/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "mozilla/HangMonitor.h" #include "mozilla/Atomics.h" #include "mozilla/BackgroundHangMonitor.h" #include "mozilla/Monitor.h" #include "mozilla/Preferences.h" #include "mozilla/ProcessedStack.h" #include "mozilla/Telemetry.h" #include "mozilla/StaticPtr.h" #include "mozilla/UniquePtr.h" #include "nsReadableUtils.h" #include "mozilla/StackWalk.h" #include "nsThreadUtils.h" #include "nsXULAppAPI.h" #ifdef MOZ_CRASHREPORTER #include "nsExceptionHandler.h" #endif #ifdef XP_WIN #include #endif #if defined(MOZ_ENABLE_PROFILER_SPS) && defined(MOZ_PROFILING) && defined(XP_WIN) #define REPORT_CHROME_HANGS #endif namespace mozilla { namespace HangMonitor { /** * A flag which may be set from within a debugger to disable the hang * monitor. */ volatile bool gDebugDisableHangMonitor = false; const char kHangMonitorPrefName[] = "hangmonitor.timeout"; #ifdef REPORT_CHROME_HANGS const char kTelemetryPrefName[] = "toolkit.telemetry.enabled"; #endif // Monitor protects gShutdown and gTimeout, but not gTimestamp which rely on // being atomically set by the processor; synchronization doesn't really matter // in this use case. Monitor* gMonitor; // The timeout preference, in seconds. int32_t gTimeout; PRThread* gThread; // Set when shutdown begins to signal the thread to exit immediately. bool gShutdown; // The timestamp of the last event notification, or PR_INTERVAL_NO_WAIT if // we're currently not processing events. Atomic gTimestamp(PR_INTERVAL_NO_WAIT); #ifdef REPORT_CHROME_HANGS // Main thread ID used in reporting chrome hangs under Windows static HANDLE winMainThreadHandle = nullptr; // Default timeout for reporting chrome hangs to Telemetry (5 seconds) static const int32_t DEFAULT_CHROME_HANG_INTERVAL = 5; // Maximum number of PCs to gather from the stack static const int32_t MAX_CALL_STACK_PCS = 400; #endif // PrefChangedFunc void PrefChanged(const char*, void*) { int32_t newval = Preferences::GetInt(kHangMonitorPrefName); #ifdef REPORT_CHROME_HANGS // Monitor chrome hangs on the profiling branch if Telemetry enabled if (newval == 0) { bool telemetryEnabled = Preferences::GetBool(kTelemetryPrefName); if (telemetryEnabled) { newval = DEFAULT_CHROME_HANG_INTERVAL; } } #endif MonitorAutoLock lock(*gMonitor); if (newval != gTimeout) { gTimeout = newval; lock.Notify(); } } void Crash() { if (gDebugDisableHangMonitor) { return; } #ifdef XP_WIN if (::IsDebuggerPresent()) { return; } #endif #ifdef MOZ_CRASHREPORTER CrashReporter::AnnotateCrashReport(NS_LITERAL_CSTRING("Hang"), NS_LITERAL_CSTRING("1")); #endif NS_RUNTIMEABORT("HangMonitor triggered"); } #ifdef REPORT_CHROME_HANGS static void ChromeStackWalker(uint32_t aFrameNumber, void* aPC, void* aSP, void* aClosure) { MOZ_ASSERT(aClosure); std::vector* stack = static_cast*>(aClosure); if (stack->size() == MAX_CALL_STACK_PCS) { return; } MOZ_ASSERT(stack->size() < MAX_CALL_STACK_PCS); stack->push_back(reinterpret_cast(aPC)); } static void GetChromeHangReport(Telemetry::ProcessedStack& aStack, int32_t& aSystemUptime, int32_t& aFirefoxUptime) { MOZ_ASSERT(winMainThreadHandle); // The thread we're about to suspend might have the alloc lock // so allocate ahead of time std::vector rawStack; rawStack.reserve(MAX_CALL_STACK_PCS); DWORD