blob: d3e9a826e102b9b1729951b23c5ca7748a93fe4c [file] [log] [blame]
// Copyright 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/third_party/quiche/src/quic/core/quic_sent_packet_manager.h"
#include <algorithm>
#include <cstddef>
#include <string>
#include "net/third_party/quiche/src/quic/core/congestion_control/general_loss_algorithm.h"
#include "net/third_party/quiche/src/quic/core/congestion_control/pacing_sender.h"
#include "net/third_party/quiche/src/quic/core/crypto/crypto_protocol.h"
#include "net/third_party/quiche/src/quic/core/frames/quic_ack_frequency_frame.h"
#include "net/third_party/quiche/src/quic/core/proto/cached_network_parameters_proto.h"
#include "net/third_party/quiche/src/quic/core/quic_connection_stats.h"
#include "net/third_party/quiche/src/quic/core/quic_constants.h"
#include "net/third_party/quiche/src/quic/core/quic_packet_number.h"
#include "net/third_party/quiche/src/quic/core/quic_transmission_info.h"
#include "net/third_party/quiche/src/quic/core/quic_types.h"
#include "net/third_party/quiche/src/quic/core/quic_utils.h"
#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"
#include "net/third_party/quiche/src/quic/platform/api/quic_map_util.h"
namespace quic {
namespace {
static const int64_t kDefaultRetransmissionTimeMs = 500;
static const int64_t kMaxRetransmissionTimeMs = 60000;
// Maximum number of exponential backoffs used for RTO timeouts.
static const size_t kMaxRetransmissions = 10;
// Maximum number of packets retransmitted upon an RTO.
static const size_t kMaxRetransmissionsOnTimeout = 2;
// The path degrading delay is the sum of this number of consecutive RTO delays.
const size_t kNumRetransmissionDelaysForPathDegradingDelay = 2;
// Ensure the handshake timer isnt't faster than 10ms.
// This limits the tenth retransmitted packet to 10s after the initial CHLO.
static const int64_t kMinHandshakeTimeoutMs = 10;
// Sends up to two tail loss probes before firing an RTO,
// per draft RFC draft-dukkipati-tcpm-tcp-loss-probe.
static const size_t kDefaultMaxTailLossProbes = 2;
// Returns true of retransmissions of the specified type should retransmit
// the frames directly (as opposed to resulting in a loss notification).
inline bool ShouldForceRetransmission(TransmissionType transmission_type) {
return transmission_type == HANDSHAKE_RETRANSMISSION ||
transmission_type == TLP_RETRANSMISSION ||
transmission_type == PROBING_RETRANSMISSION ||
transmission_type == RTO_RETRANSMISSION ||
transmission_type == PTO_RETRANSMISSION;
}
// If pacing rate is accurate, > 2 burst token is not likely to help first ACK
// to arrive earlier, and overly large burst token could cause incast packet
// losses.
static const uint32_t kConservativeUnpacedBurst = 2;
} // namespace
#define ENDPOINT \
(unacked_packets_.perspective() == Perspective::IS_SERVER ? "Server: " \
: "Client: ")
QuicSentPacketManager::QuicSentPacketManager(
Perspective perspective,
const QuicClock* clock,
QuicRandom* random,
QuicConnectionStats* stats,
CongestionControlType congestion_control_type)
: unacked_packets_(perspective),
clock_(clock),
random_(random),
stats_(stats),
debug_delegate_(nullptr),
network_change_visitor_(nullptr),
initial_congestion_window_(kInitialCongestionWindow),
loss_algorithm_(&uber_loss_algorithm_),
consecutive_rto_count_(0),
consecutive_tlp_count_(0),
consecutive_crypto_retransmission_count_(0),
pending_timer_transmission_count_(0),
max_tail_loss_probes_(kDefaultMaxTailLossProbes),
max_rto_packets_(kMaxRetransmissionsOnTimeout),
enable_half_rtt_tail_loss_probe_(false),
using_pacing_(false),
use_new_rto_(false),
conservative_handshake_retransmits_(false),
min_tlp_timeout_(
QuicTime::Delta::FromMilliseconds(kMinTailLossProbeTimeoutMs)),
min_rto_timeout_(
QuicTime::Delta::FromMilliseconds(kMinRetransmissionTimeMs)),
largest_mtu_acked_(0),
handshake_finished_(false),
peer_max_ack_delay_(
QuicTime::Delta::FromMilliseconds(kDefaultDelayedAckTimeMs)),
rtt_updated_(false),
acked_packets_iter_(last_ack_frame_.packets.rbegin()),
pto_enabled_(GetQuicReloadableFlag(quic_default_on_pto)),
max_probe_packets_per_pto_(2),
consecutive_pto_count_(0),
handshake_mode_disabled_(false),
skip_packet_number_for_pto_(false),
always_include_max_ack_delay_for_pto_timeout_(true),
pto_exponential_backoff_start_point_(0),
pto_rttvar_multiplier_(4),
num_tlp_timeout_ptos_(0),
handshake_packet_acked_(false),
zero_rtt_packet_acked_(false),
one_rtt_packet_acked_(false),
first_pto_srtt_multiplier_(0),
use_standard_deviation_for_pto_(false),
pto_multiplier_without_rtt_samples_(3),
num_ptos_for_path_degrading_(0),
ignore_pings_(false) {
SetSendAlgorithm(congestion_control_type);
if (pto_enabled_) {
QUIC_RELOADABLE_FLAG_COUNT_N(quic_default_on_pto, 1, 2);
// TODO(fayang): change the default values when deprecating
// quic_default_on_pto.
first_pto_srtt_multiplier_ = 1.5;
pto_rttvar_multiplier_ = 2;
}
}
QuicSentPacketManager::~QuicSentPacketManager() {}
void QuicSentPacketManager::SetFromConfig(const QuicConfig& config) {
const Perspective perspective = unacked_packets_.perspective();
if (config.HasReceivedInitialRoundTripTimeUs() &&
config.ReceivedInitialRoundTripTimeUs() > 0) {
if (!config.HasClientSentConnectionOption(kNRTT, perspective)) {
SetInitialRtt(QuicTime::Delta::FromMicroseconds(
config.ReceivedInitialRoundTripTimeUs()));
}
} else if (config.HasInitialRoundTripTimeUsToSend() &&
config.GetInitialRoundTripTimeUsToSend() > 0) {
SetInitialRtt(QuicTime::Delta::FromMicroseconds(
config.GetInitialRoundTripTimeUsToSend()));
}
if (config.HasReceivedMaxAckDelayMs()) {
peer_max_ack_delay_ =
QuicTime::Delta::FromMilliseconds(config.ReceivedMaxAckDelayMs());
}
if (GetQuicReloadableFlag(quic_can_send_ack_frequency) &&
perspective == Perspective::IS_SERVER) {
if (config.HasReceivedMinAckDelayMs()) {
peer_min_ack_delay_ =
QuicTime::Delta::FromMilliseconds(config.ReceivedMinAckDelayMs());
}
if (config.HasClientSentConnectionOption(kAFF1, perspective)) {
use_smoothed_rtt_in_ack_delay_ = true;
}
}
if (config.HasClientSentConnectionOption(kMAD0, perspective)) {
rtt_stats_.set_ignore_max_ack_delay(true);
}
if (config.HasClientSentConnectionOption(kMAD2, perspective)) {
// Set the minimum to the alarm granularity.
min_tlp_timeout_ = kAlarmGranularity;
}
if (config.HasClientSentConnectionOption(kMAD3, perspective)) {
// Set the minimum to the alarm granularity.
min_rto_timeout_ = kAlarmGranularity;
}
if (config.HasClientSentConnectionOption(k2PTO, perspective)) {
pto_enabled_ = true;
}
if (config.HasClientSentConnectionOption(k1PTO, perspective)) {
pto_enabled_ = true;
max_probe_packets_per_pto_ = 1;
}
if (config.HasClientSentConnectionOption(kPTOS, perspective)) {
if (!pto_enabled_) {
QUIC_PEER_BUG
<< "PTO is not enabled when receiving PTOS connection option.";
pto_enabled_ = true;
max_probe_packets_per_pto_ = 1;
}
skip_packet_number_for_pto_ = true;
}
if (pto_enabled_) {
if (config.HasClientSentConnectionOption(kPTOA, perspective)) {
always_include_max_ack_delay_for_pto_timeout_ = false;
}
if (config.HasClientSentConnectionOption(kPEB1, perspective)) {
StartExponentialBackoffAfterNthPto(1);
}
if (config.HasClientSentConnectionOption(kPEB2, perspective)) {
StartExponentialBackoffAfterNthPto(2);
}
if (config.HasClientSentConnectionOption(kPVS1, perspective)) {
pto_rttvar_multiplier_ = 2;
}
if (config.HasClientSentConnectionOption(kPAG1, perspective)) {
QUIC_CODE_COUNT(one_aggressive_pto);
num_tlp_timeout_ptos_ = 1;
}
if (config.HasClientSentConnectionOption(kPAG2, perspective)) {
QUIC_CODE_COUNT(two_aggressive_ptos);
num_tlp_timeout_ptos_ = 2;
}
if (config.HasClientSentConnectionOption(kPLE1, perspective) ||
config.HasClientSentConnectionOption(kTLPR, perspective)) {
first_pto_srtt_multiplier_ = 0.5;
} else if (config.HasClientSentConnectionOption(kPLE2, perspective)) {
first_pto_srtt_multiplier_ = 1.5;
}
if (config.HasClientSentConnectionOption(kAPTO, perspective)) {
pto_multiplier_without_rtt_samples_ = 1.5;
}
if (config.HasClientSentConnectionOption(kPSDA, perspective)) {
use_standard_deviation_for_pto_ = true;
rtt_stats_.EnableStandardDeviationCalculation();
}
if (config.HasClientRequestedIndependentOption(kPDP2, perspective)) {
num_ptos_for_path_degrading_ = 2;
}
if (config.HasClientRequestedIndependentOption(kPDP3, perspective)) {
num_ptos_for_path_degrading_ = 3;
}
if (config.HasClientRequestedIndependentOption(kPDP4, perspective)) {
num_ptos_for_path_degrading_ = 4;
}
if (config.HasClientRequestedIndependentOption(kPDP5, perspective)) {
num_ptos_for_path_degrading_ = 5;
}
}
// Configure congestion control.
