vendor/go.uber.org/zap/zapcore/sampler.go - voltha-go - Gitiles

 // Copyright (c) 2016 Uber Technologies, Inc.
 //
 // Permission is hereby granted, free of charge, to any person obtaining a copy
 // of this software and associated documentation files (the "Software"), to deal
 // in the Software without restriction, including without limitation the rights
 // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 // copies of the Software, and to permit persons to whom the Software is
 // furnished to do so, subject to the following conditions:
 //
 // The above copyright notice and this permission notice shall be included in
 // all copies or substantial portions of the Software.
 //
 // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 // THE SOFTWARE.

 package zapcore

 import (
 	"time"

 	"go.uber.org/atomic"
 )

 const (
 	_numLevels        = _maxLevel - _minLevel + 1
 	_countersPerLevel = 4096
 )

 type counter struct {
 	resetAt atomic.Int64
 	counter atomic.Uint64
 }

 type counters [_numLevels][_countersPerLevel]counter

 func newCounters() *counters {
 	return &counters{}
 }

 func (cs *counters) get(lvl Level, key string) *counter {
 	i := lvl - _minLevel
 	j := fnv32a(key) % _countersPerLevel
 	return &cs[i][j]
 }

 // fnv32a, adapted from "hash/fnv", but without a []byte(string) alloc
 func fnv32a(s string) uint32 {
 	const (
 		offset32 = 2166136261
 		prime32  = 16777619
 	)
 	hash := uint32(offset32)
 	for i := 0; i < len(s); i++ {
 		hash ^= uint32(s[i])
 		hash *= prime32
 	}
 	return hash
 }

 func (c *counter) IncCheckReset(t time.Time, tick time.Duration) uint64 {
 	tn := t.UnixNano()
 	resetAfter := c.resetAt.Load()
 	if resetAfter > tn {
 		return c.counter.Inc()
 	}

 	c.counter.Store(1)

 	newResetAfter := tn + tick.Nanoseconds()
 	if !c.resetAt.CAS(resetAfter, newResetAfter) {
 		// We raced with another goroutine trying to reset, and it also reset
 		// the counter to 1, so we need to reincrement the counter.
 		return c.counter.Inc()
 	}

 	return 1
 }

 // SamplingDecision is a decision represented as a bit field made by sampler.
 // More decisions may be added in the future.
 type SamplingDecision uint32

 const (
 	// LogDropped indicates that the Sampler dropped a log entry.
 	LogDropped SamplingDecision = 1 << iota
 	// LogSampled indicates that the Sampler sampled a log entry.
 	LogSampled
 )

 // optionFunc wraps a func so it satisfies the SamplerOption interface.
 type optionFunc func(*sampler)

 func (f optionFunc) apply(s *sampler) {
 	f(s)
 }

 // SamplerOption configures a Sampler.
 type SamplerOption interface {
 	apply(*sampler)
 }

 // nopSamplingHook is the default hook used by sampler.
 func nopSamplingHook(Entry, SamplingDecision) {}

 // SamplerHook registers a function  which will be called when Sampler makes a
 // decision.
 //
 // This hook may be used to get visibility into the performance of the sampler.
 // For example, use it to track metrics of dropped versus sampled logs.
 //
 //  var dropped atomic.Int64
 //  zapcore.SamplerHook(func(ent zapcore.Entry, dec zapcore.SamplingDecision) {
 //    if dec&zapcore.LogDropped > 0 {
 //      dropped.Inc()
 //    }
 //  })
 func SamplerHook(hook func(entry Entry, dec SamplingDecision)) SamplerOption {
 	return optionFunc(func(s *sampler) {
 		s.hook = hook
 	})
 }

