modules/congestion_controller/goog_cc/loss_based_bwe_v2.h - src - Git at Google

 /*
  *  Copyright 2021 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.
  */

 #ifndef MODULES_CONGESTION_CONTROLLER_GOOG_CC_LOSS_BASED_BWE_V2_H_
 #define MODULES_CONGESTION_CONTROLLER_GOOG_CC_LOSS_BASED_BWE_V2_H_

 #include <vector>

 #include "absl/types/optional.h"
 #include "api/array_view.h"
 #include "api/field_trials_view.h"
 #include "api/transport/network_types.h"
 #include "api/units/data_rate.h"
 #include "api/units/data_size.h"
 #include "api/units/time_delta.h"
 #include "api/units/timestamp.h"

 namespace webrtc {

 // State of the loss based estimate, which can be either increasing/decreasing
 // when network is loss limited, or equal to the delay based estimate.
 enum class LossBasedState {
   kIncreasing = 0,
   // TODO(bugs.webrtc.org/12707): Remove one of the increasing states once we
   // have decided if padding is usefull for ramping up when BWE is loss
   // limited.
   kIncreaseUsingPadding = 1,
   kDecreasing = 2,
   kDelayBasedEstimate = 3
 };

 class LossBasedBweV2 {
  public:
   struct Result {
     ~Result() = default;
     DataRate bandwidth_estimate = DataRate::Zero();
     // State is used by goog_cc, which later sends probe requests to probe
     // controller if state is kIncreasing.
     LossBasedState state = LossBasedState::kDelayBasedEstimate;
   };
   // Creates a disabled `LossBasedBweV2` if the
   // `key_value_config` is not valid.
   explicit LossBasedBweV2(const FieldTrialsView* key_value_config);

   LossBasedBweV2(const LossBasedBweV2&) = delete;
   LossBasedBweV2& operator=(const LossBasedBweV2&) = delete;

   ~LossBasedBweV2() = default;

   bool IsEnabled() const;
   // Returns true iff a BWE can be calculated, i.e., the estimator has been
   // initialized with a BWE and then has received enough `PacketResult`s.
   bool IsReady() const;

   // Returns true if loss based BWE is ready to be used in the start phase.
   bool ReadyToUseInStartPhase() const;

   // Returns true if loss based BWE can be used in the start phase.
   bool UseInStartPhase() const;

   // Returns `DataRate::PlusInfinity` if no BWE can be calculated.
   Result GetLossBasedResult() const;

   void SetAcknowledgedBitrate(DataRate acknowledged_bitrate);
   void SetMinMaxBitrate(DataRate min_bitrate, DataRate max_bitrate);
   void UpdateBandwidthEstimate(
       rtc::ArrayView<const PacketResult> packet_results,
       DataRate delay_based_estimate,
       bool in_alr);
   bool PaceAtLossBasedEstimate() const;

   // For unit testing only.
   void SetBandwidthEstimate(DataRate bandwidth_estimate);

  private:
   struct ChannelParameters {
     double inherent_loss = 0.0;
     DataRate loss_limited_bandwidth = DataRate::MinusInfinity();
   };

   struct Config {
     double bandwidth_rampup_upper_bound_factor = 0.0;
     double bandwidth_rampup_upper_bound_factor_in_hold = 0;
     double bandwidth_rampup_hold_threshold = 0;
     double rampup_acceleration_max_factor = 0.0;
     TimeDelta rampup_acceleration_maxout_time = TimeDelta::Zero();
     std::vector<double> candidate_factors;
     double higher_bandwidth_bias_factor = 0.0;
     double higher_log_bandwidth_bias_factor = 0.0;
     double inherent_loss_lower_bound = 0.0;
     double loss_threshold_of_high_bandwidth_preference = 0.0;
     double bandwidth_preference_smoothing_factor = 0.0;
     DataRate inherent_loss_upper_bound_bandwidth_balance =
         DataRate::MinusInfinity();
     double inherent_loss_upper_bound_offset = 0.0;
     double initial_inherent_loss_estimate = 0.0;
     int newton_iterations = 0;
     double newton_step_size = 0.0;
     bool append_acknowledged_rate_candidate = true;
     bool append_delay_based_estimate_candidate = false;
     bool append_upper_bound_candidate_in_alr = false;
     TimeDelta observation_duration_lower_bound = TimeDelta::Zero();
     int observation_window_size = 0;
     double sending_rate_smoothing_factor = 0.0;
     double instant_upper_bound_temporal_weight_factor = 0.0;
     DataRate instant_upper_bound_bandwidth_balance = DataRate::MinusInfinity();
     double instant_upper_bound_loss_offset = 0.0;
     double temporal_weight_factor = 0.0;
     double bandwidth_backoff_lower_bound_factor = 0.0;
     double max_increase_factor = 0.0;
     TimeDelta delayed_increase_window = TimeDelta::Zero();
     bool not_increase_if_inherent_loss_less_than_average_loss = false;
     bool not_use_acked_rate_in_alr = false;
     bool use_in_start_phase = false;
     int min_num_observations = 0;
     double lower_bound_by_acked_rate_factor = 0.0;
     double hold_duration_factor = 0.0;
     bool use_byte_loss_rate = false;
     TimeDelta padding_duration = TimeDelta::Zero();
     bool bound_best_candidate = false;
     bool pace_at_loss_based_estimate = false;
   };

