6736ef96ea
The next revision, 19185, renames several runtime files, and will be handled in a separate change. From-SVN: r211328
442 lines
12 KiB
Go
442 lines
12 KiB
Go
// Copyright 2009 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package testing
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import (
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"flag"
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"fmt"
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"os"
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"runtime"
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"sync"
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"sync/atomic"
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"time"
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)
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var matchBenchmarks = flag.String("test.bench", "", "regular expression to select benchmarks to run")
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var benchTime = flag.Duration("test.benchtime", 1*time.Second, "approximate run time for each benchmark")
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var benchmarkMemory = flag.Bool("test.benchmem", false, "print memory allocations for benchmarks")
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// Global lock to ensure only one benchmark runs at a time.
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var benchmarkLock sync.Mutex
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// Used for every benchmark for measuring memory.
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var memStats runtime.MemStats
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// An internal type but exported because it is cross-package; part of the implementation
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// of the "go test" command.
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type InternalBenchmark struct {
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Name string
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F func(b *B)
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}
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// B is a type passed to Benchmark functions to manage benchmark
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// timing and to specify the number of iterations to run.
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type B struct {
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common
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N int
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previousN int // number of iterations in the previous run
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previousDuration time.Duration // total duration of the previous run
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benchmark InternalBenchmark
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bytes int64
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timerOn bool
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showAllocResult bool
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result BenchmarkResult
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parallelism int // RunParallel creates parallelism*GOMAXPROCS goroutines
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// The initial states of memStats.Mallocs and memStats.TotalAlloc.
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startAllocs uint64
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startBytes uint64
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// The net total of this test after being run.
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netAllocs uint64
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netBytes uint64
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}
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// StartTimer starts timing a test. This function is called automatically
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// before a benchmark starts, but it can also used to resume timing after
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// a call to StopTimer.
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func (b *B) StartTimer() {
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if !b.timerOn {
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runtime.ReadMemStats(&memStats)
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b.startAllocs = memStats.Mallocs
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b.startBytes = memStats.TotalAlloc
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b.start = time.Now()
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b.timerOn = true
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}
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}
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// StopTimer stops timing a test. This can be used to pause the timer
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// while performing complex initialization that you don't
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// want to measure.
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func (b *B) StopTimer() {
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if b.timerOn {
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b.duration += time.Now().Sub(b.start)
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runtime.ReadMemStats(&memStats)
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b.netAllocs += memStats.Mallocs - b.startAllocs
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b.netBytes += memStats.TotalAlloc - b.startBytes
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b.timerOn = false
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}
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}
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// ResetTimer zeros the elapsed benchmark time and memory allocation counters.
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// It does not affect whether the timer is running.
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func (b *B) ResetTimer() {
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if b.timerOn {
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runtime.ReadMemStats(&memStats)
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b.startAllocs = memStats.Mallocs
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b.startBytes = memStats.TotalAlloc
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b.start = time.Now()
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}
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b.duration = 0
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b.netAllocs = 0
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b.netBytes = 0
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}
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// SetBytes records the number of bytes processed in a single operation.
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// If this is called, the benchmark will report ns/op and MB/s.
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func (b *B) SetBytes(n int64) { b.bytes = n }
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// ReportAllocs enables malloc statistics for this benchmark.
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// It is equivalent to setting -test.benchmem, but it only affects the
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// benchmark function that calls ReportAllocs.
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func (b *B) ReportAllocs() {
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b.showAllocResult = true
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}
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func (b *B) nsPerOp() int64 {
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if b.N <= 0 {
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return 0
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}
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return b.duration.Nanoseconds() / int64(b.N)
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}
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// runN runs a single benchmark for the specified number of iterations.
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func (b *B) runN(n int) {
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benchmarkLock.Lock()
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defer benchmarkLock.Unlock()
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// Try to get a comparable environment for each run
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// by clearing garbage from previous runs.
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runtime.GC()
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b.N = n
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b.parallelism = 1
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b.ResetTimer()
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b.StartTimer()
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b.benchmark.F(b)
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b.StopTimer()
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b.previousN = n
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b.previousDuration = b.duration
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}
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func min(x, y int) int {
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if x > y {
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return y
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}
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return x
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}
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func max(x, y int) int {
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if x < y {
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return y
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}
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return x
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}
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// roundDown10 rounds a number down to the nearest power of 10.
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func roundDown10(n int) int {
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var tens = 0
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// tens = floor(log_10(n))
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for n >= 10 {
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n = n / 10
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tens++
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}
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// result = 10^tens
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result := 1
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for i := 0; i < tens; i++ {
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result *= 10
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}
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return result
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}
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// roundUp rounds x up to a number of the form [1eX, 2eX, 5eX].
