net/quic/congestion_control/pacing_sender.cc - platform/external/chromium_org - Git at Google

 // Copyright (c) 2013 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/quic/congestion_control/pacing_sender.h"

 namespace net {

 PacingSender::PacingSender(SendAlgorithmInterface* sender,
                            QuicTime::Delta alarm_granularity)
     : sender_(sender),
       alarm_granularity_(alarm_granularity),
       next_packet_send_time_(QuicTime::Zero()),
       was_last_send_delayed_(false),
       max_segment_size_(kDefaultMaxPacketSize) {
 }

 PacingSender::~PacingSender() {}

 void PacingSender::SetMaxPacketSize(QuicByteCount max_packet_size) {
   max_segment_size_ = max_packet_size;
   sender_->SetMaxPacketSize(max_packet_size);
 }

 void PacingSender::SetFromConfig(const QuicConfig& config, bool is_server) {
   sender_->SetFromConfig(config, is_server);
 }

 void PacingSender::OnIncomingQuicCongestionFeedbackFrame(
       const QuicCongestionFeedbackFrame& feedback,
       QuicTime feedback_receive_time,
       const SendAlgorithmInterface::SentPacketsMap& sent_packets) {
   sender_->OnIncomingQuicCongestionFeedbackFrame(
       feedback, feedback_receive_time, sent_packets);
 }

 void PacingSender::OnPacketAcked(
     QuicPacketSequenceNumber acked_sequence_number,
     QuicByteCount acked_bytes,
     QuicTime::Delta rtt) {
   sender_->OnPacketAcked(acked_sequence_number, acked_bytes, rtt);
 }

 void PacingSender::OnPacketLost(QuicPacketSequenceNumber sequence_number,
                                 QuicTime ack_receive_time) {
   sender_->OnPacketLost(sequence_number, ack_receive_time);
 }

 bool PacingSender::OnPacketSent(
     QuicTime sent_time,
     QuicPacketSequenceNumber sequence_number,
     QuicByteCount bytes,
     TransmissionType transmission_type,
     HasRetransmittableData has_retransmittable_data) {
   // Only pace data packets.
   if (has_retransmittable_data == HAS_RETRANSMITTABLE_DATA) {
     // The next packet should be sent as soon as the current packets has
     // been transferred.  We pace at twice the rate of the underlying
     // sender's bandwidth estimate to help ensure that pacing doesn't become
     // a bottleneck.
     const float kPacingAggression = 2;
     QuicTime::Delta delay =
         BandwidthEstimate().Scale(kPacingAggression).TransferTime(bytes);
     next_packet_send_time_ = next_packet_send_time_.Add(delay);
   }
   return sender_->OnPacketSent(sent_time, sequence_number, bytes,
                                transmission_type, has_retransmittable_data);
 }

 void PacingSender::OnRetransmissionTimeout() {
   sender_->OnRetransmissionTimeout();
 }

 void PacingSender::OnPacketAbandoned(QuicPacketSequenceNumber sequence_number,
                                      QuicByteCount abandoned_bytes) {
   sender_->OnPacketAbandoned(sequence_number, abandoned_bytes);
 }

 QuicTime::Delta PacingSender::TimeUntilSend(
       QuicTime now,
       TransmissionType transmission_type,
       HasRetransmittableData has_retransmittable_data,
       IsHandshake handshake) {
   QuicTime::Delta time_until_send =
       sender_->TimeUntilSend(now, transmission_type,
                              has_retransmittable_data, handshake);
   if (!time_until_send.IsZero()) {
     DCHECK(time_until_send.IsInfinite());
     // The underlying sender prevents sending.
     return time_until_send;
   }

   if (has_retransmittable_data == NO_RETRANSMITTABLE_DATA) {
     // Don't pace ACK packets, since they do not count against CWND and do not
     // cause CWND to grow.
     return QuicTime::Delta::Zero();
   }

   if (!was_last_send_delayed_ &&
       (!next_packet_send_time_.IsInitialized() ||
        now > next_packet_send_time_.Add(alarm_granularity_))) {
     // An alarm did not go off late, instead the application is "slow"
     // delivering data.  In this case, we restrict the amount of lost time
     // that we can make up for.
     next_packet_send_time_ = now.Subtract(alarm_granularity_);
   }

   // If the end of the epoch is far enough in the future, delay the send.
   if (next_packet_send_time_ > now.Add(alarm_granularity_)) {
     was_last_send_delayed_ = true;
     DVLOG(1) << "Delaying packet: "
              << next_packet_send_time_.Subtract(now).ToMicroseconds();
     return next_packet_send_time_.Subtract(now);
   }

   // Sent it immediately.  The epoch end will be adjusted in OnPacketSent.
   was_last_send_delayed_ = false;
   DVLOG(1) << "Sending packet now";
   return QuicTime::Delta::Zero();
 }

 QuicBandwidth PacingSender::BandwidthEstimate() const {
   return sender_->BandwidthEstimate();
 }

 QuicTime::Delta PacingSender::SmoothedRtt() const {
   return sender_->SmoothedRtt();
 }

 QuicTime::Delta PacingSender::RetransmissionDelay() const {
   return sender_->RetransmissionDelay();
 }

 QuicByteCount PacingSender::GetCongestionWindow() const {
   return sender_->GetCongestionWindow();
 }

