7c9314f231
* swarm: propagate ctx, enable opentracing * swarm/tracing: log error when tracing is misconfigured
565 lines
14 KiB
Go
565 lines
14 KiB
Go
// Package hdrhistogram provides an implementation of Gil Tene's HDR Histogram
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// data structure. The HDR Histogram allows for fast and accurate analysis of
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// the extreme ranges of data with non-normal distributions, like latency.
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package hdrhistogram
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import (
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"fmt"
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"math"
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)
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// A Bracket is a part of a cumulative distribution.
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type Bracket struct {
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Quantile float64
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Count, ValueAt int64
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}
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// A Snapshot is an exported view of a Histogram, useful for serializing them.
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// A Histogram can be constructed from it by passing it to Import.
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type Snapshot struct {
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LowestTrackableValue int64
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HighestTrackableValue int64
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SignificantFigures int64
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Counts []int64
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}
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// A Histogram is a lossy data structure used to record the distribution of
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// non-normally distributed data (like latency) with a high degree of accuracy
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// and a bounded degree of precision.
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type Histogram struct {
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lowestTrackableValue int64
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highestTrackableValue int64
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unitMagnitude int64
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significantFigures int64
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subBucketHalfCountMagnitude int32
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subBucketHalfCount int32
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subBucketMask int64
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subBucketCount int32
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bucketCount int32
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countsLen int32
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totalCount int64
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counts []int64
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}
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// New returns a new Histogram instance capable of tracking values in the given
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// range and with the given amount of precision.
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func New(minValue, maxValue int64, sigfigs int) *Histogram {
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if sigfigs < 1 || 5 < sigfigs {
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panic(fmt.Errorf("sigfigs must be [1,5] (was %d)", sigfigs))
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}
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largestValueWithSingleUnitResolution := 2 * math.Pow10(sigfigs)
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subBucketCountMagnitude := int32(math.Ceil(math.Log2(float64(largestValueWithSingleUnitResolution))))
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subBucketHalfCountMagnitude := subBucketCountMagnitude
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if subBucketHalfCountMagnitude < 1 {
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subBucketHalfCountMagnitude = 1
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}
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subBucketHalfCountMagnitude--
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unitMagnitude := int32(math.Floor(math.Log2(float64(minValue))))
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if unitMagnitude < 0 {
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unitMagnitude = 0
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}
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subBucketCount := int32(math.Pow(2, float64(subBucketHalfCountMagnitude)+1))
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subBucketHalfCount := subBucketCount / 2
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subBucketMask := int64(subBucketCount-1) << uint(unitMagnitude)
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// determine exponent range needed to support the trackable value with no
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// overflow:
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smallestUntrackableValue := int64(subBucketCount) << uint(unitMagnitude)
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bucketsNeeded := int32(1)
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for smallestUntrackableValue < maxValue {
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smallestUntrackableValue <<= 1
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bucketsNeeded++
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}
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bucketCount := bucketsNeeded
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countsLen := (bucketCount + 1) * (subBucketCount / 2)
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return &Histogram{
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lowestTrackableValue: minValue,
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highestTrackableValue: maxValue,
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unitMagnitude: int64(unitMagnitude),
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significantFigures: int64(sigfigs),
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subBucketHalfCountMagnitude: subBucketHalfCountMagnitude,
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subBucketHalfCount: subBucketHalfCount,
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subBucketMask: subBucketMask,
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subBucketCount: subBucketCount,
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bucketCount: bucketCount,
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countsLen: countsLen,
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totalCount: 0,
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counts: make([]int64, countsLen),
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}
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}
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// ByteSize returns an estimate of the amount of memory allocated to the
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// histogram in bytes.
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//
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// N.B.: This does not take into account the overhead for slices, which are
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// small, constant, and specific to the compiler version.
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func (h *Histogram) ByteSize() int {
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return 6*8 + 5*4 + len(h.counts)*8
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}
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// Merge merges the data stored in the given histogram with the receiver,
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// returning the number of recorded values which had to be dropped.
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func (h *Histogram) Merge(from *Histogram) (dropped int64) {
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i := from.rIterator()
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for i.next() {
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v := i.valueFromIdx
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c := i.countAtIdx
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if h.RecordValues(v, c) != nil {
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dropped += c
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}
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}
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return
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}
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// TotalCount returns total number of values recorded.
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func (h *Histogram) TotalCount() int64 {
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return h.totalCount
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}
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// Max returns the approximate maximum recorded value.
