modules/audio_coding/neteq/packet_buffer.cc - src/webrtc - 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.
  */

 // This is the implementation of the PacketBuffer class. It is mostly based on
 // an STL list. The list is kept sorted at all times so that the next packet to
 // decode is at the beginning of the list.

 #include "webrtc/modules/audio_coding/neteq/packet_buffer.h"

 #include <algorithm>  // find_if()

 #include "webrtc/api/audio_codecs/audio_decoder.h"
 #include "webrtc/modules/audio_coding/neteq/decoder_database.h"
 #include "webrtc/modules/audio_coding/neteq/statistics_calculator.h"
 #include "webrtc/modules/audio_coding/neteq/tick_timer.h"
 #include "webrtc/rtc_base/logging.h"

 namespace webrtc {
 namespace {
 // Predicate used when inserting packets in the buffer list.
 // Operator() returns true when |packet| goes before |new_packet|.
 class NewTimestampIsLarger {
  public:
   explicit NewTimestampIsLarger(const Packet& new_packet)
       : new_packet_(new_packet) {
   }
   bool operator()(const Packet& packet) {
     return (new_packet_ >= packet);
   }

  private:
   const Packet& new_packet_;
 };

 // Returns true if both payload types are known to the decoder database, and
 // have the same sample rate.
 bool EqualSampleRates(uint8_t pt1,
                       uint8_t pt2,
                       const DecoderDatabase& decoder_database) {
   auto* di1 = decoder_database.GetDecoderInfo(pt1);
   auto* di2 = decoder_database.GetDecoderInfo(pt2);
   return di1 && di2 && di1->SampleRateHz() == di2->SampleRateHz();
 }

 void LogPacketDiscarded(int codec_level, StatisticsCalculator* stats) {
   RTC_CHECK(stats);
   if (codec_level > 0) {
     stats->SecondaryPacketsDiscarded(1);
   } else {
     stats->PacketsDiscarded(1);
   }
 }

 }  // namespace

 PacketBuffer::PacketBuffer(size_t max_number_of_packets,
                            const TickTimer* tick_timer)
     : max_number_of_packets_(max_number_of_packets), tick_timer_(tick_timer) {}

 // Destructor. All packets in the buffer will be destroyed.
 PacketBuffer::~PacketBuffer() {
   Flush();
 }

 // Flush the buffer. All packets in the buffer will be destroyed.
 void PacketBuffer::Flush() {
   buffer_.clear();
 }

 bool PacketBuffer::Empty() const {
   return buffer_.empty();
 }

 int PacketBuffer::InsertPacket(Packet&& packet, StatisticsCalculator* stats) {
   if (packet.empty()) {
     LOG(LS_WARNING) << "InsertPacket invalid packet";
     return kInvalidPacket;
   }

   RTC_DCHECK_GE(packet.priority.codec_level, 0);
   RTC_DCHECK_GE(packet.priority.red_level, 0);

   int return_val = kOK;

   packet.waiting_time = tick_timer_->GetNewStopwatch();

   if (buffer_.size() >= max_number_of_packets_) {
     // Buffer is full. Flush it.
     Flush();
     LOG(LS_WARNING) << "Packet buffer flushed";
     return_val = kFlushed;
   }

   // Get an iterator pointing to the place in the buffer where the new packet
   // should be inserted. The list is searched from the back, since the most
   // likely case is that the new packet should be near the end of the list.
   PacketList::reverse_iterator rit = std::find_if(
       buffer_.rbegin(), buffer_.rend(),
       NewTimestampIsLarger(packet));

   // The new packet is to be inserted to the right of |rit|. If it has the same
   // timestamp as |rit|, which has a higher priority, do not insert the new
   // packet to list.
   if (rit != buffer_.rend() && packet.timestamp == rit->timestamp) {
     LogPacketDiscarded(packet.priority.codec_level, stats);
     return return_val;
   }

