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quiche / quiche / 1e0e142e5c44e993e7ecfb2b19174a9bf8b750c3 / . / quic / core / congestion_control / bbr2_probe_bw.cc
blob: 1b01d9d10457ded738641e54bf1e08bdecb3d142 [file] [log] [blame]
// Copyright 2019 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/bbr2_probe_bw.h"
#include "net/third_party/quiche/src/quic/core/congestion_control/bbr2_misc.h"
#include "net/third_party/quiche/src/quic/core/congestion_control/bbr2_sender.h"
#include "net/third_party/quiche/src/quic/core/quic_bandwidth.h"
#include "net/third_party/quiche/src/quic/core/quic_time.h"
#include "net/third_party/quiche/src/quic/core/quic_types.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 {
void Bbr2ProbeBwMode::Enter(QuicTime now,
const Bbr2CongestionEvent* /*congestion_event*/) {
if (cycle_.phase == CyclePhase::PROBE_NOT_STARTED) {
// First time entering PROBE_BW. Start a new probing cycle.
EnterProbeDown(/*probed_too_high=*/false, /*stopped_risky_probe=*/false,
now);
} else {
// Transitioning from PROBE_RTT to PROBE_BW. Re-enter the last phase before
// PROBE_RTT.
DCHECK(cycle_.phase == CyclePhase::PROBE_CRUISE ||
cycle_.phase == CyclePhase::PROBE_REFILL);
cycle_.cycle_start_time = now;
if (cycle_.phase == CyclePhase::PROBE_CRUISE) {
EnterProbeCruise(now);
} else if (cycle_.phase == CyclePhase::PROBE_REFILL) {
EnterProbeRefill(cycle_.probe_up_rounds, now);
}
}
}
Bbr2Mode Bbr2ProbeBwMode::OnCongestionEvent(
QuicByteCount prior_in_flight,
QuicTime event_time,
const AckedPacketVector& /*acked_packets*/,
const LostPacketVector& /*lost_packets*/,
const Bbr2CongestionEvent& congestion_event) {
DCHECK_NE(cycle_.phase, CyclePhase::PROBE_NOT_STARTED);
if (congestion_event.end_of_round_trip) {
if (cycle_.cycle_start_time != event_time) {
++cycle_.rounds_since_probe;
}
if (cycle_.phase_start_time != event_time) {
++cycle_.rounds_in_phase;
}
}
bool switch_to_probe_rtt = false;
if (cycle_.phase == CyclePhase::PROBE_UP) {
UpdateProbeUp(prior_in_flight, congestion_event);
} else if (cycle_.phase == CyclePhase::PROBE_DOWN) {
UpdateProbeDown(prior_in_flight, congestion_event);
// Maybe transition to PROBE_RTT at the end of this cycle.
if (cycle_.phase != CyclePhase::PROBE_DOWN &&
model_->MaybeExpireMinRtt(congestion_event)) {
switch_to_probe_rtt = true;
}
} else if (cycle_.phase == CyclePhase::PROBE_CRUISE) {
UpdateProbeCruise(congestion_event);
} else if (cycle_.phase == CyclePhase::PROBE_REFILL) {
UpdateProbeRefill(congestion_event);
}
// Do not need to set the gains if switching to PROBE_RTT, they will be set
// when Bbr2ProbeRttMode::Enter is called.
if (!switch_to_probe_rtt) {
model_->set_pacing_gain(PacingGainForPhase(cycle_.phase));
model_->set_cwnd_gain(Params().probe_bw_cwnd_gain);
}
return switch_to_probe_rtt ? Bbr2Mode::PROBE_RTT : Bbr2Mode::PROBE_BW;
}
Limits<QuicByteCount> Bbr2ProbeBwMode::GetCwndLimits() const {
if (!GetQuicReloadableFlag(quic_bbr2_avoid_too_low_probe_bw_cwnd)) {
if (cycle_.phase == CyclePhase::PROBE_CRUISE) {
return NoGreaterThan(
std::min(model_->inflight_lo(), model_->inflight_hi_with_headroom()));
}
return NoGreaterThan(
std::min(model_->inflight_lo(), model_->inflight_hi()));
}
QUIC_RELOADABLE_FLAG_COUNT(quic_bbr2_avoid_too_low_probe_bw_cwnd);
QuicByteCount upper_limit =
std::min(model_->inflight_lo(), cycle_.phase == CyclePhase::PROBE_CRUISE
? model_->inflight_hi_with_headroom()
: model_->inflight_hi());
if (Params().avoid_too_low_probe_bw_cwnd) {
// Ensure upper_limit is at least BDP + AckHeight.
