gecko-dev/xpcom/threads/BackgroundHangMonitor.cpp

757 строки
24 KiB
C++

/* -*- 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/ArrayUtils.h"
#include "mozilla/BackgroundHangMonitor.h"
#include "mozilla/LinkedList.h"
#include "mozilla/Monitor.h"
#include "mozilla/Move.h"
#include "mozilla/Preferences.h"
#include "mozilla/StaticPtr.h"
#include "mozilla/Telemetry.h"
#include "mozilla/ThreadHangStats.h"
#include "mozilla/ThreadLocal.h"
#include "prinrval.h"
#include "prthread.h"
#include "ThreadStackHelper.h"
#include "nsIObserverService.h"
#include "nsIObserver.h"
#include "mozilla/Services.h"
#include "nsThreadUtils.h"
#include "nsXULAppAPI.h"
#include "GeckoProfiler.h"
#include <algorithm>
// Activate BHR only for one every BHR_BETA_MOD users.
// This is now 100% of Beta population for the Beta 45/46 e10s A/B trials
// It can be scaled back again in the future
#define BHR_BETA_MOD 1;
// This variable controls the maximum number of native hang stacks which may be
// attached to a ping. This is due to how large native stacks can be. We want to
// reduce the chance of a ping being discarded due to it exceeding the maximum
// ping size.
static const uint32_t kMaximumNativeHangStacks = 300;
// Maximum depth of the call stack in the reported thread hangs. This value represents
// the 99.9th percentile of the thread hangs stack depths reported by Telemetry.
static const size_t kMaxThreadHangStackDepth = 30;
// An utility comparator function used by std::unique to collapse "(* script)" entries in
// a vector representing a call stack.
bool StackScriptEntriesCollapser(const char* aStackEntry, const char *aAnotherStackEntry)
{
return !strcmp(aStackEntry, aAnotherStackEntry) &&
(!strcmp(aStackEntry, "(chrome script)") || !strcmp(aStackEntry, "(content script)"));
}
namespace mozilla {
/**
* BackgroundHangManager is the global object that
* manages all instances of BackgroundHangThread.
*/
class BackgroundHangManager : public nsIObserver
{
private:
// Background hang monitor thread function
static void MonitorThread(void* aData)
{
AutoProfilerRegister registerThread("BgHangMonitor");
NS_SetCurrentThreadName("BgHangManager");
/* We do not hold a reference to BackgroundHangManager here
because the monitor thread only exists as long as the
BackgroundHangManager instance exists. We stop the monitor
thread in the BackgroundHangManager destructor, and we can
only get to the destructor if we don't hold a reference here. */
static_cast<BackgroundHangManager*>(aData)->RunMonitorThread();
}
// Hang monitor thread
PRThread* mHangMonitorThread;
// Stop hang monitoring
bool mShutdown;
BackgroundHangManager(const BackgroundHangManager&);
BackgroundHangManager& operator=(const BackgroundHangManager&);
void RunMonitorThread();
public:
NS_DECL_THREADSAFE_ISUPPORTS
NS_DECL_NSIOBSERVER
static StaticRefPtr<BackgroundHangManager> sInstance;
static bool sDisabled;
// Lock for access to members of this class
Monitor mLock;
// Current time as seen by hang monitors
PRIntervalTime mIntervalNow;
// List of BackgroundHangThread instances associated with each thread
LinkedList<BackgroundHangThread> mHangThreads;
void Shutdown()
{
MonitorAutoLock autoLock(mLock);
mShutdown = true;
autoLock.Notify();
}
// Attempt to wakeup the hang monitor thread.
void Wakeup()
{
mLock.AssertCurrentThreadOwns();
mLock.NotifyAll();
}
BackgroundHangManager();
private:
virtual ~BackgroundHangManager();
};
NS_IMPL_ISUPPORTS(BackgroundHangManager, nsIObserver)
NS_IMETHODIMP
BackgroundHangManager::Observe(nsISupports* aSubject, const char* aTopic, const char16_t* aData) {
NS_ENSURE_TRUE(!strcmp(aTopic, "profile-after-change"), NS_ERROR_UNEXPECTED);
BackgroundHangMonitor::DisableOnBeta();
nsCOMPtr<nsIObserverService> observerService = mozilla::services::GetObserverService();
MOZ_ASSERT(observerService);
observerService->RemoveObserver(this, "profile-after-change");
return NS_OK;
}
/**
* BackgroundHangThread is a per-thread object that is used
* by all instances of BackgroundHangMonitor to monitor hangs.
