webrtc/modules/remote_bitrate_estimator/test/bwe.cc - src - Git at Google

 /*
  *  Copyright (c) 2015 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/remote_bitrate_estimator/test/bwe.h"

 #include <limits>

 #include "webrtc/base/common.h"
 #include "webrtc/base/constructormagic.h"
 #include "webrtc/modules/remote_bitrate_estimator/test/estimators/nada.h"
 #include "webrtc/modules/remote_bitrate_estimator/test/estimators/remb.h"
 #include "webrtc/modules/remote_bitrate_estimator/test/estimators/send_side.h"
 #include "webrtc/modules/remote_bitrate_estimator/test/estimators/tcp.h"

 namespace webrtc {
 namespace testing {
 namespace bwe {

 // With the assumption that packet loss is lower than 97%, the max gap
 // between elements in the set is lower than 0x8000, hence we have a
 // total order in the set. For (x,y,z) subset of the LinkedSet,
 // (x<=y and y<=z) ==> x<=z so the set can be sorted.
 const int kSetCapacity = 1000;

 BweReceiver::BweReceiver(int flow_id)
     : flow_id_(flow_id),
       received_packets_(kSetCapacity),
       rate_counter_(),
       loss_account_() {
 }

 BweReceiver::BweReceiver(int flow_id, int64_t window_size_ms)
     : flow_id_(flow_id),
       received_packets_(kSetCapacity),
       rate_counter_(window_size_ms),
       loss_account_() {
 }

 void BweReceiver::ReceivePacket(int64_t arrival_time_ms,
                                 const MediaPacket& media_packet) {
   if (received_packets_.size() == kSetCapacity) {
     RelieveSetAndUpdateLoss();
   }

   received_packets_.Insert(media_packet.sequence_number(),
                            media_packet.send_time_ms(), arrival_time_ms,
                            media_packet.payload_size());

   rate_counter_.UpdateRates(media_packet.send_time_ms() * 1000,
                             static_cast<uint32_t>(media_packet.payload_size()));
 }

 class NullBweSender : public BweSender {
  public:
   NullBweSender() {}
   virtual ~NullBweSender() {}

   int GetFeedbackIntervalMs() const override { return 1000; }
   void GiveFeedback(const FeedbackPacket& feedback) override {}
   void OnPacketsSent(const Packets& packets) override {}
   int64_t TimeUntilNextProcess() override {
     return std::numeric_limits<int64_t>::max();
   }
   void Process() override {}

  private:
   RTC_DISALLOW_COPY_AND_ASSIGN(NullBweSender);
 };

 int64_t GetAbsSendTimeInMs(uint32_t abs_send_time) {
   const int kInterArrivalShift = 26;
   const int kAbsSendTimeInterArrivalUpshift = 8;
   const double kTimestampToMs =
       1000.0 / static_cast<double>(1 << kInterArrivalShift);
   uint32_t timestamp = abs_send_time << kAbsSendTimeInterArrivalUpshift;
   return static_cast<int64_t>(timestamp) * kTimestampToMs;
 }

 BweSender* CreateBweSender(BandwidthEstimatorType estimator,
                            int kbps,
                            BitrateObserver* observer,
                            Clock* clock) {
   switch (estimator) {
     case kRembEstimator:
       return new RembBweSender(kbps, observer, clock);
     case kFullSendSideEstimator:
       return new FullBweSender(kbps, observer, clock);
     case kNadaEstimator:
       return new NadaBweSender(kbps, observer, clock);
     case kTcpEstimator:
       FALLTHROUGH();
     case kNullEstimator:
       return new NullBweSender();
   }
   assert(false);
   return NULL;
 }