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func roundUp(n int) int {
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base := roundDown10(n)
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switch {
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case n <= base:
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return base
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case n <= (2 * base):
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return 2 * base
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case n <= (5 * base):
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return 5 * base
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default:
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return 10 * base
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}
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}
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// run times the benchmark function in a separate goroutine.
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func (b *B) run() BenchmarkResult {
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go b.launch()
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<-b.signal
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return b.result
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}
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// launch launches the benchmark function. It gradually increases the number
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// of benchmark iterations until the benchmark runs for a second in order
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// to get a reasonable measurement. It prints timing information in this form
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// testing.BenchmarkHello 100000 19 ns/op
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// launch is run by the fun function as a separate goroutine.
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func (b *B) launch() {
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// Run the benchmark for a single iteration in case it's expensive.
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n := 1
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// Signal that we're done whether we return normally
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// or by FailNow's runtime.Goexit.
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defer func() {
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b.signal <- b
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}()
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b.runN(n)
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// Run the benchmark for at least the specified amount of time.
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d := *benchTime
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for !b.failed && b.duration < d && n < 1e9 {
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last := n
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// Predict iterations/sec.
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if b.nsPerOp() == 0 {
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n = 1e9
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} else {
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n = int(d.Nanoseconds() / b.nsPerOp())
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}
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// Run more iterations than we think we'll need for a second (1.5x).
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// Don't grow too fast in case we had timing errors previously.
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// Be sure to run at least one more than last time.
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n = max(min(n+n/2, 100*last), last+1)
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// Round up to something easy to read.
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n = roundUp(n)
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b.runN(n)
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}
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b.result = BenchmarkResult{b.N, b.duration, b.bytes, b.netAllocs, b.netBytes}
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}
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// The results of a benchmark run.
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type BenchmarkResult struct {
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N int // The number of iterations.
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T time.Duration // The total time taken.
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Bytes int64 // Bytes processed in one iteration.
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MemAllocs uint64 // The total number of memory allocations.
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MemBytes uint64 // The total number of bytes allocated.
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}
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func (r BenchmarkResult) NsPerOp() int64 {
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if r.N <= 0 {
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return 0
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}
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return r.T.Nanoseconds() / int64(r.N)
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}
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func (r BenchmarkResult) mbPerSec() float64 {
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if r.Bytes <= 0 || r.T <= 0 || r.N <= 0 {
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return 0
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}
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return (float64(r.Bytes) * float64(r.N) / 1e6) / r.T.Seconds()
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}
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func (r BenchmarkResult) AllocsPerOp() int64 {
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if r.N <= 0 {
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return 0
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}
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return int64(r.MemAllocs) / int64(r.N)
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}
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func (r BenchmarkResult) AllocedBytesPerOp() int64 {
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if r.N <= 0 {
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return 0
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}
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return int64(r.MemBytes) / int64(r.N)
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}
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func (r BenchmarkResult) String() string {
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mbs := r.mbPerSec()
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mb := ""
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if mbs != 0 {
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mb = fmt.Sprintf("\t%7.2f MB/s", mbs)
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}
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nsop := r.NsPerOp()
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ns := fmt.Sprintf("%10d ns/op", nsop)
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if r.N > 0 && nsop < 100 {
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// The format specifiers here make sure that
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// the ones digits line up for all three possible formats.
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if nsop < 10 {
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ns = fmt.Sprintf("%13.2f ns/op", float64(r.T.Nanoseconds())/float64(r.N))
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} else {
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ns = fmt.Sprintf("%12.1f ns/op", float64(r.T.Nanoseconds())/float64(r.N))
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}
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}
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return fmt.Sprintf("%8d\t%s%s", r.N, ns, mb)
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}
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func (r BenchmarkResult) MemString() string {
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return fmt.Sprintf("%8d B/op\t%8d allocs/op",
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r.AllocedBytesPerOp(), r.AllocsPerOp())
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}
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// An internal function but exported because it is cross-package; part of the implementation
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// of the "go test" command.
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func RunBenchmarks(matchString func(pat, str string) (bool, error), benchmarks []InternalBenchmark) {
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// If no flag was specified, don't run benchmarks.
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if len(*matchBenchmarks) == 0 {
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return
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}
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for _, Benchmark := range benchmarks {
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matched, err := matchString(*matchBenchmarks, Benchmark.Name)
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if err != nil {
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fmt.Fprintf(os.Stderr, "testing: invalid regexp for -test.bench: %s\n", err)
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os.Exit(1)
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}
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if !matched {
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continue
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}
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for _, procs := range cpuList {
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runtime.GOMAXPROCS(procs)
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b := &B{
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common: common{
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signal: make(chan interface{}),
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},
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benchmark: Benchmark,
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}
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benchName := Benchmark.Name
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if procs != 1 {
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benchName = fmt.Sprintf("%s-%d", Benchmark.Name, procs)
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}
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fmt.Printf("%s\t", benchName)
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r := b.run()
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if b.failed {
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// The output could be very long here, but probably isn't.
