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Diffstat (limited to 'src/testing/benchmark.go')
-rw-r--r-- | src/testing/benchmark.go | 858 |
1 files changed, 858 insertions, 0 deletions
diff --git a/src/testing/benchmark.go b/src/testing/benchmark.go new file mode 100644 index 0000000..be9b87f --- /dev/null +++ b/src/testing/benchmark.go @@ -0,0 +1,858 @@ +// Copyright 2009 The Go Authors. All rights reserved. +// Use of this source code is governed by a BSD-style +// license that can be found in the LICENSE file. + +package testing + +import ( + "flag" + "fmt" + "internal/race" + "internal/sysinfo" + "io" + "math" + "os" + "runtime" + "sort" + "strconv" + "strings" + "sync" + "sync/atomic" + "time" + "unicode" +) + +func initBenchmarkFlags() { + matchBenchmarks = flag.String("test.bench", "", "run only benchmarks matching `regexp`") + benchmarkMemory = flag.Bool("test.benchmem", false, "print memory allocations for benchmarks") + flag.Var(&benchTime, "test.benchtime", "run each benchmark for duration `d`") +} + +var ( + matchBenchmarks *string + benchmarkMemory *bool + + benchTime = durationOrCountFlag{d: 1 * time.Second} // changed during test of testing package +) + +type durationOrCountFlag struct { + d time.Duration + n int + allowZero bool +} + +func (f *durationOrCountFlag) String() string { + if f.n > 0 { + return fmt.Sprintf("%dx", f.n) + } + return f.d.String() +} + +func (f *durationOrCountFlag) Set(s string) error { + if strings.HasSuffix(s, "x") { + n, err := strconv.ParseInt(s[:len(s)-1], 10, 0) + if err != nil || n < 0 || (!f.allowZero && n == 0) { + return fmt.Errorf("invalid count") + } + *f = durationOrCountFlag{n: int(n)} + return nil + } + d, err := time.ParseDuration(s) + if err != nil || d < 0 || (!f.allowZero && d == 0) { + return fmt.Errorf("invalid duration") + } + *f = durationOrCountFlag{d: d} + return nil +} + +// Global lock to ensure only one benchmark runs at a time. +var benchmarkLock sync.Mutex + +// Used for every benchmark for measuring memory. +var memStats runtime.MemStats + +// InternalBenchmark is an internal type but exported because it is cross-package; +// it is part of the implementation of the "go test" command. +type InternalBenchmark struct { + Name string + F func(b *B) +} + +// B is a type passed to Benchmark functions to manage benchmark +// timing and to specify the number of iterations to run. +// +// A benchmark ends when its Benchmark function returns or calls any of the methods +// FailNow, Fatal, Fatalf, SkipNow, Skip, or Skipf. Those methods must be called +// only from the goroutine running the Benchmark function. +// The other reporting methods, such as the variations of Log and Error, +// may be called simultaneously from multiple goroutines. +// +// Like in tests, benchmark logs are accumulated during execution +// and dumped to standard output when done. Unlike in tests, benchmark logs +// are always printed, so as not to hide output whose existence may be +// affecting benchmark results. +type B struct { + common + importPath string // import path of the package containing the benchmark + context *benchContext + N int + previousN int // number of iterations in the previous run + previousDuration time.Duration // total duration of the previous run + benchFunc func(b *B) + benchTime durationOrCountFlag + bytes int64 + missingBytes bool // one of the subbenchmarks does not have bytes set. + timerOn bool + showAllocResult bool + result BenchmarkResult + parallelism int // RunParallel creates parallelism*GOMAXPROCS goroutines + // The initial states of