 BweReceiver* CreateBweReceiver(BandwidthEstimatorType type,
                                int flow_id,
                                bool plot) {
   switch (type) {
     case kRembEstimator:
       return new RembReceiver(flow_id, plot);
     case kFullSendSideEstimator:
       return new SendSideBweReceiver(flow_id);
     case kNadaEstimator:
       return new NadaBweReceiver(flow_id);
     case kTcpEstimator:
       return new TcpBweReceiver(flow_id);
     case kNullEstimator:
       return new BweReceiver(flow_id);
   }
   assert(false);
   return NULL;
 }

 // Take into account all LinkedSet content.
 void BweReceiver::UpdateLoss() {
   loss_account_.Add(LinkedSetPacketLossRatio());
 }

 // Preserve 10% latest packets and update packet loss based on the oldest
 // 90%, that will be removed.
 void BweReceiver::RelieveSetAndUpdateLoss() {
   // Compute Loss for the whole LinkedSet and updates loss_account_.
   UpdateLoss();

   size_t num_preserved_elements = received_packets_.size() / 10;
   PacketNodeIt it = received_packets_.begin();
   std::advance(it, num_preserved_elements);

   while (it != received_packets_.end()) {
     received_packets_.Erase(it++);
   }

   // Compute Loss for the preserved elements
   loss_account_.Subtract(LinkedSetPacketLossRatio());
 }

 float BweReceiver::GlobalReceiverPacketLossRatio() {
   UpdateLoss();
   return loss_account_.LossRatio();
 }

 // This function considers at most kSetCapacity = 1000 packets.
 LossAccount BweReceiver::LinkedSetPacketLossRatio() {
   if (received_packets_.empty()) {
     return LossAccount();
   }

   uint16_t oldest_seq_num = received_packets_.OldestSeqNumber();
   uint16_t newest_seq_num = received_packets_.NewestSeqNumber();

   size_t set_total_packets =
       static_cast<uint16_t>(newest_seq_num - oldest_seq_num + 1);

   size_t set_received_packets = received_packets_.size();
   size_t set_lost_packets = set_total_packets - set_received_packets;

   return LossAccount(set_total_packets, set_lost_packets);
 }

 uint32_t BweReceiver::RecentKbps() const {
   return (rate_counter_.bits_per_second() + 500) / 1000;
 }

 // Go through a fixed time window of most recent packets received and
 // counts packets missing to obtain the packet loss ratio. If an unordered
 // packet falls out of the timewindow it will be counted as missing.
 // E.g.: for a timewindow covering 5 packets of the following arrival sequence
 // {10 7 9 5 6} 8 3 2 4 1, the output will be 1/6 (#8 is considered as missing).
 float BweReceiver::RecentPacketLossRatio() {
   if (received_packets_.empty()) {
     return 0.0f;
   }
   int number_packets_received = 0;

   PacketNodeIt node_it = received_packets_.begin();  // Latest.

   // Lowest timestamp limit, oldest one that should be checked.
   int64_t time_limit_ms = (*node_it)->arrival_time_ms - kPacketLossTimeWindowMs;
   // Oldest and newest values found within the given time window.
   uint16_t oldest_seq_num = (*node_it)->sequence_number;
   uint16_t newest_seq_num = oldest_seq_num;

   while (node_it != received_packets_.end()) {
     if ((*node_it)->arrival_time_ms < time_limit_ms) {
       break;
     }
     uint16_t seq_num = (*node_it)->sequence_number;
     if (IsNewerSequenceNumber(seq_num, newest_seq_num)) {
       newest_seq_num = seq_num;
     }
     if (IsNewerSequenceNumber(oldest_seq_num, seq_num)) {
       oldest_seq_num = seq_num;
     }
     ++node_it;
     ++number_packets_received;
   }
   // Interval width between oldest and newest sequence number.
   // There was an overflow if newest_seq_num < oldest_seq_num.
   int gap = static_cast<uint16_t>(newest_seq_num - oldest_seq_num + 1);