if (config.HasClientRequestedIndependentOption(kTBBR, perspective)) {
SetSendAlgorithm(kBBR);
}
if (GetQuicReloadableFlag(quic_allow_client_enabled_bbr_v2) &&
config.HasClientRequestedIndependentOption(kB2ON, perspective)) {
QUIC_RELOADABLE_FLAG_COUNT(quic_allow_client_enabled_bbr_v2);
SetSendAlgorithm(kBBRv2);
}
if (config.HasClientRequestedIndependentOption(kRENO, perspective)) {
SetSendAlgorithm(kRenoBytes);
} else if (config.HasClientRequestedIndependentOption(kBYTE, perspective) ||
(GetQuicReloadableFlag(quic_default_to_bbr) &&
config.HasClientRequestedIndependentOption(kQBIC, perspective))) {
SetSendAlgorithm(kCubicBytes);
}
// Initial window.
if (GetQuicReloadableFlag(quic_unified_iw_options)) {
if (config.HasClientRequestedIndependentOption(kIW03, perspective)) {
initial_congestion_window_ = 3;
send_algorithm_->SetInitialCongestionWindowInPackets(3);
}
if (config.HasClientRequestedIndependentOption(kIW10, perspective)) {
initial_congestion_window_ = 10;
send_algorithm_->SetInitialCongestionWindowInPackets(10);
}
if (config.HasClientRequestedIndependentOption(kIW20, perspective)) {
initial_congestion_window_ = 20;
send_algorithm_->SetInitialCongestionWindowInPackets(20);
}
if (config.HasClientRequestedIndependentOption(kIW50, perspective)) {
initial_congestion_window_ = 50;
send_algorithm_->SetInitialCongestionWindowInPackets(50);
}
}
if (config.HasClientRequestedIndependentOption(kBWS5, perspective)) {
initial_congestion_window_ = 10;
send_algorithm_->SetInitialCongestionWindowInPackets(10);
}
if (config.HasClientRequestedIndependentOption(kIGNP, perspective)) {
ignore_pings_ = true;
}
using_pacing_ = !GetQuicFlag(FLAGS_quic_disable_pacing_for_perf_tests);
if (config.HasClientSentConnectionOption(kNTLP, perspective)) {
max_tail_loss_probes_ = 0;
}
if (config.HasClientSentConnectionOption(k1TLP, perspective)) {
max_tail_loss_probes_ = 1;
}
if (config.HasClientSentConnectionOption(k1RTO, perspective)) {
max_rto_packets_ = 1;
}
if (config.HasClientSentConnectionOption(kTLPR, perspective)) {
enable_half_rtt_tail_loss_probe_ = true;
}
if (config.HasClientRequestedIndependentOption(kTLPR, perspective)) {
enable_half_rtt_tail_loss_probe_ = true;
}
if (config.HasClientSentConnectionOption(kNRTO, perspective)) {
use_new_rto_ = true;
}
// Configure loss detection.
if (config.HasClientRequestedIndependentOption(kILD0, perspective)) {
uber_loss_algorithm_.SetReorderingShift(kDefaultIetfLossDelayShift);
uber_loss_algorithm_.DisableAdaptiveReorderingThreshold();
}
if (config.HasClientRequestedIndependentOption(kILD1, perspective)) {
uber_loss_algorithm_.SetReorderingShift(kDefaultLossDelayShift);
uber_loss_algorithm_.DisableAdaptiveReorderingThreshold();
}
if (config.HasClientRequestedIndependentOption(kILD2, perspective)) {
uber_loss_algorithm_.EnableAdaptiveReorderingThreshold();
uber_loss_algorithm_.SetReorderingShift(kDefaultIetfLossDelayShift);
}
if (config.HasClientRequestedIndependentOption(kILD3, perspective)) {
uber_loss_algorithm_.SetReorderingShift(kDefaultLossDelayShift);
uber_loss_algorithm_.EnableAdaptiveReorderingThreshold();
}
if (config.HasClientRequestedIndependentOption(kILD4, perspective)) {
uber_loss_algorithm_.SetReorderingShift(kDefaultLossDelayShift);
uber_loss_algorithm_.EnableAdaptiveReorderingThreshold();
uber_loss_algorithm_.EnableAdaptiveTimeThreshold();
}
if (config.HasClientRequestedIndependentOption(kRUNT, perspective)) {
uber_loss_algorithm_.DisablePacketThresholdForRuntPackets();
}
if (config.HasClientSentConnectionOption(kCONH, perspective)) {
conservative_handshake_retransmits_ = true;
}
send_algorithm_->SetFromConfig(config, perspective);
loss_algorithm_->SetFromConfig(config, perspective);
if (network_change_visitor_ != nullptr) {
network_change_visitor_->OnCongestionChange();
}
}
void QuicSentPacketManager::ApplyConnectionOptions(
const QuicTagVector& connection_options) {
send_algorithm_->ApplyConnectionOptions(connection_options);
}
void QuicSentPacketManager::ResumeConnectionState(
const CachedNetworkParameters& cached_network_params,
bool max_bandwidth_resumption) {
QuicBandwidth bandwidth = QuicBandwidth::FromBytesPerSecond(
max_bandwidth_resumption
? cached_network_params.max_bandwidth_estimate_bytes_per_second()
: cached_network_params.bandwidth_estimate_bytes_per_second());
QuicTime::Delta rtt =
QuicTime::Delta::FromMilliseconds(cached_network_params.min_rtt_ms());
// This calls the old AdjustNetworkParameters interface, and fills certain
// fields in SendAlgorithmInterface::NetworkParams
// (e.g., quic_bbr_fix_pacing_rate) using GFE flags.
AdjustNetworkParameters(SendAlgorithmInterface::NetworkParams(
bandwidth, rtt, /*allow_cwnd_to_decrease = */ false));
}
void QuicSentPacketManager::AdjustNetworkParameters(
const SendAlgorithmInterface::NetworkParams& params) {
const QuicBandwidth& bandwidth = params.bandwidth;
const QuicTime::Delta& rtt = params.rtt;
if (!rtt.IsZero()) {
SetInitialRtt(rtt);
}
const QuicByteCount old_cwnd = send_algorithm_->GetCongestionWindow();
if (GetQuicReloadableFlag(quic_conservative_bursts) && using_pacing_ &&
!bandwidth.IsZero()) {
QUIC_RELOADABLE_FLAG_COUNT(quic_conservative_bursts);
pacing_sender_.SetBurstTokens(kConservativeUnpacedBurst);
}
send_algorithm_->AdjustNetworkParameters(params);
if (debug_delegate_ != nullptr) {
debug_delegate_->OnAdjustNetworkParameters(
bandwidth, rtt.IsZero() ? rtt_stats_.MinOrInitialRtt() : rtt, old_cwnd,
send_algorithm_->GetCongestionWindow());
}
}
void QuicSentPacketManager::SetLossDetectionTuner(
std::unique_ptr<LossDetectionTunerInterface> tuner) {
uber_loss_algorithm_.SetLossDetectionTuner(std::move(tuner));
}
void QuicSentPacketManager::OnConfigNegotiated() {
loss_algorithm_->OnConfigNegotiated();
}
void QuicSentPacketManager::OnConnectionClosed() {
loss_algorithm_->OnConnectionClosed();
}
void QuicSentPacketManager::SetHandshakeConfirmed() {
if (!handshake_finished_) {
handshake_finished_ = true;
NeuterHandshakePackets();
}
}
void QuicSentPacketManager::PostProcessNewlyAckedPackets(
QuicPacketNumber ack_packet_number,
EncryptionLevel ack_decrypted_level,
const QuicAckFrame& ack_frame,
QuicTime ack_receive_time,
bool rtt_updated,
QuicByteCount prior_bytes_in_flight) {
unacked_packets_.NotifyAggregatedStreamFrameAcked(
last_ack_frame_.ack_delay_time);
InvokeLossDetection(ack_receive_time);
// Ignore losses in RTO mode.
if (consecutive_rto_count_ > 0 && !use_new_rto_) {
packets_lost_.clear();
}
MaybeInvokeCongestionEvent(rtt_updated, prior_bytes_in_flight,
ack_receive_time);
unacked_packets_.RemoveObsoletePackets();
sustained_bandwidth_recorder_.RecordEstimate(
send_algorithm_->InRecovery(), send_algorithm_->InSlowStart(),
send_algorithm_->BandwidthEstimate(), ack_receive_time, clock_->WallNow(),
rtt_stats_.smoothed_rtt());
// Anytime we are making forward progress and have a new RTT estimate, reset
// the backoff counters.
if (rtt_updated) {
if (consecutive_rto_count_ > 0) {
// If the ack acknowledges data sent prior to the RTO,
// the RTO was spurious.
if (LargestAcked(ack_frame) < first_rto_transmission_) {
// Replace SRTT with latest_rtt and increase the variance to prevent
// a spurious RTO from happening again.
