/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim:set ts=2 sw=2 sts=2 et cindent: */ /* 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/ReentrantMonitor.h" #include "nsThread.h" #include "nsThreadManager.h" #include "nsIClassInfoImpl.h" #include "nsIProgrammingLanguage.h" #include "nsAutoPtr.h" #include "nsCOMPtr.h" #include "prlog.h" #include "nsIObserverService.h" #include "mozilla/HangMonitor.h" #include "mozilla/Services.h" #define HAVE_UALARM _BSD_SOURCE || (_XOPEN_SOURCE >= 500 || \ _XOPEN_SOURCE && _XOPEN_SOURCE_EXTENDED) && \ !(_POSIX_C_SOURCE >= 200809L || _XOPEN_SOURCE >= 700) #if defined(XP_UNIX) && !defined(ANDROID) && !defined(DEBUG) && HAVE_UALARM \ && defined(_GNU_SOURCE) # define MOZ_CANARY # include # include # include # include # include "nsXULAppAPI.h" #endif #include "mozilla/FunctionTimer.h" #if defined(NS_FUNCTION_TIMER) && defined(_MSC_VER) #include "nsTimerImpl.h" #include "nsStackWalk.h" #endif #ifdef NS_FUNCTION_TIMER #include "nsCRT.h" #endif using namespace mozilla; #ifdef PR_LOGGING static PRLogModuleInfo *sLog = PR_NewLogModule("nsThread"); #endif #define LOG(args) PR_LOG(sLog, PR_LOG_DEBUG, args) NS_DECL_CI_INTERFACE_GETTER(nsThread) namespace mozilla { // Fun fact: Android's GCC won't convert bool* to PRInt32*, so we can't // PR_ATOMIC_SET a bool. static PRInt32 sMemoryPressurePending = 0; /* * It's important that this function not acquire any locks, nor do anything * which might cause malloc to run. */ void ScheduleMemoryPressureEvent() { PR_ATOMIC_SET(&sMemoryPressurePending, 1); } } // namespace mozilla //----------------------------------------------------------------------------- // Because we do not have our own nsIFactory, we have to implement nsIClassInfo // somewhat manually. class nsThreadClassInfo : public nsIClassInfo { public: NS_DECL_ISUPPORTS_INHERITED // no mRefCnt NS_DECL_NSICLASSINFO nsThreadClassInfo() {} }; static nsThreadClassInfo sThreadClassInfo; NS_IMETHODIMP_(nsrefcnt) nsThreadClassInfo::AddRef() { return 2; } NS_IMETHODIMP_(nsrefcnt) nsThreadClassInfo::Release() { return 1; } NS_IMPL_QUERY_INTERFACE1(nsThreadClassInfo, nsIClassInfo) NS_IMETHODIMP nsThreadClassInfo::GetInterfaces(PRUint32 *count, nsIID ***array) { return NS_CI_INTERFACE_GETTER_NAME(nsThread)(count, array); } NS_IMETHODIMP nsThreadClassInfo::GetHelperForLanguage(PRUint32 lang, nsISupports **result) { *result = nsnull; return NS_OK; } NS_IMETHODIMP nsThreadClassInfo::GetContractID(char **result) { *result = nsnull; return NS_OK; } NS_IMETHODIMP nsThreadClassInfo::GetClassDescription(char **result) { *result = nsnull; return NS_OK; } NS_IMETHODIMP nsThreadClassInfo::GetClassID(nsCID **result) { *result = nsnull; return NS_OK; } NS_IMETHODIMP nsThreadClassInfo::GetImplementationLanguage(PRUint32 *result) { *result = nsIProgrammingLanguage::CPLUSPLUS; return NS_OK; } NS_IMETHODIMP nsThreadClassInfo::GetFlags(PRUint32 *result) { *result = THREADSAFE; return NS_OK; } NS_IMETHODIMP nsThreadClassInfo::GetClassIDNoAlloc(nsCID *result) { return NS_ERROR_NOT_AVAILABLE; } //----------------------------------------------------------------------------- NS_IMPL_THREADSAFE_ADDREF(nsThread) NS_IMPL_THREADSAFE_RELEASE(nsThread) NS_INTERFACE_MAP_BEGIN(nsThread) NS_INTERFACE_MAP_ENTRY(nsIThread) NS_INTERFACE_MAP_ENTRY(nsIThreadInternal) NS_INTERFACE_MAP_ENTRY(nsIEventTarget) NS_INTERFACE_MAP_ENTRY(nsISupportsPriority) NS_INTERFACE_MAP_ENTRY_AMBIGUOUS(nsISupports, nsIThread) if (aIID.Equals(NS_GET_IID(nsIClassInfo))) { foundInterface = static_cast(&sThreadClassInfo); } else NS_INTERFACE_MAP_END