vendor/github.com/prometheus/client_golang/prometheus/counter.go - voltha-lib-go - Gitiles

 // Copyright 2014 The Prometheus Authors
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 // http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 package prometheus

 import (
 	"errors"
 	"math"
 	"sync/atomic"

 	dto "github.com/prometheus/client_model/go"
 )

 // Counter is a Metric that represents a single numerical value that only ever
 // goes up. That implies that it cannot be used to count items whose number can
 // also go down, e.g. the number of currently running goroutines. Those
 // "counters" are represented by Gauges.
 //
 // A Counter is typically used to count requests served, tasks completed, errors
 // occurred, etc.
 //
 // To create Counter instances, use NewCounter.
 type Counter interface {
 	Metric
 	Collector

 	// Inc increments the counter by 1. Use Add to increment it by arbitrary
 	// non-negative values.
 	Inc()
 	// Add adds the given value to the counter. It panics if the value is <
 	// 0.
 	Add(float64)
 }

 // CounterOpts is an alias for Opts. See there for doc comments.
 type CounterOpts Opts

 // NewCounter creates a new Counter based on the provided CounterOpts.
 //
 // The returned implementation tracks the counter value in two separate
 // variables, a float64 and a uint64. The latter is used to track calls of the
 // Inc method and calls of the Add method with a value that can be represented
 // as a uint64. This allows atomic increments of the counter with optimal
 // performance. (It is common to have an Inc call in very hot execution paths.)
 // Both internal tracking values are added up in the Write method. This has to
 // be taken into account when it comes to precision and overflow behavior.
 func NewCounter(opts CounterOpts) Counter {
 	desc := NewDesc(
 		BuildFQName(opts.Namespace, opts.Subsystem, opts.Name),
 		opts.Help,
 		nil,
 		opts.ConstLabels,
 	)
 	result := &counter{desc: desc, labelPairs: desc.constLabelPairs}
 	result.init(result) // Init self-collection.
 	return result
 }

 type counter struct {
 	// valBits contains the bits of the represented float64 value, while
 	// valInt stores values that are exact integers. Both have to go first
 	// in the struct to guarantee alignment for atomic operations.
 	// http://golang.org/pkg/sync/atomic/#pkg-note-BUG
 	valBits uint64
 	valInt  uint64

 	selfCollector
 	desc *Desc

 	labelPairs []*dto.LabelPair
 }

 func (c *counter) Desc() *Desc {
 	return c.desc
 }

 func (c *counter) Add(v float64) {
 	if v < 0 {
 		panic(errors.New("counter cannot decrease in value"))
 	}
 	ival := uint64(v)
 	if float64(ival) == v {
 		atomic.AddUint64(&c.valInt, ival)
 		return
 	}

 	for {
 		oldBits := atomic.LoadUint64(&c.valBits)
 		newBits := math.Float64bits(math.Float64frombits(oldBits) + v)
 		if atomic.CompareAndSwapUint64(&c.valBits, oldBits, newBits) {
 			return
 		}
 	}
 }

 func (c *counter) Inc() {
 	atomic.AddUint64(&c.valInt, 1)
 }

 func (c *counter) Write(out *dto.Metric) error {
 	fval := math.Float64frombits(atomic.LoadUint64(&c.valBits))
 	ival := atomic.LoadUint64(&c.valInt)
 	val := fval + float64(ival)

 	return populateMetric(CounterValue, val, c.labelPairs, out)
 }

 // CounterVec is a Collector that bundles a set of Counters that all share the
 // same Desc, but have different values for their variable labels. This is used
 // if you want to count the same thing partitioned by various dimensions
 // (e.g. number of HTTP requests, partitioned by response code and
 // method). Create instances with NewCounterVec.
 type CounterVec struct {
 	*metricVec
 }

