Mercurial > trustbridge > nss-cmake-static
view nspr/pr/src/pthreads/ptthread.c @ 3:150b72113545
Add DBM and legacydb support
author | Andre Heinecke <andre.heinecke@intevation.de> |
---|---|
date | Tue, 05 Aug 2014 18:32:02 +0200 |
parents | 1e5118fa0cb1 |
children |
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/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* 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/. */ /* ** File: ptthread.c ** Descritpion: Implemenation for threds using pthreds ** Exports: ptthread.h */ #if defined(_PR_PTHREADS) || defined(_PR_DCETHREADS) #include "prlog.h" #include "primpl.h" #include "prpdce.h" #include <pthread.h> #include <unistd.h> #include <string.h> #include <signal.h> #include <dlfcn.h> #ifdef SYMBIAN /* In Open C sched_get_priority_min/max do not work properly, so we undefine * _POSIX_THREAD_PRIORITY_SCHEDULING here. */ #undef _POSIX_THREAD_PRIORITY_SCHEDULING #endif #ifdef _PR_NICE_PRIORITY_SCHEDULING #undef _POSIX_THREAD_PRIORITY_SCHEDULING #include <sys/resource.h> #ifndef HAVE_GETTID #define gettid() (syscall(SYS_gettid)) #endif #endif /* * Record whether or not we have the privilege to set the scheduling * policy and priority of threads. 0 means that privilege is available. * EPERM means that privilege is not available. */ static PRIntn pt_schedpriv = 0; extern PRLock *_pr_sleeplock; static struct _PT_Bookeeping { PRLock *ml; /* a lock to protect ourselves */ PRCondVar *cv; /* used to signal global things */ PRInt32 system, user; /* a count of the two different types */ PRUintn this_many; /* number of threads allowed for exit */ pthread_key_t key; /* thread private data key */ PRBool keyCreated; /* whether 'key' should be deleted */ PRThread *first, *last; /* list of threads we know about */ #if defined(_PR_DCETHREADS) || defined(_POSIX_THREAD_PRIORITY_SCHEDULING) PRInt32 minPrio, maxPrio; /* range of scheduling priorities */ #endif } pt_book = {0}; static void _pt_thread_death(void *arg); static void _pt_thread_death_internal(void *arg, PRBool callDestructors); static void init_pthread_gc_support(void); #if defined(_PR_DCETHREADS) || defined(_POSIX_THREAD_PRIORITY_SCHEDULING) static PRIntn pt_PriorityMap(PRThreadPriority pri) { #ifdef NTO /* This priority algorithm causes lots of problems on Neutrino * for now I have just hard coded everything to run at priority 10 * until I can come up with a new algorithm. * Jerry.Kirk@Nexwarecorp.com */ return 10; #else return pt_book.minPrio + pri * (pt_book.maxPrio - pt_book.minPrio) / PR_PRIORITY_LAST; #endif } #elif defined(_PR_NICE_PRIORITY_SCHEDULING) /* * This functions maps higher priorities to lower nice values relative to the * nice value specified in the |nice| parameter. The corresponding relative * adjustments are: * * PR_PRIORITY_LOW +1 * PR_PRIORITY_NORMAL 0 * PR_PRIORITY_HIGH -1 * PR_PRIORITY_URGENT -2 */ static int pt_RelativePriority(int nice, PRThreadPriority pri) { return nice + (1 - pri); } #endif /* ** Initialize a stack for a native pthread thread */ static void _PR_InitializeStack(PRThreadStack *ts) { if( ts && (ts->stackTop == 0) ) { ts->allocBase = (char *) &ts; ts->allocSize = ts->stackSize; /* ** Setup stackTop and stackBottom values. */ #ifdef HAVE_STACK_GROWING_UP ts->stackBottom = ts->allocBase + ts->stackSize; ts->stackTop = ts->allocBase; #else ts->stackTop = ts->allocBase; ts->stackBottom = ts->allocBase - ts->stackSize; #endif } } static void *_pt_root(void *arg) { PRIntn rv; PRThread *thred = (PRThread*)arg; PRBool detached = (thred->state & PT_THREAD_DETACHED) ? PR_TRUE : PR_FALSE; pthread_t id = pthread_self(); #ifdef _PR_NICE_PRIORITY_SCHEDULING pid_t tid; #endif #ifdef _PR_NICE_PRIORITY_SCHEDULING /* * We need to know the kernel thread ID of each thread in order to * set its nice value hence we do it here instead of at creation time. */ tid = gettid(); errno = 0; rv = getpriority(PRIO_PROCESS, 0); /* If we cannot read the main thread's nice value don't try to change the * new thread's nice value. */ if (errno == 0) { setpriority(PRIO_PROCESS, tid, pt_RelativePriority(rv, thred->priority)); } #endif /* ** DCE Threads can't detach during creation, so do it late. ** I would like to do it only here, but that doesn't seem ** to work. */ #if defined(_PR_DCETHREADS) if (detached) { /* pthread_detach() modifies its argument, so we must pass a copy */ pthread_t self = id; rv = pthread_detach(&self); PR_ASSERT(0 == rv); } #endif /* defined(_PR_DCETHREADS) */ /* Set up the thread stack information */ _PR_InitializeStack(thred->stack); /* * Set within the current thread the pointer to our object. * This object will be deleted when the thread termintates, * whether in a join or detached (see _PR_InitThreads()). */ rv = pthread_setspecific(pt_book.key, thred); PR_ASSERT(0 == rv); /* make the thread visible to the rest of the runtime */ PR_Lock(pt_book.ml); /* * Both the parent thread and this new thread set thred->id. * The new thread must ensure that thred->id is set before * it executes its startFunc. The parent thread must ensure * that thred->id is set before PR_CreateThread() returns. * Both threads set thred->id while holding pt_book.ml and * use thred->idSet to ensure thred->id is written only once. */ if (!thred->idSet) { thred->id = id; thred->idSet = PR_TRUE; } else { PR_ASSERT(pthread_equal(thred->id, id)); } #ifdef _PR_NICE_PRIORITY_SCHEDULING thred->tid = tid; PR_NotifyAllCondVar(pt_book.cv); #endif /* If this is a GCABLE thread, set its state appropriately */ if (thred->suspend & PT_THREAD_SETGCABLE) thred->state |= PT_THREAD_GCABLE; thred->suspend = 0; thred->prev = pt_book.last; if (pt_book.last) pt_book.last->next = thred; else pt_book.first = thred; thred->next = NULL; pt_book.last = thred; PR_Unlock(pt_book.ml); thred->startFunc(thred->arg); /* make visible to the client */ /* unhook the thread from the runtime */ PR_Lock(pt_book.ml); /* * At this moment, PR_CreateThread() may not have set thred->id yet. * It is safe for a detached thread to free thred only after * PR_CreateThread() has accessed thred->id and thred->idSet. */ if (detached) { while (!thred->okToDelete) PR_WaitCondVar(pt_book.cv, PR_INTERVAL_NO_TIMEOUT); } if (thred->state & PT_THREAD_SYSTEM) pt_book.system -= 1; else if (--pt_book.user == pt_book.this_many) PR_NotifyAllCondVar(pt_book.cv); if (NULL == thred->prev) pt_book.first = thred->next; else thred->prev->next = thred->next; if (NULL == thred->next) pt_book.last = thred->prev; else thred->next->prev = thred->prev; PR_Unlock(pt_book.ml); /* * Here we set the pthread's backpointer to the PRThread to NULL. * Otherwise the destructor would get called eagerly as the thread * returns to the pthread runtime. The joining thread would them be * the proud possessor of a dangling reference. However, this is the * last chance to delete the object if the thread is detached, so * just let the destructor do the work. */ if (PR_FALSE == detached) { /* Call TPD destructors on this thread. */ _PR_DestroyThreadPrivate(thred); rv = pthread_setspecific(pt_book.key, NULL); PR_ASSERT(0 == rv); } return NULL; } /* _pt_root */ static PRThread* pt_AttachThread(void) { PRThread *thred = NULL; /* * NSPR must have been initialized when PR_AttachThread is called. * We cannot have PR_AttachThread call implicit initialization * because if multiple threads call PR_AttachThread simultaneously, * NSPR may be initialized more than once. * We can't call any function that calls PR_GetCurrentThread() * either (e.g., PR_SetError()) as that will result in infinite * recursion. */ if (!_pr_initialized) return NULL; /* PR_NEWZAP must not call PR_GetCurrentThread() */ thred = PR_NEWZAP(PRThread); if (NULL != thred) { int rv; thred->priority = PR_PRIORITY_NORMAL; thred->id = pthread_self(); thred->idSet = PR_TRUE; #ifdef _PR_NICE_PRIORITY_SCHEDULING thred->tid = gettid(); #endif rv = pthread_setspecific(pt_book.key, thred); PR_ASSERT(0 == rv); thred->state = PT_THREAD_GLOBAL | PT_THREAD_FOREIGN; PR_Lock(pt_book.ml); /* then put it into the list */ thred->prev = pt_book.last; if (pt_book.last) pt_book.last->next = thred; else pt_book.first = thred; thred->next = NULL; pt_book.last = thred; PR_Unlock(pt_book.ml); } return thred; /* may be NULL */ } /* pt_AttachThread */ static PRThread* _PR_CreateThread( PRThreadType type, void (*start)(void *arg), void *arg, PRThreadPriority priority, PRThreadScope scope, PRThreadState state, PRUint32 stackSize, PRBool isGCAble) { int rv; PRThread *thred; pthread_attr_t tattr; if (!_pr_initialized) _PR_ImplicitInitialization(); if ((PRIntn)PR_PRIORITY_FIRST > (PRIntn)priority) priority = PR_PRIORITY_FIRST; else if ((PRIntn)PR_PRIORITY_LAST < (PRIntn)priority) priority = PR_PRIORITY_LAST; rv = _PT_PTHREAD_ATTR_INIT(&tattr); PR_ASSERT(0 == rv); if (EPERM != pt_schedpriv) { #if !defined(_PR_DCETHREADS) && defined(_POSIX_THREAD_PRIORITY_SCHEDULING) struct sched_param schedule; #endif #if defined(_POSIX_THREAD_PRIORITY_SCHEDULING) rv = pthread_attr_setinheritsched(&tattr, PTHREAD_EXPLICIT_SCHED); PR_ASSERT(0 == rv); #endif /* Use the default scheduling policy */ #if defined(_PR_DCETHREADS) rv = pthread_attr_setprio(&tattr, pt_PriorityMap(priority)); PR_ASSERT(0 == rv); #elif defined(_POSIX_THREAD_PRIORITY_SCHEDULING) rv = pthread_attr_getschedparam(&tattr, &schedule); PR_ASSERT(0 == rv); schedule.sched_priority = pt_PriorityMap(priority); rv = pthread_attr_setschedparam(&tattr, &schedule); PR_ASSERT(0 == rv); #ifdef NTO rv = pthread_attr_setschedpolicy(&tattr, SCHED_RR); /* Round Robin */ PR_ASSERT(0 == rv); #endif #endif /* !defined(_PR_DCETHREADS) */ } /* * DCE threads can't set detach state before creating the thread. * AIX can't set detach late. Why can't we all just get along? */ #if !defined(_PR_DCETHREADS) rv = pthread_attr_setdetachstate(&tattr, ((PR_JOINABLE_THREAD == state) ? PTHREAD_CREATE_JOINABLE : PTHREAD_CREATE_DETACHED)); PR_ASSERT(0 == rv); #endif /* !defined(_PR_DCETHREADS) */ /* * If stackSize is 0, we use the default pthread stack size. */ if (stackSize) { #ifdef _MD_MINIMUM_STACK_SIZE if (stackSize < _MD_MINIMUM_STACK_SIZE) stackSize = _MD_MINIMUM_STACK_SIZE; #endif rv = pthread_attr_setstacksize(&tattr, stackSize); PR_ASSERT(0 == rv); } thred = PR_NEWZAP(PRThread); if (NULL == thred) { PR_SetError(PR_OUT_OF_MEMORY_ERROR, errno); goto done; } else { pthread_t id; thred->arg = arg; thred->startFunc = start; thred->priority = priority; if (PR_UNJOINABLE_THREAD == state) thred->state |= PT_THREAD_DETACHED; if (PR_LOCAL_THREAD == scope) scope = PR_GLOBAL_THREAD; if (PR_GLOBAL_BOUND_THREAD == scope) { #if defined(_POSIX_THREAD_PRIORITY_SCHEDULING) rv = pthread_attr_setscope(&tattr, PTHREAD_SCOPE_SYSTEM); if (rv) { /* * system scope not supported */ scope = PR_GLOBAL_THREAD; /* * reset scope */ rv = pthread_attr_setscope(&tattr, PTHREAD_SCOPE_PROCESS); PR_ASSERT(0 == rv); } #endif } if (PR_GLOBAL_THREAD == scope) thred->state |= PT_THREAD_GLOBAL; else if (PR_GLOBAL_BOUND_THREAD == scope) thred->state |= (PT_THREAD_GLOBAL | PT_THREAD_BOUND); else /* force it global */ thred->state |= PT_THREAD_GLOBAL; if (PR_SYSTEM_THREAD == type) thred->state |= PT_THREAD_SYSTEM; thred->suspend =(isGCAble) ? PT_THREAD_SETGCABLE : 0; thred->stack = PR_NEWZAP(PRThreadStack); if (thred->stack == NULL) { PRIntn oserr = errno; PR_Free(thred); /* all that work ... poof! */ PR_SetError(PR_OUT_OF_MEMORY_ERROR, oserr); thred = NULL; /* and for what? */ goto done; } thred->stack->stackSize = stackSize; thred->stack->thr = thred; #ifdef PT_NO_SIGTIMEDWAIT pthread_mutex_init(&thred->suspendResumeMutex,NULL); pthread_cond_init(&thred->suspendResumeCV,NULL); #endif /* make the thread counted to the rest of the runtime */ PR_Lock(pt_book.ml); if (PR_SYSTEM_THREAD == type) pt_book.system += 1; else