modules/congestion_controller/probe_bitrate_estimator.cc - src/webrtc - Git at Google

 /*
  *  Copyright (c) 2016 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 "webrtc/modules/congestion_controller/probe_bitrate_estimator.h"

 #include <algorithm>

 #include "webrtc/logging/rtc_event_log/rtc_event_log.h"
 #include "webrtc/rtc_base/checks.h"
 #include "webrtc/rtc_base/logging.h"

 namespace {
 // The minumum number of probes we need to receive feedback about in percent
 // in order to have a valid estimate.
 constexpr int kMinReceivedProbesPercent = 80;

 // The minumum number of bytes we need to receive feedback about in percent
 // in order to have a valid estimate.
 constexpr int kMinReceivedBytesPercent = 80;

 // The maximum |receive rate| / |send rate| ratio for a valid estimate.
 constexpr float kMaxValidRatio = 2.0f;

 // The minimum |receive rate| / |send rate| ratio assuming that the link is
 // not saturated, i.e. we assume that we will receive at least
 // kMinRatioForUnsaturatedLink * |send rate| if |send rate| is less than the
 // link capacity.
 constexpr float kMinRatioForUnsaturatedLink = 0.9f;

 // The target utilization of the link. If we know true link capacity
 // we'd like to send at 95% of that rate.
 constexpr float kTargetUtilizationFraction = 0.95f;

 // The maximum time period over which the cluster history is retained.
 // This is also the maximum time period beyond which a probing burst is not
 // expected to last.
 constexpr int kMaxClusterHistoryMs = 1000;

 // The maximum time interval between first and the last probe on a cluster
 // on the sender side as well as the receive side.
 constexpr int kMaxProbeIntervalMs = 1000;
 }  // namespace

 namespace webrtc {

 ProbeBitrateEstimator::ProbeBitrateEstimator(RtcEventLog* event_log)
     : event_log_(event_log) {}

 ProbeBitrateEstimator::~ProbeBitrateEstimator() = default;

 int ProbeBitrateEstimator::HandleProbeAndEstimateBitrate(
     const PacketFeedback& packet_feedback) {
   int cluster_id = packet_feedback.pacing_info.probe_cluster_id;
   RTC_DCHECK_NE(cluster_id, PacedPacketInfo::kNotAProbe);

   EraseOldClusters(packet_feedback.arrival_time_ms - kMaxClusterHistoryMs);

   int payload_size_bits = packet_feedback.payload_size * 8;
   AggregatedCluster* cluster = &clusters_[cluster_id];

   if (packet_feedback.send_time_ms < cluster->first_send_ms) {
     cluster->first_send_ms = packet_feedback.send_time_ms;
   }
   if (packet_feedback.send_time_ms > cluster->last_send_ms) {
     cluster->last_send_ms = packet_feedback.send_time_ms;
     cluster->size_last_send = payload_size_bits;
   }
   if (packet_feedback.arrival_time_ms < cluster->first_receive_ms) {
     cluster->first_receive_ms = packet_feedback.arrival_time_ms;
     cluster->size_first_receive = payload_size_bits;
   }
   if (packet_feedback.arrival_time_ms > cluster->last_receive_ms) {
     cluster->last_receive_ms = packet_feedback.arrival_time_ms;
   }
   cluster->size_total += payload_size_bits;
   cluster->num_probes += 1;

   RTC_DCHECK_GT(packet_feedback.pacing_info.probe_cluster_min_probes, 0);
   RTC_DCHECK_GT(packet_feedback.pacing_info.probe_cluster_min_bytes, 0);

   int min_probes = packet_feedback.pacing_info.probe_cluster_min_probes *
                    kMinReceivedProbesPercent / 100;
   int min_bytes = packet_feedback.pacing_info.probe_cluster_min_bytes *
                   kMinReceivedBytesPercent / 100;
   if (cluster->num_probes < min_probes || cluster->size_total < min_bytes * 8)
     return -1;