 // NewCounterVec creates a new CounterVec based on the provided CounterOpts and
 // partitioned by the given label names.
 func NewCounterVec(opts CounterOpts, labelNames []string) *CounterVec {
 	desc := NewDesc(
 		BuildFQName(opts.Namespace, opts.Subsystem, opts.Name),
 		opts.Help,
 		labelNames,
 		opts.ConstLabels,
 	)
 	return &CounterVec{
 		metricVec: newMetricVec(desc, func(lvs ...string) Metric {
 			if len(lvs) != len(desc.variableLabels) {
 				panic(makeInconsistentCardinalityError(desc.fqName, desc.variableLabels, lvs))
 			}
 			result := &counter{desc: desc, labelPairs: makeLabelPairs(desc, lvs)}
 			result.init(result) // Init self-collection.
 			return result
 		}),
 	}
 }

 // GetMetricWithLabelValues returns the Counter for the given slice of label
 // values (same order as the VariableLabels in Desc). If that combination of
 // label values is accessed for the first time, a new Counter is created.
 //
 // It is possible to call this method without using the returned Counter to only
 // create the new Counter but leave it at its starting value 0. See also the
 // SummaryVec example.
 //
 // Keeping the Counter for later use is possible (and should be considered if
 // performance is critical), but keep in mind that Reset, DeleteLabelValues and
 // Delete can be used to delete the Counter from the CounterVec. In that case,
 // the Counter will still exist, but it will not be exported anymore, even if a
 // Counter with the same label values is created later.
 //
 // An error is returned if the number of label values is not the same as the
 // number of VariableLabels in Desc (minus any curried labels).
 //
 // Note that for more than one label value, this method is prone to mistakes
 // caused by an incorrect order of arguments. Consider GetMetricWith(Labels) as
 // an alternative to avoid that type of mistake. For higher label numbers, the
 // latter has a much more readable (albeit more verbose) syntax, but it comes
 // with a performance overhead (for creating and processing the Labels map).
 // See also the GaugeVec example.
 func (v *CounterVec) GetMetricWithLabelValues(lvs ...string) (Counter, error) {
 	metric, err := v.metricVec.getMetricWithLabelValues(lvs...)
 	if metric != nil {
 		return metric.(Counter), err
 	}
 	return nil, err
 }

 // GetMetricWith returns the Counter for the given Labels map (the label names
 // must match those of the VariableLabels in Desc). If that label map is
 // accessed for the first time, a new Counter is created. Implications of
 // creating a Counter without using it and keeping the Counter for later use are
 // the same as for GetMetricWithLabelValues.
 //
 // An error is returned if the number and names of the Labels are inconsistent
 // with those of the VariableLabels in Desc (minus any curried labels).
 //
 // This method is used for the same purpose as
 // GetMetricWithLabelValues(...string). See there for pros and cons of the two
 // methods.
 func (v *CounterVec) GetMetricWith(labels Labels) (Counter, error) {
 	metric, err := v.metricVec.getMetricWith(labels)
 	if metric != nil {
 		return metric.(Counter), err
 	}
 	return nil, err
 }

 // WithLabelValues works as GetMetricWithLabelValues, but panics where
 // GetMetricWithLabelValues would have returned an error. Not returning an
 // error allows shortcuts like
 //     myVec.WithLabelValues("404", "GET").Add(42)
 func (v *CounterVec) WithLabelValues(lvs ...string) Counter {
 	c, err := v.GetMetricWithLabelValues(lvs...)
 	if err != nil {
 		panic(err)
 	}
 	return c
 }

 // With works as GetMetricWith, but panics where GetMetricWithLabels would have
 // returned an error. Not returning an error allows shortcuts like
 //     myVec.With(prometheus.Labels{"code": "404", "method": "GET"}).Add(42)
 func (v *CounterVec) With(labels Labels) Counter {
 	c, err := v.GetMetricWith(labels)
 	if err != nil {
 		panic(err)
 	}
 	return c
 }