QuicByteCount bdp_with_ack_height =
model_->BDP(model_->MaxBandwidth()) + model_->MaxAckHeight();
if (upper_limit < bdp_with_ack_height) {
QUIC_DVLOG(3) << sender_ << " Rasing upper_limit from " << upper_limit
<< " to " << bdp_with_ack_height;
QUIC_CODE_COUNT(quic_bbr2_avoid_too_low_probe_bw_cwnd_in_effect);
upper_limit = bdp_with_ack_height;
}
}
return NoGreaterThan(upper_limit);
}
bool Bbr2ProbeBwMode::IsProbingForBandwidth() const {
return cycle_.phase == CyclePhase::PROBE_REFILL ||
cycle_.phase == CyclePhase::PROBE_UP;
}
Bbr2Mode Bbr2ProbeBwMode::OnExitQuiescence(QuicTime now,
QuicTime quiescence_start_time) {
QUIC_DVLOG(3) << sender_ << " Postponing min_rtt_timestamp("
<< model_->MinRttTimestamp() << ") by "
<< now - quiescence_start_time;
model_->PostponeMinRttTimestamp(now - quiescence_start_time);
return Bbr2Mode::PROBE_BW;
}
// TODO(ianswett): Remove prior_in_flight from UpdateProbeDown.
void Bbr2ProbeBwMode::UpdateProbeDown(
QuicByteCount prior_in_flight,
const Bbr2CongestionEvent& congestion_event) {
DCHECK_EQ(cycle_.phase, CyclePhase::PROBE_DOWN);
if (cycle_.rounds_in_phase == 1 && congestion_event.end_of_round_trip) {
cycle_.is_sample_from_probing = false;
if (!congestion_event.last_sample_is_app_limited) {
QUIC_DVLOG(2)
<< sender_
<< " Advancing max bw filter after one round in PROBE_DOWN.";
model_->AdvanceMaxBandwidthFilter();
cycle_.has_advanced_max_bw = true;
}
if (last_cycle_stopped_risky_probe_ && !last_cycle_probed_too_high_) {
EnterProbeRefill(/*probe_up_rounds=*/0, congestion_event.event_time);
return;
}
}
MaybeAdaptUpperBounds(congestion_event);
if (IsTimeToProbeBandwidth(congestion_event)) {
EnterProbeRefill(/*probe_up_rounds=*/0, congestion_event.event_time);
return;
}
if (HasStayedLongEnoughInProbeDown(congestion_event)) {
QUIC_DVLOG(3) << sender_ << " Proportional time based PROBE_DOWN exit";
EnterProbeCruise(congestion_event.event_time);
return;
}
const QuicByteCount inflight_with_headroom =
model_->inflight_hi_with_headroom();
QUIC_DVLOG(3)
<< sender_
<< " Checking if have enough inflight headroom. prior_in_flight:"
<< prior_in_flight << " congestion_event.bytes_in_flight:"
<< congestion_event.bytes_in_flight
<< ", inflight_with_headroom:" << inflight_with_headroom;
QuicByteCount bytes_in_flight = congestion_event.bytes_in_flight;
if (bytes_in_flight > inflight_with_headroom) {
// Stay in PROBE_DOWN.
return;
}
// Transition to PROBE_CRUISE iff we've drained to target.
