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- // Copyright 2014 The etcd 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.
- // the file is borrowed from github.com/rakyll/boom/boomer/print.go
- package report
- import (
- "fmt"
- "math"
- "sort"
- "strings"
- "time"
- )
- const (
- barChar = "∎"
- )
- // Result describes the timings for an operation.
- type Result struct {
- Start time.Time
- End time.Time
- Err error
- Weight float64
- }
- func (res *Result) Duration() time.Duration { return res.End.Sub(res.Start) }
- type report struct {
- results chan Result
- precision string
- stats Stats
- sps *secondPoints
- }
- // Stats exposes results raw data.
- type Stats struct {
- AvgTotal float64
- Fastest float64
- Slowest float64
- Average float64
- Stddev float64
- RPS float64
- Total time.Duration
- ErrorDist map[string]int
- Lats []float64
- TimeSeries TimeSeries
- }
- func (s *Stats) copy() Stats {
- ss := *s
- ss.ErrorDist = copyMap(ss.ErrorDist)
- ss.Lats = copyFloats(ss.Lats)
- return ss
- }
- // Report processes a result stream until it is closed, then produces a
- // string with information about the consumed result data.
- type Report interface {
- Results() chan<- Result
- // Run returns results in print-friendly format.
- Run() <-chan string
- // Stats returns results in raw data.
- Stats() <-chan Stats
- }
- func NewReport(precision string) Report { return newReport(precision) }
- func newReport(precision string) *report {
- r := &report{
- results: make(chan Result, 16),
- precision: precision,
- }
- r.stats.ErrorDist = make(map[string]int)
- return r
- }
- func NewReportSample(precision string) Report {
- r := NewReport(precision).(*report)
- r.sps = newSecondPoints()
- return r
- }
- func (r *report) Results() chan<- Result { return r.results }
- func (r *report) Run() <-chan string {
- donec := make(chan string, 1)
- go func() {
- defer close(donec)
- r.processResults()
- donec <- r.String()
- }()
- return donec
- }
- func (r *report) Stats() <-chan Stats {
- donec := make(chan Stats, 1)
- go func() {
- defer close(donec)
- r.processResults()
- s := r.stats.copy()
- if r.sps != nil {
- s.TimeSeries = r.sps.getTimeSeries()
- }
- donec <- s
- }()
- return donec
- }
- func copyMap(m map[string]int) (c map[string]int) {
- c = make(map[string]int, len(m))
- for k, v := range m {
- c[k] = v
- }
- return
- }
- func copyFloats(s []float64) (c []float64) {
- c = make([]float64, len(s))
- copy(c, s)
- return
- }
- func (r *report) String() (s string) {
- if len(r.stats.Lats) > 0 {
- s += fmt.Sprintf("\nSummary:\n")
- s += fmt.Sprintf(" Total:\t%s.\n", r.sec2str(r.stats.Total.Seconds()))
- s += fmt.Sprintf(" Slowest:\t%s.\n", r.sec2str(r.stats.Slowest))
- s += fmt.Sprintf(" Fastest:\t%s.\n", r.sec2str(r.stats.Fastest))
- s += fmt.Sprintf(" Average:\t%s.\n", r.sec2str(r.stats.Average))
- s += fmt.Sprintf(" Stddev:\t%s.\n", r.sec2str(r.stats.Stddev))
- s += fmt.Sprintf(" Requests/sec:\t"+r.precision+"\n", r.stats.RPS)
- s += r.histogram()
- s += r.sprintLatencies()
- if r.sps != nil {
- s += fmt.Sprintf("%v\n", r.sps.getTimeSeries())
- }
- }
- if len(r.stats.ErrorDist) > 0 {
