modules/congestion_controller/pcc/pcc_network_controller.cc - src - Git at Google

 /*
  *  Copyright (c) 2018 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/pcc/pcc_network_controller.h"

 #include <algorithm>

 #include "absl/types/optional.h"
 #include "api/units/data_size.h"
 #include "rtc_base/checks.h"

 namespace webrtc {
 namespace pcc {
 namespace {
 constexpr int64_t kInitialRttMs = 200;
 constexpr int64_t kInitialBandwidthKbps = 300;
 constexpr double kMonitorIntervalDurationRatio = 1;
 constexpr double kDefaultSamplingStep = 0.05;
 constexpr double kTimeoutRatio = 2;
 constexpr double kAlphaForRtt = 0.9;
 constexpr double kSlowStartModeIncrease = 1.5;

 constexpr double kAlphaForPacketInterval = 0.9;
 constexpr int64_t kMinPacketsNumberPerInterval = 20;
 const TimeDelta kMinDurationOfMonitorInterval = TimeDelta::Millis(50);
 const TimeDelta kStartupDuration = TimeDelta::Millis(500);
 constexpr double kMinRateChangeBps = 4000;
 constexpr DataRate kMinRateHaveMultiplicativeRateChange = DataRate::BitsPerSec(
     static_cast<int64_t>(kMinRateChangeBps / kDefaultSamplingStep));

 // Bitrate controller constants.
 constexpr double kInitialConversionFactor = 5;
 constexpr double kInitialDynamicBoundary = 0.1;
 constexpr double kDynamicBoundaryIncrement = 0.1;
 // Utility function parameters.
 constexpr double kRttGradientCoefficientBps = 0.005;
 constexpr double kLossCoefficientBps = 10;
 constexpr double kThroughputCoefficient = 0.001;
 constexpr double kThroughputPower = 0.9;
 constexpr double kRttGradientThreshold = 0.01;
 constexpr double kDelayGradientNegativeBound = 0.1;

 constexpr int64_t kNumberOfPacketsToKeep = 20;
 const uint64_t kRandomSeed = 100;
 }  // namespace

 PccNetworkController::PccNetworkController(NetworkControllerConfig config)
     : start_time_(Timestamp::PlusInfinity()),
       last_sent_packet_time_(Timestamp::PlusInfinity()),
       smoothed_packets_sending_interval_(TimeDelta::Zero()),
       mode_(Mode::kStartup),
       default_bandwidth_(DataRate::KilobitsPerSec(kInitialBandwidthKbps)),
       bandwidth_estimate_(default_bandwidth_),
       rtt_tracker_(TimeDelta::Millis(kInitialRttMs), kAlphaForRtt),
       monitor_interval_timeout_(TimeDelta::Millis(kInitialRttMs) *
                                 kTimeoutRatio),
       monitor_interval_length_strategy_(MonitorIntervalLengthStrategy::kFixed),
       monitor_interval_duration_ratio_(kMonitorIntervalDurationRatio),
       sampling_step_(kDefaultSamplingStep),
       monitor_interval_timeout_ratio_(kTimeoutRatio),
       min_packets_number_per_interval_(kMinPacketsNumberPerInterval),
       bitrate_controller_(kInitialConversionFactor,
                           kInitialDynamicBoundary,
                           kDynamicBoundaryIncrement,
                           kRttGradientCoefficientBps,
                           kLossCoefficientBps,
                           kThroughputCoefficient,
                           kThroughputPower,
                           kRttGradientThreshold,
                           kDelayGradientNegativeBound),
       monitor_intervals_duration_(TimeDelta::Zero()),
       complete_feedback_monitor_interval_number_(0),
       random_generator_(kRandomSeed) {
   if (config.constraints.starting_rate) {
     default_bandwidth_ = *config.constraints.starting_rate;
     bandwidth_estimate_ = default_bandwidth_;
   }
 }

 PccNetworkController::~PccNetworkController() {}

 NetworkControlUpdate PccNetworkController::CreateRateUpdate(
     Timestamp at_time) const {
   DataRate sending_rate = DataRate::Zero();
   if (monitor_intervals_.empty() ||
       (monitor_intervals_.size() >= monitor_intervals_bitrates_.size() &&
        at_time >= monitor_intervals_.back().GetEndTime())) {
     sending_rate = bandwidth_estimate_;
   } else {
     sending_rate = monitor_intervals_.back().GetTargetSendingRate();
   }
   // Set up config when sending rate is computed.
   NetworkControlUpdate update;