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// We print it all, regardless, because we don't want to trim the reason
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// the benchmark failed.
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fmt.Printf("--- FAIL: %s\n%s", benchName, b.output)
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continue
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}
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results := r.String()
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if *benchmarkMemory || b.showAllocResult {
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results += "\t" + r.MemString()
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}
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fmt.Println(results)
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// Unlike with tests, we ignore the -chatty flag and always print output for
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// benchmarks since the output generation time will skew the results.
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if len(b.output) > 0 {
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b.trimOutput()
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fmt.Printf("--- BENCH: %s\n%s", benchName, b.output)
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}
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if p := runtime.GOMAXPROCS(-1); p != procs {
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fmt.Fprintf(os.Stderr, "testing: %s left GOMAXPROCS set to %d\n", benchName, p)
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}
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}
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}
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}
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// trimOutput shortens the output from a benchmark, which can be very long.
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func (b *B) trimOutput() {
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// The output is likely to appear multiple times because the benchmark
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// is run multiple times, but at least it will be seen. This is not a big deal
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// because benchmarks rarely print, but just in case, we trim it if it's too long.
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const maxNewlines = 10
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for nlCount, j := 0, 0; j < len(b.output); j++ {
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if b.output[j] == '\n' {
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nlCount++
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if nlCount >= maxNewlines {
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b.output = append(b.output[:j], "\n\t... [output truncated]\n"...)
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break
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}
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}
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}
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}
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// A PB is used by RunParallel for running parallel benchmarks.
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type PB struct {
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globalN *uint64 // shared between all worker goroutines iteration counter
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grain uint64 // acquire that many iterations from globalN at once
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cache uint64 // local cache of acquired iterations
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bN uint64 // total number of iterations to execute (b.N)
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}
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// Next reports whether there are more iterations to execute.
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func (pb *PB) Next() bool {
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if pb.cache == 0 {
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n := atomic.AddUint64(pb.globalN, pb.grain)
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if n <= pb.bN {
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pb.cache = pb.grain
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} else if n < pb.bN+pb.grain {
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pb.cache = pb.bN + pb.grain - n
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} else {
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return false
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}
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}
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pb.cache--
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return true
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}
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// RunParallel runs a benchmark in parallel.
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// It creates multiple goroutines and distributes b.N iterations among them.
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// The number of goroutines defaults to GOMAXPROCS. To increase parallelism for
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// non-CPU-bound benchmarks, call SetParallelism before RunParallel.
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// RunParallel is usually used with the go test -cpu flag.
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//
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// The body function will be run in each goroutine. It should set up any
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// goroutine-local state and then iterate until pb.Next returns false.
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// It should not use the StartTimer, StopTimer, or ResetTimer functions,
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// because they have global effect.
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func (b *B) RunParallel(body func(*PB)) {
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// Calculate grain size as number of iterations that take ~100µs.
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// 100µs is enough to amortize the overhead and provide sufficient
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// dynamic load balancing.
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grain := uint64(0)
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if b.previousN > 0 && b.previousDuration > 0 {
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grain = 1e5 * uint64(b.previousN) / uint64(b.previousDuration)
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}
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if grain < 1 {
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grain = 1
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}
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// We expect the inner loop and function call to take at least 10ns,
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// so do not do more than 100µs/10ns=1e4 iterations.
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if grain > 1e4 {
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grain = 1e4
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}
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n := uint64(0)
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numProcs := b.parallelism * runtime.GOMAXPROCS(0)
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var wg sync.WaitGroup
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wg.Add(numProcs)
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for p := 0; p < numProcs; p++ {
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go func() {
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defer wg.Done()
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pb := &PB{
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globalN: &n,
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grain: grain,
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bN: uint64(b.N),
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}
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body(pb)
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}()
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}
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wg.Wait()
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}
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// SetParallelism sets the number of goroutines used by RunParallel to p*GOMAXPROCS.
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// There is usually no need to call SetParallelism for CPU-bound benchmarks.
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// If p is less than 1, this call will have no effect.
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func (b *B) SetParallelism(p int) {
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if p >= 1 {
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b.parallelism = p
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}
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}
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// Benchmark benchmarks a single function. Useful for creating
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// custom benchmarks that do not use the "go test" command.
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func Benchmark(f func(b *B)) BenchmarkResult {
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b := &B{
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common: common{
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signal: make(chan interface{}),
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},
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benchmark: InternalBenchmark{"", f},
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}
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return b.run()
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}
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