*/
class BackgroundHangThread : public LinkedListElement<BackgroundHangThread>
{
private:
static MOZ_THREAD_LOCAL(BackgroundHangThread*) sTlsKey;
static bool sTlsKeyInitialized;
BackgroundHangThread(const BackgroundHangThread&);
BackgroundHangThread& operator=(const BackgroundHangThread&);
~BackgroundHangThread();
/* Keep a reference to the manager, so we can keep going even
after BackgroundHangManager::Shutdown is called. */
const RefPtr<BackgroundHangManager> mManager;
// Unique thread ID for identification
const PRThread* mThreadID;
void Update();
public:
NS_INLINE_DECL_REFCOUNTING(BackgroundHangThread)
/**
* Returns the BackgroundHangThread associated with the
* running thread. Note that this will not find private
* BackgroundHangThread threads.
*
* @return BackgroundHangThread*, or nullptr if no thread
* is found.
*/
static BackgroundHangThread* FindThread();
static void Startup()
{
/* We can tolerate init() failing. */
sTlsKeyInitialized = sTlsKey.init();
}
// Hang timeout in ticks
const PRIntervalTime mTimeout;
// PermaHang timeout in ticks
const PRIntervalTime mMaxTimeout;
// Time at last activity
PRIntervalTime mInterval;
// Time when a hang started
PRIntervalTime mHangStart;
// Is the thread in a hang
bool mHanging;
// Is the thread in a waiting state
bool mWaiting;
// Is the thread dedicated to a single BackgroundHangMonitor
BackgroundHangMonitor::ThreadType mThreadType;
// Platform-specific helper to get hang stacks
ThreadStackHelper mStackHelper;
// Stack of current hang
Telemetry::HangStack mHangStack;
// Native stack of current hang
Telemetry::NativeHangStack mNativeHangStack;
// Statistics for telemetry
Telemetry::ThreadHangStats mStats;
// Annotations for the current hang
UniquePtr<HangMonitor::HangAnnotations> mAnnotations;
// Annotators registered for this thread
HangMonitor::Observer::Annotators mAnnotators;
BackgroundHangThread(const char* aName,
uint32_t aTimeoutMs,
uint32_t aMaxTimeoutMs,
BackgroundHangMonitor::ThreadType aThreadType = BackgroundHangMonitor::THREAD_SHARED);
// Report a hang; aManager->mLock IS locked
Telemetry::HangHistogram& ReportHang(PRIntervalTime aHangTime);
// Report a permanent hang; aManager->mLock IS locked
void ReportPermaHang();
// Called by BackgroundHangMonitor::NotifyActivity
void NotifyActivity()
{
MonitorAutoLock autoLock(mManager->mLock);
Update();
}
// Called by BackgroundHangMonitor::NotifyWait
void NotifyWait()
{
MonitorAutoLock autoLock(mManager->mLock);
if (mWaiting) {
return;
}
Update();
mWaiting = true;
}
// Returns true if this thread is (or might be) shared between other
// BackgroundHangMonitors for the monitored thread.
bool IsShared() {
return mThreadType == BackgroundHangMonitor::THREAD_SHARED;
}
};
StaticRefPtr<BackgroundHangManager> BackgroundHangManager::sInstance;
bool BackgroundHangManager::sDisabled = false;
MOZ_THREAD_LOCAL(BackgroundHangThread*) BackgroundHangThread::sTlsKey;
bool BackgroundHangThread::sTlsKeyInitialized;
BackgroundHangManager::BackgroundHangManager()
: mShutdown(false)
, mLock("BackgroundHangManager")
, mIntervalNow(0)
{
// Lock so we don't race against the new monitor thread
MonitorAutoLock autoLock(mLock);
mHangMonitorThread = PR_CreateThread(
PR_USER_THREAD, MonitorThread, this,
PR_PRIORITY_LOW, PR_GLOBAL_THREAD, PR_JOINABLE_THREAD, 0);
MOZ_ASSERT(mHangMonitorThread, "Failed to create monitor thread");
}
BackgroundHangManager::~BackgroundHangManager()
{
MOZ_ASSERT(mShutdown, "Destruction without Shutdown call");
MOZ_ASSERT(mHangThreads.isEmpty(), "Destruction with outstanding monitors");
MOZ_ASSERT(mHangMonitorThread, "No monitor thread");
// PR_CreateThread could have failed above due to resource limitation
if (mHangMonitorThread) {
// The monitor thread can only live as long as the instance lives
PR_JoinThread(mHangMonitorThread);
}
}
void
BackgroundHangManager::RunMonitorThread()
{
// Keep us locked except when waiting
MonitorAutoLock autoLock(mLock);
/* mIntervalNow is updated at various intervals determined by waitTime.
