// 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. //go:build aix || darwin || dragonfly || freebsd || linux || netbsd || openbsd || solaris package signal import ( "bytes" "context" "flag" "fmt" "internal/testenv" "os" "os/exec" "runtime" "runtime/trace" "strconv" "strings" "sync" "syscall" "testing" "time" ) // settleTime is an upper bound on how long we expect signals to take to be // delivered. Lower values make the test faster, but also flakier — especially // on heavily loaded systems. // // The current value is set based on flakes observed in the Go builders. var settleTime = 100 * time.Millisecond // fatalWaitingTime is an absurdly long time to wait for signals to be // delivered but, using it, we (hopefully) eliminate test flakes on the // build servers. See #46736 for discussion. var fatalWaitingTime = 30 * time.Second func init() { if testenv.Builder() == "solaris-amd64-oraclerel" { // The solaris-amd64-oraclerel builder has been observed to time out in // TestNohup even with a 250ms settle time. // // Use a much longer settle time on that builder to try to suss out whether // the test is flaky due to builder slowness (which may mean we need a // longer GO_TEST_TIMEOUT_SCALE) or due to a dropped signal (which may // instead need a test-skip and upstream bug filed against the Solaris // kernel). // // This constant is chosen so as to make the test as generous as possible // while still reliably completing within 3 minutes in non-short mode. // // See https://golang.org/issue/33174. settleTime = 11 * time.Second } else if runtime.GOOS == "linux" && strings.HasPrefix(runtime.GOARCH, "ppc64") { // Older linux kernels seem to have some hiccups delivering the signal // in a timely manner on ppc64 and ppc64le. When running on a // ppc64le/ubuntu 16.04/linux 4.4 host the time can vary quite // substantially even on a idle system. 5 seconds is twice any value // observed when running 10000 tests on such a system. settleTime = 5 * time.Second } else if s := os.Getenv("GO_TEST_TIMEOUT_SCALE"); s != "" { if scale, err := strconv.Atoi(s); err == nil { settleTime *= time.Duration(scale) } } } func waitSig(t *testing.T, c <-chan os.Signal, sig os.Signal) { t.Helper() waitSig1(t, c, sig, false) } func waitSigAll(t *testing.T, c <-chan os.Signal, sig os.Signal) { t.Helper() waitSig1(t, c, sig, true) } func waitSig1(t *testing.T, c <-chan os.Signal, sig os.Signal, all bool) { t.Helper() // Sleep multiple times to give the kernel more tries to // deliver the signal. start := time.Now() timer := time.NewTimer(settleTime / 10) defer timer.Stop() // If the caller notified for all signals on c, filter out SIGURG, // which is used for runtime preemption and can come at unpredictable times. // General user code should filter out all unexpected signals instead of just // SIGURG, but since os/signal is tightly coupled to the runtime it seems // appropriate to be stricter here. for time.Since(start) < fatalWaitingTime { select { case s := <-c: if s == sig { return } if !all || s != syscall.SIGURG { t.Fatalf("signal was %v, want %v", s, sig) } case <-timer.C: timer.Reset(settleTime / 10) } } t.Fatalf("timeout after %v waiting for %v", fatalWaitingTime, sig) } // quiesce waits until we can be reasonably confident that all pending signals // have been delivered by the OS. func quiesce() { // The kernel will deliver a signal as a thread returns // from a syscall. If the only active thread is sleeping, // and the system is busy, the kernel may not get around // to waking up a thread to catch the signal. // We try splitting up the sleep to give the kernel // many chances to deliver the signal. start := time.Now() for