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prometheus/model/histogram/histogram.go

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// Copyright 2021 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 histogram
import (
"fmt"
"math"
"strings"
"golang.org/x/exp/slices"
)
// CounterResetHint contains the known information about a counter reset,
// or alternatively that we are dealing with a gauge histogram, where counter resets do not apply.
type CounterResetHint byte
const (
UnknownCounterReset CounterResetHint = iota // UnknownCounterReset means we cannot say if this histogram signals a counter reset or not.
CounterReset // CounterReset means there was definitely a counter reset starting from this histogram.
NotCounterReset // NotCounterReset means there was definitely no counter reset with this histogram.
GaugeType // GaugeType means this is a gauge histogram, where counter resets do not happen.
)
// Histogram encodes a sparse, high-resolution histogram. See the design
// document for full details:
// https://docs.google.com/document/d/1cLNv3aufPZb3fNfaJgdaRBZsInZKKIHo9E6HinJVbpM/edit#
//
// The most tricky bit is how bucket indices represent real bucket boundaries.
// An example for schema 0 (by which each bucket is twice as wide as the
// previous bucket):
//
// Bucket boundaries → [-2,-1) [-1,-0.5) [-0.5,-0.25) ... [-0.001,0.001] ... (0.25,0.5] (0.5,1] (1,2] ....
// ↑ ↑ ↑ ↑ ↑ ↑ ↑
// Zero bucket (width e.g. 0.001) → | | | ZB | | |
// Positive bucket indices → | | | ... -1 0 1 2 3
// Negative bucket indices → 3 2 1 0 -1 ...
//
// Which bucket indices are actually used is determined by the spans.
type Histogram struct {
// Counter reset information.
CounterResetHint CounterResetHint
// Currently valid schema numbers are -4 <= n <= 8. They are all for
// base-2 bucket schemas, where 1 is a bucket boundary in each case, and
// then each power of two is divided into 2^n logarithmic buckets. Or
// in other words, each bucket boundary is the previous boundary times
// 2^(2^-n).
Schema int32
// Width of the zero bucket.
ZeroThreshold float64
// Observations falling into the zero bucket.
ZeroCount uint64
// Total number of observations.
Count uint64
// Sum of observations. This is also used as the stale marker.
Sum float64
// Spans for positive and negative buckets (see Span below).
PositiveSpans, NegativeSpans []Span
// Observation counts in buckets. The first element is an absolute
// count. All following ones are deltas relative to the previous
// element.
PositiveBuckets, NegativeBuckets []int64
}
// A Span defines a continuous sequence of buckets.
type Span struct {
// Gap to previous span (always positive), or starting index for the 1st
// span (which can be negative).
Offset int32
// Length of the span.
Length uint32
}
// Copy returns a deep copy of the Histogram.
func (h *Histogram) Copy() *Histogram {
c := *h
if len(h.PositiveSpans) != 0 {
c.PositiveSpans = make([]Span, len(h.PositiveSpans))
copy(c.PositiveSpans, h.PositiveSpans)
}
if len(h.NegativeSpans) != 0 {
c.NegativeSpans = make([]Span, len(h.NegativeSpans))
copy(c.NegativeSpans, h.NegativeSpans)
}
if len(h.PositiveBuckets) != 0 {
c.PositiveBuckets = make([]int64, len(h.PositiveBuckets))
copy(c.PositiveBuckets, h.PositiveBuckets)
}
if len(h.NegativeBuckets) != 0 {
c.NegativeBuckets = make([]int64, len(h.NegativeBuckets))
copy(c.NegativeBuckets, h.NegativeBuckets)
}
return &c
}
// String returns a string representation of the Histogram.
func (h *Histogram) String() string {
var sb strings.Builder
fmt.Fprintf(&sb, "{count:%d, sum:%g", h.Count, h.Sum)
var nBuckets []Bucket[uint64]
for it := h.NegativeBucketIterator(); it.Next(); {
bucket := it.At()
if bucket.Count != 0 {
nBuckets = append(nBuckets, it.At())
}
}
for i := len(nBuckets) - 1; i >= 0; i-- {
fmt.Fprintf(&sb, ", %s", nBuckets[i].String())
}
if h.ZeroCount != 0 {
fmt.Fprintf(&sb, ", %s", h.ZeroBucket().String())
}
for it := h.PositiveBucketIterator(); it.Next(); {
bucket := it.At()
if bucket.Count != 0 {
fmt.Fprintf(&sb, ", %s", bucket.String())
}
}
sb.WriteRune('}')
return sb.String()
}
// ZeroBucket returns the zero bucket.
