test/heapsampling.go - go - Git at Google

 // run

 // 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.

 // Test heap sampling logic.

 package main

 import (
 	"fmt"
 	"math"
 	"runtime"
 )

 var a16 *[16]byte
 var a512 *[512]byte
 var a256 *[256]byte
 var a1k *[1024]byte
 var a64k *[64 * 1024]byte

 // This test checks that heap sampling produces reasonable
 // results. Note that heap sampling uses randomization, so the results
 // vary for run to run. This test only checks that the resulting
 // values appear reasonable.
 func main() {
 	const countInterleaved = 10000
 	allocInterleaved(countInterleaved)
 	checkAllocations(getMemProfileRecords(), "main.allocInterleaved", countInterleaved, []int64{256 * 1024, 1024, 256 * 1024, 512, 256 * 1024, 256})

 	const count = 100000
 	alloc(count)
 	checkAllocations(getMemProfileRecords(), "main.alloc", count, []int64{1024, 512, 256})
 }

 // allocInterleaved stress-tests the heap sampling logic by
 // interleaving large and small allocations.
 func allocInterleaved(n int) {
 	for i := 0; i < n; i++ {
 		// Test verification depends on these lines being contiguous.
 		a64k = new([64 * 1024]byte)
 		a1k = new([1024]byte)
 		a64k = new([64 * 1024]byte)
 		a512 = new([512]byte)
 		a64k = new([64 * 1024]byte)
 		a256 = new([256]byte)
 	}
 }

 // alloc performs only small allocations for sanity testing.
 func alloc(n int) {
 	for i := 0; i < n; i++ {
 		// Test verification depends on these lines being contiguous.
 		a1k = new([1024]byte)
 		a512 = new([512]byte)
 		a256 = new([256]byte)
 	}
 }

 // checkAllocations validates that the profile records collected for
 // the named function are consistent with count contiguous allocations
 // of the specified sizes.
 func checkAllocations(records []runtime.MemProfileRecord, fname string, count int64, size []int64) {
 	a := allocObjects(records, fname)
 	firstLine := 0
 	for ln := range a {
 		if firstLine == 0 || firstLine > ln {
 			firstLine = ln
 		}
 	}
 	var totalcount int64
 	for i, w := range size {
 		ln := firstLine + i
 		s := a[ln]
 		checkValue(fname, ln, "objects", count, s.objects)
 		checkValue(fname, ln, "bytes", count*w, s.bytes)
 		totalcount += s.objects
 	}
 	// Check the total number of allocations, to ensure some sampling occurred.
 	if totalwant := count * int64(len(size)); totalcount <= 0 || totalcount > totalwant*1024 {
 		panic(fmt.Sprintf("%s want total count > 0 && <= %d, got %d", fname, totalwant*1024, totalcount))
 	}
 }

 // checkValue checks an unsampled value against a range.
 func checkValue(fname string, ln int, name string, want, got int64) {
 	if got < 0 || got > 1024*want {
 		panic(fmt.Sprintf("%s:%d want %s >= 0 && <= %d, got %d", fname, ln, name, 1024*want, got))
 	}
 }

 func getMemProfileRecords() []runtime.MemProfileRecord {
 	// Force the runtime to update the object and byte counts.
 	// This can take up to two GC cycles to get a complete
 	// snapshot of the current point in time.
 	runtime.GC()
 	runtime.GC()

 	// Find out how many records there are (MemProfile(nil, true)),
 	// allocate that many records, and get the data.
 	// There's a race—more records might be added between
 	// the two calls—so allocate a few extra records for safety
 	// and also try again if we're very unlucky.
 	// The loop should only execute one iteration in the common case.
 	var p []runtime.MemProfileRecord
 	n, ok := runtime.MemProfile(nil, true)
 	for {
 		// Allocate room for a slightly bigger profile,
 		// in case a few more entries have been added
 		// since the call to MemProfile.
 		p = make([]runtime.MemProfileRecord, n+50)
 		n, ok = runtime.MemProfile(p, true)
 		if ok {
 			p = p[0:n]
 			break
 		}
 		// Profile grew; try again.
 	}
 	return p
 }

 type allocStat struct {
 	bytes, objects int64
 }

 // allocObjects examines the profile records for the named function
 // and returns the allocation stats aggregated by source line number.
 func allocObjects(records []runtime.MemProfileRecord, function string) map[int]allocStat {
 	a := make(map[int]allocStat)
 	for _, r := range records {
 		for _, s := range r.Stack0 {
 			if s == 0 {
 				break
 			}
 			if f := runtime.FuncForPC(s); f != nil {
 				name := f.Name()
 				_, line := f.FileLine(s)
 				if name == function {
 					allocStat := a[line]
 					allocStat.bytes += r.AllocBytes
 					allocStat.objects += r.AllocObjects
 					a[line] = allocStat
 				}
 			}
 		}
 	}
 	for line, stats := range a {
 		objects, bytes := scaleHeapSample(stats.objects, stats.bytes, int64(runtime.MemProfileRate))
 		a[line] = allocStat{bytes, objects}
 	}
 	return a
 }

 // scaleHeapSample unsamples heap allocations.
 // Taken from src/cmd/pprof/internal/profile/legacy_profile.go
 func scaleHeapSample(count, size, rate int64) (int64, int64) {
 	if count == 0 || size == 0 {
 		return 0, 0
 	}

 	if rate <= 1 {
 		// if rate==1 all samples were collected so no adjustment is needed.
 		// if rate<1 treat as unknown and skip scaling.
 		return count, size
 	}

 	avgSize := float64(size) / float64(count)
 	scale := 1 / (1 - math.Exp(-avgSize/float64(rate)))

 	return int64(float64(count) * scale), int64(float64(size) * scale)
 }
	// run

	// 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.

