quic/core/congestion_control/bandwidth_sampler.cc - quiche.git - Git at Google

 // Copyright 2016 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "net/third_party/quiche/src/quic/core/congestion_control/bandwidth_sampler.h"

 #include <algorithm>

 #include "net/third_party/quiche/src/quic/platform/api/quic_bug_tracker.h"
 #include "net/third_party/quiche/src/quic/platform/api/quic_flag_utils.h"
 #include "net/third_party/quiche/src/quic/platform/api/quic_flags.h"
 #include "net/third_party/quiche/src/quic/platform/api/quic_logging.h"

 namespace quic {
 BandwidthSampler::BandwidthSampler()
     : total_bytes_sent_(0),
       total_bytes_acked_(0),
       total_bytes_lost_(0),
       total_bytes_sent_at_last_acked_packet_(0),
       last_acked_packet_sent_time_(QuicTime::Zero()),
       last_acked_packet_ack_time_(QuicTime::Zero()),
       is_app_limited_(false),
       connection_state_map_(),
       max_tracked_packets_(GetQuicFlag(FLAGS_quic_max_tracked_packet_count)) {}

 BandwidthSampler::~BandwidthSampler() {}

 void BandwidthSampler::OnPacketSent(
     QuicTime sent_time,
     QuicPacketNumber packet_number,
     QuicByteCount bytes,
     QuicByteCount bytes_in_flight,
     HasRetransmittableData has_retransmittable_data) {
   last_sent_packet_ = packet_number;

   if (has_retransmittable_data != HAS_RETRANSMITTABLE_DATA) {
     return;
   }

   total_bytes_sent_ += bytes;

   // If there are no packets in flight, the time at which the new transmission
   // opens can be treated as the A_0 point for the purpose of bandwidth
   // sampling. This underestimates bandwidth to some extent, and produces some
   // artificially low samples for most packets in flight, but it provides with
   // samples at important points where we would not have them otherwise, most
   // importantly at the beginning of the connection.
   if (bytes_in_flight == 0) {
     last_acked_packet_ack_time_ = sent_time;
     total_bytes_sent_at_last_acked_packet_ = total_bytes_sent_;

     // In this situation ack compression is not a concern, set send rate to
     // effectively infinite.
     last_acked_packet_sent_time_ = sent_time;
   }

   if (!connection_state_map_.IsEmpty() &&
       packet_number >
           connection_state_map_.last_packet() + max_tracked_packets_) {
     QUIC_BUG << "BandwidthSampler in-flight packet map has exceeded maximum "
                 "number "
                 "of tracked packets.";
   }

   bool success =
       connection_state_map_.Emplace(packet_number, sent_time, bytes, *this);
   QUIC_BUG_IF(!success) << "BandwidthSampler failed to insert the packet "
                            "into the map, most likely because it's already "
                            "in it.";
 }

 BandwidthSample BandwidthSampler::OnPacketAcknowledged(
     QuicTime ack_time,
     QuicPacketNumber packet_number) {
   ConnectionStateOnSentPacket* sent_packet_pointer =
       connection_state_map_.GetEntry(packet_number);
   if (sent_packet_pointer == nullptr) {
     // See the TODO below.
     return BandwidthSample();
   }
   BandwidthSample sample =
       OnPacketAcknowledgedInner(ack_time, packet_number, *sent_packet_pointer);
   connection_state_map_.Remove(packet_number);
   return sample;
 }

 BandwidthSample BandwidthSampler::OnPacketAcknowledgedInner(
     QuicTime ack_time,
     QuicPacketNumber packet_number,
     const ConnectionStateOnSentPacket& sent_packet) {
   total_bytes_acked_ += sent_packet.size;
   total_bytes_sent_at_last_acked_packet_ =
       sent_packet.send_time_state.total_bytes_sent;
   last_acked_packet_sent_time_ = sent_packet.sent_time;
   last_acked_packet_ack_time_ = ack_time;

   // Exit app-limited phase once a packet that was sent while the connection is
   // not app-limited is acknowledged.
   if (is_app_limited_ && packet_number > end_of_app_limited_phase_) {
     is_app_limited_ = false;
   }

   // There might have been no packets acknowledged at the moment when the
   // current packet was sent. In that case, there is no bandwidth sample to
   // make.
   if (sent_packet.last_acked_packet_sent_time == QuicTime::Zero()) {
     return BandwidthSample();
   }

