api/neteq/neteq.h - src - Git at Google

 /*
  *  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 API_NETEQ_NETEQ_H_
 #define API_NETEQ_NETEQ_H_

 #include <stddef.h>  // Provide access to size_t.

 #include <map>
 #include <string>
 #include <vector>

 #include "absl/types/optional.h"
 #include "api/audio_codecs/audio_codec_pair_id.h"
 #include "api/audio_codecs/audio_decoder.h"
 #include "api/audio_codecs/audio_format.h"
 #include "api/rtp_headers.h"
 #include "api/scoped_refptr.h"

 namespace webrtc {

 // Forward declarations.
 class AudioFrame;
 class AudioDecoderFactory;
 class Clock;

 struct NetEqNetworkStatistics {
   uint16_t current_buffer_size_ms;    // Current jitter buffer size in ms.
   uint16_t preferred_buffer_size_ms;  // Target buffer size in ms.
   uint16_t jitter_peaks_found;        // 1 if adding extra delay due to peaky
                                       // jitter; 0 otherwise.
   uint16_t expand_rate;         // Fraction (of original stream) of synthesized
                                 // audio inserted through expansion (in Q14).
   uint16_t speech_expand_rate;  // Fraction (of original stream) of synthesized
                                 // speech inserted through expansion (in Q14).
   uint16_t preemptive_rate;     // Fraction of data inserted through pre-emptive
                                 // expansion (in Q14).
   uint16_t accelerate_rate;     // Fraction of data removed through acceleration
                                 // (in Q14).
   uint16_t secondary_decoded_rate;    // Fraction of data coming from FEC/RED
                                       // decoding (in Q14).
   uint16_t secondary_discarded_rate;  // Fraction of discarded FEC/RED data (in
                                       // Q14).
   // Statistics for packet waiting times, i.e., the time between a packet
   // arrives until it is decoded.
   int mean_waiting_time_ms;
   int median_waiting_time_ms;
   int min_waiting_time_ms;
   int max_waiting_time_ms;
 };

 // NetEq statistics that persist over the lifetime of the class.
 // These metrics are never reset.
 struct NetEqLifetimeStatistics {
   // Stats below correspond to similarly-named fields in the WebRTC stats spec.
   // https://w3c.github.io/webrtc-stats/#dom-rtcmediastreamtrackstats
   uint64_t total_samples_received = 0;
   uint64_t concealed_samples = 0;
   uint64_t concealment_events = 0;
   uint64_t jitter_buffer_delay_ms = 0;
   uint64_t jitter_buffer_emitted_count = 0;
   uint64_t jitter_buffer_target_delay_ms = 0;
   uint64_t inserted_samples_for_deceleration = 0;
   uint64_t removed_samples_for_acceleration = 0;
   uint64_t silent_concealed_samples = 0;
   uint64_t fec_packets_received = 0;
   uint64_t fec_packets_discarded = 0;
   // Below stats are not part of the spec.
   uint64_t delayed_packet_outage_samples = 0;
   // This is sum of relative packet arrival delays of received packets so far.
   // Since end-to-end delay of a packet is difficult to measure and is not
   // necessarily useful for measuring jitter buffer performance, we report a
   // relative packet arrival delay. The relative packet arrival delay of a
   // packet is defined as the arrival delay compared to the first packet
   // received, given that it had zero delay. To avoid clock drift, the "first"
   // packet can be made dynamic.
   uint64_t relative_packet_arrival_delay_ms = 0;
   uint64_t jitter_buffer_packets_received = 0;
   // An interruption is a loss-concealment event lasting at least 150 ms. The
   // two stats below count the number os such events and the total duration of
   // these events.
   int32_t interruption_count = 0;
   int32_t total_interruption_duration_ms = 0;
 };

 // Metrics that describe the operations performed in NetEq, and the internal
 // state.
 struct NetEqOperationsAndState {
   // These sample counters are cumulative, and don't reset. As a reference, the
   // total number of output samples can be found in
   // NetEqLifetimeStatistics::total_samples_received.
   uint64_t preemptive_samples = 0;
   uint64_t accelerate_samples = 0;
   // Count of the number of buffer flushes.
   uint64_t packet_buffer_flushes = 0;
   // The number of primary packets that were discarded.
   uint64_t discarded_primary_packets = 0;
   // The statistics below are not cumulative.
   // The waiting time of the last decoded packet.
   uint64_t last_waiting_time_ms = 0;
   // The sum of the packet and jitter buffer size in ms.
   uint64_t current_buffer_size_ms = 0;
   // The current frame size in ms.
   uint64_t current_frame_size_ms = 0;
   // Flag to indicate that the next packet is available.
   bool next_packet_available = false;
 };

