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2004-08-02 Ulrich Drepper <drepper@redhat.com> * linuxthreads.texi (Cleanup Handlers): Fix typo. Reported by Bjoern Engelmann <bjengelmann@gmx.de>.
1628 lines
67 KiB
Plaintext
1628 lines
67 KiB
Plaintext
@node POSIX Threads
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@c @node POSIX Threads, , Top, Top
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@chapter POSIX Threads
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@c %MENU% The standard threads library
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@c This chapter needs more work bigtime. -zw
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This chapter describes the pthreads (POSIX threads) library. This
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library provides support functions for multithreaded programs: thread
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primitives, synchronization objects, and so forth. It also implements
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POSIX 1003.1b semaphores (not to be confused with System V semaphores).
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The threads operations (@samp{pthread_*}) do not use @var{errno}.
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Instead they return an error code directly. The semaphore operations do
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use @var{errno}.
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@menu
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* Basic Thread Operations:: Creating, terminating, and waiting for threads.
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* Thread Attributes:: Tuning thread scheduling.
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* Cancellation:: Stopping a thread before it's done.
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* Cleanup Handlers:: Deallocating resources when a thread is
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canceled.
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* Mutexes:: One way to synchronize threads.
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* Condition Variables:: Another way.
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* POSIX Semaphores:: And a third way.
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* Thread-Specific Data:: Variables with different values in
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different threads.
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* Threads and Signal Handling:: Why you should avoid mixing the two, and
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how to do it if you must.
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* Threads and Fork:: Interactions between threads and the
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@code{fork} function.
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* Streams and Fork:: Interactions between stdio streams and
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@code{fork}.
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* Miscellaneous Thread Functions:: A grab bag of utility routines.
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@end menu
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@node Basic Thread Operations
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@section Basic Thread Operations
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These functions are the thread equivalents of @code{fork}, @code{exit},
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and @code{wait}.
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_create (pthread_t * @var{thread}, pthread_attr_t * @var{attr}, void * (*@var{start_routine})(void *), void * @var{arg})
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@code{pthread_create} creates a new thread of control that executes
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concurrently with the calling thread. The new thread calls the
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function @var{start_routine}, passing it @var{arg} as first argument. The
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new thread terminates either explicitly, by calling @code{pthread_exit},
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or implicitly, by returning from the @var{start_routine} function. The
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latter case is equivalent to calling @code{pthread_exit} with the result
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returned by @var{start_routine} as exit code.
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The @var{attr} argument specifies thread attributes to be applied to the
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new thread. @xref{Thread Attributes}, for details. The @var{attr}
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argument can also be @code{NULL}, in which case default attributes are
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used: the created thread is joinable (not detached) and has an ordinary
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(not realtime) scheduling policy.
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On success, the identifier of the newly created thread is stored in the
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location pointed by the @var{thread} argument, and a 0 is returned. On
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error, a non-zero error code is returned.
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This function may return the following errors:
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@table @code
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@item EAGAIN
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Not enough system resources to create a process for the new thread,
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or more than @code{PTHREAD_THREADS_MAX} threads are already active.
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@end table
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun void pthread_exit (void *@var{retval})
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@code{pthread_exit} terminates the execution of the calling thread. All
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cleanup handlers (@pxref{Cleanup Handlers}) that have been set for the
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calling thread with @code{pthread_cleanup_push} are executed in reverse
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order (the most recently pushed handler is executed first). Finalization
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functions for thread-specific data are then called for all keys that
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have non-@code{NULL} values associated with them in the calling thread
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(@pxref{Thread-Specific Data}). Finally, execution of the calling
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thread is stopped.
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The @var{retval} argument is the return value of the thread. It can be
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retrieved from another thread using @code{pthread_join}.
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The @code{pthread_exit} function never returns.
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_cancel (pthread_t @var{thread})
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@code{pthread_cancel} sends a cancellation request to the thread denoted
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by the @var{thread} argument. If there is no such thread,
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@code{pthread_cancel} fails and returns @code{ESRCH}. Otherwise it
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returns 0. @xref{Cancellation}, for details.
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_join (pthread_t @var{th}, void **thread_@var{return})
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@code{pthread_join} suspends the execution of the calling thread until
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the thread identified by @var{th} terminates, either by calling
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@code{pthread_exit} or by being canceled.
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If @var{thread_return} is not @code{NULL}, the return value of @var{th}
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is stored in the location pointed to by @var{thread_return}. The return
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value of @var{th} is either the argument it gave to @code{pthread_exit},
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or @code{PTHREAD_CANCELED} if @var{th} was canceled.
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The joined thread @code{th} must be in the joinable state: it must not
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have been detached using @code{pthread_detach} or the
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@code{PTHREAD_CREATE_DETACHED} attribute to @code{pthread_create}.
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When a joinable thread terminates, its memory resources (thread
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descriptor and stack) are not deallocated until another thread performs
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@code{pthread_join} on it. Therefore, @code{pthread_join} must be called
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once for each joinable thread created to avoid memory leaks.
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At most one thread can wait for the termination of a given
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thread. Calling @code{pthread_join} on a thread @var{th} on which
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another thread is already waiting for termination returns an error.
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@code{pthread_join} is a cancellation point. If a thread is canceled
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while suspended in @code{pthread_join}, the thread execution resumes
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immediately and the cancellation is executed without waiting for the
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@var{th} thread to terminate. If cancellation occurs during
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@code{pthread_join}, the @var{th} thread remains not joined.
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On success, the return value of @var{th} is stored in the location
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pointed to by @var{thread_return}, and 0 is returned. On error, one of
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the following values is returned:
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@table @code
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@item ESRCH
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No thread could be found corresponding to that specified by @var{th}.
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@item EINVAL
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The @var{th} thread has been detached, or another thread is already
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waiting on termination of @var{th}.
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@item EDEADLK
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The @var{th} argument refers to the calling thread.
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@end table
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@end deftypefun
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@node Thread Attributes
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@section Thread Attributes
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@comment pthread.h
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@comment POSIX
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Threads have a number of attributes that may be set at creation time.
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This is done by filling a thread attribute object @var{attr} of type
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@code{pthread_attr_t}, then passing it as second argument to
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@code{pthread_create}. Passing @code{NULL} is equivalent to passing a
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thread attribute object with all attributes set to their default values.
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Attribute objects are consulted only when creating a new thread. The
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same attribute object can be used for creating several threads.
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Modifying an attribute object after a call to @code{pthread_create} does
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not change the attributes of the thread previously created.
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_attr_init (pthread_attr_t *@var{attr})
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@code{pthread_attr_init} initializes the thread attribute object
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@var{attr} and fills it with default values for the attributes. (The
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default values are listed below for each attribute.)
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Each attribute @var{attrname} (see below for a list of all attributes)
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can be individually set using the function
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@code{pthread_attr_set@var{attrname}} and retrieved using the function
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@code{pthread_attr_get@var{attrname}}.
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_attr_destroy (pthread_attr_t *@var{attr})
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@code{pthread_attr_destroy} destroys the attribute object pointed to by
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@var{attr} releasing any resources associated with it. @var{attr} is
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left in an undefined state, and you must not use it again in a call to
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any pthreads function until it has been reinitialized.
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@end deftypefun
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@findex pthread_attr_setdetachstate
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@findex pthread_attr_setguardsize
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@findex pthread_attr_setinheritsched
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@findex pthread_attr_setschedparam
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@findex pthread_attr_setschedpolicy
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@findex pthread_attr_setscope
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@findex pthread_attr_setstack
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@findex pthread_attr_setstackaddr
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@findex pthread_attr_setstacksize
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_attr_setattr (pthread_attr_t *@var{obj}, int @var{value})
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Set attribute @var{attr} to @var{value} in the attribute object pointed
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to by @var{obj}. See below for a list of possible attributes and the
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values they can take.
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On success, these functions return 0. If @var{value} is not meaningful
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for the @var{attr} being modified, they will return the error code
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@code{EINVAL}. Some of the functions have other failure modes; see
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below.