   // Infinite rate indicates that the sampler is supposed to discard the
   // current send rate sample and use only the ack rate.
   QuicBandwidth send_rate = QuicBandwidth::Infinite();
   if (sent_packet.sent_time > sent_packet.last_acked_packet_sent_time) {
     send_rate = QuicBandwidth::FromBytesAndTimeDelta(
         sent_packet.send_time_state.total_bytes_sent -
             sent_packet.total_bytes_sent_at_last_acked_packet,
         sent_packet.sent_time - sent_packet.last_acked_packet_sent_time);
   }

   // During the slope calculation, ensure that ack time of the current packet is
   // always larger than the time of the previous packet, otherwise division by
   // zero or integer underflow can occur.
   if (ack_time <= sent_packet.last_acked_packet_ack_time) {
     // TODO(wub): Compare this code count before and after fixing clock jitter
     // issue.
     if (sent_packet.last_acked_packet_ack_time == sent_packet.sent_time) {
       // This is the 1st packet after quiescense.
       QUIC_CODE_COUNT_N(quic_prev_ack_time_larger_than_current_ack_time, 1, 2);
     } else {
       QUIC_CODE_COUNT_N(quic_prev_ack_time_larger_than_current_ack_time, 2, 2);
     }
     QUIC_LOG(ERROR) << "Time of the previously acked packet:"
                     << sent_packet.last_acked_packet_ack_time.ToDebuggingValue()
                     << " is larger than the ack time of the current packet:"
                     << ack_time.ToDebuggingValue();
     return BandwidthSample();
   }
   QuicBandwidth ack_rate = QuicBandwidth::FromBytesAndTimeDelta(
       total_bytes_acked_ - sent_packet.send_time_state.total_bytes_acked,
       ack_time - sent_packet.last_acked_packet_ack_time);

   BandwidthSample sample;
   sample.bandwidth = std::min(send_rate, ack_rate);
   // Note: this sample does not account for delayed acknowledgement time.  This
   // means that the RTT measurements here can be artificially high, especially
   // on low bandwidth connections.
   sample.rtt = ack_time - sent_packet.sent_time;
   SentPacketToSendTimeState(sent_packet, &sample.state_at_send);
   return sample;
 }

 SendTimeState BandwidthSampler::OnPacketLost(QuicPacketNumber packet_number) {
   // TODO(vasilvv): see the comment for the case of missing packets in
   // BandwidthSampler::OnPacketAcknowledged on why this does not raise a
   // QUIC_BUG when removal fails.
   SendTimeState send_time_state;
   send_time_state.is_valid = connection_state_map_.Remove(
       packet_number, [&](const ConnectionStateOnSentPacket& sent_packet) {
         total_bytes_lost_ += sent_packet.size;
         SentPacketToSendTimeState(sent_packet, &send_time_state);
       });
   return send_time_state;
 }

 void BandwidthSampler::SentPacketToSendTimeState(
     const ConnectionStateOnSentPacket& sent_packet,
     SendTimeState* send_time_state) const {
   *send_time_state = sent_packet.send_time_state;
   send_time_state->is_valid = true;
 }

 void BandwidthSampler::OnAppLimited() {
   is_app_limited_ = true;
   end_of_app_limited_phase_ = last_sent_packet_;
 }

 void BandwidthSampler::RemoveObsoletePackets(QuicPacketNumber least_unacked) {
   // A packet can become obsolete when it is removed from QuicUnackedPacketMap's
   // view of inflight before it is acked or marked as lost. For example, when
   // QuicSentPacketManager::RetransmitCryptoPackets retransmits a crypto packet,
   // the packet is removed from QuicUnackedPacketMap's inflight, but is not
   // marked as acked or lost in the BandwidthSampler.
   while (!connection_state_map_.IsEmpty() &&
          connection_state_map_.first_packet() < least_unacked) {
     connection_state_map_.Remove(
         connection_state_map_.first_packet(),
         [&](const ConnectionStateOnSentPacket& sent_packet) {
           // Obsoleted packets as either acked or lost but the sampler doesn't
           // know. We count them as acked here, since most packets are acked.
           total_bytes_acked_ += sent_packet.size;
         });
   }
 }

 QuicByteCount BandwidthSampler::total_bytes_sent() const {
   return total_bytes_sent_;
 }

 QuicByteCount BandwidthSampler::total_bytes_acked() const {
   return total_bytes_acked_;
 }

 QuicByteCount BandwidthSampler::total_bytes_lost() const {
   return total_bytes_lost_;
 }

 bool BandwidthSampler::is_app_limited() const {
   return is_app_limited_;
 }

 QuicPacketNumber BandwidthSampler::end_of_app_limited_phase() const {
   return end_of_app_limited_phase_;
 }

