mihomo/transport/tuic/congestion_v2/bbr_sender.go
2024-06-05 11:56:27 +08:00

936 lines
32 KiB
Go

package congestion
// src from https://github.com/google/quiche/blob/e7872fc9e12bb1d46a118949c3d4da36de58aa44/quiche/quic/core/congestion_control/bbr_sender.cc
import (
"fmt"
"time"
"github.com/metacubex/quic-go"
"github.com/metacubex/quic-go/congestion"
"github.com/metacubex/randv2"
)
// BbrSender implements BBR congestion control algorithm. BBR aims to estimate
// the current available Bottleneck Bandwidth and RTT (hence the name), and
// regulates the pacing rate and the size of the congestion window based on
// those signals.
//
// BBR relies on pacing in order to function properly. Do not use BBR when
// pacing is disabled.
//
const (
minBps = 65536 // 64 kbps
invalidPacketNumber = -1
initialCongestionWindowPackets = 32
// Constants based on TCP defaults.
// The minimum CWND to ensure delayed acks don't reduce bandwidth measurements.
// Does not inflate the pacing rate.
defaultMinimumCongestionWindow = 4 * congestion.ByteCount(congestion.InitialPacketSize)
// The gain used for the STARTUP, equal to 2/ln(2).
defaultHighGain = 2.885
// The newly derived gain for STARTUP, equal to 4 * ln(2)
derivedHighGain = 2.773
// The newly derived CWND gain for STARTUP, 2.
derivedHighCWNDGain = 2.0
)
// The cycle of gains used during the PROBE_BW stage.
var pacingGain = [...]float64{1.25, 0.75, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0}
const (
// The length of the gain cycle.
gainCycleLength = len(pacingGain)
// The size of the bandwidth filter window, in round-trips.
bandwidthWindowSize = gainCycleLength + 2
// The time after which the current min_rtt value expires.
minRttExpiry = 10 * time.Second
// The minimum time the connection can spend in PROBE_RTT mode.
probeRttTime = 200 * time.Millisecond
// If the bandwidth does not increase by the factor of |kStartupGrowthTarget|
// within |kRoundTripsWithoutGrowthBeforeExitingStartup| rounds, the connection
// will exit the STARTUP mode.
startupGrowthTarget = 1.25
roundTripsWithoutGrowthBeforeExitingStartup = int64(3)
// Flag.
defaultStartupFullLossCount = 8
quicBbr2DefaultLossThreshold = 0.02
maxBbrBurstPackets = 10
)
type bbrMode int
const (
// Startup phase of the connection.
bbrModeStartup = iota
// After achieving the highest possible bandwidth during the startup, lower
// the pacing rate in order to drain the queue.
bbrModeDrain
// Cruising mode.
bbrModeProbeBw
// Temporarily slow down sending in order to empty the buffer and measure
// the real minimum RTT.
bbrModeProbeRtt
)
// Indicates how the congestion control limits the amount of bytes in flight.
type bbrRecoveryState int
const (
// Do not limit.
bbrRecoveryStateNotInRecovery = iota
// Allow an extra outstanding byte for each byte acknowledged.
bbrRecoveryStateConservation
// Allow two extra outstanding bytes for each byte acknowledged (slow
// start).
bbrRecoveryStateGrowth
)
type bbrSender struct {
rttStats congestion.RTTStatsProvider
clock Clock
pacer *Pacer
mode bbrMode
// Bandwidth sampler provides BBR with the bandwidth measurements at
// individual points.
sampler *bandwidthSampler
// The number of the round trips that have occurred during the connection.
roundTripCount roundTripCount
// The packet number of the most recently sent packet.
lastSentPacket congestion.PacketNumber
// Acknowledgement of any packet after |current_round_trip_end_| will cause
// the round trip counter to advance.
currentRoundTripEnd congestion.PacketNumber
// Number of congestion events with some losses, in the current round.
numLossEventsInRound uint64
// Number of total bytes lost in the current round.
bytesLostInRound congestion.ByteCount
// The filter that tracks the maximum bandwidth over the multiple recent
// round-trips.
maxBandwidth *WindowedFilter[Bandwidth, roundTripCount]
// Minimum RTT estimate. Automatically expires within 10 seconds (and
// triggers PROBE_RTT mode) if no new value is sampled during that period.
minRtt time.Duration
// The time at which the current value of |min_rtt_| was assigned.
minRttTimestamp time.Time
// The maximum allowed number of bytes in flight.
congestionWindow congestion.ByteCount
// The initial value of the |congestion_window_|.