pt_book.user += 1; PR_Unlock(pt_book.ml); /* * We pass a pointer to a local copy (instead of thred->id) * to pthread_create() because who knows what wacky things * pthread_create() may be doing to its argument. */ rv = _PT_PTHREAD_CREATE(&id, tattr, _pt_root, thred); #if !defined(_PR_DCETHREADS) if (EPERM == rv) { #if defined(IRIX) if (PR_GLOBAL_BOUND_THREAD == scope) { /* * SCOPE_SYSTEM requires appropriate privilege * reset to process scope and try again */ rv = pthread_attr_setscope(&tattr, PTHREAD_SCOPE_PROCESS); PR_ASSERT(0 == rv); thred->state &= ~PT_THREAD_BOUND; } #else /* Remember that we don't have thread scheduling privilege. */ pt_schedpriv = EPERM; PR_LOG(_pr_thread_lm, PR_LOG_MIN, ("_PR_CreateThread: no thread scheduling privilege")); /* Try creating the thread again without setting priority. */ #if defined(_POSIX_THREAD_PRIORITY_SCHEDULING) rv = pthread_attr_setinheritsched(&tattr, PTHREAD_INHERIT_SCHED); PR_ASSERT(0 == rv); #endif #endif /* IRIX */ rv = _PT_PTHREAD_CREATE(&id, tattr, _pt_root, thred); } #endif if (0 != rv) { #if defined(_PR_DCETHREADS) PRIntn oserr = errno; #else PRIntn oserr = rv; #endif PR_Lock(pt_book.ml); if (thred->state & PT_THREAD_SYSTEM) pt_book.system -= 1; else if (--pt_book.user == pt_book.this_many) PR_NotifyAllCondVar(pt_book.cv); PR_Unlock(pt_book.ml); PR_Free(thred->stack); PR_Free(thred); /* all that work ... poof! */ PR_SetError(PR_INSUFFICIENT_RESOURCES_ERROR, oserr); thred = NULL; /* and for what? */ goto done; } PR_Lock(pt_book.ml); /* * Both the parent thread and this new thread set thred->id. * The parent thread must ensure that thred->id is set before * PR_CreateThread() returns. (See comments in _pt_root().) */ if (!thred->idSet) { thred->id = id; thred->idSet = PR_TRUE; } else { PR_ASSERT(pthread_equal(thred->id, id)); } /* * If the new thread is detached, tell it that PR_CreateThread() has * accessed thred->id and thred->idSet so it's ok to delete thred. */ if (PR_UNJOINABLE_THREAD == state) { thred->okToDelete = PR_TRUE; PR_NotifyAllCondVar(pt_book.cv); } PR_Unlock(pt_book.ml); } done: rv = _PT_PTHREAD_ATTR_DESTROY(&tattr); PR_ASSERT(0 == rv); return thred; } /* _PR_CreateThread */ PR_IMPLEMENT(PRThread*) PR_CreateThread( PRThreadType type, void (*start)(void *arg), void *arg, PRThreadPriority priority, PRThreadScope scope, PRThreadState state, PRUint32 stackSize) { return _PR_CreateThread( type, start, arg, priority, scope, state, stackSize, PR_FALSE); } /* PR_CreateThread */ PR_IMPLEMENT(PRThread*) PR_CreateThreadGCAble( PRThreadType type, void (*start)(void *arg), void *arg, PRThreadPriority priority, PRThreadScope scope, PRThreadState state, PRUint32 stackSize) { return _PR_CreateThread( type, start, arg, priority, scope, state, stackSize, PR_TRUE); } /* PR_CreateThreadGCAble */ PR_IMPLEMENT(void*) GetExecutionEnvironment(PRThread *thred) { return thred->environment; } /* GetExecutionEnvironment */ PR_IMPLEMENT(void) SetExecutionEnvironment(PRThread *thred, void *env) { thred->environment = env; } /* SetExecutionEnvironment */ PR_IMPLEMENT(PRThread*) PR_AttachThread( PRThreadType type, PRThreadPriority priority, PRThreadStack *stack) { return PR_GetCurrentThread(); } /* PR_AttachThread */ PR_IMPLEMENT(PRStatus) PR_JoinThread(PRThread *thred) { int rv = -1; void *result = NULL; PR_ASSERT(thred != NULL); if ((0xafafafaf == thred->state) || (PT_THREAD_DETACHED == (PT_THREAD_DETACHED & thred->state)) || (PT_THREAD_FOREIGN == (PT_THREAD_FOREIGN & thred->state))) { /* * This might be a bad address, but if it isn't, the state should * either be an unjoinable thread or it's already had the object * deleted. However, the client that called join on a detached * thread deserves all the rath I can muster.... */ PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); PR_LogPrint( "PR_JoinThread: %p not joinable | already smashed\n", thred); } else { pthread_t id = thred->id; rv = pthread_join(id, &result); PR_ASSERT(rv == 0 && result == NULL); if (0 == rv) { #ifdef _PR_DCETHREADS rv = pthread_detach(&id); PR_ASSERT(0 == rv); #endif /* * PR_FALSE, because the thread already called the TPD * destructors before exiting _pt_root. */ _pt_thread_death_internal(thred, PR_FALSE); } else { PRErrorCode prerror; switch (rv) { case EINVAL: /* not a joinable thread */ case ESRCH: /* no thread with given ID */ prerror = PR_INVALID_ARGUMENT_ERROR; break; case EDEADLK: /* a thread joining with itself */ prerror = PR_DEADLOCK_ERROR; break; default: prerror = PR_UNKNOWN_ERROR; break; } PR_SetError(prerror, rv); } } return (0 == rv) ? PR_SUCCESS : PR_FAILURE; } /* PR_JoinThread */ PR_IMPLEMENT(void) PR_DetachThread(void) { void *thred; int rv; _PT_PTHREAD_GETSPECIFIC(pt_book.key, thred); if (NULL == thred) return; _pt_thread_death(thred); rv = pthread_setspecific(pt_book.key, NULL); PR_ASSERT(0 == rv); } /* PR_DetachThread */ PR_IMPLEMENT(PRThread*) PR_GetCurrentThread(void) { void *thred; if (!_pr_initialized) _PR_ImplicitInitialization(); _PT_PTHREAD_GETSPECIFIC(pt_book.key, thred); if (NULL == thred) thred = pt_AttachThread(); PR_ASSERT(NULL != thred); return (PRThread*)thred; } /* PR_GetCurrentThread */ PR_IMPLEMENT(PRThreadScope) PR_GetThreadScope(const PRThread *thred) { return (thred->state & PT_THREAD_BOUND) ? PR_GLOBAL_BOUND_THREAD : PR_GLOBAL_THREAD; } /* PR_GetThreadScope() */ PR_IMPLEMENT(PRThreadType) PR_GetThreadType(const PRThread *thred) { return (thred->state & PT_THREAD_SYSTEM) ? PR_SYSTEM_THREAD : PR_USER_THREAD; } PR_IMPLEMENT(PRThreadState) PR_GetThreadState(const PRThread *thred) { return (thred->state & PT_THREAD_DETACHED) ? PR_UNJOINABLE_THREAD : PR_JOINABLE_THREAD; } /* PR_GetThreadState */ PR_IMPLEMENT(PRThreadPriority) PR_GetThreadPriority(const PRThread *thred) { PR_ASSERT(thred != NULL); return thred->priority; } /* PR_GetThreadPriority */ PR_IMPLEMENT(void) PR_SetThreadPriority(PRThread *thred, PRThreadPriority