   float send_interval_ms = cluster->last_send_ms - cluster->first_send_ms;
   float receive_interval_ms =
       cluster->last_receive_ms - cluster->first_receive_ms;

   if (send_interval_ms <= 0 || send_interval_ms > kMaxProbeIntervalMs ||
       receive_interval_ms <= 0 || receive_interval_ms > kMaxProbeIntervalMs) {
     LOG(LS_INFO) << "Probing unsuccessful, invalid send/receive interval"
                  << " [cluster id: " << cluster_id
                  << "] [send interval: " << send_interval_ms << " ms]"
                  << " [receive interval: " << receive_interval_ms << " ms]";
     if (event_log_) {
       event_log_->LogProbeResultFailure(cluster_id,
                                         kInvalidSendReceiveInterval);
     }
     return -1;
   }
   // Since the |send_interval_ms| does not include the time it takes to actually
   // send the last packet the size of the last sent packet should not be
   // included when calculating the send bitrate.
   RTC_DCHECK_GT(cluster->size_total, cluster->size_last_send);
   float send_size = cluster->size_total - cluster->size_last_send;
   float send_bps = send_size / send_interval_ms * 1000;

   // Since the |receive_interval_ms| does not include the time it takes to
   // actually receive the first packet the size of the first received packet
   // should not be included when calculating the receive bitrate.
   RTC_DCHECK_GT(cluster->size_total, cluster->size_first_receive);
   float receive_size = cluster->size_total - cluster->size_first_receive;
   float receive_bps = receive_size / receive_interval_ms * 1000;

   float ratio = receive_bps / send_bps;
   if (ratio > kMaxValidRatio) {
     LOG(LS_INFO) << "Probing unsuccessful, receive/send ratio too high"
                  << " [cluster id: " << cluster_id << "] [send: " << send_size
                  << " bytes / " << send_interval_ms
                  << " ms = " << send_bps / 1000 << " kb/s]"
                  << " [receive: " << receive_size << " bytes / "
                  << receive_interval_ms << " ms = " << receive_bps / 1000
                  << " kb/s]"
                  << " [ratio: " << receive_bps / 1000 << " / "
                  << send_bps / 1000 << " = " << ratio << " > kMaxValidRatio ("
                  << kMaxValidRatio << ")]";
     if (event_log_)
       event_log_->LogProbeResultFailure(cluster_id, kInvalidSendReceiveRatio);
     return -1;
   }
   LOG(LS_INFO) << "Probing successful"
                << " [cluster id: " << cluster_id << "] [send: " << send_size
                << " bytes / " << send_interval_ms << " ms = " << send_bps / 1000
                << " kb/s]"
                << " [receive: " << receive_size << " bytes / "
                << receive_interval_ms << " ms = " << receive_bps / 1000
                << " kb/s]";

   float res = std::min(send_bps, receive_bps);
   // If we're receiving at significantly lower bitrate than we were sending at,
   // it suggests that we've found the true capacity of the link. In this case,
   // set the target bitrate slightly lower to not immediately overuse.
   if (receive_bps < kMinRatioForUnsaturatedLink * send_bps) {
     RTC_DCHECK_GT(send_bps, receive_bps);
     res = kTargetUtilizationFraction * receive_bps;
   }
   if (event_log_)
     event_log_->LogProbeResultSuccess(cluster_id, res);
   estimated_bitrate_bps_ = rtc::Optional<int>(res);
   return *estimated_bitrate_bps_;
 }

 rtc::Optional<int>
 ProbeBitrateEstimator::FetchAndResetLastEstimatedBitrateBps() {
   rtc::Optional<int> estimated_bitrate_bps = estimated_bitrate_bps_;
   estimated_bitrate_bps_.reset();
   return estimated_bitrate_bps;
 }

 void ProbeBitrateEstimator::EraseOldClusters(int64_t timestamp_ms) {
   for (auto it = clusters_.begin(); it != clusters_.end();) {
     if (it->second.last_receive_ms < timestamp_ms) {
       it = clusters_.erase(it);
     } else {
       ++it;
     }
   }
 }
 }  // namespace webrtc
	/*
	* Copyright (c) 2016 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 "webrtc/modules/congestion_controller/probe_bitrate_estimator.h"