time.Since(start) < settleTime { time.Sleep(settleTime / 10) } } // Test that basic signal handling works. func TestSignal(t *testing.T) { // Ask for SIGHUP c := make(chan os.Signal, 1) Notify(c, syscall.SIGHUP) defer Stop(c) // Send this process a SIGHUP t.Logf("sighup...") syscall.Kill(syscall.Getpid(), syscall.SIGHUP) waitSig(t, c, syscall.SIGHUP) // Ask for everything we can get. The buffer size has to be // more than 1, since the runtime might send SIGURG signals. // Using 10 is arbitrary. c1 := make(chan os.Signal, 10) Notify(c1) // Stop relaying the SIGURG signals. See #49724 Reset(syscall.SIGURG) defer Stop(c1) // Send this process a SIGWINCH t.Logf("sigwinch...") syscall.Kill(syscall.Getpid(), syscall.SIGWINCH) waitSigAll(t, c1, syscall.SIGWINCH) // Send two more SIGHUPs, to make sure that // they get delivered on c1 and that not reading // from c does not block everything. t.Logf("sighup...") syscall.Kill(syscall.Getpid(), syscall.SIGHUP) waitSigAll(t, c1, syscall.SIGHUP) t.Logf("sighup...") syscall.Kill(syscall.Getpid(), syscall.SIGHUP) waitSigAll(t, c1, syscall.SIGHUP) // The first SIGHUP should be waiting for us on c. waitSig(t, c, syscall.SIGHUP) } func TestStress(t *testing.T) { dur := 3 * time.Second if testing.Short() { dur = 100 * time.Millisecond } defer runtime.GOMAXPROCS(runtime.GOMAXPROCS(4)) sig := make(chan os.Signal, 1) Notify(sig, syscall.SIGUSR1) go func() { stop := time.After(dur) for { select { case <-stop: // Allow enough time for all signals to be delivered before we stop // listening for them. quiesce() Stop(sig) // According to its documentation, “[w]hen Stop returns, it in // guaranteed that c will receive no more signals.” So we can safely // close sig here: if there is a send-after-close race here, that is a // bug in Stop and we would like to detect it. close(sig) return default: syscall.Kill(syscall.Getpid(), syscall.SIGUSR1) runtime.Gosched() } } }() for range sig { // Receive signals until the sender closes sig. } } func testCancel(t *testing.T, ignore bool) { // Ask to be notified on c1 when a SIGWINCH is received. c1 := make(chan os.Signal, 1) Notify(c1, syscall.SIGWINCH) defer Stop(c1) // Ask to be notified on c2 when a SIGHUP is received. c2 := make(chan os.Signal, 1) Notify(c2, syscall.SIGHUP) defer Stop(c2) // Send this process a SIGWINCH and wait for notification on c1. syscall.Kill(syscall.Getpid(), syscall.SIGWINCH) waitSig(t, c1, syscall.SIGWINCH) // Send this process a SIGHUP and wait for notification on c2. syscall.Kill(syscall.Getpid(), syscall.SIGHUP) waitSig(t, c2, syscall.SIGHUP) // Ignore, or reset the signal handlers for, SIGWINCH and SIGHUP. // Either way, this should undo both calls to Notify above. if ignore { Ignore(syscall.SIGWINCH, syscall.SIGHUP) // Don't bother deferring a call to Reset: it is documented to undo Notify, // but its documentation says nothing about Ignore, and (as of the time of // writing) it empirically does not undo an Ignore. } else { Reset(syscall.SIGWINCH, syscall.SIGHUP) } // Send this process a SIGWINCH. It should be ignored. syscall.Kill(syscall.Getpid(), syscall.SIGWINCH) // If ignoring, Send this process a SIGHUP. It should be ignored. if ignore { syscall.Kill(syscall.Getpid(), syscall.SIGHUP) } quiesce() select { case s := <-c1: t.Errorf("unexpected signal %v", s) default: // nothing to read - good } select { case s := <-c2: t.Errorf("unexpected signal %v", s) default: // nothing to read - good } // One or both of the signals may have been blocked for this process // by the calling process. // Discard any queued signals now to avoid interfering with other tests. Notify(c1, syscall.SIGWINCH) Notify(c2, syscall.SIGHUP) quiesce() } // Test