mirror of
https://github.com/ceph/ceph-csi.git
synced 2024-11-14 02:10:21 +00:00
02b8cd0b4b
Signed-off-by: Humble Chirammal <hchiramm@redhat.com>
607 lines
20 KiB
Go
607 lines
20 KiB
Go
/*
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Copyright 2014 The Kubernetes Authors.
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Licensed under the Apache License, Version 2.0 (the "License");
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you may not use this file except in compliance with the License.
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You may obtain a copy of the License at
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http://www.apache.org/licenses/LICENSE-2.0
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Unless required by applicable law or agreed to in writing, software
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distributed under the License is distributed on an "AS IS" BASIS,
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WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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See the License for the specific language governing permissions and
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limitations under the License.
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*/
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package wait
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import (
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"context"
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"errors"
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"math"
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"math/rand"
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"sync"
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"time"
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"k8s.io/apimachinery/pkg/util/clock"
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"k8s.io/apimachinery/pkg/util/runtime"
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)
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// For any test of the style:
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// ...
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// <- time.After(timeout):
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// t.Errorf("Timed out")
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// The value for timeout should effectively be "forever." Obviously we don't want our tests to truly lock up forever, but 30s
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// is long enough that it is effectively forever for the things that can slow down a run on a heavily contended machine
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// (GC, seeks, etc), but not so long as to make a developer ctrl-c a test run if they do happen to break that test.
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var ForeverTestTimeout = time.Second * 30
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// NeverStop may be passed to Until to make it never stop.
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var NeverStop <-chan struct{} = make(chan struct{})
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// Group allows to start a group of goroutines and wait for their completion.
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type Group struct {
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wg sync.WaitGroup
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}
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func (g *Group) Wait() {
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g.wg.Wait()
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}
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// StartWithChannel starts f in a new goroutine in the group.
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// stopCh is passed to f as an argument. f should stop when stopCh is available.
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func (g *Group) StartWithChannel(stopCh <-chan struct{}, f func(stopCh <-chan struct{})) {
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g.Start(func() {
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f(stopCh)
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})
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}
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// StartWithContext starts f in a new goroutine in the group.
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// ctx is passed to f as an argument. f should stop when ctx.Done() is available.
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func (g *Group) StartWithContext(ctx context.Context, f func(context.Context)) {
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g.Start(func() {
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f(ctx)
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})
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}
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// Start starts f in a new goroutine in the group.
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func (g *Group) Start(f func()) {
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g.wg.Add(1)
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go func() {
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defer g.wg.Done()
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f()
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}()
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}
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// Forever calls f every period for ever.
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//
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// Forever is syntactic sugar on top of Until.
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func Forever(f func(), period time.Duration) {
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Until(f, period, NeverStop)
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}
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// Until loops until stop channel is closed, running f every period.
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//
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// Until is syntactic sugar on top of JitterUntil with zero jitter factor and
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// with sliding = true (which means the timer for period starts after the f
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// completes).
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func Until(f func(), period time.Duration, stopCh <-chan struct{}) {
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JitterUntil(f, period, 0.0, true, stopCh)
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}
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// UntilWithContext loops until context is done, running f every period.
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//
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// UntilWithContext is syntactic sugar on top of JitterUntilWithContext
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// with zero jitter factor and with sliding = true (which means the timer
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// for period starts after the f completes).
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func UntilWithContext(ctx context.Context, f func(context.Context), period time.Duration) {
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JitterUntilWithContext(ctx, f, period, 0.0, true)
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}
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// NonSlidingUntil loops until stop channel is closed, running f every
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// period.
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//
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// NonSlidingUntil is syntactic sugar on top of JitterUntil with zero jitter
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// factor, with sliding = false (meaning the timer for period starts at the same
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// time as the function starts).
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func NonSlidingUntil(f func(), period time.Duration, stopCh <-chan struct{}) {
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JitterUntil(f, period, 0.0, false, stopCh)
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}
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// NonSlidingUntilWithContext loops until context is done, running f every
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// period.
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//
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// NonSlidingUntilWithContext is syntactic sugar on top of JitterUntilWithContext
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// with zero jitter factor, with sliding = false (meaning the timer for period
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// starts at the same time as the function starts).