rtt_stats_.ExpireSmoothedMetrics();
} else {
if (!use_new_rto_) {
send_algorithm_->OnRetransmissionTimeout(true);
}
}
}
// Records the max consecutive RTO or PTO before forward progress has been
// made.
if (consecutive_rto_count_ >
stats_->max_consecutive_rto_with_forward_progress) {
stats_->max_consecutive_rto_with_forward_progress =
consecutive_rto_count_;
} else if (consecutive_pto_count_ >
stats_->max_consecutive_rto_with_forward_progress) {
stats_->max_consecutive_rto_with_forward_progress =
consecutive_pto_count_;
}
// Reset all retransmit counters any time a new packet is acked.
consecutive_rto_count_ = 0;
consecutive_tlp_count_ = 0;
consecutive_pto_count_ = 0;
consecutive_crypto_retransmission_count_ = 0;
}
if (debug_delegate_ != nullptr) {
debug_delegate_->OnIncomingAck(
ack_packet_number, ack_decrypted_level, ack_frame, ack_receive_time,
LargestAcked(ack_frame), rtt_updated, GetLeastUnacked());
}
// Remove packets below least unacked from all_packets_acked_ and
// last_ack_frame_.
last_ack_frame_.packets.RemoveUpTo(unacked_packets_.GetLeastUnacked());
last_ack_frame_.received_packet_times.clear();
}
void QuicSentPacketManager::MaybeInvokeCongestionEvent(
bool rtt_updated,
QuicByteCount prior_in_flight,
QuicTime event_time) {
if (!rtt_updated && packets_acked_.empty() && packets_lost_.empty()) {
return;
}
const bool overshooting_detected =
stats_->overshooting_detected_with_network_parameters_adjusted;
if (using_pacing_) {
pacing_sender_.OnCongestionEvent(rtt_updated, prior_in_flight, event_time,
packets_acked_, packets_lost_);
} else {
send_algorithm_->OnCongestionEvent(rtt_updated, prior_in_flight, event_time,
packets_acked_, packets_lost_);
}
if (debug_delegate_ != nullptr && !overshooting_detected &&
stats_->overshooting_detected_with_network_parameters_adjusted) {
debug_delegate_->OnOvershootingDetected();
}
packets_acked_.clear();
packets_lost_.clear();
if (network_change_visitor_ != nullptr) {
network_change_visitor_->OnCongestionChange();
}
}
void QuicSentPacketManager::MarkZeroRttPacketsForRetransmission() {
if (unacked_packets_.use_circular_deque()) {
if (unacked_packets_.empty()) {
return;
}
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
QuicPacketNumber largest_sent_packet =
unacked_packets_.largest_sent_packet();
for (; packet_number <= largest_sent_packet; ++packet_number) {
QuicTransmissionInfo* transmission_info =
unacked_packets_.GetMutableTransmissionInfo(packet_number);
if (transmission_info->encryption_level == ENCRYPTION_ZERO_RTT) {
if (transmission_info->in_flight) {
// Remove 0-RTT packets and packets of the wrong version from flight,
// because neither can be processed by the peer.
unacked_packets_.RemoveFromInFlight(transmission_info);
}
if (unacked_packets_.HasRetransmittableFrames(*transmission_info)) {
MarkForRetransmission(packet_number, ALL_ZERO_RTT_RETRANSMISSION);
}
}
}
} else {
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
for (QuicUnackedPacketMap::iterator it = unacked_packets_.begin();
it != unacked_packets_.end(); ++it, ++packet_number) {
if (it->encryption_level == ENCRYPTION_ZERO_RTT) {
if (it->in_flight) {
// Remove 0-RTT packets and packets of the wrong version from
// flight, because neither can be processed by the peer.
unacked_packets_.RemoveFromInFlight(&*it);
}
if (unacked_packets_.HasRetransmittableFrames(*it)) {
MarkForRetransmission(packet_number, ALL_ZERO_RTT_RETRANSMISSION);
}
}
}
}
}
void QuicSentPacketManager::NeuterUnencryptedPackets() {
for (QuicPacketNumber packet_number :
unacked_packets_.NeuterUnencryptedPackets()) {
send_algorithm_->OnPacketNeutered(packet_number);
}
if (handshake_mode_disabled_) {
consecutive_pto_count_ = 0;
uber_loss_algorithm_.ResetLossDetection(INITIAL_DATA);
}
}
void QuicSentPacketManager::NeuterHandshakePackets() {
for (QuicPacketNumber packet_number :
unacked_packets_.NeuterHandshakePackets()) {
send_algorithm_->OnPacketNeutered(packet_number);
}
if (handshake_mode_disabled_) {
consecutive_pto_count_ = 0;
uber_loss_algorithm_.ResetLossDetection(HANDSHAKE_DATA);
}
}
bool QuicSentPacketManager::ShouldAddMaxAckDelay(
PacketNumberSpace space) const {
DCHECK(pto_enabled_);
if (supports_multiple_packet_number_spaces() && space != APPLICATION_DATA) {
// When the PTO is armed for Initial or Handshake packet number spaces,
// the max_ack_delay is 0.
return false;
}
if (always_include_max_ack_delay_for_pto_timeout_) {
return true;
}
if (!unacked_packets_
.GetLargestSentRetransmittableOfPacketNumberSpace(APPLICATION_DATA)
.IsInitialized() ||
unacked_packets_.GetLargestSentRetransmittableOfPacketNumberSpace(
APPLICATION_DATA) <
FirstSendingPacketNumber() + kMinReceivedBeforeAckDecimation - 1) {
// Peer is doing TCP style acking. Expect an immediate ACK if more than 1
// packet are outstanding.
if (unacked_packets_.packets_in_flight() >=
kDefaultRetransmittablePacketsBeforeAck) {
return false;
}
} else if (unacked_packets_.packets_in_flight() >=
kMaxRetransmittablePacketsBeforeAck) {
// Peer is doing ack decimation. Expect an immediate ACK if >= 10
// packets are outstanding.
return false;
}
if (skip_packet_number_for_pto_ && consecutive_pto_count_ > 0) {
// An immediate ACK is expected when doing PTOS. Please note, this will miss
// cases when PTO fires and turns out to be spurious.
return false;
}
return true;
}
QuicTime QuicSentPacketManager::GetEarliestPacketSentTimeForPto(
PacketNumberSpace* packet_number_space) const {
DCHECK(supports_multiple_packet_number_spaces());
QuicTime earliest_sent_time = QuicTime::Zero();
for (int8_t i = 0; i < NUM_PACKET_NUMBER_SPACES; ++i) {
const QuicTime sent_time = unacked_packets_.GetLastInFlightPacketSentTime(
static_cast<PacketNumberSpace>(i));
if (!handshake_finished_ && i == APPLICATION_DATA) {
// Do not arm PTO for application data until handshake gets confirmed.
continue;
}
if (!sent_time.IsInitialized() || (earliest_sent_time.IsInitialized() &&
earliest_sent_time <= sent_time)) {
continue;
}
earliest_sent_time = sent_time;
*packet_number_space = static_cast<PacketNumberSpace>(i);
}
return earliest_sent_time;
}
void QuicSentPacketManager::MarkForRetransmission(
QuicPacketNumber packet_number,
TransmissionType transmission_type) {
QuicTransmissionInfo* transmission_info =
unacked_packets_.GetMutableTransmissionInfo(packet_number);
// A previous RTO retransmission may cause connection close; packets without
// retransmittable frames can be marked for loss retransmissions.
QUIC_BUG_IF(transmission_type != LOSS_RETRANSMISSION &&
transmission_type != RTO_RETRANSMISSION &&
!unacked_packets_.HasRetransmittableFrames(*transmission_info))
<< "transmission_type: " << transmission_type;
// Handshake packets should never be sent as probing retransmissions.
DCHECK(!transmission_info->has_crypto_handshake ||
transmission_type != PROBING_RETRANSMISSION);
HandleRetransmission(transmission_type, transmission_info);
// Get the latest transmission_info here as it can be invalidated after
// HandleRetransmission adding new sent packets into unacked_packets_.
transmission_info =
unacked_packets_.GetMutableTransmissionInfo(packet_number);
// Update packet state according to transmission type.
transmission_info->state =
QuicUtils::RetransmissionTypeToPacketState(transmission_type);
}
void QuicSentPacketManager::HandleRetransmission(
TransmissionType transmission_type,
QuicTransmissionInfo* transmission_info) {
if (ShouldForceRetransmission(transmission_type)) {
// TODO(fayang): Consider to make RTO and PROBING retransmission
// strategies be configurable by applications. Today, TLP, RTO and PROBING
// retransmissions are handled similarly, i.e., always retranmist the
// oldest outstanding data. This is not ideal in general because different
// applications may want different strategies. For example, some
// applications may want to use higher priority stream data for bandwidth
// probing, and some applications want to consider RTO is an indication of
// loss, etc.