   struct Derivatives {
     double first = 0.0;
     double second = 0.0;
   };

   struct Observation {
     bool IsInitialized() const { return id != -1; }

     int num_packets = 0;
     int num_lost_packets = 0;
     int num_received_packets = 0;
     DataRate sending_rate = DataRate::MinusInfinity();
     DataSize size = DataSize::Zero();
     DataSize lost_size = DataSize::Zero();
     int id = -1;
   };

   struct PartialObservation {
     int num_packets = 0;
     int num_lost_packets = 0;
     DataSize size = DataSize::Zero();
     DataSize lost_size = DataSize::Zero();
   };

   struct PaddingInfo {
     DataRate padding_rate = DataRate::MinusInfinity();
     Timestamp padding_timestamp = Timestamp::MinusInfinity();
   };

   struct HoldInfo {
     Timestamp timestamp = Timestamp::MinusInfinity();
     TimeDelta duration = TimeDelta::Zero();
     DataRate rate = DataRate::PlusInfinity();
   };

   static absl::optional<Config> CreateConfig(
       const FieldTrialsView* key_value_config);
   bool IsConfigValid() const;

   // Returns `0.0` if not enough loss statistics have been received.
   double GetAverageReportedLossRatio() const;
   double GetAverageReportedPacketLossRatio() const;
   double GetAverageReportedByteLossRatio() const;
   std::vector<ChannelParameters> GetCandidates(bool in_alr) const;
   DataRate GetCandidateBandwidthUpperBound() const;
   Derivatives GetDerivatives(const ChannelParameters& channel_parameters) const;
   double GetFeasibleInherentLoss(
       const ChannelParameters& channel_parameters) const;
   double GetInherentLossUpperBound(DataRate bandwidth) const;
   double AdjustBiasFactor(double loss_rate, double bias_factor) const;
   double GetHighBandwidthBias(DataRate bandwidth) const;
   double GetObjective(const ChannelParameters& channel_parameters) const;
   DataRate GetSendingRate(DataRate instantaneous_sending_rate) const;
   DataRate GetInstantUpperBound() const;
   void CalculateInstantUpperBound();
   DataRate GetInstantLowerBound() const;
   void CalculateInstantLowerBound();

   void CalculateTemporalWeights();
   void NewtonsMethodUpdate(ChannelParameters& channel_parameters) const;

   // Returns false if no observation was created.
   bool PushBackObservation(rtc::ArrayView<const PacketResult> packet_results);
   bool IsEstimateIncreasingWhenLossLimited(DataRate old_estimate,
                                            DataRate new_estimate);
   bool IsInLossLimitedState() const;
   bool CanKeepIncreasingState(DataRate estimate) const;

   absl::optional<DataRate> acknowledged_bitrate_;
   absl::optional<Config> config_;
   ChannelParameters current_best_estimate_;
   int num_observations_ = 0;
   std::vector<Observation> observations_;
   PartialObservation partial_observation_;
   Timestamp last_send_time_most_recent_observation_ = Timestamp::PlusInfinity();
   Timestamp last_time_estimate_reduced_ = Timestamp::MinusInfinity();
   absl::optional<DataRate> cached_instant_upper_bound_;
   absl::optional<DataRate> cached_instant_lower_bound_;
   std::vector<double> instant_upper_bound_temporal_weights_;
   std::vector<double> temporal_weights_;
   Timestamp recovering_after_loss_timestamp_ = Timestamp::MinusInfinity();
   DataRate bandwidth_limit_in_current_window_ = DataRate::PlusInfinity();
   DataRate min_bitrate_ = DataRate::KilobitsPerSec(1);
   DataRate max_bitrate_ = DataRate::PlusInfinity();
   DataRate delay_based_estimate_ = DataRate::PlusInfinity();
   LossBasedBweV2::Result loss_based_result_ = LossBasedBweV2::Result();
   HoldInfo last_hold_info_ = HoldInfo();
   PaddingInfo last_padding_info_ = PaddingInfo();
 };