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func NonSlidingUntilWithContext(ctx context.Context, f func(context.Context), period time.Duration) {
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JitterUntilWithContext(ctx, f, period, 0.0, false)
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}
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// JitterUntil loops until stop channel is closed, running f every period.
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//
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// If jitterFactor is positive, the period is jittered before every run of f.
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// If jitterFactor is not positive, the period is unchanged and not jittered.
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//
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// If sliding is true, the period is computed after f runs. If it is false then
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// period includes the runtime for f.
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//
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// Close stopCh to stop. f may not be invoked if stop channel is already
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// closed. Pass NeverStop to if you don't want it stop.
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func JitterUntil(f func(), period time.Duration, jitterFactor float64, sliding bool, stopCh <-chan struct{}) {
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BackoffUntil(f, NewJitteredBackoffManager(period, jitterFactor, &clock.RealClock{}), sliding, stopCh)
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}
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// BackoffUntil loops until stop channel is closed, run f every duration given by BackoffManager.
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//
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// If sliding is true, the period is computed after f runs. If it is false then
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// period includes the runtime for f.
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func BackoffUntil(f func(), backoff BackoffManager, sliding bool, stopCh <-chan struct{}) {
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var t clock.Timer
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for {
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select {
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case <-stopCh:
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return
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default:
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}
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if !sliding {
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t = backoff.Backoff()
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}
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func() {
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defer runtime.HandleCrash()
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f()
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}()
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if sliding {
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t = backoff.Backoff()
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}
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// NOTE: b/c there is no priority selection in golang
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// it is possible for this to race, meaning we could
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// trigger t.C and stopCh, and t.C select falls through.
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// In order to mitigate we re-check stopCh at the beginning
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// of every loop to prevent extra executions of f().
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select {
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case <-stopCh:
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return
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case <-t.C():
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}
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}
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}
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// JitterUntilWithContext loops until context is done, running f every period.
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//
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// If jitterFactor is positive, the period is jittered before every run of f.
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// If jitterFactor is not positive, the period is unchanged and not jittered.
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//
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// If sliding is true, the period is computed after f runs. If it is false then
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// period includes the runtime for f.
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//
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// Cancel context to stop. f may not be invoked if context is already expired.
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func JitterUntilWithContext(ctx context.Context, f func(context.Context), period time.Duration, jitterFactor float64, sliding bool) {
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JitterUntil(func() { f(ctx) }, period, jitterFactor, sliding, ctx.Done())
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}
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// Jitter returns a time.Duration between duration and duration + maxFactor *
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// duration.
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//
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// This allows clients to avoid converging on periodic behavior. If maxFactor
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// is 0.0, a suggested default value will be chosen.
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func Jitter(duration time.Duration, maxFactor float64) time.Duration {
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if maxFactor <= 0.0 {
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maxFactor = 1.0
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}
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wait := duration + time.Duration(rand.Float64()*maxFactor*float64(duration))
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return wait
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}
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// ErrWaitTimeout is returned when the condition exited without success.
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var ErrWaitTimeout = errors.New("timed out waiting for the condition")
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// ConditionFunc returns true if the condition is satisfied, or an error
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// if the loop should be aborted.
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type ConditionFunc func() (done bool, err error)
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// runConditionWithCrashProtection runs a ConditionFunc with crash protection
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func runConditionWithCrashProtection(condition ConditionFunc) (bool, error) {
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defer runtime.HandleCrash()
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return condition()
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}
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// Backoff holds parameters applied to a Backoff function.
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type Backoff struct {
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// The initial duration.
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Duration time.Duration
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// Duration is multiplied by factor each iteration, if factor is not zero
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// and the limits imposed by Steps and Cap have not been reached.
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// Should not be negative.
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// The jitter does not contribute to the updates to the duration parameter.
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Factor float64
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// The sleep at each iteration is the duration plus an additional
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// amount chosen uniformly at random from the interval between
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// zero and `jitter*duration`.
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Jitter float64
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// The remaining number of iterations in which the duration
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// parameter may change (but progress can be stopped earlier by
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// hitting the cap). If not positive, the duration is not
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// changed. Used for exponential backoff in combination with
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// Factor and Cap.
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Steps int
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// A limit on revised values of the duration parameter. If a
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// multiplication by the factor parameter would make the duration
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// exceed the cap then the duration is set to the cap and the
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// steps parameter is set to zero.
