modules/congestion_controller/goog_cc/robust_throughput_estimator.cc - src - Git at Google

 /*
  *  Copyright (c) 2019 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/congestion_controller/goog_cc/robust_throughput_estimator.h"

 #include <stddef.h>

 #include <algorithm>
 #include <utility>

 #include "rtc_base/checks.h"

 namespace webrtc {

 RobustThroughputEstimator::RobustThroughputEstimator(
     const RobustThroughputEstimatorSettings& settings)
     : settings_(settings) {
   RTC_DCHECK(settings.enabled);
 }

 RobustThroughputEstimator::~RobustThroughputEstimator() {}

 void RobustThroughputEstimator::IncomingPacketFeedbackVector(
     const std::vector<PacketResult>& packet_feedback_vector) {
   RTC_DCHECK(std::is_sorted(packet_feedback_vector.begin(),
                             packet_feedback_vector.end(),
                             PacketResult::ReceiveTimeOrder()));
   for (const auto& packet : packet_feedback_vector) {
     // Insert the new packet.
     window_.push_back(packet);
     window_.back().sent_packet.prior_unacked_data =
         window_.back().sent_packet.prior_unacked_data *
         settings_.unacked_weight;
     // In most cases, receive timestamps should already be in order, but in the
     // rare case where feedback packets have been reordered, we do some swaps to
     // ensure that the window is sorted.
     for (size_t i = window_.size() - 1;
          i > 0 && window_[i].receive_time < window_[i - 1].receive_time; i--) {
       std::swap(window_[i], window_[i - 1]);
     }
     // Remove old packets.
     while (window_.size() > settings_.kMaxPackets ||
            (window_.size() > settings_.min_packets &&
             packet.receive_time - window_.front().receive_time >
                 settings_.window_duration)) {
       window_.pop_front();
     }
   }
 }

 absl::optional<DataRate> RobustThroughputEstimator::bitrate() const {
   if (window_.size() < settings_.initial_packets)
     return absl::nullopt;

   TimeDelta largest_recv_gap(TimeDelta::Millis(0));
   TimeDelta second_largest_recv_gap(TimeDelta::Millis(0));
   for (size_t i = 1; i < window_.size(); i++) {
     // Find receive time gaps
     TimeDelta gap = window_[i].receive_time - window_[i - 1].receive_time;
     if (gap > largest_recv_gap) {
       second_largest_recv_gap = largest_recv_gap;
       largest_recv_gap = gap;
     } else if (gap > second_largest_recv_gap) {
       second_largest_recv_gap = gap;
     }
   }

   Timestamp min_send_time = window_[0].sent_packet.send_time;
   Timestamp max_send_time = window_[0].sent_packet.send_time;
   Timestamp min_recv_time = window_[0].receive_time;
   Timestamp max_recv_time = window_[0].receive_time;
   DataSize data_size = DataSize::Bytes(0);
   for (const auto& packet : window_) {
     min_send_time = std::min(min_send_time, packet.sent_packet.send_time);
     max_send_time = std::max(max_send_time, packet.sent_packet.send_time);
     min_recv_time = std::min(min_recv_time, packet.receive_time);
     max_recv_time = std::max(max_recv_time, packet.receive_time);
     data_size += packet.sent_packet.size;
     data_size += packet.sent_packet.prior_unacked_data;
   }

   // Suppose a packet of size S is sent every T milliseconds.
   // A window of N packets would contain N*S bytes, but the time difference
   // between the first and the last packet would only be (N-1)*T. Thus, we
   // need to remove one packet.
   DataSize recv_size = data_size;
   DataSize send_size = data_size;
   if (settings_.assume_shared_link) {
     // Depending on how the bottleneck queue is implemented, a large packet
     // may delay sending of sebsequent packets, so the delay between packets
     // i and i+1  depends on the size of both packets. In this case we minimize
     // the maximum error by removing half of both the first and last packet
     // size.
     DataSize first_last_average_size =
         (window_.front().sent_packet.size +
          window_.front().sent_packet.prior_unacked_data +
          window_.back().sent_packet.size +
          window_.back().sent_packet.prior_unacked_data) /
         2;
     recv_size -= first_last_average_size;
     send_size -= first_last_average_size;
   } else {
     // In the simpler case where the delay between packets i and i+1 only
     // depends on the size of packet i+1, the first packet doesn't give us
     // any information. Analogously, we assume that the start send time
     // for the last packet doesn't depend on the size of the packet.
     recv_size -= (window_.front().sent_packet.size +
                   window_.front().sent_packet.prior_unacked_data);
     send_size -= (window_.back().sent_packet.size +
                   window_.back().sent_packet.prior_unacked_data);
   }

   // Remove the largest gap by replacing it by the second largest gap
   // or the average gap.
   TimeDelta send_duration = max_send_time - min_send_time;
   TimeDelta recv_duration = (max_recv_time - min_recv_time) - largest_recv_gap;
   if (settings_.reduce_bias) {
     recv_duration += second_largest_recv_gap;
   } else {
     recv_duration += recv_duration / (window_.size() - 2);
   }

   send_duration = std::max(send_duration, TimeDelta::Millis(1));
   recv_duration = std::max(recv_duration, TimeDelta::Millis(1));
   return std::min(send_size / send_duration, recv_size / recv_duration);
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2019 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/congestion_controller/goog_cc/robust_throughput_estimator.h"