// transmission_info owning these frames may be deallocated after each
// retransimission. Make a copy of retransmissible frames to prevent the
// invalidation.
if (unacked_packets_.use_circular_deque()) {
unacked_packets_.RetransmitFrames(
QuicFrames(transmission_info->retransmittable_frames),
transmission_type);
} else {
unacked_packets_.RetransmitFrames(
transmission_info->retransmittable_frames, transmission_type);
}
return;
}
unacked_packets_.NotifyFramesLost(*transmission_info, transmission_type);
if (transmission_info->retransmittable_frames.empty()) {
return;
}
if (transmission_type == LOSS_RETRANSMISSION) {
// Record the first packet sent after loss, which allows to wait 1
// more RTT before giving up on this lost packet.
transmission_info->first_sent_after_loss =
unacked_packets_.largest_sent_packet() + 1;
} else {
// Clear the recorded first packet sent after loss when version or
// encryption changes.
transmission_info->first_sent_after_loss.Clear();
}
}
void QuicSentPacketManager::RecordOneSpuriousRetransmission(
const QuicTransmissionInfo& info) {
stats_->bytes_spuriously_retransmitted += info.bytes_sent;
++stats_->packets_spuriously_retransmitted;
if (debug_delegate_ != nullptr) {
debug_delegate_->OnSpuriousPacketRetransmission(info.transmission_type,
info.bytes_sent);
}
}
void QuicSentPacketManager::MarkPacketHandled(QuicPacketNumber packet_number,
QuicTransmissionInfo* info,
QuicTime ack_receive_time,
QuicTime::Delta ack_delay_time,
QuicTime receive_timestamp) {
if (info->has_ack_frequency) {
for (const auto& frame : info->retransmittable_frames) {
if (frame.type == ACK_FREQUENCY_FRAME) {
OnAckFrequencyFrameAcked(*frame.ack_frequency_frame);
}
}
}
// Try to aggregate acked stream frames if acked packet is not a
// retransmission.
if (info->transmission_type == NOT_RETRANSMISSION) {
unacked_packets_.MaybeAggregateAckedStreamFrame(*info, ack_delay_time,
receive_timestamp);
} else {
unacked_packets_.NotifyAggregatedStreamFrameAcked(ack_delay_time);
const bool new_data_acked = unacked_packets_.NotifyFramesAcked(
*info, ack_delay_time, receive_timestamp);
if (!new_data_acked && info->transmission_type != NOT_RETRANSMISSION) {
// Record as a spurious retransmission if this packet is a
// retransmission and no new data gets acked.
QUIC_DVLOG(1) << "Detect spurious retransmitted packet " << packet_number
<< " transmission type: " << info->transmission_type;
RecordOneSpuriousRetransmission(*info);
}
}
if (info->state == LOST) {
// Record as a spurious loss as a packet previously declared lost gets
// acked.
const PacketNumberSpace packet_number_space =
unacked_packets_.GetPacketNumberSpace(info->encryption_level);
const QuicPacketNumber previous_largest_acked =
supports_multiple_packet_number_spaces()
? unacked_packets_.GetLargestAckedOfPacketNumberSpace(
packet_number_space)
: unacked_packets_.largest_acked();
QUIC_DVLOG(1) << "Packet " << packet_number
<< " was detected lost spuriously, "
"previous_largest_acked: "
<< previous_largest_acked;
loss_algorithm_->SpuriousLossDetected(unacked_packets_, rtt_stats_,
ack_receive_time, packet_number,
previous_largest_acked);
++stats_->packet_spuriously_detected_lost;
}
if (network_change_visitor_ != nullptr &&
info->bytes_sent > largest_mtu_acked_) {
largest_mtu_acked_ = info->bytes_sent;
network_change_visitor_->OnPathMtuIncreased(largest_mtu_acked_);
}
unacked_packets_.RemoveFromInFlight(info);
unacked_packets_.RemoveRetransmittability(info);
info->state = ACKED;
}
bool QuicSentPacketManager::CanSendAckFrequency() const {
return !peer_min_ack_delay_.IsInfinite() && handshake_finished_;
}
QuicAckFrequencyFrame QuicSentPacketManager::GetUpdatedAckFrequencyFrame()
const {
QuicAckFrequencyFrame frame;
if (!CanSendAckFrequency()) {
QUIC_BUG << "New AckFrequencyFrame is created while it shouldn't.";
return frame;
}
QUIC_RELOADABLE_FLAG_COUNT_N(quic_can_send_ack_frequency, 1, 3);
frame.packet_tolerance = kMaxRetransmittablePacketsBeforeAck;
auto rtt = use_smoothed_rtt_in_ack_delay_ ? rtt_stats_.SmoothedOrInitialRtt()
: rtt_stats_.MinOrInitialRtt();
frame.max_ack_delay = rtt * kAckDecimationDelay;
frame.max_ack_delay = std::max(frame.max_ack_delay, peer_min_ack_delay_);
// TODO(haoyuewang) Remove this once kDefaultMinAckDelayTimeMs is updated to
// 5 ms on the client side.
frame.max_ack_delay =
std::max(frame.max_ack_delay,
QuicTime::Delta::FromMilliseconds(kDefaultMinAckDelayTimeMs));
return frame;
}
bool QuicSentPacketManager::OnPacketSent(
SerializedPacket* mutable_packet,
QuicTime sent_time,
TransmissionType transmission_type,
HasRetransmittableData has_retransmittable_data,
bool measure_rtt) {
const SerializedPacket& packet = *mutable_packet;
QuicPacketNumber packet_number = packet.packet_number;
DCHECK_LE(FirstSendingPacketNumber(), packet_number);
DCHECK(!unacked_packets_.IsUnacked(packet_number));
QUIC_BUG_IF(packet.encrypted_length == 0) << "Cannot send empty packets.";
if (pending_timer_transmission_count_ > 0) {
--pending_timer_transmission_count_;
}
bool in_flight = has_retransmittable_data == HAS_RETRANSMITTABLE_DATA;
if (ignore_pings_ && mutable_packet->retransmittable_frames.size() == 1 &&
mutable_packet->retransmittable_frames[0].type == PING_FRAME) {
// Dot not use PING only packet for RTT measure or congestion control.
in_flight = false;
measure_rtt = false;
}
if (using_pacing_) {
pacing_sender_.OnPacketSent(sent_time, unacked_packets_.bytes_in_flight(),
packet_number, packet.encrypted_length,
has_retransmittable_data);
} else {
send_algorithm_->OnPacketSent(sent_time, unacked_packets_.bytes_in_flight(),
packet_number, packet.encrypted_length,
has_retransmittable_data);
}
// Deallocate message data in QuicMessageFrame immediately after packet
// sent.
if (packet.has_message) {
for (auto& frame : mutable_packet->retransmittable_frames) {
if (frame.type == MESSAGE_FRAME) {
frame.message_frame->message_data.clear();
frame.message_frame->message_length = 0;
}
}
}
if (packet.has_ack_frequency) {
for (const auto& frame : packet.retransmittable_frames) {
if (frame.type == ACK_FREQUENCY_FRAME) {
OnAckFrequencyFrameSent(*frame.ack_frequency_frame);
}
}
}
unacked_packets_.AddSentPacket(mutable_packet, transmission_type, sent_time,
in_flight, measure_rtt);
// Reset the retransmission timer anytime a pending packet is sent.
return in_flight;
}
QuicSentPacketManager::RetransmissionTimeoutMode
QuicSentPacketManager::OnRetransmissionTimeout() {
DCHECK(unacked_packets_.HasInFlightPackets() ||
(handshake_mode_disabled_ && !handshake_finished_));
DCHECK_EQ(0u, pending_timer_transmission_count_);
// Handshake retransmission, timer based loss detection, TLP, and RTO are
// implemented with a single alarm. The handshake alarm is set when the
// handshake has not completed, the loss alarm is set when the loss detection
// algorithm says to, and the TLP and RTO alarms are set after that.
// The TLP alarm is always set to run for under an RTO.
switch (GetRetransmissionMode()) {
case HANDSHAKE_MODE:
DCHECK(!handshake_mode_disabled_);
++stats_->crypto_retransmit_count;
RetransmitCryptoPackets();
return HANDSHAKE_MODE;
case LOSS_MODE: {
++stats_->loss_timeout_count;
QuicByteCount prior_in_flight = unacked_packets_.bytes_in_flight();
const QuicTime now = clock_->Now();
InvokeLossDetection(now);
MaybeInvokeCongestionEvent(false, prior_in_flight, now);
return LOSS_MODE;
}
case TLP_MODE:
++stats_->tlp_count;
++consecutive_tlp_count_;
pending_timer_transmission_count_ = 1;
// TLPs prefer sending new data instead of retransmitting data, so
// give the connection a chance to write before completing the TLP.
return TLP_MODE;
case RTO_MODE:
++stats_->rto_count;
RetransmitRtoPackets();
return RTO_MODE;
case PTO_MODE:
QUIC_DVLOG(1) << ENDPOINT << "PTO mode";
++stats_->pto_count;
if (handshake_mode_disabled_ && !handshake_finished_) {
++stats_->crypto_retransmit_count;
}
++consecutive_pto_count_;
pending_timer_transmission_count_ = max_probe_packets_per_pto_;
return PTO_MODE;
}
QUIC_BUG << "Unknown retransmission mode " << GetRetransmissionMode();
return GetRetransmissionMode();
}
void QuicSentPacketManager::RetransmitCryptoPackets() {
DCHECK_EQ(HANDSHAKE_MODE, GetRetransmissionMode());
++consecutive_crypto_retransmission_count_;
bool packet_retransmitted = false;
std::vector<QuicPacketNumber> crypto_retransmissions;
if (unacked_packets_.use_circular_deque()) {
if (!unacked_packets_.empty()) {
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
QuicPacketNumber largest_sent_packet =
unacked_packets_.largest_sent_packet();
for (; packet_number <= largest_sent_packet; ++packet_number) {
QuicTransmissionInfo* transmission_info =
unacked_packets_.GetMutableTransmissionInfo(packet_number);
// Only retransmit frames which are in flight, and therefore have been
// sent.
if (!transmission_info->in_flight ||
transmission_info->state != OUTSTANDING ||
!transmission_info->has_crypto_handshake ||
!unacked_packets_.HasRetransmittableFrames(*transmission_info)) {
continue;
}
packet_retransmitted = true;
crypto_retransmissions.push_back(packet_number);
++pending_timer_transmission_count_;
}
}
} else {
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
for (auto it = unacked_packets_.begin(); it != unacked_packets_.end();
++it, ++packet_number) {
// Only retransmit frames which are in flight, and therefore have been
// sent.