However, if an update latency is too long (due to CPU scheduling, system
sleep, etc.), we don't update mIntervalNow at all. This is done so that
long latencies in our timing are not detected as hangs. systemTime is
used to track PR_IntervalNow() and determine our latency. */
PRIntervalTime systemTime = PR_IntervalNow();
// Default values for the first iteration of thread loop
PRIntervalTime waitTime = PR_INTERVAL_NO_WAIT;
PRIntervalTime recheckTimeout = PR_INTERVAL_NO_WAIT;
while (!mShutdown) {
nsresult rv = autoLock.Wait(waitTime);
PRIntervalTime newTime = PR_IntervalNow();
PRIntervalTime systemInterval = newTime - systemTime;
systemTime = newTime;
/* waitTime is a quarter of the shortest timeout value; If our timing
latency is low enough (less than half the shortest timeout value),
we can update mIntervalNow. */
if (MOZ_LIKELY(waitTime != PR_INTERVAL_NO_TIMEOUT &&
systemInterval < 2 * waitTime)) {
mIntervalNow += systemInterval;
}
/* If it's before the next recheck timeout, and our wait did not get
interrupted, we can keep the current waitTime and skip iterating
through hang monitors. */
if (MOZ_LIKELY(systemInterval < recheckTimeout &&
systemInterval >= waitTime &&
rv == NS_OK)) {
recheckTimeout -= systemInterval;
continue;
}
/* We are in one of the following scenarios,
- Hang or permahang recheck timeout
- Thread added/removed
- Thread wait or hang ended
In all cases, we want to go through our list of hang
monitors and update waitTime and recheckTimeout. */
waitTime = PR_INTERVAL_NO_TIMEOUT;
recheckTimeout = PR_INTERVAL_NO_TIMEOUT;
// Locally hold mIntervalNow
PRIntervalTime intervalNow = mIntervalNow;
// iterate through hang monitors
for (BackgroundHangThread* currentThread = mHangThreads.getFirst();
currentThread; currentThread = currentThread->getNext()) {
if (currentThread->mWaiting) {
// Thread is waiting, not hanging
continue;
}
PRIntervalTime interval = currentThread->mInterval;
PRIntervalTime hangTime = intervalNow - interval;
if (MOZ_UNLIKELY(hangTime >= currentThread->mMaxTimeout)) {
// A permahang started
// Skip subsequent iterations and tolerate a race on mWaiting here
currentThread->mWaiting = true;
currentThread->mHanging = false;
currentThread->ReportPermaHang();
continue;
}
if (MOZ_LIKELY(!currentThread->mHanging)) {
if (MOZ_UNLIKELY(hangTime >= currentThread->mTimeout)) {
// A hang started
#ifdef NIGHTLY_BUILD
if (currentThread->mStats.mNativeStackCnt < kMaximumNativeHangStacks) {
// NOTE: In nightly builds of firefox we want to collect native stacks
// for all hangs, not just permahangs.
currentThread->mStats.mNativeStackCnt += 1;
currentThread->mStackHelper.GetPseudoAndNativeStack(
currentThread->mHangStack, currentThread->mNativeHangStack);
} else {
currentThread->mStackHelper.GetPseudoStack(currentThread->mHangStack);
}
#else
currentThread->mStackHelper.GetPseudoStack(currentThread->mHangStack);
#endif
currentThread->mHangStart = interval;
currentThread->mHanging = true;
currentThread->mAnnotations =
currentThread->mAnnotators.GatherAnnotations();
}
} else {
if (MOZ_LIKELY(interval != currentThread->mHangStart)) {
// A hang ended
currentThread->ReportHang(intervalNow - currentThread->mHangStart);
currentThread->mHanging = false;
}
}
/* If we are hanging, the next time we check for hang status is when
the hang turns into a permahang. If we're not hanging, the next
recheck timeout is when we may be entering a hang. */
PRIntervalTime nextRecheck;
if (currentThread->mHanging) {
nextRecheck = currentThread->mMaxTimeout;
} else {
nextRecheck = currentThread->mTimeout;
}
recheckTimeout = std::min(recheckTimeout, nextRecheck - hangTime);
if (currentThread->mTimeout != PR_INTERVAL_NO_TIMEOUT) {
/* We wait for a quarter of the shortest timeout
value to give mIntervalNow enough granularity. */
waitTime = std::min(waitTime, currentThread->mTimeout / 4);
}
}
}
/* We are shutting down now.