func (h *Histogram) ZeroBucket() Bucket[uint64] {
return Bucket[uint64]{
Lower: -h.ZeroThreshold,
Upper: h.ZeroThreshold,
LowerInclusive: true,
UpperInclusive: true,
Count: h.ZeroCount,
}
}
// PositiveBucketIterator returns a BucketIterator to iterate over all positive
// buckets in ascending order (starting next to the zero bucket and going up).
func (h *Histogram) PositiveBucketIterator() BucketIterator[uint64] {
it := newRegularBucketIterator(h.PositiveSpans, h.PositiveBuckets, h.Schema, true)
return &it
}
// NegativeBucketIterator returns a BucketIterator to iterate over all negative
// buckets in descending order (starting next to the zero bucket and going down).
func (h *Histogram) NegativeBucketIterator() BucketIterator[uint64] {
it := newRegularBucketIterator(h.NegativeSpans, h.NegativeBuckets, h.Schema, false)
return &it
}
// CumulativeBucketIterator returns a BucketIterator to iterate over a
// cumulative view of the buckets. This method currently only supports
// Histograms without negative buckets and panics if the Histogram has negative
// buckets. It is currently only used for testing.
func (h *Histogram) CumulativeBucketIterator() BucketIterator[uint64] {
if len(h.NegativeBuckets) > 0 {
panic("CumulativeBucketIterator called on Histogram with negative buckets")
}
return &cumulativeBucketIterator{h: h, posSpansIdx: -1}
}
// Equals returns true if the given histogram matches exactly.
// Exact match is when there are no new buckets (even empty) and no missing buckets,
// and all the bucket values match. Spans can have different empty length spans in between,
// but they must represent the same bucket layout to match.
// Sum is compared based on its bit pattern because this method
// is about data equality rather than mathematical equality.
func (h *Histogram) Equals(h2 *Histogram) bool {
if h2 == nil {
return false
}
if h.Schema != h2.Schema || h.ZeroThreshold != h2.ZeroThreshold ||
h.ZeroCount != h2.ZeroCount || h.Count != h2.Count ||
math.Float64bits(h.Sum) != math.Float64bits(h2.Sum) {
return false
}
if !spansMatch(h.PositiveSpans, h2.PositiveSpans) {
return false
}
if !spansMatch(h.NegativeSpans, h2.NegativeSpans) {
return false
}
if !slices.Equal(h.PositiveBuckets, h2.PositiveBuckets) {
return false
}
if !slices.Equal(h.NegativeBuckets, h2.NegativeBuckets) {
return false
}
return true
}
// spansMatch returns true if both spans represent the same bucket layout
// after combining zero length spans with the next non-zero length span.
func spansMatch(s1, s2 []Span) bool {
if len(s1) == 0 && len(s2) == 0 {
return true
}
s1idx, s2idx := 0, 0
for {
if s1idx >= len(s1) {
return allEmptySpans(s2[s2idx:])
}
if s2idx >= len(s2) {
return allEmptySpans(s1[s1idx:])
}
currS1, currS2 := s1[s1idx], s2[s2idx]
s1idx++
s2idx++
if currS1.Length == 0 {
// This span is zero length, so we add consecutive such spans
// until we find a non-zero span.
for ; s1idx < len(s1) && s1[s1idx].Length == 0; s1idx++ {
currS1.Offset += s1[s1idx].Offset
}
if s1idx < len(s1) {
currS1.Offset += s1[s1idx].Offset
currS1.Length = s1[s1idx].Length
s1idx++
}
}
if currS2.Length == 0 {
// This span is zero length, so we add consecutive such spans
// until we find a non-zero span.
for ; s2idx < len(s2) && s2[s2idx].Length == 0; s2idx++ {
currS2.Offset += s2[s2idx].Offset
}
if s2idx < len(s2) {
currS2.Offset += s2[s2idx].Offset
currS2.Length = s2[s2idx].Length
s2idx++
}
}
if currS1.Length == 0 && currS2.Length == 0 {
// The last spans of both set are zero length. Previous spans match.