	#include <algorithm>

	#include "webrtc/logging/rtc_event_log/rtc_event_log.h"
	#include "webrtc/rtc_base/checks.h"
	#include "webrtc/rtc_base/logging.h"

	namespace {
	// The minumum number of probes we need to receive feedback about in percent
	// in order to have a valid estimate.
	constexpr int kMinReceivedProbesPercent = 80;

	// The minumum number of bytes we need to receive feedback about in percent
	// in order to have a valid estimate.
	constexpr int kMinReceivedBytesPercent = 80;

	// The maximum \|receive rate\| / \|send rate\| ratio for a valid estimate.
	constexpr float kMaxValidRatio = 2.0f;

	// The minimum \|receive rate\| / \|send rate\| ratio assuming that the link is
	// not saturated, i.e. we assume that we will receive at least
	// kMinRatioForUnsaturatedLink * \|send rate\| if \|send rate\| is less than the
	// link capacity.
	constexpr float kMinRatioForUnsaturatedLink = 0.9f;

	// The target utilization of the link. If we know true link capacity
	// we'd like to send at 95% of that rate.
	constexpr float kTargetUtilizationFraction = 0.95f;

	// The maximum time period over which the cluster history is retained.
	// This is also the maximum time period beyond which a probing burst is not
	// expected to last.
	constexpr int kMaxClusterHistoryMs = 1000;

	// The maximum time interval between first and the last probe on a cluster
	// on the sender side as well as the receive side.
	constexpr int kMaxProbeIntervalMs = 1000;
	} // namespace

	namespace webrtc {

	ProbeBitrateEstimator::ProbeBitrateEstimator(RtcEventLog* event_log)
	: event_log_(event_log) {}

	ProbeBitrateEstimator::~ProbeBitrateEstimator() = default;

	int ProbeBitrateEstimator::HandleProbeAndEstimateBitrate(
	const PacketFeedback& packet_feedback) {
	int cluster_id = packet_feedback.pacing_info.probe_cluster_id;
	RTC_DCHECK_NE(cluster_id, PacedPacketInfo::kNotAProbe);

	EraseOldClusters(packet_feedback.arrival_time_ms - kMaxClusterHistoryMs);

	int payload_size_bits = packet_feedback.payload_size * 8;
	AggregatedCluster* cluster = &clusters_[cluster_id];

	if (packet_feedback.send_time_ms < cluster->first_send_ms) {
	cluster->first_send_ms = packet_feedback.send_time_ms;
	}
	if (packet_feedback.send_time_ms > cluster->last_send_ms) {
	cluster->last_send_ms = packet_feedback.send_time_ms;
	cluster->size_last_send = payload_size_bits;
	}
	if (packet_feedback.arrival_time_ms < cluster->first_receive_ms) {
	cluster->first_receive_ms = packet_feedback.arrival_time_ms;
	cluster->size_first_receive = payload_size_bits;
	}
	if (packet_feedback.arrival_time_ms > cluster->last_receive_ms) {
	cluster->last_receive_ms = packet_feedback.arrival_time_ms;
	}
	cluster->size_total += payload_size_bits;
	cluster->num_probes += 1;

	RTC_DCHECK_GT(packet_feedback.pacing_info.probe_cluster_min_probes, 0);
	RTC_DCHECK_GT(packet_feedback.pacing_info.probe_cluster_min_bytes, 0);

	int min_probes = packet_feedback.pacing_info.probe_cluster_min_probes *
	kMinReceivedProbesPercent / 100;
	int min_bytes = packet_feedback.pacing_info.probe_cluster_min_bytes *
	kMinReceivedBytesPercent / 100;
	if (cluster->num_probes < min_probes \|\| cluster->size_total < min_bytes * 8)
	return -1;

	float send_interval_ms = cluster->last_send_ms - cluster->first_send_ms;
	float receive_interval_ms =
	cluster->last_receive_ms - cluster->first_receive_ms;