memStats.Mallocs and memStats.TotalAlloc. + startAllocs uint64 + startBytes uint64 + // The net total of this test after being run. + netAllocs uint64 + netBytes uint64 + // Extra metrics collected by ReportMetric. + extra map[string]float64 +} + +// StartTimer starts timing a test. This function is called automatically +// before a benchmark starts, but it can also be used to resume timing after +// a call to StopTimer. +func (b *B) StartTimer() { + if !b.timerOn { + runtime.ReadMemStats(&memStats) + b.startAllocs = memStats.Mallocs + b.startBytes = memStats.TotalAlloc + b.start = time.Now() + b.timerOn = true + } +} + +// StopTimer stops timing a test. This can be used to pause the timer +// while performing complex initialization that you don't +// want to measure. +func (b *B) StopTimer() { + if b.timerOn { + b.duration += time.Since(b.start) + runtime.ReadMemStats(&memStats) + b.netAllocs += memStats.Mallocs - b.startAllocs + b.netBytes += memStats.TotalAlloc - b.startBytes + b.timerOn = false + } +} + +// ResetTimer zeroes the elapsed benchmark time and memory allocation counters +// and deletes user-reported metrics. +// It does not affect whether the timer is running. +func (b *B) ResetTimer() { + if b.extra == nil { + // Allocate the extra map before reading memory stats. + // Pre-size it to make more allocation unlikely. + b.extra = make(map[string]float64, 16) + } else { + for k := range b.extra { + delete(b.extra, k) + } + } + if b.timerOn { + runtime.ReadMemStats(&memStats) + b.startAllocs = memStats.Mallocs + b.startBytes = memStats.TotalAlloc + b.start = time.Now() + } + b.duration = 0 + b.netAllocs = 0 + b.netBytes = 0 +} + +// SetBytes records the number of bytes processed in a single operation. +// If this is called, the benchmark will report ns/op and MB/s. +func (b *B) SetBytes(n int64) { b.bytes = n } + +// ReportAllocs enables malloc statistics for this benchmark. +// It is equivalent to setting -test.benchmem, but it only affects the +// benchmark function that calls ReportAllocs. +func (b *B) ReportAllocs() { + b.showAllocResult = true +} + +// runN runs a single benchmark for the specified number of iterations. +func (b *B) runN(n int) { + benchmarkLock.Lock() + defer benchmarkLock.Unlock() + defer b.runCleanup(normalPanic) + // Try to get a comparable environment for each run + // by clearing garbage from previous runs. + runtime.GC() + b.raceErrors = -race.Errors() + b.N = n + b.parallelism = 1 + b.ResetTimer() + b.StartTimer() + b.benchFunc(b) + b.StopTimer() + b.previousN = n + b.previousDuration = b.duration + b.raceErrors += race.Errors() + if b.raceErrors > 0 { + b.Errorf("race detected during execution of benchmark") + } +} + +func min(x, y int64) int64 { + if x > y { + return y + } + return x +} + +func max(x, y int64) int64 { + if x < y { + return y + } + return x +} + +// run1 runs the first iteration of benchFunc. It reports whether more +// iterations of this benchmarks should be run. +func (b *B) run1() bool { + if ctx := b.context; ctx != nil { + // Extend maxLen, if needed. + if n := len(b.name) + ctx.extLen + 1; n > ctx.maxLen { + ctx.maxLen = n + 8 // Add additional slack to avoid too many jumps in size. + } + } + go func() { + // Signal that we're done whether we return normally + // or by FailNow's runtime.Goexit. + defer func() { + b.signal <- true + }() + + b.runN(1) + }() + <-b.signal + if b.failed { + fmt.Fprintf(b.w, "%s--- FAIL: %s\n%s", b.chatty.prefix(), b.name, b.output) + return false + } + // Only print the output if we know we are not going to proceed. + // Otherwise