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// Copyright 2023 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 trace_test
import (
"bufio"
"bytes"
"fmt"
"internal/race"
"internal/testenv"
"internal/trace/v2"
"internal/trace/v2/testtrace"
"io"
"os"
"path/filepath"
"runtime"
"strings"
"testing"
)
func TestTraceAnnotations(t *testing.T) {
testTraceProg(t, "annotations.go", func(t *testing.T, tb, _ []byte, _ bool) {
type evDesc struct {
kind trace.EventKind
task trace.TaskID
args []string
}
want := []evDesc{
{trace.EventTaskBegin, trace.TaskID(1), []string{"task0"}},
{trace.EventRegionBegin, trace.TaskID(1), []string{"region0"}},
{trace.EventRegionBegin, trace.TaskID(1), []string{"region1"}},
{trace.EventLog, trace.TaskID(1), []string{"key0", "0123456789abcdef"}},
{trace.EventRegionEnd, trace.TaskID(1), []string{"region1"}},
{trace.EventRegionEnd, trace.TaskID(1), []string{"region0"}},
{trace.EventTaskEnd, trace.TaskID(1), []string{"task0"}},
// Currently, pre-existing region is not recorded to avoid allocations.
{trace.EventRegionBegin, trace.BackgroundTask, []string{"post-existing region"}},
}
r, err := trace.NewReader(bytes.NewReader(tb))
if err != nil {
t.Error(err)
}
for {
ev, err := r.ReadEvent()
if err == io.EOF {
break
}
if err != nil {
t.Fatal(err)
}
for i, wantEv := range want {
if wantEv.kind != ev.Kind() {
continue
}
match := false
switch ev.Kind() {
case trace.EventTaskBegin, trace.EventTaskEnd:
task := ev.Task()
match = task.ID == wantEv.task && task.Type == wantEv.args[0]
case trace.EventRegionBegin, trace.EventRegionEnd:
reg := ev.Region()
match = reg.Task == wantEv.task && reg.Type == wantEv.args[0]
case trace.EventLog:
log := ev.Log()
match = log.Task == wantEv.task && log.Category == wantEv.args[0] && log.Message == wantEv.args[1]
}
if match {
want[i] = want[len(want)-1]
want = want[:len(want)-1]
break
}
}
}
if len(want) != 0 {
for _, ev := range want {
t.Errorf("no match for %s TaskID=%d Args=%#v", ev.kind, ev.task, ev.args)
}
}
})
}
func TestTraceAnnotationsStress(t *testing.T) {
testTraceProg(t, "annotations-stress.go", nil)
}
func TestTraceCgoCallback(t *testing.T) {
testenv.MustHaveCGO(t)
switch runtime.GOOS {
case "plan9", "windows":
t.Skipf("cgo callback test requires pthreads and is not supported on %s", runtime.GOOS)
}
testTraceProg(t, "cgo-callback.go", nil)
}
func TestTraceCPUProfile(t *testing.T) {
testTraceProg(t, "cpu-profile.go", func(t *testing.T, tb, stderr []byte, _ bool) {
// Parse stderr which has a CPU profile summary, if everything went well.
// (If it didn't, we shouldn't even make it here.)
scanner := bufio.NewScanner(bytes.NewReader(stderr))
pprofSamples := 0
pprofStacks := make(map[string]int)
for scanner.Scan() {
var stack string
var samples int
_, err := fmt.Sscanf(scanner.Text(), "%s\t%d", &stack, &samples)
if err != nil {
t.Fatalf("failed to parse CPU profile summary in stderr: %s\n\tfull:\n%s", scanner.Text(), stderr)
}
pprofStacks[stack] = samples
pprofSamples += samples
}
if err := scanner.Err(); err != nil {
t.Fatalf("failed to parse CPU profile summary in stderr: %v", err)
}
if pprofSamples == 0 {
t.Skip("CPU profile did not include any samples while tracing was active")
}
// Examine the execution tracer's view of the CPU profile samples. Filter it
// to only include samples from the single test goroutine. Use the goroutine
// ID that was recorded in the events: that should reflect getg().m.curg,
// same as the profiler's labels (even when the M is using its g0 stack).