 }  // namespace webrtc

 #endif  // MODULES_CONGESTION_CONTROLLER_GOOG_CC_LOSS_BASED_BWE_V2_H_
	/*
	* Copyright 2021 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.
	*/

	#ifndef MODULES_CONGESTION_CONTROLLER_GOOG_CC_LOSS_BASED_BWE_V2_H_
	#define MODULES_CONGESTION_CONTROLLER_GOOG_CC_LOSS_BASED_BWE_V2_H_

	#include <vector>

	#include "absl/types/optional.h"
	#include "api/array_view.h"
	#include "api/field_trials_view.h"
	#include "api/transport/network_types.h"
	#include "api/units/data_rate.h"
	#include "api/units/data_size.h"
	#include "api/units/time_delta.h"
	#include "api/units/timestamp.h"

	namespace webrtc {

	// State of the loss based estimate, which can be either increasing/decreasing
	// when network is loss limited, or equal to the delay based estimate.
	enum class LossBasedState {
	kIncreasing = 0,
	// TODO(bugs.webrtc.org/12707): Remove one of the increasing states once we
	// have decided if padding is usefull for ramping up when BWE is loss
	// limited.
	kIncreaseUsingPadding = 1,
	kDecreasing = 2,
	kDelayBasedEstimate = 3
	};

	class LossBasedBweV2 {
	public:
	struct Result {
	~Result() = default;
	DataRate bandwidth_estimate = DataRate::Zero();
	// State is used by goog_cc, which later sends probe requests to probe
	// controller if state is kIncreasing.
	LossBasedState state = LossBasedState::kDelayBasedEstimate;
	};
	// Creates a disabled `LossBasedBweV2` if the
	// `key_value_config` is not valid.
	explicit LossBasedBweV2(const FieldTrialsView* key_value_config);

	LossBasedBweV2(const LossBasedBweV2&) = delete;
	LossBasedBweV2& operator=(const LossBasedBweV2&) = delete;

	~LossBasedBweV2() = default;

	bool IsEnabled() const;
	// Returns true iff a BWE can be calculated, i.e., the estimator has been
	// initialized with a BWE and then has received enough `PacketResult`s.
	bool IsReady() const;

	// Returns true if loss based BWE is ready to be used in the start phase.
	bool ReadyToUseInStartPhase() const;

	// Returns true if loss based BWE can be used in the start phase.
	bool UseInStartPhase() const;

	// Returns `DataRate::PlusInfinity` if no BWE can be calculated.
	Result GetLossBasedResult() const;

	void SetAcknowledgedBitrate(DataRate acknowledged_bitrate);
	void SetMinMaxBitrate(DataRate min_bitrate, DataRate max_bitrate);
	void UpdateBandwidthEstimate(
	rtc::ArrayView<const PacketResult> packet_results,
	DataRate delay_based_estimate,
	bool in_alr);
	bool PaceAtLossBasedEstimate() const;

	// For unit testing only.
	void SetBandwidthEstimate(DataRate bandwidth_estimate);

	private:
	struct ChannelParameters {
	double inherent_loss = 0.0;
	DataRate loss_limited_bandwidth = DataRate::MinusInfinity();
	};

	struct Config {
	double bandwidth_rampup_upper_bound_factor = 0.0;
	double bandwidth_rampup_upper_bound_factor_in_hold = 0;
	double bandwidth_rampup_hold_threshold = 0;
	double rampup_acceleration_max_factor = 0.0;
	TimeDelta rampup_acceleration_maxout_time = TimeDelta::Zero();
	std::vector<double> candidate_factors;
	double higher_bandwidth_bias_factor = 0.0;
	double higher_log_bandwidth_bias_factor = 0.0;
	double inherent_loss_lower_bound = 0.0;
	double loss_threshold_of_high_bandwidth_preference = 0.0;
	double bandwidth_preference_smoothing_factor = 0.0;
	DataRate inherent_loss_upper_bound_bandwidth_balance =
	DataRate::MinusInfinity();
	double inherent_loss_upper_bound_offset = 0.0;
	double initial_inherent_loss_estimate = 0.0;
	int newton_iterations = 0;
	double newton_step_size = 0.0;
	bool append_acknowledged_rate_candidate = true;
	bool append_delay_based_estimate_candidate = false;
	bool append_upper_bound_candidate_in_alr = false;
	TimeDelta observation_duration_lower_bound = TimeDelta::Zero();
	int observation_window_size = 0;
	double sending_rate_smoothing_factor = 0.0;
	double instant_upper_bound_temporal_weight_factor = 0.0;
	DataRate instant_upper_bound_bandwidth_balance = DataRate::MinusInfinity();
	double instant_upper_bound_loss_offset = 0.0;
	double temporal_weight_factor = 0.0;
	double bandwidth_backoff_lower_bound_factor = 0.0;
	double max_increase_factor = 0.0;
	TimeDelta delayed_increase_window = TimeDelta::Zero();
	bool not_increase_if_inherent_loss_less_than_average_loss = false;
	bool not_use_acked_rate_in_alr = false;
	bool use_in_start_phase = false;
	int min_num_observations = 0;
	double lower_bound_by_acked_rate_factor = 0.0;
	double hold_duration_factor = 0.0;
	bool use_byte_loss_rate = false;
	TimeDelta padding_duration = TimeDelta::Zero();
	bool bound_best_candidate = false;
	bool pace_at_loss_based_estimate = false;
	};