   return static_cast<float>(gap - number_packets_received) / gap;
 }

 LinkedSet::~LinkedSet() {
   while (!empty())
     RemoveTail();
 }

 void LinkedSet::Insert(uint16_t sequence_number,
                        int64_t send_time_ms,
                        int64_t arrival_time_ms,
                        size_t payload_size) {
   auto it = map_.find(sequence_number);
   if (it != map_.end()) {
     PacketNodeIt node_it = it->second;
     PacketIdentifierNode* node = *node_it;
     node->arrival_time_ms = arrival_time_ms;
     if (node_it != list_.begin()) {
       list_.erase(node_it);
       list_.push_front(node);
       map_[sequence_number] = list_.begin();
     }
   } else {
     if (size() == capacity_) {
       RemoveTail();
     }
     UpdateHead(new PacketIdentifierNode(sequence_number, send_time_ms,
                                         arrival_time_ms, payload_size));
   }
 }

 void LinkedSet::Insert(PacketIdentifierNode packet_identifier) {
   Insert(packet_identifier.sequence_number, packet_identifier.send_time_ms,
          packet_identifier.arrival_time_ms, packet_identifier.payload_size);
 }

 void LinkedSet::RemoveTail() {
   map_.erase(list_.back()->sequence_number);
   delete list_.back();
   list_.pop_back();
 }
 void LinkedSet::UpdateHead(PacketIdentifierNode* new_head) {
   list_.push_front(new_head);
   map_[new_head->sequence_number] = list_.begin();
 }

 void LinkedSet::Erase(PacketNodeIt node_it) {
   map_.erase((*node_it)->sequence_number);
   delete (*node_it);
   list_.erase(node_it);
 }

 void LossAccount::Add(LossAccount rhs) {
   num_total += rhs.num_total;
   num_lost += rhs.num_lost;
 }
 void LossAccount::Subtract(LossAccount rhs) {
   num_total -= rhs.num_total;
   num_lost -= rhs.num_lost;
 }

 float LossAccount::LossRatio() {
   if (num_total == 0)
     return 0.0f;
   return static_cast<float>(num_lost) / num_total;
 }

 }  // namespace bwe
 }  // namespace testing
 }  // namespace webrtc
	/*
	* Copyright (c) 2015 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/remote_bitrate_estimator/test/bwe.h"

	#include <limits>

	#include "webrtc/base/common.h"
	#include "webrtc/base/constructormagic.h"
	#include "webrtc/modules/remote_bitrate_estimator/test/estimators/nada.h"
	#include "webrtc/modules/remote_bitrate_estimator/test/estimators/remb.h"
	#include "webrtc/modules/remote_bitrate_estimator/test/estimators/send_side.h"
	#include "webrtc/modules/remote_bitrate_estimator/test/estimators/tcp.h"

	namespace webrtc {
	namespace testing {
	namespace bwe {

	// With the assumption that packet loss is lower than 97%, the max gap
	// between elements in the set is lower than 0x8000, hence we have a
	// total order in the set. For (x,y,z) subset of the LinkedSet,
	// (x<=y and y<=z) ==> x<=z so the set can be sorted.
	const int kSetCapacity = 1000;

	BweReceiver::BweReceiver(int flow_id)
	: flow_id_(flow_id),
	received_packets_(kSetCapacity),
	rate_counter_(),
	loss_account_() {
	}

	BweReceiver::BweReceiver(int flow_id, int64_t window_size_ms)
	: flow_id_(flow_id),
	received_packets_(kSetCapacity),
	rate_counter_(window_size_ms),
	loss_account_() {
	}

	void BweReceiver::ReceivePacket(int64_t arrival_time_ms,
	const MediaPacket& media_packet) {
	if (received_packets_.size() == kSetCapacity) {
	RelieveSetAndUpdateLoss();
	}

	received_packets_.Insert(media_packet.sequence_number(),
	media_packet.send_time_ms(), arrival_time_ms,
	media_packet.payload_size());

	rate_counter_.UpdateRates(media_packet.send_time_ms() * 1000,
	static_cast<uint32_t>(media_packet.payload_size()));
	}