NS_IMPL_CI_INTERFACE_GETTER4(nsThread, nsIThread, nsIThreadInternal, nsIEventTarget, nsISupportsPriority) //----------------------------------------------------------------------------- class nsThreadStartupEvent : public nsRunnable { public: // Create a new thread startup object. static nsThreadStartupEvent *Create() { return new nsThreadStartupEvent(); } // This method does not return until the thread startup object is in the // completion state. void Wait() { if (mInitialized) // Maybe avoid locking... return; ReentrantMonitorAutoEnter mon(mMon); while (!mInitialized) mon.Wait(); } // This method needs to be public to support older compilers (xlC_r on AIX). // It should be called directly as this class type is reference counted. virtual ~nsThreadStartupEvent() { } private: NS_IMETHOD Run() { ReentrantMonitorAutoEnter mon(mMon); mInitialized = true; mon.Notify(); return NS_OK; } nsThreadStartupEvent() : mMon("nsThreadStartupEvent.mMon") , mInitialized(false) { } ReentrantMonitor mMon; bool mInitialized; }; //----------------------------------------------------------------------------- struct nsThreadShutdownContext { nsThread *joiningThread; bool shutdownAck; }; // This event is responsible for notifying nsThread::Shutdown that it is time // to call PR_JoinThread. class nsThreadShutdownAckEvent : public nsRunnable { public: nsThreadShutdownAckEvent(nsThreadShutdownContext *ctx) : mShutdownContext(ctx) { } NS_IMETHOD Run() { mShutdownContext->shutdownAck = true; return NS_OK; } private: nsThreadShutdownContext *mShutdownContext; }; // This event is responsible for setting mShutdownContext class nsThreadShutdownEvent : public nsRunnable { public: nsThreadShutdownEvent(nsThread *thr, nsThreadShutdownContext *ctx) : mThread(thr), mShutdownContext(ctx) { } NS_IMETHOD Run() { mThread->mShutdownContext = mShutdownContext; return NS_OK; } private: nsRefPtr mThread; nsThreadShutdownContext *mShutdownContext; }; //----------------------------------------------------------------------------- /*static*/ void nsThread::ThreadFunc(void *arg) { nsThread *self = static_cast(arg); // strong reference self->mThread = PR_GetCurrentThread(); // Inform the ThreadManager nsThreadManager::get()->RegisterCurrentThread(self); // Wait for and process startup event nsCOMPtr event; if (!self->GetEvent(true, getter_AddRefs(event))) { NS_WARNING("failed waiting for thread startup event"); return; } event->Run(); // unblocks nsThread::Init event = nsnull; // Now, process incoming events... while (!self->ShuttingDown()) NS_ProcessNextEvent(self); // Do NS_ProcessPendingEvents but with special handling to set // mEventsAreDoomed atomically with the removal of the last event. The key // invariant here is that we will never permit PutEvent to succeed if the // event would be left in the queue after our final call to // NS_ProcessPendingEvents. while (true) { { MutexAutoLock lock(self->mLock); if (!self->mEvents.HasPendingEvent()) { // No events in the queue, so we will stop now. Don't let any more // events be added, since they won't be processed. It is critical // that no PutEvent can occur between testing that the event queue is // empty and setting mEventsAreDoomed! self->mEventsAreDoomed = true; break; } } NS_ProcessPendingEvents(self); } // Inform the threadmanager that this thread is going away nsThreadManager::get()->UnregisterCurrentThread(self); // Dispatch shutdown ACK event = new nsThreadShutdownAckEvent(self->mShutdownContext); self->mShutdownContext->joiningThread->Dispatch(event, NS_DISPATCH_NORMAL); // Release any observer of the thread