	struct Derivatives {
	double first = 0.0;
	double second = 0.0;
	};

	struct Observation {
	bool IsInitialized() const { return id != -1; }

	int num_packets = 0;
	int num_lost_packets = 0;
	int num_received_packets = 0;
	DataRate sending_rate = DataRate::MinusInfinity();
	DataSize size = DataSize::Zero();
	DataSize lost_size = DataSize::Zero();
	int id = -1;
	};

	struct PartialObservation {
	int num_packets = 0;
	int num_lost_packets = 0;
	DataSize size = DataSize::Zero();
	DataSize lost_size = DataSize::Zero();
	};

	struct PaddingInfo {
	DataRate padding_rate = DataRate::MinusInfinity();
	Timestamp padding_timestamp = Timestamp::MinusInfinity();
	};

	struct HoldInfo {
	Timestamp timestamp = Timestamp::MinusInfinity();
	TimeDelta duration = TimeDelta::Zero();
	DataRate rate = DataRate::PlusInfinity();
	};

	static absl::optional<Config> CreateConfig(
	const FieldTrialsView* key_value_config);
	bool IsConfigValid() const;

	// Returns `0.0` if not enough loss statistics have been received.
	double GetAverageReportedLossRatio() const;
	double GetAverageReportedPacketLossRatio() const;
	double GetAverageReportedByteLossRatio() const;
	std::vector<ChannelParameters> GetCandidates(bool in_alr) const;
	DataRate GetCandidateBandwidthUpperBound() const;
	Derivatives GetDerivatives(const ChannelParameters& channel_parameters) const;
	double GetFeasibleInherentLoss(
	const ChannelParameters& channel_parameters) const;
	double GetInherentLossUpperBound(DataRate bandwidth) const;
	double AdjustBiasFactor(double loss_rate, double bias_factor) const;
	double GetHighBandwidthBias(DataRate bandwidth) const;
	double GetObjective(const ChannelParameters& channel_parameters) const;
	DataRate GetSendingRate(DataRate instantaneous_sending_rate) const;
	DataRate GetInstantUpperBound() const;
	void CalculateInstantUpperBound();
	DataRate GetInstantLowerBound() const;
	void CalculateInstantLowerBound();

	void CalculateTemporalWeights();
	void NewtonsMethodUpdate(ChannelParameters& channel_parameters) const;

	// Returns false if no observation was created.
	bool PushBackObservation(rtc::ArrayView<const PacketResult> packet_results);
	bool IsEstimateIncreasingWhenLossLimited(DataRate old_estimate,
	DataRate new_estimate);
	bool IsInLossLimitedState() const;
	bool CanKeepIncreasingState(DataRate estimate) const;

	absl::optional<DataRate> acknowledged_bitrate_;
	absl::optional<Config> config_;
	ChannelParameters current_best_estimate_;
	int num_observations_ = 0;
	std::vector<Observation> observations_;
	PartialObservation partial_observation_;
	Timestamp last_send_time_most_recent_observation_ = Timestamp::PlusInfinity();
	Timestamp last_time_estimate_reduced_ = Timestamp::MinusInfinity();
	absl::optional<DataRate> cached_instant_upper_bound_;
	absl::optional<DataRate> cached_instant_lower_bound_;
	std::vector<double> instant_upper_bound_temporal_weights_;
	std::vector<double> temporal_weights_;
	Timestamp recovering_after_loss_timestamp_ = Timestamp::MinusInfinity();
	DataRate bandwidth_limit_in_current_window_ = DataRate::PlusInfinity();
	DataRate min_bitrate_ = DataRate::KilobitsPerSec(1);
	DataRate max_bitrate_ = DataRate::PlusInfinity();
	DataRate delay_based_estimate_ = DataRate::PlusInfinity();
	LossBasedBweV2::Result loss_based_result_ = LossBasedBweV2::Result();
	HoldInfo last_hold_info_ = HoldInfo();
	PaddingInfo last_padding_info_ = PaddingInfo();
	};

	} // namespace webrtc

	#endif // MODULES_CONGESTION_CONTROLLER_GOOG_CC_LOSS_BASED_BWE_V2_H_