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Cap time.Duration
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}
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// Step (1) returns an amount of time to sleep determined by the
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// original Duration and Jitter and (2) mutates the provided Backoff
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// to update its Steps and Duration.
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func (b *Backoff) Step() time.Duration {
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if b.Steps < 1 {
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if b.Jitter > 0 {
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return Jitter(b.Duration, b.Jitter)
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}
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return b.Duration
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}
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b.Steps--
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duration := b.Duration
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// calculate the next step
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if b.Factor != 0 {
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b.Duration = time.Duration(float64(b.Duration) * b.Factor)
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if b.Cap > 0 && b.Duration > b.Cap {
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b.Duration = b.Cap
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b.Steps = 0
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}
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}
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if b.Jitter > 0 {
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duration = Jitter(duration, b.Jitter)
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}
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return duration
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}
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// contextForChannel derives a child context from a parent channel.
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//
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// The derived context's Done channel is closed when the returned cancel function
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// is called or when the parent channel is closed, whichever happens first.
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//
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// Note the caller must *always* call the CancelFunc, otherwise resources may be leaked.
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func contextForChannel(parentCh <-chan struct{}) (context.Context, context.CancelFunc) {
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ctx, cancel := context.WithCancel(context.Background())
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go func() {
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select {
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case <-parentCh:
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cancel()
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case <-ctx.Done():
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}
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}()
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return ctx, cancel
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}
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// BackoffManager manages backoff with a particular scheme based on its underlying implementation. It provides
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// an interface to return a timer for backoff, and caller shall backoff until Timer.C() drains. If the second Backoff()
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// is called before the timer from the first Backoff() call finishes, the first timer will NOT be drained and result in
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// undetermined behavior.
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// The BackoffManager is supposed to be called in a single-threaded environment.
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type BackoffManager interface {
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Backoff() clock.Timer
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}
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type exponentialBackoffManagerImpl struct {
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backoff *Backoff
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backoffTimer clock.Timer
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lastBackoffStart time.Time
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initialBackoff time.Duration
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backoffResetDuration time.Duration
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clock clock.Clock
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}
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// NewExponentialBackoffManager returns a manager for managing exponential backoff. Each backoff is jittered and
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// backoff will not exceed the given max. If the backoff is not called within resetDuration, the backoff is reset.
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// This backoff manager is used to reduce load during upstream unhealthiness.
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func NewExponentialBackoffManager(initBackoff, maxBackoff, resetDuration time.Duration, backoffFactor, jitter float64, c clock.Clock) BackoffManager {
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return &exponentialBackoffManagerImpl{
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backoff: &Backoff{
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Duration: initBackoff,
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Factor: backoffFactor,
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Jitter: jitter,
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// the current impl of wait.Backoff returns Backoff.Duration once steps are used up, which is not
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// what we ideally need here, we set it to max int and assume we will never use up the steps
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Steps: math.MaxInt32,
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Cap: maxBackoff,
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},
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backoffTimer: nil,
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initialBackoff: initBackoff,
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lastBackoffStart: c.Now(),
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backoffResetDuration: resetDuration,
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clock: c,
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}
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}
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func (b *exponentialBackoffManagerImpl) getNextBackoff() time.Duration {
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if b.clock.Now().Sub(b.lastBackoffStart) > b.backoffResetDuration {
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b.backoff.Steps = math.MaxInt32
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b.backoff.Duration = b.initialBackoff
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}
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b.lastBackoffStart = b.clock.Now()
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return b.backoff.Step()
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}
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// Backoff implements BackoffManager.Backoff, it returns a timer so caller can block on the timer for exponential backoff.
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// The returned timer must be drained before calling Backoff() the second time
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func (b *exponentialBackoffManagerImpl) Backoff() clock.Timer {
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if b.backoffTimer == nil {
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b.backoffTimer = b.clock.NewTimer(b.getNextBackoff())
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} else {
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b.backoffTimer.Reset(b.getNextBackoff())
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}
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return b.backoffTimer
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}
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type jitteredBackoffManagerImpl struct {
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clock clock.Clock
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duration time.Duration
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jitter float64
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backoffTimer clock.Timer
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}
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// NewJitteredBackoffManager returns a BackoffManager that backoffs with given duration plus given jitter. If the jitter
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// is negative, backoff will not be jittered.