 // This is the interface class for NetEq.
 class NetEq {
  public:
   struct Config {
     Config();
     Config(const Config&);
     Config(Config&&);
     ~Config();
     Config& operator=(const Config&);
     Config& operator=(Config&&);

     std::string ToString() const;

     int sample_rate_hz = 16000;  // Initial value. Will change with input data.
     bool enable_post_decode_vad = false;
     size_t max_packets_in_buffer = 200;
     int max_delay_ms = 0;
     int min_delay_ms = 0;
     bool enable_fast_accelerate = false;
     bool enable_muted_state = false;
     bool enable_rtx_handling = false;
     absl::optional<AudioCodecPairId> codec_pair_id;
     bool for_test_no_time_stretching = false;  // Use only for testing.
     // Adds extra delay to the output of NetEq, without affecting jitter or
     // loss behavior. This is mainly for testing. Value must be a non-negative
     // multiple of 10 ms.
     int extra_output_delay_ms = 0;
   };

   enum ReturnCodes { kOK = 0, kFail = -1 };

   enum class Operation {
     kNormal,
     kMerge,
     kExpand,
     kAccelerate,
     kFastAccelerate,
     kPreemptiveExpand,
     kRfc3389Cng,
     kRfc3389CngNoPacket,
     kCodecInternalCng,
     kDtmf,
     kUndefined,
   };

   enum class Mode {
     kNormal,
     kExpand,
     kMerge,
     kAccelerateSuccess,
     kAccelerateLowEnergy,
     kAccelerateFail,
     kPreemptiveExpandSuccess,
     kPreemptiveExpandLowEnergy,
     kPreemptiveExpandFail,
     kRfc3389Cng,
     kCodecInternalCng,
     kCodecPlc,
     kDtmf,
     kError,
     kUndefined,
   };

   // Return type for GetDecoderFormat.
   struct DecoderFormat {
     int sample_rate_hz;
     int num_channels;
     SdpAudioFormat sdp_format;
   };

   // Creates a new NetEq object, with parameters set in |config|. The |config|
   // object will only have to be valid for the duration of the call to this
   // method.
   static NetEq* Create(
       const NetEq::Config& config,
       Clock* clock,
       const rtc::scoped_refptr<AudioDecoderFactory>& decoder_factory);

   virtual ~NetEq() {}

   // Inserts a new packet into NetEq.
   // Returns 0 on success, -1 on failure.
   virtual int InsertPacket(const RTPHeader& rtp_header,
                            rtc::ArrayView<const uint8_t> payload) = 0;

   // Lets NetEq know that a packet arrived with an empty payload. This typically
   // happens when empty packets are used for probing the network channel, and
   // these packets use RTP sequence numbers from the same series as the actual
   // audio packets.
   virtual void InsertEmptyPacket(const RTPHeader& rtp_header) = 0;

   // Instructs NetEq to deliver 10 ms of audio data. The data is written to
   // |audio_frame|. All data in |audio_frame| is wiped; |data_|, |speech_type_|,
   // |num_channels_|, |sample_rate_hz_|, |samples_per_channel_|, and
   // |vad_activity_| are updated upon success. If an error is returned, some
   // fields may not have been updated, or may contain inconsistent values.
   // If muted state is enabled (through Config::enable_muted_state), |muted|
   // may be set to true after a prolonged expand period. When this happens, the
   // |data_| in |audio_frame| is not written, but should be interpreted as being
   // all zeros. For testing purposes, an override can be supplied in the
   // |action_override| argument, which will cause NetEq to take this action
   // next, instead of the action it would normally choose.
   // Returns kOK on success, or kFail in case of an error.
   virtual int GetAudio(
       AudioFrame* audio_frame,
       bool* muted,
       absl::optional<Operation> action_override = absl::nullopt) = 0;

   // Replaces the current set of decoders with the given one.
   virtual void SetCodecs(const std::map<int, SdpAudioFormat>& codecs) = 0;

   // Associates |rtp_payload_type| with the given codec, which NetEq will
   // instantiate when it needs it. Returns true iff successful.
   virtual bool RegisterPayloadType(int rtp_payload_type,
                                    const SdpAudioFormat& audio_format) = 0;