that Reset cancels registration for listed signals on all channels. func TestReset(t *testing.T) { testCancel(t, false) } // Test that Ignore cancels registration for listed signals on all channels. func TestIgnore(t *testing.T) { testCancel(t, true) } // Test that Ignored correctly detects changes to the ignored status of a signal. func TestIgnored(t *testing.T) { // Ask to be notified on SIGWINCH. c := make(chan os.Signal, 1) Notify(c, syscall.SIGWINCH) // If we're being notified, then the signal should not be ignored. if Ignored(syscall.SIGWINCH) { t.Errorf("expected SIGWINCH to not be ignored.") } Stop(c) Ignore(syscall.SIGWINCH) // We're no longer paying attention to this signal. if !Ignored(syscall.SIGWINCH) { t.Errorf("expected SIGWINCH to be ignored when explicitly ignoring it.") } Reset() } var checkSighupIgnored = flag.Bool("check_sighup_ignored", false, "if true, TestDetectNohup will fail if SIGHUP is not ignored.") // Test that Ignored(SIGHUP) correctly detects whether it is being run under nohup. func TestDetectNohup(t *testing.T) { if *checkSighupIgnored { if !Ignored(syscall.SIGHUP) { t.Fatal("SIGHUP is not ignored.") } else { t.Log("SIGHUP is ignored.") } } else { defer Reset() // Ugly: ask for SIGHUP so that child will not have no-hup set // even if test is running under nohup environment. // We have no intention of reading from c. c := make(chan os.Signal, 1) Notify(c, syscall.SIGHUP) if out, err := exec.Command(os.Args[0], "-test.run=TestDetectNohup", "-check_sighup_ignored").CombinedOutput(); err == nil { t.Errorf("ran test with -check_sighup_ignored and it succeeded: expected failure.\nOutput:\n%s", out) } Stop(c) // Again, this time with nohup, assuming we can find it. _, err := os.Stat("/usr/bin/nohup") if err != nil { t.Skip("cannot find nohup; skipping second half of test") } Ignore(syscall.SIGHUP) os.Remove("nohup.out") out, err := exec.Command("/usr/bin/nohup", os.Args[0], "-test.run=TestDetectNohup", "-check_sighup_ignored").CombinedOutput() data, _ := os.ReadFile("nohup.out") os.Remove("nohup.out") if err != nil { t.Errorf("ran test with -check_sighup_ignored under nohup and it failed: expected success.\nError: %v\nOutput:\n%s%s", err, out, data) } } } var ( sendUncaughtSighup = flag.Int("send_uncaught_sighup", 0, "send uncaught SIGHUP during TestStop") dieFromSighup = flag.Bool("die_from_sighup", false, "wait to die from uncaught SIGHUP") ) // Test that Stop cancels the channel's registrations. func TestStop(t *testing.T) { sigs := []syscall.Signal{ syscall.SIGWINCH, syscall.SIGHUP, syscall.SIGUSR1, } for _, sig := range sigs { sig := sig t.Run(fmt.Sprint(sig), func(t *testing.T) { // When calling Notify with a specific signal, // independent signals should not interfere with each other, // and we end up needing to wait for signals to quiesce a lot. // Test the three different signals concurrently. t.Parallel() // If the signal is not ignored, send the signal before registering a // channel to verify the behavior of the default Go handler. // If it's SIGWINCH or SIGUSR1 we should not see it. // If it's SIGHUP, maybe we'll die. Let the flag tell us what to do. mayHaveBlockedSignal := false if !Ignored(sig) && (sig != syscall.SIGHUP || *sendUncaughtSighup == 1) { syscall.Kill(syscall.Getpid(), sig) quiesce() // We don't know whether sig is blocked for this process; see // https://golang.org/issue/38165. Assume that it could be. mayHaveBlockedSignal = true } // Ask for signal c := make(chan os.Signal, 1) Notify(c, sig) // Send this process the signal again. syscall.Kill(syscall.Getpid(), sig) waitSig(t, c, sig) if mayHaveBlockedSignal { // We may have received a queued initial