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@end deftypefun
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@findex pthread_attr_getdetachstate
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@findex pthread_attr_getguardsize
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@findex pthread_attr_getinheritsched
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@findex pthread_attr_getschedparam
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@findex pthread_attr_getschedpolicy
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@findex pthread_attr_getscope
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@findex pthread_attr_getstack
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@findex pthread_attr_getstackaddr
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@findex pthread_attr_getstacksize
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_attr_getattr (const pthread_attr_t *@var{obj}, int *@var{value})
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Store the current setting of @var{attr} in @var{obj} into the variable
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pointed to by @var{value}.
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These functions always return 0.
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@end deftypefun
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The following thread attributes are supported:
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@table @samp
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@item detachstate
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Choose whether the thread is created in the joinable state (value
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@code{PTHREAD_CREATE_JOINABLE}) or in the detached state
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(@code{PTHREAD_CREATE_DETACHED}). The default is
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@code{PTHREAD_CREATE_JOINABLE}.
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In the joinable state, another thread can synchronize on the thread
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termination and recover its termination code using @code{pthread_join},
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but some of the thread resources are kept allocated after the thread
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terminates, and reclaimed only when another thread performs
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@code{pthread_join} on that thread.
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In the detached state, the thread resources are immediately freed when
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it terminates, but @code{pthread_join} cannot be used to synchronize on
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the thread termination.
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A thread created in the joinable state can later be put in the detached
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thread using @code{pthread_detach}.
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@item schedpolicy
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Select the scheduling policy for the thread: one of @code{SCHED_OTHER}
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(regular, non-realtime scheduling), @code{SCHED_RR} (realtime,
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round-robin) or @code{SCHED_FIFO} (realtime, first-in first-out).
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The default is @code{SCHED_OTHER}.
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@c Not doc'd in our manual: FIXME.
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@c See @code{sched_setpolicy} for more information on scheduling policies.
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The realtime scheduling policies @code{SCHED_RR} and @code{SCHED_FIFO}
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are available only to processes with superuser privileges.
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@code{pthread_attr_setschedparam} will fail and return @code{ENOTSUP} if
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you try to set a realtime policy when you are unprivileged.
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The scheduling policy of a thread can be changed after creation with
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@code{pthread_setschedparam}.
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@item schedparam
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Change the scheduling parameter (the scheduling priority)
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for the thread. The default is 0.
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This attribute is not significant if the scheduling policy is
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@code{SCHED_OTHER}; it only matters for the realtime policies
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@code{SCHED_RR} and @code{SCHED_FIFO}.
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The scheduling priority of a thread can be changed after creation with
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@code{pthread_setschedparam}.
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@item inheritsched
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Choose whether the scheduling policy and scheduling parameter for the
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newly created thread are determined by the values of the
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@var{schedpolicy} and @var{schedparam} attributes (value
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@code{PTHREAD_EXPLICIT_SCHED}) or are inherited from the parent thread
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(value @code{PTHREAD_INHERIT_SCHED}). The default is
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@code{PTHREAD_EXPLICIT_SCHED}.
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@item scope
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Choose the scheduling contention scope for the created thread. The
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default is @code{PTHREAD_SCOPE_SYSTEM}, meaning that the threads contend
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for CPU time with all processes running on the machine. In particular,
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thread priorities are interpreted relative to the priorities of all
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other processes on the machine. The other possibility,
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@code{PTHREAD_SCOPE_PROCESS}, means that scheduling contention occurs
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only between the threads of the running process: thread priorities are
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interpreted relative to the priorities of the other threads of the
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process, regardless of the priorities of other processes.
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@code{PTHREAD_SCOPE_PROCESS} is not supported in LinuxThreads. If you
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try to set the scope to this value, @code{pthread_attr_setscope} will
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fail and return @code{ENOTSUP}.
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@item stackaddr
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Provide an address for an application managed stack. The size of the
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stack must be at least @code{PTHREAD_STACK_MIN}.
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@item stacksize
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Change the size of the stack created for the thread. The value defines
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the minimum stack size, in bytes.
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If the value exceeds the system's maximum stack size, or is smaller
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than @code{PTHREAD_STACK_MIN}, @code{pthread_attr_setstacksize} will
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fail and return @code{EINVAL}.
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@item stack
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Provide both the address and size of an application managed stack to
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use for the new thread. The base of the memory area is @var{stackaddr}
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with the size of the memory area, @var{stacksize}, measured in bytes.
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If the value of @var{stacksize} is less than @code{PTHREAD_STACK_MIN},
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or greater than the system's maximum stack size, or if the value of
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@var{stackaddr} lacks the proper alignment, @code{pthread_attr_setstack}
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will fail and return @code{EINVAL}.
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@item guardsize
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Change the minimum size in bytes of the guard area for the thread's
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stack. The default size is a single page. If this value is set, it
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will be rounded up to the nearest page size. If the value is set to 0,
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a guard area will not be created for this thread. The space allocated
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for the guard area is used to catch stack overflow. Therefore, when
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allocating large structures on the stack, a larger guard area may be
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required to catch a stack overflow.
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If the caller is managing their own stacks (if the @code{stackaddr}
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attribute has been set), then the @code{guardsize} attribute is ignored.
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If the value exceeds the @code{stacksize}, @code{pthread_atrr_setguardsize}
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will fail and return @code{EINVAL}.
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@end table
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@node Cancellation
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@section Cancellation
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Cancellation is the mechanism by which a thread can terminate the
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execution of another thread. More precisely, a thread can send a
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cancellation request to another thread. Depending on its settings, the
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target thread can then either ignore the request, honor it immediately,
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or defer it till it reaches a cancellation point. When threads are
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first created by @code{pthread_create}, they always defer cancellation
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requests.
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When a thread eventually honors a cancellation request, it behaves as if
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@code{pthread_exit(PTHREAD_CANCELED)} was called. All cleanup handlers
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are executed in reverse order, finalization functions for
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thread-specific data are called, and finally the thread stops executing.
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If the canceled thread was joinable, the return value
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@code{PTHREAD_CANCELED} is provided to whichever thread calls
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@var{pthread_join} on it. See @code{pthread_exit} for more information.
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Cancellation points are the points where the thread checks for pending
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cancellation requests and performs them. The POSIX threads functions
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@code{pthread_join}, @code{pthread_cond_wait},
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@code{pthread_cond_timedwait}, @code{pthread_testcancel},
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@code{sem_wait}, and @code{sigwait} are cancellation points. In
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addition, these system calls are cancellation points:
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@multitable @columnfractions .33 .33 .33
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@item @t{accept} @tab @t{open} @tab @t{sendmsg}
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@item @t{close} @tab @t{pause} @tab @t{sendto}
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@item @t{connect} @tab @t{read} @tab @t{system}
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@item @t{fcntl} @tab @t{recv} @tab @t{tcdrain}
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@item @t{fsync} @tab @t{recvfrom} @tab @t{wait}
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@item @t{lseek} @tab @t{recvmsg} @tab @t{waitpid}
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@item @t{msync} @tab @t{send} @tab @t{write}
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@item @t{nanosleep}
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@end multitable
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@noindent
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All library functions that call these functions (such as
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@code{printf}) are also cancellation points.
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_setcancelstate (int @var{state}, int *@var{oldstate})
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@code{pthread_setcancelstate} changes the cancellation state for the
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calling thread -- that is, whether cancellation requests are ignored or
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not. The @var{state} argument is the new cancellation state: either
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@code{PTHREAD_CANCEL_ENABLE} to enable cancellation, or
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@code{PTHREAD_CANCEL_DISABLE} to disable cancellation (cancellation
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requests are ignored).
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If @var{oldstate} is not @code{NULL}, the previous cancellation state is
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stored in the location pointed to by @var{oldstate}, and can thus be
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restored later by another call to @code{pthread_setcancelstate}.
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If the @var{state} argument is not @code{PTHREAD_CANCEL_ENABLE} or
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@code{PTHREAD_CANCEL_DISABLE}, @code{pthread_setcancelstate} fails and
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returns @code{EINVAL}. Otherwise it returns 0.