   // Removes |rtp_payload_type| from the codec database. Returns 0 on success,
   // -1 on failure. Removing a payload type that is not registered is ok and
   // will not result in an error.
   virtual int RemovePayloadType(uint8_t rtp_payload_type) = 0;

   // Removes all payload types from the codec database.
   virtual void RemoveAllPayloadTypes() = 0;

   // Sets a minimum delay in millisecond for packet buffer. The minimum is
   // maintained unless a higher latency is dictated by channel condition.
   // Returns true if the minimum is successfully applied, otherwise false is
   // returned.
   virtual bool SetMinimumDelay(int delay_ms) = 0;

   // Sets a maximum delay in milliseconds for packet buffer. The latency will
   // not exceed the given value, even required delay (given the channel
   // conditions) is higher. Calling this method has the same effect as setting
   // the |max_delay_ms| value in the NetEq::Config struct.
   virtual bool SetMaximumDelay(int delay_ms) = 0;

   // Sets a base minimum delay in milliseconds for packet buffer. The minimum
   // delay which is set via |SetMinimumDelay| can't be lower than base minimum
   // delay. Calling this method is similar to setting the |min_delay_ms| value
   // in the NetEq::Config struct. Returns true if the base minimum is
   // successfully applied, otherwise false is returned.
   virtual bool SetBaseMinimumDelayMs(int delay_ms) = 0;

   // Returns current value of base minimum delay in milliseconds.
   virtual int GetBaseMinimumDelayMs() const = 0;

   // Returns the current target delay in ms. This includes any extra delay
   // requested through SetMinimumDelay.
   virtual int TargetDelayMs() const = 0;

   // Returns the current total delay (packet buffer and sync buffer) in ms,
   // with smoothing applied to even out short-time fluctuations due to jitter.
   // The packet buffer part of the delay is not updated during DTX/CNG periods.
   virtual int FilteredCurrentDelayMs() const = 0;

   // Writes the current network statistics to |stats|. The statistics are reset
   // after the call.
   virtual int NetworkStatistics(NetEqNetworkStatistics* stats) = 0;

   // Current values only, not resetting any state.
   virtual NetEqNetworkStatistics CurrentNetworkStatistics() const = 0;

   // Returns a copy of this class's lifetime statistics. These statistics are
   // never reset.
   virtual NetEqLifetimeStatistics GetLifetimeStatistics() const = 0;

   // Returns statistics about the performed operations and internal state. These
   // statistics are never reset.
   virtual NetEqOperationsAndState GetOperationsAndState() const = 0;

   // Enables post-decode VAD. When enabled, GetAudio() will return
   // kOutputVADPassive when the signal contains no speech.
   virtual void EnableVad() = 0;

   // Disables post-decode VAD.
   virtual void DisableVad() = 0;

   // Returns the RTP timestamp for the last sample delivered by GetAudio().
   // The return value will be empty if no valid timestamp is available.
   virtual absl::optional<uint32_t> GetPlayoutTimestamp() const = 0;

   // Returns the sample rate in Hz of the audio produced in the last GetAudio
   // call. If GetAudio has not been called yet, the configured sample rate
   // (Config::sample_rate_hz) is returned.
   virtual int last_output_sample_rate_hz() const = 0;

   // Returns the decoder info for the given payload type. Returns empty if no
   // such payload type was registered.
   virtual absl::optional<DecoderFormat> GetDecoderFormat(
       int payload_type) const = 0;

   // Flushes both the packet buffer and the sync buffer.
   virtual void FlushBuffers() = 0;

   // Enables NACK and sets the maximum size of the NACK list, which should be
   // positive and no larger than Nack::kNackListSizeLimit. If NACK is already
   // enabled then the maximum NACK list size is modified accordingly.
   virtual void EnableNack(size_t max_nack_list_size) = 0;

   virtual void DisableNack() = 0;

   // Returns a list of RTP sequence numbers corresponding to packets to be
   // retransmitted, given an estimate of the round-trip time in milliseconds.
   virtual std::vector<uint16_t> GetNackList(
       int64_t round_trip_time_ms) const = 0;

   // Returns a vector containing the timestamps of the packets that were decoded
   // in the last GetAudio call. If no packets were decoded in the last call, the
   // vector is empty.
   // Mainly intended for testing.
   virtual std::vector<uint32_t> LastDecodedTimestamps() const = 0;

   // Returns the length of the audio yet to play in the sync buffer.
   // Mainly intended for testing.
   virtual int SyncBufferSizeMs() const = 0;
 };

 }  // namespace webrtc
 #endif  // API_NETEQ_NETEQ_H_
	/*
	* 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 API_NETEQ_NETEQ_H_
	#define API_NETEQ_NETEQ_H_

	#include <stddef.h> // Provide access to size_t.