here. self->SetObserver(nsnull); NS_RELEASE(self); } //----------------------------------------------------------------------------- nsThread::nsThread(MainThreadFlag aMainThread, PRUint32 aStackSize) : mLock("nsThread.mLock") , mPriority(PRIORITY_NORMAL) , mThread(nsnull) , mRunningEvent(0) , mStackSize(aStackSize) , mShutdownContext(nsnull) , mShutdownRequired(false) , mEventsAreDoomed(false) , mIsMainThread(aMainThread) { } nsThread::~nsThread() { } nsresult nsThread::Init() { // spawn thread and wait until it is fully setup nsRefPtr startup = nsThreadStartupEvent::Create(); NS_ENSURE_TRUE(startup, NS_ERROR_OUT_OF_MEMORY); NS_ADDREF_THIS(); mShutdownRequired = true; // ThreadFunc is responsible for setting mThread PRThread *thr = PR_CreateThread(PR_USER_THREAD, ThreadFunc, this, PR_PRIORITY_NORMAL, PR_GLOBAL_THREAD, PR_JOINABLE_THREAD, mStackSize); if (!thr) { NS_RELEASE_THIS(); return NS_ERROR_OUT_OF_MEMORY; } // ThreadFunc will wait for this event to be run before it tries to access // mThread. By delaying insertion of this event into the queue, we ensure // that mThread is set properly. { MutexAutoLock lock(mLock); mEvents.PutEvent(startup); } // Wait for thread to call ThreadManager::SetupCurrentThread, which completes // initialization of ThreadFunc. startup->Wait(); return NS_OK; } nsresult nsThread::InitCurrentThread() { mThread = PR_GetCurrentThread(); nsThreadManager::get()->RegisterCurrentThread(this); return NS_OK; } nsresult nsThread::PutEvent(nsIRunnable *event) { { MutexAutoLock lock(mLock); if (mEventsAreDoomed) { NS_WARNING("An event was posted to a thread that will never run it (rejected)"); return NS_ERROR_UNEXPECTED; } if (!mEvents.PutEvent(event)) return NS_ERROR_OUT_OF_MEMORY; } nsCOMPtr obs = GetObserver(); if (obs) obs->OnDispatchedEvent(this); return NS_OK; } //----------------------------------------------------------------------------- // nsIEventTarget NS_IMETHODIMP nsThread::Dispatch(nsIRunnable *event, PRUint32 flags) { LOG(("THRD(%p) Dispatch [%p %x]\n", this, event, flags)); NS_ENSURE_ARG_POINTER(event); if (flags & DISPATCH_SYNC) { nsThread *thread = nsThreadManager::get()->GetCurrentThread(); NS_ENSURE_STATE(thread); // XXX we should be able to do something better here... we should // be able to monitor the slot occupied by this event and use // that to tell us when the event has been processed. nsRefPtr wrapper = new nsThreadSyncDispatch(thread, event); if (!wrapper) return NS_ERROR_OUT_OF_MEMORY; nsresult rv = PutEvent(wrapper); // Don't wait for the event to finish if we didn't dispatch it... if (NS_FAILED(rv)) return rv; while (wrapper->IsPending()) NS_ProcessNextEvent(thread); return wrapper->Result(); } NS_ASSERTION(flags == NS_DISPATCH_NORMAL, "unexpected dispatch flags"); return PutEvent(event); } NS_IMETHODIMP nsThread::IsOnCurrentThread(bool *result) { *result = (PR_GetCurrentThread() == mThread); return NS_OK; } //----------------------------------------------------------------------------- // nsIThread NS_IMETHODIMP nsThread::GetPRThread(PRThread **result) { *result = mThread; return NS_OK; } NS_IMETHODIMP nsThread::Shutdown() { LOG(("THRD(%p) shutdown\n", this)); // XXX If we make this warn, then we hit that warning at xpcom shutdown while // shutting down a thread in a thread pool. That happens b/c the thread // in the thread pool is already shutdown by the thread manager. if (!mThread) return NS_OK; NS_ENSURE_STATE(mThread != PR_GetCurrentThread()); // Prevent multiple calls to this method { MutexAutoLock lock(mLock); if (!mShutdownRequired) return NS_ERROR_UNEXPECTED; mShutdownRequired = false; } nsThreadShutdownContext context; context.joiningThread = nsThreadManager::get()->GetCurrentThread(); context.shutdownAck = false; // Set mShutdownContext and wake up the thread in case it is waiting for // events to process. nsCOMPtr event = new nsThreadShutdownEvent(this, &context); if (!event) return NS_ERROR_OUT_OF_MEMORY; // XXXroc What if posting the event fails due to OOM? PutEvent(event); // We could still end up with other events being added after the shutdown // task, but that's okay because we process pending events in ThreadFunc // after setting mShutdownContext just before exiting. // Process events on the current thread until we receive a shutdown ACK. while (!context.shutdownAck) NS_ProcessNextEvent(context.joiningThread); // Now, it should be safe to join without fear of dead-locking. PR_JoinThread(mThread); mThread = nsnull; // We hold strong references to our event observers, and once the thread is // shut down the observers can't easily unregister themselves. Do it here // to avoid leaking. ClearObservers(); #ifdef DEBUG { MutexAutoLock lock(mLock); NS_ASSERTION(!mObserver, "Should have been cleared at shutdown!"); } #endif return NS_OK; } NS_IMETHODIMP nsThread::HasPendingEvents(bool *result) { NS_ENSURE_STATE(PR_GetCurrentThread() == mThread); *result = mEvents.GetEvent(false, nsnull); return NS_OK; } #ifdef MOZ_CANARY void canary_alarm_handler (int signum); class Canary { //XXX ToDo: support nested loops public: Canary() { if (sOutputFD != 0 && EventLatencyIsImportant()) { if (sOutputFD == -1) { const int flags = O_WRONLY | O_APPEND | O_CREAT | O_NONBLOCK; const mode_t mode = S_IRUSR | S_IWUSR | S_IRGRP | S_IROTH; char* env_var_flag = getenv("MOZ_KILL_CANARIES"); sOutputFD = env_var_flag ? (env_var_flag[0] ? open(env_var_flag, flags, mode) : STDERR_FILENO) : 0; if (sOutputFD == 0) return; } signal(SIGALRM, canary_alarm_handler); ualarm(15000, 0); } } ~Canary() { if (sOutputFD != 0 && EventLatencyIsImportant()) ualarm(0, 0); } static bool EventLatencyIsImportant() { return NS_IsMainThread() && XRE_GetProcessType() == GeckoProcessType_Default; } static int sOutputFD; }; int Canary::sOutputFD = -1; void canary_alarm_handler (int signum) { void *array[30]; const char msg[29] = "event took too long to run:\n"; // use write to be safe in the signal handler write(Canary::sOutputFD, msg, sizeof(msg)); backtrace_symbols_fd(array, backtrace(array, 30), Canary::sOutputFD); } #endif #define NOTIFY_EVENT_OBSERVERS(func_, params_) \ PR_BEGIN_MACRO \ if (!mEventObservers.IsEmpty()) { \ nsAutoTObserverArray, 2>::ForwardIterator \ iter_(mEventObservers); \ nsCOMPtr obs_; \ while (iter_.HasMore()) { \ obs_ = iter_.GetNext(); \ obs_ -> func_ params_ ; \ } \ } \ PR_END_MACRO NS_IMETHODIMP nsThread::ProcessNextEvent(bool mayWait, bool *result) { LOG(("THRD(%p) ProcessNextEvent [%u %u]\n", this, mayWait, mRunningEvent)); NS_ENSURE_STATE(PR_GetCurrentThread() == mThread); if (MAIN_THREAD == mIsMainThread && mayWait && !ShuttingDown()) HangMonitor::Suspend(); // Fire a memory pressure notification, if we're the main thread and one is // pending. if (MAIN_THREAD == mIsMainThread && !ShuttingDown()) { bool mpPending = PR_ATOMIC_SET(&sMemoryPressurePending, 0); if (mpPending) { nsCOMPtr os = services::GetObserverService(); if (os) { os->NotifyObservers(nsnull, "memory-pressure", NS_LITERAL_STRING("low-memory").get()); } else { NS_WARNING("Can't get observer service!"); } } } nsCOMPtr obs = mObserver; if (obs) obs->OnProcessNextEvent(this, mayWait && !ShuttingDown(), mRunningEvent); NOTIFY_EVENT_OBSERVERS(OnProcessNextEvent, (this, mayWait && !ShuttingDown(), mRunningEvent)); ++mRunningEvent; #ifdef