vendor/github.com/rcrowley/go-metrics/log.go - voltha-go - Gitiles

 package metrics

 import (
 	"time"
 )

 type Logger interface {
 	Printf(format string, v ...interface{})
 }

 // Log outputs each metric in the given registry periodically using the given logger.
 func Log(r Registry, freq time.Duration, l Logger) {
 	LogScaled(r, freq, time.Nanosecond, l)
 }

 // LogOnCue outputs each metric in the given registry on demand through the channel
 // using the given logger
 func LogOnCue(r Registry, ch chan interface{}, l Logger) {
 	LogScaledOnCue(r, ch, time.Nanosecond, l)
 }

 // LogScaled outputs each metric in the given registry periodically using the given
 // logger. Print timings in `scale` units (eg time.Millisecond) rather than nanos.
 func LogScaled(r Registry, freq time.Duration, scale time.Duration, l Logger) {
 	ch := make(chan interface{})
 	go func(channel chan interface{}) {
 		for _ = range time.Tick(freq) {
 			channel <- struct{}{}
 		}
 	}(ch)
 	LogScaledOnCue(r, ch, scale, l)
 }

 // LogScaledOnCue outputs each metric in the given registry on demand through the channel
 // using the given logger. Print timings in `scale` units (eg time.Millisecond) rather
 // than nanos.
 func LogScaledOnCue(r Registry, ch chan interface{}, scale time.Duration, l Logger) {
 	du := float64(scale)
 	duSuffix := scale.String()[1:]

 	for _ = range ch {
 		r.Each(func(name string, i interface{}) {
 			switch metric := i.(type) {
 			case Counter:
 				l.Printf("counter %s\n", name)
 				l.Printf("  count:       %9d\n", metric.Count())
 			case Gauge:
 				l.Printf("gauge %s\n", name)
 				l.Printf("  value:       %9d\n", metric.Value())
 			case GaugeFloat64:
 				l.Printf("gauge %s\n", name)
 				l.Printf("  value:       %f\n", metric.Value())
 			case Healthcheck:
 				metric.Check()
 				l.Printf("healthcheck %s\n", name)
 				l.Printf("  error:       %v\n", metric.Error())
 			case Histogram:
 				h := metric.Snapshot()
 				ps := h.Percentiles([]float64{0.5, 0.75, 0.95, 0.99, 0.999})
 				l.Printf("histogram %s\n", name)
 				l.Printf("  count:       %9d\n", h.Count())
 				l.Printf("  min:         %9d\n", h.Min())
 				l.Printf("  max:         %9d\n", h.Max())
 				l.Printf("  mean:        %12.2f\n", h.Mean())
 				l.Printf("  stddev:      %12.2f\n", h.StdDev())
 				l.Printf("  median:      %12.2f\n", ps[0])
 				l.Printf("  75%%:         %12.2f\n", ps[1])
 				l.Printf("  95%%:         %12.2f\n", ps[2])
 				l.Printf("  99%%:         %12.2f\n", ps[3])
 				l.Printf("  99.9%%:       %12.2f\n", ps[4])
 			case Meter:
 				m := metric.Snapshot()
 				l.Printf("meter %s\n", name)
 				l.Printf("  count:       %9d\n", m.Count())
 				l.Printf("  1-min rate:  %12.2f\n", m.Rate1())
 				l.Printf("  5-min rate:  %12.2f\n", m.Rate5())
 				l.Printf("  15-min rate: %12.2f\n", m.Rate15())
 				l.Printf("  mean rate:   %12.2f\n", m.RateMean())
 			case Timer:
 				t := metric.Snapshot()
 				ps := t.Percentiles([]float64{0.5, 0.75, 0.95, 0.99, 0.999})
 				l.Printf("timer %s\n", name)
 				l.Printf("  count:       %9d\n", t.Count())
 				l.Printf("  min:         %12.2f%s\n", float64(t.Min())/du, duSuffix)
 				l.Printf("  max:         %12.2f%s\n", float64(t.Max())/du, duSuffix)
 				l.Printf("  mean:        %12.2f%s\n", t.Mean()/du, duSuffix)
 				l.Printf("  stddev:      %12.2f%s\n", t.StdDev()/du, duSuffix)
 				l.Printf("  median:      %12.2f%s\n", ps[0]/du, duSuffix)
 				l.Printf("  75%%:         %12.2f%s\n", ps[1]/du, duSuffix)
 				l.Printf("  95%%:         %12.2f%s\n", ps[2]/du, duSuffix)
 				l.Printf("  99%%:         %12.2f%s\n", ps[3]/du, duSuffix)
 				l.Printf("  99.9%%:       %12.2f%s\n", ps[4]/du, duSuffix)
 				l.Printf("  1-min rate:  %12.2f\n", t.Rate1())
 				l.Printf("  5-min rate:  %12.2f\n", t.Rate5())
 				l.Printf("  15-min rate: %12.2f\n", t.Rate15())
 				l.Printf("  mean rate:   %12.2f\n", t.RateMean())
 			}
 		})
 	}
 }
	package metrics

	import (
	"time"
	)

	type Logger interface {
	Printf(format string, v ...interface{})
	}

	// Log outputs each metric in the given registry periodically using the given logger.
	func Log(r Registry, freq time.Duration, l Logger) {
	LogScaled(r, freq, time.Nanosecond, l)
	}