 }  // namespace quic
	// Copyright 2016 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "net/third_party/quiche/src/quic/core/congestion_control/bandwidth_sampler.h"

	#include <algorithm>

	#include "net/third_party/quiche/src/quic/platform/api/quic_bug_tracker.h"
	#include "net/third_party/quiche/src/quic/platform/api/quic_flag_utils.h"
	#include "net/third_party/quiche/src/quic/platform/api/quic_flags.h"
	#include "net/third_party/quiche/src/quic/platform/api/quic_logging.h"

	namespace quic {
	BandwidthSampler::BandwidthSampler()
	: total_bytes_sent_(0),
	total_bytes_acked_(0),
	total_bytes_lost_(0),
	total_bytes_sent_at_last_acked_packet_(0),
	last_acked_packet_sent_time_(QuicTime::Zero()),
	last_acked_packet_ack_time_(QuicTime::Zero()),
	is_app_limited_(false),
	connection_state_map_(),
	max_tracked_packets_(GetQuicFlag(FLAGS_quic_max_tracked_packet_count)) {}

	BandwidthSampler::~BandwidthSampler() {}

	void BandwidthSampler::OnPacketSent(
	QuicTime sent_time,
	QuicPacketNumber packet_number,
	QuicByteCount bytes,
	QuicByteCount bytes_in_flight,
	HasRetransmittableData has_retransmittable_data) {
	last_sent_packet_ = packet_number;

	if (has_retransmittable_data != HAS_RETRANSMITTABLE_DATA) {
	return;
	}

	total_bytes_sent_ += bytes;

	// If there are no packets in flight, the time at which the new transmission
	// opens can be treated as the A_0 point for the purpose of bandwidth
	// sampling. This underestimates bandwidth to some extent, and produces some
	// artificially low samples for most packets in flight, but it provides with
	// samples at important points where we would not have them otherwise, most
	// importantly at the beginning of the connection.
	if (bytes_in_flight == 0) {
	last_acked_packet_ack_time_ = sent_time;
	total_bytes_sent_at_last_acked_packet_ = total_bytes_sent_;

	// In this situation ack compression is not a concern, set send rate to
	// effectively infinite.
	last_acked_packet_sent_time_ = sent_time;
	}

	if (!connection_state_map_.IsEmpty() &&
	packet_number >
	connection_state_map_.last_packet() + max_tracked_packets_) {
	QUIC_BUG << "BandwidthSampler in-flight packet map has exceeded maximum "
	"number "
	"of tracked packets.";
	}

	bool success =
	connection_state_map_.Emplace(packet_number, sent_time, bytes, *this);
	QUIC_BUG_IF(!success) << "BandwidthSampler failed to insert the packet "
	"into the map, most likely because it's already "
	"in it.";
	}

	BandwidthSample BandwidthSampler::OnPacketAcknowledged(
	QuicTime ack_time,
	QuicPacketNumber packet_number) {
	ConnectionStateOnSentPacket* sent_packet_pointer =
	connection_state_map_.GetEntry(packet_number);
	if (sent_packet_pointer == nullptr) {
	// See the TODO below.
	return BandwidthSample();
	}
	BandwidthSample sample =
	OnPacketAcknowledgedInner(ack_time, packet_number, *sent_packet_pointer);
	connection_state_map_.Remove(packet_number);
	return sample;
	}

	BandwidthSample BandwidthSampler::OnPacketAcknowledgedInner(
	QuicTime ack_time,
	QuicPacketNumber packet_number,
	const ConnectionStateOnSentPacket& sent_packet) {
	total_bytes_acked_ += sent_packet.size;
	total_bytes_sent_at_last_acked_packet_ =
	sent_packet.send_time_state.total_bytes_sent;
	last_acked_packet_sent_time_ = sent_packet.sent_time;
	last_acked_packet_ack_time_ = ack_time;

	// Exit app-limited phase once a packet that was sent while the connection is
	// not app-limited is acknowledged.
	if (is_app_limited_ && packet_number > end_of_app_limited_phase_) {
	is_app_limited_ = false;
	}

	// There might have been no packets acknowledged at the moment when the
	// current packet was sent. In that case, there is no bandwidth sample to
	// make.
	if (sent_packet.last_acked_packet_sent_time == QuicTime::Zero()) {
	return BandwidthSample();
	}