signal in addition to the one // that we sent after Notify. If so, waitSig may have observed that // initial signal instead of the second one, and we may need to wait for // the second signal to clear. Do that now. quiesce() select { case <-c: default: } } // Stop watching for the signal and send it again. // If it's SIGHUP, maybe we'll die. Let the flag tell us what to do. Stop(c) if sig != syscall.SIGHUP || *sendUncaughtSighup == 2 { syscall.Kill(syscall.Getpid(), sig) quiesce() select { case s := <-c: t.Errorf("unexpected signal %v", s) default: // nothing to read - good } // If we're going to receive a signal, it has almost certainly been // received by now. However, it may have been blocked for this process — // we don't know. Explicitly unblock it and wait for it to clear now. Notify(c, sig) quiesce() Stop(c) } }) } } // Test that when run under nohup, an uncaught SIGHUP does not kill the program. func TestNohup(t *testing.T) { // Ugly: ask for SIGHUP so that child will not have no-hup set // even if test is running under nohup environment. // We have no intention of reading from c. c := make(chan os.Signal, 1) Notify(c, syscall.SIGHUP) // When run without nohup, the test should crash on an uncaught SIGHUP. // When run under nohup, the test should ignore uncaught SIGHUPs, // because the runtime is not supposed to be listening for them. // Either way, TestStop should still be able to catch them when it wants them // and then when it stops wanting them, the original behavior should resume. // // send_uncaught_sighup=1 sends the SIGHUP before starting to listen for SIGHUPs. // send_uncaught_sighup=2 sends the SIGHUP after no longer listening for SIGHUPs. // // Both should fail without nohup and succeed with nohup. var subTimeout time.Duration var wg sync.WaitGroup wg.Add(2) if deadline, ok := t.Deadline(); ok { subTimeout = time.Until(deadline) subTimeout -= subTimeout / 10 // Leave 10% headroom for propagating output. } for i := 1; i <= 2; i++ { i := i go t.Run(fmt.Sprintf("uncaught-%d", i), func(t *testing.T) { defer wg.Done() args := []string{ "-test.v", "-test.run=TestStop", "-send_uncaught_sighup=" + strconv.Itoa(i), "-die_from_sighup", } if subTimeout != 0 { args = append(args, fmt.Sprintf("-test.timeout=%v", subTimeout)) } out, err := exec.Command(os.Args[0], args...).CombinedOutput() if err == nil { t.Errorf("ran test with -send_uncaught_sighup=%d and it succeeded: expected failure.\nOutput:\n%s", i, out) } else { t.Logf("test with -send_uncaught_sighup=%d failed as expected.\nError: %v\nOutput:\n%s", i, err, out) } }) } wg.Wait() Stop(c) // Skip the nohup test below when running in tmux on darwin, since nohup // doesn't work correctly there. See issue #5135. if runtime.GOOS == "darwin" && os.Getenv("TMUX") != "" { t.Skip("Skipping nohup test due to running in tmux on darwin") } // Again, this time with nohup, assuming we can find it. _, err := exec.LookPath("nohup") if err != nil { t.Skip("cannot find nohup; skipping second half of test") } wg.Add(2) if deadline, ok := t.Deadline(); ok { subTimeout = time.Until(deadline) subTimeout -= subTimeout / 10 // Leave 10% headroom for propagating output. } for i := 1; i <= 2; i++ { i := i go t.Run(fmt.Sprintf("nohup-%d", i), func(t *testing.T) { defer wg.Done() // POSIX specifies that nohup writes to a file named nohup.out if standard // output is a terminal. However, for an exec.Command, standard output is // not a terminal — so we don't need to read or remove that file (and, // indeed, cannot even create it if the current user is unable to write to // GOROOT/src, such as when GOROOT is installed and owned by root). args := []string{ os.Args[0], "-test.v", "-test.run=TestStop", "-send_uncaught_sighup=" + strconv.Itoa(i), } if subTimeout != 0 { args = append(args, fmt.Sprintf("-test.timeout=%v", subTimeout)) } out, err := exec.Command("nohup", args...).CombinedOutput() if err != nil { t.Errorf("ran test with -send_uncaught_sighup=%d under nohup and it failed: expected success.