   // Set up target rate to encoder.
   TargetTransferRate target_rate_msg;
   target_rate_msg.at_time = at_time;
   target_rate_msg.network_estimate.at_time = at_time;
   target_rate_msg.network_estimate.round_trip_time = rtt_tracker_.GetRtt();
   // TODO(koloskova): Add correct estimate.
   target_rate_msg.network_estimate.loss_rate_ratio = 0;
   target_rate_msg.network_estimate.bwe_period =
       monitor_interval_duration_ratio_ * rtt_tracker_.GetRtt();

   target_rate_msg.target_rate = sending_rate;
   update.target_rate = target_rate_msg;

   // Set up pacing/padding target rate.
   PacerConfig pacer_config;
   pacer_config.at_time = at_time;
   pacer_config.time_window = TimeDelta::Millis(1);
   pacer_config.data_window = sending_rate * pacer_config.time_window;
   pacer_config.pad_window = sending_rate * pacer_config.time_window;

   update.pacer_config = pacer_config;
   return update;
 }

 NetworkControlUpdate PccNetworkController::OnSentPacket(SentPacket msg) {
   // Start new monitor interval if previous has finished.
   // Monitor interval is initialized in OnProcessInterval function.
   if (start_time_.IsInfinite()) {
     start_time_ = msg.send_time;
     monitor_intervals_duration_ = kStartupDuration;
     monitor_intervals_bitrates_ = {bandwidth_estimate_};
     monitor_intervals_.emplace_back(bandwidth_estimate_, msg.send_time,
                                     monitor_intervals_duration_);
     complete_feedback_monitor_interval_number_ = 0;
   }
   if (last_sent_packet_time_.IsFinite()) {
     smoothed_packets_sending_interval_ =
         (msg.send_time - last_sent_packet_time_) * kAlphaForPacketInterval +
         (1 - kAlphaForPacketInterval) * smoothed_packets_sending_interval_;
   }
   last_sent_packet_time_ = msg.send_time;
   if (!monitor_intervals_.empty() &&
       msg.send_time >= monitor_intervals_.back().GetEndTime() &&
       monitor_intervals_bitrates_.size() > monitor_intervals_.size()) {
     // Start new monitor interval.
     monitor_intervals_.emplace_back(
         monitor_intervals_bitrates_[monitor_intervals_.size()], msg.send_time,
         monitor_intervals_duration_);
   }
   if (IsTimeoutExpired(msg.send_time)) {
     DataSize received_size = DataSize::Zero();
     for (size_t i = 1; i < last_received_packets_.size(); ++i) {
       received_size += last_received_packets_[i].sent_packet.size;
     }
     TimeDelta sending_time = TimeDelta::Zero();
     if (last_received_packets_.size() > 0)
       sending_time = last_received_packets_.back().receive_time -
                      last_received_packets_.front().receive_time;
     DataRate receiving_rate = bandwidth_estimate_;
     if (sending_time > TimeDelta::Zero())
       receiving_rate = received_size / sending_time;
     bandwidth_estimate_ =
         std::min<DataRate>(bandwidth_estimate_ * 0.5, receiving_rate);
     if (mode_ == Mode::kSlowStart)
       mode_ = Mode::kOnlineLearning;
   }
   if (mode_ == Mode::kStartup &&
       msg.send_time - start_time_ >= kStartupDuration) {
     DataSize received_size = DataSize::Zero();
     for (size_t i = 1; i < last_received_packets_.size(); ++i) {
       received_size += last_received_packets_[i].sent_packet.size;
     }
     TimeDelta sending_time = TimeDelta::Zero();
     if (last_received_packets_.size() > 0)
       sending_time = last_received_packets_.back().receive_time -
                      last_received_packets_.front().receive_time;
     DataRate receiving_rate = bandwidth_estimate_;
     if (sending_time > TimeDelta::Zero())
       receiving_rate = received_size / sending_time;
     bandwidth_estimate_ = receiving_rate;
     monitor_intervals_.clear();
     mode_ = Mode::kSlowStart;
     monitor_intervals_duration_ = ComputeMonitorIntervalsDuration();
     monitor_intervals_bitrates_ = {bandwidth_estimate_};
     monitor_intervals_.emplace_back(bandwidth_estimate_, msg.send_time,
                                     monitor_intervals_duration_);
     bandwidth_estimate_ = bandwidth_estimate_ * (1 / kSlowStartModeIncrease);
     complete_feedback_monitor_interval_number_ = 0;
     return CreateRateUpdate(msg.send_time);
   }
   if (IsFeedbackCollectionDone() || IsTimeoutExpired(msg.send_time)) {
     // Creating new monitor intervals.
     monitor_intervals_.clear();
     monitor_interval_timeout_ =
         rtt_tracker_.GetRtt() * monitor_interval_timeout_ratio_;
     monitor_intervals_duration_ = ComputeMonitorIntervalsDuration();
     complete_feedback_monitor_interval_number_ = 0;
     // Compute bitrates and start first monitor interval.
     if (mode_ == Mode::kSlowStart) {
       monitor_intervals_bitrates_ = {kSlowStartModeIncrease *
                                      bandwidth_estimate_};
       monitor_intervals_.emplace_back(
           kSlowStartModeIncrease * bandwidth_estimate_, msg.send_time,
           monitor_intervals_duration_);
     } else {
       RTC_DCHECK(mode_ == Mode::kOnlineLearning || mode_ == Mode::kDoubleCheck);
       monitor_intervals_.clear();
       int64_t sign = 2 * (random_generator_.Rand(0, 1) % 2) - 1;
       RTC_DCHECK_GE(sign, -1);
       RTC_DCHECK_LE(sign, 1);
       if (bandwidth_estimate_ >= kMinRateHaveMultiplicativeRateChange) {
         monitor_intervals_bitrates_ = {
             bandwidth_estimate_ * (1 + sign * sampling_step_),
             bandwidth_estimate_ * (1 - sign * sampling_step_)};
       } else {
         monitor_intervals_bitrates_ = {
             DataRate::BitsPerSec(std::max<double>(
                 bandwidth_estimate_.bps() + sign * kMinRateChangeBps, 0)),
             DataRate::BitsPerSec(std::max<double>(
                 bandwidth_estimate_.bps() - sign * kMinRateChangeBps, 0))};
       }
       monitor_intervals_.emplace_back(monitor_intervals_bitrates_[0],
                                       msg.send_time,
                                       monitor_intervals_duration_);
     }
   }
   return CreateRateUpdate(msg.send_time);
 }