if (!it->in_flight || it->state != OUTSTANDING ||
!it->has_crypto_handshake ||
!unacked_packets_.HasRetransmittableFrames(*it)) {
continue;
}
packet_retransmitted = true;
crypto_retransmissions.push_back(packet_number);
++pending_timer_transmission_count_;
}
}
DCHECK(packet_retransmitted) << "No crypto packets found to retransmit.";
for (QuicPacketNumber retransmission : crypto_retransmissions) {
MarkForRetransmission(retransmission, HANDSHAKE_RETRANSMISSION);
}
}
bool QuicSentPacketManager::MaybeRetransmitTailLossProbe() {
DCHECK(!pto_enabled_);
if (pending_timer_transmission_count_ == 0) {
return false;
}
if (!MaybeRetransmitOldestPacket(TLP_RETRANSMISSION)) {
return false;
}
return true;
}
bool QuicSentPacketManager::MaybeRetransmitOldestPacket(TransmissionType type) {
if (unacked_packets_.use_circular_deque()) {
if (!unacked_packets_.empty()) {
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
QuicPacketNumber largest_sent_packet =
unacked_packets_.largest_sent_packet();
for (; packet_number <= largest_sent_packet; ++packet_number) {
QuicTransmissionInfo* transmission_info =
unacked_packets_.GetMutableTransmissionInfo(packet_number);
// Only retransmit frames which are in flight, and therefore have been
// sent.
if (!transmission_info->in_flight ||
transmission_info->state != OUTSTANDING ||
!unacked_packets_.HasRetransmittableFrames(*transmission_info)) {
continue;
}
MarkForRetransmission(packet_number, type);
return true;
}
}
} else {
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
for (auto it = unacked_packets_.begin(); it != unacked_packets_.end();
++it, ++packet_number) {
// Only retransmit frames which are in flight, and therefore have been
// sent.
if (!it->in_flight || it->state != OUTSTANDING ||
!unacked_packets_.HasRetransmittableFrames(*it)) {
continue;
}
MarkForRetransmission(packet_number, type);
return true;
}
}
QUIC_DVLOG(1)
<< "No retransmittable packets, so RetransmitOldestPacket failed.";
return false;
}
void QuicSentPacketManager::RetransmitRtoPackets() {
DCHECK(!pto_enabled_);
QUIC_BUG_IF(pending_timer_transmission_count_ > 0)
<< "Retransmissions already queued:" << pending_timer_transmission_count_;
// Mark two packets for retransmission.
std::vector<QuicPacketNumber> retransmissions;
if (unacked_packets_.use_circular_deque()) {
if (!unacked_packets_.empty()) {
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
QuicPacketNumber largest_sent_packet =
unacked_packets_.largest_sent_packet();
for (; packet_number <= largest_sent_packet; ++packet_number) {
QuicTransmissionInfo* transmission_info =
unacked_packets_.GetMutableTransmissionInfo(packet_number);
if (transmission_info->state == OUTSTANDING &&
unacked_packets_.HasRetransmittableFrames(*transmission_info) &&
pending_timer_transmission_count_ < max_rto_packets_) {
DCHECK(transmission_info->in_flight);
retransmissions.push_back(packet_number);
++pending_timer_transmission_count_;
}
}
}
} else {
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
for (auto it = unacked_packets_.begin(); it != unacked_packets_.end();
++it, ++packet_number) {
if (it->state == OUTSTANDING &&
unacked_packets_.HasRetransmittableFrames(*it) &&
pending_timer_transmission_count_ < max_rto_packets_) {
DCHECK(it->in_flight);
retransmissions.push_back(packet_number);
++pending_timer_transmission_count_;
}
}
}
if (pending_timer_transmission_count_ > 0) {
if (consecutive_rto_count_ == 0) {
first_rto_transmission_ = unacked_packets_.largest_sent_packet() + 1;
}
++consecutive_rto_count_;
}
for (QuicPacketNumber retransmission : retransmissions) {
MarkForRetransmission(retransmission, RTO_RETRANSMISSION);
}
if (retransmissions.empty()) {
QUIC_BUG_IF(pending_timer_transmission_count_ != 0);
// No packets to be RTO retransmitted, raise up a credit to allow
// connection to send.
QUIC_CODE_COUNT(no_packets_to_be_rto_retransmitted);
pending_timer_transmission_count_ = 1;
}
}
void QuicSentPacketManager::MaybeSendProbePackets() {
if (pending_timer_transmission_count_ == 0) {
return;
}
PacketNumberSpace packet_number_space;
if (supports_multiple_packet_number_spaces()) {
// Find out the packet number space to send probe packets.
if (!GetEarliestPacketSentTimeForPto(&packet_number_space)
.IsInitialized()) {
QUIC_BUG_IF(unacked_packets_.perspective() == Perspective::IS_SERVER)
<< "earlist_sent_time not initialized when trying to send PTO "
"retransmissions";
return;
}
}
std::vector<QuicPacketNumber> probing_packets;
if (unacked_packets_.use_circular_deque()) {
if (!unacked_packets_.empty()) {
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
QuicPacketNumber largest_sent_packet =
unacked_packets_.largest_sent_packet();
for (; packet_number <= largest_sent_packet; ++packet_number) {
QuicTransmissionInfo* transmission_info =
unacked_packets_.GetMutableTransmissionInfo(packet_number);
if (transmission_info->state == OUTSTANDING &&
unacked_packets_.HasRetransmittableFrames(*transmission_info) &&
(!supports_multiple_packet_number_spaces() ||
unacked_packets_.GetPacketNumberSpace(
transmission_info->encryption_level) == packet_number_space)) {
DCHECK(transmission_info->in_flight);
probing_packets.push_back(packet_number);
if (probing_packets.size() == pending_timer_transmission_count_) {
break;
}
}
}
}
} else {
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
for (auto it = unacked_packets_.begin(); it != unacked_packets_.end();
++it, ++packet_number) {
if (it->state == OUTSTANDING &&
unacked_packets_.HasRetransmittableFrames(*it) &&
(!supports_multiple_packet_number_spaces() ||
unacked_packets_.GetPacketNumberSpace(it->encryption_level) ==
packet_number_space)) {
DCHECK(it->in_flight);
probing_packets.push_back(packet_number);
if (probing_packets.size() == pending_timer_transmission_count_) {
break;
}
}
}
}
for (QuicPacketNumber retransmission : probing_packets) {
QUIC_DVLOG(1) << ENDPOINT << "Marking " << retransmission
<< " for probing retransmission";
MarkForRetransmission(retransmission, PTO_RETRANSMISSION);
}
// It is possible that there is not enough outstanding data for probing.
}
void QuicSentPacketManager::AdjustPendingTimerTransmissions() {
if (pending_timer_transmission_count_ < max_probe_packets_per_pto_) {
// There are packets sent already, clear credit.
pending_timer_transmission_count_ = 0;
return;
}
// No packet gets sent, leave 1 credit to allow data to be write eventually.
pending_timer_transmission_count_ = 1;
}
void QuicSentPacketManager::EnableIetfPtoAndLossDetection() {
if (pto_enabled_) {
QUIC_RELOADABLE_FLAG_COUNT_N(quic_default_on_pto, 2, 2);
// Disable handshake mode.
handshake_mode_disabled_ = true;
return;
}
pto_enabled_ = true;
handshake_mode_disabled_ = true;
// Default to 1 packet per PTO and skip a packet number. Arm the 1st PTO with
// max of earliest in flight sent time + PTO delay and 1.5 * srtt from
// last in flight packet.
max_probe_packets_per_pto_ = 1;
skip_packet_number_for_pto_ = true;
first_pto_srtt_multiplier_ = 1.5;
pto_rttvar_multiplier_ = 2;
}
void QuicSentPacketManager::StartExponentialBackoffAfterNthPto(
size_t exponential_backoff_start_point) {
pto_exponential_backoff_start_point_ = exponential_backoff_start_point;
}
void QuicSentPacketManager::RetransmitDataOfSpaceIfAny(
PacketNumberSpace space) {
DCHECK(supports_multiple_packet_number_spaces());
if (!unacked_packets_.GetLastInFlightPacketSentTime(space).IsInitialized()) {
// No in flight data of space.