\nError: %v\nOutput:\n%s", i, err, out) } else { t.Logf("ran test with -send_uncaught_sighup=%d under nohup.\nOutput:\n%s", i, out) } }) } wg.Wait() } // Test that SIGCONT works (issue 8953). func TestSIGCONT(t *testing.T) { c := make(chan os.Signal, 1) Notify(c, syscall.SIGCONT) defer Stop(c) syscall.Kill(syscall.Getpid(), syscall.SIGCONT) waitSig(t, c, syscall.SIGCONT) } // Test race between stopping and receiving a signal (issue 14571). func TestAtomicStop(t *testing.T) { if os.Getenv("GO_TEST_ATOMIC_STOP") != "" { atomicStopTestProgram(t) t.Fatal("atomicStopTestProgram returned") } testenv.MustHaveExec(t) // Call Notify for SIGINT before starting the child process. // That ensures that SIGINT is not ignored for the child. // This is necessary because if SIGINT is ignored when a // Go program starts, then it remains ignored, and closing // the last notification channel for SIGINT will switch it // back to being ignored. In that case the assumption of // atomicStopTestProgram, that it will either die from SIGINT // or have it be reported, breaks down, as there is a third // option: SIGINT might be ignored. cs := make(chan os.Signal, 1) Notify(cs, syscall.SIGINT) defer Stop(cs) const execs = 10 for i := 0; i < execs; i++ { timeout := "0" if deadline, ok := t.Deadline(); ok { timeout = time.Until(deadline).String() } cmd := exec.Command(os.Args[0], "-test.run=TestAtomicStop", "-test.timeout="+timeout) cmd.Env = append(os.Environ(), "GO_TEST_ATOMIC_STOP=1") out, err := cmd.CombinedOutput() if err == nil { if len(out) > 0 { t.Logf("iteration %d: output %s", i, out) } } else { t.Logf("iteration %d: exit status %q: output: %s", i, err, out) } lost := bytes.Contains(out, []byte("lost signal")) if lost { t.Errorf("iteration %d: lost signal", i) } // The program should either die due to SIGINT, // or exit with success without printing "lost signal". if err == nil { if len(out) > 0 && !lost { t.Errorf("iteration %d: unexpected output", i) } } else { if ee, ok := err.(*exec.ExitError); !ok { t.Errorf("iteration %d: error (%v) has type %T; expected exec.ExitError", i, err, err) } else if ws, ok := ee.Sys().(syscall.WaitStatus); !ok { t.Errorf("iteration %d: error.Sys (%v) has type %T; expected syscall.WaitStatus", i, ee.Sys(), ee.Sys()) } else if !ws.Signaled() || ws.Signal() != syscall.SIGINT { t.Errorf("iteration %d: got exit status %v; expected SIGINT", i, ee) } } } } // atomicStopTestProgram is run in a subprocess by TestAtomicStop. // It tries to trigger a signal delivery race. This function should // either catch a signal or die from it. func atomicStopTestProgram(t *testing.T) { // This test won't work if SIGINT is ignored here. if Ignored(syscall.SIGINT) { fmt.Println("SIGINT is ignored") os.Exit(1) } const tries = 10 timeout := 2 * time.Second if deadline, ok := t.Deadline(); ok { // Give each try an equal slice of the deadline, with one slice to spare for // cleanup. timeout = time.Until(deadline) / (tries + 1) } pid := syscall.Getpid() printed := false for i := 0; i < tries; i++ { cs := make(chan os.Signal, 1) Notify(cs, syscall.SIGINT) var wg sync.WaitGroup wg.Add(1) go func() { defer wg.Done() Stop(cs) }() syscall.Kill(pid, syscall.SIGINT) // At this point we should either die from SIGINT or // get a notification on cs. If neither happens, we // dropped the signal. It is given 2 seconds