 TimeDelta PccNetworkController::ComputeMonitorIntervalsDuration() const {
   TimeDelta monitor_intervals_duration = TimeDelta::Zero();
   if (monitor_interval_length_strategy_ ==
       MonitorIntervalLengthStrategy::kAdaptive) {
     monitor_intervals_duration = std::max(
         rtt_tracker_.GetRtt() * monitor_interval_duration_ratio_,
         smoothed_packets_sending_interval_ * min_packets_number_per_interval_);
   } else {
     RTC_DCHECK(monitor_interval_length_strategy_ ==
                MonitorIntervalLengthStrategy::kFixed);
     monitor_intervals_duration =
         smoothed_packets_sending_interval_ * min_packets_number_per_interval_;
   }
   monitor_intervals_duration =
       std::max(kMinDurationOfMonitorInterval, monitor_intervals_duration);
   return monitor_intervals_duration;
 }

 bool PccNetworkController::IsTimeoutExpired(Timestamp current_time) const {
   if (complete_feedback_monitor_interval_number_ >= monitor_intervals_.size()) {
     return false;
   }
   return current_time -
              monitor_intervals_[complete_feedback_monitor_interval_number_]
                  .GetEndTime() >=
          monitor_interval_timeout_;
 }

 bool PccNetworkController::IsFeedbackCollectionDone() const {
   return complete_feedback_monitor_interval_number_ >=
          monitor_intervals_bitrates_.size();
 }