 // NewSamplerWithOptions creates a Core that samples incoming entries, which
 // caps the CPU and I/O load of logging while attempting to preserve a
 // representative subset of your logs.
 //
 // Zap samples by logging the first N entries with a given level and message
 // each tick. If more Entries with the same level and message are seen during
 // the same interval, every Mth message is logged and the rest are dropped.
 //
 // Sampler can be configured to report sampling decisions with the SamplerHook
 // option.
 //
 // Keep in mind that zap's sampling implementation is optimized for speed over
 // absolute precision; under load, each tick may be slightly over- or
 // under-sampled.
 func NewSamplerWithOptions(core Core, tick time.Duration, first, thereafter int, opts ...SamplerOption) Core {
 	s := &sampler{
 		Core:       core,
 		tick:       tick,
 		counts:     newCounters(),
 		first:      uint64(first),
 		thereafter: uint64(thereafter),
 		hook:       nopSamplingHook,
 	}
 	for _, opt := range opts {
 		opt.apply(s)
 	}

 	return s
 }

 type sampler struct {
 	Core

 	counts            *counters
 	tick              time.Duration
 	first, thereafter uint64
 	hook              func(Entry, SamplingDecision)
 }

 // NewSampler creates a Core that samples incoming entries, which
 // caps the CPU and I/O load of logging while attempting to preserve a
 // representative subset of your logs.
 //
 // Zap samples by logging the first N entries with a given level and message
 // each tick. If more Entries with the same level and message are seen during
 // the same interval, every Mth message is logged and the rest are dropped.
 //
 // Keep in mind that zap's sampling implementation is optimized for speed over
 // absolute precision; under load, each tick may be slightly over- or
 // under-sampled.
 //
 // Deprecated: use NewSamplerWithOptions.
 func NewSampler(core Core, tick time.Duration, first, thereafter int) Core {
 	return NewSamplerWithOptions(core, tick, first, thereafter)
 }

 func (s *sampler) With(fields []Field) Core {
 	return &sampler{
 		Core:       s.Core.With(fields),
 		tick:       s.tick,
 		counts:     s.counts,
 		first:      s.first,
 		thereafter: s.thereafter,
 		hook:       s.hook,
 	}
 }

 func (s *sampler) Check(ent Entry, ce *CheckedEntry) *CheckedEntry {
 	if !s.Enabled(ent.Level) {
 		return ce
 	}

 	counter := s.counts.get(ent.Level, ent.Message)
 	n := counter.IncCheckReset(ent.Time, s.tick)
 	if n > s.first && (n-s.first)%s.thereafter != 0 {
 		s.hook(ent, LogDropped)
 		return ce
 	}
 	s.hook(ent, LogSampled)
 	return s.Core.Check(ent, ce)
 }
	// Copyright (c) 2016 Uber Technologies, Inc.
	//
	// Permission is hereby granted, free of charge, to any person obtaining a copy
	// of this software and associated documentation files (the "Software"), to deal
	// in the Software without restriction, including without limitation the rights
	// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
	// copies of the Software, and to permit persons to whom the Software is
	// furnished to do so, subject to the following conditions:
	//
	// The above copyright notice and this permission notice shall be included in
	// all copies or substantial portions of the Software.
	//
	// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
	// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
	// THE SOFTWARE.

	package zapcore

	import (
	"time"

	"go.uber.org/atomic"
	)

	const (
	_numLevels = _maxLevel - _minLevel + 1
	_countersPerLevel = 4096
	)

	type counter struct {
	resetAt atomic.Int64
	counter atomic.Uint64
	}

	type counters [_numLevels][_countersPerLevel]counter

	func newCounters() *counters {
	return &counters{}
	}

	func (cs counters) get(lvl Level, key string) counter {
	i := lvl - _minLevel
	j := fnv32a(key) % _countersPerLevel
	return &cs[i][j]
	}

	// fnv32a, adapted from "hash/fnv", but without a []byte(string) alloc
	func fnv32a(s string) uint32 {
	const (
	offset32 = 2166136261
	prime32 = 16777619
	)
	hash := uint32(offset32)
	for i := 0; i < len(s); i++ {
	hash ^= uint32(s[i])
	hash *= prime32
	}
	return hash
	}

	func (c *counter) IncCheckReset(t time.Time, tick time.Duration) uint64 {
	tn := t.UnixNano()
	resetAfter := c.resetAt.Load()
	if resetAfter > tn {
	return c.counter.Inc()
	}

	c.counter.Store(1)

	newResetAfter := tn + tick.Nanoseconds()
	if !c.resetAt.CAS(resetAfter, newResetAfter) {
	// We raced with another goroutine trying to reset, and it also reset
	// the counter to 1, so we need to reincrement the counter.
	return c.counter.Inc()
	}

	return 1
	}

	// SamplingDecision is a decision represented as a bit field made by sampler.
	// More decisions may be added in the future.
	type SamplingDecision uint32

	const (
	// LogDropped indicates that the Sampler dropped a log entry.
	LogDropped SamplingDecision = 1 << iota
	// LogSampled indicates that the Sampler sampled a log entry.
	LogSampled
	)

