// Copyright 2011 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. // +build !nacl package pprof_test import ( "bytes" "compress/gzip" "fmt" "internal/pprof/profile" "internal/testenv" "io" "io/ioutil" "math/big" "os" "os/exec" "regexp" "runtime" . "runtime/pprof" "strings" "sync" "testing" "time" ) func cpuHogger(f func(), dur time.Duration) { // We only need to get one 100 Hz clock tick, so we've got // a large safety buffer. // But do at least 500 iterations (which should take about 100ms), // otherwise TestCPUProfileMultithreaded can fail if only one // thread is scheduled during the testing period. t0 := time.Now() for i := 0; i < 500 || time.Since(t0) < dur; i++ { f() } } var ( salt1 = 0 salt2 = 0 ) // The actual CPU hogging function. // Must not call other functions nor access heap/globals in the loop, // otherwise under race detector the samples will be in the race runtime. func cpuHog1() { foo := salt1 for i := 0; i < 1e5; i++ { if foo > 0 { foo *= foo } else { foo *= foo + 1 } } salt1 = foo } func cpuHog2() { foo := salt2 for i := 0; i < 1e5; i++ { if foo > 0 { foo *= foo } else { foo *= foo + 2 } } salt2 = foo } func TestCPUProfile(t *testing.T) { testCPUProfile(t, []string{"runtime/pprof_test.cpuHog1"}, func(dur time.Duration) { cpuHogger(cpuHog1, dur) }) } func TestCPUProfileMultithreaded(t *testing.T) { defer runtime.GOMAXPROCS(runtime.GOMAXPROCS(2)) testCPUProfile(t, []string{"runtime/pprof_test.cpuHog1", "runtime/pprof_test.cpuHog2"}, func(dur time.Duration) { c := make(chan int) go func() { cpuHogger(cpuHog1, dur) c <- 1 }() cpuHogger(cpuHog2, dur) <-c }) } func parseProfile(t *testing.T, valBytes []byte, f func(uintptr, []uintptr)) { p, err := profile.Parse(bytes.NewReader(valBytes)) if err != nil { t.Fatal(err) } for _, sample := range p.Sample { count := uintptr(sample.Value[0]) stk := make([]uintptr, len(sample.Location)) for i := range sample.Location { stk[i] = uintptr(sample.Location[i].Address) } f(count, stk) } } func testCPUProfile(t *testing.T, need []string, f func(dur time.Duration)) { switch runtime.GOOS { case "darwin": switch runtime.GOARCH { case "arm", "arm64": // nothing default: out, err := exec.Command("uname", "-a").CombinedOutput() if err != nil { t.Fatal(err) } vers := string(out) t.Logf("uname -a: %v", vers) } case "plan9": t.Skip("skipping on plan9") } const maxDuration = 5 * time.Second // If we're running a long test, start with a long duration // because some of the tests (e.g., TestStackBarrierProfiling) // are trying to make sure something *doesn't* happen. duration := 5 * time.Second if testing.Short() { duration = 200 * time.Millisecond } // Profiling tests are inherently flaky, especially on a // loaded system, such as when this test is running with // several others under go test std. If a test fails in a way // that could mean it just didn't run long enough, try with a // longer duration. for duration <= maxDuration { var prof bytes.Buffer if err := StartCPUProfile(&prof); err != nil { t.Fatal(err) } f(duration) StopCPUProfile() if profileOk(t, need, prof, duration) { return } duration *= 2 if duration <= maxDuration { t.Logf("retrying with %s duration", duration) } } if badOS[runtime.GOOS] { t.Skipf("ignoring failure on %s; see golang.org/issue/13841", runtime.GOOS) return } // Ignore the failure if the tests are running in a QEMU-based emulator, // QEMU is not perfect at emulating everything. // IN_QEMU environmental variable is set by some of the Go builders. // IN_QEMU=1 indicates that the tests are running in QEMU. See issue 9605. if os.Getenv("IN_QEMU") == "1" { t.Skip("ignore the failure in QEMU; see golang.org/issue/9605") return } t.FailNow() } func profileOk(t *testing.T, need []string, prof bytes.Buffer, duration time.Duration) (ok bool) { ok = true // Check that profile is well formed and contains need. have := make([]uintptr, len(need)) var samples uintptr parseProfile(t, prof.Bytes(), func(count uintptr, stk []uintptr) { samples += count for _, pc := range stk { f := runtime.FuncForPC(pc) if f == nil { continue } for i, name := range need { if strings.Contains(f.Name(), name) { have[i] += count } } if strings.Contains(f.Name(), "stackBarrier") { // The runtime should have unwound this. t.Fatalf("profile includes stackBarrier") } } }) t.Logf("total %d CPU profile samples collected", samples) if samples < 10 && runtime.GOOS == "windows" { // On some windows machines we end up with // not enough samples due to coarse timer // resolution. Let it go. t.Log("too few samples on Windows (golang.org/issue/10842)") return false } // Check that we got a reasonable number of samples. // We used to always require at least ideal/4 samples, // but that is too hard to guarantee on a loaded system. // Now we accept 10 or more samples, which we take to be // enough to show that at least some profiling is occurring. if ideal := uintptr(duration * 100 / time.Second); samples == 0 || (samples < ideal/4 && samples < 10) { t.Logf("too few samples; got %d, want at least %d, ideally %d", samples, ideal/4, ideal) ok = false } if len(need) == 0 { return ok } var total uintptr for i, name := range need { total += have[i] t.Logf("%s: %d\n", name, have[i]) } if total == 0 { t.Logf("no samples in expected functions") ok = false } // We'd like to check a reasonable minimum, like // total / len(have) / smallconstant, but this test is // pretty flaky (see bug 7095). So we'll just test to // make sure we got at least one sample. min := uintptr(1) for i, name := range need { if have[i] < min { t.Logf("%s has %d samples out of %d, want at least %d, ideally %d", name, have[i], total, min, total/uintptr(len(have))) ok = false } } return ok } // Fork can hang if preempted with signals frequently enough (see issue 5517). // Ensure that we do not do this. func TestCPUProfileWithFork(t *testing.T) { testenv.MustHaveExec(t) heap := 1 << 30 if runtime.GOOS == "android" { // Use smaller size for Android to avoid crash. heap = 100 << 20 } if testing.Short() { heap = 100 << 20 } // This makes fork slower. garbage := make([]byte, heap) // Need to touch the slice, otherwise it won't be paged in. done := make(chan bool) go func() { for i := range garbage { garbage[i] = 42 } done <- true }() <-done var prof bytes.Buffer if err := StartCPUProfile(&prof); err != nil { t.Fatal(err) } defer StopCPUProfile() for i := 0; i < 10; i++ { exec.Command(os.Args[0], "-h").CombinedOutput() } } // Test that profiler does not observe runtime.gogo as "user" goroutine execution. // If it did, it would see inconsistent state and would either record an incorrect stack // or crash because the stack was malformed. func TestGoroutineSwitch(t *testing.T) { // How much to try. These defaults take about 1 seconds // on a 2012 MacBook Pro. The ones in short mode take // about 0.1 seconds. tries := 10 count := 1000000 if testing.Short() { tries = 1 } for try := 0; try < tries; try++ { var prof bytes.Buffer if err := StartCPUProfile(&prof); err != nil { t.Fatal(err) } for i := 0; i < count; i++ { runtime.Gosched() } StopCPUProfile() // Read profile to look for entries for runtime.gogo with an attempt at a traceback. // The special entry parseProfile(t, prof.Bytes(), func(count uintptr, stk []uintptr) { // An entry with two frames with 'System' in its top frame // exists to record