QuicByteCount bdp = model_->BDP();
QUIC_DVLOG(3) << sender_ << " Checking if drained to target. bytes_in_flight:"
<< bytes_in_flight << ", bdp:" << bdp;
if (bytes_in_flight < bdp) {
EnterProbeCruise(congestion_event.event_time);
}
}
Bbr2ProbeBwMode::AdaptUpperBoundsResult Bbr2ProbeBwMode::MaybeAdaptUpperBounds(
const Bbr2CongestionEvent& congestion_event) {
const SendTimeState& send_state = congestion_event.last_packet_send_state;
if (!send_state.is_valid) {
QUIC_DVLOG(3) << sender_ << " " << cycle_.phase
<< ": NOT_ADAPTED_INVALID_SAMPLE";
return NOT_ADAPTED_INVALID_SAMPLE;
}
// TODO(ianswett): Rename to bytes_delivered if
// use_bytes_delivered_for_inflight_hi is default enabled.
QuicByteCount inflight_at_send = BytesInFlight(send_state);
if (Params().use_bytes_delivered_for_inflight_hi) {
if (congestion_event.last_packet_send_state.total_bytes_acked <=
model_->total_bytes_acked()) {
inflight_at_send =
model_->total_bytes_acked() -
congestion_event.last_packet_send_state.total_bytes_acked;
} else {
QUIC_BUG << "Total_bytes_acked(" << model_->total_bytes_acked()
<< ") < send_state.total_bytes_acked("
<< congestion_event.last_packet_send_state.total_bytes_acked
<< ")";
}
}
if (model_->IsInflightTooHigh(congestion_event,
Params().probe_bw_full_loss_count)) {
if (cycle_.is_sample_from_probing) {
cycle_.is_sample_from_probing = false;
if (!send_state.is_app_limited) {
const QuicByteCount inflight_target =
sender_->GetTargetBytesInflight() * (1.0 - Params().beta);
if (inflight_at_send >= inflight_target) {
// The new code does not change behavior.
QUIC_CODE_COUNT(quic_bbr2_cut_inflight_hi_gradually_noop);
} else {
// The new code actually cuts inflight_hi slower than before.
QUIC_CODE_COUNT(quic_bbr2_cut_inflight_hi_gradually_in_effect);
}
if (Params().limit_inflight_hi_by_max_delivered) {
QuicByteCount new_inflight_hi =
std::max(inflight_at_send, inflight_target);
if (new_inflight_hi >= model_->max_bytes_delivered_in_round()) {
QUIC_CODE_COUNT(quic_bbr2_cut_inflight_hi_max_delivered_noop);
} else {
QUIC_CODE_COUNT(quic_bbr2_cut_inflight_hi_max_delivered_in_effect);
new_inflight_hi = model_->max_bytes_delivered_in_round();
}
QUIC_DVLOG(3) << sender_
<< " Setting inflight_hi due to loss. new_inflight_hi:"
<< new_inflight_hi
<< ", inflight_at_send:" << inflight_at_send
<< ", inflight_target:" << inflight_target
<< ", max_bytes_delivered_in_round:"
<< model_->max_bytes_delivered_in_round() << " @ "
<< congestion_event.event_time;
model_->set_inflight_hi(new_inflight_hi);
} else {
model_->set_inflight_hi(std::max(inflight_at_send, inflight_target));
}
}
QUIC_DVLOG(3) << sender_ << " " << cycle_.phase
<< ": ADAPTED_PROBED_TOO_HIGH";
return ADAPTED_PROBED_TOO_HIGH;
}
return ADAPTED_OK;
}
if (model_->inflight_hi() == model_->inflight_hi_default()) {
QUIC_DVLOG(3) << sender_ << " " << cycle_.phase
<< ": NOT_ADAPTED_INFLIGHT_HIGH_NOT_SET";
return NOT_ADAPTED_INFLIGHT_HIGH_NOT_SET;
}
// Raise the upper bound for inflight.
