modules/audio_coding/neteq/nack_tracker.cc - src - Git at Google

 /*
  *  Copyright (c) 2013 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include "modules/audio_coding/neteq/nack_tracker.h"

 #include <assert.h>

 #include <cstdint>
 #include <utility>

 #include "rtc_base/checks.h"

 namespace webrtc {
 namespace {

 const int kDefaultSampleRateKhz = 48;
 const int kDefaultPacketSizeMs = 20;

 }  // namespace

 NackTracker::NackTracker(int nack_threshold_packets)
     : nack_threshold_packets_(nack_threshold_packets),
       sequence_num_last_received_rtp_(0),
       timestamp_last_received_rtp_(0),
       any_rtp_received_(false),
       sequence_num_last_decoded_rtp_(0),
       timestamp_last_decoded_rtp_(0),
       any_rtp_decoded_(false),
       sample_rate_khz_(kDefaultSampleRateKhz),
       samples_per_packet_(sample_rate_khz_ * kDefaultPacketSizeMs),
       max_nack_list_size_(kNackListSizeLimit) {}

 NackTracker::~NackTracker() = default;

 NackTracker* NackTracker::Create(int nack_threshold_packets) {
   return new NackTracker(nack_threshold_packets);
 }

 void NackTracker::UpdateSampleRate(int sample_rate_hz) {
   assert(sample_rate_hz > 0);
   sample_rate_khz_ = sample_rate_hz / 1000;
 }

 void NackTracker::UpdateLastReceivedPacket(uint16_t sequence_number,
                                            uint32_t timestamp) {
   // Just record the value of sequence number and timestamp if this is the
   // first packet.
   if (!any_rtp_received_) {
     sequence_num_last_received_rtp_ = sequence_number;
     timestamp_last_received_rtp_ = timestamp;
     any_rtp_received_ = true;
     // If no packet is decoded, to have a reasonable estimate of time-to-play
     // use the given values.
     if (!any_rtp_decoded_) {
       sequence_num_last_decoded_rtp_ = sequence_number;
       timestamp_last_decoded_rtp_ = timestamp;
     }
     return;
   }

   if (sequence_number == sequence_num_last_received_rtp_)
     return;

   // Received RTP should not be in the list.
   nack_list_.erase(sequence_number);

   // If this is an old sequence number, no more action is required, return.
   if (IsNewerSequenceNumber(sequence_num_last_received_rtp_, sequence_number))
     return;

   UpdateSamplesPerPacket(sequence_number, timestamp);

   UpdateList(sequence_number);

   sequence_num_last_received_rtp_ = sequence_number;
   timestamp_last_received_rtp_ = timestamp;
   LimitNackListSize();
 }

 void NackTracker::UpdateSamplesPerPacket(
     uint16_t sequence_number_current_received_rtp,
     uint32_t timestamp_current_received_rtp) {
   uint32_t timestamp_increase =
       timestamp_current_received_rtp - timestamp_last_received_rtp_;
   uint16_t sequence_num_increase =
       sequence_number_current_received_rtp - sequence_num_last_received_rtp_;

   samples_per_packet_ = timestamp_increase / sequence_num_increase;
 }

 void NackTracker::UpdateList(uint16_t sequence_number_current_received_rtp) {
   // Some of the packets which were considered late, now are considered missing.
   ChangeFromLateToMissing(sequence_number_current_received_rtp);

   if (IsNewerSequenceNumber(sequence_number_current_received_rtp,
                             sequence_num_last_received_rtp_ + 1))
     AddToList(sequence_number_current_received_rtp);
 }

 void NackTracker::ChangeFromLateToMissing(
     uint16_t sequence_number_current_received_rtp) {
   NackList::const_iterator lower_bound =
       nack_list_.lower_bound(static_cast<uint16_t>(
           sequence_number_current_received_rtp - nack_threshold_packets_));

   for (NackList::iterator it = nack_list_.begin(); it != lower_bound; ++it)
     it->second.is_missing = true;
 }

 uint32_t NackTracker::EstimateTimestamp(uint16_t sequence_num) {
   uint16_t sequence_num_diff = sequence_num - sequence_num_last_received_rtp_;
   return sequence_num_diff * samples_per_packet_ + timestamp_last_received_rtp_;
 }

 void NackTracker::AddToList(uint16_t sequence_number_current_received_rtp) {
   assert(!any_rtp_decoded_ ||
          IsNewerSequenceNumber(sequence_number_current_received_rtp,
                                sequence_num_last_decoded_rtp_));

