078c404c3b
* Add prometheus collector and route * dep ensure -add github.com/prometheus/client_golang/prometheus * dep ensure -update github.com/golang/protobuf * add metrics to reserved usernames * add comment head in metrics package * fix style imports * add metrics settings * add bearer token check * mapping metrics configs * fix lint * update config cheat sheet * update conf sample, typo fix
614 lines
21 KiB
Go
614 lines
21 KiB
Go
// Copyright 2015 The Prometheus Authors
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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package prometheus
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import (
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"fmt"
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"math"
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"runtime"
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"sort"
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"sync"
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"sync/atomic"
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"github.com/golang/protobuf/proto"
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dto "github.com/prometheus/client_model/go"
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)
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// A Histogram counts individual observations from an event or sample stream in
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// configurable buckets. Similar to a summary, it also provides a sum of
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// observations and an observation count.
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//
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// On the Prometheus server, quantiles can be calculated from a Histogram using
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// the histogram_quantile function in the query language.
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//
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// Note that Histograms, in contrast to Summaries, can be aggregated with the
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// Prometheus query language (see the documentation for detailed
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// procedures). However, Histograms require the user to pre-define suitable
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// buckets, and they are in general less accurate. The Observe method of a
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// Histogram has a very low performance overhead in comparison with the Observe
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// method of a Summary.
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//
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// To create Histogram instances, use NewHistogram.
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type Histogram interface {
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Metric
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Collector
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// Observe adds a single observation to the histogram.
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Observe(float64)
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}
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// bucketLabel is used for the label that defines the upper bound of a
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// bucket of a histogram ("le" -> "less or equal").
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const bucketLabel = "le"
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// DefBuckets are the default Histogram buckets. The default buckets are
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// tailored to broadly measure the response time (in seconds) of a network
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// service. Most likely, however, you will be required to define buckets
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// customized to your use case.
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var (
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DefBuckets = []float64{.005, .01, .025, .05, .1, .25, .5, 1, 2.5, 5, 10}
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errBucketLabelNotAllowed = fmt.Errorf(
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"%q is not allowed as label name in histograms", bucketLabel,
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)
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)
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// LinearBuckets creates 'count' buckets, each 'width' wide, where the lowest
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// bucket has an upper bound of 'start'. The final +Inf bucket is not counted
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// and not included in the returned slice. The returned slice is meant to be
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// used for the Buckets field of HistogramOpts.
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//
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// The function panics if 'count' is zero or negative.
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func LinearBuckets(start, width float64, count int) []float64 {
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if count < 1 {
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panic("LinearBuckets needs a positive count")
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}
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buckets := make([]float64, count)
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for i := range buckets {
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buckets[i] = start
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start += width
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}
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return buckets
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}
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// ExponentialBuckets creates 'count' buckets, where the lowest bucket has an
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// upper bound of 'start' and each following bucket's upper bound is 'factor'
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// times the previous bucket's upper bound. The final +Inf bucket is not counted
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// and not included in the returned slice. The returned slice is meant to be
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// used for the Buckets field of HistogramOpts.
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//
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// The function panics if 'count' is 0 or negative, if 'start' is 0 or negative,
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// or if 'factor' is less than or equal 1.
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func ExponentialBuckets(start, factor float64, count int) []float64 {
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if count < 1 {
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panic("ExponentialBuckets needs a positive count")
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}
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if start <= 0 {
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panic("ExponentialBuckets needs a positive start value")
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}
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if factor <= 1 {
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panic("ExponentialBuckets needs a factor greater than 1")
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}
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buckets := make([]float64, count)
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for i := range buckets {
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buckets[i] = start
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start *= factor
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}
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return buckets
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}
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// HistogramOpts bundles the options for creating a Histogram metric. It is
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// mandatory to set Name to a non-empty string. All other fields are optional
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// and can safely be left at their zero value, although it is strongly
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// encouraged to set a Help string.
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type HistogramOpts struct {
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// Namespace, Subsystem, and Name are components of the fully-qualified
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// name of the Histogram (created by joining these components with
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// "_"). Only Name is mandatory, the others merely help structuring the
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// name. Note that the fully-qualified name of the Histogram must be a
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// valid Prometheus metric name.
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Namespace string
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Subsystem string
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Name string
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// Help provides information about this Histogram.
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//
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// Metrics with the same fully-qualified name must have the same Help
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// string.
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Help string
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// ConstLabels are used to attach fixed labels to this metric. Metrics
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// with the same fully-qualified name must have the same label names in
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// their ConstLabels.