totalTraceSamples := 0
traceSamples := 0
traceStacks := make(map[string]int)
r, err := trace.NewReader(bytes.NewReader(tb))
if err != nil {
t.Error(err)
}
var hogRegion *trace.Event
var hogRegionClosed bool
for {
ev, err := r.ReadEvent()
if err == io.EOF {
break
}
if err != nil {
t.Fatal(err)
}
if ev.Kind() == trace.EventRegionBegin && ev.Region().Type == "cpuHogger" {
hogRegion = &ev
}
if ev.Kind() == trace.EventStackSample {
totalTraceSamples++
if hogRegion != nil && ev.Goroutine() == hogRegion.Goroutine() {
traceSamples++
var fns []string
ev.Stack().Frames(func(frame trace.StackFrame) bool {
if frame.Func != "runtime.goexit" {
fns = append(fns, fmt.Sprintf("%s:%d", frame.Func, frame.Line))
}
return true
})
stack := strings.Join(fns, "|")
traceStacks[stack]++
}
}
if ev.Kind() == trace.EventRegionEnd && ev.Region().Type == "cpuHogger" {
hogRegionClosed = true
}
}
if hogRegion == nil {
t.Fatalf("execution trace did not identify cpuHogger goroutine")
} else if !hogRegionClosed {
t.Fatalf("execution trace did not close cpuHogger region")
}
// The execution trace may drop CPU profile samples if the profiling buffer
// overflows. Based on the size of profBufWordCount, that takes a bit over
// 1900 CPU samples or 19 thread-seconds at a 100 Hz sample rate. If we've
// hit that case, then we definitely have at least one full buffer's worth
// of CPU samples, so we'll call that success.
overflowed := totalTraceSamples >= 1900
if traceSamples < pprofSamples {
t.Logf("execution trace did not include all CPU profile samples; %d in profile, %d in trace", pprofSamples, traceSamples)
if !overflowed {
t.Fail()
}
}
for stack, traceSamples := range traceStacks {
pprofSamples := pprofStacks[stack]
delete(pprofStacks, stack)
if traceSamples < pprofSamples {
t.Logf("execution trace did not include all CPU profile samples for stack %q; %d in profile, %d in trace",
stack, pprofSamples, traceSamples)
if !overflowed {
t.Fail()
}
}
}
for stack, pprofSamples := range pprofStacks {
t.Logf("CPU profile included %d samples at stack %q not present in execution trace", pprofSamples, stack)
if !overflowed {
t.Fail()
}
}
if t.Failed() {
t.Logf("execution trace CPU samples:")
for stack, samples := range traceStacks {
t.Logf("%d: %q", samples, stack)
}
t.Logf("CPU profile:\n%s", stderr)
}
})
}
func TestTraceFutileWakeup(t *testing.T) {
testTraceProg(t, "futile-wakeup.go", func(t *testing.T, tb, _ []byte, _ bool) {
// Check to make sure that no goroutine in the "special" trace region
// ends up blocking, unblocking, then immediately blocking again.
//
// The goroutines are careful to call runtime.Gosched in between blocking,
// so there should never be a clean block/unblock on the goroutine unless
// the runtime was generating extraneous events.
const (
entered = iota
blocked
runnable
running
)
gs := make(map[trace.GoID]int)
seenSpecialGoroutines := false
r, err := trace.NewReader(bytes.NewReader(tb))
if err != nil {
t.Error(err)
}
for {
ev, err := r.ReadEvent()
if err == io.EOF {
break
}
if err != nil {
t.Fatal(err)
}
// Only track goroutines in the special region we control, so runtime
// goroutines don't interfere (it's totally valid in traces for a
// goroutine to block, run, and block again; that's not what we care about).
if ev.Kind() == trace.EventRegionBegin && ev.Region().Type == "special" {
seenSpecialGoroutines = true
gs[ev.Goroutine()] = entered
}
if ev.Kind() == trace.EventRegionEnd && ev.Region().Type == "special" {
delete(gs, ev.Goroutine())
}
// Track state transitions for goroutines we care about.