 NetworkControlUpdate PccNetworkController::OnTransportPacketsFeedback(
     TransportPacketsFeedback msg) {
   if (msg.packet_feedbacks.empty())
     return NetworkControlUpdate();
   // Save packets to last_received_packets_ array.
   for (const PacketResult& packet_result : msg.ReceivedWithSendInfo()) {
     last_received_packets_.push_back(packet_result);
   }
   while (last_received_packets_.size() > kNumberOfPacketsToKeep) {
     last_received_packets_.pop_front();
   }
   rtt_tracker_.OnPacketsFeedback(msg.PacketsWithFeedback(), msg.feedback_time);
   // Skip rate update in case when online learning mode just started, but
   // corresponding monitor intervals were not started yet.
   if (mode_ == Mode::kOnlineLearning &&
       monitor_intervals_bitrates_.size() < 2) {
     return NetworkControlUpdate();
   }
   if (!IsFeedbackCollectionDone() && !monitor_intervals_.empty()) {
     while (complete_feedback_monitor_interval_number_ <
            monitor_intervals_.size()) {
       monitor_intervals_[complete_feedback_monitor_interval_number_]
           .OnPacketsFeedback(msg.PacketsWithFeedback());
       if (!monitor_intervals_[complete_feedback_monitor_interval_number_]
                .IsFeedbackCollectionDone())
         break;
       ++complete_feedback_monitor_interval_number_;
     }
   }
   if (IsFeedbackCollectionDone()) {
     if (mode_ == Mode::kDoubleCheck) {
       mode_ = Mode::kOnlineLearning;
     } else if (NeedDoubleCheckMeasurments()) {
       mode_ = Mode::kDoubleCheck;
     }
     if (mode_ != Mode::kDoubleCheck)
       UpdateSendingRateAndMode();
   }
   return NetworkControlUpdate();
 }

 bool PccNetworkController::NeedDoubleCheckMeasurments() const {
   if (mode_ == Mode::kSlowStart) {
     return false;
   }
   double first_loss_rate = monitor_intervals_[0].GetLossRate();
   double second_loss_rate = monitor_intervals_[1].GetLossRate();
   DataRate first_bitrate = monitor_intervals_[0].GetTargetSendingRate();
   DataRate second_bitrate = monitor_intervals_[1].GetTargetSendingRate();
   if ((first_bitrate.bps() - second_bitrate.bps()) *
           (first_loss_rate - second_loss_rate) <
       0) {
     return true;
   }
   return false;
 }

 void PccNetworkController::UpdateSendingRateAndMode() {
   if (monitor_intervals_.empty() || !IsFeedbackCollectionDone()) {
     return;
   }
   if (mode_ == Mode::kSlowStart) {
     DataRate old_bandwidth_estimate = bandwidth_estimate_;
     bandwidth_estimate_ =
         bitrate_controller_
             .ComputeRateUpdateForSlowStartMode(monitor_intervals_[0])
             .value_or(bandwidth_estimate_);
     if (bandwidth_estimate_ <= old_bandwidth_estimate)
       mode_ = Mode::kOnlineLearning;
   } else {
     RTC_DCHECK(mode_ == Mode::kOnlineLearning);
     bandwidth_estimate_ =
         bitrate_controller_.ComputeRateUpdateForOnlineLearningMode(
             monitor_intervals_, bandwidth_estimate_);
   }
 }

 NetworkControlUpdate PccNetworkController::OnNetworkAvailability(
     NetworkAvailability msg) {
   return NetworkControlUpdate();
 }

 NetworkControlUpdate PccNetworkController::OnNetworkRouteChange(
     NetworkRouteChange msg) {
   return NetworkControlUpdate();
 }

 NetworkControlUpdate PccNetworkController::OnProcessInterval(
     ProcessInterval msg) {
   return CreateRateUpdate(msg.at_time);
 }

 NetworkControlUpdate PccNetworkController::OnTargetRateConstraints(
     TargetRateConstraints msg) {
   return NetworkControlUpdate();
 }

 NetworkControlUpdate PccNetworkController::OnRemoteBitrateReport(
     RemoteBitrateReport) {
   return NetworkControlUpdate();
 }

 NetworkControlUpdate PccNetworkController::OnRoundTripTimeUpdate(
     RoundTripTimeUpdate) {
   return NetworkControlUpdate();
 }

 NetworkControlUpdate PccNetworkController::OnTransportLossReport(
     TransportLossReport) {
   return NetworkControlUpdate();
 }

 NetworkControlUpdate PccNetworkController::OnStreamsConfig(StreamsConfig msg) {
   return NetworkControlUpdate();
 }

 NetworkControlUpdate PccNetworkController::OnReceivedPacket(
     ReceivedPacket msg) {
   return NetworkControlUpdate();
 }

 NetworkControlUpdate PccNetworkController::OnNetworkStateEstimate(
     NetworkStateEstimate msg) {
   return NetworkControlUpdate();
 }

