bsc/metrics/timer.go
Martin HS 9badb15e80 rpc: fix ns/µs mismatch in metrics (#28649)
The rpc/duration/all meter was in nanoseconds, the individual meter in microseconds.
This PR changes it so both of them use nanoseconds.
2023-12-21 16:41:55 +08:00

183 lines
5.4 KiB
Go

package metrics
import (
"sync"
"time"
)
type TimerSnapshot interface {
HistogramSnapshot
MeterSnapshot
}
// Timers capture the duration and rate of events.
type Timer interface {
Snapshot() TimerSnapshot
Stop()
Time(func())
UpdateSince(time.Time)
Update(time.Duration)
}
// GetOrRegisterTimer returns an existing Timer or constructs and registers a
// new StandardTimer.
// Be sure to unregister the meter from the registry once it is of no use to
// allow for garbage collection.
func GetOrRegisterTimer(name string, r Registry) Timer {
if nil == r {
r = DefaultRegistry
}
return r.GetOrRegister(name, NewTimer).(Timer)
}
// NewCustomTimer constructs a new StandardTimer from a Histogram and a Meter.
// Be sure to call Stop() once the timer is of no use to allow for garbage collection.
func NewCustomTimer(h Histogram, m Meter) Timer {
if !Enabled {
return NilTimer{}
}
return &StandardTimer{
histogram: h,
meter: m,
}
}
// NewRegisteredTimer constructs and registers a new StandardTimer.
// Be sure to unregister the meter from the registry once it is of no use to
// allow for garbage collection.
func NewRegisteredTimer(name string, r Registry) Timer {
c := NewTimer()
if nil == r {
r = DefaultRegistry
}
r.Register(name, c)
return c
}
// NewTimer constructs a new StandardTimer using an exponentially-decaying
// sample with the same reservoir size and alpha as UNIX load averages.
// Be sure to call Stop() once the timer is of no use to allow for garbage collection.
func NewTimer() Timer {
if !Enabled {
return NilTimer{}
}
return &StandardTimer{
histogram: NewHistogram(NewExpDecaySample(1028, 0.015)),
meter: NewMeter(),
}
}
// NilTimer is a no-op Timer.
type NilTimer struct{}
func (NilTimer) Snapshot() TimerSnapshot { return (*emptySnapshot)(nil) }
func (NilTimer) Stop() {}
func (NilTimer) Time(f func()) { f() }
func (NilTimer) Update(time.Duration) {}
func (NilTimer) UpdateSince(time.Time) {}
// StandardTimer is the standard implementation of a Timer and uses a Histogram
// and Meter.
type StandardTimer struct {
histogram Histogram
meter Meter
mutex sync.Mutex
}
// Snapshot returns a read-only copy of the timer.
func (t *StandardTimer) Snapshot() TimerSnapshot {
t.mutex.Lock()
defer t.mutex.Unlock()
return &timerSnapshot{
histogram: t.histogram.Snapshot(),
meter: t.meter.Snapshot(),
}
}
// Stop stops the meter.
func (t *StandardTimer) Stop() {
t.meter.Stop()
}
// Record the duration of the execution of the given function.
func (t *StandardTimer) Time(f func()) {
ts := time.Now()
f()
t.Update(time.Since(ts))
}
// Record the duration of an event, in nanoseconds.
func (t *StandardTimer) Update(d time.Duration) {
t.mutex.Lock()
defer t.mutex.Unlock()
t.histogram.Update(d.Nanoseconds())
t.meter.Mark(1)
}
// Record the duration of an event that started at a time and ends now.
// The record uses nanoseconds.
func (t *StandardTimer) UpdateSince(ts time.Time) {
t.Update(time.Since(ts))
}
// timerSnapshot is a read-only copy of another Timer.
type timerSnapshot struct {
histogram HistogramSnapshot
meter MeterSnapshot
}
// Count returns the number of events recorded at the time the snapshot was
// taken.
func (t *timerSnapshot) Count() int64 { return t.histogram.Count() }
// Max returns the maximum value at the time the snapshot was taken.
func (t *timerSnapshot) Max() int64 { return t.histogram.Max() }
// Size returns the size of the sample at the time the snapshot was taken.
func (t *timerSnapshot) Size() int { return t.histogram.Size() }
// Mean returns the mean value at the time the snapshot was taken.
func (t *timerSnapshot) Mean() float64 { return t.histogram.Mean() }
// Min returns the minimum value at the time the snapshot was taken.
func (t *timerSnapshot) Min() int64 { return t.histogram.Min() }
// Percentile returns an arbitrary percentile of sampled values at the time the
// snapshot was taken.
func (t *timerSnapshot) Percentile(p float64) float64 {
return t.histogram.Percentile(p)
}
// Percentiles returns a slice of arbitrary percentiles of sampled values at
// the time the snapshot was taken.
func (t *timerSnapshot) Percentiles(ps []float64) []float64 {
return t.histogram.Percentiles(ps)
}
// Rate1 returns the one-minute moving average rate of events per second at the
// time the snapshot was taken.
func (t *timerSnapshot) Rate1() float64 { return t.meter.Rate1() }
// Rate5 returns the five-minute moving average rate of events per second at
// the time the snapshot was taken.
func (t *timerSnapshot) Rate5() float64 { return t.meter.Rate5() }
// Rate15 returns the fifteen-minute moving average rate of events per second
// at the time the snapshot was taken.
func (t *timerSnapshot) Rate15() float64 { return t.meter.Rate15() }
// RateMean returns the meter's mean rate of events per second at the time the
// snapshot was taken.
func (t *timerSnapshot) RateMean() float64 { return t.meter.RateMean() }
// StdDev returns the standard deviation of the values at the time the snapshot
// was taken.
func (t *timerSnapshot) StdDev() float64 { return t.histogram.StdDev() }
// Sum returns the sum at the time the snapshot was taken.
func (t *timerSnapshot) Sum() int64 { return t.histogram.Sum() }
// Variance returns the variance of the values at the time the snapshot was
// taken.
func (t *timerSnapshot) Variance() float64 { return t.histogram.Variance() }