/* ****************************************************************************** * * Copyright (C) 1997-2011, International Business Machines * Corporation and others. All Rights Reserved. * ****************************************************************************** * * File umutex.c * * Modification History: * * Date Name Description * 04/02/97 aliu Creation. * 04/07/99 srl updated * 05/13/99 stephen Changed to umutex (from cmutex). * 11/22/99 aliu Make non-global mutex autoinitialize [j151] ****************************************************************************** */ #include "unicode/utypes.h" #include "uassert.h" #include "ucln_cmn.h" /* * ICU Mutex wrappers. Wrap operating system mutexes, giving the rest of ICU a * platform independent set of mutex operations. For internal ICU use only. */ /* Assume POSIX, and modify as necessary below */ #define POSIX #if defined(U_WINDOWS) #undef POSIX #endif #if defined(macintosh) #undef POSIX #endif #if defined(OS2) #undef POSIX #endif #if defined(POSIX) && (ICU_USE_THREADS==1) # include <pthread.h> /* must be first, so that we get the multithread versions of things. */ #endif /* POSIX && (ICU_USE_THREADS==1) */ #ifdef U_WINDOWS # define WIN32_LEAN_AND_MEAN # define VC_EXTRALEAN # define NOUSER # define NOSERVICE # define NOIME # define NOMCX # include <windows.h> #endif #include "umutex.h" #include "cmemory.h" /* * A note on ICU Mutex Initialization and ICU startup: * * ICU mutexes, as used through the rest of the ICU code, are self-initializing. * To make this work, ICU uses the _ICU GLobal Mutex_ to synchronize the lazy init * of other ICU mutexes. For the global mutex itself, we need some other mechanism * to safely initialize it on first use. This becomes important when two or more * threads are more or less simultaenously the first to use ICU in a process, and * are racing into the mutex initialization code. * * * The solution for the global mutex init is platform dependent. * On POSIX systems, plain C-style initialization can be used on a mutex, with the * macro PTHREAD_MUTEX_INITIALIZER. The mutex is then ready for use, without * first calling pthread_mutex_init(). * * Windows has no equivalent statically initialized mutex or CRITICAL SECION. * InitializeCriticalSection() must be called. If the global mutex does not * appear to be initialized, a thread will create and initialize a new * CRITICAL_SECTION, then use a Windows InterlockedCompareAndExchange to * swap it in as the global mutex while avoid problems with race conditions. */ /* On WIN32 mutexes are reentrant. On POSIX platforms they are not, and a deadlock * will occur if a thread attempts to acquire a mutex it already has locked. * ICU mutexes (in debug builds) include checking code that will cause an assertion * failure if a mutex is reentered. If you are having deadlock problems * on a POSIX machine, debugging may be easier on Windows. */ #if (ICU_USE_THREADS == 0) #define MUTEX_TYPE void * #define PLATFORM_MUTEX_INIT(m) #define PLATFORM_MUTEX_LOCK(m) #define PLATFORM_MUTEX_UNLOCK(m) #define PLATFORM_MUTEX_DESTROY(m) #define PLATFORM_MUTEX_INITIALIZER NULL #define SYNC_COMPARE_AND_SWAP(dest, oldval, newval) \ mutexed_compare_and_swap(dest, newval, oldval) #elif defined(U_WINDOWS) #define MUTEX_TYPE CRITICAL_SECTION #define PLATFORM_MUTEX_INIT(m) InitializeCriticalSection(m) #define PLATFORM_MUTEX_LOCK(m) EnterCriticalSection(m) #define PLATFORM_MUTEX_UNLOCK(m) LeaveCriticalSection(m) #define PLATFORM_MUTEX_DESTROY(m) DeleteCriticalSection(m) #define SYNC_COMPARE_AND_SWAP(dest, oldval, newval) \ InterlockedCompareExchangePointer(dest, newval, oldval) #elif defined(POSIX) #define MUTEX_TYPE pthread_mutex_t #define PLATFORM_MUTEX_INIT(m) pthread_mutex_init(m, NULL) #define PLATFORM_MUTEX_LOCK(m) pthread_mutex_lock(m) #define PLATFORM_MUTEX_UNLOCK(m) pthread_mutex_unlock(m) #define PLATFORM_MUTEX_DESTROY(m) pthread_mutex_destroy(m) #define PLATFORM_MUTEX_INITIALIZER PTHREAD_MUTEX_INITIALIZER #if (U_HAVE_GCC_ATOMICS == 1) #define SYNC_COMPARE_AND_SWAP(dest, oldval, newval) \ __sync_val_compare_and_swap(dest, oldval, newval) #else #define SYNC_COMPARE_AND_SWAP(dest, oldval, newval) \ mutexed_compare_and_swap(dest, newval, oldval) #endif #else /* Unknown platform. Note that user can still set mutex functions at run time. */ #define MUTEX_TYPE void * #define PLATFORM_MUTEX_INIT(m) #define PLATFORM_MUTEX_LOCK(m) #define PLATFORM_MUTEX_UNLOCK(m) #define PLATFORM_MUTEX_DESTROY(m) #define SYNC_COMPARE_AND_SWAP(dest, oldval, newval) \ mutexed_compare_and_swap(dest, newval, oldval) #endif /* Forward declarations */ static void *mutexed_compare_and_swap(void **dest, void *newval, void *oldval); typedef struct ICUMutex ICUMutex; /* * ICUMutex One of these is set up for each UMTX that is used by other ICU code. * The opaque UMTX points to the corresponding ICUMutex struct. * * Because the total number of ICU mutexes is quite small, no effort has * been made to squeeze every byte out of this struct. */ struct ICUMutex { UMTX *owner; /* Points back to the UMTX corrsponding to this */ /* ICUMutex object. */ UBool heapAllocated; /* Set if this ICUMutex is heap allocated, and */ /* will need to be deleted. The global mutex */ /* is static on POSIX platforms; all others */ /* will be heap allocated. */ ICUMutex *next; /* All ICUMutexes are chained into a list so that */ /* they can be found and deleted by u_cleanup(). */ int32_t recursionCount; /* For debugging, detect recursive mutex locks. */ MUTEX_TYPE platformMutex; /* The underlying OS mutex being wrapped. */ UMTX userMutex; /* For use with u_setMutexFunctions operations, */ /* corresponds to platformMutex. */ }; /* The global ICU mutex. * For POSIX platforms, it gets a C style initialization, and is ready to use * at program startup. * For Windows, it will be lazily instantiated on first use. */ #if defined(POSIX) static UMTX globalUMTX; static ICUMutex globalMutex = {&globalUMTX, FALSE, NULL, 0, PLATFORM_MUTEX_INITIALIZER, NULL}; static UMTX globalUMTX = &globalMutex; #else static UMTX globalUMTX = NULL; #endif /* Head of the list of all ICU mutexes. * Linked list is through ICUMutex::next * Modifications to the list are synchronized with the global mutex. * The list is used by u_cleanup(), which needs to dispose of all of the ICU mutexes. * * The statically initialized global mutex on POSIX platforms does not get added to this * mutex list, but that's not a problem - the global mutex gets special handling * during u_cleanup(). */ static ICUMutex *mutexListHead; /* * User mutex implementation functions. If non-null, call back to these rather than * directly using the system (Posix or Windows) APIs. See u_setMutexFunctions(). * (declarations are in uclean.h) */ static UMtxInitFn *pMutexInitFn = NULL; static UMtxFn *pMutexDestroyFn = NULL; static UMtxFn *pMutexLockFn = NULL; static UMtxFn *pMutexUnlockFn = NULL; static const void *gMutexContext = NULL; /* * umtx_lock */ U_CAPI void U_EXPORT2 umtx_lock(UMTX *mutex) { ICUMutex *m; if (mutex == NULL) { mutex = &globalUMTX; } m = (ICUMutex *)*mutex; if (m == NULL) { /* See note on lazy initialization, above. We can get away with it here, with mutexes, * where we couldn't with normal user level data. */ umtx_init(mutex); m = (ICUMutex *)*mutex; } U_ASSERT(m->owner == mutex); if (pMutexLockFn != NULL) { (*pMutexLockFn)(gMutexContext, &m->userMutex); } else { PLATFORM_MUTEX_LOCK(&m->platformMutex); } #if defined(U_DEBUG) m->recursionCount++; /* Recursion causes deadlock on Unixes. */ U_ASSERT(m->recursionCount == 1); /* Recursion detection works on Windows. */ /* Assertion failure on non-Windows indicates a */ /* problem with the mutex implementation itself. */ #endif } /* * umtx_unlock */ U_CAPI void U_EXPORT2 umtx_unlock(UMTX* mutex) { ICUMutex *m; if(mutex == NULL) { mutex = &globalUMTX; } m = (ICUMutex *)*mutex; if (m == NULL) { U_ASSERT(FALSE); /* This mutex is not initialized. */ return; } U_ASSERT(m->owner == mutex); #if defined (U_DEBUG) m->recursionCount--; U_ASSERT(m->recursionCount == 0); /* Detect unlock of an already unlocked