return true
}
if currS1.Offset != currS2.Offset || currS1.Length != currS2.Length {
return false
}
}
}
func allEmptySpans(s []Span) bool {
for _, ss := range s {
if ss.Length > 0 {
return false
}
}
return true
}
// Compact works like FloatHistogram.Compact. See there for detailed
// explanations.
func (h *Histogram) Compact(maxEmptyBuckets int) *Histogram {
h.PositiveBuckets, h.PositiveSpans = compactBuckets(
h.PositiveBuckets, h.PositiveSpans, maxEmptyBuckets, true,
)
h.NegativeBuckets, h.NegativeSpans = compactBuckets(
h.NegativeBuckets, h.NegativeSpans, maxEmptyBuckets, true,
)
return h
}
// ToFloat returns a FloatHistogram representation of the Histogram. It is a deep
// copy (e.g. spans are not shared). The function accepts a FloatHistogram as an
// argument whose memory will be reused and overwritten if provided. If this
// argument is nil, a new FloatHistogram will be allocated.
func (h *Histogram) ToFloat(fh *FloatHistogram) *FloatHistogram {
if fh == nil {
fh = &FloatHistogram{}
}
fh.CounterResetHint = h.CounterResetHint
fh.Schema = h.Schema
fh.ZeroThreshold = h.ZeroThreshold
fh.ZeroCount = float64(h.ZeroCount)
fh.Count = float64(h.Count)
fh.Sum = h.Sum
fh.PositiveSpans = resize(fh.PositiveSpans, len(h.PositiveSpans))
copy(fh.PositiveSpans, h.PositiveSpans)
fh.NegativeSpans = resize(fh.NegativeSpans, len(h.NegativeSpans))
copy(fh.NegativeSpans, h.NegativeSpans)
fh.PositiveBuckets = resize(fh.PositiveBuckets, len(h.PositiveBuckets))
var currentPositive float64
for i, b := range h.PositiveBuckets {
currentPositive += float64(b)
fh.PositiveBuckets[i] = currentPositive
}
fh.NegativeBuckets = resize(fh.NegativeBuckets, len(h.NegativeBuckets))
var currentNegative float64
for i, b := range h.NegativeBuckets {
currentNegative += float64(b)
fh.NegativeBuckets[i] = currentNegative
}
return fh
}
func resize[T any](items []T, n int) []T {
if cap(items) < n {
return make([]T, n)
}
return items[:n]
}
// Validate validates consistency between span and bucket slices. Also, buckets are checked
// against negative values.
// For histograms that have not observed any NaN values (based on IsNaN(h.Sum) check), a
// strict h.Count = nCount + pCount + h.ZeroCount check is performed.
// Otherwise, only a lower bound check will be done (h.Count >= nCount + pCount + h.ZeroCount),
// because NaN observations do not increment the values of buckets (but they do increment
// the total h.Count).
func (h *Histogram) Validate() error {
if err := checkHistogramSpans(h.NegativeSpans, len(h.NegativeBuckets)); err != nil {
return fmt.Errorf("negative side: %w", err)
}
if err := checkHistogramSpans(h.PositiveSpans, len(h.PositiveBuckets)); err != nil {
return fmt.Errorf("positive side: %w", err)
}
var nCount, pCount uint64
err := checkHistogramBuckets(h.NegativeBuckets, &nCount, true)
if err != nil {
return fmt.Errorf("negative side: %w", err)
}
err = checkHistogramBuckets(h.PositiveBuckets, &pCount, true)
if err != nil {
return fmt.Errorf("positive side: %w", err)
}
sumOfBuckets := nCount + pCount + h.ZeroCount
if math.IsNaN(h.Sum) {
if sumOfBuckets > h.Count {
return fmt.Errorf("%d observations found in buckets, but the Count field is %d: %w", sumOfBuckets, h.Count, ErrHistogramCountNotBigEnough)
}
} else {
if sumOfBuckets != h.Count {
return fmt.Errorf("%d observations found in buckets, but the Count field is %d: %w", sumOfBuckets, h.Count, ErrHistogramCountMismatch)
}
}
return nil
}
type regularBucketIterator struct {
baseBucketIterator[uint64, int64]
}
func newRegularBucketIterator(spans []Span, buckets []int64, schema int32, positive bool) regularBucketIterator {
i := baseBucketIterator[uint64, int64]{
schema: schema,
spans: spans,
buckets: buckets,
positive: positive,
}
return regularBucketIterator{i}
}
func (r *regularBucketIterator) Next() bool {
if r.spansIdx >= len(r.spans) {
return false
}
span := r.spans[r.spansIdx]
// Seed currIdx for the first bucket.
