mirror of
https://github.com/ceph/ceph-csi.git
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292 lines
8.2 KiB
Go
292 lines
8.2 KiB
Go
/*
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*
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* Copyright 2017 gRPC authors.
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*
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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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*
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*/
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package stats
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import (
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"bytes"
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"fmt"
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"io"
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"math"
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"sort"
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"strconv"
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"time"
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)
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// Features contains most fields for a benchmark
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type Features struct {
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NetworkMode string
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EnableTrace bool
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Latency time.Duration
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Kbps int
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Mtu int
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MaxConcurrentCalls int
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ReqSizeBytes int
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RespSizeBytes int
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EnableCompressor bool
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}
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// String returns the textual output of the Features as string.
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func (f Features) String() string {
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return fmt.Sprintf("traceMode_%t-latency_%s-kbps_%#v-MTU_%#v-maxConcurrentCalls_"+
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"%#v-reqSize_%#vB-respSize_%#vB-Compressor_%t", f.EnableTrace,
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f.Latency.String(), f.Kbps, f.Mtu, f.MaxConcurrentCalls, f.ReqSizeBytes, f.RespSizeBytes, f.EnableCompressor)
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}
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// PartialPrintString can print certain features with different format.
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func PartialPrintString(noneEmptyPos []bool, f Features, shared bool) string {
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s := ""
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var (
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prefix, suffix, linker string
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isNetwork bool
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)
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if shared {
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suffix = "\n"
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linker = ": "
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} else {
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prefix = "-"
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linker = "_"
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}
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if noneEmptyPos[0] {
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s += fmt.Sprintf("%sTrace%s%t%s", prefix, linker, f.EnableCompressor, suffix)
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}
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if shared && f.NetworkMode != "" {
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s += fmt.Sprintf("Network: %s \n", f.NetworkMode)
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isNetwork = true
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}
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if !isNetwork {
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if noneEmptyPos[1] {
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s += fmt.Sprintf("%slatency%s%s%s", prefix, linker, f.Latency.String(), suffix)
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}
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if noneEmptyPos[2] {
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s += fmt.Sprintf("%skbps%s%#v%s", prefix, linker, f.Kbps, suffix)
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}
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if noneEmptyPos[3] {
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s += fmt.Sprintf("%sMTU%s%#v%s", prefix, linker, f.Mtu, suffix)
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}
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}
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if noneEmptyPos[4] {
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s += fmt.Sprintf("%sCallers%s%#v%s", prefix, linker, f.MaxConcurrentCalls, suffix)
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}
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if noneEmptyPos[5] {
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s += fmt.Sprintf("%sreqSize%s%#vB%s", prefix, linker, f.ReqSizeBytes, suffix)
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}
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if noneEmptyPos[6] {
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s += fmt.Sprintf("%srespSize%s%#vB%s", prefix, linker, f.RespSizeBytes, suffix)
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}
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if noneEmptyPos[7] {
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s += fmt.Sprintf("%sCompressor%s%t%s", prefix, linker, f.EnableCompressor, suffix)
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}
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return s
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}
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type percentLatency struct {
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Percent int
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Value time.Duration
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}
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// BenchResults records features and result of a benchmark.
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type BenchResults struct {
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RunMode string
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Features Features
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Latency []percentLatency
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Operations int
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NsPerOp int64
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AllocedBytesPerOp int64
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AllocsPerOp int64
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SharedPosion []bool
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}
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// SetBenchmarkResult sets features of benchmark and basic results.
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func (stats *Stats) SetBenchmarkResult(mode string, features Features, o int, allocdBytes, allocs int64, sharedPos []bool) {
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stats.result.RunMode = mode
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stats.result.Features = features
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stats.result.Operations = o
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stats.result.AllocedBytesPerOp = allocdBytes
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stats.result.AllocsPerOp = allocs
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stats.result.SharedPosion = sharedPos
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}
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// GetBenchmarkResults returns the result of the benchmark including features and result.
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func (stats *Stats) GetBenchmarkResults() BenchResults {
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return stats.result
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}
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// BenchString output latency stats as the format as time + unit.
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func (stats *Stats) BenchString() string {
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stats.maybeUpdate()
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s := stats.result
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res := s.RunMode + "-" + s.Features.String() + ": \n"
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if len(s.Latency) != 0 {
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var statsUnit = s.Latency[0].Value
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var timeUnit = fmt.Sprintf("%v", statsUnit)[1:]
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for i := 1; i < len(s.Latency)-1; i++ {
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res += fmt.Sprintf("%d_Latency: %s %s \t", s.Latency[i].Percent,
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strconv.FormatFloat(float64(s.Latency[i].Value)/float64(statsUnit), 'f', 4, 64), timeUnit)
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}
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res += fmt.Sprintf("Avg latency: %s %s \t",
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strconv.FormatFloat(float64(s.Latency[len(s.Latency)-1].Value)/float64(statsUnit), 'f', 4, 64), timeUnit)
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}
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res += fmt.Sprintf("Count: %v \t", s.Operations)
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res += fmt.Sprintf("%v Bytes/op\t", s.AllocedBytesPerOp)
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res += fmt.Sprintf("%v Allocs/op\t", s.AllocsPerOp)
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return res
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}
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// Stats is a simple helper for gathering additional statistics like histogram
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// during benchmarks. This is not thread safe.