   // Packets with sequence numbers older than |upper_bound_missing| are
   // considered missing, and the rest are considered late.
   uint16_t upper_bound_missing =
       sequence_number_current_received_rtp - nack_threshold_packets_;

   for (uint16_t n = sequence_num_last_received_rtp_ + 1;
        IsNewerSequenceNumber(sequence_number_current_received_rtp, n); ++n) {
     bool is_missing = IsNewerSequenceNumber(upper_bound_missing, n);
     uint32_t timestamp = EstimateTimestamp(n);
     NackElement nack_element(TimeToPlay(timestamp), timestamp, is_missing);
     nack_list_.insert(nack_list_.end(), std::make_pair(n, nack_element));
   }
 }

 void NackTracker::UpdateEstimatedPlayoutTimeBy10ms() {
   while (!nack_list_.empty() &&
          nack_list_.begin()->second.time_to_play_ms <= 10)
     nack_list_.erase(nack_list_.begin());

   for (NackList::iterator it = nack_list_.begin(); it != nack_list_.end(); ++it)
     it->second.time_to_play_ms -= 10;
 }

 void NackTracker::UpdateLastDecodedPacket(uint16_t sequence_number,
                                           uint32_t timestamp) {
   if (IsNewerSequenceNumber(sequence_number, sequence_num_last_decoded_rtp_) ||
       !any_rtp_decoded_) {
     sequence_num_last_decoded_rtp_ = sequence_number;
     timestamp_last_decoded_rtp_ = timestamp;
     // Packets in the list with sequence numbers less than the
     // sequence number of the decoded RTP should be removed from the lists.
     // They will be discarded by the jitter buffer if they arrive.
     nack_list_.erase(nack_list_.begin(),
                      nack_list_.upper_bound(sequence_num_last_decoded_rtp_));

     // Update estimated time-to-play.
     for (NackList::iterator it = nack_list_.begin(); it != nack_list_.end();
          ++it)
       it->second.time_to_play_ms = TimeToPlay(it->second.estimated_timestamp);
   } else {
     assert(sequence_number == sequence_num_last_decoded_rtp_);

     // Same sequence number as before. 10 ms is elapsed, update estimations for
     // time-to-play.
     UpdateEstimatedPlayoutTimeBy10ms();

     // Update timestamp for better estimate of time-to-play, for packets which
     // are added to NACK list later on.
     timestamp_last_decoded_rtp_ += sample_rate_khz_ * 10;
   }
   any_rtp_decoded_ = true;
 }

 NackTracker::NackList NackTracker::GetNackList() const {
   return nack_list_;
 }

 void NackTracker::Reset() {
   nack_list_.clear();

   sequence_num_last_received_rtp_ = 0;
   timestamp_last_received_rtp_ = 0;
   any_rtp_received_ = false;
   sequence_num_last_decoded_rtp_ = 0;
   timestamp_last_decoded_rtp_ = 0;
   any_rtp_decoded_ = false;
   sample_rate_khz_ = kDefaultSampleRateKhz;
   samples_per_packet_ = sample_rate_khz_ * kDefaultPacketSizeMs;
 }

 void NackTracker::SetMaxNackListSize(size_t max_nack_list_size) {
   RTC_CHECK_GT(max_nack_list_size, 0);
   // Ugly hack to get around the problem of passing static consts by reference.
   const size_t kNackListSizeLimitLocal = NackTracker::kNackListSizeLimit;
   RTC_CHECK_LE(max_nack_list_size, kNackListSizeLimitLocal);

   max_nack_list_size_ = max_nack_list_size;
   LimitNackListSize();
 }

 void NackTracker::LimitNackListSize() {
   uint16_t limit = sequence_num_last_received_rtp_ -
                    static_cast<uint16_t>(max_nack_list_size_) - 1;
   nack_list_.erase(nack_list_.begin(), nack_list_.upper_bound(limit));
 }

 int64_t NackTracker::TimeToPlay(uint32_t timestamp) const {
   uint32_t timestamp_increase = timestamp - timestamp_last_decoded_rtp_;
   return timestamp_increase / sample_rate_khz_;
 }

 // We don't erase elements with time-to-play shorter than round-trip-time.
 std::vector<uint16_t> NackTracker::GetNackList(
     int64_t round_trip_time_ms) const {
   RTC_DCHECK_GE(round_trip_time_ms, 0);
   std::vector<uint16_t> sequence_numbers;
   for (NackList::const_iterator it = nack_list_.begin(); it != nack_list_.end();
        ++it) {
     if (it->second.is_missing &&
         it->second.time_to_play_ms > round_trip_time_ms)
       sequence_numbers.push_back(it->first);
   }
   return sequence_numbers;
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2013 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include "modules/audio_coding/neteq/nack_tracker.h"