	// optionFunc wraps a func so it satisfies the SamplerOption interface.
	type optionFunc func(*sampler)

	func (f optionFunc) apply(s *sampler) {
	f(s)
	}

	// SamplerOption configures a Sampler.
	type SamplerOption interface {
	apply(*sampler)
	}

	// nopSamplingHook is the default hook used by sampler.
	func nopSamplingHook(Entry, SamplingDecision) {}

	// SamplerHook registers a function which will be called when Sampler makes a
	// decision.
	//
	// This hook may be used to get visibility into the performance of the sampler.
	// For example, use it to track metrics of dropped versus sampled logs.
	//
	// var dropped atomic.Int64
	// zapcore.SamplerHook(func(ent zapcore.Entry, dec zapcore.SamplingDecision) {
	// if dec&zapcore.LogDropped > 0 {
	// dropped.Inc()
	// }
	// })
	func SamplerHook(hook func(entry Entry, dec SamplingDecision)) SamplerOption {
	return optionFunc(func(s *sampler) {
	s.hook = hook
	})
	}

	// NewSamplerWithOptions creates a Core that samples incoming entries, which
	// caps the CPU and I/O load of logging while attempting to preserve a
	// representative subset of your logs.
	//
	// Zap samples by logging the first N entries with a given level and message
	// each tick. If more Entries with the same level and message are seen during
	// the same interval, every Mth message is logged and the rest are dropped.
	//
	// Sampler can be configured to report sampling decisions with the SamplerHook
	// option.
	//
	// Keep in mind that zap's sampling implementation is optimized for speed over
	// absolute precision; under load, each tick may be slightly over- or
	// under-sampled.
	func NewSamplerWithOptions(core Core, tick time.Duration, first, thereafter int, opts ...SamplerOption) Core {
	s := &sampler{
	Core: core,
	tick: tick,
	counts: newCounters(),
	first: uint64(first),
	thereafter: uint64(thereafter),
	hook: nopSamplingHook,
	}
	for _, opt := range opts {
	opt.apply(s)
	}

	return s
	}

	type sampler struct {
	Core

	counts *counters
	tick time.Duration
	first, thereafter uint64
	hook func(Entry, SamplingDecision)
	}

	// NewSampler creates a Core that samples incoming entries, which
	// caps the CPU and I/O load of logging while attempting to preserve a
	// representative subset of your logs.
	//
	// Zap samples by logging the first N entries with a given level and message
	// each tick. If more Entries with the same level and message are seen during
	// the same interval, every Mth message is logged and the rest are dropped.
	//
	// Keep in mind that zap's sampling implementation is optimized for speed over
	// absolute precision; under load, each tick may be slightly over- or
	// under-sampled.
	//
	// Deprecated: use NewSamplerWithOptions.
	func NewSampler(core Core, tick time.Duration, first, thereafter int) Core {
	return NewSamplerWithOptions(core, tick, first, thereafter)
	}

	func (s *sampler) With(fields []Field) Core {
	return &sampler{
	Core: s.Core.With(fields),
	tick: s.tick,
	counts: s.counts,
	first: s.first,
	thereafter: s.thereafter,
	hook: s.hook,
	}
	}

	func (s sampler) Check(ent Entry, ce CheckedEntry) *CheckedEntry {
	if !s.Enabled(ent.Level) {
	return ce
	}

	counter := s.counts.get(ent.Level, ent.Message)
	n := counter.IncCheckReset(ent.Time, s.tick)
	if n > s.first && (n-s.first)%s.thereafter != 0 {
	s.hook(ent, LogDropped)
	return ce
	}
	s.hook(ent, LogSampled)
	return s.Core.Check(ent, ce)
	}