//
// The goroutines we care about will advance through the state machine
// of entered -> blocked -> runnable -> running. If in the running state
// we block, then we have a futile wakeup. Because of the runtime.Gosched
// on these specially marked goroutines, we should end up back in runnable
// first. If at any point we go to a different state, switch back to entered
// and wait for the next time the goroutine blocks.
if ev.Kind() != trace.EventStateTransition {
continue
}
st := ev.StateTransition()
if st.Resource.Kind != trace.ResourceGoroutine {
continue
}
id := st.Resource.Goroutine()
state, ok := gs[id]
if !ok {
continue
}
_, new := st.Goroutine()
switch state {
case entered:
if new == trace.GoWaiting {
state = blocked
} else {
state = entered
}
case blocked:
if new == trace.GoRunnable {
state = runnable
} else {
state = entered
}
case runnable:
if new == trace.GoRunning {
state = running
} else {
state = entered
}
case running:
if new == trace.GoWaiting {
t.Fatalf("found futile wakeup on goroutine %d", id)
} else {
state = entered
}
}
gs[id] = state
}
if !seenSpecialGoroutines {
t.Fatal("did not see a goroutine in a the region 'special'")
}
})
}
func TestTraceGCStress(t *testing.T) {
testTraceProg(t, "gc-stress.go", nil)
}
func TestTraceGOMAXPROCS(t *testing.T) {
testTraceProg(t, "gomaxprocs.go", nil)
}
func TestTraceStacks(t *testing.T) {
testTraceProg(t, "stacks.go", func(t *testing.T, tb, _ []byte, stress bool) {
type frame struct {
fn string
line int
}
type evDesc struct {
kind trace.EventKind
match string
frames []frame
}
// mainLine is the line number of `func main()` in testprog/stacks.go.
const mainLine = 21
want := []evDesc{
{trace.EventStateTransition, "Goroutine Running->Runnable", []frame{
{"main.main", mainLine + 82},
}},
{trace.EventStateTransition, "Goroutine NotExist->Runnable", []frame{
{"main.main", mainLine + 11},
}},
{trace.EventStateTransition, "Goroutine Running->Waiting", []frame{
{"runtime.block", 0},
{"main.main.func1", 0},
}},
{trace.EventStateTransition, "Goroutine Running->Waiting", []frame{
{"runtime.chansend1", 0},
{"main.main.func2", 0},
}},
{trace.EventStateTransition, "Goroutine Running->Waiting", []frame{
{"runtime.chanrecv1", 0},
{"main.main.func3", 0},
}},
{trace.EventStateTransition, "Goroutine Running->Waiting", []frame{
{"runtime.chanrecv1", 0},
{"main.main.func4", 0},
}},
{trace.EventStateTransition, "Goroutine Waiting->Runnable", []frame{
{"runtime.chansend1", 0},
{"main.main", mainLine + 84},
}},
{trace.EventStateTransition, "Goroutine Running->Waiting", []frame{
{"runtime.chansend1", 0},
{"main.main.func5", 0},
}},
{trace.EventStateTransition, "Goroutine Waiting->Runnable", []frame{
{"runtime.chanrecv1", 0},
{"main.main", mainLine + 85},
}},
{trace.EventStateTransition, "Goroutine Running->Waiting", []frame{
{"runtime.selectgo", 0},
{"main.main.func6", 0},
}},
{trace.EventStateTransition, "Goroutine Waiting->Runnable", []frame{
{"runtime.selectgo", 0},
{"main.main", mainLine + 86},
}},
{trace.EventStateTransition, "Goroutine Running->Waiting", []frame{
{"sync.(*Mutex).Lock", 0},
{"main.main.func7", 0},
}},
{trace.EventStateTransition, "Goroutine Waiting->Runnable", []frame{
{"sync.(*Mutex).Unlock", 0},
{"main.main", 0},
}},
{trace.EventStateTransition, "Goroutine Running->Waiting", []frame{
{"sync.(*WaitGroup).Wait", 0},
{"main.main.func8", 0},
}},
{trace.EventStateTransition, "Goroutine Waiting->Runnable", []frame{
{"sync.(*WaitGroup).Add", 0},
{"sync.(*WaitGroup).Done", 0},
{"main.main", mainLine + 91},
}},
{trace.EventStateTransition, "Goroutine Running->Waiting", []frame{
{"sync.(*Cond).Wait", 0},
{"main.main.func9", 0},
}},
{trace.EventStateTransition, "Goroutine Waiting->Runnable", []frame{
{"sync.(*Cond).Signal", 0},
{"main.main", 0},
}},
{trace.EventStateTransition, "Goroutine Running->Waiting", []frame{
{"time.Sleep", 0},
{"main.main", 0},
}},
{trace.EventMetric, "/sched/gomaxprocs:threads", []frame{
{"runtime.startTheWorld", 0}, // this is when the current gomaxprocs is logged.