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_setcanceltype (int @var{type}, int *@var{oldtype})
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@code{pthread_setcanceltype} changes the type of responses to
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cancellation requests for the calling thread: asynchronous (immediate)
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or deferred. The @var{type} argument is the new cancellation type:
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either @code{PTHREAD_CANCEL_ASYNCHRONOUS} to cancel the calling thread
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as soon as the cancellation request is received, or
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@code{PTHREAD_CANCEL_DEFERRED} to keep the cancellation request pending
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until the next cancellation point. If @var{oldtype} is not @code{NULL},
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the previous cancellation state is stored in the location pointed to by
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@var{oldtype}, and can thus be restored later by another call to
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@code{pthread_setcanceltype}.
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If the @var{type} argument is not @code{PTHREAD_CANCEL_DEFERRED} or
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@code{PTHREAD_CANCEL_ASYNCHRONOUS}, @code{pthread_setcanceltype} fails
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and returns @code{EINVAL}. Otherwise it returns 0.
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun void pthread_testcancel (@var{void})
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@code{pthread_testcancel} does nothing except testing for pending
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cancellation and executing it. Its purpose is to introduce explicit
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checks for cancellation in long sequences of code that do not call
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cancellation point functions otherwise.
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@end deftypefun
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@node Cleanup Handlers
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@section Cleanup Handlers
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Cleanup handlers are functions that get called when a thread terminates,
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either by calling @code{pthread_exit} or because of
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cancellation. Cleanup handlers are installed and removed following a
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stack-like discipline.
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The purpose of cleanup handlers is to free the resources that a thread
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may hold at the time it terminates. In particular, if a thread exits or
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is canceled while it owns a locked mutex, the mutex will remain locked
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forever and prevent other threads from executing normally. The best way
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to avoid this is, just before locking the mutex, to install a cleanup
|
|
handler whose effect is to unlock the mutex. Cleanup handlers can be
|
|
used similarly to free blocks allocated with @code{malloc} or close file
|
|
descriptors on thread termination.
|
|
|
|
Here is how to lock a mutex @var{mut} in such a way that it will be
|
|
unlocked if the thread is canceled while @var{mut} is locked:
|
|
|
|
@smallexample
|
|
pthread_cleanup_push(pthread_mutex_unlock, (void *) &mut);
|
|
pthread_mutex_lock(&mut);
|
|
/* do some work */
|
|
pthread_mutex_unlock(&mut);
|
|
pthread_cleanup_pop(0);
|
|
@end smallexample
|
|
|
|
Equivalently, the last two lines can be replaced by
|
|
|
|
@smallexample
|
|
pthread_cleanup_pop(1);
|
|
@end smallexample
|
|
|
|
Notice that the code above is safe only in deferred cancellation mode
|
|
(see @code{pthread_setcanceltype}). In asynchronous cancellation mode, a
|
|
cancellation can occur between @code{pthread_cleanup_push} and
|
|
@code{pthread_mutex_lock}, or between @code{pthread_mutex_unlock} and
|
|
@code{pthread_cleanup_pop}, resulting in both cases in the thread trying
|
|
to unlock a mutex not locked by the current thread. This is the main
|
|
reason why asynchronous cancellation is difficult to use.
|
|
|
|
If the code above must also work in asynchronous cancellation mode,
|
|
then it must switch to deferred mode for locking and unlocking the
|
|
mutex:
|
|
|
|
@smallexample
|
|
pthread_setcanceltype(PTHREAD_CANCEL_DEFERRED, &oldtype);
|
|
pthread_cleanup_push(pthread_mutex_unlock, (void *) &mut);
|
|
pthread_mutex_lock(&mut);
|
|
/* do some work */
|
|
pthread_cleanup_pop(1);
|
|
pthread_setcanceltype(oldtype, NULL);
|
|
@end smallexample
|
|
|
|
The code above can be rewritten in a more compact and efficient way,
|
|
using the non-portable functions @code{pthread_cleanup_push_defer_np}
|
|
and @code{pthread_cleanup_pop_restore_np}:
|
|
|
|
@smallexample
|
|
pthread_cleanup_push_defer_np(pthread_mutex_unlock, (void *) &mut);
|
|
pthread_mutex_lock(&mut);
|
|
/* do some work */
|
|
pthread_cleanup_pop_restore_np(1);
|
|
@end smallexample
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun void pthread_cleanup_push (void (*@var{routine}) (void *), void *@var{arg})
|
|
|
|
@code{pthread_cleanup_push} installs the @var{routine} function with
|
|
argument @var{arg} as a cleanup handler. From this point on to the
|
|
matching @code{pthread_cleanup_pop}, the function @var{routine} will be
|
|
called with arguments @var{arg} when the thread terminates, either
|
|
through @code{pthread_exit} or by cancellation. If several cleanup
|
|
handlers are active at that point, they are called in LIFO order: the
|
|
most recently installed handler is called first.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun void pthread_cleanup_pop (int @var{execute})
|
|
@code{pthread_cleanup_pop} removes the most recently installed cleanup
|
|
handler. If the @var{execute} argument is not 0, it also executes the
|
|
handler, by calling the @var{routine} function with arguments
|
|
@var{arg}. If the @var{execute} argument is 0, the handler is only
|
|
removed but not executed.
|
|
@end deftypefun
|
|
|
|
Matching pairs of @code{pthread_cleanup_push} and
|
|
@code{pthread_cleanup_pop} must occur in the same function, at the same
|
|
level of block nesting. Actually, @code{pthread_cleanup_push} and
|
|
@code{pthread_cleanup_pop} are macros, and the expansion of
|
|
@code{pthread_cleanup_push} introduces an open brace @code{@{} with the
|
|
matching closing brace @code{@}} being introduced by the expansion of the
|
|
matching @code{pthread_cleanup_pop}.
|
|
|
|
@comment pthread.h
|
|
@comment GNU
|
|
@deftypefun void pthread_cleanup_push_defer_np (void (*@var{routine}) (void *), void *@var{arg})
|
|
@code{pthread_cleanup_push_defer_np} is a non-portable extension that
|
|
combines @code{pthread_cleanup_push} and @code{pthread_setcanceltype}.
|
|
It pushes a cleanup handler just as @code{pthread_cleanup_push} does,
|
|
but also saves the current cancellation type and sets it to deferred
|
|
cancellation. This ensures that the cleanup mechanism is effective even
|
|
if the thread was initially in asynchronous cancellation mode.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment GNU
|
|
@deftypefun void pthread_cleanup_pop_restore_np (int @var{execute})
|
|
@code{pthread_cleanup_pop_restore_np} pops a cleanup handler introduced
|
|
by @code{pthread_cleanup_push_defer_np}, and restores the cancellation
|
|
type to its value at the time @code{pthread_cleanup_push_defer_np} was
|
|
called.
|
|
@end deftypefun
|
|
|
|
@code{pthread_cleanup_push_defer_np} and
|
|
@code{pthread_cleanup_pop_restore_np} must occur in matching pairs, at
|
|
the same level of block nesting.
|
|
|
|
The sequence
|
|
|
|
@smallexample
|
|
pthread_cleanup_push_defer_np(routine, arg);
|
|
...
|
|
pthread_cleanup_pop_restore_np(execute);
|
|
@end smallexample
|
|
|
|
@noindent
|
|
is functionally equivalent to (but more compact and efficient than)
|
|
|
|
@smallexample
|
|
@{
|
|
int oldtype;
|
|
pthread_setcanceltype(PTHREAD_CANCEL_DEFERRED, &oldtype);
|
|
pthread_cleanup_push(routine, arg);
|
|
...
|
|
pthread_cleanup_pop(execute);
|
|
pthread_setcanceltype(oldtype, NULL);
|
|
@}
|
|
@end smallexample
|
|
|
|
|
|
@node Mutexes
|
|
@section Mutexes
|
|
|
|
A mutex is a MUTual EXclusion device, and is useful for protecting
|
|
shared data structures from concurrent modifications, and implementing
|
|
critical sections and monitors.
|
|
|
|
A mutex has two possible states: unlocked (not owned by any thread),
|
|
and locked (owned by one thread). A mutex can never be owned by two
|
|
different threads simultaneously. A thread attempting to lock a mutex
|
|
that is already locked by another thread is suspended until the owning
|
|
thread unlocks the mutex first.
|
|
|
|
None of the mutex functions is a cancellation point, not even
|
|
@code{pthread_mutex_lock}, in spite of the fact that it can suspend a
|
|
thread for arbitrary durations. This way, the status of mutexes at
|
|
cancellation points is predictable, allowing cancellation handlers to
|
|
unlock precisely those mutexes that need to be unlocked before the
|
|
thread stops executing. Consequently, threads using deferred
|
|
cancellation should never hold a mutex for extended periods of time.
|
|
|
|
It is not safe to call mutex functions from a signal handler. In
|
|
particular, calling @code{pthread_mutex_lock} or
|
|
@code{pthread_mutex_unlock} from a signal handler may deadlock the
|
|
calling thread.