 // CurryWith returns a vector curried with the provided labels, i.e. the
 // returned vector has those labels pre-set for all labeled operations performed
 // on it. The cardinality of the curried vector is reduced accordingly. The
 // order of the remaining labels stays the same (just with the curried labels
 // taken out of the sequence – which is relevant for the
 // (GetMetric)WithLabelValues methods). It is possible to curry a curried
 // vector, but only with labels not yet used for currying before.
 //
 // The metrics contained in the CounterVec are shared between the curried and
 // uncurried vectors. They are just accessed differently. Curried and uncurried
 // vectors behave identically in terms of collection. Only one must be
 // registered with a given registry (usually the uncurried version). The Reset
 // method deletes all metrics, even if called on a curried vector.
 func (v *CounterVec) CurryWith(labels Labels) (*CounterVec, error) {
 	vec, err := v.curryWith(labels)
 	if vec != nil {
 		return &CounterVec{vec}, err
 	}
 	return nil, err
 }

 // MustCurryWith works as CurryWith but panics where CurryWith would have
 // returned an error.
 func (v *CounterVec) MustCurryWith(labels Labels) *CounterVec {
 	vec, err := v.CurryWith(labels)
 	if err != nil {
 		panic(err)
 	}
 	return vec
 }

 // CounterFunc is a Counter whose value is determined at collect time by calling a
 // provided function.
 //
 // To create CounterFunc instances, use NewCounterFunc.
 type CounterFunc interface {
 	Metric
 	Collector
 }

 // NewCounterFunc creates a new CounterFunc based on the provided
 // CounterOpts. The value reported is determined by calling the given function
 // from within the Write method. Take into account that metric collection may
 // happen concurrently. If that results in concurrent calls to Write, like in
 // the case where a CounterFunc is directly registered with Prometheus, the
 // provided function must be concurrency-safe. The function should also honor
 // the contract for a Counter (values only go up, not down), but compliance will
 // not be checked.
 func NewCounterFunc(opts CounterOpts, function func() float64) CounterFunc {
 	return newValueFunc(NewDesc(
 		BuildFQName(opts.Namespace, opts.Subsystem, opts.Name),
 		opts.Help,
 		nil,
 		opts.ConstLabels,
 	), CounterValue, function)
 }
	// Copyright 2014 The Prometheus Authors
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	package prometheus

	import (
	"errors"
	"math"
	"sync/atomic"

	dto "github.com/prometheus/client_model/go"
	)

	// Counter is a Metric that represents a single numerical value that only ever
	// goes up. That implies that it cannot be used to count items whose number can
	// also go down, e.g. the number of currently running goroutines. Those
	// "counters" are represented by Gauges.
	//
	// A Counter is typically used to count requests served, tasks completed, errors
	// occurred, etc.
	//
	// To create Counter instances, use NewCounter.
	type Counter interface {
	Metric
	Collector

	// Inc increments the counter by 1. Use Add to increment it by arbitrary
	// non-negative values.
	Inc()
	// Add adds the given value to the counter. It panics if the value is <
	// 0.
	Add(float64)
	}

	// CounterOpts is an alias for Opts. See there for doc comments.
	type CounterOpts Opts

	// NewCounter creates a new Counter based on the provided CounterOpts.
	//
	// The returned implementation tracks the counter value in two separate
	// variables, a float64 and a uint64. The latter is used to track calls of the
	// Inc method and calls of the Add method with a value that can be represented
	// as a uint64. This allows atomic increments of the counter with optimal
	// performance. (It is common to have an Inc call in very hot execution paths.)
	// Both internal tracking values are added up in the Write method. This has to
	// be taken into account when it comes to precision and overflow behavior.
	func NewCounter(opts CounterOpts) Counter {
	desc := NewDesc(
	BuildFQName(opts.Namespace, opts.Subsystem, opts.Name),
	opts.Help,
	nil,
	opts.ConstLabels,
	)
	result := &counter{desc: desc, labelPairs: desc.constLabelPairs}
	result.init(result) // Init self-collection.
	return result
	}