if (inflight_at_send > model_->inflight_hi()) {
QUIC_DVLOG(3)
<< sender_ << " " << cycle_.phase
<< ": Adapting inflight_hi from inflight_at_send. inflight_at_send:"
<< inflight_at_send << ", old inflight_hi:" << model_->inflight_hi();
model_->set_inflight_hi(inflight_at_send);
}
return ADAPTED_OK;
}
bool Bbr2ProbeBwMode::IsTimeToProbeBandwidth(
const Bbr2CongestionEvent& congestion_event) const {
if (HasCycleLasted(cycle_.probe_wait_time, congestion_event)) {
return true;
}
if (IsTimeToProbeForRenoCoexistence(1.0, congestion_event)) {
++sender_->connection_stats_->bbr_num_short_cycles_for_reno_coexistence;
return true;
}
return false;
}
// QUIC only. Used to prevent a Bbr2 flow from staying in PROBE_DOWN for too
// long, as seen in some multi-sender simulator tests.
bool Bbr2ProbeBwMode::HasStayedLongEnoughInProbeDown(
const Bbr2CongestionEvent& congestion_event) const {
// Stay in PROBE_DOWN for at most the time of a min rtt, as it is done in
// BBRv1.
// TODO(wub): Consider exit after a full round instead, which typically
// indicates most(if not all) packets sent during PROBE_UP have been acked.
return HasPhaseLasted(model_->MinRtt(), congestion_event);
}
bool Bbr2ProbeBwMode::HasCycleLasted(
QuicTime::Delta duration,
const Bbr2CongestionEvent& congestion_event) const {
bool result =
(congestion_event.event_time - cycle_.cycle_start_time) > duration;
QUIC_DVLOG(3) << sender_ << " " << cycle_.phase
<< ": HasCycleLasted=" << result << ". elapsed:"
<< (congestion_event.event_time - cycle_.cycle_start_time)
<< ", duration:" << duration;
return result;
}
bool Bbr2ProbeBwMode::HasPhaseLasted(
QuicTime::Delta duration,
const Bbr2CongestionEvent& congestion_event) const {
bool result =
(congestion_event.event_time - cycle_.phase_start_time) > duration;
QUIC_DVLOG(3) << sender_ << " " << cycle_.phase
<< ": HasPhaseLasted=" << result << ". elapsed:"
<< (congestion_event.event_time - cycle_.phase_start_time)
<< ", duration:" << duration;
return result;
}
bool Bbr2ProbeBwMode::IsTimeToProbeForRenoCoexistence(
double probe_wait_fraction,
const Bbr2CongestionEvent& /*congestion_event*/) const {
uint64_t rounds = Params().probe_bw_probe_max_rounds;
if (Params().probe_bw_probe_reno_gain > 0.0) {
QuicByteCount target_bytes_inflight = sender_->GetTargetBytesInflight();
uint64_t reno_rounds = Params().probe_bw_probe_reno_gain *
target_bytes_inflight / kDefaultTCPMSS;
rounds = std::min(rounds, reno_rounds);
}
bool result = cycle_.rounds_since_probe >= (rounds * probe_wait_fraction);
QUIC_DVLOG(3) << sender_ << " " << cycle_.phase
<< ": IsTimeToProbeForRenoCoexistence=" << result
<< ". rounds_since_probe:" << cycle_.rounds_since_probe
<< ", rounds:" << rounds
<< ", probe_wait_fraction:" << probe_wait_fraction;
return result;
}
void Bbr2ProbeBwMode::RaiseInflightHighSlope() {
DCHECK_EQ(cycle_.phase, CyclePhase::PROBE_UP);
uint64_t growth_this_round = 1 << cycle_.probe_up_rounds;
// The number 30 below means |growth_this_round| is capped at 1G and the lower
// bound of |probe_up_bytes| is (practically) 1 mss, at this speed inflight_hi
// grows by approximately 1 packet per packet acked.