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_mutex_init (pthread_mutex_t *@var{mutex}, const pthread_mutexattr_t *@var{mutexattr})
|
|
|
|
@code{pthread_mutex_init} initializes the mutex object pointed to by
|
|
@var{mutex} according to the mutex attributes specified in @var{mutexattr}.
|
|
If @var{mutexattr} is @code{NULL}, default attributes are used instead.
|
|
|
|
The LinuxThreads implementation supports only one mutex attribute,
|
|
the @var{mutex type}, which is either ``fast'', ``recursive'', or
|
|
``error checking''. The type of a mutex determines whether
|
|
it can be locked again by a thread that already owns it.
|
|
The default type is ``fast''.
|
|
|
|
Variables of type @code{pthread_mutex_t} can also be initialized
|
|
statically, using the constants @code{PTHREAD_MUTEX_INITIALIZER} (for
|
|
timed mutexes), @code{PTHREAD_RECURSIVE_MUTEX_INITIALIZER_NP} (for
|
|
recursive mutexes), @code{PTHREAD_ADAPTIVE_MUTEX_INITIALIZER_NP}
|
|
(for fast mutexes(, and @code{PTHREAD_ERRORCHECK_MUTEX_INITIALIZER_NP}
|
|
(for error checking mutexes).
|
|
|
|
@code{pthread_mutex_init} always returns 0.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_mutex_lock (pthread_mutex_t *mutex))
|
|
@code{pthread_mutex_lock} locks the given mutex. If the mutex is
|
|
currently unlocked, it becomes locked and owned by the calling thread,
|
|
and @code{pthread_mutex_lock} returns immediately. If the mutex is
|
|
already locked by another thread, @code{pthread_mutex_lock} suspends the
|
|
calling thread until the mutex is unlocked.
|
|
|
|
If the mutex is already locked by the calling thread, the behavior of
|
|
@code{pthread_mutex_lock} depends on the type of the mutex. If the mutex
|
|
is of the ``fast'' type, the calling thread is suspended. It will
|
|
remain suspended forever, because no other thread can unlock the mutex.
|
|
If the mutex is of the ``error checking'' type, @code{pthread_mutex_lock}
|
|
returns immediately with the error code @code{EDEADLK}. If the mutex is
|
|
of the ``recursive'' type, @code{pthread_mutex_lock} succeeds and
|
|
returns immediately, recording the number of times the calling thread
|
|
has locked the mutex. An equal number of @code{pthread_mutex_unlock}
|
|
operations must be performed before the mutex returns to the unlocked
|
|
state.
|
|
@c This doesn't discuss PTHREAD_MUTEX_TIMED_NP mutex attributes. FIXME
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_mutex_trylock (pthread_mutex_t *@var{mutex})
|
|
@code{pthread_mutex_trylock} behaves identically to
|
|
@code{pthread_mutex_lock}, except that it does not block the calling
|
|
thread if the mutex is already locked by another thread (or by the
|
|
calling thread in the case of a ``fast'' mutex). Instead,
|
|
@code{pthread_mutex_trylock} returns immediately with the error code
|
|
@code{EBUSY}.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_mutex_timedlock (pthread_mutex_t *@var{mutex}, const struct timespec *@var{abstime})
|
|
The @code{pthread_mutex_timedlock} is similar to the
|
|
@code{pthread_mutex_lock} function but instead of blocking for in
|
|
indefinite time if the mutex is locked by another thread, it returns
|
|
when the time specified in @var{abstime} is reached.
|
|
|
|
This function can only be used on standard (``timed'') and ``error
|
|
checking'' mutexes. It behaves just like @code{pthread_mutex_lock} for
|
|
all other types.
|
|
|
|
If the mutex is successfully locked, the function returns zero. If the
|
|
time specified in @var{abstime} is reached without the mutex being locked,
|
|
@code{ETIMEDOUT} is returned.
|
|
|
|
This function was introduced in the POSIX.1d revision of the POSIX standard.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_mutex_unlock (pthread_mutex_t *@var{mutex})
|
|
@code{pthread_mutex_unlock} unlocks the given mutex. The mutex is
|
|
assumed to be locked and owned by the calling thread on entrance to
|
|
@code{pthread_mutex_unlock}. If the mutex is of the ``fast'' type,
|
|
@code{pthread_mutex_unlock} always returns it to the unlocked state. If
|
|
it is of the ``recursive'' type, it decrements the locking count of the
|
|
mutex (number of @code{pthread_mutex_lock} operations performed on it by
|
|
the calling thread), and only when this count reaches zero is the mutex
|
|
actually unlocked.
|
|
|
|
On ``error checking'' mutexes, @code{pthread_mutex_unlock} actually
|
|
checks at run-time that the mutex is locked on entrance, and that it was
|
|
locked by the same thread that is now calling
|
|
@code{pthread_mutex_unlock}. If these conditions are not met,
|
|
@code{pthread_mutex_unlock} returns @code{EPERM}, and the mutex remains
|
|
unchanged. ``Fast'' and ``recursive'' mutexes perform no such checks,
|
|
thus allowing a locked mutex to be unlocked by a thread other than its
|
|
owner. This is non-portable behavior and must not be relied upon.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_mutex_destroy (pthread_mutex_t *@var{mutex})
|
|
@code{pthread_mutex_destroy} destroys a mutex object, freeing the
|
|
resources it might hold. The mutex must be unlocked on entrance. In the
|
|
LinuxThreads implementation, no resources are associated with mutex
|
|
objects, thus @code{pthread_mutex_destroy} actually does nothing except
|
|
checking that the mutex is unlocked.
|
|
|
|
If the mutex is locked by some thread, @code{pthread_mutex_destroy}
|
|
returns @code{EBUSY}. Otherwise it returns 0.
|
|
@end deftypefun
|
|
|
|
If any of the above functions (except @code{pthread_mutex_init})
|
|
is applied to an uninitialized mutex, they will simply return
|
|
@code{EINVAL} and do nothing.
|
|
|
|
A shared global variable @var{x} can be protected by a mutex as follows:
|
|
|
|
@smallexample
|
|
int x;
|
|
pthread_mutex_t mut = PTHREAD_MUTEX_INITIALIZER;
|
|
@end smallexample
|
|
|
|
All accesses and modifications to @var{x} should be bracketed by calls to
|
|
@code{pthread_mutex_lock} and @code{pthread_mutex_unlock} as follows:
|
|
|
|
@smallexample
|
|
pthread_mutex_lock(&mut);
|
|
/* operate on x */
|
|
pthread_mutex_unlock(&mut);
|
|
@end smallexample
|
|
|
|
Mutex attributes can be specified at mutex creation time, by passing a
|
|
mutex attribute object as second argument to @code{pthread_mutex_init}.
|
|
Passing @code{NULL} is equivalent to passing a mutex attribute object
|
|
with all attributes set to their default values.