if r.bucketsIdx == 0 {
r.currIdx = span.Offset
} else {
r.currIdx++
}
for r.idxInSpan >= span.Length {
// We have exhausted the current span and have to find a new
// one. We'll even handle pathologic spans of length 0.
r.idxInSpan = 0
r.spansIdx++
if r.spansIdx >= len(r.spans) {
return false
}
span = r.spans[r.spansIdx]
r.currIdx += span.Offset
}
r.currCount += r.buckets[r.bucketsIdx]
r.idxInSpan++
r.bucketsIdx++
return true
}
type cumulativeBucketIterator struct {
h *Histogram
posSpansIdx int // Index in h.PositiveSpans we are in. -1 means 0 bucket.
posBucketsIdx int // Index in h.PositiveBuckets.
idxInSpan uint32 // Index in the current span. 0 <= idxInSpan < span.Length.
initialized bool
currIdx int32 // The actual bucket index after decoding from spans.
currUpper float64 // The upper boundary of the current bucket.
currCount int64 // Current non-cumulative count for the current bucket. Does not apply for empty bucket.
currCumulativeCount uint64 // Current "cumulative" count for the current bucket.
// Between 2 spans there could be some empty buckets which
// still needs to be counted for cumulative buckets.
// When we hit the end of a span, we use this to iterate
// through the empty buckets.
emptyBucketCount int32
}
func (c *cumulativeBucketIterator) Next() bool {
if c.posSpansIdx == -1 {
// Zero bucket.
c.posSpansIdx++
if c.h.ZeroCount == 0 {
return c.Next()
}
c.currUpper = c.h.ZeroThreshold
c.currCount = int64(c.h.ZeroCount)
c.currCumulativeCount = uint64(c.currCount)
return true
}
if c.posSpansIdx >= len(c.h.PositiveSpans) {
return false
}
if c.emptyBucketCount > 0 {
// We are traversing through empty buckets at the moment.
c.currUpper = getBound(c.currIdx, c.h.Schema)
c.currIdx++
c.emptyBucketCount--
return true
}
span := c.h.PositiveSpans[c.posSpansIdx]
if c.posSpansIdx == 0 && !c.initialized {
// Initializing.
c.currIdx = span.Offset
// The first bucket is an absolute value and not a delta with Zero bucket.
c.currCount = 0
c.initialized = true
}
c.currCount += c.h.PositiveBuckets[c.posBucketsIdx]
c.currCumulativeCount += uint64(c.currCount)
c.currUpper = getBound(c.currIdx, c.h.Schema)
c.posBucketsIdx++
c.idxInSpan++
c.currIdx++
if c.idxInSpan >= span.Length {
// Move to the next span. This one is done.
c.posSpansIdx++
c.idxInSpan = 0
if c.posSpansIdx < len(c.h.PositiveSpans) {
c.emptyBucketCount = c.h.PositiveSpans[c.posSpansIdx].Offset
}
}
return true
}
func (c *cumulativeBucketIterator) At() Bucket[uint64] {
return Bucket[uint64]{
Upper: c.currUpper,
Lower: math.Inf(-1),
UpperInclusive: true,
LowerInclusive: true,
Count: c.currCumulativeCount,
Index: c.currIdx - 1,
}
}
// ReduceResolution reduces the histogram's spans, buckets into target schema.
// The target schema must be smaller than the current histogram's schema.
func (h *Histogram) ReduceResolution(targetSchema int32) *Histogram {
if targetSchema >= h.Schema {
panic(fmt.Errorf("cannot reduce resolution from schema %d to %d", h.Schema, targetSchema))
}
h.PositiveSpans, h.PositiveBuckets = reduceResolution(
h.PositiveSpans, h.PositiveBuckets, h.Schema, targetSchema, true, true,
)
h.NegativeSpans, h.NegativeBuckets = reduceResolution(
h.NegativeSpans, h.NegativeBuckets, h.Schema, targetSchema, true, true,
)
h.Schema = targetSchema
return h
}