	class NullBweSender : public BweSender {
	public:
	NullBweSender() {}
	virtual ~NullBweSender() {}

	int GetFeedbackIntervalMs() const override { return 1000; }
	void GiveFeedback(const FeedbackPacket& feedback) override {}
	void OnPacketsSent(const Packets& packets) override {}
	int64_t TimeUntilNextProcess() override {
	return std::numeric_limits<int64_t>::max();
	}
	void Process() override {}

	private:
	RTC_DISALLOW_COPY_AND_ASSIGN(NullBweSender);
	};

	int64_t GetAbsSendTimeInMs(uint32_t abs_send_time) {
	const int kInterArrivalShift = 26;
	const int kAbsSendTimeInterArrivalUpshift = 8;
	const double kTimestampToMs =
	1000.0 / static_cast<double>(1 << kInterArrivalShift);
	uint32_t timestamp = abs_send_time << kAbsSendTimeInterArrivalUpshift;
	return static_cast<int64_t>(timestamp) * kTimestampToMs;
	}

	BweSender* CreateBweSender(BandwidthEstimatorType estimator,
	int kbps,
	BitrateObserver* observer,
	Clock* clock) {
	switch (estimator) {
	case kRembEstimator:
	return new RembBweSender(kbps, observer, clock);
	case kFullSendSideEstimator:
	return new FullBweSender(kbps, observer, clock);
	case kNadaEstimator:
	return new NadaBweSender(kbps, observer, clock);
	case kTcpEstimator:
	FALLTHROUGH();
	case kNullEstimator:
	return new NullBweSender();
	}
	assert(false);
	return NULL;
	}

	BweReceiver* CreateBweReceiver(BandwidthEstimatorType type,
	int flow_id,
	bool plot) {
	switch (type) {
	case kRembEstimator:
	return new RembReceiver(flow_id, plot);
	case kFullSendSideEstimator:
	return new SendSideBweReceiver(flow_id);
	case kNadaEstimator:
	return new NadaBweReceiver(flow_id);
	case kTcpEstimator:
	return new TcpBweReceiver(flow_id);
	case kNullEstimator:
	return new BweReceiver(flow_id);
	}
	assert(false);
	return NULL;
	}

	// Take into account all LinkedSet content.
	void BweReceiver::UpdateLoss() {
	loss_account_.Add(LinkedSetPacketLossRatio());
	}

	// Preserve 10% latest packets and update packet loss based on the oldest
	// 90%, that will be removed.
	void BweReceiver::RelieveSetAndUpdateLoss() {
	// Compute Loss for the whole LinkedSet and updates loss_account_.
	UpdateLoss();

	size_t num_preserved_elements = received_packets_.size() / 10;
	PacketNodeIt it = received_packets_.begin();
	std::advance(it, num_preserved_elements);

	while (it != received_packets_.end()) {
	received_packets_.Erase(it++);
	}

	// Compute Loss for the preserved elements
	loss_account_.Subtract(LinkedSetPacketLossRatio());
	}

	float BweReceiver::GlobalReceiverPacketLossRatio() {
	UpdateLoss();
	return loss_account_.LossRatio();
	}

	// This function considers at most kSetCapacity = 1000 packets.
	LossAccount BweReceiver::LinkedSetPacketLossRatio() {
	if (received_packets_.empty()) {
	return LossAccount();
	}

	uint16_t oldest_seq_num = received_packets_.OldestSeqNumber();
	uint16_t newest_seq_num = received_packets_.NewestSeqNumber();

	size_t set_total_packets =
	static_cast<uint16_t>(newest_seq_num - oldest_seq_num + 1);

	size_t set_received_packets = received_packets_.size();
	size_t set_lost_packets = set_total_packets - set_received_packets;

	return LossAccount(set_total_packets, set_lost_packets);
	}

	uint32_t BweReceiver::RecentKbps() const {
	return (rate_counter_.bits_per_second() + 500) / 1000;
	}

