modules/pacing/packet_queue2.cc - src - Git at Google

 /*
  *  Copyright (c) 2017 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/pacing/packet_queue2.h"

 #include <algorithm>

 #include "rtc_base/checks.h"
 #include "system_wrappers/include/clock.h"

 namespace webrtc {

 PacketQueue2::Stream::Stream() : bytes(0) {}
 PacketQueue2::Stream::~Stream() {}

 PacketQueue2::PacketQueue2(const Clock* clock)
     : PacketQueue(clock),
       clock_(clock),
       time_last_updated_(clock_->TimeInMilliseconds()) {}

 PacketQueue2::~PacketQueue2() {}

 void PacketQueue2::Push(const Packet& packet_to_insert) {
   Packet packet(packet_to_insert);

   auto stream_info_it = streams_.find(packet.ssrc);
   if (stream_info_it == streams_.end()) {
     stream_info_it = streams_.emplace(packet.ssrc, Stream()).first;
     stream_info_it->second.priority_it = stream_priorities_.end();
     stream_info_it->second.ssrc = packet.ssrc;
   }

   Stream* streams_ = &stream_info_it->second;

   if (streams_->priority_it == stream_priorities_.end()) {
     // If the SSRC is not currently scheduled, add it to |stream_priorities_|.
     RTC_CHECK(!IsSsrcScheduled(streams_->ssrc));
     streams_->priority_it = stream_priorities_.emplace(
         StreamPrioKey(packet.priority, streams_->bytes), packet.ssrc);
   } else if (packet.priority < streams_->priority_it->first.priority) {
     // If the priority of this SSRC increased, remove the outdated StreamPrioKey
     // and insert a new one with the new priority. Note that
     // RtpPacketSender::Priority uses lower ordinal for higher priority.
     stream_priorities_.erase(streams_->priority_it);
     streams_->priority_it = stream_priorities_.emplace(
         StreamPrioKey(packet.priority, streams_->bytes), packet.ssrc);
   }
   RTC_CHECK(streams_->priority_it != stream_priorities_.end());

   packet.enqueue_time_it = enqueue_times_.insert(packet.enqueue_time_ms);

   // In order to figure out how much time a packet has spent in the queue while
   // not in a paused state, we subtract the total amount of time the queue has
   // been paused so far, and when the packet is poped we subtract the total
   // amount of time the queue has been paused at that moment. This way we
   // subtract the total amount of time the packet has spent in the queue while
   // in a paused state.
   UpdateQueueTime(packet.enqueue_time_ms);
   packet.enqueue_time_ms -= pause_time_sum_ms_;
   streams_->packet_queue.push(packet);

   size_packets_ += 1;
   size_bytes_ += packet.bytes;
 }

 const PacketQueue2::Packet& PacketQueue2::BeginPop() {
   RTC_CHECK(!pop_packet_ && !pop_stream_);

   Stream* stream = GetHighestPriorityStream();
   pop_stream_.emplace(stream);
   pop_packet_.emplace(stream->packet_queue.top());
   stream->packet_queue.pop();

   return *pop_packet_;
 }

 void PacketQueue2::CancelPop(const Packet& packet) {
   RTC_CHECK(pop_packet_ && pop_stream_);
   (*pop_stream_)->packet_queue.push(*pop_packet_);
   pop_packet_.reset();
   pop_stream_.reset();
 }

 void PacketQueue2::FinalizePop(const Packet& packet) {
   RTC_CHECK(!paused_);
   if (!Empty()) {
     RTC_CHECK(pop_packet_ && pop_stream_);
     Stream* stream = *pop_stream_;
     stream_priorities_.erase(stream->priority_it);
     const Packet& packet = *pop_packet_;

     // Calculate the total amount of time spent by this packet in the queue
     // while in a non-paused state. Note that the |pause_time_sum_ms_| was
     // subtracted from |packet.enqueue_time_ms| when the packet was pushed, and
     // by subtracting it now we effectively remove the time spent in in the
     // queue while in a paused state.
     int64_t time_in_non_paused_state_ms =
         time_last_updated_ - packet.enqueue_time_ms - pause_time_sum_ms_;
     queue_time_sum_ms_ -= time_in_non_paused_state_ms;