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func NewJitteredBackoffManager(duration time.Duration, jitter float64, c clock.Clock) BackoffManager {
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return &jitteredBackoffManagerImpl{
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clock: c,
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duration: duration,
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jitter: jitter,
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backoffTimer: nil,
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}
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}
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func (j *jitteredBackoffManagerImpl) getNextBackoff() time.Duration {
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jitteredPeriod := j.duration
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if j.jitter > 0.0 {
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jitteredPeriod = Jitter(j.duration, j.jitter)
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}
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return jitteredPeriod
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}
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// Backoff implements BackoffManager.Backoff, it returns a timer so caller can block on the timer for jittered backoff.
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// The returned timer must be drained before calling Backoff() the second time
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func (j *jitteredBackoffManagerImpl) Backoff() clock.Timer {
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backoff := j.getNextBackoff()
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if j.backoffTimer == nil {
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j.backoffTimer = j.clock.NewTimer(backoff)
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} else {
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j.backoffTimer.Reset(backoff)
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}
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return j.backoffTimer
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}
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// ExponentialBackoff repeats a condition check with exponential backoff.
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//
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// It repeatedly checks the condition and then sleeps, using `backoff.Step()`
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// to determine the length of the sleep and adjust Duration and Steps.
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// Stops and returns as soon as:
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// 1. the condition check returns true or an error,
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// 2. `backoff.Steps` checks of the condition have been done, or
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// 3. a sleep truncated by the cap on duration has been completed.
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// In case (1) the returned error is what the condition function returned.
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// In all other cases, ErrWaitTimeout is returned.
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func ExponentialBackoff(backoff Backoff, condition ConditionFunc) error {
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for backoff.Steps > 0 {
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if ok, err := runConditionWithCrashProtection(condition); err != nil || ok {
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return err
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}
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if backoff.Steps == 1 {
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break
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}
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time.Sleep(backoff.Step())
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}
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return ErrWaitTimeout
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}
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// Poll tries a condition func until it returns true, an error, or the timeout
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// is reached.
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//
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// Poll always waits the interval before the run of 'condition'.
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// 'condition' will always be invoked at least once.
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//
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// Some intervals may be missed if the condition takes too long or the time
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// window is too short.
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//
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// If you want to Poll something forever, see PollInfinite.
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func Poll(interval, timeout time.Duration, condition ConditionFunc) error {
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return pollInternal(poller(interval, timeout), condition)
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}
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func pollInternal(wait WaitFunc, condition ConditionFunc) error {
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done := make(chan struct{})
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defer close(done)
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return WaitFor(wait, condition, done)
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}
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// PollImmediate tries a condition func until it returns true, an error, or the timeout
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// is reached.
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//
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// PollImmediate always checks 'condition' before waiting for the interval. 'condition'
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// will always be invoked at least once.
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//
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// Some intervals may be missed if the condition takes too long or the time
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// window is too short.
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//
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// If you want to immediately Poll something forever, see PollImmediateInfinite.
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func PollImmediate(interval, timeout time.Duration, condition ConditionFunc) error {
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return pollImmediateInternal(poller(interval, timeout), condition)
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}
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func pollImmediateInternal(wait WaitFunc, condition ConditionFunc) error {
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done, err := runConditionWithCrashProtection(condition)
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if err != nil {
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return err
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}
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if done {
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return nil
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}
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return pollInternal(wait, condition)
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}
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// PollInfinite tries a condition func until it returns true or an error
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//
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// PollInfinite always waits the interval before the run of 'condition'.
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//
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// Some intervals may be missed if the condition takes too long or the time
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// window is too short.
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func PollInfinite(interval time.Duration, condition ConditionFunc) error {
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done := make(chan struct{})
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defer close(done)
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return PollUntil(interval, condition, done)
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}
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// PollImmediateInfinite tries a condition func until it returns true or an error
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//
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// PollImmediateInfinite runs the 'condition' before waiting for the interval.
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//
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// Some intervals may be missed if the condition takes too long or the time
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// window is too short.
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func PollImmediateInfinite(interval time.Duration, condition ConditionFunc) error {
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done, err := runConditionWithCrashProtection(condition)
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if err != nil {
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return err
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}
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if done {
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return nil
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}
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return PollInfinite(interval, condition)
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}
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// PollUntil tries a condition func until it returns true, an error or stopCh is
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// closed.
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//
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// PollUntil always waits interval before the first run of 'condition'.