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//
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// ConstLabels are only used rarely. In particular, do not use them to
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// attach the same labels to all your metrics. Those use cases are
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// better covered by target labels set by the scraping Prometheus
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// server, or by one specific metric (e.g. a build_info or a
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// machine_role metric). See also
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// https://prometheus.io/docs/instrumenting/writing_exporters/#target-labels,-not-static-scraped-labels
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ConstLabels Labels
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// Buckets defines the buckets into which observations are counted. Each
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// element in the slice is the upper inclusive bound of a bucket. The
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// values must be sorted in strictly increasing order. There is no need
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// to add a highest bucket with +Inf bound, it will be added
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// implicitly. The default value is DefBuckets.
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Buckets []float64
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}
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// NewHistogram creates a new Histogram based on the provided HistogramOpts. It
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// panics if the buckets in HistogramOpts are not in strictly increasing order.
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func NewHistogram(opts HistogramOpts) Histogram {
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return newHistogram(
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NewDesc(
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BuildFQName(opts.Namespace, opts.Subsystem, opts.Name),
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opts.Help,
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nil,
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opts.ConstLabels,
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),
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opts,
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)
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}
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func newHistogram(desc *Desc, opts HistogramOpts, labelValues ...string) Histogram {
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if len(desc.variableLabels) != len(labelValues) {
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panic(errInconsistentCardinality)
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}
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for _, n := range desc.variableLabels {
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if n == bucketLabel {
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panic(errBucketLabelNotAllowed)
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}
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}
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for _, lp := range desc.constLabelPairs {
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if lp.GetName() == bucketLabel {
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panic(errBucketLabelNotAllowed)
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}
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}
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if len(opts.Buckets) == 0 {
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opts.Buckets = DefBuckets
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}
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h := &histogram{
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desc: desc,
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upperBounds: opts.Buckets,
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labelPairs: makeLabelPairs(desc, labelValues),
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counts: [2]*histogramCounts{&histogramCounts{}, &histogramCounts{}},
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}
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for i, upperBound := range h.upperBounds {
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if i < len(h.upperBounds)-1 {
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if upperBound >= h.upperBounds[i+1] {
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panic(fmt.Errorf(
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"histogram buckets must be in increasing order: %f >= %f",
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upperBound, h.upperBounds[i+1],
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))
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}
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} else {
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if math.IsInf(upperBound, +1) {
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// The +Inf bucket is implicit. Remove it here.
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h.upperBounds = h.upperBounds[:i]
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}
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}
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}
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// Finally we know the final length of h.upperBounds and can make counts
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// for both states:
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h.counts[0].buckets = make([]uint64, len(h.upperBounds))
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h.counts[1].buckets = make([]uint64, len(h.upperBounds))
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h.init(h) // Init self-collection.
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return h
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}
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type histogramCounts struct {
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// sumBits contains the bits of the float64 representing the sum of all
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// observations. sumBits and count have to go first in the struct to
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// guarantee alignment for atomic operations.
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// http://golang.org/pkg/sync/atomic/#pkg-note-BUG
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sumBits uint64
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count uint64
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buckets []uint64
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}
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type histogram struct {
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// countAndHotIdx is a complicated one. For lock-free yet atomic
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// observations, we need to save the total count of observations again,
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// combined with the index of the currently-hot counts struct, so that
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// we can perform the operation on both values atomically. The least
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// significant bit defines the hot counts struct. The remaining 63 bits
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// represent the total count of observations. This happens under the
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// assumption that the 63bit count will never overflow. Rationale: An
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// observations takes about 30ns. Let's assume it could happen in
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// 10ns. Overflowing the counter will then take at least (2^63)*10ns,
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// which is about 3000 years.
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//
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// This has to be first in the struct for 64bit alignment. See
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// http://golang.org/pkg/sync/atomic/#pkg-note-BUG
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countAndHotIdx uint64
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selfCollector
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desc *Desc
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writeMtx sync.Mutex // Only used in the Write method.
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upperBounds []float64
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// Two counts, one is "hot" for lock-free observations, the other is
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// "cold" for writing out a dto.Metric. It has to be an array of
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// pointers to guarantee 64bit alignment of the histogramCounts, see
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// http://golang.org/pkg/sync/atomic/#pkg-note-BUG.
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counts [2]*histogramCounts
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hotIdx int // Index of currently-hot counts. Only used within Write.
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labelPairs []*dto.LabelPair
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}
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func (h *histogram) Desc() *Desc {
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return h.desc
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}
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func (h *histogram) Observe(v float64) {
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// TODO(beorn7): For small numbers of buckets (<30), a linear search is
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// slightly faster than the binary search. If we really care, we could
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// switch from one search strategy to the other depending on the number
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// of buckets.