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func (h *Histogram) Max() int64 {
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var max int64
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i := h.iterator()
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for i.next() {
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if i.countAtIdx != 0 {
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max = i.highestEquivalentValue
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}
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}
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return h.highestEquivalentValue(max)
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}
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// Min returns the approximate minimum recorded value.
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func (h *Histogram) Min() int64 {
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var min int64
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i := h.iterator()
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for i.next() {
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if i.countAtIdx != 0 && min == 0 {
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min = i.highestEquivalentValue
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break
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}
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}
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return h.lowestEquivalentValue(min)
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}
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// Mean returns the approximate arithmetic mean of the recorded values.
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func (h *Histogram) Mean() float64 {
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if h.totalCount == 0 {
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return 0
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}
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var total int64
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i := h.iterator()
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for i.next() {
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if i.countAtIdx != 0 {
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total += i.countAtIdx * h.medianEquivalentValue(i.valueFromIdx)
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}
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}
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return float64(total) / float64(h.totalCount)
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}
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// StdDev returns the approximate standard deviation of the recorded values.
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func (h *Histogram) StdDev() float64 {
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if h.totalCount == 0 {
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return 0
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}
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mean := h.Mean()
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geometricDevTotal := 0.0
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i := h.iterator()
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for i.next() {
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if i.countAtIdx != 0 {
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dev := float64(h.medianEquivalentValue(i.valueFromIdx)) - mean
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geometricDevTotal += (dev * dev) * float64(i.countAtIdx)
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}
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}
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return math.Sqrt(geometricDevTotal / float64(h.totalCount))
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}
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// Reset deletes all recorded values and restores the histogram to its original
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// state.
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func (h *Histogram) Reset() {
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h.totalCount = 0
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for i := range h.counts {
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h.counts[i] = 0
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}
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}
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// RecordValue records the given value, returning an error if the value is out
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// of range.
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func (h *Histogram) RecordValue(v int64) error {
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return h.RecordValues(v, 1)
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}
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// RecordCorrectedValue records the given value, correcting for stalls in the
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// recording process. This only works for processes which are recording values
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// at an expected interval (e.g., doing jitter analysis). Processes which are
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// recording ad-hoc values (e.g., latency for incoming requests) can't take
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// advantage of this.
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func (h *Histogram) RecordCorrectedValue(v, expectedInterval int64) error {
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if err := h.RecordValue(v); err != nil {
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return err
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}
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if expectedInterval <= 0 || v <= expectedInterval {
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return nil
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}
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missingValue := v - expectedInterval
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for missingValue >= expectedInterval {
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if err := h.RecordValue(missingValue); err != nil {
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return err
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}
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missingValue -= expectedInterval
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}
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return nil
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}
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// RecordValues records n occurrences of the given value, returning an error if
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// the value is out of range.
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func (h *Histogram) RecordValues(v, n int64) error {
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idx := h.countsIndexFor(v)
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if idx < 0 || int(h.countsLen) <= idx {
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return fmt.Errorf("value %d is too large to be recorded", v)
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}
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h.counts[idx] += n
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h.totalCount += n
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return nil
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}
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// ValueAtQuantile returns the recorded value at the given quantile (0..100).
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func (h *Histogram) ValueAtQuantile(q float64) int64 {
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if q > 100 {
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q = 100
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}
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total := int64(0)
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countAtPercentile := int64(((q / 100) * float64(h.totalCount)) + 0.5)
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i := h.iterator()
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for i.next() {
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total += i.countAtIdx
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if total >= countAtPercentile {
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return h.highestEquivalentValue(i.valueFromIdx)
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}
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}
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return 0
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}
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// CumulativeDistribution returns an ordered list of brackets of the
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// distribution of recorded values.