initialCongestionWindow congestion.ByteCount
// The largest value the |congestion_window_| can achieve.
maxCongestionWindow congestion.ByteCount
// The smallest value the |congestion_window_| can achieve.
minCongestionWindow congestion.ByteCount
// The pacing gain applied during the STARTUP phase.
highGain float64
// The CWND gain applied during the STARTUP phase.
highCwndGain float64
// The pacing gain applied during the DRAIN phase.
drainGain float64
// The current pacing rate of the connection.
pacingRate Bandwidth
// The gain currently applied to the pacing rate.
pacingGain float64
// The gain currently applied to the congestion window.
congestionWindowGain float64
// The gain used for the congestion window during PROBE_BW. Latched from
// quic_bbr_cwnd_gain flag.
congestionWindowGainConstant float64
// The number of RTTs to stay in STARTUP mode. Defaults to 3.
numStartupRtts int64
// Number of round-trips in PROBE_BW mode, used for determining the current
// pacing gain cycle.
cycleCurrentOffset int
// The time at which the last pacing gain cycle was started.
lastCycleStart time.Time
// Indicates whether the connection has reached the full bandwidth mode.
isAtFullBandwidth bool
// Number of rounds during which there was no significant bandwidth increase.
roundsWithoutBandwidthGain int64
// The bandwidth compared to which the increase is measured.
bandwidthAtLastRound Bandwidth
// Set to true upon exiting quiescence.
exitingQuiescence bool
// Time at which PROBE_RTT has to be exited. Setting it to zero indicates
// that the time is yet unknown as the number of packets in flight has not
// reached the required value.
exitProbeRttAt time.Time
// Indicates whether a round-trip has passed since PROBE_RTT became active.
probeRttRoundPassed bool
// Indicates whether the most recent bandwidth sample was marked as
// app-limited.
lastSampleIsAppLimited bool
// Indicates whether any non app-limited samples have been recorded.
hasNoAppLimitedSample bool
// Current state of recovery.
recoveryState bbrRecoveryState
// Receiving acknowledgement of a packet after |end_recovery_at_| will cause
// BBR to exit the recovery mode. A value above zero indicates at least one
// loss has been detected, so it must not be set back to zero.
endRecoveryAt congestion.PacketNumber
// A window used to limit the number of bytes in flight during loss recovery.
recoveryWindow congestion.ByteCount
// If true, consider all samples in recovery app-limited.
isAppLimitedRecovery bool // not used
// When true, pace at 1.5x and disable packet conservation in STARTUP.
slowerStartup bool // not used
// When true, disables packet conservation in STARTUP.
rateBasedStartup bool // not used
// When true, add the most recent ack aggregation measurement during STARTUP.
enableAckAggregationDuringStartup bool
// When true, expire the windowed ack aggregation values in STARTUP when
// bandwidth increases more than 25%.
expireAckAggregationInStartup bool
// If true, will not exit low gain mode until bytes_in_flight drops below BDP
// or it's time for high gain mode.
drainToTarget bool
// If true, slow down pacing rate in STARTUP when overshooting is detected.
detectOvershooting bool
// Bytes lost while detect_overshooting_ is true.
bytesLostWhileDetectingOvershooting congestion.ByteCount
// Slow down pacing rate if
// bytes_lost_while_detecting_overshooting_ *
// bytes_lost_multiplier_while_detecting_overshooting_ > IW.
bytesLostMultiplierWhileDetectingOvershooting uint8
// When overshooting is detected, do not drop pacing_rate_ below this value /
// min_rtt.
cwndToCalculateMinPacingRate congestion.ByteCount
// Max congestion window when adjusting network parameters.
maxCongestionWindowWithNetworkParametersAdjusted congestion.ByteCount // not used
// Params.