 }  // namespace pcc
 }  // namespace webrtc
	/*
	* Copyright (c) 2018 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/pcc/pcc_network_controller.h"

	#include <algorithm>

	#include "absl/types/optional.h"
	#include "api/units/data_size.h"
	#include "rtc_base/checks.h"

	namespace webrtc {
	namespace pcc {
	namespace {
	constexpr int64_t kInitialRttMs = 200;
	constexpr int64_t kInitialBandwidthKbps = 300;
	constexpr double kMonitorIntervalDurationRatio = 1;
	constexpr double kDefaultSamplingStep = 0.05;
	constexpr double kTimeoutRatio = 2;
	constexpr double kAlphaForRtt = 0.9;
	constexpr double kSlowStartModeIncrease = 1.5;

	constexpr double kAlphaForPacketInterval = 0.9;
	constexpr int64_t kMinPacketsNumberPerInterval = 20;
	const TimeDelta kMinDurationOfMonitorInterval = TimeDelta::Millis(50);
	const TimeDelta kStartupDuration = TimeDelta::Millis(500);
	constexpr double kMinRateChangeBps = 4000;
	constexpr DataRate kMinRateHaveMultiplicativeRateChange = DataRate::BitsPerSec(
	static_cast<int64_t>(kMinRateChangeBps / kDefaultSamplingStep));

	// Bitrate controller constants.
	constexpr double kInitialConversionFactor = 5;
	constexpr double kInitialDynamicBoundary = 0.1;
	constexpr double kDynamicBoundaryIncrement = 0.1;
	// Utility function parameters.
	constexpr double kRttGradientCoefficientBps = 0.005;
	constexpr double kLossCoefficientBps = 10;
	constexpr double kThroughputCoefficient = 0.001;
	constexpr double kThroughputPower = 0.9;
	constexpr double kRttGradientThreshold = 0.01;
	constexpr double kDelayGradientNegativeBound = 0.1;

	constexpr int64_t kNumberOfPacketsToKeep = 20;
	const uint64_t kRandomSeed = 100;
	} // namespace

	PccNetworkController::PccNetworkController(NetworkControllerConfig config)
	: start_time_(Timestamp::PlusInfinity()),
	last_sent_packet_time_(Timestamp::PlusInfinity()),
	smoothed_packets_sending_interval_(TimeDelta::Zero()),
	mode_(Mode::kStartup),
	default_bandwidth_(DataRate::KilobitsPerSec(kInitialBandwidthKbps)),
	bandwidth_estimate_(default_bandwidth_),
	rtt_tracker_(TimeDelta::Millis(kInitialRttMs), kAlphaForRtt),
	monitor_interval_timeout_(TimeDelta::Millis(kInitialRttMs) *
	kTimeoutRatio),
	monitor_interval_length_strategy_(MonitorIntervalLengthStrategy::kFixed),
	monitor_interval_duration_ratio_(kMonitorIntervalDurationRatio),
	sampling_step_(kDefaultSamplingStep),
	monitor_interval_timeout_ratio_(kTimeoutRatio),
	min_packets_number_per_interval_(kMinPacketsNumberPerInterval),
	bitrate_controller_(kInitialConversionFactor,
	kInitialDynamicBoundary,
	kDynamicBoundaryIncrement,
	kRttGradientCoefficientBps,
	kLossCoefficientBps,
	kThroughputCoefficient,
	kThroughputPower,
	kRttGradientThreshold,
	kDelayGradientNegativeBound),
	monitor_intervals_duration_(TimeDelta::Zero()),
	complete_feedback_monitor_interval_number_(0),
	random_generator_(kRandomSeed) {
	if (config.constraints.starting_rate) {
	default_bandwidth_ = *config.constraints.starting_rate;
	bandwidth_estimate_ = default_bandwidth_;
	}
	}

	PccNetworkController::~PccNetworkController() {}

	NetworkControlUpdate PccNetworkController::CreateRateUpdate(
	Timestamp at_time) const {
	DataRate sending_rate = DataRate::Zero();
	if (monitor_intervals_.empty() \|\|
	(monitor_intervals_.size() >= monitor_intervals_bitrates_.size() &&
	at_time >= monitor_intervals_.back().GetEndTime())) {
	sending_rate = bandwidth_estimate_;
	} else {
	sending_rate = monitor_intervals_.back().GetTargetSendingRate();
	}
	// Set up config when sending rate is computed.
	NetworkControlUpdate update;