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func (h *Histogram) CumulativeDistribution() []Bracket {
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var result []Bracket
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i := h.pIterator(1)
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for i.next() {
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result = append(result, Bracket{
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Quantile: i.percentile,
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Count: i.countToIdx,
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ValueAt: i.highestEquivalentValue,
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})
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}
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return result
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}
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// SignificantFigures returns the significant figures used to create the
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// histogram
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func (h *Histogram) SignificantFigures() int64 {
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return h.significantFigures
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}
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// LowestTrackableValue returns the lower bound on values that will be added
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// to the histogram
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func (h *Histogram) LowestTrackableValue() int64 {
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return h.lowestTrackableValue
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}
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// HighestTrackableValue returns the upper bound on values that will be added
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// to the histogram
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func (h *Histogram) HighestTrackableValue() int64 {
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return h.highestTrackableValue
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}
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// Histogram bar for plotting
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type Bar struct {
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From, To, Count int64
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}
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// Pretty print as csv for easy plotting
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func (b Bar) String() string {
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return fmt.Sprintf("%v, %v, %v\n", b.From, b.To, b.Count)
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}
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// Distribution returns an ordered list of bars of the
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// distribution of recorded values, counts can be normalized to a probability
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func (h *Histogram) Distribution() (result []Bar) {
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i := h.iterator()
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for i.next() {
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result = append(result, Bar{
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Count: i.countAtIdx,
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From: h.lowestEquivalentValue(i.valueFromIdx),
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To: i.highestEquivalentValue,
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})
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}
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return result
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}
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// Equals returns true if the two Histograms are equivalent, false if not.
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func (h *Histogram) Equals(other *Histogram) bool {
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switch {
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case
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h.lowestTrackableValue != other.lowestTrackableValue,
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h.highestTrackableValue != other.highestTrackableValue,
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h.unitMagnitude != other.unitMagnitude,
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h.significantFigures != other.significantFigures,
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h.subBucketHalfCountMagnitude != other.subBucketHalfCountMagnitude,
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h.subBucketHalfCount != other.subBucketHalfCount,
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h.subBucketMask != other.subBucketMask,
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h.subBucketCount != other.subBucketCount,
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h.bucketCount != other.bucketCount,
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h.countsLen != other.countsLen,
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h.totalCount != other.totalCount:
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return false
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default:
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for i, c := range h.counts {
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if c != other.counts[i] {
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return false
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}
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}
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}
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return true
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}
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// Export returns a snapshot view of the Histogram. This can be later passed to
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// Import to construct a new Histogram with the same state.
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func (h *Histogram) Export() *Snapshot {
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return &Snapshot{
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LowestTrackableValue: h.lowestTrackableValue,
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HighestTrackableValue: h.highestTrackableValue,
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SignificantFigures: h.significantFigures,
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Counts: append([]int64(nil), h.counts...), // copy
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}
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}
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// Import returns a new Histogram populated from the Snapshot data (which the
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// caller must stop accessing).
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func Import(s *Snapshot) *Histogram {
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h := New(s.LowestTrackableValue, s.HighestTrackableValue, int(s.SignificantFigures))
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h.counts = s.Counts
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totalCount := int64(0)
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for i := int32(0); i < h.countsLen; i++ {
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countAtIndex := h.counts[i]
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if countAtIndex > 0 {
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totalCount += countAtIndex
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}
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}
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h.totalCount = totalCount
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return h
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}
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func (h *Histogram) iterator() *iterator {
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return &iterator{
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h: h,
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subBucketIdx: -1,
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}
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}
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func (h *Histogram) rIterator() *rIterator {
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return &rIterator{
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iterator: iterator{
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h: h,
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subBucketIdx: -1,
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},
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}
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}
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func (h *Histogram) pIterator(ticksPerHalfDistance int32) *pIterator {
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return &pIterator{
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iterator: iterator{
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h: h,
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subBucketIdx: -1,
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},
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ticksPerHalfDistance: ticksPerHalfDistance,
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}
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}
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func (h *Histogram) sizeOfEquivalentValueRange(v int64) int64 {
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bucketIdx := h.getBucketIndex(v)
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subBucketIdx := h.getSubBucketIdx(v, bucketIdx)