maxDatagramSize congestion.ByteCount
// Recorded on packet sent. equivalent |unacked_packets_->bytes_in_flight()|
bytesInFlight congestion.ByteCount
}
var _ congestion.CongestionControl = &bbrSender{}
func NewBbrSender(
clock Clock,
initialMaxDatagramSize congestion.ByteCount,
initialCongestionWindowPackets congestion.ByteCount,
) *bbrSender {
return newBbrSender(
clock,
initialMaxDatagramSize,
initialCongestionWindowPackets*initialMaxDatagramSize,
congestion.MaxCongestionWindowPackets*initialMaxDatagramSize,
)
}
func newBbrSender(
clock Clock,
initialMaxDatagramSize,
initialCongestionWindow,
initialMaxCongestionWindow congestion.ByteCount,
) *bbrSender {
b := &bbrSender{
clock: clock,
mode: bbrModeStartup,
sampler: newBandwidthSampler(roundTripCount(bandwidthWindowSize)),
lastSentPacket: invalidPacketNumber,
currentRoundTripEnd: invalidPacketNumber,
maxBandwidth: NewWindowedFilter(roundTripCount(bandwidthWindowSize), MaxFilter[Bandwidth]),
congestionWindow: initialCongestionWindow,
initialCongestionWindow: initialCongestionWindow,
maxCongestionWindow: initialMaxCongestionWindow,
minCongestionWindow: defaultMinimumCongestionWindow,
highGain: defaultHighGain,
highCwndGain: defaultHighGain,
drainGain: 1.0 / defaultHighGain,
pacingGain: 1.0,
congestionWindowGain: 1.0,
congestionWindowGainConstant: 2.0,
numStartupRtts: roundTripsWithoutGrowthBeforeExitingStartup,
recoveryState: bbrRecoveryStateNotInRecovery,
endRecoveryAt: invalidPacketNumber,
recoveryWindow: initialMaxCongestionWindow,
bytesLostMultiplierWhileDetectingOvershooting: 2,
cwndToCalculateMinPacingRate: initialCongestionWindow,
maxCongestionWindowWithNetworkParametersAdjusted: initialMaxCongestionWindow,
maxDatagramSize: initialMaxDatagramSize,
}
b.pacer = NewPacer(b.bandwidthForPacer)
/*
if b.tracer != nil {
b.lastState = logging.CongestionStateStartup
b.tracer.UpdatedCongestionState(logging.CongestionStateStartup)
}
*/
b.enterStartupMode(b.clock.Now())
b.setHighCwndGain(derivedHighCWNDGain)
return b
}
func (b *bbrSender) SetRTTStatsProvider(provider congestion.RTTStatsProvider) {
b.rttStats = provider
}
// TimeUntilSend implements the SendAlgorithm interface.
func (b *bbrSender) TimeUntilSend(bytesInFlight congestion.ByteCount) time.Time {
return b.pacer.TimeUntilSend()
}
// HasPacingBudget implements the SendAlgorithm interface.
func (b *bbrSender) HasPacingBudget(now time.Time) bool {
return b.pacer.Budget(now) >= b.maxDatagramSize
}
// OnPacketSent implements the SendAlgorithm interface.
func (b *bbrSender) OnPacketSent(
sentTime time.Time,
bytesInFlight congestion.ByteCount,
packetNumber congestion.PacketNumber,
bytes congestion.ByteCount,
isRetransmittable bool,
) {
b.pacer.SentPacket(sentTime, bytes)
b.lastSentPacket = packetNumber
b.bytesInFlight = bytesInFlight
if bytesInFlight == 0 {
b.exitingQuiescence = true
}
b.sampler.OnPacketSent(sentTime, packetNumber, bytes, bytesInFlight, isRetransmittable)
b.maybeAppLimited(bytesInFlight)
}
// CanSend implements the SendAlgorithm interface.
func (b *bbrSender) CanSend(bytesInFlight congestion.ByteCount) bool {
return bytesInFlight < b.GetCongestionWindow()
}
// MaybeExitSlowStart implements the SendAlgorithm interface.
func (b *bbrSender) MaybeExitSlowStart() {
// Do nothing
}
// OnPacketAcked implements the SendAlgorithm interface.
func (b *bbrSender) OnPacketAcked(number congestion.PacketNumber, ackedBytes, priorInFlight congestion.ByteCount, eventTime time.Time) {
// Do nothing.
}
// OnPacketLost implements the SendAlgorithm interface.
func (b *bbrSender) OnPacketLost(number congestion.PacketNumber, lostBytes, priorInFlight congestion.ByteCount) {
// Do nothing.
}
// OnRetransmissionTimeout implements the SendAlgorithm interface.
func (b *bbrSender) OnRetransmissionTimeout(packetsRetransmitted bool) {
// Do nothing.