	// Set up target rate to encoder.
	TargetTransferRate target_rate_msg;
	target_rate_msg.at_time = at_time;
	target_rate_msg.network_estimate.at_time = at_time;
	target_rate_msg.network_estimate.round_trip_time = rtt_tracker_.GetRtt();
	// TODO(koloskova): Add correct estimate.
	target_rate_msg.network_estimate.loss_rate_ratio = 0;
	target_rate_msg.network_estimate.bwe_period =
	monitor_interval_duration_ratio_ * rtt_tracker_.GetRtt();

	target_rate_msg.target_rate = sending_rate;
	update.target_rate = target_rate_msg;

	// Set up pacing/padding target rate.
	PacerConfig pacer_config;
	pacer_config.at_time = at_time;
	pacer_config.time_window = TimeDelta::Millis(1);
	pacer_config.data_window = sending_rate * pacer_config.time_window;
	pacer_config.pad_window = sending_rate * pacer_config.time_window;

	update.pacer_config = pacer_config;
	return update;
	}

	NetworkControlUpdate PccNetworkController::OnSentPacket(SentPacket msg) {
	// Start new monitor interval if previous has finished.
	// Monitor interval is initialized in OnProcessInterval function.
	if (start_time_.IsInfinite()) {
	start_time_ = msg.send_time;
	monitor_intervals_duration_ = kStartupDuration;
	monitor_intervals_bitrates_ = {bandwidth_estimate_};
	monitor_intervals_.emplace_back(bandwidth_estimate_, msg.send_time,
	monitor_intervals_duration_);
	complete_feedback_monitor_interval_number_ = 0;
	}
	if (last_sent_packet_time_.IsFinite()) {
	smoothed_packets_sending_interval_ =
	(msg.send_time - last_sent_packet_time_) * kAlphaForPacketInterval +
	(1 - kAlphaForPacketInterval) * smoothed_packets_sending_interval_;
	}
	last_sent_packet_time_ = msg.send_time;
	if (!monitor_intervals_.empty() &&
	msg.send_time >= monitor_intervals_.back().GetEndTime() &&
	monitor_intervals_bitrates_.size() > monitor_intervals_.size()) {
	// Start new monitor interval.
	monitor_intervals_.emplace_back(
	monitor_intervals_bitrates_[monitor_intervals_.size()], msg.send_time,
	monitor_intervals_duration_);
	}
	if (IsTimeoutExpired(msg.send_time)) {
	DataSize received_size = DataSize::Zero();
	for (size_t i = 1; i < last_received_packets_.size(); ++i) {
	received_size += last_received_packets_[i].sent_packet.size;
	}
	TimeDelta sending_time = TimeDelta::Zero();
	if (last_received_packets_.size() > 0)
	sending_time = last_received_packets_.back().receive_time -
	last_received_packets_.front().receive_time;
	DataRate receiving_rate = bandwidth_estimate_;
	if (sending_time > TimeDelta::Zero())
	receiving_rate = received_size / sending_time;
	bandwidth_estimate_ =
	std::min<DataRate>(bandwidth_estimate_ * 0.5, receiving_rate);
	if (mode_ == Mode::kSlowStart)
	mode_ = Mode::kOnlineLearning;
	}
	if (mode_ == Mode::kStartup &&
	msg.send_time - start_time_ >= kStartupDuration) {
	DataSize received_size = DataSize::Zero();
	for (size_t i = 1; i < last_received_packets_.size(); ++i) {
	received_size += last_received_packets_[i].sent_packet.size;
	}
	TimeDelta sending_time = TimeDelta::Zero();
	if (last_received_packets_.size() > 0)
	sending_time = last_received_packets_.back().receive_time -
	last_received_packets_.front().receive_time;
	DataRate receiving_rate = bandwidth_estimate_;
	if (sending_time > TimeDelta::Zero())
	receiving_rate = received_size / sending_time;
	bandwidth_estimate_ = receiving_rate;
	monitor_intervals_.clear();
	mode_ = Mode::kSlowStart;
	monitor_intervals_duration_ = ComputeMonitorIntervalsDuration();
	monitor_intervals_bitrates_ = {bandwidth_estimate_};
	monitor_intervals_.emplace_back(bandwidth_estimate_, msg.send_time,
	monitor_intervals_duration_);
	bandwidth_estimate_ = bandwidth_estimate_ * (1 / kSlowStartModeIncrease);
	complete_feedback_monitor_interval_number_ = 0;
	return CreateRateUpdate(msg.send_time);
	}
	if (IsFeedbackCollectionDone() \|\| IsTimeoutExpired(msg.send_time)) {
	// Creating new monitor intervals.
	monitor_intervals_.clear();
	monitor_interval_timeout_ =
	rtt_tracker_.GetRtt() * monitor_interval_timeout_ratio_;
	monitor_intervals_duration_ = ComputeMonitorIntervalsDuration();
	complete_feedback_monitor_interval_number_ = 0;
	// Compute bitrates and start first monitor interval.
	if (mode_ == Mode::kSlowStart) {
	monitor_intervals_bitrates_ = {kSlowStartModeIncrease *
	bandwidth_estimate_};
	monitor_intervals_.emplace_back(
	kSlowStartModeIncrease * bandwidth_estimate_, msg.send_time,
	monitor_intervals_duration_);
	} else {
	RTC_DCHECK(mode_ == Mode::kOnlineLearning \|\| mode_ == Mode::kDoubleCheck);
	monitor_intervals_.clear();
	int64_t sign = 2 * (random_generator_.Rand(0, 1) % 2) - 1;
	RTC_DCHECK_GE(sign, -1);
	RTC_DCHECK_LE(sign, 1);
	if (bandwidth_estimate_ >= kMinRateHaveMultiplicativeRateChange) {
	monitor_intervals_bitrates_ = {
	bandwidth_estimate_ * (1 + sign * sampling_step_),
	bandwidth_estimate_ * (1 - sign * sampling_step_)};
	} else {
	monitor_intervals_bitrates_ = {
	DataRate::BitsPerSec(std::max<double>(
	bandwidth_estimate_.bps() + sign * kMinRateChangeBps, 0)),
	DataRate::BitsPerSec(std::max<double>(
	bandwidth_estimate_.bps() - sign * kMinRateChangeBps, 0))};
	}
	monitor_intervals_.emplace_back(monitor_intervals_bitrates_[0],
	msg.send_time,
	monitor_intervals_duration_);
	}
	}
	return CreateRateUpdate(msg.send_time);
	}

