPlayoutAudioGenerator() = 0;
// Use to send UMA histograms at end of a call. Note that all histogram
// specific member variables are reset.
virtual void UpdateHistogramsOnCallEnd() = 0;
// Get audio processing statistics. The |has_remote_tracks| argument should be
// set if there are active remote tracks (this would usually be true during
// a call). If there are no remote tracks some of the stats will not be set by
// AudioProcessing, because they only make sense if there is at least one
// remote track.
virtual AudioProcessingStats GetStatistics(bool has_remote_tracks) const = 0;
// These provide access to the component interfaces and should never return
// NULL. The pointers will be valid for the lifetime of the APM instance.
// The memory for these objects is entirely managed internally.
virtual GainControl* gain_control() const = 0;
virtual LevelEstimator* level_estimator() const = 0;
virtual NoiseSuppression* noise_suppression() const = 0;
virtual VoiceDetection* voice_detection() const = 0;
// Returns the last applied configuration.
virtual AudioProcessing::Config GetConfig() const = 0;
enum Error {
// Fatal errors.
kNoError = 0,
kUnspecifiedError = -1,
kCreationFailedError = -2,
kUnsupportedComponentError = -3,
kUnsupportedFunctionError = -4,
kNullPointerError = -5,
kBadParameterError = -6,
kBadSampleRateError = -7,
kBadDataLengthError = -8,
kBadNumberChannelsError = -9,
kFileError = -10,
kStreamParameterNotSetError = -11,
kNotEnabledError = -12,
// Warnings are non-fatal.
// This results when a set_stream_ parameter is out of range. Processing
// will continue, but the parameter may have been truncated.
kBadStreamParameterWarning = -13
};
enum NativeRate {
kSampleRate8kHz = 8000,
kSampleRate16kHz = 16000,
kSampleRate32kHz = 32000,
kSampleRate48kHz = 48000
};
// TODO(kwiberg): We currently need to support a compiler (Visual C++) that
// complains if we don't explicitly state the size of the array here. Remove
// the size when that's no longer the case.
static constexpr int kNativeSampleRatesHz[4] = {
kSampleRate8kHz, kSampleRate16kHz, kSampleRate32kHz, kSampleRate48kHz};
static constexpr size_t kNumNativeSampleRates =
arraysize(kNativeSampleRatesHz);
static constexpr int kMaxNativeSampleRateHz =
kNativeSampleRatesHz[kNumNativeSampleRates - 1];
static const int kChunkSizeMs = 10;
};
class RTC_EXPORT AudioProcessingBuilder {
public:
AudioProcessingBuilder();
~AudioProcessingBuilder();
// The AudioProcessingBuilder takes ownership of the echo_control_factory.
AudioProcessingBuilder& SetEchoControlFactory(
std::unique_ptr<EchoControlFactory> echo_control_factory);
// The AudioProcessingBuilder takes ownership of the capture_post_processing.
AudioProcessingBuilder& SetCapturePostProcessing(
std::unique_ptr<CustomProcessing> capture_post_processing);
// The AudioProcessingBuilder takes ownership of the render_pre_processing.
AudioProcessingBuilder& SetRenderPreProcessing(
std::unique_ptr<CustomProcessing> render_pre_processing);
// The AudioProcessingBuilder takes ownership of the echo_detector.
AudioProcessingBuilder& SetEchoDetector(
rtc::scoped_refptr<EchoDetector> echo_detector);
// The AudioProcessingBuilder takes ownership of the capture_analyzer.
AudioProcessingBuilder& SetCaptureAnalyzer(
std::unique_ptr<CustomAudioAnalyzer> capture_analyzer);
// This creates an APM instance using the previously set components. Calling
// the Create function resets the AudioProcessingBuilder to its initial state.
AudioProcessing* Create();
AudioProcessing* Create(const webrtc::Config& config);
private:
std::unique_ptr<EchoControlFactory> echo_control_factory_;
std::unique_ptr<CustomProcessing> capture_post_processing_;
std::unique_ptr<CustomProcessing> render_pre_processing_;
rtc::scoped_refptr<EchoDetector> echo_detector_;
std::unique_ptr<CustomAudioAnalyzer> capture_analyzer_;
RTC_DISALLOW_COPY_AND_ASSIGN(AudioProcessingBuilder);
};
class StreamConfig {
public:
// sample_rate_hz: The sampling rate of the stream.