cycle_.probe_up_rounds = std::min<uint64_t>(cycle_.probe_up_rounds + 1, 30);
uint64_t probe_up_bytes = sender_->GetCongestionWindow() / growth_this_round;
cycle_.probe_up_bytes =
std::max<QuicByteCount>(probe_up_bytes, kDefaultTCPMSS);
QUIC_DVLOG(3) << sender_ << " Rasing inflight_hi slope. probe_up_rounds:"
<< cycle_.probe_up_rounds
<< ", probe_up_bytes:" << cycle_.probe_up_bytes;
}
void Bbr2ProbeBwMode::ProbeInflightHighUpward(
const Bbr2CongestionEvent& congestion_event) {
DCHECK_EQ(cycle_.phase, CyclePhase::PROBE_UP);
if (!model_->IsCongestionWindowLimited(congestion_event)) {
QUIC_DVLOG(3) << sender_
<< " Raising inflight_hi early return: Not cwnd limited.";
// Not fully utilizing cwnd, so can't safely grow.
return;
}
if (congestion_event.prior_cwnd < model_->inflight_hi()) {
QUIC_DVLOG(3)
<< sender_
<< " Raising inflight_hi early return: inflight_hi not fully used.";
// Not fully using inflight_hi, so don't grow it.
return;
}
// Increase inflight_hi by the number of probe_up_bytes within probe_up_acked.
cycle_.probe_up_acked += congestion_event.bytes_acked;
if (cycle_.probe_up_acked >= cycle_.probe_up_bytes) {
uint64_t delta = cycle_.probe_up_acked / cycle_.probe_up_bytes;
cycle_.probe_up_acked -= delta * cycle_.probe_up_bytes;
QuicByteCount new_inflight_hi =
model_->inflight_hi() + delta * kDefaultTCPMSS;
if (new_inflight_hi > model_->inflight_hi()) {
QUIC_DVLOG(3) << sender_ << " Raising inflight_hi from "
<< model_->inflight_hi() << " to " << new_inflight_hi
<< ". probe_up_bytes:" << cycle_.probe_up_bytes
<< ", delta:" << delta
<< ", (new)probe_up_acked:" << cycle_.probe_up_acked;
model_->set_inflight_hi(new_inflight_hi);
} else {
QUIC_BUG << "Not growing inflight_hi due to wrap around. Old value:"
<< model_->inflight_hi() << ", new value:" << new_inflight_hi;
}
}
if (congestion_event.end_of_round_trip) {
RaiseInflightHighSlope();
}
}
void Bbr2ProbeBwMode::UpdateProbeCruise(
const Bbr2CongestionEvent& congestion_event) {
DCHECK_EQ(cycle_.phase, CyclePhase::PROBE_CRUISE);
MaybeAdaptUpperBounds(congestion_event);
DCHECK(!cycle_.is_sample_from_probing);
if (IsTimeToProbeBandwidth(congestion_event)) {
EnterProbeRefill(/*probe_up_rounds=*/0, congestion_event.event_time);
return;
}
}
void Bbr2ProbeBwMode::UpdateProbeRefill(
const Bbr2CongestionEvent& congestion_event) {
DCHECK_EQ(cycle_.phase, CyclePhase::PROBE_REFILL);
MaybeAdaptUpperBounds(congestion_event);
DCHECK(!cycle_.is_sample_from_probing);
if (cycle_.rounds_in_phase > 0 && congestion_event.end_of_round_trip) {
EnterProbeUp(congestion_event.event_time);
return;
}
}
void Bbr2ProbeBwMode::UpdateProbeUp(
QuicByteCount prior_in_flight,
const Bbr2CongestionEvent& congestion_event) {
DCHECK_EQ(cycle_.phase, CyclePhase::PROBE_UP);
if (MaybeAdaptUpperBounds(congestion_event) == ADAPTED_PROBED_TOO_HIGH) {
EnterProbeDown(/*probed_too_high=*/true, /*stopped_risky_probe=*/false,
congestion_event.event_time);
return;
}
// TODO(wub): Consider exit PROBE_UP after a certain number(e.g. 64) of RTTs.