	TimeDelta PccNetworkController::ComputeMonitorIntervalsDuration() const {
	TimeDelta monitor_intervals_duration = TimeDelta::Zero();
	if (monitor_interval_length_strategy_ ==
	MonitorIntervalLengthStrategy::kAdaptive) {
	monitor_intervals_duration = std::max(
	rtt_tracker_.GetRtt() * monitor_interval_duration_ratio_,
	smoothed_packets_sending_interval_ * min_packets_number_per_interval_);
	} else {
	RTC_DCHECK(monitor_interval_length_strategy_ ==
	MonitorIntervalLengthStrategy::kFixed);
	monitor_intervals_duration =
	smoothed_packets_sending_interval_ * min_packets_number_per_interval_;
	}
	monitor_intervals_duration =
	std::max(kMinDurationOfMonitorInterval, monitor_intervals_duration);
	return monitor_intervals_duration;
	}

	bool PccNetworkController::IsTimeoutExpired(Timestamp current_time) const {
	if (complete_feedback_monitor_interval_number_ >= monitor_intervals_.size()) {
	return false;
	}
	return current_time -
	monitor_intervals_[complete_feedback_monitor_interval_number_]
	.GetEndTime() >=
	monitor_interval_timeout_;
	}

	bool PccNetworkController::IsFeedbackCollectionDone() const {
	return complete_feedback_monitor_interval_number_ >=
	monitor_intervals_bitrates_.size();
	}