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//
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// Microbenchmarks (BenchmarkHistogramNoLabels):
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// 11 buckets: 38.3 ns/op linear - binary 48.7 ns/op
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// 100 buckets: 78.1 ns/op linear - binary 54.9 ns/op
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// 300 buckets: 154 ns/op linear - binary 61.6 ns/op
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i := sort.SearchFloat64s(h.upperBounds, v)
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// We increment h.countAndHotIdx by 2 so that the counter in the upper
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// 63 bits gets incremented by 1. At the same time, we get the new value
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// back, which we can use to find the currently-hot counts.
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n := atomic.AddUint64(&h.countAndHotIdx, 2)
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hotCounts := h.counts[n%2]
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if i < len(h.upperBounds) {
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atomic.AddUint64(&hotCounts.buckets[i], 1)
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}
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for {
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oldBits := atomic.LoadUint64(&hotCounts.sumBits)
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newBits := math.Float64bits(math.Float64frombits(oldBits) + v)
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if atomic.CompareAndSwapUint64(&hotCounts.sumBits, oldBits, newBits) {
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break
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}
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}
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// Increment count last as we take it as a signal that the observation
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// is complete.
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atomic.AddUint64(&hotCounts.count, 1)
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}
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func (h *histogram) Write(out *dto.Metric) error {
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var (
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his = &dto.Histogram{}
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buckets = make([]*dto.Bucket, len(h.upperBounds))
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hotCounts, coldCounts *histogramCounts
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count uint64
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)
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// For simplicity, we mutex the rest of this method. It is not in the
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// hot path, i.e. Observe is called much more often than Write. The
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// complication of making Write lock-free isn't worth it.
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h.writeMtx.Lock()
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defer h.writeMtx.Unlock()
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// This is a bit arcane, which is why the following spells out this if
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// clause in English:
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//
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// If the currently-hot counts struct is #0, we atomically increment
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// h.countAndHotIdx by 1 so that from now on Observe will use the counts
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// struct #1. Furthermore, the atomic increment gives us the new value,
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// which, in its most significant 63 bits, tells us the count of
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// observations done so far up to and including currently ongoing
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// observations still using the counts struct just changed from hot to
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// cold. To have a normal uint64 for the count, we bitshift by 1 and
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// save the result in count. We also set h.hotIdx to 1 for the next
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// Write call, and we will refer to counts #1 as hotCounts and to counts
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// #0 as coldCounts.
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//
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// If the currently-hot counts struct is #1, we do the corresponding
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// things the other way round. We have to _decrement_ h.countAndHotIdx
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// (which is a bit arcane in itself, as we have to express -1 with an
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// unsigned int...).
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if h.hotIdx == 0 {
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count = atomic.AddUint64(&h.countAndHotIdx, 1) >> 1
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h.hotIdx = 1
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hotCounts = h.counts[1]
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coldCounts = h.counts[0]
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} else {
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count = atomic.AddUint64(&h.countAndHotIdx, ^uint64(0)) >> 1 // Decrement.
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h.hotIdx = 0
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hotCounts = h.counts[0]
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coldCounts = h.counts[1]
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}
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// Now we have to wait for the now-declared-cold counts to actually cool
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// down, i.e. wait for all observations still using it to finish. That's
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// the case once the count in the cold counts struct is the same as the
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// one atomically retrieved from the upper 63bits of h.countAndHotIdx.
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for {
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if count == atomic.LoadUint64(&coldCounts.count) {
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break
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}
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runtime.Gosched() // Let observations get work done.
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}
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his.SampleCount = proto.Uint64(count)
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his.SampleSum = proto.Float64(math.Float64frombits(atomic.LoadUint64(&coldCounts.sumBits)))
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var cumCount uint64
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for i, upperBound := range h.upperBounds {
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cumCount += atomic.LoadUint64(&coldCounts.buckets[i])
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buckets[i] = &dto.Bucket{
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CumulativeCount: proto.Uint64(cumCount),
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UpperBound: proto.Float64(upperBound),
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}
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}
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his.Bucket = buckets
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out.Histogram = his
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out.Label = h.labelPairs
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// Finally add all the cold counts to the new hot counts and reset the cold counts.