   // The new packet is to be inserted to the left of |it|. If it has the same
   // timestamp as |it|, which has a lower priority, replace |it| with the new
   // packet.
   PacketList::iterator it = rit.base();
   if (it != buffer_.end() && packet.timestamp == it->timestamp) {
     LogPacketDiscarded(packet.priority.codec_level, stats);
     it = buffer_.erase(it);
   }
   buffer_.insert(it, std::move(packet));  // Insert the packet at that position.

   return return_val;
 }

 int PacketBuffer::InsertPacketList(
     PacketList* packet_list,
     const DecoderDatabase& decoder_database,
     rtc::Optional<uint8_t>* current_rtp_payload_type,
     rtc::Optional<uint8_t>* current_cng_rtp_payload_type,
     StatisticsCalculator* stats) {
   RTC_DCHECK(stats);
   bool flushed = false;
   for (auto& packet : *packet_list) {
     if (decoder_database.IsComfortNoise(packet.payload_type)) {
       if (*current_cng_rtp_payload_type &&
           **current_cng_rtp_payload_type != packet.payload_type) {
         // New CNG payload type implies new codec type.
         *current_rtp_payload_type = rtc::Optional<uint8_t>();
         Flush();
         flushed = true;
       }
       *current_cng_rtp_payload_type =
           rtc::Optional<uint8_t>(packet.payload_type);
     } else if (!decoder_database.IsDtmf(packet.payload_type)) {
       // This must be speech.
       if ((*current_rtp_payload_type &&
            **current_rtp_payload_type != packet.payload_type) ||
           (*current_cng_rtp_payload_type &&
            !EqualSampleRates(packet.payload_type,
                              **current_cng_rtp_payload_type,
                              decoder_database))) {
         *current_cng_rtp_payload_type = rtc::Optional<uint8_t>();
         Flush();
         flushed = true;
       }
       *current_rtp_payload_type = rtc::Optional<uint8_t>(packet.payload_type);
     }
     int return_val = InsertPacket(std::move(packet), stats);
     if (return_val == kFlushed) {
       // The buffer flushed, but this is not an error. We can still continue.
       flushed = true;
     } else if (return_val != kOK) {
       // An error occurred. Delete remaining packets in list and return.
       packet_list->clear();
       return return_val;
     }
   }
   packet_list->clear();
   return flushed ? kFlushed : kOK;
 }

 int PacketBuffer::NextTimestamp(uint32_t* next_timestamp) const {
   if (Empty()) {
     return kBufferEmpty;
   }
   if (!next_timestamp) {
     return kInvalidPointer;
   }
   *next_timestamp = buffer_.front().timestamp;
   return kOK;
 }

 int PacketBuffer::NextHigherTimestamp(uint32_t timestamp,
                                       uint32_t* next_timestamp) const {
   if (Empty()) {
     return kBufferEmpty;
   }
   if (!next_timestamp) {
     return kInvalidPointer;
   }
   PacketList::const_iterator it;
   for (it = buffer_.begin(); it != buffer_.end(); ++it) {
     if (it->timestamp >= timestamp) {
       // Found a packet matching the search.
       *next_timestamp = it->timestamp;
       return kOK;
     }
   }
   return kNotFound;
 }

 const Packet* PacketBuffer::PeekNextPacket() const {
   return buffer_.empty() ? nullptr : &buffer_.front();
 }

 rtc::Optional<Packet> PacketBuffer::GetNextPacket() {
   if (Empty()) {
     // Buffer is empty.
     return rtc::Optional<Packet>();
   }

   rtc::Optional<Packet> packet(std::move(buffer_.front()));
   // Assert that the packet sanity checks in InsertPacket method works.
   RTC_DCHECK(!packet->empty());
   buffer_.pop_front();

   return packet;
 }

 int PacketBuffer::DiscardNextPacket(StatisticsCalculator* stats) {
   if (Empty()) {
     return kBufferEmpty;
   }
   // Assert that the packet sanity checks in InsertPacket method works.
   const Packet& packet = buffer_.front();
   RTC_DCHECK(!packet.empty());
   LogPacketDiscarded(packet.priority.codec_level, stats);
   buffer_.pop_front();
   return kOK;
 }