mutex */ #endif if (pMutexUnlockFn) { (*pMutexUnlockFn)(gMutexContext, &m->userMutex); } else { PLATFORM_MUTEX_UNLOCK(&m->platformMutex); } } /* umtx_ct Allocate and initialize a new ICUMutex. * If a non-null pointer is supplied, initialize an existing ICU Mutex. */ static ICUMutex *umtx_ct(ICUMutex *m) { if (m == NULL) { m = (ICUMutex *)uprv_malloc(sizeof(ICUMutex)); m->heapAllocated = TRUE; } m->next = NULL; /* List of mutexes is maintained at a higher level. */ m->recursionCount = 0; m->userMutex = NULL; if (pMutexInitFn != NULL) { UErrorCode status = U_ZERO_ERROR; (*pMutexInitFn)(gMutexContext, &m->userMutex, &status); U_ASSERT(U_SUCCESS(status)); } else { PLATFORM_MUTEX_INIT(&m->platformMutex); } return m; } /* umtx_dt Delete a ICUMutex. Destroy the underlying OS Platform mutex. * Does not touch the linked list of ICU Mutexes. */ static void umtx_dt(ICUMutex *m) { if (pMutexDestroyFn != NULL) { (*pMutexDestroyFn)(gMutexContext, &m->userMutex); m->userMutex = NULL; } else { PLATFORM_MUTEX_DESTROY(&m->platformMutex); } if (m->heapAllocated) { uprv_free(m); } } U_CAPI void U_EXPORT2 umtx_init(UMTX *mutex) { ICUMutex *m = NULL; void *originalValue; if (*mutex != NULL) { /* Mutex is already initialized. * Multiple umtx_init()s of a UMTX by other ICU code are explicitly permitted. */ return; } #if defined(POSIX) if (mutex == &globalUMTX) { m = &globalMutex; } #endif m = umtx_ct(m); originalValue = SYNC_COMPARE_AND_SWAP(mutex, NULL, m); if (originalValue != NULL) { umtx_dt(m); return; } m->owner = mutex; /* Hook the new mutex into the list of all ICU mutexes, so that we can find and * delete it for u_cleanup(). */ umtx_lock(NULL); m->next = mutexListHead; mutexListHead = m; umtx_unlock(NULL); return; } /* * umtx_destroy. Un-initialize a mutex, releasing any underlying resources * that it may be holding. Destroying an already destroyed * mutex has no effect. Unlike umtx_init(), this function * is not thread safe; two threads must not concurrently try to * destroy the same mutex. */ U_CAPI void U_EXPORT2 umtx_destroy(UMTX *mutex) { ICUMutex *m; /* No one should be deleting the global ICU mutex. * (u_cleanup() does delete it, but does so explicitly, not by passing NULL) */ U_ASSERT(mutex != NULL); if (mutex == NULL) { return; } m = (ICUMutex *)*mutex; if (m == NULL) { /* Mutex not initialized, or already destroyed. */ return; } U_ASSERT(m->owner == mutex); if (m->owner != mutex) { return; } /* Remove this mutex from the linked list of mutexes. */ umtx_lock(NULL); if (mutexListHead == m) { mutexListHead = m->next; } else { ICUMutex *prev; for (prev = mutexListHead; prev!=NULL && prev->next!=m; prev = prev->next); /* Empty for loop body */ if (prev != NULL) { prev->next = m->next; } } umtx_unlock(NULL); umtx_dt(m); /* Delete the internal ICUMutex */ *mutex = NULL; /* Clear the caller's UMTX */ } U_CAPI void U_EXPORT2 u_setMutexFunctions(const void *context, UMtxInitFn *i, UMtxFn *d, UMtxFn *l, UMtxFn *u, UErrorCode *status) { if (U_FAILURE(*status)) { return; } /* Can not set a mutex function to a NULL value */ if (i==NULL || d==NULL || l==NULL || u==NULL) { *status = U_ILLEGAL_ARGUMENT_ERROR; return; } /* If ICU is not in an initial state, disallow this operation. */ if (cmemory_inUse()) { *status = U_INVALID_STATE_ERROR; return; } /* Kill any existing global mutex. POSIX platforms have a global mutex * even before any other part of ICU is initialized. */ umtx_destroy(&globalUMTX); /* Swap in the mutex function pointers. */ pMutexInitFn = i; pMutexDestroyFn = d; pMutexLockFn = l; pMutexUnlockFn = u; gMutexContext = context; #if defined (POSIX) /* POSIX platforms must have a pre-initialized global mutex * to allow other mutexes to initialize safely. */ umtx_init(&globalUMTX); #endif } /* synchronized compare and swap function, for use when OS or compiler built-in * equivalents aren't available. * * This operation relies on the ICU global mutex for synchronization. * * There are two cases where this function can be entered when the global mutex is not * yet initialized - at the end u_cleanup(), and at the end of u_setMutexFunctions, both * of which re-init the global mutex. But neither function is thread-safe, so the lack of * synchronization at these points doesn't matter. */ static void *mutexed_compare_and_swap(void **dest, void *newval, void *oldval) { void *temp; UBool needUnlock = FALSE; if (globalUMTX != NULL) { umtx_lock(&globalUMTX); needUnlock = TRUE; } temp = *dest; if (temp == oldval) { *dest = newval; } if (needUnlock) { umtx_unlock(&globalUMTX); } return temp; } /*----------------------------------------------------------------- * * Atomic Increment and Decrement * umtx_atomic_inc * umtx_atomic_dec * *----------------------------------------------------------------*/ /* Pointers to user-supplied inc/dec functions. Null if no funcs have been set. */ static UMtxAtomicFn *pIncFn = NULL; static UMtxAtomicFn *pDecFn = NULL; static const void *gIncDecContext = NULL; static UMTX gIncDecMutex = NULL; U_CAPI int32_t U_EXPORT2 umtx_atomic_inc(int32_t *p) { int32_t retVal; if (pIncFn) { retVal = (*pIncFn)(gIncDecContext, p); } else { #if defined (U_WINDOWS) && ICU_USE_THREADS == 1 retVal = InterlockedIncrement((LONG*)p); #elif defined(USE_MAC_OS_ATOMIC_INCREMENT) retVal = OSAtomicIncrement32Barrier(p); #elif (U_HAVE_GCC_ATOMICS == 1) retVal = __sync_add_and_fetch(p, 1); #elif defined (POSIX) && ICU_USE_THREADS == 1 umtx_lock(&gIncDecMutex); retVal = ++(*p); umtx_unlock(&gIncDecMutex); #else /* Unknown Platform, or ICU thread support compiled out. */ retVal = ++(*p); #endif } return retVal; } U_CAPI int32_t U_EXPORT2 umtx_atomic_dec(int32_t *p) { int32_t retVal; if (pDecFn) { retVal = (*pDecFn)(gIncDecContext, p); } else { #if defined (U_WINDOWS) && ICU_USE_THREADS == 1 retVal = InterlockedDecrement((LONG*)p); #elif defined(USE_MAC_OS_ATOMIC_INCREMENT) retVal = OSAtomicDecrement32Barrier(p); #elif (U_HAVE_GCC_ATOMICS == 1) retVal = __sync_sub_and_fetch(p, 1); #elif defined (POSIX) && ICU_USE_THREADS == 1 umtx_lock(&gIncDecMutex); retVal = --(*p); umtx_unlock(&gIncDecMutex); #else /* Unknown Platform, or ICU thread support compiled out. */ retVal = --(*p); #endif } return retVal; } U_CAPI void U_EXPORT2 u_setAtomicIncDecFunctions(const void *context, UMtxAtomicFn *ip, UMtxAtomicFn *dp, UErrorCode *status) { if (U_FAILURE(*status)) { return; } /* Can not set a mutex function to a NULL value */ if (ip==NULL || dp==NULL) { *status = U_ILLEGAL_ARGUMENT_ERROR; return; } /* If ICU is not in an initial state, disallow this operation. */ if (cmemory_inUse()) { *status = U_INVALID_STATE_ERROR; return; } pIncFn = ip; pDecFn = dp; gIncDecContext = context; #if !U_RELEASE { int32_t testInt = 0; U_ASSERT(umtx_atomic_inc(&testInt) == 1); /* Sanity Check. Do the functions work at all? */ U_ASSERT(testInt == 1); U_ASSERT(umtx_atomic_dec(&testInt) == 0); U_ASSERT(testInt == 0); } #endif } /* * Mutex Cleanup Function * * Destroy the global mutex(es), and reset the mutex function callback pointers. */ U_CFUNC UBool umtx_cleanup(void) { ICUMutex *thisMutex = NULL; ICUMutex *nextMutex = NULL; /* Extra, do-nothing function call to suppress compiler warnings on platforms where * mutexed_compare_and_swap is not otherwise used. */ mutexed_compare_and_swap(&globalUMTX, NULL, NULL); /* Delete all of the ICU mutexes. Do the global mutex last because it is used during * the umtx_destroy operation of other mutexes. */ for (thisMutex=mutexListHead; thisMutex!=NULL; thisMutex=nextMutex) { UMTX *umtx = thisMutex->owner; nextMutex = thisMutex->next; U_ASSERT(*umtx = (void *)thisMutex); if (umtx != &globalUMTX) { umtx_destroy(umtx); } } umtx_destroy(&globalUMTX); pMutexInitFn = NULL; pMutexDestroyFn = NULL; pMutexLockFn = NULL; pMutexUnlockFn = NULL; gMutexContext = NULL; pIncFn = NULL; pDecFn = NULL; gIncDecContext = NULL; gIncDecMutex = NULL; #if defined (POSIX) /* POSIX platforms must come out of u_cleanup() with a functioning global mutex * to permit the safe resumption of use of ICU in multi-threaded environments. */ umtx_init(&globalUMTX); #endif return TRUE; }