	type counter struct {
	// valBits contains the bits of the represented float64 value, while
	// valInt stores values that are exact integers. Both have to go first
	// in the struct to guarantee alignment for atomic operations.
	// http://golang.org/pkg/sync/atomic/#pkg-note-BUG
	valBits uint64
	valInt uint64

	selfCollector
	desc *Desc

	labelPairs []*dto.LabelPair
	}

	func (c counter) Desc() Desc {
	return c.desc
	}

	func (c *counter) Add(v float64) {
	if v < 0 {
	panic(errors.New("counter cannot decrease in value"))
	}
	ival := uint64(v)
	if float64(ival) == v {
	atomic.AddUint64(&c.valInt, ival)
	return
	}

	for {
	oldBits := atomic.LoadUint64(&c.valBits)
	newBits := math.Float64bits(math.Float64frombits(oldBits) + v)
	if atomic.CompareAndSwapUint64(&c.valBits, oldBits, newBits) {
	return
	}
	}
	}

	func (c *counter) Inc() {
	atomic.AddUint64(&c.valInt, 1)
	}

	func (c counter) Write(out dto.Metric) error {
	fval := math.Float64frombits(atomic.LoadUint64(&c.valBits))
	ival := atomic.LoadUint64(&c.valInt)
	val := fval + float64(ival)

	return populateMetric(CounterValue, val, c.labelPairs, out)
	}

	// CounterVec is a Collector that bundles a set of Counters that all share the
	// same Desc, but have different values for their variable labels. This is used
	// if you want to count the same thing partitioned by various dimensions
	// (e.g. number of HTTP requests, partitioned by response code and
	// method). Create instances with NewCounterVec.
	type CounterVec struct {
	*metricVec
	}

	// NewCounterVec creates a new CounterVec based on the provided CounterOpts and
	// partitioned by the given label names.
	func NewCounterVec(opts CounterOpts, labelNames []string) *CounterVec {
	desc := NewDesc(
	BuildFQName(opts.Namespace, opts.Subsystem, opts.Name),
	opts.Help,
	labelNames,
	opts.ConstLabels,
	)
	return &CounterVec{
	metricVec: newMetricVec(desc, func(lvs ...string) Metric {
	if len(lvs) != len(desc.variableLabels) {
	panic(makeInconsistentCardinalityError(desc.fqName, desc.variableLabels, lvs))
	}
	result := &counter{desc: desc, labelPairs: makeLabelPairs(desc, lvs)}
	result.init(result) // Init self-collection.
	return result
	}),
	}
	}

	// GetMetricWithLabelValues returns the Counter for the given slice of label
	// values (same order as the VariableLabels in Desc). If that combination of
	// label values is accessed for the first time, a new Counter is created.
	//
	// It is possible to call this method without using the returned Counter to only
	// create the new Counter but leave it at its starting value 0. See also the
	// SummaryVec example.
	//
	// Keeping the Counter for later use is possible (and should be considered if
	// performance is critical), but keep in mind that Reset, DeleteLabelValues and
	// Delete can be used to delete the Counter from the CounterVec. In that case,
	// the Counter will still exist, but it will not be exported anymore, even if a
	// Counter with the same label values is created later.
	//
	// An error is returned if the number of label values is not the same as the
	// number of VariableLabels in Desc (minus any curried labels).
	//
	// Note that for more than one label value, this method is prone to mistakes
	// caused by an incorrect order of arguments. Consider GetMetricWith(Labels) as
	// an alternative to avoid that type of mistake. For higher label numbers, the
	// latter has a much more readable (albeit more verbose) syntax, but it comes
	// with a performance overhead (for creating and processing the Labels map).
	// See also the GaugeVec example.
	func (v *CounterVec) GetMetricWithLabelValues(lvs ...string) (Counter, error) {
	metric, err := v.metricVec.getMetricWithLabelValues(lvs...)
	if metric != nil {
	return metric.(Counter), err
	}
	return nil, err
	}