	NetworkControlUpdate PccNetworkController::OnTransportPacketsFeedback(
	TransportPacketsFeedback msg) {
	if (msg.packet_feedbacks.empty())
	return NetworkControlUpdate();
	// Save packets to last_received_packets_ array.
	for (const PacketResult& packet_result : msg.ReceivedWithSendInfo()) {
	last_received_packets_.push_back(packet_result);
	}
	while (last_received_packets_.size() > kNumberOfPacketsToKeep) {
	last_received_packets_.pop_front();
	}
	rtt_tracker_.OnPacketsFeedback(msg.PacketsWithFeedback(), msg.feedback_time);
	// Skip rate update in case when online learning mode just started, but
	// corresponding monitor intervals were not started yet.
	if (mode_ == Mode::kOnlineLearning &&
	monitor_intervals_bitrates_.size() < 2) {
	return NetworkControlUpdate();
	}
	if (!IsFeedbackCollectionDone() && !monitor_intervals_.empty()) {
	while (complete_feedback_monitor_interval_number_ <
	monitor_intervals_.size()) {
	monitor_intervals_[complete_feedback_monitor_interval_number_]
	.OnPacketsFeedback(msg.PacketsWithFeedback());
	if (!monitor_intervals_[complete_feedback_monitor_interval_number_]
	.IsFeedbackCollectionDone())
	break;
	++complete_feedback_monitor_interval_number_;
	}
	}
	if (IsFeedbackCollectionDone()) {
	if (mode_ == Mode::kDoubleCheck) {
	mode_ = Mode::kOnlineLearning;
	} else if (NeedDoubleCheckMeasurments()) {
	mode_ = Mode::kDoubleCheck;
	}
	if (mode_ != Mode::kDoubleCheck)
	UpdateSendingRateAndMode();
	}
	return NetworkControlUpdate();
	}

	bool PccNetworkController::NeedDoubleCheckMeasurments() const {
	if (mode_ == Mode::kSlowStart) {
	return false;
	}
	double first_loss_rate = monitor_intervals_[0].GetLossRate();
	double second_loss_rate = monitor_intervals_[1].GetLossRate();
	DataRate first_bitrate = monitor_intervals_[0].GetTargetSendingRate();
	DataRate second_bitrate = monitor_intervals_[1].GetTargetSendingRate();
	if ((first_bitrate.bps() - second_bitrate.bps()) *
	(first_loss_rate - second_loss_rate) <
	0) {
	return true;
	}
	return false;
	}

	void PccNetworkController::UpdateSendingRateAndMode() {
	if (monitor_intervals_.empty() \|\| !IsFeedbackCollectionDone()) {
	return;
	}
	if (mode_ == Mode::kSlowStart) {
	DataRate old_bandwidth_estimate = bandwidth_estimate_;
	bandwidth_estimate_ =
	bitrate_controller_
	.ComputeRateUpdateForSlowStartMode(monitor_intervals_[0])
	.value_or(bandwidth_estimate_);
	if (bandwidth_estimate_ <= old_bandwidth_estimate)
	mode_ = Mode::kOnlineLearning;
	} else {
	RTC_DCHECK(mode_ == Mode::kOnlineLearning);
	bandwidth_estimate_ =
	bitrate_controller_.ComputeRateUpdateForOnlineLearningMode(
	monitor_intervals_, bandwidth_estimate_);
	}
	}

	NetworkControlUpdate PccNetworkController::OnNetworkAvailability(
	NetworkAvailability msg) {
	return NetworkControlUpdate();
	}

	NetworkControlUpdate PccNetworkController::OnNetworkRouteChange(
	NetworkRouteChange msg) {
	return NetworkControlUpdate();
	}

	NetworkControlUpdate PccNetworkController::OnProcessInterval(
	ProcessInterval msg) {
	return CreateRateUpdate(msg.at_time);
	}

	NetworkControlUpdate PccNetworkController::OnTargetRateConstraints(
	TargetRateConstraints msg) {
	return NetworkControlUpdate();
	}

	NetworkControlUpdate PccNetworkController::OnRemoteBitrateReport(
	RemoteBitrateReport) {
	return NetworkControlUpdate();
	}

	NetworkControlUpdate PccNetworkController::OnRoundTripTimeUpdate(
	RoundTripTimeUpdate) {
	return NetworkControlUpdate();
	}

	NetworkControlUpdate PccNetworkController::OnTransportLossReport(
	TransportLossReport) {
	return NetworkControlUpdate();
	}

	NetworkControlUpdate PccNetworkController::OnStreamsConfig(StreamsConfig msg) {
	return NetworkControlUpdate();
	}

	NetworkControlUpdate PccNetworkController::OnReceivedPacket(
	ReceivedPacket msg) {
	return NetworkControlUpdate();
	}

	NetworkControlUpdate PccNetworkController::OnNetworkStateEstimate(
	NetworkStateEstimate msg) {
	return NetworkControlUpdate();
	}

	} // namespace pcc
	} // namespace webrtc