}
// SetMaxDatagramSize implements the SendAlgorithm interface.
func (b *bbrSender) SetMaxDatagramSize(s congestion.ByteCount) {
if s < b.maxDatagramSize {
panic(fmt.Sprintf("congestion BUG: decreased max datagram size from %d to %d", b.maxDatagramSize, s))
}
cwndIsMinCwnd := b.congestionWindow == b.minCongestionWindow
b.maxDatagramSize = s
if cwndIsMinCwnd {
b.congestionWindow = b.minCongestionWindow
}
b.pacer.SetMaxDatagramSize(s)
}
// InSlowStart implements the SendAlgorithmWithDebugInfos interface.
func (b *bbrSender) InSlowStart() bool {
return b.mode == bbrModeStartup
}
// InRecovery implements the SendAlgorithmWithDebugInfos interface.
func (b *bbrSender) InRecovery() bool {
return b.recoveryState != bbrRecoveryStateNotInRecovery
}
// GetCongestionWindow implements the SendAlgorithmWithDebugInfos interface.
func (b *bbrSender) GetCongestionWindow() congestion.ByteCount {
if b.mode == bbrModeProbeRtt {
return b.probeRttCongestionWindow()
}
if b.InRecovery() {
return Min(b.congestionWindow, b.recoveryWindow)
}
return b.congestionWindow
}
func (b *bbrSender) OnCongestionEvent(number congestion.PacketNumber, lostBytes, priorInFlight congestion.ByteCount) {
// Do nothing.
}
func (b *bbrSender) OnCongestionEventEx(priorInFlight congestion.ByteCount, eventTime time.Time, ackedPackets []congestion.AckedPacketInfo, lostPackets []congestion.LostPacketInfo) {
totalBytesAckedBefore := b.sampler.TotalBytesAcked()
totalBytesLostBefore := b.sampler.TotalBytesLost()
var isRoundStart, minRttExpired bool
var excessAcked, bytesLost congestion.ByteCount
// The send state of the largest packet in acked_packets, unless it is
// empty. If acked_packets is empty, it's the send state of the largest
// packet in lost_packets.
var lastPacketSendState sendTimeState
// Update bytesInFlight
b.bytesInFlight = priorInFlight
for _, p := range ackedPackets {
b.bytesInFlight -= p.BytesAcked
}
for _, p := range lostPackets {
b.bytesInFlight -= p.BytesLost
}
if len(ackedPackets) != 0 {
lastAckedPacket := ackedPackets[len(ackedPackets)-1].PacketNumber
isRoundStart = b.updateRoundTripCounter(lastAckedPacket)
b.updateRecoveryState(lastAckedPacket, len(lostPackets) != 0, isRoundStart)
}
sample := b.sampler.OnCongestionEvent(eventTime,
ackedPackets, lostPackets, b.maxBandwidth.GetBest(), infBandwidth, b.roundTripCount)
if sample.lastPacketSendState.isValid {
b.lastSampleIsAppLimited = sample.lastPacketSendState.isAppLimited
b.hasNoAppLimitedSample = b.hasNoAppLimitedSample || !b.lastSampleIsAppLimited
}
// Avoid updating |max_bandwidth_| if a) this is a loss-only event, or b) all
// packets in |acked_packets| did not generate valid samples. (e.g. ack of
// ack-only packets). In both cases, sampler_.total_bytes_acked() will not
// change.
if totalBytesAckedBefore != b.sampler.TotalBytesAcked() {
if !sample.sampleIsAppLimited || sample.sampleMaxBandwidth > b.maxBandwidth.GetBest() {
b.maxBandwidth.Update(sample.sampleMaxBandwidth, b.roundTripCount)
}
}
if sample.sampleRtt != infRTT {
minRttExpired = b.maybeUpdateMinRtt(eventTime, sample.sampleRtt)
}
bytesLost = b.sampler.TotalBytesLost() - totalBytesLostBefore
excessAcked = sample.extraAcked
lastPacketSendState = sample.lastPacketSendState
if len(lostPackets) != 0 {
b.numLossEventsInRound++
b.bytesLostInRound += bytesLost
}
// Handle logic specific to PROBE_BW mode.
if b.mode == bbrModeProbeBw {
b.updateGainCyclePhase(eventTime, priorInFlight, len(lostPackets) != 0)
}
// Handle logic specific to STARTUP and DRAIN modes.
if isRoundStart && !b.isAtFullBandwidth {
b.checkIfFullBandwidthReached(&lastPacketSendState)
}
b.maybeExitStartupOrDrain(eventTime)
// Handle logic specific to PROBE_RTT.
b.maybeEnterOrExitProbeRtt(eventTime, isRoundStart, minRttExpired)
// Calculate number of packets acked and lost.
bytesAcked := b.sampler.TotalBytesAcked() - totalBytesAckedBefore
// After the model is updated, recalculate the pacing rate and congestion
// window.
b.calculatePacingRate(bytesLost)
b.calculateCongestionWindow(bytesAcked, excessAcked)
b.calculateRecoveryWindow(bytesAcked, bytesLost)
// Cleanup internal state.