MOZ_CANARY Canary canary; #endif nsresult rv = NS_OK; { // Scope for |event| to make sure that its destructor fires while // mRunningEvent has been incremented, since that destructor can // also do work. // If we are shutting down, then do not wait for new events. nsCOMPtr event; mEvents.GetEvent(mayWait && !ShuttingDown(), getter_AddRefs(event)); #ifdef NS_FUNCTION_TIMER char message[1024] = {'\0'}; if (MAIN_THREAD == mIsMainThread) { mozilla::FunctionTimer::ft_snprintf(message, sizeof(message), "@ Main Thread Event %p", (void*)event.get()); } // If message is empty, it means that we're not on the main thread, and // FunctionTimer won't time this function. NS_TIME_FUNCTION_MIN_FMT(5.0, message); #endif *result = (event.get() != nsnull); if (event) { LOG(("THRD(%p) running [%p]\n", this, event.get())); if (MAIN_THREAD == mIsMainThread) HangMonitor::NotifyActivity(); event->Run(); } else if (mayWait) { NS_ASSERTION(ShuttingDown(), "This should only happen when shutting down"); rv = NS_ERROR_UNEXPECTED; } } --mRunningEvent; NOTIFY_EVENT_OBSERVERS(AfterProcessNextEvent, (this, mRunningEvent)); if (obs) obs->AfterProcessNextEvent(this, mRunningEvent); return rv; } //----------------------------------------------------------------------------- // nsISupportsPriority NS_IMETHODIMP nsThread::GetPriority(PRInt32 *priority) { *priority = mPriority; return NS_OK; } NS_IMETHODIMP nsThread::SetPriority(PRInt32 priority) { NS_ENSURE_STATE(mThread); // NSPR defines the following four thread priorities: // PR_PRIORITY_LOW // PR_PRIORITY_NORMAL // PR_PRIORITY_HIGH // PR_PRIORITY_URGENT // We map the priority values defined on nsISupportsPriority to these values. mPriority = priority; PRThreadPriority pri; if (mPriority <= PRIORITY_HIGHEST) { pri = PR_PRIORITY_URGENT; } else if (mPriority < PRIORITY_NORMAL) { pri = PR_PRIORITY_HIGH; } else if (mPriority > PRIORITY_NORMAL) { pri = PR_PRIORITY_LOW; } else { pri = PR_PRIORITY_NORMAL; } PR_SetThreadPriority(mThread, pri); return NS_OK; } NS_IMETHODIMP nsThread::AdjustPriority(PRInt32 delta) { return SetPriority(mPriority + delta); } //----------------------------------------------------------------------------- // nsIThreadInternal NS_IMETHODIMP nsThread::GetObserver(nsIThreadObserver **obs) { MutexAutoLock lock(mLock); NS_IF_ADDREF(*obs = mObserver); return NS_OK; } NS_IMETHODIMP nsThread::SetObserver(nsIThreadObserver *obs) { NS_ENSURE_STATE(PR_GetCurrentThread() == mThread); MutexAutoLock lock(mLock); mObserver = obs; return NS_OK; } NS_IMETHODIMP nsThread::GetRecursionDepth(PRUint32 *depth) { NS_ENSURE_ARG_POINTER(depth); NS_ENSURE_STATE(PR_GetCurrentThread() == mThread); *depth = mRunningEvent; return NS_OK; } NS_IMETHODIMP nsThread::AddObserver(nsIThreadObserver *observer) { NS_ENSURE_ARG_POINTER(observer); NS_ENSURE_STATE(PR_GetCurrentThread() == mThread); NS_WARN_IF_FALSE(!mEventObservers.Contains(observer), "Adding an observer twice!"); if (!mEventObservers.AppendElement(observer)) { NS_WARNING("Out of memory!"); return NS_ERROR_OUT_OF_MEMORY; } return NS_OK; } NS_IMETHODIMP nsThread::RemoveObserver(nsIThreadObserver *observer) { NS_ENSURE_STATE(PR_GetCurrentThread() == mThread); if (observer && !mEventObservers.RemoveElement(observer)) { NS_WARNING("Removing an observer that was never added!"); } return NS_OK; } //----------------------------------------------------------------------------- NS_IMETHODIMP nsThreadSyncDispatch::Run() { if (mSyncTask) { mResult = mSyncTask->Run(); mSyncTask = nsnull; // unblock the origin thread mOrigin->Dispatch(this, NS_DISPATCH_NORMAL); } return NS_OK; }