//
// num_channels: The number of audio channels in the stream, excluding the
// keyboard channel if it is present. When passing a
// StreamConfig with an array of arrays T*[N],
//
// N == {num_channels + 1 if has_keyboard
// {num_channels if !has_keyboard
//
// has_keyboard: True if the stream has a keyboard channel. When has_keyboard
// is true, the last channel in any corresponding list of
// channels is the keyboard channel.
StreamConfig(int sample_rate_hz = 0,
size_t num_channels = 0,
bool has_keyboard = false)
: sample_rate_hz_(sample_rate_hz),
num_channels_(num_channels),
has_keyboard_(has_keyboard),
num_frames_(calculate_frames(sample_rate_hz)) {}
void set_sample_rate_hz(int value) {
sample_rate_hz_ = value;
num_frames_ = calculate_frames(value);
}
void set_num_channels(size_t value) { num_channels_ = value; }
void set_has_keyboard(bool value) { has_keyboard_ = value; }
int sample_rate_hz() const { return sample_rate_hz_; }
// The number of channels in the stream, not including the keyboard channel if
// present.
size_t num_channels() const { return num_channels_; }
bool has_keyboard() const { return has_keyboard_; }
size_t num_frames() const { return num_frames_; }
size_t num_samples() const { return num_channels_ * num_frames_; }
bool operator==(const StreamConfig& other) const {
return sample_rate_hz_ == other.sample_rate_hz_ &&
num_channels_ == other.num_channels_ &&
has_keyboard_ == other.has_keyboard_;
}
bool operator!=(const StreamConfig& other) const { return !(*this == other); }
private:
static size_t calculate_frames(int sample_rate_hz) {
return static_cast<size_t>(AudioProcessing::kChunkSizeMs * sample_rate_hz /
1000);
}
int sample_rate_hz_;
size_t num_channels_;
bool has_keyboard_;
size_t num_frames_;
};
class ProcessingConfig {
public:
enum StreamName {
kInputStream,
kOutputStream,
kReverseInputStream,
kReverseOutputStream,
kNumStreamNames,
};
const StreamConfig& input_stream() const {
return streams[StreamName::kInputStream];
}
const StreamConfig& output_stream() const {
return streams[StreamName::kOutputStream];
}
const StreamConfig& reverse_input_stream() const {
return streams[StreamName::kReverseInputStream];
}
const StreamConfig& reverse_output_stream() const {
return streams[StreamName::kReverseOutputStream];
}
StreamConfig& input_stream() { return streams[StreamName::kInputStream]; }
StreamConfig& output_stream() { return streams[StreamName::kOutputStream]; }
StreamConfig& reverse_input_stream() {
return streams[StreamName::kReverseInputStream];
}
StreamConfig& reverse_output_stream() {
return streams[StreamName::kReverseOutputStream];
}
bool operator==(const ProcessingConfig& other) const {
for (int i = 0; i < StreamName::kNumStreamNames; ++i) {
if (this->streams[i] != other.streams[i]) {
return false;
}
}
return true;
}
bool operator!=(const ProcessingConfig& other) const {
return !(*this == other);
}
StreamConfig streams[StreamName::kNumStreamNames];
};
// An estimation component used to retrieve level metrics.
class LevelEstimator {
public:
virtual int Enable(bool enable) = 0;
virtual bool is_enabled() const = 0;
// Returns the root mean square (RMS) level in dBFs (decibels from digital
// full-scale), or alternately dBov. It is computed over all primary stream
// frames since the last call to RMS(). The returned value is positive but
// should be interpreted as negative. It is constrained to [0, 127].
//
// The computation follows: https://tools.ietf.org/html/rfc6465
// with the intent that it can provide the RTP audio level indication.
//
// Frames passed to ProcessStream() with an |_energy| of zero are considered
// to have been muted. The RMS of the frame will be interpreted as -127.
virtual int RMS() = 0;
protected:
virtual ~LevelEstimator() {}
};
// The noise suppression (NS) component attempts to remove noise while
// retaining speech. Recommended to be enabled on the client-side.