newPri) { PRIntn rv = -1; PR_ASSERT(NULL != thred); if ((PRIntn)PR_PRIORITY_FIRST > (PRIntn)newPri) newPri = PR_PRIORITY_FIRST; else if ((PRIntn)PR_PRIORITY_LAST < (PRIntn)newPri) newPri = PR_PRIORITY_LAST; #if defined(_PR_DCETHREADS) rv = pthread_setprio(thred->id, pt_PriorityMap(newPri)); /* pthread_setprio returns the old priority */ #elif defined(_POSIX_THREAD_PRIORITY_SCHEDULING) if (EPERM != pt_schedpriv) { int policy; struct sched_param schedule; rv = pthread_getschedparam(thred->id, &policy, &schedule); if(0 == rv) { schedule.sched_priority = pt_PriorityMap(newPri); rv = pthread_setschedparam(thred->id, policy, &schedule); if (EPERM == rv) { pt_schedpriv = EPERM; PR_LOG(_pr_thread_lm, PR_LOG_MIN, ("PR_SetThreadPriority: no thread scheduling privilege")); } } if (rv != 0) rv = -1; } #elif defined(_PR_NICE_PRIORITY_SCHEDULING) PR_Lock(pt_book.ml); while (thred->tid == 0) PR_WaitCondVar(pt_book.cv, PR_INTERVAL_NO_TIMEOUT); PR_Unlock(pt_book.ml); errno = 0; rv = getpriority(PRIO_PROCESS, 0); /* Do not proceed unless we know the main thread's nice value. */ if (errno == 0) { rv = setpriority(PRIO_PROCESS, thred->tid, pt_RelativePriority(rv, newPri)); if (rv == -1) { /* We don't set pt_schedpriv to EPERM in case errno == EPERM * because adjusting the nice value might be permitted for certain * ranges but not for others. */ PR_LOG(_pr_thread_lm, PR_LOG_MIN, ("PR_SetThreadPriority: setpriority failed with error %d", errno)); } } #endif thred->priority = newPri; } /* PR_SetThreadPriority */ PR_IMPLEMENT(PRStatus) PR_Interrupt(PRThread *thred) { /* ** If the target thread indicates that it's waiting, ** find the condition and broadcast to it. Broadcast ** since we don't know which thread (if there are more ** than one). This sounds risky, but clients must ** test their invariants when resumed from a wait and ** I don't expect very many threads to be waiting on ** a single condition and I don't expect interrupt to ** be used very often. ** ** I don't know why I thought this would work. Must have ** been one of those weaker momements after I'd been ** smelling the vapors. ** ** Even with the followng changes it is possible that ** the pointer to the condition variable is pointing ** at a bogus value. Will the unerlying code detect ** that? */ PRCondVar *cv; PR_ASSERT(NULL != thred); if (NULL == thred) return PR_FAILURE; thred->state |= PT_THREAD_ABORTED; cv = thred->waiting; if ((NULL != cv) && !thred->interrupt_blocked) { PRIntn rv; (void)PR_ATOMIC_INCREMENT(&cv->notify_pending); rv = pthread_cond_broadcast(&cv->cv); PR_ASSERT(0 == rv); if (0 > PR_ATOMIC_DECREMENT(&cv->notify_pending)) PR_DestroyCondVar(cv); } return PR_SUCCESS; } /* PR_Interrupt */ PR_IMPLEMENT(void) PR_ClearInterrupt(void) { PRThread *me = PR_GetCurrentThread(); me->state &= ~PT_THREAD_ABORTED; } /* PR_ClearInterrupt */ PR_IMPLEMENT(void) PR_BlockInterrupt(void) { PRThread *me = PR_GetCurrentThread(); _PT_THREAD_BLOCK_INTERRUPT(me); } /* PR_BlockInterrupt */ PR_IMPLEMENT(void) PR_UnblockInterrupt(void) { PRThread *me = PR_GetCurrentThread(); _PT_THREAD_UNBLOCK_INTERRUPT(me); } /* PR_UnblockInterrupt */ PR_IMPLEMENT(PRStatus) PR_Yield(void) { static PRBool warning = PR_TRUE; if (warning) warning = _PR_Obsolete( "PR_Yield()", "PR_Sleep(PR_INTERVAL_NO_WAIT)"); return PR_Sleep(PR_INTERVAL_NO_WAIT); } PR_IMPLEMENT(PRStatus) PR_Sleep(PRIntervalTime ticks) { PRStatus rv = PR_SUCCESS; if (!_pr_initialized) _PR_ImplicitInitialization(); if (PR_INTERVAL_NO_WAIT == ticks) { _PT_PTHREAD_YIELD(); } else { PRCondVar *cv; PRIntervalTime timein; timein = PR_IntervalNow(); cv = PR_NewCondVar(_pr_sleeplock); PR_ASSERT(cv != NULL); PR_Lock(_pr_sleeplock); do { PRIntervalTime now = PR_IntervalNow(); PRIntervalTime delta = now - timein; if (delta > ticks) break; rv = PR_WaitCondVar(cv, ticks - delta); } while (PR_SUCCESS == rv); PR_Unlock(_pr_sleeplock); PR_DestroyCondVar(cv); } return rv; } /* PR_Sleep */ static void _pt_thread_death(void *arg) { void *thred; int rv; _PT_PTHREAD_GETSPECIFIC(pt_book.key, thred); if (NULL == thred) { /* * Have PR_GetCurrentThread return the expected value to the * destructors. */ rv = pthread_setspecific(pt_book.key, arg); PR_ASSERT(0 == rv); } /* PR_TRUE for: call destructors */ _pt_thread_death_internal(arg, PR_TRUE); if (NULL == thred) { rv = pthread_setspecific(pt_book.key, NULL); PR_ASSERT(0 == rv); } } static void _pt_thread_death_internal(void *arg, PRBool callDestructors) { PRThread *thred = (PRThread*)arg; if (thred->state & (PT_THREAD_FOREIGN|PT_THREAD_PRIMORD)) { PR_Lock(pt_book.ml); if (NULL == thred->prev) pt_book.first = thred->next; else thred->prev->next = thred->next; if (NULL == thred->next) pt_book.last = thred->prev; else thred->next->prev = thred->prev; PR_Unlock(pt_book.ml); } if (callDestructors) _PR_DestroyThreadPrivate(thred); PR_Free(thred->privateData); if (NULL != thred->errorString) PR_Free(thred->errorString); if (NULL != thred->name) PR_Free(thred->name); PR_Free(thred->stack); if (NULL != thred->syspoll_list) PR_Free(thred->syspoll_list); #if defined(_PR_POLL_WITH_SELECT) if (NULL != thred->selectfd_list) PR_Free(thred->selectfd_list); #endif #if defined(DEBUG) memset(thred, 0xaf, sizeof(PRThread)); #endif /* defined(DEBUG) */ PR_Free(thred); } /* _pt_thread_death */ void _PR_InitThreads( PRThreadType type, PRThreadPriority priority, PRUintn maxPTDs) { int rv; PRThread *thred; PR_ASSERT(priority == PR_PRIORITY_NORMAL); #ifdef _PR_NEED_PTHREAD_INIT /* * On BSD/OS (3.1 and 4.0), the pthread subsystem is lazily * initialized, but pthread_self() fails to initialize * pthreads and hence returns a null thread ID if invoked * by the primordial thread before any other pthread call. * So we explicitly initialize pthreads here. */ pthread_init(); #endif #if defined(_PR_DCETHREADS) || defined(_POSIX_THREAD_PRIORITY_SCHEDULING) #if defined(FREEBSD) { pthread_attr_t