	// Infinite rate indicates that the sampler is supposed to discard the
	// current send rate sample and use only the ack rate.
	QuicBandwidth send_rate = QuicBandwidth::Infinite();
	if (sent_packet.sent_time > sent_packet.last_acked_packet_sent_time) {
	send_rate = QuicBandwidth::FromBytesAndTimeDelta(
	sent_packet.send_time_state.total_bytes_sent -
	sent_packet.total_bytes_sent_at_last_acked_packet,
	sent_packet.sent_time - sent_packet.last_acked_packet_sent_time);
	}

	// During the slope calculation, ensure that ack time of the current packet is
	// always larger than the time of the previous packet, otherwise division by
	// zero or integer underflow can occur.
	if (ack_time <= sent_packet.last_acked_packet_ack_time) {
	// TODO(wub): Compare this code count before and after fixing clock jitter
	// issue.
	if (sent_packet.last_acked_packet_ack_time == sent_packet.sent_time) {
	// This is the 1st packet after quiescense.
	QUIC_CODE_COUNT_N(quic_prev_ack_time_larger_than_current_ack_time, 1, 2);
	} else {
	QUIC_CODE_COUNT_N(quic_prev_ack_time_larger_than_current_ack_time, 2, 2);
	}
	QUIC_LOG(ERROR) << "Time of the previously acked packet:"
	<< sent_packet.last_acked_packet_ack_time.ToDebuggingValue()
	<< " is larger than the ack time of the current packet:"
	<< ack_time.ToDebuggingValue();
	return BandwidthSample();
	}
	QuicBandwidth ack_rate = QuicBandwidth::FromBytesAndTimeDelta(
	total_bytes_acked_ - sent_packet.send_time_state.total_bytes_acked,
	ack_time - sent_packet.last_acked_packet_ack_time);

	BandwidthSample sample;
	sample.bandwidth = std::min(send_rate, ack_rate);
	// Note: this sample does not account for delayed acknowledgement time. This
	// means that the RTT measurements here can be artificially high, especially
	// on low bandwidth connections.
	sample.rtt = ack_time - sent_packet.sent_time;
	SentPacketToSendTimeState(sent_packet, &sample.state_at_send);
	return sample;
	}

	SendTimeState BandwidthSampler::OnPacketLost(QuicPacketNumber packet_number) {
	// TODO(vasilvv): see the comment for the case of missing packets in
	// BandwidthSampler::OnPacketAcknowledged on why this does not raise a
	// QUIC_BUG when removal fails.
	SendTimeState send_time_state;
	send_time_state.is_valid = connection_state_map_.Remove(
	packet_number, [&](const ConnectionStateOnSentPacket& sent_packet) {
	total_bytes_lost_ += sent_packet.size;
	SentPacketToSendTimeState(sent_packet, &send_time_state);
	});
	return send_time_state;
	}

	void BandwidthSampler::SentPacketToSendTimeState(
	const ConnectionStateOnSentPacket& sent_packet,
	SendTimeState* send_time_state) const {
	*send_time_state = sent_packet.send_time_state;
	send_time_state->is_valid = true;
	}

	void BandwidthSampler::OnAppLimited() {
	is_app_limited_ = true;
	end_of_app_limited_phase_ = last_sent_packet_;
	}

	void BandwidthSampler::RemoveObsoletePackets(QuicPacketNumber least_unacked) {
	// A packet can become obsolete when it is removed from QuicUnackedPacketMap's
	// view of inflight before it is acked or marked as lost. For example, when
	// QuicSentPacketManager::RetransmitCryptoPackets retransmits a crypto packet,
	// the packet is removed from QuicUnackedPacketMap's inflight, but is not
	// marked as acked or lost in the BandwidthSampler.
	while (!connection_state_map_.IsEmpty() &&
	connection_state_map_.first_packet() < least_unacked) {
	connection_state_map_.Remove(
	connection_state_map_.first_packet(),
	[&](const ConnectionStateOnSentPacket& sent_packet) {
	// Obsoleted packets as either acked or lost but the sampler doesn't
	// know. We count them as acked here, since most packets are acked.
	total_bytes_acked_ += sent_packet.size;
	});
	}
	}

	QuicByteCount BandwidthSampler::total_bytes_sent() const {
	return total_bytes_sent_;
	}

	QuicByteCount BandwidthSampler::total_bytes_acked() const {
	return total_bytes_acked_;
	}

	QuicByteCount BandwidthSampler::total_bytes_lost() const {
	return total_bytes_lost_;
	}

	bool BandwidthSampler::is_app_limited() const {
	return is_app_limited_;
	}

	QuicPacketNumber BandwidthSampler::end_of_app_limited_phase() const {
	return end_of_app_limited_phase_;
	}

	} // namespace quic