// -*- c++ -*- // posix-threads.h - Defines for using POSIX threads. /* Copyright (C) 1998, 1999 Cygnus Solutions This file is part of libgcj. This software is copyrighted work licensed under the terms of the Libgcj License. Please consult the file "LIBGCJ_LICENSE" for details. */ #ifndef __JV_POSIX_THREADS__ #define __JV_POSIX_THREADS__ // NOTE: This file may only reference those pthread functions which // are known not to be overridden by the Boehm GC. If in doubt, scan // boehm-gc/gc.h. This is yucky but lets us avoid including gc.h // everywhere (which would be truly yucky). #include #include #if defined (HAVE_PTHREAD_MUTEXATTR_SETTYPE) || defined (HAVE_PTHREAD_MUTEXATTR_SETKIND_NP) # define HAVE_RECURSIVE_MUTEX 1 #endif // // Typedefs. // typedef pthread_cond_t _Jv_ConditionVariable_t; #if defined (PTHREAD_MUTEX_HAVE_M_COUNT) || defined (PTHREAD_MUTEX_HAVE___M_COUNT) // On Linux we use implementation details of mutexes in order to get // faster results. typedef pthread_mutex_t _Jv_Mutex_t; #else /* LINUX_THREADS */ #define PTHREAD_MUTEX_IS_STRUCT typedef struct { // Mutex used when locking this structure transiently. pthread_mutex_t mutex; #ifndef HAVE_RECURSIVE_MUTEX // Some systems do not have recursive mutexes, so we must simulate // them. Solaris is one such system. // Mutex the thread holds the entire time this mutex is held. This // is used to make condition variables work properly. pthread_mutex_t mutex2; // Condition variable used when waiting for this lock. pthread_cond_t cond; // Thread holding this mutex. If COUNT is 0, no thread is holding. pthread_t thread; #endif /* HAVE_RECURSIVE_MUTEX */ // Number of times mutex is held. If 0, the lock is not held. We // do this even if we have a native recursive mutex so that we can // keep track of whether the lock is held; this lets us do error // checking. FIXME it would be nice to optimize this; on some // systems we could do so by relying on implementation details of // recursive mutexes. int count; } _Jv_Mutex_t; #endif typedef struct { // Flag values are defined in implementation. int flags; // Actual thread id. pthread_t thread; } _Jv_Thread_t; typedef void _Jv_ThreadStartFunc (java::lang::Thread *); // This convenience function is used to return the POSIX mutex // corresponding to our mutex. inline pthread_mutex_t * _Jv_PthreadGetMutex (_Jv_Mutex_t *mu) { #if ! defined (PTHREAD_MUTEX_IS_STRUCT) return mu; #elif defined (HAVE_RECURSIVE_MUTEX) return &mu->mutex; #else return &mu->mutex2; #endif } #include // This is a convenience function used only by the pthreads thread // implementation. This is slow, but that's too bad -- we need to do // the checks for correctness. It might be nice to be able to compile // this out. inline int _Jv_PthreadCheckMonitor (_Jv_Mutex_t *mu) { pthread_mutex_t *pmu = _Jv_PthreadGetMutex (mu); // See if the mutex is locked by this thread. if (pthread_mutex_trylock (pmu)) return 1; #if defined (PTHREAD_MUTEX_HAVE_M_COUNT) // On Linux we exploit knowledge of the implementation. int r = pmu->m_count == 1; #elif defined (PTHREAD_MUTEX_HAVE___M_COUNT) // In glibc 2.1, the first time the mutex is grabbed __m_count is // set to 0 and __m_owner is set to pthread_self(). int r = ! pmu->__m_count; #else int r = mu->count == 0; #endif pthread_mutex_unlock (pmu); return r; } // // Condition variables. // inline void _Jv_CondInit (_Jv_ConditionVariable_t *cv) { pthread_cond_init (cv, 0); } #ifndef LINUX_THREADS // pthread_cond_destroy does nothing on Linux and it is a win to avoid // defining this macro. #define _Jv_HaveCondDestroy inline void _Jv_CondDestroy (_Jv_ConditionVariable_t *cv) { pthread_cond_destroy (cv); } #endif /* LINUX_THREADS */ int _Jv_CondWait (_Jv_ConditionVariable_t *cv, _Jv_Mutex_t *mu, jlong millis, jint nanos); inline int _Jv_CondNotify (_Jv_ConditionVariable_t *cv, _Jv_Mutex_t *mu) { return _Jv_PthreadCheckMonitor (mu) || pthread_cond_signal (cv); } inline int _Jv_CondNotifyAll (_Jv_ConditionVariable_t *cv, _Jv_Mutex_t *mu) { return _Jv_PthreadCheckMonitor (mu) || pthread_cond_broadcast (cv); } // // Mutexes. // #ifdef RECURSIVE_MUTEX_IS_DEFAULT inline void _Jv_MutexInit (_Jv_Mutex_t *mu) { pthread_mutex_init (_Jv_PthreadGetMutex (mu), NULL); #ifdef PTHREAD_MUTEX_IS_STRUCT mu->count = 0; #endif } #else void _Jv_MutexInit (_Jv_Mutex_t *mu); #endif #ifndef LINUX_THREADS // pthread_mutex_destroy does nothing on Linux and it is a win to avoid // defining this macro. #define _Jv_HaveMutexDestroy #ifdef HAVE_RECURSIVE_MUTEX inline void _Jv_MutexDestroy (_Jv_Mutex_t *mu) { pthread_mutex_destroy (_Jv_PthreadGetMutex (mu)); } #else /* HAVE_RECURSIVE_MUTEX */ extern void _Jv_MutexDestroy (_Jv_Mutex_t *mu); #endif /* HAVE_RECURSIVE_MUTEX */ #endif /* LINUX_THREADS */ #ifdef HAVE_RECURSIVE_MUTEX inline int _Jv_MutexLock (_Jv_Mutex_t *mu) { int r = pthread_mutex_lock (_Jv_PthreadGetMutex (mu)); #ifdef PTHREAD_MUTEX_IS_STRUCT if (! r) ++mu->count; #endif return r; } inline int _Jv_MutexUnlock (_Jv_Mutex_t *mu) { int r = pthread_mutex_unlock (_Jv_PthreadGetMutex (mu)); #ifdef PTHREAD_MUTEX_IS_STRUCT if (! r) --mu->count; #endif return r; } #else /* HAVE_RECURSIVE_MUTEX */ extern int _Jv_MutexLock (_Jv_Mutex_t *mu); extern int _Jv_MutexUnlock (_Jv_Mutex_t *mu); #endif /* HAVE_RECURSIVE_MUTEX */ // // Thread creation and manipulation. // void _Jv_InitThreads (void); void _Jv_ThreadInitData (_Jv_Thread_t **data, java::lang::Thread *thread); inline java::lang::Thread * _Jv_ThreadCurrent (void) { extern pthread_key_t _Jv_ThreadKey; return (java::lang::Thread *) pthread_getspecific (_Jv_ThreadKey); } inline _Jv_Thread_t * _Jv_ThreadCurrentData (void) { extern pthread_key_t _Jv_ThreadDataKey; return (_Jv_Thread_t *) pthread_getspecific (_Jv_ThreadDataKey); } inline void _Jv_ThreadYield (void) { #ifdef HAVE_SCHED_YIELD sched_yield (); #endif /* HAVE_SCHED_YIELD */ } void _Jv_ThreadSetPriority (_Jv_Thread_t *data, jint prio); void _Jv_ThreadStart (java::lang::Thread *thread, _Jv_Thread_t *data, _Jv_ThreadStartFunc *meth); void _Jv_ThreadWait (void); void _Jv_ThreadInterrupt (_Jv_Thread_t *data); #endif /* __JV_POSIX_THREADS__ */