a PC without a traceback. Those are okay. if len(stk) == 2 { f := runtime.FuncForPC(stk[1]) if f != nil && (f.Name() == "runtime._System" || f.Name() == "runtime._ExternalCode" || f.Name() == "runtime._GC") { return } } // Otherwise, should not see runtime.gogo. // The place we'd see it would be the inner most frame. f := runtime.FuncForPC(stk[0]) if f != nil && f.Name() == "runtime.gogo" { var buf bytes.Buffer for _, pc := range stk { f := runtime.FuncForPC(pc) if f == nil { fmt.Fprintf(&buf, "%#x ?:0\n", pc) } else { file, line := f.FileLine(pc) fmt.Fprintf(&buf, "%#x %s:%d\n", pc, file, line) } } t.Fatalf("found profile entry for runtime.gogo:\n%s", buf.String()) } }) } } // Test that profiling of division operations is okay, especially on ARM. See issue 6681. func TestMathBigDivide(t *testing.T) { testCPUProfile(t, nil, func(duration time.Duration) { t := time.After(duration) pi := new(big.Int) for { for i := 0; i < 100; i++ { n := big.NewInt(2646693125139304345) d := big.NewInt(842468587426513207) pi.Div(n, d) } select { case <-t: return default: } } }) } func slurpString(r io.Reader) string { slurp, _ := ioutil.ReadAll(r) return string(slurp) } func getLinuxKernelConfig() string { if f, err := os.Open("/proc/config"); err == nil { defer f.Close() return slurpString(f) } if f, err := os.Open("/proc/config.gz"); err == nil { defer f.Close() r, err := gzip.NewReader(f) if err != nil { return "" } return slurpString(r) } if f, err := os.Open("/boot/config"); err == nil { defer f.Close() return slurpString(f) } uname, _ := exec.Command("uname", "-r").Output() if len(uname) > 0 { if f, err := os.Open("/boot/config-" + strings.TrimSpace(string(uname))); err == nil { defer f.Close() return slurpString(f) } } return "" } func haveLinuxHiresTimers() bool { config := getLinuxKernelConfig() return strings.Contains(config, "CONFIG_HIGH_RES_TIMERS=y") } func TestStackBarrierProfiling(t *testing.T) { if (runtime.GOOS == "linux" && runtime.GOARCH == "arm") || runtime.GOOS == "openbsd" || runtime.GOOS == "solaris" || runtime.GOOS == "dragonfly" || runtime.GOOS == "freebsd" { // This test currently triggers a large number of // usleep(100)s. These kernels/arches have poor // resolution timers, so this gives up a whole // scheduling quantum. On Linux and the BSDs (and // probably Solaris), profiling signals are only // generated when a process completes a whole // scheduling quantum, so this test often gets zero // profiling signals and fails. t.Skipf("low resolution timers inhibit profiling signals (golang.org/issue/13405)") return } if runtime.GOOS == "linux" && strings.HasPrefix(runtime.GOARCH, "mips") { if !haveLinuxHiresTimers() { t.Skipf("low resolution timers inhibit profiling signals (golang.org/issue/13405, golang.org/issue/17936)") } } if !strings.Contains(os.Getenv("GODEBUG"), "gcstackbarrierall=1") { // Re-execute this test with constant GC and stack // barriers at every frame. testenv.MustHaveExec(t) if runtime.GOARCH == "ppc64" || runtime.GOARCH == "ppc64le" { t.Skip("gcstackbarrierall doesn't work on ppc64") } args := []string{"-test.run=TestStackBarrierProfiling"} if testing.Short() { args = append(args, "-test.short") } cmd := exec.Command(os.Args[0], args...) cmd.Env = append([]string{"GODEBUG=gcstackbarrierall=1", "GOGC=1", "GOTRACEBACK=system"}, os.Environ()...) if out, err := cmd.CombinedOutput(); err != nil { t.Fatalf("subprocess failed with %v:\n%s", err, out) } return } testCPUProfile(t, nil, func(duration time.Duration) { // In long mode, we're likely to get one or two // samples in stackBarrier. t := time.After(duration) for { deepStack(1000) select { case <-t: return