2015-09-14 15:03:45 -06:00
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// run
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// 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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// Test heap sampling logic.
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package main
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import (
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"fmt"
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"math"
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"runtime"
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)
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var a16 *[16]byte
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var a512 *[512]byte
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var a256 *[256]byte
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var a1k *[1024]byte
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var a16k *[16 * 1024]byte
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var a17k *[17 * 1024]byte
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var a18k *[18 * 1024]byte
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2015-09-14 15:03:45 -06:00
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2019-01-18 12:06:16 -07:00
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// This test checks that heap sampling produces reasonable results.
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// Note that heap sampling uses randomization, so the results vary for
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// run to run. To avoid flakes, this test performs multiple
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// experiments and only complains if all of them consistently fail.
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2015-09-14 15:03:45 -06:00
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func main() {
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2019-01-18 12:06:16 -07:00
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// Sample at 16K instead of default 512K to exercise sampling more heavily.
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runtime.MemProfileRate = 16 * 1024
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2015-09-14 15:03:45 -06:00
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2019-01-18 12:06:16 -07:00
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if err := testInterleavedAllocations(); err != nil {
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panic(err.Error())
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}
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if err := testSmallAllocations(); err != nil {
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panic(err.Error())
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}
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}
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// Repeatedly exercise a set of allocations and check that the heap
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// profile collected by the runtime unsamples to a reasonable
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// value. Because sampling is based on randomization, there can be
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// significant variability on the unsampled data. To account for that,
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// the testcase allows for a 10% margin of error, but only fails if it
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// consistently fails across three experiments, avoiding flakes.
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func testInterleavedAllocations() error {
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const iters = 100000
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// Sizes of the allocations performed by each experiment.
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frames := []string{"main.allocInterleaved1", "main.allocInterleaved2", "main.allocInterleaved3"}
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// Pass if at least one of three experiments has no errors. Use a separate
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// function for each experiment to identify each experiment in the profile.
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allocInterleaved1(iters)
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if checkAllocations(getMemProfileRecords(), frames[0:1], iters, allocInterleavedSizes) == nil {
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// Passed on first try, report no error.
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return nil
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}
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allocInterleaved2(iters)
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if checkAllocations(getMemProfileRecords(), frames[0:2], iters, allocInterleavedSizes) == nil {
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// Passed on second try, report no error.
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return nil
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}
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allocInterleaved3(iters)
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// If it fails a third time, we may be onto something.
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return checkAllocations(getMemProfileRecords(), frames[0:3], iters, allocInterleavedSizes)
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2015-09-14 15:03:45 -06:00
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}
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2019-01-18 12:06:16 -07:00
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var allocInterleavedSizes = []int64{17 * 1024, 1024, 18 * 1024, 512, 16 * 1024, 256}
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// allocInterleaved stress-tests the heap sampling logic by interleaving large and small allocations.
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func allocInterleaved(n int) {
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for i := 0; i < n; i++ {
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// Test verification depends on these lines being contiguous.
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a17k = new([17 * 1024]byte)
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a1k = new([1024]byte)
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a18k = new([18 * 1024]byte)
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a512 = new([512]byte)
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a16k = new([16 * 1024]byte)
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a256 = new([256]byte)
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// Test verification depends on these lines being contiguous.
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}
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}
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func allocInterleaved1(n int) {
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allocInterleaved(n)
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}
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func allocInterleaved2(n int) {
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allocInterleaved(n)
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}
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func allocInterleaved3(n int) {
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allocInterleaved(n)
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}
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// Repeatedly exercise a set of allocations and check that the heap
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// profile collected by the runtime unsamples to a reasonable
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// value. Because sampling is based on randomization, there can be
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// significant variability on the unsampled data. To account for that,
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// the testcase allows for a 10% margin of error, but only fails if it
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// consistently fails across three experiments, avoiding flakes.
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func testSmallAllocations() error {
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const iters = 100000
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// Sizes of the allocations performed by each experiment.
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sizes := []int64{1024, 512, 256}
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frames := []string{"main.allocSmall1", "main.allocSmall2", "main.allocSmall3"}
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// Pass if at least one of three experiments has no errors. Use a separate
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// function for each experiment to identify each experiment in the profile.
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allocSmall1(iters)
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if checkAllocations(getMemProfileRecords(), frames[0:1], iters, sizes) == nil {
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// Passed on first try, report no error.
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return nil
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}
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allocSmall2(iters)
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if checkAllocations(getMemProfileRecords(), frames[0:2], iters, sizes) == nil {
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// Passed on second try, report no error.
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return nil
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2015-09-14 15:03:45 -06:00
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}
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allocSmall3(iters)
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// If it fails a third time, we may be onto something.
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return checkAllocations(getMemProfileRecords(), frames[0:3], iters, sizes)
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2015-09-14 15:03:45 -06:00
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}
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2019-01-18 12:06:16 -07:00
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// allocSmall performs only small allocations for sanity testing.
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func allocSmall(n int) {
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for i := 0; i < n; i++ {
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// Test verification depends on these lines being contiguous.
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a1k = new([1024]byte)
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a512 = new([512]byte)
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a256 = new([256]byte)
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}
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}
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2019-01-18 12:06:16 -07:00
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// Three separate instances of testing to avoid flakes. Will report an error
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// only if they all consistently report failures.