	// GetMetricWith returns the Counter for the given Labels map (the label names
	// must match those of the VariableLabels in Desc). If that label map is
	// accessed for the first time, a new Counter is created. Implications of
	// creating a Counter without using it and keeping the Counter for later use are
	// the same as for GetMetricWithLabelValues.
	//
	// An error is returned if the number and names of the Labels are inconsistent
	// with those of the VariableLabels in Desc (minus any curried labels).
	//
	// This method is used for the same purpose as
	// GetMetricWithLabelValues(...string). See there for pros and cons of the two
	// methods.
	func (v *CounterVec) GetMetricWith(labels Labels) (Counter, error) {
	metric, err := v.metricVec.getMetricWith(labels)
	if metric != nil {
	return metric.(Counter), err
	}
	return nil, err
	}

	// WithLabelValues works as GetMetricWithLabelValues, but panics where
	// GetMetricWithLabelValues would have returned an error. Not returning an
	// error allows shortcuts like
	// myVec.WithLabelValues("404", "GET").Add(42)
	func (v *CounterVec) WithLabelValues(lvs ...string) Counter {
	c, err := v.GetMetricWithLabelValues(lvs...)
	if err != nil {
	panic(err)
	}
	return c
	}

	// With works as GetMetricWith, but panics where GetMetricWithLabels would have
	// returned an error. Not returning an error allows shortcuts like
	// myVec.With(prometheus.Labels{"code": "404", "method": "GET"}).Add(42)
	func (v *CounterVec) With(labels Labels) Counter {
	c, err := v.GetMetricWith(labels)
	if err != nil {
	panic(err)
	}
	return c
	}

	// CurryWith returns a vector curried with the provided labels, i.e. the
	// returned vector has those labels pre-set for all labeled operations performed
	// on it. The cardinality of the curried vector is reduced accordingly. The
	// order of the remaining labels stays the same (just with the curried labels
	// taken out of the sequence – which is relevant for the
	// (GetMetric)WithLabelValues methods). It is possible to curry a curried
	// vector, but only with labels not yet used for currying before.
	//
	// The metrics contained in the CounterVec are shared between the curried and
	// uncurried vectors. They are just accessed differently. Curried and uncurried
	// vectors behave identically in terms of collection. Only one must be
	// registered with a given registry (usually the uncurried version). The Reset
	// method deletes all metrics, even if called on a curried vector.
	func (v CounterVec) CurryWith(labels Labels) (CounterVec, error) {
	vec, err := v.curryWith(labels)
	if vec != nil {
	return &CounterVec{vec}, err
	}
	return nil, err
	}

	// MustCurryWith works as CurryWith but panics where CurryWith would have
	// returned an error.
	func (v CounterVec) MustCurryWith(labels Labels) CounterVec {
	vec, err := v.CurryWith(labels)
	if err != nil {
	panic(err)
	}
	return vec
	}

	// CounterFunc is a Counter whose value is determined at collect time by calling a
	// provided function.
	//
	// To create CounterFunc instances, use NewCounterFunc.
	type CounterFunc interface {
	Metric
	Collector
	}

	// NewCounterFunc creates a new CounterFunc based on the provided
	// CounterOpts. The value reported is determined by calling the given function
	// from within the Write method. Take into account that metric collection may
	// happen concurrently. If that results in concurrent calls to Write, like in
	// the case where a CounterFunc is directly registered with Prometheus, the
	// provided function must be concurrency-safe. The function should also honor
	// the contract for a Counter (values only go up, not down), but compliance will
	// not be checked.
	func NewCounterFunc(opts CounterOpts, function func() float64) CounterFunc {
	return newValueFunc(NewDesc(
	BuildFQName(opts.Namespace, opts.Subsystem, opts.Name),
	opts.Help,
	nil,
	opts.ConstLabels,
	), CounterValue, function)
	}