attr; int policy; /* get the min and max priorities of the default policy */ pthread_attr_init(&attr); pthread_attr_setinheritsched(&attr, PTHREAD_EXPLICIT_SCHED); pthread_attr_getschedpolicy(&attr, &policy); pt_book.minPrio = sched_get_priority_min(policy); PR_ASSERT(-1 != pt_book.minPrio); pt_book.maxPrio = sched_get_priority_max(policy); PR_ASSERT(-1 != pt_book.maxPrio); pthread_attr_destroy(&attr); } #else /* ** These might be function evaluations */ pt_book.minPrio = PT_PRIO_MIN; pt_book.maxPrio = PT_PRIO_MAX; #endif #endif PR_ASSERT(NULL == pt_book.ml); pt_book.ml = PR_NewLock(); PR_ASSERT(NULL != pt_book.ml); pt_book.cv = PR_NewCondVar(pt_book.ml); PR_ASSERT(NULL != pt_book.cv); thred = PR_NEWZAP(PRThread); PR_ASSERT(NULL != thred); thred->arg = NULL; thred->startFunc = NULL; thred->priority = priority; thred->id = pthread_self(); thred->idSet = PR_TRUE; #ifdef _PR_NICE_PRIORITY_SCHEDULING thred->tid = gettid(); #endif thred->state = (PT_THREAD_DETACHED | PT_THREAD_PRIMORD); if (PR_SYSTEM_THREAD == type) { thred->state |= PT_THREAD_SYSTEM; pt_book.system += 1; pt_book.this_many = 0; } else { pt_book.user += 1; pt_book.this_many = 1; } thred->next = thred->prev = NULL; pt_book.first = pt_book.last = thred; thred->stack = PR_NEWZAP(PRThreadStack); PR_ASSERT(thred->stack != NULL); thred->stack->stackSize = 0; thred->stack->thr = thred; _PR_InitializeStack(thred->stack); /* * Create a key for our use to store a backpointer in the pthread * to our PRThread object. This object gets deleted when the thread * returns from its root in the case of a detached thread. Other * threads delete the objects in Join. * * NB: The destructor logic seems to have a bug so it isn't used. * NBB: Oh really? I'm going to give it a spin - AOF 19 June 1998. * More info - the problem is that pthreads calls the destructor * eagerly as the thread returns from its root, rather than lazily * after the thread is joined. Therefore, threads that are joining * and holding PRThread references are actually holding pointers to * nothing. */ rv = _PT_PTHREAD_KEY_CREATE(&pt_book.key, _pt_thread_death); if (0 != rv) PR_Assert("0 == rv", __FILE__, __LINE__); pt_book.keyCreated = PR_TRUE; rv = pthread_setspecific(pt_book.key, thred); PR_ASSERT(0 == rv); } /* _PR_InitThreads */ #ifdef __GNUC__ /* * GCC supports the constructor and destructor attributes as of * version 2.5. */ static void _PR_Fini(void) __attribute__ ((destructor)); #elif defined(__SUNPRO_C) /* * Sun Studio compiler */ #pragma fini(_PR_Fini) static void _PR_Fini(void); #elif defined(HPUX) /* * Current versions of HP C compiler define __HP_cc. * HP C compiler A.11.01.20 doesn't define __HP_cc. */ #if defined(__ia64) || defined(_LP64) #pragma FINI "_PR_Fini" static void _PR_Fini(void); #else /* * Only HP-UX 10.x style initializers are supported in 32-bit links. * Need to use the +I PR_HPUX10xInit linker option. */ #include <dl.h> static void _PR_Fini(void); void PR_HPUX10xInit(shl_t handle, int loading) { /* * This function is called when a shared library is loaded as well * as when the shared library is unloaded. Note that it may not * be called when the user's program terminates. * * handle is the shl_load API handle for the shared library being * initialized. * * loading is non-zero at startup and zero at termination. */ if (loading) { /* ... do some initializations ... */ } else { _PR_Fini(); } } #endif #elif defined(AIX) /* Need to use the -binitfini::_PR_Fini linker option. */ #endif void _PR_Fini(void) { void *thred; int rv; if (!_pr_initialized) { /* Either NSPR was never successfully initialized or * PR_Cleanup has been called already. */ if (pt_book.keyCreated) { rv = pthread_key_delete(pt_book.key); PR_ASSERT(0 == rv); pt_book.keyCreated = PR_FALSE; } return; } _PT_PTHREAD_GETSPECIFIC(pt_book.key, thred); if (NULL != thred) { /* * PR_FALSE, because it is unsafe to call back to the * thread private data destructors at final cleanup. */ _pt_thread_death_internal(thred, PR_FALSE); rv = pthread_setspecific(pt_book.key, NULL); PR_ASSERT(0 == rv); } rv = pthread_key_delete(pt_book.key); PR_ASSERT(0 == rv); pt_book.keyCreated = PR_FALSE; /* TODO: free other resources used by NSPR */ /* _pr_initialized = PR_FALSE; */ } /* _PR_Fini */ PR_IMPLEMENT(PRStatus) PR_Cleanup(void) { PRThread *me = PR_GetCurrentThread(); int rv; PR_LOG(_pr_thread_lm, PR_LOG_MIN, ("PR_Cleanup: shutting down NSPR")); PR_ASSERT(me->state & PT_THREAD_PRIMORD); if (me->state & PT_THREAD_PRIMORD) { PR_Lock(pt_book.ml); while (pt_book.user > pt_book.this_many) PR_WaitCondVar(pt_book.cv, PR_INTERVAL_NO_TIMEOUT); if (me->state & PT_THREAD_SYSTEM) pt_book.system -= 1; else pt_book.user -= 1; PR_Unlock(pt_book.ml); _PR_MD_EARLY_CLEANUP(); _PR_CleanupMW(); _PR_CleanupTime(); _PR_CleanupDtoa(); _PR_CleanupCallOnce(); _PR_ShutdownLinker(); _PR_LogCleanup(); _PR_CleanupNet(); /* Close all the fd's before calling _PR_CleanupIO */ _PR_CleanupIO(); _PR_CleanupCMon(); _pt_thread_death(me); rv = pthread_setspecific(pt_book.key, NULL); PR_ASSERT(0 == rv); /* * I am not sure if it's safe to delete the cv and lock here, * since there may still be "system" threads around. If this * call isn't immediately prior to exiting, then there's a * problem. */ if (0 == pt_book.system) { PR_DestroyCondVar(pt_book.cv); pt_book.cv = NULL; PR_DestroyLock(pt_book.ml); pt_book.ml = NULL; } PR_DestroyLock(_pr_sleeplock); _pr_sleeplock = NULL; _PR_CleanupLayerCache(); _PR_CleanupEnv(); #ifdef _PR_ZONE_ALLOCATOR _PR_DestroyZones(); #endif _pr_initialized = PR_FALSE; return PR_SUCCESS; } return PR_FAILURE; } /* PR_Cleanup */ PR_IMPLEMENT(void) PR_ProcessExit(PRIntn status) { _exit(status); } PR_IMPLEMENT(PRUint32) PR_GetThreadID(PRThread *thred) { #if defined(_PR_DCETHREADS) return (PRUint32)&thred->id; /* this is really a sham! */ #else return (PRUint32)thred->id; /* and I don't know what they will do with it */ #endif } /* * $$$ * The following two thread-to-processor affinity functions are not * yet implemented for pthreads. By the way, these functions should return * PRStatus rather than PRInt32 to indicate the success/failure status. * $$$ */ PR_IMPLEMENT(PRInt32) PR_GetThreadAffinityMask(PRThread *thread, PRUint32 *mask) { return 0; /* not implemented */ } PR_IMPLEMENT(PRInt32) PR_SetThreadAffinityMask(PRThread *thread, PRUint32 mask ) { return 0; /* not implemented */ } PR_IMPLEMENT(void) PR_SetThreadDumpProc(PRThread* thread, PRThreadDumpProc dump, void *arg) { thread->dump = dump; thread->dumpArg = arg; } /* * Garbage collection support follows. */ #if defined(_PR_DCETHREADS) /* * statics for Garbage Collection support. We don't need to protect these * signal masks since the garbage collector itself is protected by a lock * and multiple threads will not be garbage collecting at the same time. */ static sigset_t javagc_vtalarm_sigmask; static sigset_t javagc_intsoff_sigmask; #else /* defined(_PR_DCETHREADS) */ /* a bogus signal mask for forcing a timed wait */ /* Not so bogus in AIX as we really do a sigwait */ static sigset_t sigwait_set; static struct timespec onemillisec = {0, 1000000L}; #ifndef PT_NO_SIGTIMEDWAIT static struct timespec hundredmillisec = {0, 100000000L}; #endif static void suspend_signal_handler(PRIntn sig); #ifdef PT_NO_SIGTIMEDWAIT static void null_signal_handler(PRIntn sig); #endif #endif /* defined(_PR_DCETHREADS) */ /* * Linux pthreads use SIGUSR1 and SIGUSR2 internally, which * conflict with the use of these two signals in our GC support. * So we don't know how to support GC on Linux pthreads. */ static void init_pthread_gc_support(void) { #ifndef SYMBIAN PRIntn rv; #if defined(_PR_DCETHREADS) rv = sigemptyset(&javagc_vtalarm_sigmask); PR_ASSERT(0 == rv); rv = sigaddset(&javagc_vtalarm_sigmask, SIGVTALRM); PR_ASSERT(0 == rv); #else /* defined(_PR_DCETHREADS) */ { struct sigaction sigact_usr2; sigact_usr2.sa_handler = suspend_signal_handler; sigact_usr2.sa_flags = SA_RESTART; sigemptyset (&sigact_usr2.sa_mask); rv = sigaction (SIGUSR2, &sigact_usr2, NULL); PR_ASSERT(0 == rv); sigemptyset (&sigwait_set); #if defined(PT_NO_SIGTIMEDWAIT) sigaddset (&sigwait_set, SIGUSR1); #else sigaddset (&sigwait_set, SIGUSR2); #endif /* defined(PT_NO_SIGTIMEDWAIT) */ } #if defined(PT_NO_SIGTIMEDWAIT) { struct sigaction sigact_null; sigact_null.sa_handler = null_signal_handler; sigact_null.sa_flags = SA_RESTART; sigemptyset (&sigact_null.sa_mask); rv = sigaction (SIGUSR1, &sigact_null, NULL); PR_ASSERT(0 ==rv); } #endif /* defined(PT_NO_SIGTIMEDWAIT) */ #endif /* defined(_PR_DCETHREADS) */ #endif /* SYMBIAN */ } PR_IMPLEMENT(void) PR_SetThreadGCAble(void) { PR_Lock(pt_book.ml); PR_GetCurrentThread()->state |= PT_THREAD_GCABLE; PR_Unlock(pt_book.ml); } PR_IMPLEMENT(void) PR_ClearThreadGCAble(void) { PR_Lock(pt_book.ml); PR_GetCurrentThread()->state &= (~PT_THREAD_GCABLE); PR_Unlock(pt_book.ml); } #if defined(DEBUG) static PRBool suspendAllOn = PR_FALSE; #endif static PRBool suspendAllSuspended = PR_FALSE; PR_IMPLEMENT(PRStatus) PR_EnumerateThreads(PREnumerator func, void *arg) { PRIntn count = 0; PRStatus rv = PR_SUCCESS; PRThread* thred = pt_book.first; #if defined(DEBUG) || defined(FORCE_PR_ASSERT) #if !defined(_PR_DCETHREADS) PRThread *me = PR_GetCurrentThread(); #endif #endif PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("Begin PR_EnumerateThreads\n")); /* * $$$ * Need to suspend all threads other than me before doing this. * This is really a gross and disgusting thing to do. The only * good thing is that since all other threads are suspended, holding * the lock during a callback seems like child's play. * $$$ */ PR_ASSERT(suspendAllOn); while (thred != NULL) { /* Steve Morse, 4-23-97: Note that we can't walk a queue by taking * qp->next after applying the function "func". In particular, "func" * might remove the thread from the queue and put it into another one in * which case qp->next no longer points to the next entry in the original * queue. * * To get around this problem, we save qp->next in qp_next before applying * "func" and use that saved value as the next value after applying "func". */ PRThread* next = thred->next; if (_PT_IS_GCABLE_THREAD(thred)) { #if !defined(_PR_DCETHREADS) PR_ASSERT((thred == me) || (thred->suspend & PT_THREAD_SUSPENDED)); #endif PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("In PR_EnumerateThreads callback thread %p thid = %X\n", thred, thred->id)); rv = func(thred, count++, arg); if (rv != PR_SUCCESS) return rv; } thred = next; } PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("End PR_EnumerateThreads count = %d \n", count)); return rv; } /* PR_EnumerateThreads */ /* * PR_SuspendAll and PR_ResumeAll are called during garbage collection. The strategy * we use is to send a SIGUSR2 signal to every gc able thread that we intend to suspend. * The signal handler will record the stack pointer and will block until resumed by * the resume call. Since the signal handler is the last routine called for the * suspended thread, the stack pointer will also serve as a place where all the * registers have been saved on the stack for the previously executing routines. * * Through global variables, we also make sure that PR_Suspend and PR_Resume does not * proceed until the thread is suspended or resumed. */ #if !defined(_PR_DCETHREADS) /* * In the signal handler, we can not use condition variable notify or wait. * This does not work consistently across all pthread platforms. We also can not * use locking since that does not seem to work reliably across platforms. * Only thing we can do is yielding while testing for a global condition * to change. This does work on pthread supported platforms. We may have * to play with priortities if there are any problems detected. */ /* * In AIX, you cannot use ANY pthread calls in