// This is where we clean up obsolete (acked or lost) packets from the bandwidth sampler.
// The "least unacked" should actually be FirstOutstanding, but since we are not passing
// that through OnCongestionEventEx, we will only do an estimate using acked/lost packets
// for now. Because of fast retransmission, they should differ by no more than 2 packets.
// (this is controlled by packetThreshold in quic-go's sentPacketHandler)
var leastUnacked congestion.PacketNumber
if len(ackedPackets) != 0 {
leastUnacked = ackedPackets[len(ackedPackets)-1].PacketNumber - 2
} else {
leastUnacked = lostPackets[len(lostPackets)-1].PacketNumber + 1
}
b.sampler.RemoveObsoletePackets(leastUnacked)
if isRoundStart {
b.numLossEventsInRound = 0
b.bytesLostInRound = 0
}
}
func (b *bbrSender) PacingRate() Bandwidth {
if b.pacingRate == 0 {
return Bandwidth(b.highGain * float64(
BandwidthFromDelta(b.initialCongestionWindow, b.getMinRtt())))
}
return b.pacingRate
}
func (b *bbrSender) hasGoodBandwidthEstimateForResumption() bool {
return b.hasNonAppLimitedSample()
}
func (b *bbrSender) hasNonAppLimitedSample() bool {
return b.hasNoAppLimitedSample
}
// Sets the pacing gain used in STARTUP. Must be greater than 1.
func (b *bbrSender) setHighGain(highGain float64) {
b.highGain = highGain
if b.mode == bbrModeStartup {
b.pacingGain = highGain
}
}
// Sets the CWND gain used in STARTUP. Must be greater than 1.
func (b *bbrSender) setHighCwndGain(highCwndGain float64) {
b.highCwndGain = highCwndGain
if b.mode == bbrModeStartup {
b.congestionWindowGain = highCwndGain
}
}
// Sets the gain used in DRAIN. Must be less than 1.
func (b *bbrSender) setDrainGain(drainGain float64) {
b.drainGain = drainGain
}
// Get the current bandwidth estimate. Note that Bandwidth is in bits per second.
func (b *bbrSender) bandwidthEstimate() Bandwidth {
return b.maxBandwidth.GetBest()
}
func (b *bbrSender) bandwidthForPacer() congestion.ByteCount {
bps := congestion.ByteCount(float64(b.bandwidthEstimate()) * b.congestionWindowGain / float64(BytesPerSecond))
if bps < minBps {
// We need to make sure that the bandwidth value for pacer is never zero,
// otherwise it will go into an edge case where HasPacingBudget = false
// but TimeUntilSend is before, causing the quic-go send loop to go crazy and get stuck.
return minBps
}
return bps
}
// Returns the current estimate of the RTT of the connection. Outside of the
// edge cases, this is minimum RTT.
func (b *bbrSender) getMinRtt() time.Duration {
if b.minRtt != 0 {
return b.minRtt
}
// min_rtt could be available if the handshake packet gets neutered then
// gets acknowledged. This could only happen for QUIC crypto where we do not
// drop keys.
minRtt := b.rttStats.MinRTT()
if minRtt == 0 {
return 100 * time.Millisecond
} else {
return minRtt
}
}
// Computes the target congestion window using the specified gain.
func (b *bbrSender) getTargetCongestionWindow(gain float64) congestion.ByteCount {
bdp := bdpFromRttAndBandwidth(b.getMinRtt(), b.bandwidthEstimate())
congestionWindow := congestion.ByteCount(gain * float64(bdp))
// BDP estimate will be zero if no bandwidth samples are available yet.
if congestionWindow == 0 {
congestionWindow = congestion.ByteCount(gain * float64(b.initialCongestionWindow))
}
return Max(congestionWindow, b.minCongestionWindow)
}
// The target congestion window during PROBE_RTT.
func (b *bbrSender) probeRttCongestionWindow() congestion.ByteCount {
return b.minCongestionWindow
}
func (b *bbrSender) maybeUpdateMinRtt(now time.Time, sampleMinRtt time.Duration) bool {
// Do not expire min_rtt if none was ever available.
minRttExpired := b.minRtt != 0 && now.After(b.minRttTimestamp.Add(minRttExpiry))
if minRttExpired || sampleMinRtt < b.minRtt || b.minRtt == 0 {
b.minRtt = sampleMinRtt
b.minRttTimestamp = now
}
return minRttExpired
}
// Enters the STARTUP mode.