 }  // namespace net
	// Copyright (c) 2013 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/quic/congestion_control/pacing_sender.h"

	namespace net {

	PacingSender::PacingSender(SendAlgorithmInterface* sender,
	QuicTime::Delta alarm_granularity)
	: sender_(sender),
	alarm_granularity_(alarm_granularity),
	next_packet_send_time_(QuicTime::Zero()),
	was_last_send_delayed_(false),
	max_segment_size_(kDefaultMaxPacketSize) {
	}

	PacingSender::~PacingSender() {}

	void PacingSender::SetMaxPacketSize(QuicByteCount max_packet_size) {
	max_segment_size_ = max_packet_size;
	sender_->SetMaxPacketSize(max_packet_size);
	}

	void PacingSender::SetFromConfig(const QuicConfig& config, bool is_server) {
	sender_->SetFromConfig(config, is_server);
	}

	void PacingSender::OnIncomingQuicCongestionFeedbackFrame(
	const QuicCongestionFeedbackFrame& feedback,
	QuicTime feedback_receive_time,
	const SendAlgorithmInterface::SentPacketsMap& sent_packets) {
	sender_->OnIncomingQuicCongestionFeedbackFrame(
	feedback, feedback_receive_time, sent_packets);
	}

	void PacingSender::OnPacketAcked(
	QuicPacketSequenceNumber acked_sequence_number,
	QuicByteCount acked_bytes,
	QuicTime::Delta rtt) {
	sender_->OnPacketAcked(acked_sequence_number, acked_bytes, rtt);
	}

	void PacingSender::OnPacketLost(QuicPacketSequenceNumber sequence_number,
	QuicTime ack_receive_time) {
	sender_->OnPacketLost(sequence_number, ack_receive_time);
	}

	bool PacingSender::OnPacketSent(
	QuicTime sent_time,
	QuicPacketSequenceNumber sequence_number,
	QuicByteCount bytes,
	TransmissionType transmission_type,
	HasRetransmittableData has_retransmittable_data) {
	// Only pace data packets.
	if (has_retransmittable_data == HAS_RETRANSMITTABLE_DATA) {
	// The next packet should be sent as soon as the current packets has
	// been transferred. We pace at twice the rate of the underlying
	// sender's bandwidth estimate to help ensure that pacing doesn't become
	// a bottleneck.
	const float kPacingAggression = 2;
	QuicTime::Delta delay =
	BandwidthEstimate().Scale(kPacingAggression).TransferTime(bytes);
	next_packet_send_time_ = next_packet_send_time_.Add(delay);
	}
	return sender_->OnPacketSent(sent_time, sequence_number, bytes,
	transmission_type, has_retransmittable_data);
	}

	void PacingSender::OnRetransmissionTimeout() {
	sender_->OnRetransmissionTimeout();
	}

	void PacingSender::OnPacketAbandoned(QuicPacketSequenceNumber sequence_number,
	QuicByteCount abandoned_bytes) {
	sender_->OnPacketAbandoned(sequence_number, abandoned_bytes);
	}

	QuicTime::Delta PacingSender::TimeUntilSend(
	QuicTime now,
	TransmissionType transmission_type,
	HasRetransmittableData has_retransmittable_data,
	IsHandshake handshake) {
	QuicTime::Delta time_until_send =
	sender_->TimeUntilSend(now, transmission_type,
	has_retransmittable_data, handshake);
	if (!time_until_send.IsZero()) {
	DCHECK(time_until_send.IsInfinite());
	// The underlying sender prevents sending.
	return time_until_send;
	}

	if (has_retransmittable_data == NO_RETRANSMITTABLE_DATA) {
	// Don't pace ACK packets, since they do not count against CWND and do not
	// cause CWND to grow.
	return QuicTime::Delta::Zero();
	}

	if (!was_last_send_delayed_ &&
	(!next_packet_send_time_.IsInitialized() \|\|
	now > next_packet_send_time_.Add(alarm_granularity_))) {
	// An alarm did not go off late, instead the application is "slow"
	// delivering data. In this case, we restrict the amount of lost time
	// that we can make up for.
	next_packet_send_time_ = now.Subtract(alarm_granularity_);
	}

	// If the end of the epoch is far enough in the future, delay the send.
	if (next_packet_send_time_ > now.Add(alarm_granularity_)) {
	was_last_send_delayed_ = true;
	DVLOG(1) << "Delaying packet: "
	<< next_packet_send_time_.Subtract(now).ToMicroseconds();
	return next_packet_send_time_.Subtract(now);
	}

	// Sent it immediately. The epoch end will be adjusted in OnPacketSent.
	was_last_send_delayed_ = false;
	DVLOG(1) << "Sending packet now";
	return QuicTime::Delta::Zero();
	}

	QuicBandwidth PacingSender::BandwidthEstimate() const {
	return sender_->BandwidthEstimate();
	}

	QuicTime::Delta PacingSender::SmoothedRtt() const {
	return sender_->SmoothedRtt();
	}

	QuicTime::Delta PacingSender::RetransmissionDelay() const {
	return sender_->RetransmissionDelay();
	}

	QuicByteCount PacingSender::GetCongestionWindow() const {
	return sender_->GetCongestionWindow();
	}

	} // namespace net