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type Stats struct {
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numBuckets int
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unit time.Duration
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min, max int64
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histogram *Histogram
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durations durationSlice
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dirty bool
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sortLatency bool
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result BenchResults
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}
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type durationSlice []time.Duration
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// NewStats creates a new Stats instance. If numBuckets is not positive,
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// the default value (16) will be used.
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func NewStats(numBuckets int) *Stats {
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if numBuckets <= 0 {
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numBuckets = 16
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}
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return &Stats{
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// Use one more bucket for the last unbounded bucket.
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numBuckets: numBuckets + 1,
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durations: make(durationSlice, 0, 100000),
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}
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}
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// Add adds an elapsed time per operation to the stats.
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func (stats *Stats) Add(d time.Duration) {
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stats.durations = append(stats.durations, d)
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stats.dirty = true
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}
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// Clear resets the stats, removing all values.
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func (stats *Stats) Clear() {
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stats.durations = stats.durations[:0]
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stats.histogram = nil
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stats.dirty = false
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stats.result = BenchResults{}
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}
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//Sort method for durations
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func (a durationSlice) Len() int { return len(a) }
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func (a durationSlice) Swap(i, j int) { a[i], a[j] = a[j], a[i] }
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func (a durationSlice) Less(i, j int) bool { return a[i] < a[j] }
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func max(a, b int64) int64 {
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if a > b {
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return a
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}
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return b
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}
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// maybeUpdate updates internal stat data if there was any newly added
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// stats since this was updated.
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func (stats *Stats) maybeUpdate() {
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if !stats.dirty {
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return
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}
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if stats.sortLatency {
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sort.Sort(stats.durations)
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stats.min = int64(stats.durations[0])
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stats.max = int64(stats.durations[len(stats.durations)-1])
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}
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stats.min = math.MaxInt64
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stats.max = 0
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for _, d := range stats.durations {
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if stats.min > int64(d) {
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stats.min = int64(d)
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}
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if stats.max < int64(d) {
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stats.max = int64(d)
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}
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}
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// Use the largest unit that can represent the minimum time duration.
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stats.unit = time.Nanosecond
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for _, u := range []time.Duration{time.Microsecond, time.Millisecond, time.Second} {
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if stats.min <= int64(u) {
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break
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}
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stats.unit = u
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}
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numBuckets := stats.numBuckets
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if n := int(stats.max - stats.min + 1); n < numBuckets {
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numBuckets = n
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}
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stats.histogram = NewHistogram(HistogramOptions{
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NumBuckets: numBuckets,
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// max-min(lower bound of last bucket) = (1 + growthFactor)^(numBuckets-2) * baseBucketSize.
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GrowthFactor: math.Pow(float64(stats.max-stats.min), 1/float64(numBuckets-2)) - 1,
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BaseBucketSize: 1.0,
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MinValue: stats.min})
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for _, d := range stats.durations {
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stats.histogram.Add(int64(d))
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}
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stats.dirty = false
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if stats.durations.Len() != 0 {
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var percentToObserve = []int{50, 90, 99}
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// First data record min unit from the latency result.
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stats.result.Latency = append(stats.result.Latency, percentLatency{Percent: -1, Value: stats.unit})
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for _, position := range percentToObserve {
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stats.result.Latency = append(stats.result.Latency, percentLatency{Percent: position, Value: stats.durations[max(stats.histogram.Count*int64(position)/100-1, 0)]})
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}
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// Last data record the average latency.
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avg := float64(stats.histogram.Sum) / float64(stats.histogram.Count)
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stats.result.Latency = append(stats.result.Latency, percentLatency{Percent: -1, Value: time.Duration(avg)})
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}
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}
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// SortLatency blocks the output
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func (stats *Stats) SortLatency() {
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stats.sortLatency = true
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}
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// Print writes textual output of the Stats.
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func (stats *Stats) Print(w io.Writer) {
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stats.maybeUpdate()
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if stats.histogram == nil {
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fmt.Fprint(w, "Histogram (empty)\n")
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} else {
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fmt.Fprintf(w, "Histogram (unit: %s)\n", fmt.Sprintf("%v", stats.unit)[1:])
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stats.histogram.PrintWithUnit(w, float64(stats.unit))
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}
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}
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// String returns the textual output of the Stats as string.
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func (stats *Stats) String() string {
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var b bytes.Buffer
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stats.Print(&b)
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return b.String()
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}
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