it is printed in processBench. + b.mu.RLock() + finished := b.finished + b.mu.RUnlock() + if b.hasSub.Load() || finished { + tag := "BENCH" + if b.skipped { + tag = "SKIP" + } + if b.chatty != nil && (len(b.output) > 0 || finished) { + b.trimOutput() + fmt.Fprintf(b.w, "%s--- %s: %s\n%s", b.chatty.prefix(), tag, b.name, b.output) + } + return false + } + return true +} + +var labelsOnce sync.Once + +// run executes the benchmark in a separate goroutine, including all of its +// subbenchmarks. b must not have subbenchmarks. +func (b *B) run() { + labelsOnce.Do(func() { + fmt.Fprintf(b.w, "goos: %s\n", runtime.GOOS) + fmt.Fprintf(b.w, "goarch: %s\n", runtime.GOARCH) + if b.importPath != "" { + fmt.Fprintf(b.w, "pkg: %s\n", b.importPath) + } + if cpu := sysinfo.CPU.Name(); cpu != "" { + fmt.Fprintf(b.w, "cpu: %s\n", cpu) + } + }) + if b.context != nil { + // Running go test --test.bench + b.context.processBench(b) // Must call doBench. + } else { + // Running func Benchmark. + b.doBench() + } +} + +func (b *B) doBench() BenchmarkResult { + go b.launch() + <-b.signal + return b.result +} + +// launch launches the benchmark function. It gradually increases the number +// of benchmark iterations until the benchmark runs for the requested benchtime. +// launch is run by the doBench function as a separate goroutine. +// run1 must have been called on b. +func (b *B) launch() { + // Signal that we're done whether we return normally + // or by FailNow's runtime.Goexit. + defer func() { + b.signal <- true + }() + + // Run the benchmark for at least the specified amount of time. + if b.benchTime.n > 0 { + // We already ran a single iteration in run1. + // If -benchtime=1x was requested, use that result. + // See https://golang.org/issue/32051. + if b.benchTime.n > 1 { + b.runN(b.benchTime.n) + } + } else { + d := b.benchTime.d + for n := int64(1); !b.failed && b.duration < d && n < 1e9; { + last := n + // Predict required iterations. + goalns := d.Nanoseconds() + prevIters := int64(b.N) + prevns := b.duration.Nanoseconds() + if prevns <= 0 { + // Round up, to avoid div by zero. + prevns = 1 + } + // Order of operations matters. + // For very fast benchmarks, prevIters ~= prevns. + // If you divide first, you get 0 or 1, + // which can hide an order of magnitude in execution time. + // So multiply first, then divide. + n = goalns * prevIters / prevns + // Run more iterations than we think we'll need (1.2x). + n += n / 5 + // Don't grow too fast in case we had timing errors previously. + n = min(n, 100*last) + // Be sure to run at least one more than last time. + n = max(n, last+1) + // Don't run more than 1e9 times. (This also keeps n in int range on 32 bit platforms.) + n = min(n, 1e9) + b.runN(int(n)) + } + } + b.result = BenchmarkResult{b.N, b.duration, b.bytes, b.netAllocs, b.netBytes, b.extra} +} + +// Elapsed returns the measured elapsed time of the benchmark. +// The duration reported by Elapsed matches the one measured by +// StartTimer, StopTimer, and ResetTimer. +func (b *B) Elapsed() time.Duration { + d := b.duration + if b.timerOn { + d += time.Since(b.start) + } + return d +} + +// ReportMetric adds "n unit" to the reported benchmark results. +// If the metric is per-iteration, the caller should divide by b.N, +// and by convention units should end in "/op". +// ReportMetric overrides any previously reported value for the same unit. +// ReportMetric panics if unit is the empty string or if unit contains +// any whitespace. +// If unit is a unit normally reported by the benchmark framework itself +// (such as "allocs/op"), ReportMetric will override that metric. +// Setting "ns/op" to 0 will suppress that built-in metric. +func (b *B) ReportMetric(n float64, unit string) { + if unit == "" { + panic("metric unit must not be empty") + } + if strings.IndexFunc(unit, unicode.IsSpace) >= 0 { + panic("metric unit must not contain whitespace") + } + b.extra[unit] = n +} + +// BenchmarkResult contains the results of a benchmark run. +type BenchmarkResult struct { + N int // The number of iterations. + T time.Duration // The total time taken. + Bytes int64 // Bytes processed in one iteration. + MemAllocs uint64 // The total number of memory allocations. + MemBytes uint64 // The total number of bytes allocated. + + // Extra records additional metrics reported by ReportMetric. + Extra map[string]float64 +} + +// NsPerOp returns the "ns/op" metric. +func (r BenchmarkResult) NsPerOp() int64 { + if v, ok := r.Extra["ns/op"]; ok { + return int64(v) + } + if r.N <= 0 { + return 0 + } + return r.T.Nanoseconds() / int64(r.N) +} + +// mbPerSec returns the "MB/s" metric. +func (r BenchmarkResult) mbPerSec() float64 { + if v, ok := r.Extra["MB/s"]; ok { + return v + } + if r.Bytes <= 0 || r.T <= 0 || r.N <= 0 { + return 0 + } + return (float64(r.Bytes) * float64(r.N) / 1e6) / r.T.Seconds() +} + +// AllocsPerOp returns the "allocs/op" metric, +// which is calculated as r.MemAllocs / r.N. +func (r BenchmarkResult) AllocsPerOp() int64 { + if v, ok := r.Extra["allocs/op"]; ok { + return int64(v) + } + if r.N <= 0 { + return 0 + } + return int64(r.MemAllocs) / int64(r.N) +} + +// AllocedBytesPerOp returns the "B/op" metric, +// which is calculated as r.MemBytes / r.N. +func (r BenchmarkResult) AllocedBytesPerOp() int64 { + if v, ok := r.Extra["B/op"]; ok { + return int64(v) + } + if r.N <= 0 { + return 0 + } + return int64(r.MemBytes) / int64(r.N) +} + +// String returns a summary of the benchmark results. +// It follows the benchmark result line format from +// https://golang.org/design/14313-benchmark-format, not including the +// benchmark name. +// Extra metrics override built-in metrics of the same name. +// String does not include allocs/op or B/op, since those are reported +// by MemString. +func (r BenchmarkResult) String() string { + buf := new(strings.Builder) + fmt.Fprintf(buf, "%8d", r.N) + + // Get ns/op as a float. + ns, ok := r.Extra["ns/op"] + if !ok { + ns = float64(r.T.Nanoseconds()) / float64(r.N) + } + if ns != 0 { + buf.WriteByte('\t') + prettyPrint(buf, ns, "ns/op") + } + + if mbs := r.mbPerSec(); mbs != 0 { + fmt.Fprintf(buf, "\t%7.2f MB/s", mbs) + } + + // Print extra metrics that aren't represented in the standard + // metrics. + var extraKeys []string + for k := range r.Extra { + switch k { + case "ns/op", "MB/s", "B/op", "allocs/op": + // Built-in metrics reported elsewhere. + continue + } + extraKeys = append(extraKeys, k) + } + sort.Strings(extraKeys) + for _, k := range extraKeys { + buf.WriteByte('\t') + prettyPrint(buf, r.Extra[k], k) + } + return buf.String() +} + +func prettyPrint(w io.Writer, x float64, unit string) { + // Print all numbers with 10 places before the decimal point + // and small numbers with four sig figs. Field widths are + // chosen to fit the whole part in 10 places while aligning + // the decimal point of all fractional formats. + var format string + switch y := math.Abs(x); { + case y == 0 || y >= 999.95: + format = "%10.0f %s" + case y >= 99.995: + format = "%12.1f %s" + case y >= 9.9995: + format = "%13.2f %s" + case y >= 0.99995: + format = "%14.3f %s" + case y >= 0.099995: + format = "%15.4f %s" + case