return;
}
if (unacked_packets_.use_circular_deque()) {
if (unacked_packets_.empty()) {
return;
}
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
QuicPacketNumber largest_sent_packet =
unacked_packets_.largest_sent_packet();
for (; packet_number <= largest_sent_packet; ++packet_number) {
QuicTransmissionInfo* transmission_info =
unacked_packets_.GetMutableTransmissionInfo(packet_number);
if (transmission_info->state == OUTSTANDING &&
unacked_packets_.HasRetransmittableFrames(*transmission_info) &&
unacked_packets_.GetPacketNumberSpace(
transmission_info->encryption_level) == space) {
DCHECK(transmission_info->in_flight);
if (GetQuicReloadableFlag(quic_fix_pto_pending_timer_count) &&
pending_timer_transmission_count_ == 0) {
QUIC_RELOADABLE_FLAG_COUNT(quic_fix_pto_pending_timer_count);
pending_timer_transmission_count_ = 1;
}
MarkForRetransmission(packet_number, PTO_RETRANSMISSION);
return;
}
}
} else {
QuicPacketNumber packet_number = unacked_packets_.GetLeastUnacked();
for (auto it = unacked_packets_.begin(); it != unacked_packets_.end();
++it, ++packet_number) {
if (it->state == OUTSTANDING &&
unacked_packets_.HasRetransmittableFrames(*it) &&
unacked_packets_.GetPacketNumberSpace(it->encryption_level) ==
space) {
DCHECK(it->in_flight);
if (GetQuicReloadableFlag(quic_fix_pto_pending_timer_count) &&
pending_timer_transmission_count_ == 0) {
QUIC_RELOADABLE_FLAG_COUNT(quic_fix_pto_pending_timer_count);
pending_timer_transmission_count_ = 1;
}
MarkForRetransmission(packet_number, PTO_RETRANSMISSION);
return;
}
}
}
}
QuicSentPacketManager::RetransmissionTimeoutMode
QuicSentPacketManager::GetRetransmissionMode() const {
DCHECK(unacked_packets_.HasInFlightPackets() ||
(handshake_mode_disabled_ && !handshake_finished_));
if (!handshake_mode_disabled_ && !handshake_finished_ &&
unacked_packets_.HasPendingCryptoPackets()) {
return HANDSHAKE_MODE;
}
if (loss_algorithm_->GetLossTimeout() != QuicTime::Zero()) {
return LOSS_MODE;
}
if (pto_enabled_) {
return PTO_MODE;
}
if (consecutive_tlp_count_ < max_tail_loss_probes_) {
if (unacked_packets_.HasUnackedRetransmittableFrames()) {
return TLP_MODE;
}
}
return RTO_MODE;
}
void QuicSentPacketManager::InvokeLossDetection(QuicTime time) {
if (!packets_acked_.empty()) {
DCHECK_LE(packets_acked_.front().packet_number,
packets_acked_.back().packet_number);
largest_newly_acked_ = packets_acked_.back().packet_number;
}
LossDetectionInterface::DetectionStats detection_stats =
loss_algorithm_->DetectLosses(unacked_packets_, time, rtt_stats_,
largest_newly_acked_, packets_acked_,
&packets_lost_);
if (detection_stats.sent_packets_max_sequence_reordering >
stats_->sent_packets_max_sequence_reordering) {
stats_->sent_packets_max_sequence_reordering =
detection_stats.sent_packets_max_sequence_reordering;
}
stats_->sent_packets_num_borderline_time_reorderings +=
detection_stats.sent_packets_num_borderline_time_reorderings;
stats_->total_loss_detection_response_time +=
detection_stats.total_loss_detection_response_time;
for (const LostPacket& packet : packets_lost_) {
QuicTransmissionInfo* info =
unacked_packets_.GetMutableTransmissionInfo(packet.packet_number);
++stats_->packets_lost;
if (debug_delegate_ != nullptr) {
debug_delegate_->OnPacketLoss(packet.packet_number,
info->encryption_level, LOSS_RETRANSMISSION,
time);
}
unacked_packets_.RemoveFromInFlight(info);
MarkForRetransmission(packet.packet_number, LOSS_RETRANSMISSION);
}
}
bool QuicSentPacketManager::MaybeUpdateRTT(QuicPacketNumber largest_acked,
QuicTime::Delta ack_delay_time,
QuicTime ack_receive_time) {
// We rely on ack_delay_time to compute an RTT estimate, so we
// only update rtt when the largest observed gets acked.
if (!unacked_packets_.IsUnacked(largest_acked)) {
return false;
}
// We calculate the RTT based on the highest ACKed packet number, the lower
// packet numbers will include the ACK aggregation delay.
const QuicTransmissionInfo& transmission_info =
unacked_packets_.GetTransmissionInfo(largest_acked);
// Ensure the packet has a valid sent time.
if (transmission_info.sent_time == QuicTime::Zero()) {
QUIC_BUG << "Acked packet has zero sent time, largest_acked:"
<< largest_acked;
return false;
}
if (transmission_info.sent_time > ack_receive_time) {
QUIC_CODE_COUNT(quic_receive_acked_before_sending);
}
QuicTime::Delta send_delta = ack_receive_time - transmission_info.sent_time;
const bool min_rtt_available = !rtt_stats_.min_rtt().IsZero();
rtt_stats_.UpdateRtt(send_delta, ack_delay_time, ack_receive_time);
if (!min_rtt_available && !rtt_stats_.min_rtt().IsZero()) {
loss_algorithm_->OnMinRttAvailable();
}
return true;
}
QuicTime::Delta QuicSentPacketManager::TimeUntilSend(QuicTime now) const {
// The TLP logic is entirely contained within QuicSentPacketManager, so the
// send algorithm does not need to be consulted.
if (pending_timer_transmission_count_ > 0) {
return QuicTime::Delta::Zero();
}
if (using_pacing_) {
return pacing_sender_.TimeUntilSend(now,
unacked_packets_.bytes_in_flight());
}
return send_algorithm_->CanSend(unacked_packets_.bytes_in_flight())
? QuicTime::Delta::Zero()
: QuicTime::Delta::Infinite();
}
const QuicTime QuicSentPacketManager::GetRetransmissionTime() const {
if (!unacked_packets_.HasInFlightPackets() &&
PeerCompletedAddressValidation()) {
return QuicTime::Zero();
}
if (pending_timer_transmission_count_ > 0) {
// Do not set the timer if there is any credit left.
return QuicTime::Zero();
}
PacketNumberSpace packet_number_space;
if (supports_multiple_packet_number_spaces() &&
unacked_packets_.perspective() == Perspective::IS_SERVER &&
!GetEarliestPacketSentTimeForPto(&packet_number_space).IsInitialized()) {
// Do not set the timer on the server side if the only in flight packets are
// half RTT data.
return QuicTime::Zero();
}
switch (GetRetransmissionMode()) {
case HANDSHAKE_MODE:
return unacked_packets_.GetLastCryptoPacketSentTime() +
GetCryptoRetransmissionDelay();
case LOSS_MODE:
return loss_algorithm_->GetLossTimeout();
case TLP_MODE: {
DCHECK(!pto_enabled_);
// TODO(ianswett): When CWND is available, it would be preferable to
// set the timer based on the earliest retransmittable packet.
// Base the updated timer on the send time of the last packet.
const QuicTime sent_time =
unacked_packets_.GetLastInFlightPacketSentTime();
const QuicTime tlp_time = sent_time + GetTailLossProbeDelay();
// Ensure the TLP timer never gets set to a time in the past.
return std::max(clock_->ApproximateNow(), tlp_time);
}
case RTO_MODE: {
DCHECK(!pto_enabled_);
// The RTO is based on the first outstanding packet.
const QuicTime sent_time =
unacked_packets_.GetLastInFlightPacketSentTime();
QuicTime rto_time = sent_time + GetRetransmissionDelay();
// Wait for TLP packets to be acked before an RTO fires.
QuicTime tlp_time = sent_time + GetTailLossProbeDelay();
return std::max(tlp_time, rto_time);
}
case PTO_MODE: {
if (!supports_multiple_packet_number_spaces()) {
if (first_pto_srtt_multiplier_ > 0 &&
unacked_packets_.HasInFlightPackets() &&
consecutive_pto_count_ == 0) {
// Arm 1st PTO with earliest in flight sent time, and make sure at
// least first_pto_srtt_multiplier_ * RTT has been passed since last
// in flight packet.
return std::max(
clock_->ApproximateNow(),
std::max(unacked_packets_.GetFirstInFlightTransmissionInfo()
->sent_time +
GetProbeTimeoutDelay(NUM_PACKET_NUMBER_SPACES),
unacked_packets_.GetLastInFlightPacketSentTime() +
first_pto_srtt_multiplier_ *
rtt_stats_.SmoothedOrInitialRtt()));
}
// Ensure PTO never gets set to a time in the past.
return std::max(clock_->ApproximateNow(),
unacked_packets_.GetLastInFlightPacketSentTime() +
GetProbeTimeoutDelay(NUM_PACKET_NUMBER_SPACES));
}
PacketNumberSpace packet_number_space = NUM_PACKET_NUMBER_SPACES;
// earliest_right_edge is the earliest sent time of the last in flight
// packet of all packet number spaces.
QuicTime earliest_right_edge =
GetEarliestPacketSentTimeForPto(&packet_number_space);
if (!earliest_right_edge.IsInitialized()) {
// Arm PTO from now if there is no in flight packets.
earliest_right_edge = clock_->ApproximateNow();
}
if (first_pto_srtt_multiplier_ > 0 &&
packet_number_space == APPLICATION_DATA &&
consecutive_pto_count_ == 0) {
const QuicTransmissionInfo* first_application_info =
unacked_packets_.GetFirstInFlightTransmissionInfoOfSpace(
APPLICATION_DATA);
if (first_application_info != nullptr) {
// Arm 1st PTO with earliest in flight sent time, and make sure at
// least first_pto_srtt_multiplier_ * RTT has been passed since last
// in flight packet. Only do this for application data.
return std::max(
clock_->ApproximateNow(),
std::max(
first_application_info->sent_time +
GetProbeTimeoutDelay(packet_number_space),
earliest_right_edge + first_pto_srtt_multiplier_ *
rtt_stats_.SmoothedOrInitialRtt()));
}
}
return std::max(
clock_->ApproximateNow(),
earliest_right_edge + GetProbeTimeoutDelay(packet_number_space));
}
}
DCHECK(false);
return QuicTime::Zero();
}
const QuicTime::Delta QuicSentPacketManager::GetPathDegradingDelay() const {
if (num_ptos_for_path_degrading_ > 0) {
return num_ptos_for_path_degrading_ * GetPtoDelay();
}
return GetNConsecutiveRetransmissionTimeoutDelay(
max_tail_loss_probes_ + kNumRetransmissionDelaysForPathDegradingDelay);
}
const QuicTime::Delta QuicSentPacketManager::GetNetworkBlackholeDelay(
int8_t num_rtos_for_blackhole_detection) const {
return GetNConsecutiveRetransmissionTimeoutDelay(
max_tail_loss_probes_ + num_rtos_for_blackhole_detection);
}
QuicTime::Delta QuicSentPacketManager::GetMtuReductionDelay(
int8_t num_rtos_for_blackhole_detection) const {
return GetNetworkBlackholeDelay(num_rtos_for_blackhole_detection / 2);
}
const QuicTime::Delta QuicSentPacketManager::GetCryptoRetransmissionDelay()
const {
// This is equivalent to the TailLossProbeDelay, but slightly more aggressive
// because crypto handshake messages don't incur a delayed ack time.