{"runtime.startTheWorldGC", 0},
{"runtime.GOMAXPROCS", 0},
{"main.main", 0},
}},
}
if !stress {
// Only check for this stack if !stress because traceAdvance alone could
// allocate enough memory to trigger a GC if called frequently enough.
// This might cause the runtime.GC call we're trying to match against to
// coalesce with an active GC triggered this by traceAdvance. In that case
// we won't have an EventRangeBegin event that matches the stace trace we're
// looking for, since runtime.GC will not have triggered the GC.
gcEv := evDesc{trace.EventRangeBegin, "GC concurrent mark phase", []frame{
{"runtime.GC", 0},
{"main.main", 0},
}}
want = append(want, gcEv)
}
if runtime.GOOS != "windows" && runtime.GOOS != "plan9" {
want = append(want, []evDesc{
{trace.EventStateTransition, "Goroutine Running->Waiting", []frame{
{"internal/poll.(*FD).Accept", 0},
{"net.(*netFD).accept", 0},
{"net.(*TCPListener).accept", 0},
{"net.(*TCPListener).Accept", 0},
{"main.main.func10", 0},
}},
{trace.EventStateTransition, "Goroutine Running->Syscall", []frame{
{"syscall.read", 0},
{"syscall.Read", 0},
{"internal/poll.ignoringEINTRIO", 0},
{"internal/poll.(*FD).Read", 0},
{"os.(*File).read", 0},
{"os.(*File).Read", 0},
{"main.main.func11", 0},
}},
}...)
}
stackMatches := func(stk trace.Stack, frames []frame) bool {
i := 0
match := true
stk.Frames(func(f trace.StackFrame) bool {
if f.Func != frames[i].fn {
match = false
return false
}
if line := uint64(frames[i].line); line != 0 && line != f.Line {
match = false
return false
}
i++
return true
})
return match
}
r, err := trace.NewReader(bytes.NewReader(tb))
if err != nil {
t.Error(err)
}
for {
ev, err := r.ReadEvent()
if err == io.EOF {
break
}
if err != nil {
t.Fatal(err)
}
for i, wantEv := range want {
if wantEv.kind != ev.Kind() {
continue
}
match := false
switch ev.Kind() {
case trace.EventStateTransition:
st := ev.StateTransition()
str := ""
switch st.Resource.Kind {
case trace.ResourceGoroutine:
old, new := st.Goroutine()
str = fmt.Sprintf("%s %s->%s", st.Resource.Kind, old, new)
}
match = str == wantEv.match
case trace.EventRangeBegin:
rng := ev.Range()
match = rng.Name == wantEv.match
case trace.EventMetric:
metric := ev.Metric()
match = metric.Name == wantEv.match
}
match = match && stackMatches(ev.Stack(), wantEv.frames)
if match {
want[i] = want[len(want)-1]
want = want[:len(want)-1]
break
}
}
}
if len(want) != 0 {
for _, ev := range want {
t.Errorf("no match for %s Match=%s Stack=%#v", ev.kind, ev.match, ev.frames)
}
}
})
}
func TestTraceStress(t *testing.T) {
switch runtime.GOOS {
case "js", "wasip1":
t.Skip("no os.Pipe on " + runtime.GOOS)
}
testTraceProg(t, "stress.go", nil)
}
func TestTraceStressStartStop(t *testing.T) {
switch runtime.GOOS {
case "js", "wasip1":
t.Skip("no os.Pipe on " + runtime.GOOS)
}
testTraceProg(t, "stress-start-stop.go", nil)
}
func TestTraceManyStartStop(t *testing.T) {
testTraceProg(t, "many-start-stop.go", nil)
}
func TestTraceWaitOnPipe(t *testing.T) {
switch runtime.GOOS {
case "dragonfly", "freebsd", "linux", "netbsd", "openbsd", "solaris":
testTraceProg(t, "wait-on-pipe.go", nil)
return
}
t.Skip("no applicable syscall.Pipe on " + runtime.GOOS)
}
func TestTraceIterPull(t *testing.T) {
testTraceProg(t, "iter-pull.go", nil)
}
func testTraceProg(t *testing.T, progName string, extra func(t *testing.T, trace, stderr []byte, stress bool)) {
testenv.MustHaveGoRun(t)
// Check if we're on a builder.