to // deliver, as needed for gccgo on some loaded test systems. select { case <-cs: case <-time.After(timeout): if !printed { fmt.Print("lost signal on tries:") printed = true } fmt.Printf(" %d", i) } wg.Wait() } if printed { fmt.Print("\n") } os.Exit(0) } func TestTime(t *testing.T) { // Test that signal works fine when we are in a call to get time, // which on some platforms is using VDSO. See issue #34391. dur := 3 * time.Second if testing.Short() { dur = 100 * time.Millisecond } defer runtime.GOMAXPROCS(runtime.GOMAXPROCS(4)) sig := make(chan os.Signal, 1) Notify(sig, syscall.SIGUSR1) stop := make(chan struct{}) go func() { for { select { case <-stop: // Allow enough time for all signals to be delivered before we stop // listening for them. quiesce() Stop(sig) // According to its documentation, “[w]hen Stop returns, it in // guaranteed that c will receive no more signals.” So we can safely // close sig here: if there is a send-after-close race, that is a bug in // Stop and we would like to detect it. close(sig) return default: syscall.Kill(syscall.Getpid(), syscall.SIGUSR1) runtime.Gosched() } } }() done := make(chan struct{}) go func() { for range sig { // Receive signals until the sender closes sig. } close(done) }() t0 := time.Now() for t1 := t0; t1.Sub(t0) < dur; t1 = time.Now() { } // hammering on getting time close(stop) <-done } var ( checkNotifyContext = flag.Bool("check_notify_ctx", false, "if true, TestNotifyContext will fail if SIGINT is not received.") ctxNotifyTimes = flag.Int("ctx_notify_times", 1, "number of times a SIGINT signal should be received") ) func TestNotifyContextNotifications(t *testing.T) { if *checkNotifyContext { ctx, _ := NotifyContext(context.Background(), syscall.SIGINT) // We want to make sure not to be calling Stop() internally on NotifyContext() when processing a received signal. // Being able to wait for a number of received system signals allows us to do so. var wg sync.WaitGroup n := *ctxNotifyTimes wg.Add(n) for i := 0; i < n; i++ { go func() { syscall.Kill(syscall.Getpid(), syscall.SIGINT) wg.Done() }() } wg.Wait() <-ctx.Done() fmt.Print("received SIGINT") // Sleep to give time to simultaneous signals to reach the process. // These signals must be ignored given stop() is not called on this code. // We want to guarantee a SIGINT doesn't cause a premature termination of the program. time.Sleep(settleTime) return } t.Parallel() testCases := []struct { name string n int // number of times a SIGINT should be notified. }{ {"once", 1}, {"multiple", 10}, } for _, tc := range testCases { t.Run(tc.name, func(t *testing.T) { var subTimeout time.Duration if deadline, ok := t.Deadline(); ok { subTimeout := time.Until(deadline) subTimeout -= subTimeout / 10 // Leave 10% headroom for cleaning up subprocess. } args := []string{ "-test.v", "-test.run=TestNotifyContextNotifications$", "-check_notify_ctx", fmt.Sprintf("-ctx_notify_times=%d", tc.n), } if subTimeout != 0 { args = append(args, fmt.Sprintf("-test.timeout=%v", subTimeout)) } out, err := exec.Command(os.Args[0], args...).CombinedOutput() if err != nil { t.Errorf("ran test with -check_notify_ctx_notification and it failed with %v.