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adjustedBucket := bucketIdx
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if subBucketIdx >= h.subBucketCount {
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adjustedBucket++
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}
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return int64(1) << uint(h.unitMagnitude+int64(adjustedBucket))
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}
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func (h *Histogram) valueFromIndex(bucketIdx, subBucketIdx int32) int64 {
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return int64(subBucketIdx) << uint(int64(bucketIdx)+h.unitMagnitude)
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}
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func (h *Histogram) lowestEquivalentValue(v int64) int64 {
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bucketIdx := h.getBucketIndex(v)
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subBucketIdx := h.getSubBucketIdx(v, bucketIdx)
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return h.valueFromIndex(bucketIdx, subBucketIdx)
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}
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func (h *Histogram) nextNonEquivalentValue(v int64) int64 {
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return h.lowestEquivalentValue(v) + h.sizeOfEquivalentValueRange(v)
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}
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func (h *Histogram) highestEquivalentValue(v int64) int64 {
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return h.nextNonEquivalentValue(v) - 1
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}
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func (h *Histogram) medianEquivalentValue(v int64) int64 {
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return h.lowestEquivalentValue(v) + (h.sizeOfEquivalentValueRange(v) >> 1)
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}
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func (h *Histogram) getCountAtIndex(bucketIdx, subBucketIdx int32) int64 {
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return h.counts[h.countsIndex(bucketIdx, subBucketIdx)]
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}
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func (h *Histogram) countsIndex(bucketIdx, subBucketIdx int32) int32 {
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bucketBaseIdx := (bucketIdx + 1) << uint(h.subBucketHalfCountMagnitude)
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offsetInBucket := subBucketIdx - h.subBucketHalfCount
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return bucketBaseIdx + offsetInBucket
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}
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func (h *Histogram) getBucketIndex(v int64) int32 {
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pow2Ceiling := bitLen(v | h.subBucketMask)
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return int32(pow2Ceiling - int64(h.unitMagnitude) -
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int64(h.subBucketHalfCountMagnitude+1))
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}
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func (h *Histogram) getSubBucketIdx(v int64, idx int32) int32 {
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return int32(v >> uint(int64(idx)+int64(h.unitMagnitude)))
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}
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func (h *Histogram) countsIndexFor(v int64) int {
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bucketIdx := h.getBucketIndex(v)
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subBucketIdx := h.getSubBucketIdx(v, bucketIdx)
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return int(h.countsIndex(bucketIdx, subBucketIdx))
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}
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type iterator struct {
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h *Histogram
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bucketIdx, subBucketIdx int32
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countAtIdx, countToIdx, valueFromIdx int64
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highestEquivalentValue int64
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}
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func (i *iterator) next() bool {
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if i.countToIdx >= i.h.totalCount {
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return false
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}
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// increment bucket
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i.subBucketIdx++
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if i.subBucketIdx >= i.h.subBucketCount {
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i.subBucketIdx = i.h.subBucketHalfCount
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i.bucketIdx++
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}
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if i.bucketIdx >= i.h.bucketCount {
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return false
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}
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i.countAtIdx = i.h.getCountAtIndex(i.bucketIdx, i.subBucketIdx)
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i.countToIdx += i.countAtIdx
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i.valueFromIdx = i.h.valueFromIndex(i.bucketIdx, i.subBucketIdx)
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i.highestEquivalentValue = i.h.highestEquivalentValue(i.valueFromIdx)
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return true
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}
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type rIterator struct {
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iterator
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countAddedThisStep int64
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}
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func (r *rIterator) next() bool {
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for r.iterator.next() {
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if r.countAtIdx != 0 {
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r.countAddedThisStep = r.countAtIdx
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return true
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}
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}
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return false
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}
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type pIterator struct {
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iterator
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seenLastValue bool
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ticksPerHalfDistance int32
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percentileToIteratorTo float64
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percentile float64
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}
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func (p *pIterator) next() bool {
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if !(p.countToIdx < p.h.totalCount) {
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if p.seenLastValue {
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return false
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}
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p.seenLastValue = true
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p.percentile = 100
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return true
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}
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if p.subBucketIdx == -1 && !p.iterator.next() {
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return false
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}
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var done = false
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for !done {
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currentPercentile := (100.0 * float64(p.countToIdx)) / float64(p.h.totalCount)
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if p.countAtIdx != 0 && p.percentileToIteratorTo <= currentPercentile {
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p.percentile = p.percentileToIteratorTo
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halfDistance := math.Trunc(math.Pow(2, math.Trunc(math.Log2(100.0/(100.0-p.percentileToIteratorTo)))+1))
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percentileReportingTicks := float64(p.ticksPerHalfDistance) * halfDistance
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p.percentileToIteratorTo += 100.0 / percentileReportingTicks
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return true
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}
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done = !p.iterator.next()
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}
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return true
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}
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func bitLen(x int64) (n int64) {
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for ; x >= 0x8000; x >>= 16 {
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n += 16
|
|
}
|
|
if x >= 0x80 {
|
|
x >>= 8
|
|
n += 8
|
|
}
|
|
if x >= 0x8 {
|
|
x >>= 4
|
|
n += 4
|
|
}
|
|
if x >= 0x2 {
|
|
x >>= 2
|
|
n += 2
|
|
}
|
|
if x >= 0x1 {
|
|
n++
|
|
}
|
|
return
|
|
}
|