func (b *bbrSender) enterStartupMode(now time.Time) {
b.mode = bbrModeStartup
// b.maybeTraceStateChange(logging.CongestionStateStartup)
b.pacingGain = b.highGain
b.congestionWindowGain = b.highCwndGain
}
// Enters the PROBE_BW mode.
func (b *bbrSender) enterProbeBandwidthMode(now time.Time) {
b.mode = bbrModeProbeBw
// b.maybeTraceStateChange(logging.CongestionStateProbeBw)
b.congestionWindowGain = b.congestionWindowGainConstant
// Pick a random offset for the gain cycle out of {0, 2..7} range. 1 is
// excluded because in that case increased gain and decreased gain would not
// follow each other.
b.cycleCurrentOffset = int(randv2.Int32N(congestion.PacketsPerConnectionID)) % (gainCycleLength - 1)
if b.cycleCurrentOffset >= 1 {
b.cycleCurrentOffset += 1
}
b.lastCycleStart = now
b.pacingGain = pacingGain[b.cycleCurrentOffset]
}
// Updates the round-trip counter if a round-trip has passed. Returns true if
// the counter has been advanced.
func (b *bbrSender) updateRoundTripCounter(lastAckedPacket congestion.PacketNumber) bool {
if b.currentRoundTripEnd == invalidPacketNumber || lastAckedPacket > b.currentRoundTripEnd {
b.roundTripCount++
b.currentRoundTripEnd = b.lastSentPacket
return true
}
return false
}
// Updates the current gain used in PROBE_BW mode.
func (b *bbrSender) updateGainCyclePhase(now time.Time, priorInFlight congestion.ByteCount, hasLosses bool) {
// In most cases, the cycle is advanced after an RTT passes.
shouldAdvanceGainCycling := now.After(b.lastCycleStart.Add(b.getMinRtt()))
// If the pacing gain is above 1.0, the connection is trying to probe the
// bandwidth by increasing the number of bytes in flight to at least
// pacing_gain * BDP. Make sure that it actually reaches the target, as long
// as there are no losses suggesting that the buffers are not able to hold
// that much.
if b.pacingGain > 1.0 && !hasLosses && priorInFlight < b.getTargetCongestionWindow(b.pacingGain) {
shouldAdvanceGainCycling = false
}
// If pacing gain is below 1.0, the connection is trying to drain the extra
// queue which could have been incurred by probing prior to it. If the number
// of bytes in flight falls down to the estimated BDP value earlier, conclude
// that the queue has been successfully drained and exit this cycle early.
if b.pacingGain < 1.0 && b.bytesInFlight <= b.getTargetCongestionWindow(1) {
shouldAdvanceGainCycling = true
}
if shouldAdvanceGainCycling {
b.cycleCurrentOffset = (b.cycleCurrentOffset + 1) % gainCycleLength
b.lastCycleStart = now
// Stay in low gain mode until the target BDP is hit.
// Low gain mode will be exited immediately when the target BDP is achieved.
if b.drainToTarget && b.pacingGain < 1 &&
pacingGain[b.cycleCurrentOffset] == 1 &&
b.bytesInFlight > b.getTargetCongestionWindow(1) {
return
}
b.pacingGain = pacingGain[b.cycleCurrentOffset]
}
}
// Tracks for how many round-trips the bandwidth has not increased
// significantly.
func (b *bbrSender) checkIfFullBandwidthReached(lastPacketSendState *sendTimeState) {
if b.lastSampleIsAppLimited {
return
}
target := Bandwidth(float64(b.bandwidthAtLastRound) * startupGrowthTarget)
if b.bandwidthEstimate() >= target {
b.bandwidthAtLastRound = b.bandwidthEstimate()
b.roundsWithoutBandwidthGain = 0
if b.expireAckAggregationInStartup {
// Expire old excess delivery measurements now that bandwidth increased.
b.sampler.ResetMaxAckHeightTracker(0, b.roundTripCount)
}
return
}
b.roundsWithoutBandwidthGain++
if b.roundsWithoutBandwidthGain >= b.numStartupRtts ||
b.shouldExitStartupDueToLoss(lastPacketSendState) {
b.isAtFullBandwidth = true
}
}
func (b *bbrSender) maybeAppLimited(bytesInFlight congestion.ByteCount) {
congestionWindow := b.GetCongestionWindow()
if bytesInFlight >= congestionWindow {
return
}
availableBytes := congestionWindow - bytesInFlight
if availableBytes > maxBbrBurstPackets*b.maxDatagramSize {
b.sampler.OnAppLimited()
}
}
// Transitions from STARTUP to DRAIN and from DRAIN to PROBE_BW if
// appropriate.