	#include <stddef.h>

	#include <algorithm>
	#include <utility>

	#include "rtc_base/checks.h"

	namespace webrtc {

	RobustThroughputEstimator::RobustThroughputEstimator(
	const RobustThroughputEstimatorSettings& settings)
	: settings_(settings) {
	RTC_DCHECK(settings.enabled);
	}

	RobustThroughputEstimator::~RobustThroughputEstimator() {}

	void RobustThroughputEstimator::IncomingPacketFeedbackVector(
	const std::vector<PacketResult>& packet_feedback_vector) {
	RTC_DCHECK(std::is_sorted(packet_feedback_vector.begin(),
	packet_feedback_vector.end(),
	PacketResult::ReceiveTimeOrder()));
	for (const auto& packet : packet_feedback_vector) {
	// Insert the new packet.
	window_.push_back(packet);
	window_.back().sent_packet.prior_unacked_data =
	window_.back().sent_packet.prior_unacked_data *
	settings_.unacked_weight;
	// In most cases, receive timestamps should already be in order, but in the
	// rare case where feedback packets have been reordered, we do some swaps to
	// ensure that the window is sorted.
	for (size_t i = window_.size() - 1;
	i > 0 && window_[i].receive_time < window_[i - 1].receive_time; i--) {
	std::swap(window_[i], window_[i - 1]);
	}
	// Remove old packets.
	while (window_.size() > settings_.kMaxPackets \|\|
	(window_.size() > settings_.min_packets &&
	packet.receive_time - window_.front().receive_time >
	settings_.window_duration)) {
	window_.pop_front();
	}
	}
	}

	absl::optional<DataRate> RobustThroughputEstimator::bitrate() const {
	if (window_.size() < settings_.initial_packets)
	return absl::nullopt;

	TimeDelta largest_recv_gap(TimeDelta::Millis(0));
	TimeDelta second_largest_recv_gap(TimeDelta::Millis(0));
	for (size_t i = 1; i < window_.size(); i++) {
	// Find receive time gaps
	TimeDelta gap = window_[i].receive_time - window_[i - 1].receive_time;
	if (gap > largest_recv_gap) {
	second_largest_recv_gap = largest_recv_gap;
	largest_recv_gap = gap;
	} else if (gap > second_largest_recv_gap) {
	second_largest_recv_gap = gap;
	}
	}

	Timestamp min_send_time = window_[0].sent_packet.send_time;
	Timestamp max_send_time = window_[0].sent_packet.send_time;
	Timestamp min_recv_time = window_[0].receive_time;
	Timestamp max_recv_time = window_[0].receive_time;
	DataSize data_size = DataSize::Bytes(0);
	for (const auto& packet : window_) {
	min_send_time = std::min(min_send_time, packet.sent_packet.send_time);
	max_send_time = std::max(max_send_time, packet.sent_packet.send_time);
	min_recv_time = std::min(min_recv_time, packet.receive_time);
	max_recv_time = std::max(max_recv_time, packet.receive_time);
	data_size += packet.sent_packet.size;
	data_size += packet.sent_packet.prior_unacked_data;
	}

	// Suppose a packet of size S is sent every T milliseconds.
	// A window of N packets would contain N*S bytes, but the time difference
	// between the first and the last packet would only be (N-1)*T. Thus, we
	// need to remove one packet.
	DataSize recv_size = data_size;
	DataSize send_size = data_size;
	if (settings_.assume_shared_link) {
	// Depending on how the bottleneck queue is implemented, a large packet
	// may delay sending of sebsequent packets, so the delay between packets
	// i and i+1 depends on the size of both packets. In this case we minimize
	// the maximum error by removing half of both the first and last packet
	// size.
	DataSize first_last_average_size =
	(window_.front().sent_packet.size +
	window_.front().sent_packet.prior_unacked_data +
	window_.back().sent_packet.size +
	window_.back().sent_packet.prior_unacked_data) /
	2;
	recv_size -= first_last_average_size;
	send_size -= first_last_average_size;
	} else {
	// In the simpler case where the delay between packets i and i+1 only
	// depends on the size of packet i+1, the first packet doesn't give us
	// any information. Analogously, we assume that the start send time
	// for the last packet doesn't depend on the size of the packet.
	recv_size -= (window_.front().sent_packet.size +
	window_.front().sent_packet.prior_unacked_data);
	send_size -= (window_.back().sent_packet.size +
	window_.back().sent_packet.prior_unacked_data);
	}

	// Remove the largest gap by replacing it by the second largest gap
	// or the average gap.
	TimeDelta send_duration = max_send_time - min_send_time;
	TimeDelta recv_duration = (max_recv_time - min_recv_time) - largest_recv_gap;
	if (settings_.reduce_bias) {
	recv_duration += second_largest_recv_gap;
	} else {
	recv_duration += recv_duration / (window_.size() - 2);
	}

	send_duration = std::max(send_duration, TimeDelta::Millis(1));
	recv_duration = std::max(recv_duration, TimeDelta::Millis(1));
	return std::min(send_size / send_duration, recv_size / recv_duration);
	}

	} // namespace webrtc