the signal handler except perhaps * pthread_yield. But that is horribly inefficient. Hence we use only sigwait, no * sigtimedwait is available. We need to use another user signal, SIGUSR1. Actually * SIGUSR1 is also used by exec in Java. So our usage here breaks the exec in Java, * for AIX. You cannot use pthread_cond_wait or pthread_delay_np in the signal * handler as all synchronization mechanisms just break down. */ #if defined(PT_NO_SIGTIMEDWAIT) static void null_signal_handler(PRIntn sig) { return; } #endif static void suspend_signal_handler(PRIntn sig) { PRThread *me = PR_GetCurrentThread(); PR_ASSERT(me != NULL); PR_ASSERT(_PT_IS_GCABLE_THREAD(me)); PR_ASSERT((me->suspend & PT_THREAD_SUSPENDED) == 0); PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("Begin suspend_signal_handler thred %p thread id = %X\n", me, me->id)); /* * save stack pointer */ me->sp = &me; /* At this point, the thread's stack pointer has been saved, And it is going to enter a wait loop until it is resumed. So it is _really_ suspended */ me->suspend |= PT_THREAD_SUSPENDED; /* * now, block current thread */ #if defined(PT_NO_SIGTIMEDWAIT) pthread_cond_signal(&me->suspendResumeCV); while (me->suspend & PT_THREAD_SUSPENDED) { #if !defined(FREEBSD) && !defined(NETBSD) && !defined(OPENBSD) \ && !defined(BSDI) && !defined(UNIXWARE) \ && !defined(DARWIN) && !defined(RISCOS) \ && !defined(SYMBIAN) /*XXX*/ PRIntn rv; sigwait(&sigwait_set, &rv); #endif } me->suspend |= PT_THREAD_RESUMED; pthread_cond_signal(&me->suspendResumeCV); #else /* defined(PT_NO_SIGTIMEDWAIT) */ while (me->suspend & PT_THREAD_SUSPENDED) { PRIntn rv = sigtimedwait(&sigwait_set, NULL, &hundredmillisec); PR_ASSERT(-1 == rv); } me->suspend |= PT_THREAD_RESUMED; #endif /* * At this point, thread has been resumed, so set a global condition. * The ResumeAll needs to know that this has really been resumed. * So the signal handler sets a flag which PR_ResumeAll will reset. * The PR_ResumeAll must reset this flag ... */ PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("End suspend_signal_handler thred = %p tid = %X\n", me, me->id)); } /* suspend_signal_handler */ static void pt_SuspendSet(PRThread *thred) { PRIntn rv; PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("pt_SuspendSet thred %p thread id = %X\n", thred, thred->id)); /* * Check the thread state and signal the thread to suspend */ PR_ASSERT((thred->suspend & PT_THREAD_SUSPENDED) == 0); PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("doing pthread_kill in pt_SuspendSet thred %p tid = %X\n", thred, thred->id)); #if defined(SYMBIAN) /* All signal group functions are not implemented in Symbian OS */ rv = 0; #else rv = pthread_kill (thred->id, SIGUSR2); #endif PR_ASSERT(0 == rv); } static void pt_SuspendTest(PRThread *thred) { PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("Begin pt_SuspendTest thred %p thread id = %X\n", thred, thred->id)); /* * Wait for the thread to be really suspended. This happens when the * suspend signal handler stores the stack pointer and sets the state * to suspended. */ #if defined(PT_NO_SIGTIMEDWAIT) pthread_mutex_lock(&thred->suspendResumeMutex); while ((thred->suspend & PT_THREAD_SUSPENDED) == 0) { pthread_cond_timedwait( &thred->suspendResumeCV, &thred->suspendResumeMutex, &onemillisec); } pthread_mutex_unlock(&thred->suspendResumeMutex); #else while ((thred->suspend & PT_THREAD_SUSPENDED) == 0) { PRIntn rv = sigtimedwait(&sigwait_set, NULL, &onemillisec); PR_ASSERT(-1 == rv); } #endif PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("End pt_SuspendTest thred %p tid %X\n", thred, thred->id)); } /* pt_SuspendTest */ static void pt_ResumeSet(PRThread *thred) { PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("pt_ResumeSet thred %p thread id = %X\n", thred, thred->id)); /* * Clear the global state and set the thread state so that it will * continue past yield loop in the suspend signal handler */ PR_ASSERT(thred->suspend & PT_THREAD_SUSPENDED); thred->suspend &= ~PT_THREAD_SUSPENDED; #if defined(PT_NO_SIGTIMEDWAIT) #if defined(SYMBIAN) /* All signal group functions are not implemented in Symbian OS */ #else pthread_kill(thred->id, SIGUSR1); #endif #endif } /* pt_ResumeSet */ static void pt_ResumeTest(PRThread *thred) { PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("Begin pt_ResumeTest thred %p thread id = %X\n", thred, thred->id)); /* * Wait for the threads resume state to change * to indicate it is really resumed */ #if defined(PT_NO_SIGTIMEDWAIT) pthread_mutex_lock(&thred->suspendResumeMutex); while ((thred->suspend & PT_THREAD_RESUMED) == 0) { pthread_cond_timedwait( &thred->suspendResumeCV, &thred->suspendResumeMutex, &onemillisec); } pthread_mutex_unlock(&thred->suspendResumeMutex); #else while ((thred->suspend & PT_THREAD_RESUMED) == 0) { PRIntn rv = sigtimedwait(&sigwait_set, NULL, &onemillisec); PR_ASSERT(-1 == rv); } #endif thred->suspend &= ~PT_THREAD_RESUMED; PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ( "End pt_ResumeTest thred %p tid %X\n", thred, thred->id)); } /* pt_ResumeTest */ static pthread_once_t pt_gc_support_control = PTHREAD_ONCE_INIT; PR_IMPLEMENT(void) PR_SuspendAll(void) { #ifdef DEBUG PRIntervalTime stime, etime; #endif PRThread* thred = pt_book.first; PRThread *me = PR_GetCurrentThread(); int rv; rv = pthread_once(&pt_gc_support_control, init_pthread_gc_support); PR_ASSERT(0 == rv); PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("Begin PR_SuspendAll\n")); /* * Stop all threads which are marked GC able. */ PR_Lock(pt_book.ml); #ifdef DEBUG suspendAllOn = PR_TRUE; stime = PR_IntervalNow(); #endif while (thred != NULL) { if ((thred != me) && _PT_IS_GCABLE_THREAD(thred)) pt_SuspendSet(thred); thred = thred->next; } /* Wait till they are really suspended */ thred = pt_book.first; while (thred != NULL) { if ((thred != me) && _PT_IS_GCABLE_THREAD(thred)) pt_SuspendTest(thred); thred = thred->next; } suspendAllSuspended = PR_TRUE; #ifdef DEBUG etime = PR_IntervalNow(); PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS,\ ("End PR_SuspendAll (time %dms)\n", PR_IntervalToMilliseconds(etime - stime))); #endif } /* PR_SuspendAll */ PR_IMPLEMENT(void) PR_ResumeAll(void) { #ifdef DEBUG PRIntervalTime stime, etime; #endif PRThread* thred = pt_book.first; PRThread *me = PR_GetCurrentThread(); PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("Begin PR_ResumeAll\n")); /* * Resume all previously suspended GC able threads. */ suspendAllSuspended = PR_FALSE; #ifdef DEBUG stime = PR_IntervalNow(); #endif while (thred != NULL) { if ((thred != me) && _PT_IS_GCABLE_THREAD(thred)) pt_ResumeSet(thred); thred = thred->next; } thred = pt_book.first; while (thred != NULL) { if ((thred != me) && _PT_IS_GCABLE_THREAD(thred)) pt_ResumeTest(thred); thred = thred->next; } PR_Unlock(pt_book.ml); #ifdef DEBUG suspendAllOn = PR_FALSE; etime = PR_IntervalNow(); PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("End PR_ResumeAll (time %dms)\n", PR_IntervalToMilliseconds(etime - stime))); #endif } /* PR_ResumeAll */ /* Return the stack pointer for the given thread- used by the GC */ PR_IMPLEMENT(void *)PR_GetSP(PRThread *thred) { PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("in PR_GetSP thred %p thid = %X, sp = %p\n", thred, thred->id, thred->sp)); return thred->sp; } /* PR_GetSP */ #else /* !defined(_PR_DCETHREADS) */ static pthread_once_t pt_gc_support_control = pthread_once_init; /* * For DCE threads, there is no pthread_kill or a way of suspending or resuming a * particular thread. We will just disable the preemption (virtual timer alarm) and * let the executing thread finish the garbage collection. This stops all other threads * (GC able or not) and is very inefficient but there is no other choice. */ PR_IMPLEMENT(void) PR_SuspendAll() { PRIntn rv; rv = pthread_once(&pt_gc_support_control, init_pthread_gc_support); PR_ASSERT(0 == rv); /* returns -1 on failure */ #ifdef DEBUG suspendAllOn = PR_TRUE; #endif PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("Begin PR_SuspendAll\n")); /* * turn off preemption - i.e add virtual alarm signal to the set of * blocking signals */ rv = sigprocmask( SIG_BLOCK, &javagc_vtalarm_sigmask, &javagc_intsoff_sigmask); PR_ASSERT(0 == rv); suspendAllSuspended = PR_TRUE; PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("End PR_SuspendAll\n")); } /* PR_SuspendAll */ PR_IMPLEMENT(void) PR_ResumeAll() { PRIntn rv; suspendAllSuspended = PR_FALSE; PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("Begin PR_ResumeAll\n")); /* turn on preemption - i.e re-enable virtual alarm signal */ rv = sigprocmask(SIG_SETMASK, &javagc_intsoff_sigmask, (sigset_t *)NULL); PR_ASSERT(0 == rv); #ifdef DEBUG suspendAllOn = PR_FALSE; #endif PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("End PR_ResumeAll\n")); } /* PR_ResumeAll */ /* Return the stack pointer for the given thread- used by the GC */ PR_IMPLEMENT(void*)PR_GetSP(PRThread *thred) { pthread_t tid = thred->id; char *thread_tcb, *top_sp; /* * For HPUX DCE threads, pthread_t is a struct with the * following three fields (see pthread.h, dce/cma.h): * cma_t_address field1; * short int field2; * short int field3; * where cma_t_address is typedef'd to be either void* * or char*. */ PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("Begin PR_GetSP\n")); thread_tcb = (char*)tid.field1; top_sp = *(char**)(thread_tcb + 128); PR_LOG(_pr_gc_lm, PR_LOG_ALWAYS, ("End PR_GetSP %p \n", top_sp)); return top_sp; } /* PR_GetSP */ #endif /* !defined(_PR_DCETHREADS) */ PR_IMPLEMENT(PRStatus) PR_SetCurrentThreadName(const char *name) { PRThread *thread; size_t nameLen; int result; if (!name) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return PR_FAILURE; } thread = PR_GetCurrentThread(); if (!thread) return PR_FAILURE; PR_Free(thread->name); nameLen = strlen(name); thread->name = (char *)PR_Malloc(nameLen + 1); if (!thread->name) return PR_FAILURE; memcpy(thread->name, name, nameLen + 1); #if defined(OPENBSD) || defined(FREEBSD) result = pthread_set_name_np(thread->id, name); #else /* not BSD */ /* * On OSX, pthread_setname_np is only available in 10.6 or later, so test * for it at runtime. It also may not be available on all linux distros. */ #if defined(DARWIN) int (*dynamic_pthread_setname_np)(const char*); #else int (*dynamic_pthread_setname_np)(pthread_t, const char*); #endif *(void**)(&dynamic_pthread_setname_np) = dlsym(RTLD_DEFAULT, "pthread_setname_np"); if (!dynamic_pthread_setname_np) return PR_SUCCESS; /* * The 15-character name length limit is an experimentally determined * length of a null-terminated string that most linux distros and OS X * accept as an argument to pthread_setname_np. Otherwise the E2BIG * error is returned by the function. */ #define SETNAME_LENGTH_CONSTRAINT 15 #define SETNAME_FRAGMENT1_LENGTH (SETNAME_LENGTH_CONSTRAINT >> 1) #define SETNAME_FRAGMENT2_LENGTH \ (SETNAME_LENGTH_CONSTRAINT - SETNAME_FRAGMENT1_LENGTH - 1) char name_dup[SETNAME_LENGTH_CONSTRAINT + 1]; if (nameLen > SETNAME_LENGTH_CONSTRAINT) { memcpy(name_dup, name, SETNAME_FRAGMENT1_LENGTH); name_dup[SETNAME_FRAGMENT1_LENGTH] = '~'; /* Note that this also copies the null terminator. */ memcpy(name_dup + SETNAME_FRAGMENT1_LENGTH + 1, name + nameLen - SETNAME_FRAGMENT2_LENGTH, SETNAME_FRAGMENT2_LENGTH + 1); name = name_dup; } #if defined(DARWIN) result = dynamic_pthread_setname_np(name); #else result = dynamic_pthread_setname_np(thread->id, name); #endif #endif /* not BSD */ if (result) { PR_SetError(PR_UNKNOWN_ERROR, result); return PR_FAILURE; } return PR_SUCCESS; } PR_IMPLEMENT(const char *) PR_GetThreadName(const PRThread *thread) { if (!thread) return NULL; return thread->name; } #endif /* defined(_PR_PTHREADS) || defined(_PR_DCETHREADS) */ /* ptthread.c */