	#include <map>
	#include <string>
	#include <vector>

	#include "absl/types/optional.h"
	#include "api/audio_codecs/audio_codec_pair_id.h"
	#include "api/audio_codecs/audio_decoder.h"
	#include "api/audio_codecs/audio_format.h"
	#include "api/rtp_headers.h"
	#include "api/scoped_refptr.h"

	namespace webrtc {

	// Forward declarations.
	class AudioFrame;
	class AudioDecoderFactory;
	class Clock;

	struct NetEqNetworkStatistics {
	uint16_t current_buffer_size_ms; // Current jitter buffer size in ms.
	uint16_t preferred_buffer_size_ms; // Target buffer size in ms.
	uint16_t jitter_peaks_found; // 1 if adding extra delay due to peaky
	// jitter; 0 otherwise.
	uint16_t expand_rate; // Fraction (of original stream) of synthesized
	// audio inserted through expansion (in Q14).
	uint16_t speech_expand_rate; // Fraction (of original stream) of synthesized
	// speech inserted through expansion (in Q14).
	uint16_t preemptive_rate; // Fraction of data inserted through pre-emptive
	// expansion (in Q14).
	uint16_t accelerate_rate; // Fraction of data removed through acceleration
	// (in Q14).
	uint16_t secondary_decoded_rate; // Fraction of data coming from FEC/RED
	// decoding (in Q14).
	uint16_t secondary_discarded_rate; // Fraction of discarded FEC/RED data (in
	// Q14).
	// Statistics for packet waiting times, i.e., the time between a packet
	// arrives until it is decoded.
	int mean_waiting_time_ms;
	int median_waiting_time_ms;
	int min_waiting_time_ms;
	int max_waiting_time_ms;
	};

	// NetEq statistics that persist over the lifetime of the class.
	// These metrics are never reset.
	struct NetEqLifetimeStatistics {
	// Stats below correspond to similarly-named fields in the WebRTC stats spec.
	// https://w3c.github.io/webrtc-stats/#dom-rtcmediastreamtrackstats
	uint64_t total_samples_received = 0;
	uint64_t concealed_samples = 0;
	uint64_t concealment_events = 0;
	uint64_t jitter_buffer_delay_ms = 0;
	uint64_t jitter_buffer_emitted_count = 0;
	uint64_t jitter_buffer_target_delay_ms = 0;
	uint64_t inserted_samples_for_deceleration = 0;
	uint64_t removed_samples_for_acceleration = 0;
	uint64_t silent_concealed_samples = 0;
	uint64_t fec_packets_received = 0;
	uint64_t fec_packets_discarded = 0;
	// Below stats are not part of the spec.
	uint64_t delayed_packet_outage_samples = 0;
	// This is sum of relative packet arrival delays of received packets so far.
	// Since end-to-end delay of a packet is difficult to measure and is not
	// necessarily useful for measuring jitter buffer performance, we report a
	// relative packet arrival delay. The relative packet arrival delay of a
	// packet is defined as the arrival delay compared to the first packet
	// received, given that it had zero delay. To avoid clock drift, the "first"
	// packet can be made dynamic.
	uint64_t relative_packet_arrival_delay_ms = 0;
	uint64_t jitter_buffer_packets_received = 0;
	// An interruption is a loss-concealment event lasting at least 150 ms. The
	// two stats below count the number os such events and the total duration of
	// these events.
	int32_t interruption_count = 0;
	int32_t total_interruption_duration_ms = 0;
	};

	// Metrics that describe the operations performed in NetEq, and the internal
	// state.
	struct NetEqOperationsAndState {
	// These sample counters are cumulative, and don't reset. As a reference, the
	// total number of output samples can be found in
	// NetEqLifetimeStatistics::total_samples_received.
	uint64_t preemptive_samples = 0;
	uint64_t accelerate_samples = 0;
	// Count of the number of buffer flushes.
	uint64_t packet_buffer_flushes = 0;
	// The number of primary packets that were discarded.
	uint64_t discarded_primary_packets = 0;
	// The statistics below are not cumulative.
	// The waiting time of the last decoded packet.
	uint64_t last_waiting_time_ms = 0;
	// The sum of the packet and jitter buffer size in ms.
	uint64_t current_buffer_size_ms = 0;
	// The current frame size in ms.
	uint64_t current_frame_size_ms = 0;
	// Flag to indicate that the next packet is available.
	bool next_packet_available = false;
	};