     RTC_CHECK(packet.enqueue_time_it != enqueue_times_.end());
     enqueue_times_.erase(packet.enqueue_time_it);

     // Update |bytes| of this stream. The general idea is that the stream that
     // has sent the least amount of bytes should have the highest priority.
     // The problem with that is if streams send with different rates, in which
     // case a "budget" will be built up for the stream sending at the lower
     // rate. To avoid building a too large budget we limit |bytes| to be within
     // kMaxLeading bytes of the stream that has sent the most amount of bytes.
     stream->bytes =
         std::max(stream->bytes + packet.bytes, max_bytes_ - kMaxLeadingBytes);
     max_bytes_ = std::max(max_bytes_, stream->bytes);

     size_bytes_ -= packet.bytes;
     size_packets_ -= 1;
     RTC_CHECK(size_packets_ > 0 || queue_time_sum_ms_ == 0);

     // If there are packets left to be sent, schedule the stream again.
     RTC_CHECK(!IsSsrcScheduled(stream->ssrc));
     if (stream->packet_queue.empty()) {
       stream->priority_it = stream_priorities_.end();
     } else {
       RtpPacketSender::Priority priority = stream->packet_queue.top().priority;
       stream->priority_it = stream_priorities_.emplace(
           StreamPrioKey(priority, stream->bytes), stream->ssrc);
     }

     pop_packet_.reset();
     pop_stream_.reset();
   }
 }

 bool PacketQueue2::Empty() const {
   RTC_CHECK((!stream_priorities_.empty() && size_packets_ > 0) ||
             (stream_priorities_.empty() && size_packets_ == 0));
   return stream_priorities_.empty();
 }

 size_t PacketQueue2::SizeInPackets() const {
   return size_packets_;
 }

 uint64_t PacketQueue2::SizeInBytes() const {
   return size_bytes_;
 }

 int64_t PacketQueue2::OldestEnqueueTimeMs() const {
   if (Empty())
     return 0;
   RTC_CHECK(!enqueue_times_.empty());
   return *enqueue_times_.begin();
 }

 void PacketQueue2::UpdateQueueTime(int64_t timestamp_ms) {
   RTC_CHECK_GE(timestamp_ms, time_last_updated_);
   if (timestamp_ms == time_last_updated_)
     return;

   int64_t delta_ms = timestamp_ms - time_last_updated_;

   if (paused_) {
     pause_time_sum_ms_ += delta_ms;
   } else {
     queue_time_sum_ms_ += delta_ms * size_packets_;
   }

   time_last_updated_ = timestamp_ms;
 }

 void PacketQueue2::SetPauseState(bool paused, int64_t timestamp_ms) {
   if (paused_ == paused)
     return;
   UpdateQueueTime(timestamp_ms);
   paused_ = paused;
 }

 int64_t PacketQueue2::AverageQueueTimeMs() const {
   if (Empty())
     return 0;
   return queue_time_sum_ms_ / size_packets_;
 }

 PacketQueue2::Stream* PacketQueue2::GetHighestPriorityStream() {
   RTC_CHECK(!stream_priorities_.empty());
   uint32_t ssrc = stream_priorities_.begin()->second;

   auto stream_info_it = streams_.find(ssrc);
   RTC_CHECK(stream_info_it != streams_.end());
   RTC_CHECK(stream_info_it->second.priority_it == stream_priorities_.begin());
   RTC_CHECK(!stream_info_it->second.packet_queue.empty());
   return &stream_info_it->second;
 }

 bool PacketQueue2::IsSsrcScheduled(uint32_t ssrc) const {
   for (const auto& scheduled_stream : stream_priorities_) {
     if (scheduled_stream.second == ssrc)
       return true;
   }
   return false;
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2017 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/pacing/packet_queue2.h"