	// Go through a fixed time window of most recent packets received and
	// counts packets missing to obtain the packet loss ratio. If an unordered
	// packet falls out of the timewindow it will be counted as missing.
	// E.g.: for a timewindow covering 5 packets of the following arrival sequence
	// {10 7 9 5 6} 8 3 2 4 1, the output will be 1/6 (#8 is considered as missing).
	float BweReceiver::RecentPacketLossRatio() {
	if (received_packets_.empty()) {
	return 0.0f;
	}
	int number_packets_received = 0;

	PacketNodeIt node_it = received_packets_.begin(); // Latest.

	// Lowest timestamp limit, oldest one that should be checked.
	int64_t time_limit_ms = (*node_it)->arrival_time_ms - kPacketLossTimeWindowMs;
	// Oldest and newest values found within the given time window.
	uint16_t oldest_seq_num = (*node_it)->sequence_number;
	uint16_t newest_seq_num = oldest_seq_num;

	while (node_it != received_packets_.end()) {
	if ((*node_it)->arrival_time_ms < time_limit_ms) {
	break;
	}
	uint16_t seq_num = (*node_it)->sequence_number;
	if (IsNewerSequenceNumber(seq_num, newest_seq_num)) {
	newest_seq_num = seq_num;
	}
	if (IsNewerSequenceNumber(oldest_seq_num, seq_num)) {
	oldest_seq_num = seq_num;
	}
	++node_it;
	++number_packets_received;
	}
	// Interval width between oldest and newest sequence number.
	// There was an overflow if newest_seq_num < oldest_seq_num.
	int gap = static_cast<uint16_t>(newest_seq_num - oldest_seq_num + 1);

	return static_cast<float>(gap - number_packets_received) / gap;
	}

	LinkedSet::~LinkedSet() {
	while (!empty())
	RemoveTail();
	}

	void LinkedSet::Insert(uint16_t sequence_number,
	int64_t send_time_ms,
	int64_t arrival_time_ms,
	size_t payload_size) {
	auto it = map_.find(sequence_number);
	if (it != map_.end()) {
	PacketNodeIt node_it = it->second;
	PacketIdentifierNode* node = *node_it;
	node->arrival_time_ms = arrival_time_ms;
	if (node_it != list_.begin()) {
	list_.erase(node_it);
	list_.push_front(node);
	map_[sequence_number] = list_.begin();
	}
	} else {
	if (size() == capacity_) {
	RemoveTail();
	}
	UpdateHead(new PacketIdentifierNode(sequence_number, send_time_ms,
	arrival_time_ms, payload_size));
	}
	}

	void LinkedSet::Insert(PacketIdentifierNode packet_identifier) {
	Insert(packet_identifier.sequence_number, packet_identifier.send_time_ms,
	packet_identifier.arrival_time_ms, packet_identifier.payload_size);
	}

	void LinkedSet::RemoveTail() {
	map_.erase(list_.back()->sequence_number);
	delete list_.back();
	list_.pop_back();
	}
	void LinkedSet::UpdateHead(PacketIdentifierNode* new_head) {
	list_.push_front(new_head);
	map_[new_head->sequence_number] = list_.begin();
	}

	void LinkedSet::Erase(PacketNodeIt node_it) {
	map_.erase((*node_it)->sequence_number);
	delete (*node_it);
	list_.erase(node_it);
	}

	void LossAccount::Add(LossAccount rhs) {
	num_total += rhs.num_total;
	num_lost += rhs.num_lost;
	}
	void LossAccount::Subtract(LossAccount rhs) {
	num_total -= rhs.num_total;
	num_lost -= rhs.num_lost;
	}

	float LossAccount::LossRatio() {
	if (num_total == 0)
	return 0.0f;
	return static_cast<float>(num_lost) / num_total;
	}

	} // namespace bwe
	} // namespace testing
	} // namespace webrtc