	// Test heap sampling logic.

	package main

	import (
	"fmt"
	"math"
	"runtime"
	)

	var a16 *[16]byte
	var a512 *[512]byte
	var a256 *[256]byte
	var a1k *[1024]byte
	var a64k [64 1024]byte

	// This test checks that heap sampling produces reasonable
	// results. Note that heap sampling uses randomization, so the results
	// vary for run to run. This test only checks that the resulting
	// values appear reasonable.
	func main() {
	const countInterleaved = 10000
	allocInterleaved(countInterleaved)
	checkAllocations(getMemProfileRecords(), "main.allocInterleaved", countInterleaved, []int64{256 * 1024, 1024, 256 * 1024, 512, 256 * 1024, 256})

	const count = 100000
	alloc(count)
	checkAllocations(getMemProfileRecords(), "main.alloc", count, []int64{1024, 512, 256})
	}

	// allocInterleaved stress-tests the heap sampling logic by
	// interleaving large and small allocations.
	func allocInterleaved(n int) {
	for i := 0; i < n; i++ {
	// Test verification depends on these lines being contiguous.
	a64k = new([64 * 1024]byte)
	a1k = new([1024]byte)
	a64k = new([64 * 1024]byte)
	a512 = new([512]byte)
	a64k = new([64 * 1024]byte)
	a256 = new([256]byte)
	}
	}

	// alloc performs only small allocations for sanity testing.
	func alloc(n int) {
	for i := 0; i < n; i++ {
	// Test verification depends on these lines being contiguous.
	a1k = new([1024]byte)
	a512 = new([512]byte)
	a256 = new([256]byte)
	}
	}

	// checkAllocations validates that the profile records collected for
	// the named function are consistent with count contiguous allocations
	// of the specified sizes.
	func checkAllocations(records []runtime.MemProfileRecord, fname string, count int64, size []int64) {
	a := allocObjects(records, fname)
	firstLine := 0
	for ln := range a {
	if firstLine == 0 \|\| firstLine > ln {
	firstLine = ln
	}
	}
	var totalcount int64
	for i, w := range size {
	ln := firstLine + i
	s := a[ln]
	checkValue(fname, ln, "objects", count, s.objects)
	checkValue(fname, ln, "bytes", count*w, s.bytes)
	totalcount += s.objects
	}
	// Check the total number of allocations, to ensure some sampling occurred.
	if totalwant := count * int64(len(size)); totalcount <= 0 \|\| totalcount > totalwant*1024 {
	panic(fmt.Sprintf("%s want total count > 0 && <= %d, got %d", fname, totalwant*1024, totalcount))
	}
	}

	// checkValue checks an unsampled value against a range.
	func checkValue(fname string, ln int, name string, want, got int64) {
	if got < 0 \|\| got > 1024*want {
	panic(fmt.Sprintf("%s:%d want %s >= 0 && <= %d, got %d", fname, ln, name, 1024*want, got))
	}
	}

	func getMemProfileRecords() []runtime.MemProfileRecord {
	// Force the runtime to update the object and byte counts.
	// This can take up to two GC cycles to get a complete
	// snapshot of the current point in time.
	runtime.GC()
	runtime.GC()

	// Find out how many records there are (MemProfile(nil, true)),
	// allocate that many records, and get the data.
	// There's a race—more records might be added between
	// the two calls—so allocate a few extra records for safety
	// and also try again if we're very unlucky.
	// The loop should only execute one iteration in the common case.
	var p []runtime.MemProfileRecord
	n, ok := runtime.MemProfile(nil, true)
	for {
	// Allocate room for a slightly bigger profile,
	// in case a few more entries have been added
	// since the call to MemProfile.
	p = make([]runtime.MemProfileRecord, n+50)
	n, ok = runtime.MemProfile(p, true)
	if ok {
	p = p[0:n]
	break
	}
	// Profile grew; try again.
	}
	return p
	}

	type allocStat struct {
	bytes, objects int64
	}

	// allocObjects examines the profile records for the named function
	// and returns the allocation stats aggregated by source line number.
	func allocObjects(records []runtime.MemProfileRecord, function string) map[int]allocStat {
	a := make(map[int]allocStat)
	for _, r := range records {
	for _, s := range r.Stack0 {
	if s == 0 {
	break
	}
	if f := runtime.FuncForPC(s); f != nil {
	name := f.Name()
	_, line := f.FileLine(s)
	if name == function {
	allocStat := a[line]
	allocStat.bytes += r.AllocBytes
	allocStat.objects += r.AllocObjects
	a[line] = allocStat
	}
	}
	}
	}
	for line, stats := range a {
	objects, bytes := scaleHeapSample(stats.objects, stats.bytes, int64(runtime.MemProfileRate))
	a[line] = allocStat{bytes, objects}
	}
	return a
	}

	// scaleHeapSample unsamples heap allocations.
	// Taken from src/cmd/pprof/internal/profile/legacy_profile.go
	func scaleHeapSample(count, size, rate int64) (int64, int64) {
	if count == 0 \|\| size == 0 {
	return 0, 0
	}

	if rate <= 1 {
	// if rate==1 all samples were collected so no adjustment is needed.
	// if rate<1 treat as unknown and skip scaling.
	return count, size
	}

	avgSize := float64(size) / float64(count)
	scale := 1 / (1 - math.Exp(-avgSize/float64(rate)))

	return int64(float64(count) * scale), int64(float64(size) * scale)
	}