default: } } }) } var x []byte func deepStack(depth int) int { if depth == 0 { return 0 } x = make([]byte, 1024) return deepStack(depth-1) + 1 } // Operating systems that are expected to fail the tests. See issue 13841. var badOS = map[string]bool{ "darwin": true, "netbsd": true, "plan9": true, "dragonfly": true, "solaris": true, } func TestBlockProfile(t *testing.T) { type TestCase struct { name string f func() re string } tests := [...]TestCase{ {"chan recv", blockChanRecv, ` [0-9]+ [0-9]+ @ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ # 0x[0-9,a-f]+ runtime\.chanrecv1\+0x[0-9,a-f]+ .*/src/runtime/chan.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.blockChanRecv\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.TestBlockProfile\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ `}, {"chan send", blockChanSend, ` [0-9]+ [0-9]+ @ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ # 0x[0-9,a-f]+ runtime\.chansend1\+0x[0-9,a-f]+ .*/src/runtime/chan.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.blockChanSend\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.TestBlockProfile\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ `}, {"chan close", blockChanClose, ` [0-9]+ [0-9]+ @ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ # 0x[0-9,a-f]+ runtime\.chanrecv1\+0x[0-9,a-f]+ .*/src/runtime/chan.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.blockChanClose\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.TestBlockProfile\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ `}, {"select recv async", blockSelectRecvAsync, ` [0-9]+ [0-9]+ @ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ # 0x[0-9,a-f]+ runtime\.selectgo\+0x[0-9,a-f]+ .*/src/runtime/select.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.blockSelectRecvAsync\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.TestBlockProfile\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ `}, {"select send sync", blockSelectSendSync, ` [0-9]+ [0-9]+ @ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ # 0x[0-9,a-f]+ runtime\.selectgo\+0x[0-9,a-f]+ .*/src/runtime/select.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.blockSelectSendSync\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.TestBlockProfile\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ `}, {"mutex", blockMutex, ` [0-9]+ [0-9]+ @ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ # 0x[0-9,a-f]+ sync\.\(\*Mutex\)\.Lock\+0x[0-9,a-f]+ .*/src/sync/mutex\.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.blockMutex\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.TestBlockProfile\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ `}, {"cond", blockCond, ` [0-9]+ [0-9]+ @ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ 0x[0-9,a-f]+ # 0x[0-9,a-f]+ sync\.\(\*Cond\)\.Wait\+0x[0-9,a-f]+ .*/src/sync/cond\.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.blockCond\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ # 0x[0-9,a-f]+ runtime/pprof_test\.TestBlockProfile\+0x[0-9,a-f]+ .*/src/runtime/pprof/pprof_test.go:[0-9]+ `}, } runtime.SetBlockProfileRate(1) defer runtime.SetBlockProfileRate(0) for _, test := range tests { test.f() } var w bytes.Buffer Lookup("block").WriteTo(&w, 1) prof := w.String() if !strings.HasPrefix(prof, "--- contention:\ncycles/second=") { t.Fatalf("Bad profile header:\n%v", prof) } if strings.HasSuffix(prof, "#\t0x0\n\n") { t.Errorf("Useless 0 suffix:\n%v", prof) } for _, test := range tests { if !regexp.MustCompile(strings.Replace(test.re, "\t", "\t+", -1)).MatchString(prof) { t.Fatalf("Bad %v entry, expect:\n%v\ngot:\n%v", test.name, test.re, prof) } } } const