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_mutexattr_init (pthread_mutexattr_t *@var{attr})
|
|
@code{pthread_mutexattr_init} initializes the mutex attribute object
|
|
@var{attr} and fills it with default values for the attributes.
|
|
|
|
This function always returns 0.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_mutexattr_destroy (pthread_mutexattr_t *@var{attr})
|
|
@code{pthread_mutexattr_destroy} destroys a mutex attribute object,
|
|
which must not be reused until it is
|
|
reinitialized. @code{pthread_mutexattr_destroy} does nothing in the
|
|
LinuxThreads implementation.
|
|
|
|
This function always returns 0.
|
|
@end deftypefun
|
|
|
|
LinuxThreads supports only one mutex attribute: the mutex type, which is
|
|
either @code{PTHREAD_MUTEX_ADAPTIVE_NP} for ``fast'' mutexes,
|
|
@code{PTHREAD_MUTEX_RECURSIVE_NP} for ``recursive'' mutexes,
|
|
@code{PTHREAD_MUTEX_TIMED_NP} for ``timed'' mutexes, or
|
|
@code{PTHREAD_MUTEX_ERRORCHECK_NP} for ``error checking'' mutexes. As
|
|
the @code{NP} suffix indicates, this is a non-portable extension to the
|
|
POSIX standard and should not be employed in portable programs.
|
|
|
|
The mutex type determines what happens if a thread attempts to lock a
|
|
mutex it already owns with @code{pthread_mutex_lock}. If the mutex is of
|
|
the ``fast'' type, @code{pthread_mutex_lock} simply suspends the calling
|
|
thread forever. If the mutex is of the ``error checking'' type,
|
|
@code{pthread_mutex_lock} returns immediately with the error code
|
|
@code{EDEADLK}. If the mutex is of the ``recursive'' type, the call to
|
|
@code{pthread_mutex_lock} returns immediately with a success return
|
|
code. The number of times the thread owning the mutex has locked it is
|
|
recorded in the mutex. The owning thread must call
|
|
@code{pthread_mutex_unlock} the same number of times before the mutex
|
|
returns to the unlocked state.
|
|
|
|
The default mutex type is ``timed'', that is, @code{PTHREAD_MUTEX_TIMED_NP}.
|
|
@c This doesn't describe how a ``timed'' mutex behaves. FIXME
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_mutexattr_settype (pthread_mutexattr_t *@var{attr}, int @var{type})
|
|
@code{pthread_mutexattr_settype} sets the mutex type attribute in
|
|
@var{attr} to the value specified by @var{type}.
|
|
|
|
If @var{type} is not @code{PTHREAD_MUTEX_ADAPTIVE_NP},
|
|
@code{PTHREAD_MUTEX_RECURSIVE_NP}, @code{PTHREAD_MUTEX_TIMED_NP}, or
|
|
@code{PTHREAD_MUTEX_ERRORCHECK_NP}, this function will return
|
|
@code{EINVAL} and leave @var{attr} unchanged.
|
|
|
|
The standard Unix98 identifiers @code{PTHREAD_MUTEX_DEFAULT},
|
|
@code{PTHREAD_MUTEX_NORMAL}, @code{PTHREAD_MUTEX_RECURSIVE},
|
|
and @code{PTHREAD_MUTEX_ERRORCHECK} are also permitted.
|
|
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_mutexattr_gettype (const pthread_mutexattr_t *@var{attr}, int *@var{type})
|
|
@code{pthread_mutexattr_gettype} retrieves the current value of the
|
|
mutex type attribute in @var{attr} and stores it in the location pointed
|
|
to by @var{type}.
|
|
|
|
This function always returns 0.
|
|
@end deftypefun
|
|
|
|
@node Condition Variables
|
|
@section Condition Variables
|
|
|
|
A condition (short for ``condition variable'') is a synchronization
|
|
device that allows threads to suspend execution until some predicate on
|
|
shared data is satisfied. The basic operations on conditions are: signal
|
|
the condition (when the predicate becomes true), and wait for the
|
|
condition, suspending the thread execution until another thread signals
|
|
the condition.
|
|
|
|
A condition variable must always be associated with a mutex, to avoid
|
|
the race condition where a thread prepares to wait on a condition
|
|
variable and another thread signals the condition just before the first
|
|
thread actually waits on it.
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_cond_init (pthread_cond_t *@var{cond}, pthread_condattr_t *cond_@var{attr})
|
|
|
|
@code{pthread_cond_init} initializes the condition variable @var{cond},
|
|
using the condition attributes specified in @var{cond_attr}, or default
|
|
attributes if @var{cond_attr} is @code{NULL}. The LinuxThreads
|
|
implementation supports no attributes for conditions, hence the
|
|
@var{cond_attr} parameter is actually ignored.
|
|
|
|
Variables of type @code{pthread_cond_t} can also be initialized
|
|
statically, using the constant @code{PTHREAD_COND_INITIALIZER}.
|
|
|
|
This function always returns 0.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_cond_signal (pthread_cond_t *@var{cond})
|
|
@code{pthread_cond_signal} restarts one of the threads that are waiting
|
|
on the condition variable @var{cond}. If no threads are waiting on
|
|
@var{cond}, nothing happens. If several threads are waiting on
|
|
@var{cond}, exactly one is restarted, but it is not specified which.
|
|
|
|
This function always returns 0.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_cond_broadcast (pthread_cond_t *@var{cond})
|
|
@code{pthread_cond_broadcast} restarts all the threads that are waiting
|
|
on the condition variable @var{cond}. Nothing happens if no threads are
|
|
waiting on @var{cond}.
|
|
|
|
This function always returns 0.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_cond_wait (pthread_cond_t *@var{cond}, pthread_mutex_t *@var{mutex})
|
|
@code{pthread_cond_wait} atomically unlocks the @var{mutex} (as per
|
|
@code{pthread_unlock_mutex}) and waits for the condition variable
|
|
@var{cond} to be signaled. The thread execution is suspended and does
|
|
not consume any CPU time until the condition variable is signaled. The
|
|
@var{mutex} must be locked by the calling thread on entrance to
|
|
@code{pthread_cond_wait}. Before returning to the calling thread,
|
|
@code{pthread_cond_wait} re-acquires @var{mutex} (as per
|
|
@code{pthread_lock_mutex}).
|
|
|
|
Unlocking the mutex and suspending on the condition variable is done
|
|
atomically. Thus, if all threads always acquire the mutex before
|
|
signaling the condition, this guarantees that the condition cannot be
|
|
signaled (and thus ignored) between the time a thread locks the mutex
|
|
and the time it waits on the condition variable.
|
|
|
|
This function always returns 0.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_cond_timedwait (pthread_cond_t *@var{cond}, pthread_mutex_t *@var{mutex}, const struct timespec *@var{abstime})
|
|
@code{pthread_cond_timedwait} atomically unlocks @var{mutex} and waits
|
|
on @var{cond}, as @code{pthread_cond_wait} does, but it also bounds the
|
|
duration of the wait. If @var{cond} has not been signaled before time
|
|
@var{abstime}, the mutex @var{mutex} is re-acquired and
|
|
@code{pthread_cond_timedwait} returns the error code @code{ETIMEDOUT}.
|
|
The wait can also be interrupted by a signal; in that case
|
|
@code{pthread_cond_timedwait} returns @code{EINTR}.
|
|
|
|
The @var{abstime} parameter specifies an absolute time, with the same
|
|
origin as @code{time} and @code{gettimeofday}: an @var{abstime} of 0
|
|
corresponds to 00:00:00 GMT, January 1, 1970.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_cond_destroy (pthread_cond_t *@var{cond})
|
|
@code{pthread_cond_destroy} destroys the condition variable @var{cond},
|
|
freeing the resources it might hold. If any threads are waiting on the
|
|
condition variable, @code{pthread_cond_destroy} leaves @var{cond}
|
|
untouched and returns @code{EBUSY}. Otherwise it returns 0, and
|
|
@var{cond} must not be used again until it is reinitialized.
|
|
|
|
In the LinuxThreads implementation, no resources are associated with
|
|
condition variables, so @code{pthread_cond_destroy} actually does
|
|
nothing.
|
|
@end deftypefun
|
|
|
|
@code{pthread_cond_wait} and @code{pthread_cond_timedwait} are
|
|
cancellation points. If a thread is canceled while suspended in one of
|
|
these functions, the thread immediately resumes execution, relocks the
|
|
mutex specified by @var{mutex}, and finally executes the cancellation.
|
|
Consequently, cleanup handlers are assured that @var{mutex} is locked
|
|
when they are called.
|
|
|
|
It is not safe to call the condition variable functions from a signal
|
|
handler. In particular, calling @code{pthread_cond_signal} or
|
|
@code{pthread_cond_broadcast} from a signal handler may deadlock the
|
|
calling thread.
|
|
|
|
Consider two shared variables @var{x} and @var{y}, protected by the
|
|
mutex @var{mut}, and a condition variable @var{cond} that is to be
|
|
signaled whenever @var{x} becomes greater than @var{y}.
