rtt.rs - mozsearch

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// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or

// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license

// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your

// option. This file may not be copied, modified, or distributed

// except according to those terms.

// Tracking of sent packets and detecting their loss.

use std::{

    cmp::{max, min},

    time::{Duration, Instant},

};

use neqo_common::{qlog::NeqoQlog, qtrace};

use crate::{

    ackrate::{AckRate, PeerAckDelay},

    packet::PacketBuilder,

    qlog::{self, QlogMetric},

    recovery::RecoveryToken,

    stats::FrameStats,

    tracking::PacketNumberSpace,

};

/// The smallest time that the system timer (via `sleep()`, `nanosleep()`,

/// `select()`, or similar) can reliably deliver; see `neqo_common::hrtime`.

pub const GRANULARITY: Duration = Duration::from_millis(1);

// Defined in -recovery 6.2 as 333ms but using lower value.

pub(crate) const INITIAL_RTT: Duration = Duration::from_millis(100);

#[derive(Debug)]

#[allow(clippy::module_name_repetitions)]

pub struct RttEstimate {

    first_sample_time: Option<Instant>,

    latest_rtt: Duration,

    smoothed_rtt: Duration,

    rttvar: Duration,

    min_rtt: Duration,

    ack_delay: PeerAckDelay,

impl RttEstimate {

    fn init(&mut self, rtt: Duration) {

        // Only allow this when there are no samples.

        debug_assert!(self.first_sample_time.is_none());

        self.latest_rtt = rtt;

        self.min_rtt = rtt;

        self.smoothed_rtt = rtt;

        self.rttvar = rtt / 2;

    #[cfg(test)]

    pub const fn from_duration(rtt: Duration) -> Self {

        Self {

            first_sample_time: None,

            latest_rtt: rtt,

            smoothed_rtt: rtt,

            rttvar: Duration::from_millis(0),

            min_rtt: rtt,

            ack_delay: PeerAckDelay::Fixed(Duration::from_millis(25)),

    pub fn set_initial(&mut self, rtt: Duration) {

        qtrace!("initial RTT={:?}", rtt);

        if rtt >= GRANULARITY {

            // Ignore if the value is too small.

            self.init(rtt);

    /// For a new path, prime the RTT based on the state of another path.

    pub fn prime_rtt(&mut self, other: &Self) {

        self.set_initial(other.smoothed_rtt + other.rttvar);

        self.ack_delay = other.ack_delay.clone();

    pub fn set_ack_delay(&mut self, ack_delay: PeerAckDelay) {

        self.ack_delay = ack_delay;

    pub fn update_ack_delay(&mut self, cwnd: usize, mtu: usize) {

        self.ack_delay.update(cwnd, mtu, self.smoothed_rtt);

    pub fn update(

        &mut self,

        qlog: &mut NeqoQlog,

        mut rtt_sample: Duration,

        ack_delay: Duration,

        confirmed: bool,

        now: Instant,

) {

        // Limit ack delay by max_ack_delay if confirmed.

        let mad = self.ack_delay.max();

        let ack_delay = if confirmed && ack_delay > mad {

mad

        } else {

            ack_delay

};

        // min_rtt ignores ack delay.

        self.min_rtt = min(self.min_rtt, rtt_sample);

        // Adjust for ack delay unless it goes below `min_rtt`.

        if rtt_sample - self.min_rtt >= ack_delay {

            rtt_sample -= ack_delay;

        if self.first_sample_time.is_none() {

            self.init(rtt_sample);

            self.first_sample_time = Some(now);

        } else {

            // Calculate EWMA RTT (based on {{?RFC6298}}).

            let rttvar_sample = if self.smoothed_rtt > rtt_sample {

                self.smoothed_rtt - rtt_sample

            } else {

                rtt_sample - self.smoothed_rtt

};

            self.latest_rtt = rtt_sample;

            self.rttvar = (self.rttvar * 3 + rttvar_sample) / 4;

            self.smoothed_rtt = (self.smoothed_rtt * 7 + rtt_sample) / 8;

        qtrace!(

            "RTT latest={:?} -> estimate={:?}~{:?}",

            self.latest_rtt,

            self.smoothed_rtt,

            self.rttvar

);

        qlog::metrics_updated(

            qlog,

&[

                QlogMetric::LatestRtt(self.latest_rtt),

                QlogMetric::MinRtt(self.min_rtt),

                QlogMetric::SmoothedRtt(self.smoothed_rtt),

],

);

    /// Get the estimated value.

    pub fn estimate(&self) -> Duration {

        self.smoothed_rtt

    pub fn pto(&self, pn_space: PacketNumberSpace) -> Duration {

        let mut t = self.estimate() + max(4 * self.rttvar, GRANULARITY);

        if pn_space == PacketNumberSpace::ApplicationData {

            t += self.ack_delay.max();

    /// Calculate the loss delay based on the current estimate and the last

    /// RTT measurement received.

    pub fn loss_delay(&self) -> Duration {

        // kTimeThreshold = 9/8

        // loss_delay = kTimeThreshold * max(latest_rtt, smoothed_rtt)

        // loss_delay = max(loss_delay, kGranularity)

        let rtt = max(self.latest_rtt, self.smoothed_rtt);

        max(rtt * 9 / 8, GRANULARITY)

    pub fn first_sample_time(&self) -> Option<Instant> {

        self.first_sample_time

    #[cfg(test)]

    pub fn latest(&self) -> Duration {

        self.latest_rtt

    pub fn rttvar(&self) -> Duration {

        self.rttvar

    pub fn minimum(&self) -> Duration {

        self.min_rtt

    pub fn write_frames(

        &mut self,

        builder: &mut PacketBuilder,

        tokens: &mut Vec<RecoveryToken>,

        stats: &mut FrameStats,

) {

        self.ack_delay.write_frames(builder, tokens, stats);

    pub fn frame_lost(&mut self, lost: &AckRate) {

        self.ack_delay.frame_lost(lost);

    pub fn frame_acked(&mut self, acked: &AckRate) {

        self.ack_delay.frame_acked(acked);

impl Default for RttEstimate {

    fn default() -> Self {

        Self {

            first_sample_time: None,

            latest_rtt: INITIAL_RTT,

            smoothed_rtt: INITIAL_RTT,

            rttvar: INITIAL_RTT / 2,

            min_rtt: INITIAL_RTT,

            ack_delay: PeerAckDelay::default(),