QuicTime::Delta srtt = rtt_stats_.SmoothedOrInitialRtt();
int64_t delay_ms;
if (conservative_handshake_retransmits_) {
// Using the delayed ack time directly could cause conservative handshake
// retransmissions to actually be more aggressive than the default.
delay_ms = std::max(peer_max_ack_delay_.ToMilliseconds(),
static_cast<int64_t>(2 * srtt.ToMilliseconds()));
} else {
delay_ms = std::max(kMinHandshakeTimeoutMs,
static_cast<int64_t>(1.5 * srtt.ToMilliseconds()));
}
return QuicTime::Delta::FromMilliseconds(
delay_ms << consecutive_crypto_retransmission_count_);
}
const QuicTime::Delta QuicSentPacketManager::GetTailLossProbeDelay() const {
QuicTime::Delta srtt = rtt_stats_.SmoothedOrInitialRtt();
if (enable_half_rtt_tail_loss_probe_ && consecutive_tlp_count_ == 0u) {
if (unacked_packets().HasUnackedStreamData()) {
// Enable TLPR if there are pending data packets.
return std::max(min_tlp_timeout_, srtt * 0.5);
}
}
if (!unacked_packets_.HasMultipleInFlightPackets()) {
// This expression really should be using the delayed ack time, but in TCP
// MinRTO was traditionally set to 2x the delayed ack timer and this
// expression assumed QUIC did the same.
return std::max(2 * srtt, 1.5 * srtt + (min_rto_timeout_ * 0.5));
}
return std::max(min_tlp_timeout_, 2 * srtt);
}
const QuicTime::Delta QuicSentPacketManager::GetRetransmissionDelay() const {
QuicTime::Delta retransmission_delay = QuicTime::Delta::Zero();
if (rtt_stats_.smoothed_rtt().IsZero()) {
// We are in the initial state, use default timeout values.
retransmission_delay =
QuicTime::Delta::FromMilliseconds(kDefaultRetransmissionTimeMs);
} else {
retransmission_delay =
rtt_stats_.smoothed_rtt() + 4 * rtt_stats_.mean_deviation();
if (retransmission_delay < min_rto_timeout_) {
retransmission_delay = min_rto_timeout_;
}
}
// Calculate exponential back off.
retransmission_delay =
retransmission_delay *
(1 << std::min<size_t>(consecutive_rto_count_, kMaxRetransmissions));
if (retransmission_delay.ToMilliseconds() > kMaxRetransmissionTimeMs) {
return QuicTime::Delta::FromMilliseconds(kMaxRetransmissionTimeMs);
}
return retransmission_delay;
}
const QuicTime::Delta QuicSentPacketManager::GetProbeTimeoutDelay(
PacketNumberSpace space) const {
DCHECK(pto_enabled_);
if (rtt_stats_.smoothed_rtt().IsZero()) {
// Respect kMinHandshakeTimeoutMs to avoid a potential amplification attack.
QUIC_BUG_IF(rtt_stats_.initial_rtt().IsZero());
return std::max(
pto_multiplier_without_rtt_samples_ * rtt_stats_.initial_rtt(),
QuicTime::Delta::FromMilliseconds(kMinHandshakeTimeoutMs)) *
(1 << consecutive_pto_count_);
}
if (enable_half_rtt_tail_loss_probe_ && consecutive_pto_count_ == 0 &&
handshake_finished_) {
return std::max(min_tlp_timeout_, rtt_stats_.smoothed_rtt() * 0.5);
}
const QuicTime::Delta rtt_var = use_standard_deviation_for_pto_
? rtt_stats_.GetStandardOrMeanDeviation()
: rtt_stats_.mean_deviation();
QuicTime::Delta pto_delay =
rtt_stats_.smoothed_rtt() +
std::max(pto_rttvar_multiplier_ * rtt_var, kAlarmGranularity) +
(ShouldAddMaxAckDelay(space) ? peer_max_ack_delay_
: QuicTime::Delta::Zero());
pto_delay =
pto_delay * (1 << (consecutive_pto_count_ -
std::min(consecutive_pto_count_,
pto_exponential_backoff_start_point_)));
if (consecutive_pto_count_ < num_tlp_timeout_ptos_) {
// Make first n PTOs similar to TLPs.
if (pto_delay > 2 * rtt_stats_.smoothed_rtt()) {
QUIC_CODE_COUNT(quic_delayed_pto);
pto_delay = std::max(kAlarmGranularity, 2 * rtt_stats_.smoothed_rtt());
} else {
QUIC_CODE_COUNT(quic_faster_pto);
}
}
return pto_delay;
}
QuicTime::Delta QuicSentPacketManager::GetSlowStartDuration() const {
if (send_algorithm_->GetCongestionControlType() == kBBR ||
send_algorithm_->GetCongestionControlType() == kBBRv2) {
return stats_->slowstart_duration.GetTotalElapsedTime(
clock_->ApproximateNow());
}
return QuicTime::Delta::Infinite();
}
std::string QuicSentPacketManager::GetDebugState() const {
return send_algorithm_->GetDebugState();
}
void QuicSentPacketManager::SetSendAlgorithm(
CongestionControlType congestion_control_type) {
if (send_algorithm_ &&
send_algorithm_->GetCongestionControlType() == congestion_control_type) {
return;
}
SetSendAlgorithm(SendAlgorithmInterface::Create(
clock_, &rtt_stats_, &unacked_packets_, congestion_control_type, random_,
stats_, initial_congestion_window_, send_algorithm_.get()));
}
void QuicSentPacketManager::SetSendAlgorithm(
SendAlgorithmInterface* send_algorithm) {
send_algorithm_.reset(send_algorithm);
pacing_sender_.set_sender(send_algorithm);
}
void QuicSentPacketManager::OnConnectionMigration(AddressChangeType type) {
if (type == PORT_CHANGE || type == IPV4_SUBNET_CHANGE) {
// Rtt and cwnd do not need to be reset when the peer address change is
// considered to be caused by NATs.
return;
}
consecutive_rto_count_ = 0;
consecutive_tlp_count_ = 0;
consecutive_pto_count_ = 0;
rtt_stats_.OnConnectionMigration();
send_algorithm_->OnConnectionMigration();
}
void QuicSentPacketManager::OnAckFrameStart(QuicPacketNumber largest_acked,
QuicTime::Delta ack_delay_time,
QuicTime ack_receive_time) {
DCHECK(packets_acked_.empty());
DCHECK_LE(largest_acked, unacked_packets_.largest_sent_packet());
if (ack_delay_time > peer_max_ack_delay()) {
ack_delay_time = peer_max_ack_delay();
}
rtt_updated_ =
MaybeUpdateRTT(largest_acked, ack_delay_time, ack_receive_time);
last_ack_frame_.ack_delay_time = ack_delay_time;
acked_packets_iter_ = last_ack_frame_.packets.rbegin();
}
void QuicSentPacketManager::OnAckRange(QuicPacketNumber start,
QuicPacketNumber end) {
if (!last_ack_frame_.largest_acked.IsInitialized() ||
end > last_ack_frame_.largest_acked + 1) {
// Largest acked increases.
unacked_packets_.IncreaseLargestAcked(end - 1);
last_ack_frame_.largest_acked = end - 1;
}
// Drop ack ranges which ack packets below least_unacked.
QuicPacketNumber least_unacked = unacked_packets_.GetLeastUnacked();
if (least_unacked.IsInitialized() && end <= least_unacked) {
return;
}
start = std::max(start, least_unacked);
do {
QuicPacketNumber newly_acked_start = start;
if (acked_packets_iter_ != last_ack_frame_.packets.rend()) {
newly_acked_start = std::max(start, acked_packets_iter_->max());
}
for (QuicPacketNumber acked = end - 1; acked >= newly_acked_start;
--acked) {
// Check if end is above the current range. If so add newly acked packets
// in descending order.
packets_acked_.push_back(AckedPacket(acked, 0, QuicTime::Zero()));
if (acked == FirstSendingPacketNumber()) {
break;
}
}
if (acked_packets_iter_ == last_ack_frame_.packets.rend() ||
start > acked_packets_iter_->min()) {
// Finish adding all newly acked packets.
return;
}
end = std::min(end, acked_packets_iter_->min());
++acked_packets_iter_;
} while (start < end);
}
void QuicSentPacketManager::OnAckTimestamp(QuicPacketNumber packet_number,
QuicTime timestamp) {
last_ack_frame_.received_packet_times.push_back({packet_number, timestamp});
for (AckedPacket& packet : packets_acked_) {
if (packet.packet_number == packet_number) {
packet.receive_timestamp = timestamp;
return;
}
}
}
AckResult QuicSentPacketManager::OnAckFrameEnd(
QuicTime ack_receive_time,
QuicPacketNumber ack_packet_number,
EncryptionLevel ack_decrypted_level) {
QuicByteCount prior_bytes_in_flight = unacked_packets_.bytes_in_flight();
// Reverse packets_acked_ so that it is in ascending order.