onBuilder := testenv.Builder() != ""
onOldBuilder := !strings.Contains(testenv.Builder(), "gotip") && !strings.Contains(testenv.Builder(), "go1")
testPath := filepath.Join("./testdata/testprog", progName)
testName := progName
runTest := func(t *testing.T, stress bool, extraGODEBUG string) {
// Run the program and capture the trace, which is always written to stdout.
cmd := testenv.Command(t, testenv.GoToolPath(t), "run")
if race.Enabled {
cmd.Args = append(cmd.Args, "-race")
}
cmd.Args = append(cmd.Args, testPath)
cmd.Env = append(os.Environ(), "GOEXPERIMENT=rangefunc")
// Add a stack ownership check. This is cheap enough for testing.
godebug := "tracecheckstackownership=1"
if stress {
// Advance a generation constantly to stress the tracer.
godebug += ",traceadvanceperiod=0"
}
if extraGODEBUG != "" {
// Add extra GODEBUG flags.
godebug += "," + extraGODEBUG
}
cmd.Env = append(cmd.Env, "GODEBUG="+godebug)
// Capture stdout and stderr.
//
// The protocol for these programs is that stdout contains the trace data
// and stderr is an expectation in string format.
var traceBuf, errBuf bytes.Buffer
cmd.Stdout = &traceBuf
cmd.Stderr = &errBuf
// Run the program.
if err := cmd.Run(); err != nil {
if errBuf.Len() != 0 {
t.Logf("stderr: %s", string(errBuf.Bytes()))
}
t.Fatal(err)
}
tb := traceBuf.Bytes()
// Test the trace and the parser.
testReader(t, bytes.NewReader(tb), testtrace.ExpectSuccess())
// Run some extra validation.
if !t.Failed() && extra != nil {
extra(t, tb, errBuf.Bytes(), stress)
}
// Dump some more information on failure.
if t.Failed() && onBuilder {
// Dump directly to the test log on the builder, since this
// data is critical for debugging and this is the only way
// we can currently make sure it's retained.
t.Log("found bad trace; dumping to test log...")
s := dumpTraceToText(t, tb)
if onOldBuilder && len(s) > 1<<20+512<<10 {
// The old build infrastructure truncates logs at ~2 MiB.
// Let's assume we're the only failure and give ourselves
// up to 1.5 MiB to dump the trace.
//
// TODO(mknyszek): Remove this when we've migrated off of
// the old infrastructure.
t.Logf("text trace too large to dump (%d bytes)", len(s))
} else {
t.Log(s)
}
} else if t.Failed() || *dumpTraces {
// We asked to dump the trace or failed. Write the trace to a file.
t.Logf("wrote trace to file: %s", dumpTraceToFile(t, testName, stress, tb))
}
}
t.Run("Default", func(t *testing.T) {
runTest(t, false, "")
})
t.Run("Stress", func(t *testing.T) {
if testing.Short() {
t.Skip("skipping trace stress tests in short mode")
}
runTest(t, true, "")
})
t.Run("AllocFree", func(t *testing.T) {
if testing.Short() {
t.Skip("skipping trace alloc/free tests in short mode")
}
runTest(t, false, "traceallocfree=1")
})
}