	// This is the interface class for NetEq.
	class NetEq {
	public:
	struct Config {
	Config();
	Config(const Config&);
	Config(Config&&);
	~Config();
	Config& operator=(const Config&);
	Config& operator=(Config&&);

	std::string ToString() const;

	int sample_rate_hz = 16000; // Initial value. Will change with input data.
	bool enable_post_decode_vad = false;
	size_t max_packets_in_buffer = 200;
	int max_delay_ms = 0;
	int min_delay_ms = 0;
	bool enable_fast_accelerate = false;
	bool enable_muted_state = false;
	bool enable_rtx_handling = false;
	absl::optional<AudioCodecPairId> codec_pair_id;
	bool for_test_no_time_stretching = false; // Use only for testing.
	// Adds extra delay to the output of NetEq, without affecting jitter or
	// loss behavior. This is mainly for testing. Value must be a non-negative
	// multiple of 10 ms.
	int extra_output_delay_ms = 0;
	};

	enum ReturnCodes { kOK = 0, kFail = -1 };

	enum class Operation {
	kNormal,
	kMerge,
	kExpand,
	kAccelerate,
	kFastAccelerate,
	kPreemptiveExpand,
	kRfc3389Cng,
	kRfc3389CngNoPacket,
	kCodecInternalCng,
	kDtmf,
	kUndefined,
	};

	enum class Mode {
	kNormal,
	kExpand,
	kMerge,
	kAccelerateSuccess,
	kAccelerateLowEnergy,
	kAccelerateFail,
	kPreemptiveExpandSuccess,
	kPreemptiveExpandLowEnergy,
	kPreemptiveExpandFail,
	kRfc3389Cng,
	kCodecInternalCng,
	kCodecPlc,
	kDtmf,
	kError,
	kUndefined,
	};

	// Return type for GetDecoderFormat.
	struct DecoderFormat {
	int sample_rate_hz;
	int num_channels;
	SdpAudioFormat sdp_format;
	};

	// Creates a new NetEq object, with parameters set in \|config\|. The \|config\|
	// object will only have to be valid for the duration of the call to this
	// method.
	static NetEq* Create(
	const NetEq::Config& config,
	Clock* clock,
	const rtc::scoped_refptr<AudioDecoderFactory>& decoder_factory);

	virtual ~NetEq() {}

	// Inserts a new packet into NetEq.
	// Returns 0 on success, -1 on failure.
	virtual int InsertPacket(const RTPHeader& rtp_header,
	rtc::ArrayView<const uint8_t> payload) = 0;

	// Lets NetEq know that a packet arrived with an empty payload. This typically
	// happens when empty packets are used for probing the network channel, and
	// these packets use RTP sequence numbers from the same series as the actual
	// audio packets.
	virtual void InsertEmptyPacket(const RTPHeader& rtp_header) = 0;

	// Instructs NetEq to deliver 10 ms of audio data. The data is written to
	// \|audio_frame\|. All data in \|audio_frame\| is wiped; \|data_\|, \|speech_type_\|,
	// \|num_channels_\|, \|sample_rate_hz_\|, \|samples_per_channel_\|, and
	// \|vad_activity_\| are updated upon success. If an error is returned, some
	// fields may not have been updated, or may contain inconsistent values.
	// If muted state is enabled (through Config::enable_muted_state), \|muted\|
	// may be set to true after a prolonged expand period. When this happens, the
	// \|data_\| in \|audio_frame\| is not written, but should be interpreted as being
	// all zeros. For testing purposes, an override can be supplied in the
	// \|action_override\| argument, which will cause NetEq to take this action
	// next, instead of the action it would normally choose.
	// Returns kOK on success, or kFail in case of an error.
	virtual int GetAudio(
	AudioFrame* audio_frame,
	bool* muted,
	absl::optional<Operation> action_override = absl::nullopt) = 0;

	// Replaces the current set of decoders with the given one.
	virtual void SetCodecs(const std::map<int, SdpAudioFormat>& codecs) = 0;

	// Associates \|rtp_payload_type\| with the given codec, which NetEq will
	// instantiate when it needs it. Returns true iff successful.
	virtual bool RegisterPayloadType(int rtp_payload_type,
	const SdpAudioFormat& audio_format) = 0;

	// Removes \|rtp_payload_type\| from the codec database. Returns 0 on success,
	// -1 on failure. Removing a payload type that is not registered is ok and
	// will not result in an error.
	virtual int RemovePayloadType(uint8_t rtp_payload_type) = 0;