Wait for all outstanding monitors to unregister. */
while (!mHangThreads.isEmpty()) {
autoLock.Wait(PR_INTERVAL_NO_TIMEOUT);
}
}
BackgroundHangThread::BackgroundHangThread(const char* aName,
uint32_t aTimeoutMs,
uint32_t aMaxTimeoutMs,
BackgroundHangMonitor::ThreadType aThreadType)
: mManager(BackgroundHangManager::sInstance)
, mThreadID(PR_GetCurrentThread())
, mTimeout(aTimeoutMs == BackgroundHangMonitor::kNoTimeout
? PR_INTERVAL_NO_TIMEOUT
: PR_MillisecondsToInterval(aTimeoutMs))
, mMaxTimeout(aMaxTimeoutMs == BackgroundHangMonitor::kNoTimeout
? PR_INTERVAL_NO_TIMEOUT
: PR_MillisecondsToInterval(aMaxTimeoutMs))
, mInterval(mManager->mIntervalNow)
, mHangStart(mInterval)
, mHanging(false)
, mWaiting(true)
, mThreadType(aThreadType)
, mStats(aName)
{
if (sTlsKeyInitialized && IsShared()) {
sTlsKey.set(this);
}
// Lock here because LinkedList is not thread-safe
MonitorAutoLock autoLock(mManager->mLock);
// Add to thread list
mManager->mHangThreads.insertBack(this);
// Wake up monitor thread to process new thread
autoLock.Notify();
}
BackgroundHangThread::~BackgroundHangThread()
{
// Lock here because LinkedList is not thread-safe
MonitorAutoLock autoLock(mManager->mLock);
// Remove from thread list
remove();
// Wake up monitor thread to process removed thread
autoLock.Notify();
// We no longer have a thread
if (sTlsKeyInitialized && IsShared()) {
sTlsKey.set(nullptr);
}
// Move our copy of ThreadHangStats to Telemetry storage
Telemetry::RecordThreadHangStats(mStats);
}
Telemetry::HangHistogram&
BackgroundHangThread::ReportHang(PRIntervalTime aHangTime)
{
// Recovered from a hang; called on the monitor thread
// mManager->mLock IS locked
// Remove unwanted "js::RunScript" frame from the stack
for (size_t i = 0; i < mHangStack.length(); ) {
const char** f = mHangStack.begin() + i;
if (!mHangStack.IsInBuffer(*f) && !strcmp(*f, "js::RunScript")) {
mHangStack.erase(f);
} else {
i++;
}
}
// Collapse duplicated "(chrome script)" and "(content script)" entries in the stack.
auto it = std::unique(mHangStack.begin(), mHangStack.end(), StackScriptEntriesCollapser);
mHangStack.erase(it, mHangStack.end());
// Limit the depth of the reported stack if greater than our limit. Only keep its
// last entries, since the most recent frames are at the end of the vector.
if (mHangStack.length() > kMaxThreadHangStackDepth) {
const int elementsToRemove = mHangStack.length() - kMaxThreadHangStackDepth;
// Replace the oldest frame with a known label so that we can tell this stack
// was limited.
