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https://codeberg.org/superseriousbusiness/gotosocial.git
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162 lines
5.6 KiB
Go
162 lines
5.6 KiB
Go
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package backoff
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import (
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"math/rand"
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"time"
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)
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/*
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ExponentialBackOff is a backoff implementation that increases the backoff
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period for each retry attempt using a randomization function that grows exponentially.
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NextBackOff() is calculated using the following formula:
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randomized interval =
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RetryInterval * (random value in range [1 - RandomizationFactor, 1 + RandomizationFactor])
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In other words NextBackOff() will range between the randomization factor
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percentage below and above the retry interval.
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For example, given the following parameters:
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RetryInterval = 2
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RandomizationFactor = 0.5
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Multiplier = 2
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the actual backoff period used in the next retry attempt will range between 1 and 3 seconds,
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multiplied by the exponential, that is, between 2 and 6 seconds.
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Note: MaxInterval caps the RetryInterval and not the randomized interval.
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If the time elapsed since an ExponentialBackOff instance is created goes past the
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MaxElapsedTime, then the method NextBackOff() starts returning backoff.Stop.
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The elapsed time can be reset by calling Reset().
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Example: Given the following default arguments, for 10 tries the sequence will be,
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and assuming we go over the MaxElapsedTime on the 10th try:
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Request # RetryInterval (seconds) Randomized Interval (seconds)
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1 0.5 [0.25, 0.75]
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2 0.75 [0.375, 1.125]
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3 1.125 [0.562, 1.687]
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4 1.687 [0.8435, 2.53]
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5 2.53 [1.265, 3.795]
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6 3.795 [1.897, 5.692]
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7 5.692 [2.846, 8.538]
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8 8.538 [4.269, 12.807]
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9 12.807 [6.403, 19.210]
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10 19.210 backoff.Stop
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Note: Implementation is not thread-safe.
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*/
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type ExponentialBackOff struct {
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InitialInterval time.Duration
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RandomizationFactor float64
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Multiplier float64
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MaxInterval time.Duration
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// After MaxElapsedTime the ExponentialBackOff returns Stop.
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// It never stops if MaxElapsedTime == 0.
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MaxElapsedTime time.Duration
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Stop time.Duration
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Clock Clock
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currentInterval time.Duration
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startTime time.Time
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}
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// Clock is an interface that returns current time for BackOff.
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type Clock interface {
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Now() time.Time
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}
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// Default values for ExponentialBackOff.
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const (
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DefaultInitialInterval = 500 * time.Millisecond
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DefaultRandomizationFactor = 0.5
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DefaultMultiplier = 1.5
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DefaultMaxInterval = 60 * time.Second
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DefaultMaxElapsedTime = 15 * time.Minute
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)
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// NewExponentialBackOff creates an instance of ExponentialBackOff using default values.
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func NewExponentialBackOff() *ExponentialBackOff {
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b := &ExponentialBackOff{
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InitialInterval: DefaultInitialInterval,
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RandomizationFactor: DefaultRandomizationFactor,
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Multiplier: DefaultMultiplier,
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MaxInterval: DefaultMaxInterval,
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MaxElapsedTime: DefaultMaxElapsedTime,
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Stop: Stop,
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Clock: SystemClock,
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}
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b.Reset()
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return b
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}
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type systemClock struct{}
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func (t systemClock) Now() time.Time {
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return time.Now()
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}
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// SystemClock implements Clock interface that uses time.Now().
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var SystemClock = systemClock{}
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// Reset the interval back to the initial retry interval and restarts the timer.
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// Reset must be called before using b.
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func (b *ExponentialBackOff) Reset() {
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b.currentInterval = b.InitialInterval
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b.startTime = b.Clock.Now()
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}
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// NextBackOff calculates the next backoff interval using the formula:
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// Randomized interval = RetryInterval * (1 ± RandomizationFactor)
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func (b *ExponentialBackOff) NextBackOff() time.Duration {
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// Make sure we have not gone over the maximum elapsed time.
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elapsed := b.GetElapsedTime()
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next := getRandomValueFromInterval(b.RandomizationFactor, rand.Float64(), b.currentInterval)
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b.incrementCurrentInterval()
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if b.MaxElapsedTime != 0 && elapsed+next > b.MaxElapsedTime {
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return b.Stop
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}
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return next
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}
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// GetElapsedTime returns the elapsed time since an ExponentialBackOff instance
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// is created and is reset when Reset() is called.
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//
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// The elapsed time is computed using time.Now().UnixNano(). It is
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// safe to call even while the backoff policy is used by a running
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// ticker.
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func (b *ExponentialBackOff) GetElapsedTime() time.Duration {
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return b.Clock.Now().Sub(b.startTime)
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}
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// Increments the current interval by multiplying it with the multiplier.
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func (b *ExponentialBackOff) incrementCurrentInterval() {
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// Check for overflow, if overflow is detected set the current interval to the max interval.
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if float64(b.currentInterval) >= float64(b.MaxInterval)/b.Multiplier {
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b.currentInterval = b.MaxInterval
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} else {
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b.currentInterval = time.Duration(float64(b.currentInterval) * b.Multiplier)
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}
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}
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// Returns a random value from the following interval:
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// [currentInterval - randomizationFactor * currentInterval, currentInterval + randomizationFactor * currentInterval].
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func getRandomValueFromInterval(randomizationFactor, random float64, currentInterval time.Duration) time.Duration {
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if randomizationFactor == 0 {
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return currentInterval // make sure no randomness is used when randomizationFactor is 0.
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}
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var delta = randomizationFactor * float64(currentInterval)
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var minInterval = float64(currentInterval) - delta
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var maxInterval = float64(currentInterval) + delta
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// Get a random value from the range [minInterval, maxInterval].
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// The formula used below has a +1 because if the minInterval is 1 and the maxInterval is 3 then
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// we want a 33% chance for selecting either 1, 2 or 3.
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return time.Duration(minInterval + (random * (maxInterval - minInterval + 1)))
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}
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