ret = ::SuspendThread(winMainThreadHandle); if (ret == -1) { return; } MozStackWalk(ChromeStackWalker, /* skipFrames */ 0, /* maxFrames */ 0, reinterpret_cast(&rawStack), reinterpret_cast(winMainThreadHandle), nullptr); ret = ::ResumeThread(winMainThreadHandle); if (ret == -1) { return; } aStack = Telemetry::GetStackAndModules(rawStack); // Record system uptime (in minutes) at the time of the hang aSystemUptime = ((GetTickCount() / 1000) - (gTimeout * 2)) / 60; // Record Firefox uptime (in minutes) at the time of the hang bool error; TimeStamp processCreation = TimeStamp::ProcessCreation(error); if (!error) { TimeDuration td = TimeStamp::Now() - processCreation; aFirefoxUptime = (static_cast(td.ToSeconds()) - (gTimeout * 2)) / 60; } else { aFirefoxUptime = -1; } } #endif void ThreadMain(void*) { PR_SetCurrentThreadName("Hang Monitor"); MonitorAutoLock lock(*gMonitor); // In order to avoid issues with the hang monitor incorrectly triggering // during a general system stop such as sleeping, the monitor thread must // run twice to trigger hang protection. PRIntervalTime lastTimestamp = 0; int waitCount = 0; #ifdef REPORT_CHROME_HANGS Telemetry::ProcessedStack stack; int32_t systemUptime = -1; int32_t firefoxUptime = -1; UniquePtr annotations; #endif while (true) { if (gShutdown) { return; // Exit the thread } // avoid rereading the volatile value in this loop PRIntervalTime timestamp = gTimestamp; PRIntervalTime now = PR_IntervalNow(); if (timestamp != PR_INTERVAL_NO_WAIT && now < timestamp) { // 32-bit overflow, reset for another waiting period timestamp = 1; // lowest legal PRInterval value } if (timestamp != PR_INTERVAL_NO_WAIT && timestamp == lastTimestamp && gTimeout > 0) { ++waitCount; #ifdef REPORT_CHROME_HANGS // Capture the chrome-hang stack + Firefox & system uptimes after // the minimum hang duration has been reached (not when the hang ends) if (waitCount == 2) { GetChromeHangReport(stack, systemUptime, firefoxUptime); annotations = ChromeHangAnnotatorCallout(); } #else // This is the crash-on-hang feature. // See bug 867313 for the quirk in the waitCount comparison if (waitCount >= 2) { int32_t delay = int32_t(PR_IntervalToSeconds(now - timestamp)); if (delay >= gTimeout) { MonitorAutoUnlock unlock(*gMonitor); Crash(); } } #endif } else { #ifdef REPORT_CHROME_HANGS if (waitCount >= 2) { uint32_t hangDuration = PR_IntervalToSeconds(now - lastTimestamp); Telemetry::RecordChromeHang(hangDuration, stack, systemUptime, firefoxUptime, Move(annotations)); stack.Clear(); } #endif lastTimestamp = timestamp; waitCount = 0; } PRIntervalTime timeout; if (gTimeout <= 0) { timeout = PR_INTERVAL_NO_TIMEOUT; } else { timeout = PR_MillisecondsToInterval(gTimeout * 500); } lock.Wait(timeout); } } void Startup() { // The hang detector only runs in chrome processes. If you change this, // you must also deal with the threadsafety of AnnotateCrashReport in // non-chrome processes! if (GeckoProcessType_Default != XRE_GetProcessType()) { return; } MOZ_ASSERT(!gMonitor, "Hang monitor already initialized"); gMonitor = new Monitor("HangMonitor"); Preferences::RegisterCallback(PrefChanged, kHangMonitorPrefName, nullptr); PrefChanged(nullptr, nullptr); #ifdef REPORT_CHROME_HANGS