mHangStack[0] = "(reduced stack)";
mHangStack.erase(mHangStack.begin() + 1, mHangStack.begin() + elementsToRemove);
}
Telemetry::HangHistogram newHistogram(Move(mHangStack), Move(mNativeHangStack));
for (Telemetry::HangHistogram* oldHistogram = mStats.mHangs.begin();
oldHistogram != mStats.mHangs.end(); oldHistogram++) {
if (newHistogram == *oldHistogram) {
// New histogram matches old one
oldHistogram->Add(aHangTime, Move(mAnnotations));
return *oldHistogram;
}
}
// Add new histogram
newHistogram.Add(aHangTime, Move(mAnnotations));
if (!mStats.mHangs.append(Move(newHistogram))) {
MOZ_CRASH();
}
return mStats.mHangs.back();
}
void
BackgroundHangThread::ReportPermaHang()
{
// Permanently hanged; called on the monitor thread
// mManager->mLock IS locked
Telemetry::HangHistogram& hang = ReportHang(mMaxTimeout);
Telemetry::NativeHangStack& stack = hang.GetNativeStack();
if (stack.empty()) {
mStats.mNativeStackCnt += 1;
if (mStats.mNativeStackCnt <= kMaximumNativeHangStacks) {
mStackHelper.GetNativeStack(stack);
}
}
}
MOZ_ALWAYS_INLINE void
BackgroundHangThread::Update()
{
PRIntervalTime intervalNow = mManager->mIntervalNow;
if (mWaiting) {
mInterval = intervalNow;
mWaiting = false;
/* We have to wake up the manager thread because when all threads
are waiting, the manager thread waits indefinitely as well. */
mManager->Wakeup();
} else {
PRIntervalTime duration = intervalNow - mInterval;
mStats.mActivity.Add(duration);
if (MOZ_UNLIKELY(duration >= mTimeout)) {
/* Wake up the manager thread to tell it that a hang ended */
mManager->Wakeup();
}
mInterval = intervalNow;
}
}
BackgroundHangThread*
BackgroundHangThread::FindThread()
{
#ifdef MOZ_ENABLE_BACKGROUND_HANG_MONITOR
if (BackgroundHangManager::sInstance == nullptr) {
MOZ_ASSERT(BackgroundHangManager::sDisabled,
"BackgroundHandleManager is not initialized");
return nullptr;
}
if (sTlsKeyInitialized) {
// Use TLS if available
return sTlsKey.get();
}
// If TLS is unavailable, we can search through the thread list
RefPtr<BackgroundHangManager> manager(BackgroundHangManager::sInstance);
MOZ_ASSERT(manager, "Creating BackgroundHangMonitor after shutdown");
PRThread* threadID = PR_GetCurrentThread();
// Lock thread list for traversal
MonitorAutoLock autoLock(manager->mLock);
for (BackgroundHangThread* thread = manager->mHangThreads.getFirst();
thread; thread = thread->getNext()) {
if (thread->mThreadID == threadID && thread->IsShared()) {
return thread;
}
}
#endif
// Current thread is not initialized
return nullptr;
}
bool
BackgroundHangMonitor::ShouldDisableOnBeta(const nsCString &clientID) {
MOZ_ASSERT(clientID.Length() == 36, "clientID is invalid");
const char *suffix = clientID.get() + clientID.Length() - 4;
return strtol(suffix, NULL, 16) % BHR_BETA_MOD;
}
bool
BackgroundHangMonitor::IsDisabled() {
#ifdef MOZ_ENABLE_BACKGROUND_HANG_MONITOR
return BackgroundHangManager::sDisabled;
#else
return true;
#endif
}
bool
BackgroundHangMonitor::DisableOnBeta() {
nsAdoptingCString clientID = Preferences::GetCString("toolkit.telemetry.cachedClientID");
bool telemetryEnabled = Preferences::GetBool("toolkit.telemetry.enabled");
if (!telemetryEnabled || !clientID || BackgroundHangMonitor::ShouldDisableOnBeta(clientID)) {
if (XRE_IsParentProcess()) {
BackgroundHangMonitor::Shutdown();
} else {
BackgroundHangManager::sDisabled = true;
}
return true;
}
return false;
}
void
BackgroundHangMonitor::Startup()
{
#ifdef MOZ_ENABLE_BACKGROUND_HANG_MONITOR
MOZ_ASSERT(!BackgroundHangManager::sInstance, "Already initialized");
if (!strcmp(NS_STRINGIFY(MOZ_UPDATE_CHANNEL), "beta")) {
if (XRE_IsParentProcess()) { // cached ClientID hasn't been read yet
ThreadStackHelper::Startup();
BackgroundHangThread::Startup();
BackgroundHangManager::sInstance = new BackgroundHangManager();