\nOutput:\n%s", err, out) } if want := []byte("received SIGINT"); !bytes.Contains(out, want) { t.Errorf("got %q, wanted %q", out, want) } }) } } func TestNotifyContextStop(t *testing.T) { Ignore(syscall.SIGHUP) if !Ignored(syscall.SIGHUP) { t.Errorf("expected SIGHUP to be ignored when explicitly ignoring it.") } parent, cancelParent := context.WithCancel(context.Background()) defer cancelParent() c, stop := NotifyContext(parent, syscall.SIGHUP) defer stop() // If we're being notified, then the signal should not be ignored. if Ignored(syscall.SIGHUP) { t.Errorf("expected SIGHUP to not be ignored.") } if want, got := "signal.NotifyContext(context.Background.WithCancel, [hangup])", fmt.Sprint(c); want != got { t.Errorf("c.String() = %q, wanted %q", got, want) } stop() select { case <-c.Done(): if got := c.Err(); got != context.Canceled { t.Errorf("c.Err() = %q, want %q", got, context.Canceled) } case <-time.After(time.Second): t.Errorf("timed out waiting for context to be done after calling stop") } } func TestNotifyContextCancelParent(t *testing.T) { parent, cancelParent := context.WithCancel(context.Background()) defer cancelParent() c, stop := NotifyContext(parent, syscall.SIGINT) defer stop() if want, got := "signal.NotifyContext(context.Background.WithCancel, [interrupt])", fmt.Sprint(c); want != got { t.Errorf("c.String() = %q, want %q", got, want) } cancelParent() select { case <-c.Done(): if got := c.Err(); got != context.Canceled { t.Errorf("c.Err() = %q, want %q", got, context.Canceled) } case <-time.After(time.Second): t.Errorf("timed out waiting for parent context to be canceled") } } func TestNotifyContextPrematureCancelParent(t *testing.T) { parent, cancelParent := context.WithCancel(context.Background()) defer cancelParent() cancelParent() // Prematurely cancel context before calling NotifyContext. c, stop := NotifyContext(parent, syscall.SIGINT) defer stop() if want, got := "signal.NotifyContext(context.Background.WithCancel, [interrupt])", fmt.Sprint(c); want != got { t.Errorf("c.String() = %q, want %q", got, want) } select { case <-c.Done(): if got := c.Err(); got != context.Canceled { t.Errorf("c.Err() = %q, want %q", got, context.Canceled) } case <-time.After(time.Second): t.Errorf("timed out waiting for parent context to be canceled") } } func TestNotifyContextSimultaneousStop(t *testing.T) { c, stop := NotifyContext(context.Background(), syscall.SIGINT) defer stop() if want, got := "signal.NotifyContext(context.Background, [interrupt])", fmt.Sprint(c); want != got { t.Errorf("c.String() = %q, want %q", got, want) } var wg sync.WaitGroup n := 10 wg.Add(n) for i := 0; i < n; i++ { go func() { stop() wg.Done() }() } wg.Wait() select { case <-c.Done(): if got := c.Err(); got != context.Canceled { t.Errorf("c.Err() = %q, want %q", got, context.Canceled) } case <-time.After(time.Second): t.Errorf("expected context to be canceled") } } func TestNotifyContextStringer(t *testing.T) { parent, cancelParent := context.WithCancel(context.Background()) defer cancelParent() c, stop := NotifyContext(parent, syscall.SIGHUP, syscall.SIGINT, syscall.SIGTERM) defer stop() want := `signal.NotifyContext(context.Background.WithCancel, [hangup interrupt terminated])` if got := fmt.Sprint(c); got != want { t.Errorf("c.String() = %q, want %q", got, want) } } // #44193 test signal handling while stopping and starting the world. func TestSignalTrace(t *testing.T) { done := make(chan struct{}) quit := make(chan struct{}) c := make(chan os.Signal, 1) Notify(c, syscall.SIGHUP) // Source and sink for signals busy loop unsynchronized with // trace starts and stops. We are ultimately validating that // signals and runtime.(stop|start)TheWorldGC are compatible. go func() { defer close(done) defer Stop(c) pid := syscall.Getpid() for { select { case <-quit: return default: syscall.Kill(pid, syscall.SIGHUP) } waitSig(t, c, syscall.SIGHUP) } }() for i := 0; i < 100; i++ { buf := new(bytes.Buffer) if err := trace.Start(buf); err != nil { t.Fatalf("[%d] failed to start tracing: %v", i, err) } time.After(1 * time.Microsecond) trace.Stop() size := buf.Len() if size == 0 { t.Fatalf("[%d] trace is empty", i) } } close(quit) <-done }