	if (send_interval_ms <= 0 \|\| send_interval_ms > kMaxProbeIntervalMs \|\|
	receive_interval_ms <= 0 \|\| receive_interval_ms > kMaxProbeIntervalMs) {
	LOG(LS_INFO) << "Probing unsuccessful, invalid send/receive interval"
	<< " [cluster id: " << cluster_id
	<< "] [send interval: " << send_interval_ms << " ms]"
	<< " [receive interval: " << receive_interval_ms << " ms]";
	if (event_log_) {
	event_log_->LogProbeResultFailure(cluster_id,
	kInvalidSendReceiveInterval);
	}
	return -1;
	}
	// Since the \|send_interval_ms\| does not include the time it takes to actually
	// send the last packet the size of the last sent packet should not be
	// included when calculating the send bitrate.
	RTC_DCHECK_GT(cluster->size_total, cluster->size_last_send);
	float send_size = cluster->size_total - cluster->size_last_send;
	float send_bps = send_size / send_interval_ms * 1000;

	// Since the \|receive_interval_ms\| does not include the time it takes to
	// actually receive the first packet the size of the first received packet
	// should not be included when calculating the receive bitrate.
	RTC_DCHECK_GT(cluster->size_total, cluster->size_first_receive);
	float receive_size = cluster->size_total - cluster->size_first_receive;
	float receive_bps = receive_size / receive_interval_ms * 1000;

	float ratio = receive_bps / send_bps;
	if (ratio > kMaxValidRatio) {
	LOG(LS_INFO) << "Probing unsuccessful, receive/send ratio too high"
	<< " [cluster id: " << cluster_id << "] [send: " << send_size
	<< " bytes / " << send_interval_ms
	<< " ms = " << send_bps / 1000 << " kb/s]"
	<< " [receive: " << receive_size << " bytes / "
	<< receive_interval_ms << " ms = " << receive_bps / 1000
	<< " kb/s]"
	<< " [ratio: " << receive_bps / 1000 << " / "
	<< send_bps / 1000 << " = " << ratio << " > kMaxValidRatio ("
	<< kMaxValidRatio << ")]";
	if (event_log_)
	event_log_->LogProbeResultFailure(cluster_id, kInvalidSendReceiveRatio);
	return -1;
	}
	LOG(LS_INFO) << "Probing successful"
	<< " [cluster id: " << cluster_id << "] [send: " << send_size
	<< " bytes / " << send_interval_ms << " ms = " << send_bps / 1000
	<< " kb/s]"
	<< " [receive: " << receive_size << " bytes / "
	<< receive_interval_ms << " ms = " << receive_bps / 1000
	<< " kb/s]";

	float res = std::min(send_bps, receive_bps);
	// If we're receiving at significantly lower bitrate than we were sending at,
	// it suggests that we've found the true capacity of the link. In this case,
	// set the target bitrate slightly lower to not immediately overuse.
	if (receive_bps < kMinRatioForUnsaturatedLink * send_bps) {
	RTC_DCHECK_GT(send_bps, receive_bps);
	res = kTargetUtilizationFraction * receive_bps;
	}
	if (event_log_)
	event_log_->LogProbeResultSuccess(cluster_id, res);
	estimated_bitrate_bps_ = rtc::Optional<int>(res);
	return *estimated_bitrate_bps_;
	}

	rtc::Optional<int>
	ProbeBitrateEstimator::FetchAndResetLastEstimatedBitrateBps() {
	rtc::Optional<int> estimated_bitrate_bps = estimated_bitrate_bps_;
	estimated_bitrate_bps_.reset();
	return estimated_bitrate_bps;
	}

	void ProbeBitrateEstimator::EraseOldClusters(int64_t timestamp_ms) {
	for (auto it = clusters_.begin(); it != clusters_.end();) {
	if (it->second.last_receive_ms < timestamp_ms) {
	it = clusters_.erase(it);
	} else {
	++it;
	}
	}
	}
	} // namespace webrtc