 void PacketBuffer::DiscardOldPackets(uint32_t timestamp_limit,
                                      uint32_t horizon_samples,
                                      StatisticsCalculator* stats) {
   buffer_.remove_if([timestamp_limit, horizon_samples, stats](const Packet& p) {
     if (timestamp_limit == p.timestamp ||
         !IsObsoleteTimestamp(p.timestamp, timestamp_limit, horizon_samples)) {
       return false;
     }
     LogPacketDiscarded(p.priority.codec_level, stats);
     return true;
   });
 }

 void PacketBuffer::DiscardAllOldPackets(uint32_t timestamp_limit,
                                         StatisticsCalculator* stats) {
   DiscardOldPackets(timestamp_limit, 0, stats);
 }

 void PacketBuffer::DiscardPacketsWithPayloadType(uint8_t payload_type,
                                                  StatisticsCalculator* stats) {
   buffer_.remove_if([payload_type, stats](const Packet& p) {
     if (p.payload_type != payload_type) {
       return false;
     }
     LogPacketDiscarded(p.priority.codec_level, stats);
     return true;
   });
 }

 size_t PacketBuffer::NumPacketsInBuffer() const {
   return buffer_.size();
 }

 size_t PacketBuffer::NumSamplesInBuffer(size_t last_decoded_length) const {
   size_t num_samples = 0;
   size_t last_duration = last_decoded_length;
   for (const Packet& packet : buffer_) {
     if (packet.frame) {
       // TODO(hlundin): Verify that it's fine to count all packets and remove
       // this check.
       if (packet.priority != Packet::Priority(0, 0)) {
         continue;
       }
       size_t duration = packet.frame->Duration();
       if (duration > 0) {
         last_duration = duration;  // Save the most up-to-date (valid) duration.
       }
     }
     num_samples += last_duration;
   }
   return num_samples;
 }

 void PacketBuffer::BufferStat(int* num_packets, int* max_num_packets) const {
   *num_packets = static_cast<int>(buffer_.size());
   *max_num_packets = static_cast<int>(max_number_of_packets_);
 }

 }  // namespace webrtc
	/*
	* 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.
	*/

	// This is the implementation of the PacketBuffer class. It is mostly based on
	// an STL list. The list is kept sorted at all times so that the next packet to
	// decode is at the beginning of the list.

	#include "webrtc/modules/audio_coding/neteq/packet_buffer.h"

	#include <algorithm> // find_if()

	#include "webrtc/api/audio_codecs/audio_decoder.h"
	#include "webrtc/modules/audio_coding/neteq/decoder_database.h"
	#include "webrtc/modules/audio_coding/neteq/statistics_calculator.h"
	#include "webrtc/modules/audio_coding/neteq/tick_timer.h"
	#include "webrtc/rtc_base/logging.h"

	namespace webrtc {
	namespace {
	// Predicate used when inserting packets in the buffer list.
	// Operator() returns true when \|packet\| goes before \|new_packet\|.
	class NewTimestampIsLarger {
	public:
	explicit NewTimestampIsLarger(const Packet& new_packet)
	: new_packet_(new_packet) {
	}
	bool operator()(const Packet& packet) {
	return (new_packet_ >= packet);
	}

	private:
	const Packet& new_packet_;
	};

	// Returns true if both payload types are known to the decoder database, and
	// have the same sample rate.
	bool EqualSampleRates(uint8_t pt1,
	uint8_t pt2,
	const DecoderDatabase& decoder_database) {
	auto* di1 = decoder_database.GetDecoderInfo(pt1);
	auto* di2 = decoder_database.GetDecoderInfo(pt2);
	return di1 && di2 && di1->SampleRateHz() == di2->SampleRateHz();
	}

	void LogPacketDiscarded(int codec_level, StatisticsCalculator* stats) {
	RTC_CHECK(stats);
	if (codec_level > 0) {
	stats->SecondaryPacketsDiscarded(1);
	} else {
	stats->PacketsDiscarded(1);
	}
	}

