/* * 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 "webrtc/modules/audio_coding/main/acm2/nack.h" #include // For assert. #include // For std::max. #include "webrtc/modules/interface/module_common_types.h" #include "webrtc/system_wrappers/interface/logging.h" namespace webrtc { namespace acm2 { namespace { const int kDefaultSampleRateKhz = 48; const int kDefaultPacketSizeMs = 20; } // namespace Nack::Nack(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) {} Nack* Nack::Create(int nack_threshold_packets) { return new Nack(nack_threshold_packets); } void Nack::UpdateSampleRate(int sample_rate_hz) { assert(sample_rate_hz > 0); sample_rate_khz_ = sample_rate_hz / 1000; } void Nack::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 Nack::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 Nack::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 Nack::ChangeFromLateToMissing( uint16_t sequence_number_current_received_rtp) { NackList::const_iterator lower_bound = nack_list_.lower_bound( static_cast(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 Nack::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 Nack::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 Nack::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 Nack::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; } Nack::NackList Nack::GetNackList() const { return nack_list_; } void Nack::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; } int Nack::SetMaxNackListSize(size_t max_nack_list_size) { if (max_nack_list_size == 0 || max_nack_list_size > kNackListSizeLimit) return -1; max_nack_list_size_ = max_nack_list_size; LimitNackListSize(); return 0; } void Nack::LimitNackListSize() { uint16_t limit = sequence_num_last_received_rtp_ - static_cast(max_nack_list_size_) - 1; nack_list_.erase(nack_list_.begin(), nack_list_.upper_bound(limit)); } int Nack::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 Nack::GetNackList(int round_trip_time_ms) const { std::vector 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 acm2 } // namespace webrtc