|
|
|
|
@smallexample
|
|
int x,y;
|
|
pthread_mutex_t mut = PTHREAD_MUTEX_INITIALIZER;
|
|
pthread_cond_t cond = PTHREAD_COND_INITIALIZER;
|
|
@end smallexample
|
|
|
|
Waiting until @var{x} is greater than @var{y} is performed as follows:
|
|
|
|
@smallexample
|
|
pthread_mutex_lock(&mut);
|
|
while (x <= y) @{
|
|
pthread_cond_wait(&cond, &mut);
|
|
@}
|
|
/* operate on x and y */
|
|
pthread_mutex_unlock(&mut);
|
|
@end smallexample
|
|
|
|
Modifications on @var{x} and @var{y} that may cause @var{x} to become greater than
|
|
@var{y} should signal the condition if needed:
|
|
|
|
@smallexample
|
|
pthread_mutex_lock(&mut);
|
|
/* modify x and y */
|
|
if (x > y) pthread_cond_broadcast(&cond);
|
|
pthread_mutex_unlock(&mut);
|
|
@end smallexample
|
|
|
|
If it can be proved that at most one waiting thread needs to be waken
|
|
up (for instance, if there are only two threads communicating through
|
|
@var{x} and @var{y}), @code{pthread_cond_signal} can be used as a slightly more
|
|
efficient alternative to @code{pthread_cond_broadcast}. In doubt, use
|
|
@code{pthread_cond_broadcast}.
|
|
|
|
To wait for @var{x} to becomes greater than @var{y} with a timeout of 5
|
|
seconds, do:
|
|
|
|
@smallexample
|
|
struct timeval now;
|
|
struct timespec timeout;
|
|
int retcode;
|
|
|
|
pthread_mutex_lock(&mut);
|
|
gettimeofday(&now);
|
|
timeout.tv_sec = now.tv_sec + 5;
|
|
timeout.tv_nsec = now.tv_usec * 1000;
|
|
retcode = 0;
|
|
while (x <= y && retcode != ETIMEDOUT) @{
|
|
retcode = pthread_cond_timedwait(&cond, &mut, &timeout);
|
|
@}
|
|
if (retcode == ETIMEDOUT) @{
|
|
/* timeout occurred */
|
|
@} else @{
|
|
/* operate on x and y */
|
|
@}
|
|
pthread_mutex_unlock(&mut);
|
|
@end smallexample
|
|
|
|
Condition attributes can be specified at condition creation time, by
|
|
passing a condition attribute object as second argument to
|
|
@code{pthread_cond_init}. Passing @code{NULL} is equivalent to passing
|
|
a condition attribute object with all attributes set to their default
|
|
values.
|
|
|
|
The LinuxThreads implementation supports no attributes for
|
|
conditions. The functions on condition attributes are included only for
|
|
compliance with the POSIX standard.
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_condattr_init (pthread_condattr_t *@var{attr})
|
|
@deftypefunx int pthread_condattr_destroy (pthread_condattr_t *@var{attr})
|
|
@code{pthread_condattr_init} initializes the condition attribute object
|
|
@var{attr} and fills it with default values for the attributes.
|
|
@code{pthread_condattr_destroy} destroys the condition attribute object
|
|
@var{attr}.
|
|
|
|
Both functions do nothing in the LinuxThreads implementation.
|
|
|
|
@code{pthread_condattr_init} and @code{pthread_condattr_destroy} always
|
|
return 0.
|
|
@end deftypefun
|
|
|
|
@node POSIX Semaphores
|
|
@section POSIX Semaphores
|
|
|
|
@vindex SEM_VALUE_MAX
|
|
Semaphores are counters for resources shared between threads. The
|
|
basic operations on semaphores are: increment the counter atomically,
|
|
and wait until the counter is non-null and decrement it atomically.
|
|
|
|
Semaphores have a maximum value past which they cannot be incremented.
|
|
The macro @code{SEM_VALUE_MAX} is defined to be this maximum value. In
|
|
the GNU C library, @code{SEM_VALUE_MAX} is equal to @code{INT_MAX}
|
|
(@pxref{Range of Type}), but it may be much smaller on other systems.
|
|
|
|
The pthreads library implements POSIX 1003.1b semaphores. These should
|
|
not be confused with System V semaphores (@code{ipc}, @code{semctl} and
|
|
@code{semop}).
|
|
@c !!! SysV IPC is not doc'd at all in our manual
|
|
|
|
All the semaphore functions and macros are defined in @file{semaphore.h}.
|
|
|
|
@comment semaphore.h
|
|
@comment POSIX
|
|
@deftypefun int sem_init (sem_t *@var{sem}, int @var{pshared}, unsigned int @var{value})
|
|
@code{sem_init} initializes the semaphore object pointed to by
|
|
@var{sem}. The count associated with the semaphore is set initially to
|
|
@var{value}. The @var{pshared} argument indicates whether the semaphore
|
|
is local to the current process (@var{pshared} is zero) or is to be
|
|
shared between several processes (@var{pshared} is not zero).
|
|
|
|
On success @code{sem_init} returns 0. On failure it returns -1 and sets
|
|
@var{errno} to one of the following values:
|
|
|
|
@table @code
|
|
@item EINVAL
|
|
@var{value} exceeds the maximal counter value @code{SEM_VALUE_MAX}
|
|
|
|
@item ENOSYS
|
|
@var{pshared} is not zero. LinuxThreads currently does not support
|
|
process-shared semaphores. (This will eventually change.)
|
|
@end table
|
|
@end deftypefun
|
|
|
|
@comment semaphore.h
|
|
@comment POSIX
|
|
@deftypefun int sem_destroy (sem_t * @var{sem})
|
|
@code{sem_destroy} destroys a semaphore object, freeing the resources it
|
|
might hold. If any threads are waiting on the semaphore when
|
|
@code{sem_destroy} is called, it fails and sets @var{errno} to
|
|
@code{EBUSY}.
|
|
|
|
In the LinuxThreads implementation, no resources are associated with
|
|
semaphore objects, thus @code{sem_destroy} actually does nothing except
|
|
checking that no thread is waiting on the semaphore. This will change
|
|
when process-shared semaphores are implemented.
|
|
@end deftypefun
|
|
|
|
@comment semaphore.h
|
|
@comment POSIX
|
|
@deftypefun int sem_wait (sem_t * @var{sem})
|
|
@code{sem_wait} suspends the calling thread until the semaphore pointed
|
|
to by @var{sem} has non-zero count. It then atomically decreases the
|
|
semaphore count.
|
|
|
|
@code{sem_wait} is a cancellation point. It always returns 0.
|
|
@end deftypefun
|
|
|
|
@comment semaphore.h
|
|
@comment POSIX
|
|
@deftypefun int sem_trywait (sem_t * @var{sem})
|
|
@code{sem_trywait} is a non-blocking variant of @code{sem_wait}. If the
|
|
semaphore pointed to by @var{sem} has non-zero count, the count is
|
|
atomically decreased and @code{sem_trywait} immediately returns 0. If
|
|
the semaphore count is zero, @code{sem_trywait} immediately returns -1
|
|
and sets errno to @code{EAGAIN}.
|
|
@end deftypefun
|
|
|
|
@comment semaphore.h
|
|
@comment POSIX
|
|
@deftypefun int sem_post (sem_t * @var{sem})
|
|
@code{sem_post} atomically increases the count of the semaphore pointed to
|
|
by @var{sem}. This function never blocks.
|
|
|
|
@c !!! This para appears not to agree with the code.
|
|
On processors supporting atomic compare-and-swap (Intel 486, Pentium and
|
|
later, Alpha, PowerPC, MIPS II, Motorola 68k, Ultrasparc), the
|
|
@code{sem_post} function is can safely be called from signal handlers.
|
|
This is the only thread synchronization function provided by POSIX
|
|
threads that is async-signal safe. On the Intel 386 and earlier Sparc
|
|
chips, the current LinuxThreads implementation of @code{sem_post} is not
|
|
async-signal safe, because the hardware does not support the required
|
|
atomic operations.
|
|
|
|
@code{sem_post} always succeeds and returns 0, unless the semaphore
|
|
count would exceed @code{SEM_VALUE_MAX} after being incremented. In
|
|
that case @code{sem_post} returns -1 and sets @var{errno} to
|
|
@code{EINVAL}. The semaphore count is left unchanged.