y >= 0.0099995: + format = "%16.5f %s" + case y >= 0.00099995: + format = "%17.6f %s" + default: + format = "%18.7f %s" + } + fmt.Fprintf(w, format, x, unit) +} + +// MemString returns r.AllocedBytesPerOp and r.AllocsPerOp in the same format as 'go test'. +func (r BenchmarkResult) MemString() string { + return fmt.Sprintf("%8d B/op\t%8d allocs/op", + r.AllocedBytesPerOp(), r.AllocsPerOp()) +} + +// benchmarkName returns full name of benchmark including procs suffix. +func benchmarkName(name string, n int) string { + if n != 1 { + return fmt.Sprintf("%s-%d", name, n) + } + return name +} + +type benchContext struct { + match *matcher + + maxLen int // The largest recorded benchmark name. + extLen int // Maximum extension length. +} + +// RunBenchmarks is an internal function but exported because it is cross-package; +// it is part of the implementation of the "go test" command. +func RunBenchmarks(matchString func(pat, str string) (bool, error), benchmarks []InternalBenchmark) { + runBenchmarks("", matchString, benchmarks) +} + +func runBenchmarks(importPath string, matchString func(pat, str string) (bool, error), benchmarks []InternalBenchmark) bool { + // If no flag was specified, don't run benchmarks. + if len(*matchBenchmarks) == 0 { + return true + } + // Collect matching benchmarks and determine longest name. + maxprocs := 1 + for _, procs := range cpuList { + if procs > maxprocs { + maxprocs = procs + } + } + ctx := &benchContext{ + match: newMatcher(matchString, *matchBenchmarks, "-test.bench", *skip), + extLen: len(benchmarkName("", maxprocs)), + } + var bs []InternalBenchmark + for _, Benchmark := range benchmarks { + if _, matched, _ := ctx.match.fullName(nil, Benchmark.Name); matched { + bs = append(bs, Benchmark) + benchName := benchmarkName(Benchmark.Name, maxprocs) + if l := len(benchName) + ctx.extLen + 1; l > ctx.maxLen { + ctx.maxLen = l + } + } + } + main := &B{ + common: common{ + name: "Main", + w: os.Stdout, + bench: true, + }, + importPath: importPath, + benchFunc: func(b *B) { + for _, Benchmark := range bs { + b.Run(Benchmark.Name, Benchmark.F) + } + }, + benchTime: benchTime, + context: ctx, + } + if Verbose() { + main.chatty = newChattyPrinter(main.w) + } + main.runN(1) + return !main.failed +} + +// processBench runs bench b for the configured CPU counts and prints the results. +func (ctx *benchContext) processBench(b *B) { + for i, procs := range cpuList { + for j := uint(0); j < *count; j++ { + runtime.GOMAXPROCS(procs) + benchName := benchmarkName(b.name, procs) + + // If it's chatty, we've already printed this information. + if b.chatty == nil { + fmt.Fprintf(b.w, "%-*s\t", ctx.maxLen, benchName) + } + // Recompute the running time for all but the first iteration. + if i > 0 || j > 0 { + b = &B{ + common: common{ + signal: make(chan bool), + name: b.name, + w: b.w, + chatty: b.chatty, + bench: true, + }, + benchFunc: b.benchFunc, + benchTime: b.benchTime, + } + b.run1() + } + r := b.doBench() + if b.failed { + // The output could be very long here, but probably isn't. + // We print it all, regardless, because we don't want to trim the reason + // the benchmark failed. + fmt.Fprintf(b.w, "%s--- FAIL: %s\n%s", b.chatty.prefix(), benchName, b.output) + continue + } + results := r.String() + if b.chatty != nil { + fmt.Fprintf(b.w, "%-*s\t", ctx.maxLen, benchName) + } + if *benchmarkMemory || b.showAllocResult { + results += "\t" + r.MemString() + } + fmt.Fprintln(b.w, results) + // Unlike with tests, we ignore the -chatty flag and always print output for + // benchmarks since the output