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// 'condition' will always be invoked at least once.
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func PollUntil(interval time.Duration, condition ConditionFunc, stopCh <-chan struct{}) error {
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ctx, cancel := contextForChannel(stopCh)
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defer cancel()
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return WaitFor(poller(interval, 0), condition, ctx.Done())
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}
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// PollImmediateUntil tries a condition func until it returns true, an error or stopCh is closed.
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//
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// PollImmediateUntil runs the 'condition' before waiting for the interval.
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// 'condition' will always be invoked at least once.
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func PollImmediateUntil(interval time.Duration, condition ConditionFunc, stopCh <-chan struct{}) error {
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done, err := condition()
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if err != nil {
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return err
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}
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if done {
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|
return nil
|
|
}
|
|
select {
|
|
case <-stopCh:
|
|
return ErrWaitTimeout
|
|
default:
|
|
return PollUntil(interval, condition, stopCh)
|
|
}
|
|
}
|
|
|
|
// WaitFunc creates a channel that receives an item every time a test
|
|
// should be executed and is closed when the last test should be invoked.
|
|
type WaitFunc func(done <-chan struct{}) <-chan struct{}
|
|
|
|
// WaitFor continually checks 'fn' as driven by 'wait'.
|
|
//
|
|
// WaitFor gets a channel from 'wait()'', and then invokes 'fn' once for every value
|
|
// placed on the channel and once more when the channel is closed. If the channel is closed
|
|
// and 'fn' returns false without error, WaitFor returns ErrWaitTimeout.
|
|
//
|
|
// If 'fn' returns an error the loop ends and that error is returned. If
|
|
// 'fn' returns true the loop ends and nil is returned.
|
|
//
|
|
// ErrWaitTimeout will be returned if the 'done' channel is closed without fn ever
|
|
// returning true.
|
|
//
|
|
// When the done channel is closed, because the golang `select` statement is
|
|
// "uniform pseudo-random", the `fn` might still run one or multiple time,
|
|
// though eventually `WaitFor` will return.
|
|
func WaitFor(wait WaitFunc, fn ConditionFunc, done <-chan struct{}) error {
|
|
stopCh := make(chan struct{})
|
|
defer close(stopCh)
|
|
c := wait(stopCh)
|
|
for {
|
|
select {
|
|
case _, open := <-c:
|
|
ok, err := runConditionWithCrashProtection(fn)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
if ok {
|
|
return nil
|
|
}
|
|
if !open {
|
|
return ErrWaitTimeout
|
|
}
|
|
case <-done:
|
|
return ErrWaitTimeout
|
|
}
|
|
}
|
|
}
|
|
|
|
// poller returns a WaitFunc that will send to the channel every interval until
|
|
// timeout has elapsed and then closes the channel.
|
|
//
|
|
// Over very short intervals you may receive no ticks before the channel is
|
|
// closed. A timeout of 0 is interpreted as an infinity, and in such a case
|
|
// it would be the caller's responsibility to close the done channel.
|
|
// Failure to do so would result in a leaked goroutine.
|
|
//
|
|
// Output ticks are not buffered. If the channel is not ready to receive an
|
|
// item, the tick is skipped.
|
|
func poller(interval, timeout time.Duration) WaitFunc {
|
|
return WaitFunc(func(done <-chan struct{}) <-chan struct{} {
|
|
ch := make(chan struct{})
|
|
|
|
go func() {
|
|
defer close(ch)
|
|
|
|
tick := time.NewTicker(interval)
|
|
defer tick.Stop()
|
|
|
|
var after <-chan time.Time
|
|
if timeout != 0 {
|
|
// time.After is more convenient, but it
|
|
// potentially leaves timers around much longer
|
|
// than necessary if we exit early.
|
|
timer := time.NewTimer(timeout)
|
|
after = timer.C
|
|
defer timer.Stop()
|
|
}
|
|
|
|
for {
|
|
select {
|
|
case <-tick.C:
|
|
// If the consumer isn't ready for this signal drop it and
|
|
// check the other channels.
|
|
select {
|
|
case ch <- struct{}{}:
|
|
default:
|
|
}
|
|
case <-after:
|
|
return
|
|
case <-done:
|
|
return
|
|
}
|
|
}
|
|
}()
|
|
|
|
return ch
|
|
})
|
|
}
|