|
|
@end deftypefun
|
|
|
|
@comment semaphore.h
|
|
@comment POSIX
|
|
@deftypefun int sem_getvalue (sem_t * @var{sem}, int * @var{sval})
|
|
@code{sem_getvalue} stores in the location pointed to by @var{sval} the
|
|
current count of the semaphore @var{sem}. It always returns 0.
|
|
@end deftypefun
|
|
|
|
@node Thread-Specific Data
|
|
@section Thread-Specific Data
|
|
|
|
Programs often need global or static variables that have different
|
|
values in different threads. Since threads share one memory space, this
|
|
cannot be achieved with regular variables. Thread-specific data is the
|
|
POSIX threads answer to this need.
|
|
|
|
Each thread possesses a private memory block, the thread-specific data
|
|
area, or TSD area for short. This area is indexed by TSD keys. The TSD
|
|
area associates values of type @code{void *} to TSD keys. TSD keys are
|
|
common to all threads, but the value associated with a given TSD key can
|
|
be different in each thread.
|
|
|
|
For concreteness, the TSD areas can be viewed as arrays of @code{void *}
|
|
pointers, TSD keys as integer indices into these arrays, and the value
|
|
of a TSD key as the value of the corresponding array element in the
|
|
calling thread.
|
|
|
|
When a thread is created, its TSD area initially associates @code{NULL}
|
|
with all keys.
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_key_create (pthread_key_t *@var{key}, void (*destr_function) (void *))
|
|
@code{pthread_key_create} allocates a new TSD key. The key is stored in
|
|
the location pointed to by @var{key}. There is a limit of
|
|
@code{PTHREAD_KEYS_MAX} on the number of keys allocated at a given
|
|
time. The value initially associated with the returned key is
|
|
@code{NULL} in all currently executing threads.
|
|
|
|
The @var{destr_function} argument, if not @code{NULL}, specifies a
|
|
destructor function associated with the key. When a thread terminates
|
|
via @code{pthread_exit} or by cancellation, @var{destr_function} is
|
|
called on the value associated with the key in that thread. The
|
|
@var{destr_function} is not called if a key is deleted with
|
|
@code{pthread_key_delete} or a value is changed with
|
|
@code{pthread_setspecific}. The order in which destructor functions are
|
|
called at thread termination time is unspecified.
|
|
|
|
Before the destructor function is called, the @code{NULL} value is
|
|
associated with the key in the current thread. A destructor function
|
|
might, however, re-associate non-@code{NULL} values to that key or some
|
|
other key. To deal with this, if after all the destructors have been
|
|
called for all non-@code{NULL} values, there are still some
|
|
non-@code{NULL} values with associated destructors, then the process is
|
|
repeated. The LinuxThreads implementation stops the process after
|
|
@code{PTHREAD_DESTRUCTOR_ITERATIONS} iterations, even if some
|
|
non-@code{NULL} values with associated descriptors remain. Other
|
|
implementations may loop indefinitely.
|
|
|
|
@code{pthread_key_create} returns 0 unless @code{PTHREAD_KEYS_MAX} keys
|
|
have already been allocated, in which case it fails and returns
|
|
@code{EAGAIN}.
|
|
@end deftypefun
|
|
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_key_delete (pthread_key_t @var{key})
|
|
@code{pthread_key_delete} deallocates a TSD key. It does not check
|
|
whether non-@code{NULL} values are associated with that key in the
|
|
currently executing threads, nor call the destructor function associated
|
|
with the key.
|
|
|
|
If there is no such key @var{key}, it returns @code{EINVAL}. Otherwise
|
|
it returns 0.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_setspecific (pthread_key_t @var{key}, const void *@var{pointer})
|
|
@code{pthread_setspecific} changes the value associated with @var{key}
|
|
in the calling thread, storing the given @var{pointer} instead.
|
|
|
|
If there is no such key @var{key}, it returns @code{EINVAL}. Otherwise
|
|
it returns 0.
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun {void *} pthread_getspecific (pthread_key_t @var{key})
|
|
@code{pthread_getspecific} returns the value currently associated with
|
|
@var{key} in the calling thread.
|
|
|
|
If there is no such key @var{key}, it returns @code{NULL}.
|
|
@end deftypefun
|
|
|
|
The following code fragment allocates a thread-specific array of 100
|
|
characters, with automatic reclaimation at thread exit:
|
|
|
|
@smallexample
|
|
/* Key for the thread-specific buffer */
|
|
static pthread_key_t buffer_key;
|
|
|
|
/* Once-only initialisation of the key */
|
|
static pthread_once_t buffer_key_once = PTHREAD_ONCE_INIT;
|
|
|
|
/* Allocate the thread-specific buffer */
|
|
void buffer_alloc(void)
|
|
@{
|
|
pthread_once(&buffer_key_once, buffer_key_alloc);
|
|
pthread_setspecific(buffer_key, malloc(100));
|
|
@}
|
|
|
|
/* Return the thread-specific buffer */
|
|
char * get_buffer(void)
|
|
@{
|
|
return (char *) pthread_getspecific(buffer_key);
|
|
@}
|
|
|
|
/* Allocate the key */
|
|
static void buffer_key_alloc()
|
|
@{
|
|
pthread_key_create(&buffer_key, buffer_destroy);
|
|
@}
|
|
|
|
/* Free the thread-specific buffer */
|
|
static void buffer_destroy(void * buf)
|
|
@{
|
|
free(buf);
|
|
@}
|
|
@end smallexample
|
|
|
|
@node Threads and Signal Handling
|
|
@section Threads and Signal Handling
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_sigmask (int @var{how}, const sigset_t *@var{newmask}, sigset_t *@var{oldmask})
|
|
@code{pthread_sigmask} changes the signal mask for the calling thread as
|
|
described by the @var{how} and @var{newmask} arguments. If @var{oldmask}
|
|
is not @code{NULL}, the previous signal mask is stored in the location
|
|
pointed to by @var{oldmask}.
|
|
|
|
The meaning of the @var{how} and @var{newmask} arguments is the same as
|
|
for @code{sigprocmask}. If @var{how} is @code{SIG_SETMASK}, the signal
|
|
mask is set to @var{newmask}. If @var{how} is @code{SIG_BLOCK}, the
|
|
signals specified to @var{newmask} are added to the current signal mask.
|
|
If @var{how} is @code{SIG_UNBLOCK}, the signals specified to
|
|
@var{newmask} are removed from the current signal mask.
|
|
|
|
Recall that signal masks are set on a per-thread basis, but signal
|
|
actions and signal handlers, as set with @code{sigaction}, are shared
|
|
between all threads.
|
|
|
|
The @code{pthread_sigmask} function returns 0 on success, and one of the
|
|
following error codes on error:
|
|
@table @code
|
|
@item EINVAL
|
|
@var{how} is not one of @code{SIG_SETMASK}, @code{SIG_BLOCK}, or @code{SIG_UNBLOCK}
|
|
|
|
@item EFAULT
|
|
@var{newmask} or @var{oldmask} point to invalid addresses
|
|
@end table
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int pthread_kill (pthread_t @var{thread}, int @var{signo})
|
|
@code{pthread_kill} sends signal number @var{signo} to the thread
|
|
@var{thread}. The signal is delivered and handled as described in
|
|
@ref{Signal Handling}.
|
|
|
|
@code{pthread_kill} returns 0 on success, one of the following error codes
|
|
on error:
|
|
@table @code
|
|
@item EINVAL
|
|
@var{signo} is not a valid signal number
|
|
|
|
@item ESRCH
|
|
The thread @var{thread} does not exist (e.g. it has already terminated)
|
|
@end table
|
|
@end deftypefun
|
|
|
|
@comment pthread.h
|
|
@comment POSIX
|
|
@deftypefun int sigwait (const sigset_t *@var{set}, int *@var{sig})
|
|
@code{sigwait} suspends the calling thread until one of the signals in
|
|
@var{set} is delivered to the calling thread. It then stores the number
|
|
of the signal received in the location pointed to by @var{sig} and
|
|
returns. The signals in @var{set} must be blocked and not ignored on
|
|
entrance to @code{sigwait}. If the delivered signal has a signal handler
|
|
function attached, that function is @emph{not} called.
