status-go/vendor/github.com/pion/sctp/rtx_timer.go

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// SPDX-FileCopyrightText: 2023 The Pion community <https://pion.ly>
// SPDX-License-Identifier: MIT
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package sctp
import (
"math"
"sync"
"time"
)
const (
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// RTO.Initial in msec
rtoInitial float64 = 1.0 * 1000
// RTO.Min in msec
rtoMin float64 = 1.0 * 1000
// RTO.Max in msec
defaultRTOMax float64 = 60.0 * 1000
// RTO.Alpha
rtoAlpha float64 = 0.125
// RTO.Beta
rtoBeta float64 = 0.25
// Max.Init.Retransmits:
maxInitRetrans uint = 8
// Path.Max.Retrans
pathMaxRetrans uint = 5
noMaxRetrans uint = 0
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)
// rtoManager manages Rtx timeout values.
// This is an implementation of RFC 4960 sec 6.3.1.
type rtoManager struct {
srtt float64
rttvar float64
rto float64
noUpdate bool
mutex sync.RWMutex
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rtoMax float64
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}
// newRTOManager creates a new rtoManager.
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func newRTOManager(rtoMax float64) *rtoManager {
mgr := rtoManager{
rto: rtoInitial,
rtoMax: rtoMax,
}
if mgr.rtoMax == 0 {
mgr.rtoMax = defaultRTOMax
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}
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return &mgr
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}
// setNewRTT takes a newly measured RTT then adjust the RTO in msec.
func (m *rtoManager) setNewRTT(rtt float64) float64 {
m.mutex.Lock()
defer m.mutex.Unlock()
if m.noUpdate {
return m.srtt
}
if m.srtt == 0 {
// First measurement
m.srtt = rtt
m.rttvar = rtt / 2
} else {
// Subsequent rtt measurement
m.rttvar = (1-rtoBeta)*m.rttvar + rtoBeta*(math.Abs(m.srtt-rtt))
m.srtt = (1-rtoAlpha)*m.srtt + rtoAlpha*rtt
}
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m.rto = math.Min(math.Max(m.srtt+4*m.rttvar, rtoMin), m.rtoMax)
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return m.srtt
}
// getRTO simply returns the current RTO in msec.
func (m *rtoManager) getRTO() float64 {
m.mutex.RLock()
defer m.mutex.RUnlock()
return m.rto
}
// reset resets the RTO variables to the initial values.
func (m *rtoManager) reset() {
m.mutex.Lock()
defer m.mutex.Unlock()
if m.noUpdate {
return
}
m.srtt = 0
m.rttvar = 0
m.rto = rtoInitial
}
// set RTO value for testing
func (m *rtoManager) setRTO(rto float64, noUpdate bool) {
m.mutex.Lock()
defer m.mutex.Unlock()
m.rto = rto
m.noUpdate = noUpdate
}
// rtxTimerObserver is the inteface to a timer observer.
// NOTE: Observers MUST NOT call start() or stop() method on rtxTimer
// from within these callbacks.
type rtxTimerObserver interface {
onRetransmissionTimeout(timerID int, n uint)
onRetransmissionFailure(timerID int)
}
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type rtxTimerState uint8
const (
rtxTimerStopped rtxTimerState = iota
rtxTimerStarted
rtxTimerClosed
)
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// rtxTimer provides the retnransmission timer conforms with RFC 4960 Sec 6.3.1
type rtxTimer struct {
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timer *time.Timer
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observer rtxTimerObserver
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id int
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maxRetrans uint
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rtoMax float64
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mutex sync.Mutex
rto float64
nRtos uint
state rtxTimerState
pending uint8
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}
// newRTXTimer creates a new retransmission timer.
// if maxRetrans is set to 0, it will keep retransmitting until stop() is called.
// (it will never make onRetransmissionFailure() callback.
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func newRTXTimer(id int, observer rtxTimerObserver, maxRetrans uint,
rtoMax float64,
) *rtxTimer {
timer := rtxTimer{
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id: id,
observer: observer,
maxRetrans: maxRetrans,
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rtoMax: rtoMax,
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}
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if timer.rtoMax == 0 {
timer.rtoMax = defaultRTOMax
}
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timer.timer = time.AfterFunc(math.MaxInt64, timer.timeout)
timer.timer.Stop()
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return &timer
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}
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func (t *rtxTimer) calculateNextTimeout() time.Duration {
timeout := calculateNextTimeout(t.rto, t.nRtos, t.rtoMax)
return time.Duration(timeout) * time.Millisecond
}
func (t *rtxTimer) timeout() {
t.mutex.Lock()
if t.pending--; t.pending == 0 && t.state == rtxTimerStarted {
if t.nRtos++; t.maxRetrans == 0 || t.nRtos <= t.maxRetrans {
t.timer.Reset(t.calculateNextTimeout())
t.pending++
defer t.observer.onRetransmissionTimeout(t.id, t.nRtos)
} else {
t.state = rtxTimerStopped
defer t.observer.onRetransmissionFailure(t.id)
}
}
t.mutex.Unlock()
}
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// start starts the timer.
func (t *rtxTimer) start(rto float64) bool {
t.mutex.Lock()
defer t.mutex.Unlock()
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// this timer is already closed or aleady running
if t.state != rtxTimerStopped {
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return false
}
// Note: rto value is intentionally not capped by RTO.Min to allow
// fast timeout for the tests. Non-test code should pass in the
// rto generated by rtoManager getRTO() method which caps the
// value at RTO.Min or at RTO.Max.
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t.rto = rto
t.nRtos = 0
t.state = rtxTimerStarted
t.pending++
t.timer.Reset(t.calculateNextTimeout())
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return true
}
// stop stops the timer.
func (t *rtxTimer) stop() {
t.mutex.Lock()
defer t.mutex.Unlock()
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if t.state == rtxTimerStarted {
if t.timer.Stop() {
t.pending--
}
t.state = rtxTimerStopped
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}
}
// closes the timer. this is similar to stop() but subsequent start() call
// will fail (the timer is no longer usable)
func (t *rtxTimer) close() {
t.mutex.Lock()
defer t.mutex.Unlock()
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if t.state == rtxTimerStarted && t.timer.Stop() {
t.pending--
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}
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t.state = rtxTimerClosed
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}
// isRunning tests if the timer is running.
// Debug purpose only
func (t *rtxTimer) isRunning() bool {
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t.mutex.Lock()
defer t.mutex.Unlock()
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return t.state == rtxTimerStarted
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}
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func calculateNextTimeout(rto float64, nRtos uint, rtoMax float64) float64 {
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// RFC 4096 sec 6.3.3. Handle T3-rtx Expiration
// E2) For the destination address for which the timer expires, set RTO
// <- RTO * 2 ("back off the timer"). The maximum value discussed
// in rule C7 above (RTO.max) may be used to provide an upper bound
// to this doubling operation.
if nRtos < 31 {
m := 1 << nRtos
return math.Min(rto*float64(m), rtoMax)
}
return rtoMax
}