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atomic.AddUint64(&hotCounts.count, count)
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atomic.StoreUint64(&coldCounts.count, 0)
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for {
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oldBits := atomic.LoadUint64(&hotCounts.sumBits)
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newBits := math.Float64bits(math.Float64frombits(oldBits) + his.GetSampleSum())
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if atomic.CompareAndSwapUint64(&hotCounts.sumBits, oldBits, newBits) {
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atomic.StoreUint64(&coldCounts.sumBits, 0)
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break
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}
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}
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for i := range h.upperBounds {
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atomic.AddUint64(&hotCounts.buckets[i], atomic.LoadUint64(&coldCounts.buckets[i]))
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atomic.StoreUint64(&coldCounts.buckets[i], 0)
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}
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return nil
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}
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// HistogramVec is a Collector that bundles a set of Histograms that all share the
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// same Desc, but have different values for their variable labels. This is used
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// if you want to count the same thing partitioned by various dimensions
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// (e.g. HTTP request latencies, partitioned by status code and method). Create
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// instances with NewHistogramVec.
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type HistogramVec struct {
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*metricVec
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}
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// NewHistogramVec creates a new HistogramVec based on the provided HistogramOpts and
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// partitioned by the given label names.
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func NewHistogramVec(opts HistogramOpts, labelNames []string) *HistogramVec {
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desc := NewDesc(
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BuildFQName(opts.Namespace, opts.Subsystem, opts.Name),
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opts.Help,
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labelNames,
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opts.ConstLabels,
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)
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return &HistogramVec{
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metricVec: newMetricVec(desc, func(lvs ...string) Metric {
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return newHistogram(desc, opts, lvs...)
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}),
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}
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}
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// GetMetricWithLabelValues returns the Histogram for the given slice of label
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// values (same order as the VariableLabels in Desc). If that combination of
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// label values is accessed for the first time, a new Histogram is created.
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//
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// It is possible to call this method without using the returned Histogram to only
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// create the new Histogram but leave it at its starting value, a Histogram without
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// any observations.
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//
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// Keeping the Histogram for later use is possible (and should be considered if
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// performance is critical), but keep in mind that Reset, DeleteLabelValues and
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// Delete can be used to delete the Histogram from the HistogramVec. In that case, the
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// Histogram will still exist, but it will not be exported anymore, even if a
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// Histogram with the same label values is created later. See also the CounterVec
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// example.
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//
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// An error is returned if the number of label values is not the same as the
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// number of VariableLabels in Desc (minus any curried labels).
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//
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// Note that for more than one label value, this method is prone to mistakes
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// caused by an incorrect order of arguments. Consider GetMetricWith(Labels) as
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// an alternative to avoid that type of mistake. For higher label numbers, the
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// latter has a much more readable (albeit more verbose) syntax, but it comes
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// with a performance overhead (for creating and processing the Labels map).
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// See also the GaugeVec example.
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func (v *HistogramVec) GetMetricWithLabelValues(lvs ...string) (Observer, error) {
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metric, err := v.metricVec.getMetricWithLabelValues(lvs...)
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if metric != nil {
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return metric.(Observer), err
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}
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return nil, err
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}
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// GetMetricWith returns the Histogram for the given Labels map (the label names
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// must match those of the VariableLabels in Desc). If that label map is
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// accessed for the first time, a new Histogram is created. Implications of
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// creating a Histogram without using it and keeping the Histogram for later use
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// are the same as for GetMetricWithLabelValues.
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//
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// An error is returned if the number and names of the Labels are inconsistent
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// with those of the VariableLabels in Desc (minus any curried labels).
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//
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// This method is used for the same purpose as
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// GetMetricWithLabelValues(...string). See there for pros and cons of the two
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// methods.
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func (v *HistogramVec) GetMetricWith(labels Labels) (Observer, error) {
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metric, err := v.metricVec.getMetricWith(labels)
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if metric != nil {
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return metric.(Observer), err
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}
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return nil, err
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}
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// WithLabelValues works as GetMetricWithLabelValues, but panics where
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// GetMetricWithLabelValues would have returned an error. Not returning an
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// error allows shortcuts like
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// myVec.WithLabelValues("404", "GET").Observe(42.21)
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func (v *HistogramVec) WithLabelValues(lvs ...string) Observer {
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h, err := v.GetMetricWithLabelValues(lvs...)