//
// Recommended to be enabled on the client-side.
class NoiseSuppression {
public:
virtual int Enable(bool enable) = 0;
virtual bool is_enabled() const = 0;
// Determines the aggressiveness of the suppression. Increasing the level
// will reduce the noise level at the expense of a higher speech distortion.
enum Level { kLow, kModerate, kHigh, kVeryHigh };
virtual int set_level(Level level) = 0;
virtual Level level() const = 0;
// Returns the internally computed prior speech probability of current frame
// averaged over output channels. This is not supported in fixed point, for
// which |kUnsupportedFunctionError| is returned.
virtual float speech_probability() const = 0;
// Returns the noise estimate per frequency bin averaged over all channels.
virtual std::vector<float> NoiseEstimate() = 0;
protected:
virtual ~NoiseSuppression() {}
};
// Experimental interface for a custom analysis submodule.
class CustomAudioAnalyzer {
public:
// (Re-) Initializes the submodule.
virtual void Initialize(int sample_rate_hz, int num_channels) = 0;
// Analyzes the given capture or render signal.
virtual void Analyze(const AudioBuffer* audio) = 0;
// Returns a string representation of the module state.
virtual std::string ToString() const = 0;
virtual ~CustomAudioAnalyzer() {}
};
// Interface for a custom processing submodule.
class CustomProcessing {
public:
// (Re-)Initializes the submodule.
virtual void Initialize(int sample_rate_hz, int num_channels) = 0;
// Processes the given capture or render signal.
virtual void Process(AudioBuffer* audio) = 0;
// Returns a string representation of the module state.
virtual std::string ToString() const = 0;
// Handles RuntimeSettings. TODO(webrtc:9262): make pure virtual
// after updating dependencies.
virtual void SetRuntimeSetting(AudioProcessing::RuntimeSetting setting);
virtual ~CustomProcessing() {}
};
// Interface for an echo detector submodule.
class EchoDetector : public rtc::RefCountInterface {
public:
// (Re-)Initializes the submodule.
virtual void Initialize(int capture_sample_rate_hz,
int num_capture_channels,
int render_sample_rate_hz,
int num_render_channels) = 0;
// Analysis (not changing) of the render signal.
virtual void AnalyzeRenderAudio(rtc::ArrayView<const float> render_audio) = 0;
// Analysis (not changing) of the capture signal.
virtual void AnalyzeCaptureAudio(
rtc::ArrayView<const float> capture_audio) = 0;
// Pack an AudioBuffer into a vector<float>.
static void PackRenderAudioBuffer(AudioBuffer* audio,
std::vector<float>* packed_buffer);
struct Metrics {
double echo_likelihood;
double echo_likelihood_recent_max;
};
// Collect current metrics from the echo detector.
virtual Metrics GetMetrics() const = 0;
};
// The voice activity detection (VAD) component analyzes the stream to
// determine if voice is present. A facility is also provided to pass in an
// external VAD decision.
//
// In addition to |stream_has_voice()| the VAD decision is provided through the
// |AudioFrame| passed to |ProcessStream()|. The |vad_activity_| member will be
// modified to reflect the current decision.
class VoiceDetection {
public:
virtual int Enable(bool enable) = 0;
virtual bool is_enabled() const = 0;
// Returns true if voice is detected in the current frame. Should be called
// after |ProcessStream()|.
virtual bool stream_has_voice() const = 0;
// Some of the APM functionality requires a VAD decision. In the case that
// a decision is externally available for the current frame, it can be passed
// in here, before |ProcessStream()| is called.
//
// VoiceDetection does _not_ need to be enabled to use this. If it happens to
// be enabled, detection will be skipped for any frame in which an external
// VAD decision is provided.
virtual int set_stream_has_voice(bool has_voice) = 0;
// Specifies the likelihood that a frame will be declared to contain voice.
// A higher value makes it more likely that speech will not be clipped, at
// the expense of more noise being detected as voice.
enum Likelihood {
kVeryLowLikelihood,
kLowLikelihood,
kModerateLikelihood,
kHighLikelihood
};
virtual int set_likelihood(Likelihood likelihood) = 0;
virtual Likelihood likelihood() const = 0;
// Sets the |size| of the frames in ms on which the VAD will operate. Larger
// frames will improve detection accuracy, but reduce the frequency of
// updates.
//
// This does not impact the size of frames passed to |ProcessStream()|.
virtual int set_frame_size_ms(int size) = 0;
virtual int frame_size_ms() const = 0;
protected:
virtual ~VoiceDetection() {}
};
} // namespace webrtc
#endif // MODULES_AUDIO_PROCESSING_INCLUDE_AUDIO_PROCESSING_H_