	#include <assert.h>

	#include <cstdint>
	#include <utility>

	#include "rtc_base/checks.h"

	namespace webrtc {
	namespace {

	const int kDefaultSampleRateKhz = 48;
	const int kDefaultPacketSizeMs = 20;

	} // namespace

	NackTracker::NackTracker(int nack_threshold_packets)
	: nack_threshold_packets_(nack_threshold_packets),
	sequence_num_last_received_rtp_(0),
	timestamp_last_received_rtp_(0),
	any_rtp_received_(false),
	sequence_num_last_decoded_rtp_(0),
	timestamp_last_decoded_rtp_(0),
	any_rtp_decoded_(false),
	sample_rate_khz_(kDefaultSampleRateKhz),
	samples_per_packet_(sample_rate_khz_ * kDefaultPacketSizeMs),
	max_nack_list_size_(kNackListSizeLimit) {}

	NackTracker::~NackTracker() = default;

	NackTracker* NackTracker::Create(int nack_threshold_packets) {
	return new NackTracker(nack_threshold_packets);
	}

	void NackTracker::UpdateSampleRate(int sample_rate_hz) {
	assert(sample_rate_hz > 0);
	sample_rate_khz_ = sample_rate_hz / 1000;
	}

	void NackTracker::UpdateLastReceivedPacket(uint16_t sequence_number,
	uint32_t timestamp) {
	// Just record the value of sequence number and timestamp if this is the
	// first packet.
	if (!any_rtp_received_) {
	sequence_num_last_received_rtp_ = sequence_number;
	timestamp_last_received_rtp_ = timestamp;
	any_rtp_received_ = true;
	// If no packet is decoded, to have a reasonable estimate of time-to-play
	// use the given values.
	if (!any_rtp_decoded_) {
	sequence_num_last_decoded_rtp_ = sequence_number;
	timestamp_last_decoded_rtp_ = timestamp;
	}
	return;
	}

	if (sequence_number == sequence_num_last_received_rtp_)
	return;

	// Received RTP should not be in the list.
	nack_list_.erase(sequence_number);

	// If this is an old sequence number, no more action is required, return.
	if (IsNewerSequenceNumber(sequence_num_last_received_rtp_, sequence_number))
	return;

	UpdateSamplesPerPacket(sequence_number, timestamp);

	UpdateList(sequence_number);

	sequence_num_last_received_rtp_ = sequence_number;
	timestamp_last_received_rtp_ = timestamp;
	LimitNackListSize();
	}

	void NackTracker::UpdateSamplesPerPacket(
	uint16_t sequence_number_current_received_rtp,
	uint32_t timestamp_current_received_rtp) {
	uint32_t timestamp_increase =
	timestamp_current_received_rtp - timestamp_last_received_rtp_;
	uint16_t sequence_num_increase =
	sequence_number_current_received_rtp - sequence_num_last_received_rtp_;

	samples_per_packet_ = timestamp_increase / sequence_num_increase;
	}

	void NackTracker::UpdateList(uint16_t sequence_number_current_received_rtp) {
	// Some of the packets which were considered late, now are considered missing.
	ChangeFromLateToMissing(sequence_number_current_received_rtp);

	if (IsNewerSequenceNumber(sequence_number_current_received_rtp,
	sequence_num_last_received_rtp_ + 1))
	AddToList(sequence_number_current_received_rtp);
	}

	void NackTracker::ChangeFromLateToMissing(
	uint16_t sequence_number_current_received_rtp) {
	NackList::const_iterator lower_bound =
	nack_list_.lower_bound(static_cast<uint16_t>(
	sequence_number_current_received_rtp - nack_threshold_packets_));

	for (NackList::iterator it = nack_list_.begin(); it != lower_bound; ++it)
	it->second.is_missing = true;
	}

	uint32_t NackTracker::EstimateTimestamp(uint16_t sequence_num) {
	uint16_t sequence_num_diff = sequence_num - sequence_num_last_received_rtp_;
	return sequence_num_diff * samples_per_packet_ + timestamp_last_received_rtp_;
	}

	void NackTracker::AddToList(uint16_t sequence_number_current_received_rtp) {
	assert(!any_rtp_decoded_ \|\|
	IsNewerSequenceNumber(sequence_number_current_received_rtp,
	sequence_num_last_decoded_rtp_));