	} // namespace

	PacketBuffer::PacketBuffer(size_t max_number_of_packets,
	const TickTimer* tick_timer)
	: max_number_of_packets_(max_number_of_packets), tick_timer_(tick_timer) {}

	// Destructor. All packets in the buffer will be destroyed.
	PacketBuffer::~PacketBuffer() {
	Flush();
	}

	// Flush the buffer. All packets in the buffer will be destroyed.
	void PacketBuffer::Flush() {
	buffer_.clear();
	}

	bool PacketBuffer::Empty() const {
	return buffer_.empty();
	}

	int PacketBuffer::InsertPacket(Packet&& packet, StatisticsCalculator* stats) {
	if (packet.empty()) {
	LOG(LS_WARNING) << "InsertPacket invalid packet";
	return kInvalidPacket;
	}

	RTC_DCHECK_GE(packet.priority.codec_level, 0);
	RTC_DCHECK_GE(packet.priority.red_level, 0);

	int return_val = kOK;

	packet.waiting_time = tick_timer_->GetNewStopwatch();

	if (buffer_.size() >= max_number_of_packets_) {
	// Buffer is full. Flush it.
	Flush();
	LOG(LS_WARNING) << "Packet buffer flushed";
	return_val = kFlushed;
	}

	// Get an iterator pointing to the place in the buffer where the new packet
	// should be inserted. The list is searched from the back, since the most
	// likely case is that the new packet should be near the end of the list.
	PacketList::reverse_iterator rit = std::find_if(
	buffer_.rbegin(), buffer_.rend(),
	NewTimestampIsLarger(packet));

	// The new packet is to be inserted to the right of \|rit\|. If it has the same
	// timestamp as \|rit\|, which has a higher priority, do not insert the new
	// packet to list.
	if (rit != buffer_.rend() && packet.timestamp == rit->timestamp) {
	LogPacketDiscarded(packet.priority.codec_level, stats);
	return return_val;
	}

	// The new packet is to be inserted to the left of \|it\|. If it has the same
	// timestamp as \|it\|, which has a lower priority, replace \|it\| with the new
	// packet.
	PacketList::iterator it = rit.base();
	if (it != buffer_.end() && packet.timestamp == it->timestamp) {
	LogPacketDiscarded(packet.priority.codec_level, stats);
	it = buffer_.erase(it);
	}
	buffer_.insert(it, std::move(packet)); // Insert the packet at that position.

	return return_val;
	}

	int PacketBuffer::InsertPacketList(
	PacketList* packet_list,
	const DecoderDatabase& decoder_database,
	rtc::Optional<uint8_t>* current_rtp_payload_type,
	rtc::Optional<uint8_t>* current_cng_rtp_payload_type,
	StatisticsCalculator* stats) {
	RTC_DCHECK(stats);
	bool flushed = false;
	for (auto& packet : *packet_list) {
	if (decoder_database.IsComfortNoise(packet.payload_type)) {
	if (*current_cng_rtp_payload_type &&
	**current_cng_rtp_payload_type != packet.payload_type) {
	// New CNG payload type implies new codec type.
	*current_rtp_payload_type = rtc::Optional<uint8_t>();
	Flush();
	flushed = true;
	}
	*current_cng_rtp_payload_type =
	rtc::Optional<uint8_t>(packet.payload_type);
	} else if (!decoder_database.IsDtmf(packet.payload_type)) {
	// This must be speech.
	if ((*current_rtp_payload_type &&
	**current_rtp_payload_type != packet.payload_type) \|\|
	(*current_cng_rtp_payload_type &&
	!EqualSampleRates(packet.payload_type,
	**current_cng_rtp_payload_type,
	decoder_database))) {
	*current_cng_rtp_payload_type = rtc::Optional<uint8_t>();
	Flush();
	flushed = true;
	}
	*current_rtp_payload_type = rtc::Optional<uint8_t>(packet.payload_type);
	}
	int return_val = InsertPacket(std::move(packet), stats);
	if (return_val == kFlushed) {
	// The buffer flushed, but this is not an error. We can still continue.
	flushed = true;
	} else if (return_val != kOK) {
	// An error occurred. Delete remaining packets in list and return.
	packet_list->clear();
	return return_val;
	}
	}
	packet_list->clear();
	return flushed ? kFlushed : kOK;
	}