	#include <algorithm>

	#include "rtc_base/checks.h"
	#include "system_wrappers/include/clock.h"

	namespace webrtc {

	PacketQueue2::Stream::Stream() : bytes(0) {}
	PacketQueue2::Stream::~Stream() {}

	PacketQueue2::PacketQueue2(const Clock* clock)
	: PacketQueue(clock),
	clock_(clock),
	time_last_updated_(clock_->TimeInMilliseconds()) {}

	PacketQueue2::~PacketQueue2() {}

	void PacketQueue2::Push(const Packet& packet_to_insert) {
	Packet packet(packet_to_insert);

	auto stream_info_it = streams_.find(packet.ssrc);
	if (stream_info_it == streams_.end()) {
	stream_info_it = streams_.emplace(packet.ssrc, Stream()).first;
	stream_info_it->second.priority_it = stream_priorities_.end();
	stream_info_it->second.ssrc = packet.ssrc;
	}

	Stream* streams_ = &stream_info_it->second;

	if (streams_->priority_it == stream_priorities_.end()) {
	// If the SSRC is not currently scheduled, add it to \|stream_priorities_\|.
	RTC_CHECK(!IsSsrcScheduled(streams_->ssrc));
	streams_->priority_it = stream_priorities_.emplace(
	StreamPrioKey(packet.priority, streams_->bytes), packet.ssrc);
	} else if (packet.priority < streams_->priority_it->first.priority) {
	// If the priority of this SSRC increased, remove the outdated StreamPrioKey
	// and insert a new one with the new priority. Note that
	// RtpPacketSender::Priority uses lower ordinal for higher priority.
	stream_priorities_.erase(streams_->priority_it);
	streams_->priority_it = stream_priorities_.emplace(
	StreamPrioKey(packet.priority, streams_->bytes), packet.ssrc);
	}
	RTC_CHECK(streams_->priority_it != stream_priorities_.end());

	packet.enqueue_time_it = enqueue_times_.insert(packet.enqueue_time_ms);

	// In order to figure out how much time a packet has spent in the queue while
	// not in a paused state, we subtract the total amount of time the queue has
	// been paused so far, and when the packet is poped we subtract the total
	// amount of time the queue has been paused at that moment. This way we
	// subtract the total amount of time the packet has spent in the queue while
	// in a paused state.
	UpdateQueueTime(packet.enqueue_time_ms);
	packet.enqueue_time_ms -= pause_time_sum_ms_;
	streams_->packet_queue.push(packet);

	size_packets_ += 1;
	size_bytes_ += packet.bytes;
	}

	const PacketQueue2::Packet& PacketQueue2::BeginPop() {
	RTC_CHECK(!pop_packet_ && !pop_stream_);

	Stream* stream = GetHighestPriorityStream();
	pop_stream_.emplace(stream);
	pop_packet_.emplace(stream->packet_queue.top());
	stream->packet_queue.pop();

	return *pop_packet_;
	}

	void PacketQueue2::CancelPop(const Packet& packet) {
	RTC_CHECK(pop_packet_ && pop_stream_);
	(pop_stream_)->packet_queue.push(pop_packet_);
	pop_packet_.reset();
	pop_stream_.reset();
	}

	void PacketQueue2::FinalizePop(const Packet& packet) {
	RTC_CHECK(!paused_);
	if (!Empty()) {
	RTC_CHECK(pop_packet_ && pop_stream_);
	Stream* stream = *pop_stream_;
	stream_priorities_.erase(stream->priority_it);
	const Packet& packet = *pop_packet_;

	// Calculate the total amount of time spent by this packet in the queue
	// while in a non-paused state. Note that the \|pause_time_sum_ms_\| was
	// subtracted from \|packet.enqueue_time_ms\| when the packet was pushed, and
	// by subtracting it now we effectively remove the time spent in in the
	// queue while in a paused state.
	int64_t time_in_non_paused_state_ms =
	time_last_updated_ - packet.enqueue_time_ms - pause_time_sum_ms_;
	queue_time_sum_ms_ -= time_in_non_paused_state_ms;