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if err != nil {
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panic(err)
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}
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return h
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}
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// With works as GetMetricWith but panics where GetMetricWithLabels would have
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// returned an error. Not returning an error allows shortcuts like
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// myVec.With(prometheus.Labels{"code": "404", "method": "GET"}).Observe(42.21)
|
||
func (v *HistogramVec) With(labels Labels) Observer {
|
||
h, err := v.GetMetricWith(labels)
|
||
if err != nil {
|
||
panic(err)
|
||
}
|
||
return h
|
||
}
|
||
|
||
// 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 HistogramVec 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 *HistogramVec) CurryWith(labels Labels) (ObserverVec, error) {
|
||
vec, err := v.curryWith(labels)
|
||
if vec != nil {
|
||
return &HistogramVec{vec}, err
|
||
}
|
||
return nil, err
|
||
}
|
||
|
||
// MustCurryWith works as CurryWith but panics where CurryWith would have
|
||
// returned an error.
|
||
func (v *HistogramVec) MustCurryWith(labels Labels) ObserverVec {
|
||
vec, err := v.CurryWith(labels)
|
||
if err != nil {
|
||
panic(err)
|
||
}
|
||
return vec
|
||
}
|
||
|
||
type constHistogram struct {
|
||
desc *Desc
|
||
count uint64
|
||
sum float64
|
||
buckets map[float64]uint64
|
||
labelPairs []*dto.LabelPair
|
||
}
|
||
|
||
func (h *constHistogram) Desc() *Desc {
|
||
return h.desc
|
||
}
|
||
|
||
func (h *constHistogram) Write(out *dto.Metric) error {
|
||
his := &dto.Histogram{}
|
||
buckets := make([]*dto.Bucket, 0, len(h.buckets))
|
||
|
||
his.SampleCount = proto.Uint64(h.count)
|
||
his.SampleSum = proto.Float64(h.sum)
|
||
|
||
for upperBound, count := range h.buckets {
|
||
buckets = append(buckets, &dto.Bucket{
|
||
CumulativeCount: proto.Uint64(count),
|
||
UpperBound: proto.Float64(upperBound),
|
||
})
|
||
}
|
||
|
||
if len(buckets) > 0 {
|
||
sort.Sort(buckSort(buckets))
|
||
}
|
||
his.Bucket = buckets
|
||
|
||
out.Histogram = his
|
||
out.Label = h.labelPairs
|
||
|
||
return nil
|
||
}
|
||
|
||
// NewConstHistogram returns a metric representing a Prometheus histogram with
|
||
// fixed values for the count, sum, and bucket counts. As those parameters
|
||
// cannot be changed, the returned value does not implement the Histogram
|
||
// interface (but only the Metric interface). Users of this package will not
|
||
// have much use for it in regular operations. However, when implementing custom
|
||
// Collectors, it is useful as a throw-away metric that is generated on the fly
|
||
// to send it to Prometheus in the Collect method.
|
||
//
|
||
// buckets is a map of upper bounds to cumulative counts, excluding the +Inf
|
||
// bucket.
|
||
//
|
||
// NewConstHistogram returns an error if the length of labelValues is not
|
||
// consistent with the variable labels in Desc or if Desc is invalid.
|
||
func NewConstHistogram(
|
||
desc *Desc,
|
||
count uint64,
|
||
sum float64,
|
||
buckets map[float64]uint64,
|
||
labelValues ...string,
|
||
) (Metric, error) {
|
||
if desc.err != nil {
|
||
return nil, desc.err
|
||
}
|
||
if err := validateLabelValues(labelValues, len(desc.variableLabels)); err != nil {
|
||
return nil, err
|
||
}
|
||
return &constHistogram{
|
||
desc: desc,
|
||
count: count,
|
||
sum: sum,
|
||
buckets: buckets,
|
||
labelPairs: makeLabelPairs(desc, labelValues),
|
||
}, nil
|
||
}
|
||
|
||
// MustNewConstHistogram is a version of NewConstHistogram that panics where
|
||
// NewConstMetric would have returned an error.
|
||
func MustNewConstHistogram(
|
||
desc *Desc,
|
||
count uint64,
|
||
sum float64,
|
||
buckets map[float64]uint64,
|
||
labelValues ...string,
|
||
) Metric {
|
||
m, err := NewConstHistogram(desc, count, sum, buckets, labelValues...)
|
||
if err != nil {
|
||
panic(err)
|
||
}
|
||
return m
|
||
}
|
||
|
||
type buckSort []*dto.Bucket
|
||
|
||
func (s buckSort) Len() int {
|
||
return len(s)
|
||
}
|
||
|
||
func (s buckSort) Swap(i, j int) {
|
||
s[i], s[j] = s[j], s[i]
|
||
}
|
||
|
||
func (s buckSort) Less(i, j int) bool {
|
||
return s[i].GetUpperBound() < s[j].GetUpperBound()
|
||
}
|