func (b *bbrSender) maybeExitStartupOrDrain(now time.Time) {
if b.mode == bbrModeStartup && b.isAtFullBandwidth {
b.mode = bbrModeDrain
// b.maybeTraceStateChange(logging.CongestionStateDrain)
b.pacingGain = b.drainGain
b.congestionWindowGain = b.highCwndGain
}
if b.mode == bbrModeDrain && b.bytesInFlight <= b.getTargetCongestionWindow(1) {
b.enterProbeBandwidthMode(now)
}
}
// Decides whether to enter or exit PROBE_RTT.
func (b *bbrSender) maybeEnterOrExitProbeRtt(now time.Time, isRoundStart, minRttExpired bool) {
if minRttExpired && !b.exitingQuiescence && b.mode != bbrModeProbeRtt {
b.mode = bbrModeProbeRtt
// b.maybeTraceStateChange(logging.CongestionStateProbRtt)
b.pacingGain = 1.0
// Do not decide on the time to exit PROBE_RTT until the |bytes_in_flight|
// is at the target small value.
b.exitProbeRttAt = time.Time{}
}
if b.mode == bbrModeProbeRtt {
b.sampler.OnAppLimited()
// b.maybeTraceStateChange(logging.CongestionStateApplicationLimited)
if b.exitProbeRttAt.IsZero() {
// If the window has reached the appropriate size, schedule exiting
// PROBE_RTT. The CWND during PROBE_RTT is kMinimumCongestionWindow, but
// we allow an extra packet since QUIC checks CWND before sending a
// packet.
if b.bytesInFlight < b.probeRttCongestionWindow()+congestion.MaxPacketBufferSize {
b.exitProbeRttAt = now.Add(probeRttTime)
b.probeRttRoundPassed = false
}
} else {
if isRoundStart {
b.probeRttRoundPassed = true
}
if now.Sub(b.exitProbeRttAt) >= 0 && b.probeRttRoundPassed {
b.minRttTimestamp = now
if !b.isAtFullBandwidth {
b.enterStartupMode(now)
} else {
b.enterProbeBandwidthMode(now)
}
}
}
}
b.exitingQuiescence = false
}
// Determines whether BBR needs to enter, exit or advance state of the
// recovery.
func (b *bbrSender) updateRecoveryState(lastAckedPacket congestion.PacketNumber, hasLosses, isRoundStart bool) {
// Disable recovery in startup, if loss-based exit is enabled.
if !b.isAtFullBandwidth {
return
}
// Exit recovery when there are no losses for a round.
if hasLosses {
b.endRecoveryAt = b.lastSentPacket
}
switch b.recoveryState {
case bbrRecoveryStateNotInRecovery:
if hasLosses {
b.recoveryState = bbrRecoveryStateConservation
// This will cause the |recovery_window_| to be set to the correct
// value in CalculateRecoveryWindow().
b.recoveryWindow = 0
// Since the conservation phase is meant to be lasting for a whole
// round, extend the current round as if it were started right now.
b.currentRoundTripEnd = b.lastSentPacket
}
case bbrRecoveryStateConservation:
if isRoundStart {
b.recoveryState = bbrRecoveryStateGrowth
}
fallthrough
case bbrRecoveryStateGrowth:
// Exit recovery if appropriate.
if !hasLosses && lastAckedPacket > b.endRecoveryAt {
b.recoveryState = bbrRecoveryStateNotInRecovery
}
}
}
// Determines the appropriate pacing rate for the connection.
func (b *bbrSender) calculatePacingRate(bytesLost congestion.ByteCount) {
if b.bandwidthEstimate() == 0 {
return
}
targetRate := Bandwidth(b.pacingGain * float64(b.bandwidthEstimate()))
if b.isAtFullBandwidth {
b.pacingRate = targetRate
return
}
// Pace at the rate of initial_window / RTT as soon as RTT measurements are
// available.
if b.pacingRate == 0 && b.rttStats.MinRTT() != 0 {
b.pacingRate = BandwidthFromDelta(b.initialCongestionWindow, b.rttStats.MinRTT())
return
}
if b.detectOvershooting {
b.bytesLostWhileDetectingOvershooting += bytesLost
// Check for overshooting with network parameters adjusted when pacing rate
// > target_rate and loss has been detected.