generation time will skew the results. + if len(b.output) > 0 { + b.trimOutput() + fmt.Fprintf(b.w, "%s--- BENCH: %s\n%s", b.chatty.prefix(), benchName, b.output) + } + if p := runtime.GOMAXPROCS(-1); p != procs { + fmt.Fprintf(os.Stderr, "testing: %s left GOMAXPROCS set to %d\n", benchName, p) + } + if b.chatty != nil && b.chatty.json { + b.chatty.Updatef("", "=== NAME %s\n", "") + } + } + } +} + +// If hideStdoutForTesting is true, Run does not print the benchName. +// This avoids a spurious print during 'go test' on package testing itself, +// which invokes b.Run in its own tests (see sub_test.go). +var hideStdoutForTesting = false + +// Run benchmarks f as a subbenchmark with the given name. It reports +// whether there were any failures. +// +// A subbenchmark is like any other benchmark. A benchmark that calls Run at +// least once will not be measured itself and will be called once with N=1. +func (b *B) Run(name string, f func(b *B)) bool { + // Since b has subbenchmarks, we will no longer run it as a benchmark itself. + // Release the lock and acquire it on exit to ensure locks stay paired. + b.hasSub.Store(true) + benchmarkLock.Unlock() + defer benchmarkLock.Lock() + + benchName, ok, partial := b.name, true, false + if b.context != nil { + benchName, ok, partial = b.context.match.fullName(&b.common, name) + } + if !ok { + return true + } + var pc [maxStackLen]uintptr + n := runtime.Callers(2, pc[:]) + sub := &B{ + common: common{ + signal: make(chan bool), + name: benchName, + parent: &b.common, + level: b.level + 1, + creator: pc[:n], + w: b.w, + chatty: b.chatty, + bench: true, + }, + importPath: b.importPath, + benchFunc: f, + benchTime: b.benchTime, + context: b.context, + } + if partial { + // Partial name match, like -bench=X/Y matching BenchmarkX. + // Only process sub-benchmarks, if any. + sub.hasSub.Store(true) + } + + if b.chatty != nil { + labelsOnce.Do(func() { + fmt.Printf("goos: %s\n", runtime.GOOS) + fmt.Printf("goarch: %s\n", runtime.GOARCH) + if b.importPath != "" { + fmt.Printf("pkg: %s\n", b.importPath) + } + if cpu := sysinfo.CPU.Name(); cpu != "" { + fmt.Printf("cpu: %s\n", cpu) + } + }) + + if !hideStdoutForTesting { + if b.chatty.json { + b.chatty.Updatef(benchName, "=== RUN %s\n", benchName) + } + fmt.Println(benchName) + } + } + + if sub.run1() { + sub.run() + } + b.add(sub.result) + return !sub.failed +} + +// add simulates running benchmarks in sequence in a single iteration. It is +// used to give some meaningful results in case func Benchmark is used in +// combination with Run. +func (b *B) add(other BenchmarkResult) { + r := &b.result + // The aggregated BenchmarkResults resemble running all subbenchmarks as + // in sequence in a single benchmark. + r.N = 1 + r.T += time.Duration(other.NsPerOp()) + if other.Bytes == 0 { + // Summing Bytes is meaningless in aggregate if not all subbenchmarks + // set it. + b.missingBytes = true + r.Bytes = 0 + } + if !b.missingBytes { + r.Bytes += other.Bytes + } + r.MemAllocs += uint64(other.AllocsPerOp()) + r.MemBytes += uint64(other.AllocedBytesPerOp()) +} + +// trimOutput shortens the output from a benchmark, which can be very long. +func (b *B) trimOutput() { + // The output is likely to appear multiple times because the benchmark + // is run multiple times, but at least it will be seen. This is not a big deal + // because benchmarks rarely print, but just in case, we trim it if it's too long. + const maxNewlines = 10 + for nlCount, j := 0, 0; j < len(b.output); j++ { + if b.output[j] == '\n' { + nlCount++ + if nlCount >= maxNewlines { + b.output = append(b.output[:j], "\n\t... [output truncated]\n"...) + break + } + } + } +} + +// A PB is used by RunParallel for running parallel benchmarks. +type PB struct { + globalN *uint64 // shared between all worker goroutines iteration counter + grain uint64 // acquire that many iterations from globalN at once + cache uint64 // local cache of acquired iterations + bN uint64 // total number of iterations to execute (b.N) +} + +// Next reports whether there are more iterations to execute. +func (pb *PB) Next() bool { + if pb.cache == 0 { + n := atomic.AddUint64(pb.globalN, pb.grain) + if n <= pb.bN { + pb.cache = pb.grain + } else if n < pb.bN+pb.grain { + pb.cache = pb.bN + pb.grain - n + } else { + return false + } + } + pb.cache-- + return true +} + +// RunParallel runs a benchmark in parallel. +// It creates multiple goroutines and distributes b.N iterations among them. +// The number of goroutines defaults to GOMAXPROCS. To increase parallelism for +// non-CPU-bound benchmarks, call SetParallelism before RunParallel. +// RunParallel is usually used with the go test -cpu flag. +// +// The body function will be run in each goroutine. It should set up any +// goroutine-local state and then iterate until pb.Next returns false. +// It should not use the StartTimer, StopTimer, or ResetTimer functions, +// because they have global effect. It should also not call Run. +// +// RunParallel reports ns/op values as wall time for the benchmark as a whole, +// not the sum of wall time or CPU time over each parallel goroutine. +func (b *B) RunParallel(body func(*PB)) { + if b.N == 0 { + return // Nothing to do when probing. + } + // Calculate grain size as number of iterations that take ~100µs. + // 100µs is enough to amortize the overhead and provide sufficient + // dynamic load balancing. + grain := uint64(0) + if b.previousN > 0 && b.previousDuration > 0 { + grain = 1e5 * uint64(b.previousN) / uint64(b.previousDuration) + } + if grain < 1 { + grain = 1 + } + // We expect the inner loop and function call to take at least 10ns, + // so do not do more than 100µs/10ns=1e4 iterations. + if grain > 1e4 { + grain = 1e4 + } + + n := uint64(0) + numProcs := b.parallelism * runtime.GOMAXPROCS(0) + var wg sync.WaitGroup + wg.Add(numProcs) + for p := 0; p < numProcs; p++ { + go func() { + defer wg.Done() + pb := &PB{ + globalN: &n, + grain: grain, + bN: uint64(b.N), + } + body(pb) + }() + } + wg.Wait() + if n <= uint64(b.N) && !b.Failed() { + b.Fatal("RunParallel: body exited without pb.Next() == false") + } +} + +// SetParallelism sets the number of goroutines used by RunParallel to p*GOMAXPROCS. +// There is usually no need to call SetParallelism for CPU-bound benchmarks. +// If p is less than 1, this call will have no effect. +func (b *B) SetParallelism(p int) { + if p >= 1 { + b.parallelism = p + } +} + +// Benchmark benchmarks a single function. It is useful for creating +// custom benchmarks that do not use the "go test" command. +// +// If f depends on testing flags, then Init must be used to register +// those flags before calling Benchmark and before calling flag.Parse. +// +// If f calls Run, the result will be an estimate of running all its +// subbenchmarks that don't call Run in sequence in a single benchmark. +func Benchmark(f func(b *B)) BenchmarkResult { + b := &B{ + common: common{ + signal: make(chan bool), + w: discard{}, + }, + benchFunc: f, + benchTime: benchTime, + } + if b.run1() { + b.run() + } + return b.result +} + +type discard struct{} + +func (discard) Write(b []byte) (n int, err error) { return len(b), nil } |