	int PacketBuffer::NextTimestamp(uint32_t* next_timestamp) const {
	if (Empty()) {
	return kBufferEmpty;
	}
	if (!next_timestamp) {
	return kInvalidPointer;
	}
	*next_timestamp = buffer_.front().timestamp;
	return kOK;
	}

	int PacketBuffer::NextHigherTimestamp(uint32_t timestamp,
	uint32_t* next_timestamp) const {
	if (Empty()) {
	return kBufferEmpty;
	}
	if (!next_timestamp) {
	return kInvalidPointer;
	}
	PacketList::const_iterator it;
	for (it = buffer_.begin(); it != buffer_.end(); ++it) {
	if (it->timestamp >= timestamp) {
	// Found a packet matching the search.
	*next_timestamp = it->timestamp;
	return kOK;
	}
	}
	return kNotFound;
	}

	const Packet* PacketBuffer::PeekNextPacket() const {
	return buffer_.empty() ? nullptr : &buffer_.front();
	}

	rtc::Optional<Packet> PacketBuffer::GetNextPacket() {
	if (Empty()) {
	// Buffer is empty.
	return rtc::Optional<Packet>();
	}

	rtc::Optional<Packet> packet(std::move(buffer_.front()));
	// Assert that the packet sanity checks in InsertPacket method works.
	RTC_DCHECK(!packet->empty());
	buffer_.pop_front();

	return packet;
	}

	int PacketBuffer::DiscardNextPacket(StatisticsCalculator* stats) {
	if (Empty()) {
	return kBufferEmpty;
	}
	// Assert that the packet sanity checks in InsertPacket method works.
	const Packet& packet = buffer_.front();
	RTC_DCHECK(!packet.empty());
	LogPacketDiscarded(packet.priority.codec_level, stats);
	buffer_.pop_front();
	return kOK;
	}

	void PacketBuffer::DiscardOldPackets(uint32_t timestamp_limit,
	uint32_t horizon_samples,
	StatisticsCalculator* stats) {
	buffer_.remove_if([timestamp_limit, horizon_samples, stats](const Packet& p) {
	if (timestamp_limit == p.timestamp \|\|
	!IsObsoleteTimestamp(p.timestamp, timestamp_limit, horizon_samples)) {
	return false;
	}
	LogPacketDiscarded(p.priority.codec_level, stats);
	return true;
	});
	}

	void PacketBuffer::DiscardAllOldPackets(uint32_t timestamp_limit,
	StatisticsCalculator* stats) {
	DiscardOldPackets(timestamp_limit, 0, stats);
	}

	void PacketBuffer::DiscardPacketsWithPayloadType(uint8_t payload_type,
	StatisticsCalculator* stats) {
	buffer_.remove_if([payload_type, stats](const Packet& p) {
	if (p.payload_type != payload_type) {
	return false;
	}
	LogPacketDiscarded(p.priority.codec_level, stats);
	return true;
	});
	}

	size_t PacketBuffer::NumPacketsInBuffer() const {
	return buffer_.size();
	}

	size_t PacketBuffer::NumSamplesInBuffer(size_t last_decoded_length) const {
	size_t num_samples = 0;
	size_t last_duration = last_decoded_length;
	for (const Packet& packet : buffer_) {
	if (packet.frame) {
	// TODO(hlundin): Verify that it's fine to count all packets and remove
	// this check.
	if (packet.priority != Packet::Priority(0, 0)) {
	continue;
	}
	size_t duration = packet.frame->Duration();
	if (duration > 0) {
	last_duration = duration; // Save the most up-to-date (valid) duration.
	}
	}
	num_samples += last_duration;
	}
	return num_samples;
	}

	void PacketBuffer::BufferStat(int* num_packets, int* max_num_packets) const {
	*num_packets = static_cast<int>(buffer_.size());
	*max_num_packets = static_cast<int>(max_number_of_packets_);
	}

	} // namespace webrtc