ProbeInflightHighUpward(congestion_event);
bool is_risky = false;
bool is_queuing = false;
if (last_cycle_probed_too_high_ && prior_in_flight >= model_->inflight_hi()) {
is_risky = true;
QUIC_DVLOG(3) << sender_
<< " Probe is too risky. last_cycle_probed_too_high_:"
<< last_cycle_probed_too_high_
<< ", prior_in_flight:" << prior_in_flight
<< ", inflight_hi:" << model_->inflight_hi();
// TCP uses min_rtt instead of a full round:
// HasPhaseLasted(model_->MinRtt(), congestion_event)
} else if (cycle_.rounds_in_phase > 0) {
const QuicByteCount bdp = model_->BDP();
QuicByteCount queuing_threshold_extra_bytes = 2 * kDefaultTCPMSS;
if (Params().add_ack_height_to_queueing_threshold) {
queuing_threshold_extra_bytes += model_->MaxAckHeight();
}
QuicByteCount queuing_threshold =
(Params().probe_bw_probe_inflight_gain * bdp) +
queuing_threshold_extra_bytes;
is_queuing = congestion_event.bytes_in_flight >= queuing_threshold;
QUIC_DVLOG(3) << sender_
<< " Checking if building up a queue. prior_in_flight:"
<< prior_in_flight
<< ", post_in_flight:" << congestion_event.bytes_in_flight
<< ", threshold:" << queuing_threshold
<< ", is_queuing:" << is_queuing
<< ", max_bw:" << model_->MaxBandwidth()
<< ", min_rtt:" << model_->MinRtt();
}
if (is_risky || is_queuing) {
EnterProbeDown(/*probed_too_high=*/false, /*stopped_risky_probe=*/is_risky,
congestion_event.event_time);
}
}
void Bbr2ProbeBwMode::EnterProbeDown(bool probed_too_high,
bool stopped_risky_probe,
QuicTime now) {
QUIC_DVLOG(2) << sender_ << " Phase change: " << cycle_.phase << " ==> "
<< CyclePhase::PROBE_DOWN << " after "
<< now - cycle_.phase_start_time << ", or "
<< cycle_.rounds_in_phase
<< " rounds. probed_too_high:" << probed_too_high
<< ", stopped_risky_probe:" << stopped_risky_probe << " @ "
<< now;
last_cycle_probed_too_high_ = probed_too_high;
last_cycle_stopped_risky_probe_ = stopped_risky_probe;
cycle_.cycle_start_time = now;
cycle_.phase = CyclePhase::PROBE_DOWN;
cycle_.rounds_in_phase = 0;
cycle_.phase_start_time = now;
++sender_->connection_stats_->bbr_num_cycles;
// Pick probe wait time.
cycle_.rounds_since_probe =
sender_->RandomUint64(Params().probe_bw_max_probe_rand_rounds);
cycle_.probe_wait_time =
Params().probe_bw_probe_base_duration +
QuicTime::Delta::FromMicroseconds(sender_->RandomUint64(
Params().probe_bw_probe_max_rand_duration.ToMicroseconds()));
cycle_.probe_up_bytes = std::numeric_limits<QuicByteCount>::max();
cycle_.has_advanced_max_bw = false;
model_->RestartRound();
}
void Bbr2ProbeBwMode::EnterProbeCruise(QuicTime now) {
if (cycle_.phase == CyclePhase::PROBE_DOWN) {
ExitProbeDown();
}
QUIC_DVLOG(2) << sender_ << " Phase change: " << cycle_.phase << " ==> "
<< CyclePhase::PROBE_CRUISE << " after "
<< now - cycle_.phase_start_time << ", or "
<< cycle_.rounds_in_phase << " rounds. @ " << now;
model_->cap_inflight_lo(model_->inflight_hi());
cycle_.phase = CyclePhase::PROBE_CRUISE;
cycle_.rounds_in_phase = 0;
cycle_.phase_start_time = now;
cycle_.is_sample_from_probing = false;
}