if b.pacingRate > targetRate && b.bytesLostWhileDetectingOvershooting > 0 {
if b.hasNoAppLimitedSample ||
b.bytesLostWhileDetectingOvershooting*congestion.ByteCount(b.bytesLostMultiplierWhileDetectingOvershooting) > b.initialCongestionWindow {
// We are fairly sure overshoot happens if 1) there is at least one
// non app-limited bw sample or 2) half of IW gets lost. Slow pacing
// rate.
b.pacingRate = Max(targetRate, BandwidthFromDelta(b.cwndToCalculateMinPacingRate, b.rttStats.MinRTT()))
b.bytesLostWhileDetectingOvershooting = 0
b.detectOvershooting = false
}
}
}
// Do not decrease the pacing rate during startup.
b.pacingRate = Max(b.pacingRate, targetRate)
}
// Determines the appropriate congestion window for the connection.
func (b *bbrSender) calculateCongestionWindow(bytesAcked, excessAcked congestion.ByteCount) {
if b.mode == bbrModeProbeRtt {
return
}
targetWindow := b.getTargetCongestionWindow(b.congestionWindowGain)
if b.isAtFullBandwidth {
// Add the max recently measured ack aggregation to CWND.
targetWindow += b.sampler.MaxAckHeight()
} else if b.enableAckAggregationDuringStartup {
// Add the most recent excess acked. Because CWND never decreases in
// STARTUP, this will automatically create a very localized max filter.
targetWindow += excessAcked
}
// Instead of immediately setting the target CWND as the new one, BBR grows
// the CWND towards |target_window| by only increasing it |bytes_acked| at a
// time.
if b.isAtFullBandwidth {
b.congestionWindow = Min(targetWindow, b.congestionWindow+bytesAcked)
} else if b.congestionWindow < targetWindow ||
b.sampler.TotalBytesAcked() < b.initialCongestionWindow {
// If the connection is not yet out of startup phase, do not decrease the
// window.
b.congestionWindow += bytesAcked
}
// Enforce the limits on the congestion window.
b.congestionWindow = Max(b.congestionWindow, b.minCongestionWindow)
b.congestionWindow = Min(b.congestionWindow, b.maxCongestionWindow)
}
// Determines the appropriate window that constrains the in-flight during recovery.
func (b *bbrSender) calculateRecoveryWindow(bytesAcked, bytesLost congestion.ByteCount) {
if b.recoveryState == bbrRecoveryStateNotInRecovery {
return
}
// Set up the initial recovery window.
if b.recoveryWindow == 0 {
b.recoveryWindow = b.bytesInFlight + bytesAcked
b.recoveryWindow = Max(b.minCongestionWindow, b.recoveryWindow)
return
}
// Remove losses from the recovery window, while accounting for a potential
// integer underflow.
if b.recoveryWindow >= bytesLost {
b.recoveryWindow = b.recoveryWindow - bytesLost
} else {
b.recoveryWindow = b.maxDatagramSize
}
// In CONSERVATION mode, just subtracting losses is sufficient. In GROWTH,
// release additional |bytes_acked| to achieve a slow-start-like behavior.
if b.recoveryState == bbrRecoveryStateGrowth {
b.recoveryWindow += bytesAcked
}
// Always allow sending at least |bytes_acked| in response.
b.recoveryWindow = Max(b.recoveryWindow, b.bytesInFlight+bytesAcked)
b.recoveryWindow = Max(b.minCongestionWindow, b.recoveryWindow)
}
// Return whether we should exit STARTUP due to excessive loss.
func (b *bbrSender) shouldExitStartupDueToLoss(lastPacketSendState *sendTimeState) bool {
if b.numLossEventsInRound < defaultStartupFullLossCount || !lastPacketSendState.isValid {
return false
}
inflightAtSend := lastPacketSendState.bytesInFlight
if inflightAtSend > 0 && b.bytesLostInRound > 0 {
if b.bytesLostInRound > congestion.ByteCount(float64(inflightAtSend)*quicBbr2DefaultLossThreshold) {
return true
}
return false
}
return false
}
func bdpFromRttAndBandwidth(rtt time.Duration, bandwidth Bandwidth) congestion.ByteCount {
return congestion.ByteCount(rtt) * congestion.ByteCount(bandwidth) / congestion.ByteCount(BytesPerSecond) / congestion.ByteCount(time.Second)
}
func GetInitialPacketSize(quicConn quic.Connection) congestion.ByteCount {
return congestion.ByteCount(quicConn.Config().InitialPacketSize)
}