std::reverse(packets_acked_.begin(), packets_acked_.end());
for (AckedPacket& acked_packet : packets_acked_) {
QuicTransmissionInfo* info =
unacked_packets_.GetMutableTransmissionInfo(acked_packet.packet_number);
if (!QuicUtils::IsAckable(info->state)) {
if (info->state == ACKED) {
QUIC_BUG << "Trying to ack an already acked packet: "
<< acked_packet.packet_number
<< ", last_ack_frame_: " << last_ack_frame_
<< ", least_unacked: " << unacked_packets_.GetLeastUnacked()
<< ", packets_acked_: " << packets_acked_;
} else {
QUIC_PEER_BUG << "Received " << ack_decrypted_level
<< " ack for unackable packet: "
<< acked_packet.packet_number << " with state: "
<< QuicUtils::SentPacketStateToString(info->state);
if (supports_multiple_packet_number_spaces()) {
if (info->state == NEVER_SENT) {
return UNSENT_PACKETS_ACKED;
}
return UNACKABLE_PACKETS_ACKED;
}
}
continue;
}
QUIC_DVLOG(1) << ENDPOINT << "Got an " << ack_decrypted_level
<< " ack for packet " << acked_packet.packet_number
<< " , state: "
<< QuicUtils::SentPacketStateToString(info->state);
const PacketNumberSpace packet_number_space =
unacked_packets_.GetPacketNumberSpace(info->encryption_level);
if (supports_multiple_packet_number_spaces() &&
QuicUtils::GetPacketNumberSpace(ack_decrypted_level) !=
packet_number_space) {
return PACKETS_ACKED_IN_WRONG_PACKET_NUMBER_SPACE;
}
last_ack_frame_.packets.Add(acked_packet.packet_number);
if (info->encryption_level == ENCRYPTION_HANDSHAKE) {
handshake_packet_acked_ = true;
} else if (info->encryption_level == ENCRYPTION_ZERO_RTT) {
zero_rtt_packet_acked_ = true;
} else if (info->encryption_level == ENCRYPTION_FORWARD_SECURE) {
one_rtt_packet_acked_ = true;
}
largest_packet_peer_knows_is_acked_.UpdateMax(info->largest_acked);
if (supports_multiple_packet_number_spaces()) {
largest_packets_peer_knows_is_acked_[packet_number_space].UpdateMax(
info->largest_acked);
}
// If data is associated with the most recent transmission of this
// packet, then inform the caller.
if (info->in_flight) {
acked_packet.bytes_acked = info->bytes_sent;
} else {
// Unackable packets are skipped earlier.
largest_newly_acked_ = acked_packet.packet_number;
}
unacked_packets_.MaybeUpdateLargestAckedOfPacketNumberSpace(
packet_number_space, acked_packet.packet_number);
MarkPacketHandled(acked_packet.packet_number, info, ack_receive_time,
last_ack_frame_.ack_delay_time,
acked_packet.receive_timestamp);
}
const bool acked_new_packet = !packets_acked_.empty();
PostProcessNewlyAckedPackets(ack_packet_number, ack_decrypted_level,
last_ack_frame_, ack_receive_time, rtt_updated_,
prior_bytes_in_flight);
return acked_new_packet ? PACKETS_NEWLY_ACKED : NO_PACKETS_NEWLY_ACKED;
}
void QuicSentPacketManager::SetDebugDelegate(DebugDelegate* debug_delegate) {
debug_delegate_ = debug_delegate;
}
void QuicSentPacketManager::OnApplicationLimited() {
if (using_pacing_) {
pacing_sender_.OnApplicationLimited();
}
send_algorithm_->OnApplicationLimited(unacked_packets_.bytes_in_flight());
if (debug_delegate_ != nullptr) {
debug_delegate_->OnApplicationLimited();
}
}
NextReleaseTimeResult QuicSentPacketManager::GetNextReleaseTime() const {
if (!using_pacing_) {
return {QuicTime::Zero(), false};
}
return pacing_sender_.GetNextReleaseTime();
}
void QuicSentPacketManager::SetInitialRtt(QuicTime::Delta rtt) {
const QuicTime::Delta min_rtt =
QuicTime::Delta::FromMicroseconds(kMinInitialRoundTripTimeUs);
QuicTime::Delta max_rtt =
QuicTime::Delta::FromMicroseconds(kMaxInitialRoundTripTimeUs);
rtt_stats_.set_initial_rtt(std::max(min_rtt, std::min(max_rtt, rtt)));
}
void QuicSentPacketManager::EnableMultiplePacketNumberSpacesSupport() {
EnableIetfPtoAndLossDetection();
unacked_packets_.EnableMultiplePacketNumberSpacesSupport();
}
QuicPacketNumber QuicSentPacketManager::GetLargestAckedPacket(
EncryptionLevel decrypted_packet_level) const {
DCHECK(supports_multiple_packet_number_spaces());
return unacked_packets_.GetLargestAckedOfPacketNumberSpace(
QuicUtils::GetPacketNumberSpace(decrypted_packet_level));
}
QuicPacketNumber QuicSentPacketManager::GetLeastPacketAwaitedByPeer(
EncryptionLevel encryption_level) const {
QuicPacketNumber largest_acked;
if (supports_multiple_packet_number_spaces()) {
largest_acked = GetLargestAckedPacket(encryption_level);
} else {
largest_acked = GetLargestObserved();
}
if (!largest_acked.IsInitialized()) {
// If no packets have been acked, return the first sent packet to ensure
// we use a large enough packet number length.
return FirstSendingPacketNumber();
}
QuicPacketNumber least_awaited = largest_acked + 1;
QuicPacketNumber least_unacked = GetLeastUnacked();
if (least_unacked.IsInitialized() && least_unacked < least_awaited) {
least_awaited = least_unacked;
}
return least_awaited;
}
QuicPacketNumber QuicSentPacketManager::GetLargestPacketPeerKnowsIsAcked(
EncryptionLevel decrypted_packet_level) const {
DCHECK(supports_multiple_packet_number_spaces());
return largest_packets_peer_knows_is_acked_[QuicUtils::GetPacketNumberSpace(
decrypted_packet_level)];
}
QuicTime::Delta
QuicSentPacketManager::GetNConsecutiveRetransmissionTimeoutDelay(
int num_timeouts) const {
QuicTime::Delta total_delay = QuicTime::Delta::Zero();
const QuicTime::Delta srtt = rtt_stats_.SmoothedOrInitialRtt();
int num_tlps =
std::min(num_timeouts, static_cast<int>(max_tail_loss_probes_));
num_timeouts -= num_tlps;
if (num_tlps > 0) {
if (enable_half_rtt_tail_loss_probe_ &&
unacked_packets().HasUnackedStreamData()) {
total_delay = total_delay + std::max(min_tlp_timeout_, srtt * 0.5);
--num_tlps;
}
if (num_tlps > 0) {
const QuicTime::Delta tlp_delay =
std::max(2 * srtt, unacked_packets_.HasMultipleInFlightPackets()
? min_tlp_timeout_
: (1.5 * srtt + (min_rto_timeout_ * 0.5)));
total_delay = total_delay + num_tlps * tlp_delay;
}
}
if (num_timeouts == 0) {
return total_delay;
}
const QuicTime::Delta retransmission_delay =
rtt_stats_.smoothed_rtt().IsZero()
? QuicTime::Delta::FromMilliseconds(kDefaultRetransmissionTimeMs)
: std::max(srtt + 4 * rtt_stats_.mean_deviation(), min_rto_timeout_);
total_delay = total_delay + ((1 << num_timeouts) - 1) * retransmission_delay;
return total_delay;
}
bool QuicSentPacketManager::PeerCompletedAddressValidation() const {
if (unacked_packets_.perspective() == Perspective::IS_SERVER ||
!handshake_mode_disabled_) {
return true;
}
// To avoid handshake deadlock due to anti-amplification limit, client needs
// to set PTO timer until server successfully processed any HANDSHAKE packet.
return handshake_finished_ || handshake_packet_acked_;
}
bool QuicSentPacketManager::IsLessThanThreePTOs(QuicTime::Delta timeout) const {
return timeout < 3 * GetPtoDelay();
}
QuicTime::Delta QuicSentPacketManager::GetPtoDelay() const {
return pto_enabled_ ? GetProbeTimeoutDelay(APPLICATION_DATA)
: GetRetransmissionDelay();
}
void QuicSentPacketManager::OnAckFrequencyFrameSent(
const QuicAckFrequencyFrame& ack_frequency_frame) {
in_use_sent_ack_delays_.emplace_back(ack_frequency_frame.max_ack_delay,
ack_frequency_frame.sequence_number);
if (ack_frequency_frame.max_ack_delay > peer_max_ack_delay_) {
peer_max_ack_delay_ = ack_frequency_frame.max_ack_delay;
}
}
void QuicSentPacketManager::OnAckFrequencyFrameAcked(
const QuicAckFrequencyFrame& ack_frequency_frame) {
int stale_entry_count = 0;
for (auto it = in_use_sent_ack_delays_.cbegin();
it != in_use_sent_ack_delays_.cend(); ++it) {
if (it->second < ack_frequency_frame.sequence_number) {
++stale_entry_count;
} else {
break;
}
}
if (stale_entry_count > 0) {
in_use_sent_ack_delays_.pop_front_n(stale_entry_count);
}
if (in_use_sent_ack_delays_.empty()) {
QUIC_BUG << "in_use_sent_ack_delays_ is empty.";
return;
}
peer_max_ack_delay_ = std::max_element(in_use_sent_ack_delays_.cbegin(),
in_use_sent_ack_delays_.cend())
->first;
}
#undef ENDPOINT // undef for jumbo builds
} // namespace quic