	// Removes all payload types from the codec database.
	virtual void RemoveAllPayloadTypes() = 0;

	// Sets a minimum delay in millisecond for packet buffer. The minimum is
	// maintained unless a higher latency is dictated by channel condition.
	// Returns true if the minimum is successfully applied, otherwise false is
	// returned.
	virtual bool SetMinimumDelay(int delay_ms) = 0;

	// Sets a maximum delay in milliseconds for packet buffer. The latency will
	// not exceed the given value, even required delay (given the channel
	// conditions) is higher. Calling this method has the same effect as setting
	// the \|max_delay_ms\| value in the NetEq::Config struct.
	virtual bool SetMaximumDelay(int delay_ms) = 0;

	// Sets a base minimum delay in milliseconds for packet buffer. The minimum
	// delay which is set via \|SetMinimumDelay\| can't be lower than base minimum
	// delay. Calling this method is similar to setting the \|min_delay_ms\| value
	// in the NetEq::Config struct. Returns true if the base minimum is
	// successfully applied, otherwise false is returned.
	virtual bool SetBaseMinimumDelayMs(int delay_ms) = 0;

	// Returns current value of base minimum delay in milliseconds.
	virtual int GetBaseMinimumDelayMs() const = 0;

	// Returns the current target delay in ms. This includes any extra delay
	// requested through SetMinimumDelay.
	virtual int TargetDelayMs() const = 0;

	// Returns the current total delay (packet buffer and sync buffer) in ms,
	// with smoothing applied to even out short-time fluctuations due to jitter.
	// The packet buffer part of the delay is not updated during DTX/CNG periods.
	virtual int FilteredCurrentDelayMs() const = 0;

	// Writes the current network statistics to \|stats\|. The statistics are reset
	// after the call.
	virtual int NetworkStatistics(NetEqNetworkStatistics* stats) = 0;

	// Current values only, not resetting any state.
	virtual NetEqNetworkStatistics CurrentNetworkStatistics() const = 0;

	// Returns a copy of this class's lifetime statistics. These statistics are
	// never reset.
	virtual NetEqLifetimeStatistics GetLifetimeStatistics() const = 0;

	// Returns statistics about the performed operations and internal state. These
	// statistics are never reset.
	virtual NetEqOperationsAndState GetOperationsAndState() const = 0;

	// Enables post-decode VAD. When enabled, GetAudio() will return
	// kOutputVADPassive when the signal contains no speech.
	virtual void EnableVad() = 0;

	// Disables post-decode VAD.
	virtual void DisableVad() = 0;

	// Returns the RTP timestamp for the last sample delivered by GetAudio().
	// The return value will be empty if no valid timestamp is available.
	virtual absl::optional<uint32_t> GetPlayoutTimestamp() const = 0;

	// Returns the sample rate in Hz of the audio produced in the last GetAudio
	// call. If GetAudio has not been called yet, the configured sample rate
	// (Config::sample_rate_hz) is returned.
	virtual int last_output_sample_rate_hz() const = 0;

	// Returns the decoder info for the given payload type. Returns empty if no
	// such payload type was registered.
	virtual absl::optional<DecoderFormat> GetDecoderFormat(
	int payload_type) const = 0;

	// Flushes both the packet buffer and the sync buffer.
	virtual void FlushBuffers() = 0;

	// Enables NACK and sets the maximum size of the NACK list, which should be
	// positive and no larger than Nack::kNackListSizeLimit. If NACK is already
	// enabled then the maximum NACK list size is modified accordingly.
	virtual void EnableNack(size_t max_nack_list_size) = 0;

	virtual void DisableNack() = 0;

	// Returns a list of RTP sequence numbers corresponding to packets to be
	// retransmitted, given an estimate of the round-trip time in milliseconds.
	virtual std::vector<uint16_t> GetNackList(
	int64_t round_trip_time_ms) const = 0;

	// Returns a vector containing the timestamps of the packets that were decoded
	// in the last GetAudio call. If no packets were decoded in the last call, the
	// vector is empty.
	// Mainly intended for testing.
	virtual std::vector<uint32_t> LastDecodedTimestamps() const = 0;

	// Returns the length of the audio yet to play in the sync buffer.
	// Mainly intended for testing.
	virtual int SyncBufferSizeMs() const = 0;
	};

	} // namespace webrtc
	#endif // API_NETEQ_NETEQ_H_