	// Packets with sequence numbers older than \|upper_bound_missing\| are
	// considered missing, and the rest are considered late.
	uint16_t upper_bound_missing =
	sequence_number_current_received_rtp - nack_threshold_packets_;

	for (uint16_t n = sequence_num_last_received_rtp_ + 1;
	IsNewerSequenceNumber(sequence_number_current_received_rtp, n); ++n) {
	bool is_missing = IsNewerSequenceNumber(upper_bound_missing, n);
	uint32_t timestamp = EstimateTimestamp(n);
	NackElement nack_element(TimeToPlay(timestamp), timestamp, is_missing);
	nack_list_.insert(nack_list_.end(), std::make_pair(n, nack_element));
	}
	}

	void NackTracker::UpdateEstimatedPlayoutTimeBy10ms() {
	while (!nack_list_.empty() &&
	nack_list_.begin()->second.time_to_play_ms <= 10)
	nack_list_.erase(nack_list_.begin());

	for (NackList::iterator it = nack_list_.begin(); it != nack_list_.end(); ++it)
	it->second.time_to_play_ms -= 10;
	}

	void NackTracker::UpdateLastDecodedPacket(uint16_t sequence_number,
	uint32_t timestamp) {
	if (IsNewerSequenceNumber(sequence_number, sequence_num_last_decoded_rtp_) \|\|
	!any_rtp_decoded_) {
	sequence_num_last_decoded_rtp_ = sequence_number;
	timestamp_last_decoded_rtp_ = timestamp;
	// Packets in the list with sequence numbers less than the
	// sequence number of the decoded RTP should be removed from the lists.
	// They will be discarded by the jitter buffer if they arrive.
	nack_list_.erase(nack_list_.begin(),
	nack_list_.upper_bound(sequence_num_last_decoded_rtp_));

	// Update estimated time-to-play.
	for (NackList::iterator it = nack_list_.begin(); it != nack_list_.end();
	++it)
	it->second.time_to_play_ms = TimeToPlay(it->second.estimated_timestamp);
	} else {
	assert(sequence_number == sequence_num_last_decoded_rtp_);

	// Same sequence number as before. 10 ms is elapsed, update estimations for
	// time-to-play.
	UpdateEstimatedPlayoutTimeBy10ms();

	// Update timestamp for better estimate of time-to-play, for packets which
	// are added to NACK list later on.
	timestamp_last_decoded_rtp_ += sample_rate_khz_ * 10;
	}
	any_rtp_decoded_ = true;
	}

	NackTracker::NackList NackTracker::GetNackList() const {
	return nack_list_;
	}

	void NackTracker::Reset() {
	nack_list_.clear();

	sequence_num_last_received_rtp_ = 0;
	timestamp_last_received_rtp_ = 0;
	any_rtp_received_ = false;
	sequence_num_last_decoded_rtp_ = 0;
	timestamp_last_decoded_rtp_ = 0;
	any_rtp_decoded_ = false;
	sample_rate_khz_ = kDefaultSampleRateKhz;
	samples_per_packet_ = sample_rate_khz_ * kDefaultPacketSizeMs;
	}

	void NackTracker::SetMaxNackListSize(size_t max_nack_list_size) {
	RTC_CHECK_GT(max_nack_list_size, 0);
	// Ugly hack to get around the problem of passing static consts by reference.
	const size_t kNackListSizeLimitLocal = NackTracker::kNackListSizeLimit;
	RTC_CHECK_LE(max_nack_list_size, kNackListSizeLimitLocal);

	max_nack_list_size_ = max_nack_list_size;
	LimitNackListSize();
	}

	void NackTracker::LimitNackListSize() {
	uint16_t limit = sequence_num_last_received_rtp_ -
	static_cast<uint16_t>(max_nack_list_size_) - 1;
	nack_list_.erase(nack_list_.begin(), nack_list_.upper_bound(limit));
	}

	int64_t NackTracker::TimeToPlay(uint32_t timestamp) const {
	uint32_t timestamp_increase = timestamp - timestamp_last_decoded_rtp_;
	return timestamp_increase / sample_rate_khz_;
	}

	// We don't erase elements with time-to-play shorter than round-trip-time.
	std::vector<uint16_t> NackTracker::GetNackList(
	int64_t round_trip_time_ms) const {
	RTC_DCHECK_GE(round_trip_time_ms, 0);
	std::vector<uint16_t> sequence_numbers;
	for (NackList::const_iterator it = nack_list_.begin(); it != nack_list_.end();
	++it) {
	if (it->second.is_missing &&
	it->second.time_to_play_ms > round_trip_time_ms)
	sequence_numbers.push_back(it->first);
	}
	return sequence_numbers;
	}

	} // namespace webrtc