nsCOMPtr<nsIObserverService> observerService = mozilla::services::GetObserverService();
MOZ_ASSERT(observerService);
observerService->AddObserver(BackgroundHangManager::sInstance, "profile-after-change", false);
return;
} else if(DisableOnBeta()){
return;
}
}
ThreadStackHelper::Startup();
BackgroundHangThread::Startup();
BackgroundHangManager::sInstance = new BackgroundHangManager();
#endif
}
void
BackgroundHangMonitor::Shutdown()
{
#ifdef MOZ_ENABLE_BACKGROUND_HANG_MONITOR
if (BackgroundHangManager::sDisabled) {
MOZ_ASSERT(!BackgroundHangManager::sInstance, "Initialized");
return;
}
MOZ_ASSERT(BackgroundHangManager::sInstance, "Not initialized");
/* Scope our lock inside Shutdown() because the sInstance object can
be destroyed as soon as we set sInstance to nullptr below, and
we don't want to hold the lock when it's being destroyed. */
BackgroundHangManager::sInstance->Shutdown();
BackgroundHangManager::sInstance = nullptr;
ThreadStackHelper::Shutdown();
BackgroundHangManager::sDisabled = true;
#endif
}
BackgroundHangMonitor::BackgroundHangMonitor(const char* aName,
uint32_t aTimeoutMs,
uint32_t aMaxTimeoutMs,
ThreadType aThreadType)
: mThread(aThreadType == THREAD_SHARED ? BackgroundHangThread::FindThread() : nullptr)
{
#ifdef MOZ_ENABLE_BACKGROUND_HANG_MONITOR
if (!BackgroundHangManager::sDisabled && !mThread) {
mThread = new BackgroundHangThread(aName, aTimeoutMs, aMaxTimeoutMs,
aThreadType);
}
#endif
}
BackgroundHangMonitor::BackgroundHangMonitor()
: mThread(BackgroundHangThread::FindThread())
{
#ifdef MOZ_ENABLE_BACKGROUND_HANG_MONITOR
if (BackgroundHangManager::sDisabled) {
return;
}
#endif
}
BackgroundHangMonitor::~BackgroundHangMonitor()
{
}
void
BackgroundHangMonitor::NotifyActivity()
{
#ifdef MOZ_ENABLE_BACKGROUND_HANG_MONITOR
if (mThread == nullptr) {
MOZ_ASSERT(BackgroundHangManager::sDisabled,
"This thread is not initialized for hang monitoring");
return;
}
if (Telemetry::CanRecordExtended()) {
mThread->NotifyActivity();
}
#endif
}
void
BackgroundHangMonitor::NotifyWait()
{
#ifdef MOZ_ENABLE_BACKGROUND_HANG_MONITOR
if (mThread == nullptr) {
MOZ_ASSERT(BackgroundHangManager::sDisabled,
"This thread is not initialized for hang monitoring");
return;
}
if (Telemetry::CanRecordExtended()) {
mThread->NotifyWait();
}
#endif
}
bool
BackgroundHangMonitor::RegisterAnnotator(HangMonitor::Annotator& aAnnotator)
{
#ifdef MOZ_ENABLE_BACKGROUND_HANG_MONITOR
BackgroundHangThread* thisThread = BackgroundHangThread::FindThread();
if (!thisThread) {
return false;
}
return thisThread->mAnnotators.Register(aAnnotator);
#else
return false;
#endif
}
bool
BackgroundHangMonitor::UnregisterAnnotator(HangMonitor::Annotator& aAnnotator)
{
#ifdef MOZ_ENABLE_BACKGROUND_HANG_MONITOR
BackgroundHangThread* thisThread = BackgroundHangThread::FindThread();
if (!thisThread) {
return false;
}
return thisThread->mAnnotators.Unregister(aAnnotator);
#else
return false;
#endif
}
/* Because we are iterating through the BackgroundHangThread linked list,
we need to take a lock. Using MonitorAutoLock as a base class makes
sure all of that is taken care of for us. */
BackgroundHangMonitor::ThreadHangStatsIterator::ThreadHangStatsIterator()
: MonitorAutoLock(BackgroundHangManager::sInstance->mLock)
, mThread(BackgroundHangManager::sInstance ?
BackgroundHangManager::sInstance->mHangThreads.getFirst() :
nullptr)
{
#ifdef MOZ_ENABLE_BACKGROUND_HANG_MONITOR
MOZ_ASSERT(BackgroundHangManager::sInstance ||
BackgroundHangManager::sDisabled,
"Inconsistent state");
#endif
}
Telemetry::ThreadHangStats*
BackgroundHangMonitor::ThreadHangStatsIterator::GetNext()
{
if (!mThread) {
return nullptr;
}
Telemetry::ThreadHangStats* stats = &mThread->mStats;
mThread = mThread->getNext();
return stats;
}
} // namespace mozilla