/* Linuxthreads - a simple clone()-based implementation of Posix */ /* threads for Linux. */ /* Copyright (C) 1996 Xavier Leroy (Xavier.Leroy@inria.fr) */ /* */ /* This program is free software; you can redistribute it and/or */ /* modify it under the terms of the GNU Library General Public License */ /* as published by the Free Software Foundation; either version 2 */ /* of the License, or (at your option) any later version. */ /* */ /* This program is distributed in the hope that it will be useful, */ /* but WITHOUT ANY WARRANTY; without even the implied warranty of */ /* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the */ /* GNU Library General Public License for more details. */ #ifndef _PTHREAD_H #define _PTHREAD_H 1 #include #define __need_sigset_t #include #define __need_timespec #include #ifdef __BUILDING_LINUXTHREADS #include #else #include #endif #ifndef _REENTRANT #define _REENTRANT #endif #include /*** Feature test macros */ #ifndef _POSIX_THREADS #define _POSIX_THREADS #endif #ifndef _POSIX_THREADS_PRIORITY_SCHEDULING #define _POSIX_THREADS_PRIORITY_SCHEDULING #endif /*** Limits (should be in limits.h) */ /* Max number of simultaneously running threads. */ #define _POSIX_THREAD_THREADS_MAX 64 /* This is the value this implementation supports. Just a hint, actually, since LinuxThreads will support arbitrarily many threads, the only limit is the number of processes supported by the kernel. */ #define PTHREAD_THREADS_MAX 512 /* Max number of keys for thread-specific data */ #define _POSIX_THREAD_KEYS_MAX 128 /* This is the value this implementation supports. */ #define PTHREAD_KEYS_MAX 128 /*** Types ***/ /* Thread descriptors */ typedef struct _pthread *pthread_t; /* Waiting queues (not abstract because mutexes and conditions aren't). */ struct _pthread_queue { pthread_t head; /* First element, or NULL if queue empty. */ pthread_t tail; /* Last element, or NULL if queue empty. */ }; /* Mutexes (not abstract because of PTHREAD_MUTEX_INITIALIZER). */ typedef struct { int m_spinlock; /* Spin lock to guarantee mutual exclusion. */ int m_count; /* 0 if free, > 0 if taken. */ pthread_t m_owner; /* Owner of mutex (for recursive mutexes) */ int m_kind; /* Kind of mutex */ struct _pthread_queue m_waiting; /* Threads waiting on this mutex. */ } pthread_mutex_t; #define PTHREAD_MUTEX_INITIALIZER {0, 0, 0, 0, {0, 0}} #define PTHREAD_RECURSIVE_MUTEX_INITIALIZER_NP {0, 0, 0, 1, {0, 0}} /* Conditions (not abstract because of PTHREAD_COND_INITIALIZER */ typedef struct { int c_spinlock; /* Spin lock to protect the queue. */ struct _pthread_queue c_waiting; /* Threads waiting on this condition. */ } pthread_cond_t; #define PTHREAD_COND_INITIALIZER {0, {0, 0}} /* Attributes */ enum { PTHREAD_CREATE_JOINABLE, PTHREAD_CREATE_DETACHED }; enum { PTHREAD_INHERIT_SCHED, PTHREAD_EXPLICIT_SCHED }; enum { PTHREAD_SCOPE_SYSTEM, PTHREAD_SCOPE_PROCESS }; typedef struct { int detachstate; int schedpolicy; struct sched_param schedparam; int inheritsched; int scope; } pthread_attr_t; enum { PTHREAD_MUTEX_FAST_NP, PTHREAD_MUTEX_RECURSIVE_NP }; typedef struct { int mutexkind; } pthread_mutexattr_t; typedef struct { int dummy; } pthread_condattr_t; /* Keys for thread-specific data */ typedef unsigned int pthread_key_t; /* Once-only execution */ typedef int pthread_once_t; #define PTHREAD_ONCE_INIT 0 /* Cleanup buffers */ struct _pthread_cleanup_buffer { void (*routine) __P ((void *)); /* Function to call. */ void *arg; /* Its argument. */ int canceltype; /* Saved cancellation type. */ struct _pthread_cleanup_buffer *prev; /* Chaining of cleanup functions. */ }; /* Cancellation */ enum { PTHREAD_CANCEL_ENABLE, PTHREAD_CANCEL_DISABLE }; enum { PTHREAD_CANCEL_DEFERRED, PTHREAD_CANCEL_ASYNCHRONOUS }; #define PTHREAD_CANCELED ((void *) -1) /*** Function for handling threads. ***/ #if defined(__cplusplus) extern "C" { #endif /* Create a thread with given attributes ATTR (or