blockDelay = 10 * time.Millisecond func blockChanRecv() { c := make(chan bool) go func() { time.Sleep(blockDelay) c <- true }() <-c } func blockChanSend() { c := make(chan bool) go func() { time.Sleep(blockDelay) <-c }() c <- true } func blockChanClose() { c := make(chan bool) go func() { time.Sleep(blockDelay) close(c) }() <-c } func blockSelectRecvAsync() { const numTries = 3 c := make(chan bool, 1) c2 := make(chan bool, 1) go func() { for i := 0; i < numTries; i++ { time.Sleep(blockDelay) c <- true } }() for i := 0; i < numTries; i++ { select { case <-c: case <-c2: } } } func blockSelectSendSync() { c := make(chan bool) c2 := make(chan bool) go func() { time.Sleep(blockDelay) <-c }() select { case c <- true: case c2 <- true: } } func blockMutex() { var mu sync.Mutex mu.Lock() go func() { time.Sleep(blockDelay) mu.Unlock() }() mu.Lock() } func blockCond() { var mu sync.Mutex c := sync.NewCond(&mu) mu.Lock() go func() { time.Sleep(blockDelay) mu.Lock() c.Signal() mu.Unlock() }() c.Wait() mu.Unlock() } func TestMutexProfile(t *testing.T) { old := runtime.SetMutexProfileFraction(1) defer runtime.SetMutexProfileFraction(old) if old != 0 { t.Fatalf("need MutexProfileRate 0, got %d", old) } blockMutex() var w bytes.Buffer Lookup("mutex").WriteTo(&w, 1) prof := w.String() if !strings.HasPrefix(prof, "--- mutex:\ncycles/second=") { t.Errorf("Bad profile header:\n%v", prof) } prof = strings.Trim(prof, "\n") lines := strings.Split(prof, "\n") if len(lines) != 6 { t.Errorf("expected 6 lines, got %d %q\n%s", len(lines), prof, prof) } if len(lines) < 6 { return } // checking that the line is like "35258904 1 @ 0x48288d 0x47cd28 0x458931" r2 := `^\d+ 1 @(?: 0x[[:xdigit:]]+)+` //r2 := "^[0-9]+ 1 @ 0x[0-9a-f x]+$" if ok, err := regexp.MatchString(r2, lines[3]); err != nil || !ok { t.Errorf("%q didn't match %q", lines[3], r2) } r3 := "^#.*runtime/pprof_test.blockMutex.*$" if ok, err := regexp.MatchString(r3, lines[5]); err != nil || !ok { t.Errorf("%q didn't match %q", lines[5], r3) } } func func1(c chan int) { <-c } func func2(c chan int) { <-c } func func3(c chan int) { <-c } func func4(c chan int) { <-c } func TestGoroutineCounts(t *testing.T) { if runtime.GOOS == "openbsd" { testenv.SkipFlaky(t, 15156) } c := make(chan int) for i := 0; i < 100; i++ { if i%10 == 0 { go func1(c) continue } if i%2 == 0 { go func2(c) continue } go func3(c) } time.Sleep(10 * time.Millisecond) // let goroutines block on channel var w bytes.Buffer goroutineProf := Lookup("goroutine") // Check debug profile goroutineProf.WriteTo(&w, 1) prof := w.String() if !containsInOrder(prof, "\n50 @ ", "\n40 @", "\n10 @", "\n1 @") { t.Errorf("expected sorted goroutine counts:\n%s", prof) } // Check proto profile w.Reset() goroutineProf.WriteTo(&w, 0) p, err := profile.Parse(&w) if err != nil { t.Errorf("error parsing protobuf profile: %v", err) } if err := p.CheckValid(); err != nil { t.Errorf("protobuf profile is invalid: %v", err) } if !containsCounts(p, []int64{50, 40, 10, 1}) { t.Errorf("expected count profile to contain goroutines with counts %v, got %v", []int64{50, 40, 10, 1}, p) } close(c) time.Sleep(10 * time.Millisecond) // let goroutines exit } func containsInOrder(s string, all ...string) bool { for _, t := range all { i := strings.Index(s, t) if i < 0 { return false } s = s[i+len(t):] } return true } func containsCounts(prof *profile.Profile, counts []int64) bool { m := make(map[int64]int) for _, c := range counts { m[c]++ } for _, s := range prof.Sample { // The count is the single value in the sample if len(s.Value) != 1 { return false } m[s.Value[0]]-- } for _, n := range m { if n > 0 { return false } } return true }