- s += r.errors()
- }
- return s
- }
- func (r *report) sec2str(sec float64) string { return fmt.Sprintf(r.precision+" secs", sec) }
- type reportRate struct{ *report }
- func NewReportRate(precision string) Report {
- return &reportRate{NewReport(precision).(*report)}
- }
- func (r *reportRate) String() string {
- return fmt.Sprintf(" Requests/sec:\t"+r.precision+"\n", r.stats.RPS)
- }
- func (r *report) processResult(res *Result) {
- if res.Err != nil {
- r.stats.ErrorDist[res.Err.Error()]++
- return
- }
- dur := res.Duration()
- r.stats.Lats = append(r.stats.Lats, dur.Seconds())
- r.stats.AvgTotal += dur.Seconds()
- if r.sps != nil {
- r.sps.Add(res.Start, dur)
- }
- }
- func (r *report) processResults() {
- st := time.Now()
- for res := range r.results {
- r.processResult(&res)
- }
- r.stats.Total = time.Since(st)
- r.stats.RPS = float64(len(r.stats.Lats)) / r.stats.Total.Seconds()
- r.stats.Average = r.stats.AvgTotal / float64(len(r.stats.Lats))
- for i := range r.stats.Lats {
- dev := r.stats.Lats[i] - r.stats.Average
- r.stats.Stddev += dev * dev
- }
- r.stats.Stddev = math.Sqrt(r.stats.Stddev / float64(len(r.stats.Lats)))
- sort.Float64s(r.stats.Lats)
- if len(r.stats.Lats) > 0 {
- r.stats.Fastest = r.stats.Lats[0]
- r.stats.Slowest = r.stats.Lats[len(r.stats.Lats)-1]
- }
- }
- var pctls = []float64{10, 25, 50, 75, 90, 95, 99, 99.9}
- // Percentiles returns percentile distribution of float64 slice.
- func Percentiles(nums []float64) (pcs []float64, data []float64) {
- return pctls, percentiles(nums)
- }
- func percentiles(nums []float64) (data []float64) {
- data = make([]float64, len(pctls))
- j := 0
- n := len(nums)
- for i := 0; i < n && j < len(pctls); i++ {
- current := float64(i) * 100.0 / float64(n)
- if current >= pctls[j] {
- data[j] = nums[i]
- j++
- }
- }
- return
- }
- func (r *report) sprintLatencies() string {
- data := percentiles(r.stats.Lats)
- s := fmt.Sprintf("\nLatency distribution:\n")
- for i := 0; i < len(pctls); i++ {
- if data[i] > 0 {
- s += fmt.Sprintf(" %v%% in %s.\n", pctls[i], r.sec2str(data[i]))
- }
- }
- return s
- }
- func (r *report) histogram() string {
- bc := 10
- buckets := make([]float64, bc+1)
- counts := make([]int, bc+1)
- bs := (r.stats.Slowest - r.stats.Fastest) / float64(bc)
- for i := 0; i < bc; i++ {
- buckets[i] = r.stats.Fastest + bs*float64(i)
- }
- buckets[bc] = r.stats.Slowest
- var bi int
- var max int
- for i := 0; i < len(r.stats.Lats); {
- if r.stats.Lats[i] <= buckets[bi] {
- i++
- counts[bi]++
- if max < counts[bi] {
- max = counts[bi]
- }
- } else if bi < len(buckets)-1 {
- bi++
- }
- }
- s := fmt.Sprintf("\nResponse time histogram:\n")
- for i := 0; i < len(buckets); i++ {
- // Normalize bar lengths.
- var barLen int
- if max > 0 {
- barLen = counts[i] * 40 / max
- }
- s += fmt.Sprintf(" "+r.precision+" [%v]\t|%v\n", buckets[i], counts[i], strings.Repeat(barChar, barLen))
- }
- return s
- }
- func (r *report) errors() string {
- s := fmt.Sprintf("\nError distribution:\n")
- for err, num := range r.stats.ErrorDist {
- s += fmt.Sprintf(" [%d]\t%s\n", num, err)
- }
- return s
- }
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