default attributes if ATTR is NULL), and call function START_ROUTINE with given arguments ARG. */ extern int pthread_create __P ((pthread_t *__thread, __const pthread_attr_t *__attr, void *(*__start_routine) (void *), void *__arg)); /* Obtain the identifier of the current thread. */ extern pthread_t pthread_self __P ((void)); /* Compare two thread identifiers. */ extern int pthread_equal __P ((pthread_t __thread1, pthread_t __thread2)); /* Terminate calling thread. */ extern void pthread_exit __P ((void *__retval)) __attribute__ ((noreturn)); /* Make calling thread wait for termination of the thread TH. The exit status of the thread is stored in *THREAD_RETURN, if THREAD_RETURN is not NULL. */ extern int pthread_join __P ((pthread_t __th, void **__thread_return)); /* Indicate that the thread TH is never to be joined with PTHREAD_JOIN. The resources of TH will therefore be freed immediately when it terminates, instead of waiting for another thread to perform PTHREAD_JOIN on it. */ extern int pthread_detach __P ((pthread_t __th)); /* Functions for handling attributes. */ /* Initialize thread attribute *ATTR with default attributes (detachstate is PTHREAD_JOINABLE, scheduling policy is SCHED_OTHER). */ extern int pthread_attr_init __P ((pthread_attr_t *__attr)); /* Destroy thread attribute *ATTR. */ extern int pthread_attr_destroy __P ((pthread_attr_t *__attr)); /* Set the `detachstate' attribute in *ATTR according to DETACHSTATE. */ extern int pthread_attr_setdetachstate __P ((pthread_attr_t *__attr, int __detachstate)); /* Return in *DETACHSTATE the `detachstate' attribute in *ATTR. */ extern int pthread_attr_getdetachstate __P ((__const pthread_attr_t *__attr, int *__detachstate)); /* Set scheduling parameters (priority, etc) in *ATTR according to PARAM. */ extern int pthread_attr_setschedparam __P ((pthread_attr_t *__attr, __const struct sched_param *__param)); /* Return in *PARAM the scheduling parameters of *ATTR. */ extern int pthread_attr_getschedparam __P ((__const pthread_attr_t *__attr, struct sched_param *__param)); /* Set scheduling policy in *ATTR according to POLICY. */ extern int pthread_attr_setschedpolicy __P ((pthread_attr_t *__attr, int __policy)); /* Return in *POLICY the scheduling policy of *ATTR. */ extern int pthread_attr_getschedpolicy __P ((__const pthread_attr_t *__attr, int *__policy)); /* Set scheduling inheritance mode in *ATTR according to INHERIT. */ extern int pthread_attr_setinheritsched __P ((pthread_attr_t *__attr, int __inherit)); /* Return in *INHERIT the scheduling inheritance mode of *ATTR. */ extern int pthread_attr_getinheritsched __P ((__const pthread_attr_t *__attr, int *__inherit)); /* Set scheduling contention scope in *ATTR according to SCOPE. */ extern int pthread_attr_setscope __P((pthread_attr_t *__attr, int __scope)); /* Return in *SCOPE the scheduling contention scope of *ATTR. */ extern int pthread_attr_getscope __P((__const pthread_attr_t *__attr, int *__scope)); /* Functions for scheduling control. */ /* Set the scheduling parameters for TARGET_THREAD according to POLICY and *PARAM. */ extern int pthread_setschedparam __P((pthread_t __target_thread, int __policy, __const struct sched_param *__param)); /* Return in *POLICY and *PARAM the scheduling parameters for TARGET_THREAD. */ extern int pthread_getschedparam __P((pthread_t __target_thread, int *__policy, struct sched_param *__param)); /* Functions for mutex handling. */ /* Initialize MUTEX using attributes in *MUTEX_ATTR, or use the default values if later is NULL. */ extern int pthread_mutex_init __P ((pthread_mutex_t *__mutex, __const pthread_mutexattr_t *__mutex_attr)); /* Destroy MUTEX. */ extern int pthread_mutex_destroy __P ((pthread_mutex_t *__mutex)); /* Try to lock MUTEX. */ extern int pthread_mutex_trylock __P ((pthread_mutex_t *__mutex)); /* Wait until lock for MUTEX becomes available and lock it. */ extern int pthread_mutex_lock __P ((pthread_mutex_t *__mutex)); /* Unlock MUTEX. */ extern int pthread_mutex_unlock __P ((pthread_mutex_t *__mutex)); /* Functions for handling mutex attributes. */ /* Initialize mutex attribute object ATTR with default attributes (kind is PTHREAD_MUTEX_FAST_NP). */ extern int pthread_mutexattr_init __P ((pthread_mutexattr_t *__attr)); /* Destroy mutex attribute object ATTR. */ extern int pthread_mutexattr_destroy __P ((pthread_mutexattr_t *__attr)); /* Set the mutex kind attribute in *ATTR to KIND (either PTHREAD_MUTEX_FAST_NP or PTHREAD_MUTEX_RECURSIVE_NP). */ extern int pthread_mutexattr_setkind_np __P ((pthread_mutexattr_t *__attr, int __kind)); /* Return in *KIND the mutex kind attribute in *ATTR. */ extern int pthread_mutexattr_getkind_np __P ((__const pthread_mutexattr_t *__attr, int *__kind)); /* Functions for handling conditional variables. */ /* Initialize condition variable COND using attributes ATTR, or use the default values if later is NULL. */ extern int pthread_cond_init __P ((pthread_cond_t *__cond, __const pthread_condattr_t *__cond_attr)); /* Destroy condition variable COND. */ extern int pthread_cond_destroy __P ((pthread_cond_t *__cond)); /* Wake up one thread waiting for condition variable COND. */ extern int pthread_cond_signal __P ((pthread_cond_t *__cond)); /* Wake up all threads waiting for condition variables COND. */ extern int pthread_cond_broadcast __P ((pthread_cond_t *__cond)); /* Wait for condition variable COND to be signaled or broadcast. MUTEX is assumed to be locked before. */ extern int pthread_cond_wait __P ((pthread_cond_t *__cond, pthread_mutex_t *__mutex)); /* Wait for condition variable COND to be signaled or broadcast until ABSTIME. MUTEX is assumed to be locked before. ABSTIME is an absolute time specification; zero is the beginning of the epoch (00:00:00 GMT, January 1, 1970). */ extern int pthread_cond_timedwait __P ((pthread_cond_t *__cond, pthread_mutex_t *__mutex, __const struct timespec *__abstime)); /* Functions for handling condition variable attributes. */ /* Initialize condition variable attribute ATTR. */ extern int pthread_condattr_init __P ((pthread_condattr_t *__attr)); /* Destroy condition variable attribute ATTR. */ extern int pthread_condattr_destroy __P ((pthread_condattr_t *__attr)); /* Functions for handling thread-specific data */ /* Create a key value identifying a location in the thread-specific data area. Each thread maintains a distinct thread-specific data area. DESTR_FUNCTION, if non-NULL, is called with the value associated to that key when the key is destroyed. DESTR_FUNCTION is not called if the value associated is NULL when the key is destroyed. */ extern int pthread_key_create __P ((pthread_key_t *__key, void (*__destr_function) (void *))); /* Destroy KEY. */ extern int pthread_key_delete __P ((pthread_key_t __key)); /* Store POINTER in the thread-specific data slot identified by KEY. */ extern int pthread_setspecific __P ((pthread_key_t __key, __const void *__pointer)); /* Return current value of the thread-specific data slot identified by KEY. */ extern void * pthread_getspecific __P ((pthread_key_t __key)); /* Functions for handling initialization */ /* Guarantees that the initialization function INIT_ROUTINE will be called only once, even if pthread_once is executed several times with the same ONCE_CONTROL argument. ONCE_CONTROL must point to a static or extern variable initialized to PTHREAD_ONCE_INIT. */ extern int pthread_once __P ((pthread_once_t *__once_control, void (*__init_routine) (void))); /* Functions for handling cancellation. */ /* Set cancelability state of current thread to STATE, returning old state in *OLDSTATE if OLDSTATE is not NULL. */ extern int pthread_setcancelstate __P ((int __state, int *__oldstate)); /* Set cancellation state of current thread to TYPE, returning the old type in *OLDTYPE if OLDTYPE is not NULL. */ extern int pthread_setcanceltype __P ((int __type, int *__oldtype)); /* Cancel THREAD immediately or at the next possibility. */ extern int pthread_cancel __P ((pthread_t __thread)); /* Test for pending cancellation for the current thread and terminate the thread as per pthread_exit(PTHREAD_CANCELED) if it has been cancelled. */ extern void pthread_testcancel __P ((void)); /* Install a cleanup handler: ROUTINE will be called with arguments ARG when the thread is cancelled or calls pthread_exit. ROUTINE will also be called with arguments ARG when the matching pthread_cleanup_pop is executed with non-zero EXECUTE argument. pthread_cleanup_push and pthread_cleanup_pop are macros and must always be used in matching pairs at the same nesting level of braces. */ #define pthread_cleanup_push(routine,arg) \ { struct _pthread_cleanup_buffer _buffer; \ _pthread_cleanup_push (&_buffer, (routine), (arg)); extern void _pthread_cleanup_push __P ((struct _pthread_cleanup_buffer *__buffer, void (*__routine) (void *), void *__arg)); /* Remove a cleanup handler installed by the matching pthread_cleanup_push. If EXECUTE is non-zero, the handler function is called. */ #define pthread_cleanup_pop(execute) \ _pthread_cleanup_pop (&_buffer, (execute)); } extern void _pthread_cleanup_pop __P ((struct _pthread_cleanup_buffer *__buffer, int __execute)); /* Install a cleanup handler as pthread_cleanup_push does, but also saves the current cancellation type and set it to deferred cancellation. */ #define pthread_cleanup_push_defer_np(routine,arg) \ { struct _pthread_cleanup_buffer _buffer; \ _pthread_cleanup_push_defer (&_buffer, (routine), (arg)); extern void _pthread_cleanup_push_defer __P ((struct _pthread_cleanup_buffer *__buffer, void (*__routine) (void *), void *__arg)); /* Remove a cleanup handler as pthread_cleanup_pop does, but also restores the cancellation type that was in effect when the matching pthread_cleanup_push_defer was called. */ #define pthread_cleanup_pop_restore_np(execute) \ _pthread_cleanup_pop_restore (&_buffer, (execute)); } extern void _pthread_cleanup_pop_restore __P ((struct _pthread_cleanup_buffer *__buffer, int __execute)); /* Functions for handling signals. */ /* Modify the signal mask for the calling thread. The arguments have the same meaning as for sigprocmask(2). */ extern int pthread_sigmask __P ((int __how, __const sigset_t *__newmask, sigset_t *__oldmask)); /* Send signal SIGNO to the given thread. */ extern int pthread_kill __P ((pthread_t __thread, int __signo)); /* Suspend the calling thread until one of the signals in SET is delivered to the thread. Store in *SIG the number of the signal received. The signals in SIG must not be ignored and must be blocked prior to calling SIGWAIT. */ extern int sigwait __P ((__const sigset_t *__set, int *__sig)); /* Functions for handling process creation and process execution. */ /* Install handlers to be called when a new process is created with FORK. The PREPARE handler is called in the parent process just before performing FORK. The PARENT handler is called in the parent process just after FORK. The CHILD handler is called in the child process. Each of the three handlers can be NULL, meaning that no handler needs to be called at that point. PTHREAD_ATFORK can be called several times, in which case the PREPARE handlers are called in LIFO order (last added with PTHREAD_ATFORK, first called before FORK), and the PARENT and CHILD handlers are called in FIFO (first added, first called). */ extern int pthread_atfork __P ((void (*__prepare)(void), void (*__parent)(void), void (*__child)(void))); /* Terminate all threads in the program except the calling process. Should be called just before invoking one of the exec*() functions. */ extern void pthread_kill_other_threads_np __P((void)); #if defined(__cplusplus) } #endif /*** Miscellaneous compatibility stuff */ /* No ENOTSUP in */ #ifndef ENOTSUP #define ENOTSUP EOPNOTSUPP #endif #endif /* pthread.h */