ntfy/util/limit.go

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package util
import (
"errors"
"golang.org/x/time/rate"
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"io"
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"sync"
"time"
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)
// ErrLimitReached is the error returned by the Limiter and LimitWriter when the predefined limit has been reached
var ErrLimitReached = errors.New("limit reached")
// Limiter is an interface that implements a rate limiting mechanism, e.g. based on time or a fixed value
type Limiter interface {
// Allow adds one to the limiters value, or returns false if the limit has been reached
Allow() bool
// AllowN adds n to the limiters value, or returns false if the limit has been reached
AllowN(n int64) bool
// Value returns the current internal limiter value
Value() int64
// Reset resets the state of the limiter
Reset()
}
// FixedLimiter is a helper that allows adding values up to a well-defined limit. Once the limit is reached
// ErrLimitReached will be returned. FixedLimiter may be used by multiple goroutines.
type FixedLimiter struct {
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value int64
limit int64
mu sync.Mutex
}
var _ Limiter = (*FixedLimiter)(nil)
// NewFixedLimiter creates a new Limiter
func NewFixedLimiter(limit int64) *FixedLimiter {
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return NewFixedLimiterWithValue(limit, 0)
}
// NewFixedLimiterWithValue creates a new Limiter and sets the initial value
func NewFixedLimiterWithValue(limit, value int64) *FixedLimiter {
return &FixedLimiter{
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limit: limit,
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value: value,
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}
}
// Allow adds one to the limiters internal value, but only if the limit has not been reached. If the limit was
// exceeded, false is returned.
func (l *FixedLimiter) Allow() bool {
return l.AllowN(1)
}
// AllowN adds n to the limiters internal value, but only if the limit has not been reached. If the limit was
// exceeded after adding n, false is returned.
func (l *FixedLimiter) AllowN(n int64) bool {
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l.mu.Lock()
defer l.mu.Unlock()
if l.value+n > l.limit {
return false
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}
l.value += n
return true
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}
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// Value returns the current limiter value
func (l *FixedLimiter) Value() int64 {
l.mu.Lock()
defer l.mu.Unlock()
return l.value
}
// Reset sets the limiter's value back to zero
func (l *FixedLimiter) Reset() {
l.mu.Lock()
defer l.mu.Unlock()
l.value = 0
}
// RateLimiter is a Limiter that wraps a rate.Limiter, allowing a floating time-based limit.
type RateLimiter struct {
r rate.Limit
b int
value int64
limiter *rate.Limiter
mu sync.Mutex
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}
var _ Limiter = (*RateLimiter)(nil)
// NewRateLimiter creates a new RateLimiter
func NewRateLimiter(r rate.Limit, b int) *RateLimiter {
return NewRateLimiterWithValue(r, b, 0)
}
// NewRateLimiterWithValue creates a new RateLimiter with the given starting value.
//
// Note that the starting value only has informational value. It does not impact the underlying
// value of the rate.Limiter.
func NewRateLimiterWithValue(r rate.Limit, b int, value int64) *RateLimiter {
return &RateLimiter{
r: r,
b: b,
value: value,
limiter: rate.NewLimiter(r, b),
}
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}
// NewBytesLimiter creates a RateLimiter that is meant to be used for a bytes-per-interval limit,
// e.g. 250 MB per day. And example of the underlying idea can be found here: https://go.dev/play/p/0ljgzIZQ6dJ
func NewBytesLimiter(bytes int, interval time.Duration) *RateLimiter {
return NewRateLimiter(rate.Limit(bytes)*rate.Every(interval), bytes)
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}
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// Allow adds one to the limiters internal value, but only if the limit has not been reached. If the limit was
// exceeded, false is returned.
func (l *RateLimiter) Allow() bool {
return l.AllowN(1)
}
// AllowN adds n to the limiters internal value, but only if the limit has not been reached. If the limit was
// exceeded after adding n, false is returned.
func (l *RateLimiter) AllowN(n int64) bool {
if n <= 0 {
return false // No-op. Can't take back bytes you're written!
}
l.mu.Lock()
defer l.mu.Unlock()
if !l.limiter.AllowN(time.Now(), int(n)) {
return false
}
l.value += n
return true
}
// Value returns the current limiter value
func (l *RateLimiter) Value() int64 {
l.mu.Lock()
defer l.mu.Unlock()
return l.value
}
// Reset sets the limiter's value back to zero, and resets the underlying rate.Limiter
func (l *RateLimiter) Reset() {
l.mu.Lock()
defer l.mu.Unlock()
l.limiter = rate.NewLimiter(l.r, l.b)
l.value = 0
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}
// LimitWriter implements an io.Writer that will pass through all Write calls to the underlying
// writer w until any of the limiter's limit is reached, at which point a Write will return ErrLimitReached.
// Each limiter's value is increased with every write.
type LimitWriter struct {
w io.Writer
written int64
limiters []Limiter
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mu sync.Mutex
}
// NewLimitWriter creates a new LimitWriter
func NewLimitWriter(w io.Writer, limiters ...Limiter) *LimitWriter {
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return &LimitWriter{
w: w,
limiters: limiters,
}
}
// Write passes through all writes to the underlying writer until any of the given limiter's limit is reached
func (w *LimitWriter) Write(p []byte) (n int, err error) {
w.mu.Lock()
defer w.mu.Unlock()
for i := 0; i < len(w.limiters); i++ {
if !w.limiters[i].AllowN(int64(len(p))) {
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for j := i - 1; j >= 0; j-- {
w.limiters[j].AllowN(-int64(len(p))) // Revert limiters limits if not allowed
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}
return 0, ErrLimitReached
}
}
n, err = w.w.Write(p)
w.written += int64(n)
return
}