void Bbr2ProbeBwMode::EnterProbeRefill(uint64_t probe_up_rounds, QuicTime now) {
if (cycle_.phase == CyclePhase::PROBE_DOWN) {
ExitProbeDown();
}
QUIC_DVLOG(2) << sender_ << " Phase change: " << cycle_.phase << " ==> "
<< CyclePhase::PROBE_REFILL << " after "
<< now - cycle_.phase_start_time << ", or "
<< cycle_.rounds_in_phase
<< " rounds. probe_up_rounds:" << probe_up_rounds << " @ "
<< now;
cycle_.phase = CyclePhase::PROBE_REFILL;
cycle_.rounds_in_phase = 0;
cycle_.phase_start_time = now;
cycle_.is_sample_from_probing = false;
last_cycle_stopped_risky_probe_ = false;
model_->clear_bandwidth_lo();
model_->clear_inflight_lo();
cycle_.probe_up_rounds = probe_up_rounds;
cycle_.probe_up_acked = 0;
model_->RestartRound();
}
void Bbr2ProbeBwMode::EnterProbeUp(QuicTime now) {
DCHECK_EQ(cycle_.phase, CyclePhase::PROBE_REFILL);
QUIC_DVLOG(2) << sender_ << " Phase change: " << cycle_.phase << " ==> "
<< CyclePhase::PROBE_UP << " after "
<< now - cycle_.phase_start_time << ", or "
<< cycle_.rounds_in_phase << " rounds. @ " << now;
cycle_.phase = CyclePhase::PROBE_UP;
cycle_.rounds_in_phase = 0;
cycle_.phase_start_time = now;
cycle_.is_sample_from_probing = true;
RaiseInflightHighSlope();
model_->RestartRound();
}
void Bbr2ProbeBwMode::ExitProbeDown() {
DCHECK_EQ(cycle_.phase, CyclePhase::PROBE_DOWN);
if (!cycle_.has_advanced_max_bw) {
QUIC_DVLOG(2) << sender_ << " Advancing max bw filter at end of cycle.";
model_->AdvanceMaxBandwidthFilter();
cycle_.has_advanced_max_bw = true;
}
}
// static
const char* Bbr2ProbeBwMode::CyclePhaseToString(CyclePhase phase) {
switch (phase) {
case CyclePhase::PROBE_NOT_STARTED:
return "PROBE_NOT_STARTED";
case CyclePhase::PROBE_UP:
return "PROBE_UP";
case CyclePhase::PROBE_DOWN:
return "PROBE_DOWN";
case CyclePhase::PROBE_CRUISE:
return "PROBE_CRUISE";
case CyclePhase::PROBE_REFILL:
return "PROBE_REFILL";
default:
break;
}
return "<Invalid CyclePhase>";
}
std::ostream& operator<<(std::ostream& os,
const Bbr2ProbeBwMode::CyclePhase phase) {
return os << Bbr2ProbeBwMode::CyclePhaseToString(phase);
}
Bbr2ProbeBwMode::DebugState Bbr2ProbeBwMode::ExportDebugState() const {
DebugState s;
s.phase = cycle_.phase;
s.cycle_start_time = cycle_.cycle_start_time;
s.phase_start_time = cycle_.phase_start_time;
return s;
}
std::ostream& operator<<(std::ostream& os,
const Bbr2ProbeBwMode::DebugState& state) {
os << "[PROBE_BW] phase: " << state.phase << "\n";
os << "[PROBE_BW] cycle_start_time: " << state.cycle_start_time << "\n";
os << "[PROBE_BW] phase_start_time: " << state.phase_start_time << "\n";
return os;
}
const Bbr2Params& Bbr2ProbeBwMode::Params() const {
return sender_->Params();
}
float Bbr2ProbeBwMode::PacingGainForPhase(
Bbr2ProbeBwMode::CyclePhase phase) const {
if (phase == Bbr2ProbeBwMode::CyclePhase::PROBE_UP) {
return Params().probe_bw_probe_up_pacing_gain;
}
if (phase == Bbr2ProbeBwMode::CyclePhase::PROBE_DOWN) {
return Params().probe_bw_probe_down_pacing_gain;
}
return Params().probe_bw_default_pacing_gain;
}
} // namespace quic