	RTC_CHECK(packet.enqueue_time_it != enqueue_times_.end());
	enqueue_times_.erase(packet.enqueue_time_it);

	// Update \|bytes\| of this stream. The general idea is that the stream that
	// has sent the least amount of bytes should have the highest priority.
	// The problem with that is if streams send with different rates, in which
	// case a "budget" will be built up for the stream sending at the lower
	// rate. To avoid building a too large budget we limit \|bytes\| to be within
	// kMaxLeading bytes of the stream that has sent the most amount of bytes.
	stream->bytes =
	std::max(stream->bytes + packet.bytes, max_bytes_ - kMaxLeadingBytes);
	max_bytes_ = std::max(max_bytes_, stream->bytes);

	size_bytes_ -= packet.bytes;
	size_packets_ -= 1;
	RTC_CHECK(size_packets_ > 0 \|\| queue_time_sum_ms_ == 0);

	// If there are packets left to be sent, schedule the stream again.
	RTC_CHECK(!IsSsrcScheduled(stream->ssrc));
	if (stream->packet_queue.empty()) {
	stream->priority_it = stream_priorities_.end();
	} else {
	RtpPacketSender::Priority priority = stream->packet_queue.top().priority;
	stream->priority_it = stream_priorities_.emplace(
	StreamPrioKey(priority, stream->bytes), stream->ssrc);
	}

	pop_packet_.reset();
	pop_stream_.reset();
	}
	}

	bool PacketQueue2::Empty() const {
	RTC_CHECK((!stream_priorities_.empty() && size_packets_ > 0) \|\|
	(stream_priorities_.empty() && size_packets_ == 0));
	return stream_priorities_.empty();
	}

	size_t PacketQueue2::SizeInPackets() const {
	return size_packets_;
	}

	uint64_t PacketQueue2::SizeInBytes() const {
	return size_bytes_;
	}

	int64_t PacketQueue2::OldestEnqueueTimeMs() const {
	if (Empty())
	return 0;
	RTC_CHECK(!enqueue_times_.empty());
	return *enqueue_times_.begin();
	}

	void PacketQueue2::UpdateQueueTime(int64_t timestamp_ms) {
	RTC_CHECK_GE(timestamp_ms, time_last_updated_);
	if (timestamp_ms == time_last_updated_)
	return;

	int64_t delta_ms = timestamp_ms - time_last_updated_;

	if (paused_) {
	pause_time_sum_ms_ += delta_ms;
	} else {
	queue_time_sum_ms_ += delta_ms * size_packets_;
	}

	time_last_updated_ = timestamp_ms;
	}

	void PacketQueue2::SetPauseState(bool paused, int64_t timestamp_ms) {
	if (paused_ == paused)
	return;
	UpdateQueueTime(timestamp_ms);
	paused_ = paused;
	}

	int64_t PacketQueue2::AverageQueueTimeMs() const {
	if (Empty())
	return 0;
	return queue_time_sum_ms_ / size_packets_;
	}

	PacketQueue2::Stream* PacketQueue2::GetHighestPriorityStream() {
	RTC_CHECK(!stream_priorities_.empty());
	uint32_t ssrc = stream_priorities_.begin()->second;

	auto stream_info_it = streams_.find(ssrc);
	RTC_CHECK(stream_info_it != streams_.end());
	RTC_CHECK(stream_info_it->second.priority_it == stream_priorities_.begin());
	RTC_CHECK(!stream_info_it->second.packet_queue.empty());
	return &stream_info_it->second;
	}

	bool PacketQueue2::IsSsrcScheduled(uint32_t ssrc) const {
	for (const auto& scheduled_stream : stream_priorities_) {
	if (scheduled_stream.second == ssrc)
	return true;
	}
	return false;
	}

	} // namespace webrtc