	// LogOnCue outputs each metric in the given registry on demand through the channel
	// using the given logger
	func LogOnCue(r Registry, ch chan interface{}, l Logger) {
	LogScaledOnCue(r, ch, time.Nanosecond, l)
	}

	// LogScaled outputs each metric in the given registry periodically using the given
	// logger. Print timings in `scale` units (eg time.Millisecond) rather than nanos.
	func LogScaled(r Registry, freq time.Duration, scale time.Duration, l Logger) {
	ch := make(chan interface{})
	go func(channel chan interface{}) {
	for _ = range time.Tick(freq) {
	channel <- struct{}{}
	}
	}(ch)
	LogScaledOnCue(r, ch, scale, l)
	}

	// LogScaledOnCue outputs each metric in the given registry on demand through the channel
	// using the given logger. Print timings in `scale` units (eg time.Millisecond) rather
	// than nanos.
	func LogScaledOnCue(r Registry, ch chan interface{}, scale time.Duration, l Logger) {
	du := float64(scale)
	duSuffix := scale.String()[1:]

	for _ = range ch {
	r.Each(func(name string, i interface{}) {
	switch metric := i.(type) {
	case Counter:
	l.Printf("counter %s\n", name)
	l.Printf(" count: %9d\n", metric.Count())
	case Gauge:
	l.Printf("gauge %s\n", name)
	l.Printf(" value: %9d\n", metric.Value())
	case GaugeFloat64:
	l.Printf("gauge %s\n", name)
	l.Printf(" value: %f\n", metric.Value())
	case Healthcheck:
	metric.Check()
	l.Printf("healthcheck %s\n", name)
	l.Printf(" error: %v\n", metric.Error())
	case Histogram:
	h := metric.Snapshot()
	ps := h.Percentiles([]float64{0.5, 0.75, 0.95, 0.99, 0.999})
	l.Printf("histogram %s\n", name)
	l.Printf(" count: %9d\n", h.Count())
	l.Printf(" min: %9d\n", h.Min())
	l.Printf(" max: %9d\n", h.Max())
	l.Printf(" mean: %12.2f\n", h.Mean())
	l.Printf(" stddev: %12.2f\n", h.StdDev())
	l.Printf(" median: %12.2f\n", ps[0])
	l.Printf(" 75%%: %12.2f\n", ps[1])
	l.Printf(" 95%%: %12.2f\n", ps[2])
	l.Printf(" 99%%: %12.2f\n", ps[3])
	l.Printf(" 99.9%%: %12.2f\n", ps[4])
	case Meter:
	m := metric.Snapshot()
	l.Printf("meter %s\n", name)
	l.Printf(" count: %9d\n", m.Count())
	l.Printf(" 1-min rate: %12.2f\n", m.Rate1())
	l.Printf(" 5-min rate: %12.2f\n", m.Rate5())
	l.Printf(" 15-min rate: %12.2f\n", m.Rate15())
	l.Printf(" mean rate: %12.2f\n", m.RateMean())
	case Timer:
	t := metric.Snapshot()
	ps := t.Percentiles([]float64{0.5, 0.75, 0.95, 0.99, 0.999})
	l.Printf("timer %s\n", name)
	l.Printf(" count: %9d\n", t.Count())
	l.Printf(" min: %12.2f%s\n", float64(t.Min())/du, duSuffix)
	l.Printf(" max: %12.2f%s\n", float64(t.Max())/du, duSuffix)
	l.Printf(" mean: %12.2f%s\n", t.Mean()/du, duSuffix)
	l.Printf(" stddev: %12.2f%s\n", t.StdDev()/du, duSuffix)
	l.Printf(" median: %12.2f%s\n", ps[0]/du, duSuffix)
	l.Printf(" 75%%: %12.2f%s\n", ps[1]/du, duSuffix)
	l.Printf(" 95%%: %12.2f%s\n", ps[2]/du, duSuffix)
	l.Printf(" 99%%: %12.2f%s\n", ps[3]/du, duSuffix)
	l.Printf(" 99.9%%: %12.2f%s\n", ps[4]/du, duSuffix)
	l.Printf(" 1-min rate: %12.2f\n", t.Rate1())
	l.Printf(" 5-min rate: %12.2f\n", t.Rate5())
	l.Printf(" 15-min rate: %12.2f\n", t.Rate15())
	l.Printf(" mean rate: %12.2f\n", t.RateMean())
	}
	})
	}
	}