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func allocSmall1(n int) {
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allocSmall(n)
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}
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func allocSmall2(n int) {
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allocSmall(n)
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}
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func allocSmall3(n int) {
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allocSmall(n)
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}
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2015-09-14 15:03:45 -06:00
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// checkAllocations validates that the profile records collected for
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// the named function are consistent with count contiguous allocations
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// of the specified sizes.
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// Check multiple functions and only report consistent failures across
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// multiple tests.
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// Look only at samples that include the named frames, and group the
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// allocations by their line number. All these allocations are done from
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// the same leaf function, so their line numbers are the same.
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func checkAllocations(records []runtime.MemProfileRecord, frames []string, count int64, size []int64) error {
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objectsPerLine := map[int][]int64{}
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bytesPerLine := map[int][]int64{}
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totalCount := []int64{}
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// Compute the line number of the first allocation. All the
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// allocations are from the same leaf, so pick the first one.
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var firstLine int
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for ln := range allocObjects(records, frames[0]) {
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if firstLine == 0 || firstLine > ln {
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firstLine = ln
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}
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}
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for _, frame := range frames {
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var objectCount int64
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a := allocObjects(records, frame)
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for s := range size {
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// Allocations of size size[s] should be on line firstLine + s.
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ln := firstLine + s
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objectsPerLine[ln] = append(objectsPerLine[ln], a[ln].objects)
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bytesPerLine[ln] = append(bytesPerLine[ln], a[ln].bytes)
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objectCount += a[ln].objects
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}
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totalCount = append(totalCount, objectCount)
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}
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for i, w := range size {
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ln := firstLine + i
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if err := checkValue(frames[0], ln, "objects", count, objectsPerLine[ln]); err != nil {
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return err
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}
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if err := checkValue(frames[0], ln, "bytes", count*w, bytesPerLine[ln]); err != nil {
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return err
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}
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}
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return checkValue(frames[0], 0, "total", count*int64(len(size)), totalCount)
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}
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2019-01-18 12:06:16 -07:00
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// checkValue checks an unsampled value against its expected value.
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// Given that this is a sampled value, it will be unexact and will change
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// from run to run. Only report it as a failure if all the values land
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// consistently far from the expected value.
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func checkValue(fname string, ln int, testName string, want int64, got []int64) error {
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if got == nil {
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return fmt.Errorf("Unexpected empty result")
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}
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min, max := got[0], got[0]
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for _, g := range got[1:] {
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if g < min {
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min = g
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}
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if g > max {
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max = g
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}
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}
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margin := want / 10 // 10% margin.
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if min > want+margin || max < want-margin {
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return fmt.Errorf("%s:%d want %s in [%d: %d], got %v", fname, ln, testName, want-margin, want+margin, got)
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}
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return nil
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}
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func getMemProfileRecords() []runtime.MemProfileRecord {
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// Force the runtime to update the object and byte counts.
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// This can take up to two GC cycles to get a complete
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// snapshot of the current point in time.
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runtime.GC()
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runtime.GC()
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// Find out how many records there are (MemProfile(nil, true)),
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// allocate that many records, and get the data.
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// There's a race—more records might be added between
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// the two calls—so allocate a few extra records for safety
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// and also try again if we're very unlucky.
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// The loop should only execute one iteration in the common case.
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var p []runtime.MemProfileRecord
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n, ok := runtime.MemProfile(nil, true)
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for {
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// Allocate room for a slightly bigger profile,
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// in case a few more entries have been added
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// since the call to MemProfile.
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p = make([]runtime.MemProfileRecord, n+50)
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n, ok = runtime.MemProfile(p, true)
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if ok {
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p = p[0:n]
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break
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}
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// Profile grew; try again.
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}
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return p
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}
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type allocStat struct {
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bytes, objects int64
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}
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2019-01-18 12:06:16 -07:00
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// allocObjects examines the profile records for samples including the
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// named function and returns the allocation stats aggregated by
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// source line number of the allocation (at the leaf frame).
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func allocObjects(records []runtime.MemProfileRecord, function string) map[int]allocStat {
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a := make(map[int]allocStat)
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for _, r := range records {
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var pcs []uintptr
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for _, s := range r.Stack0 {
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if s == 0 {
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break
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}
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pcs = append(pcs, s)
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}
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frames := runtime.CallersFrames(pcs)
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line := 0
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for {
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frame, more := frames.Next()
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name := frame.Function
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if line == 0 {
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line = frame.Line
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}
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if name == function {
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allocStat := a[line]
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allocStat.bytes += r.AllocBytes
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allocStat.objects += r.AllocObjects
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a[line] = allocStat
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}
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if !more {
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break
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}
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}
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}
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for line, stats := range a {
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objects, bytes := scaleHeapSample(stats.objects, stats.bytes, int64(runtime.MemProfileRate))
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a[line] = allocStat{bytes, objects}
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}
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return a
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}
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// scaleHeapSample unsamples heap allocations.
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// Taken from src/cmd/pprof/internal/profile/legacy_profile.go
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func scaleHeapSample(count, size, rate int64) (int64, int64) {
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if count == 0 || size == 0 {
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return 0, 0
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}
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if rate <= 1 {
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// if rate==1 all samples were collected so no adjustment is needed.
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// if rate<1 treat as unknown and skip scaling.
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return count, size
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}
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avgSize := float64(size) / float64(count)
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scale := 1 / (1 - math.Exp(-avgSize/float64(rate)))
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return int64(float64(count) * scale), int64(float64(size) * scale)
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}
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