VMS Help POSIX Threads, PTHREAD routines, pthread_create, Description *Conan The Librarian (sorry for the slow response - running on an old VAX) |
This routine creates a thread. A thread is a single, sequential flow of control within a program. It is the active execution of a designated routine, including any nested routine invocations. Successful execution of this routine includes the following actions: o The Threads Library creates a thread object to describe and control the thread. The thread object includes a thread environment block (TEB) that programs can use, with care. (See the <sys/types.h> header file on Tru64 UNIX, or the pthread.h header file on other platforms.) o The thread argument receives an identifier for the new thread. o An executable thread is created with attributes specified by the attr argument (or with default attributes if NULL is specified). Thread Creation The Threads Library creates a thread in the ready state and prepares the thread to begin executing its start routine, the function passed to pthread_create() as the start_routine argument. Depending on the presence of other threads and their scheduling and priority attributes, the new thread might start executing immediately. The new thread can also preempt its creator, depending on the two threads' respective scheduling and priority attributes. The caller of pthread_create() can synchronize with the new thread using the pthread_join() routine or using any mutually agreed upon mutexes, condition variables or read-write locks. For the duration of the new thread's existence, the Threads Library maintains and manages the thread object and other thread state overhead. A thread exists until it is both terminated and detached. A thread is detached when created if the detachstate attribute of its thread object is set to PTHREAD_CREATE_DETACHED. It is also detached after any thread returns successfully from calling pthread_detach() or pthread_join() for the thread. Termination is explained in the next section (see Thread Termination). The Threads Library assigns each new thread a thread identifier, which is written into the address specified as the pthread_ create() routine's thread argument. The new thread's thread identifier is written before the new thread executes. By default, the new thread's scheduling policy and priority are inherited from the creating thread-that is, by default, the pthread_create() routine ignores the scheduling policy and priority set in the specified thread attributes object. Thus, to create a thread that is subject to the scheduling policy and priority set in the specified thread attributes object, before calling pthread_create(), your program must use the pthread_attr_ setinheritsched() routine to set the inherit thread attributes object's scheduling attribute to PTHREAD_EXPLICIT_SCHED. On Tru64 UNIX, the signal state of the new thread is initialized as follows: 1. The signal mask is inherited from the creating thread. 2. The set of signals pending for the new thread is empty. If pthread_create() fails, no new thread is created, and the contents of the location referenced by thread are undefined. Thread Termination A thread terminates when one of the following events occurs: o The thread returns from its start routine. o The thread calls the pthread_exit() routine. o The thread is canceled. When a thread terminates, the following actions are performed: 1. A return value (if one is available) is written into the terminated thread's thread object, as follows: o If the thread has been canceled, the value PTHREAD_CANCELED is written into the thread's thread object. o If the thread terminated by returning from its start routine, the return value is copied from the start routine (if one is available) into the thread's thread object. Alternatively, if the thread explicitly called pthread_ exit(), the value received in the value_ptr argument (from pthread_exit()) is stored in the thread's thread object. Another thread can obtain this return value by joining with the terminated thread (using pthread_join()). NOTE If the thread terminated by returning from its start routine normally and the start routine does not provide a return value, the results obtained by joining with that thread are unpredictable. 2. If the termination results from a cancelation request or a call to pthread_exit(), the Threads Library calls, in turn, each cleanup handler that this thread declared (using pthread_ cleanup_push()) and that is not yet removed (using pthread_ cleanup_pop()). (The Threads Library also transfers control to any appropriate CATCH, CATCH_ALL, or FINALLY blocks .) The Threads Library calls the terminated thread's most recently pushed cleanup handler first. For C++ programmers: At normal exit from a thread, your program will call the appropriate destructor functions, just as if an exception had been raised. 3. To exit the terminated thread due to a call to pthread_exit(), the Threads Library raises the pthread_exit_e exception. To exit the terminated thread due to cancelation, the Threads Library raises the pthread_cancel_e exception. Your program can use the exception package to operate on the generated exception. (In particular, note that the practice of using CATCH handlers in place of pthread_cleanup_push() is not portable.) 4. For each of the terminated thread's thread-specific data keys that has a non-NULL value: o The thread's value for the corresponding key is set to NULL. o Call each thread-specific data destructor function in this multithreaded process' list of destructors. Repeat this step until all thread-specific data values in the thread are NULL, or for up to a number of iterations equal to PTHREAD_DESTRUCTOR_ITERATIONS. This destroys all thread- specific data associated with the terminated thread. 5. Awaken the thread (if there is one) that is currently waiting to join with the terminated thread. That is, awaken the thread that is waiting in a call to pthread_join(). 6. If the thread is already detached, destroy its thread object. Otherwise, the thread continues to exist until detached or joined with.
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