Preferences::RegisterCallback(PrefChanged, kTelemetryPrefName, nullptr); winMainThreadHandle = OpenThread(THREAD_ALL_ACCESS, FALSE, GetCurrentThreadId()); if (!winMainThreadHandle) { return; } #endif // Don't actually start measuring hangs until we hit the main event loop. // This potentially misses a small class of really early startup hangs, // but avoids dealing with some xpcshell tests and other situations which // start XPCOM but don't ever start the event loop. Suspend(); gThread = PR_CreateThread(PR_USER_THREAD, ThreadMain, nullptr, PR_PRIORITY_LOW, PR_GLOBAL_THREAD, PR_JOINABLE_THREAD, 0); } void Shutdown() { if (GeckoProcessType_Default != XRE_GetProcessType()) { return; } MOZ_ASSERT(gMonitor, "Hang monitor not started"); { // Scope the lock we're going to delete later MonitorAutoLock lock(*gMonitor); gShutdown = true; lock.Notify(); } // thread creation could theoretically fail if (gThread) { PR_JoinThread(gThread); gThread = nullptr; } delete gMonitor; gMonitor = nullptr; } static bool IsUIMessageWaiting() { #ifndef XP_WIN return false; #else #define NS_WM_IMEFIRST WM_IME_SETCONTEXT #define NS_WM_IMELAST WM_IME_KEYUP BOOL haveUIMessageWaiting = FALSE; MSG msg; haveUIMessageWaiting |= ::PeekMessageW(&msg, nullptr, WM_KEYFIRST, WM_IME_KEYLAST, PM_NOREMOVE); haveUIMessageWaiting |= ::PeekMessageW(&msg, nullptr, NS_WM_IMEFIRST, NS_WM_IMELAST, PM_NOREMOVE); haveUIMessageWaiting |= ::PeekMessageW(&msg, nullptr, WM_MOUSEFIRST, WM_MOUSELAST, PM_NOREMOVE); return haveUIMessageWaiting; #endif } void NotifyActivity(ActivityType aActivityType) { MOZ_ASSERT(NS_IsMainThread(), "HangMonitor::Notify called from off the main thread."); // Determine the activity type more specifically if (aActivityType == kGeneralActivity) { aActivityType = IsUIMessageWaiting() ? kActivityUIAVail : kActivityNoUIAVail; } // Calculate the cumulative amount of lag time since the last UI message static uint32_t cumulativeUILagMS = 0; switch (aActivityType) { case kActivityNoUIAVail: cumulativeUILagMS = 0; break; case kActivityUIAVail: case kUIActivity: if (gTimestamp != PR_INTERVAL_NO_WAIT) { cumulativeUILagMS += PR_IntervalToMilliseconds(PR_IntervalNow() - gTimestamp); } break; default: break; } // This is not a locked activity because PRTimeStamp is a 32-bit quantity // which can be read/written atomically, and we don't want to pay locking // penalties here. gTimestamp = PR_IntervalNow(); // If we have UI activity we should reset the timer and report it if it is // significant enough. if (aActivityType == kUIActivity) { // The minimum amount of lag time that we should report for telemetry data. // Mozilla's UI responsiveness goal is 50ms static const uint32_t kUIResponsivenessThresholdMS = 50; if (cumulativeUILagMS > kUIResponsivenessThresholdMS) { mozilla::Telemetry::Accumulate(mozilla::Telemetry::EVENTLOOP_UI_LAG_EXP_MS, cumulativeUILagMS); } cumulativeUILagMS = 0; } if (gThread && !gShutdown) { mozilla::BackgroundHangMonitor().NotifyActivity(); } } void Suspend() { MOZ_ASSERT(NS_IsMainThread(), "HangMonitor::Suspend called from off the main thread."); // Because gTimestamp changes this resets the wait count. gTimestamp = PR_INTERVAL_NO_WAIT; if (gThread && !gShutdown) { mozilla::BackgroundHangMonitor().NotifyWait(); } } } // namespace HangMonitor } // namespace mozilla