|
|
|
|
@code{sigwait} is a cancellation point. It always returns 0.
|
|
@end deftypefun
|
|
|
|
For @code{sigwait} to work reliably, the signals being waited for must be
|
|
blocked in all threads, not only in the calling thread, since
|
|
otherwise the POSIX semantics for signal delivery do not guarantee
|
|
that it's the thread doing the @code{sigwait} that will receive the signal.
|
|
The best way to achieve this is block those signals before any threads
|
|
are created, and never unblock them in the program other than by
|
|
calling @code{sigwait}.
|
|
|
|
Signal handling in LinuxThreads departs significantly from the POSIX
|
|
standard. According to the standard, ``asynchronous'' (external) signals
|
|
are addressed to the whole process (the collection of all threads),
|
|
which then delivers them to one particular thread. The thread that
|
|
actually receives the signal is any thread that does not currently block
|
|
the signal.
|
|
|
|
In LinuxThreads, each thread is actually a kernel process with its own
|
|
PID, so external signals are always directed to one particular thread.
|
|
If, for instance, another thread is blocked in @code{sigwait} on that
|
|
signal, it will not be restarted.
|
|
|
|
The LinuxThreads implementation of @code{sigwait} installs dummy signal
|
|
handlers for the signals in @var{set} for the duration of the
|
|
wait. Since signal handlers are shared between all threads, other
|
|
threads must not attach their own signal handlers to these signals, or
|
|
alternatively they should all block these signals (which is recommended
|
|
anyway).
|
|
|
|
@node Threads and Fork
|
|
@section Threads and Fork
|
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It's not intuitively obvious what should happen when a multi-threaded POSIX
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process calls @code{fork}. Not only are the semantics tricky, but you may
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need to write code that does the right thing at fork time even if that code
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doesn't use the @code{fork} function. Moreover, you need to be aware of
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interaction between @code{fork} and some library features like
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@code{pthread_once} and stdio streams.
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When @code{fork} is called by one of the threads of a process, it creates a new
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process which is copy of the calling process. Effectively, in addition to
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copying certain system objects, the function takes a snapshot of the memory
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areas of the parent process, and creates identical areas in the child.
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To make matters more complicated, with threads it's possible for two or more
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threads to concurrently call fork to create two or more child processes.
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The child process has a copy of the address space of the parent, but it does
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not inherit any of its threads. Execution of the child process is carried out
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by a new thread which returns from @code{fork} function with a return value of
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zero; it is the only thread in the child process. Because threads are not
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inherited across fork, issues arise. At the time of the call to @code{fork},
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threads in the parent process other than the one calling @code{fork} may have
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been executing critical regions of code. As a result, the child process may
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get a copy of objects that are not in a well-defined state. This potential
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problem affects all components of the program.
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Any program component which will continue being used in a child process must
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correctly handle its state during @code{fork}. For this purpose, the POSIX
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interface provides the special function @code{pthread_atfork} for installing
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pointers to handler functions which are called from within @code{fork}.
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_atfork (void (*@var{prepare})(void), void (*@var{parent})(void), void (*@var{child})(void))
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@code{pthread_atfork} registers handler functions to be called just
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before and just after a new process is created with @code{fork}. The
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@var{prepare} handler will be called from the parent process, just
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before the new process is created. The @var{parent} handler will be
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called from the parent process, just before @code{fork} returns. The
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@var{child} handler will be called from the child process, just before
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@code{fork} returns.
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@code{pthread_atfork} returns 0 on success and a non-zero error code on
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error.
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One or more of the three handlers @var{prepare}, @var{parent} and
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@var{child} can be given as @code{NULL}, meaning that no handler needs
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to be called at the corresponding point.
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@code{pthread_atfork} can be called several times to install several
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sets of handlers. At @code{fork} time, the @var{prepare} handlers are
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called in LIFO order (last added with @code{pthread_atfork}, first
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called before @code{fork}), while the @var{parent} and @var{child}
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handlers are called in FIFO order (first added, first called).
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If there is insufficient memory available to register the handlers,
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@code{pthread_atfork} fails and returns @code{ENOMEM}. Otherwise it
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returns 0.
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The functions @code{fork} and @code{pthread_atfork} must not be regarded as
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reentrant from the context of the handlers. That is to say, if a
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@code{pthread_atfork} handler invoked from within @code{fork} calls
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@code{pthread_atfork} or @code{fork}, the behavior is undefined.
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Registering a triplet of handlers is an atomic operation with respect to fork.
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If new handlers are registered at about the same time as a fork occurs, either
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all three handlers will be called, or none of them will be called.
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The handlers are inherited by the child process, and there is no
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way to remove them, short of using @code{exec} to load a new
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pocess image.
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@end deftypefun
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To understand the purpose of @code{pthread_atfork}, recall that
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@code{fork} duplicates the whole memory space, including mutexes in
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their current locking state, but only the calling thread: other threads
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are not running in the child process. The mutexes are not usable after
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the @code{fork} and must be initialized with @code{pthread_mutex_init}
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in the child process. This is a limitation of the current
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implementation and might or might not be present in future versions.
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To avoid this, install handlers with @code{pthread_atfork} as follows: have the
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@var{prepare} handler lock the mutexes (in locking order), and the
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@var{parent} handler unlock the mutexes. The @var{child} handler should reset
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the mutexes using @code{pthread_mutex_init}, as well as any other
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synchronization objects such as condition variables.
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Locking the global mutexes before the fork ensures that all other threads are
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locked out of the critical regions of code protected by those mutexes. Thus
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when @code{fork} takes a snapshot of the parent's address space, that snapshot
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will copy valid, stable data. Resetting the synchronization objects in the
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child process will ensure they are properly cleansed of any artifacts from the
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threading subsystem of the parent process. For example, a mutex may inherit
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a wait queue of threads waiting for the lock; this wait queue makes no sense
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in the child process. Initializing the mutex takes care of this.
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@node Streams and Fork
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@section Streams and Fork
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The GNU standard I/O library has an internal mutex which guards the internal
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linked list of all standard C FILE objects. This mutex is properly taken care
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of during @code{fork} so that the child receives an intact copy of the list.
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This allows the @code{fopen} function, and related stream-creating functions,
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to work correctly in the child process, since these functions need to insert
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into the list.
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However, the individual stream locks are not completely taken care of. Thus
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unless the multithreaded application takes special precautions in its use of
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@code{fork}, the child process might not be able to safely use the streams that
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it inherited from the parent. In general, for any given open stream in the
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parent that is to be used by the child process, the application must ensure
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that that stream is not in use by another thread when @code{fork} is called.
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Otherwise an inconsistent copy of the stream object be produced. An easy way to
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ensure this is to use @code{flockfile} to lock the stream prior to calling
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@code{fork} and then unlock it with @code{funlockfile} inside the parent
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process, provided that the parent's threads properly honor these locks.
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Nothing special needs to be done in the child process, since the library
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internally resets all stream locks.
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Note that the stream locks are not shared between the parent and child.
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For example, even if you ensure that, say, the stream @code{stdout} is properly
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treated and can be safely used in the child, the stream locks do not provide
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an exclusion mechanism between the parent and child. If both processes write
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to @code{stdout}, strangely interleaved output may result regardless of
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the explicit use of @code{flockfile} or implicit locks.
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Also note that these provisions are a GNU extension; other systems might not
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provide any way for streams to be used in the child of a multithreaded process.
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POSIX requires that such a child process confines itself to calling only
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asynchronous safe functions, which excludes much of the library, including
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standard I/O.
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@node Miscellaneous Thread Functions
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@section Miscellaneous Thread Functions
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@comment pthread.h
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@comment POSIX
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@deftypefun {pthread_t} pthread_self (@var{void})
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@code{pthread_self} returns the thread identifier for the calling thread.
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_equal (pthread_t thread1, pthread_t thread2)
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@code{pthread_equal} determines if two thread identifiers refer to the same
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thread.
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A non-zero value is returned if @var{thread1} and @var{thread2} refer to
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the same thread. Otherwise, 0 is returned.
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_detach (pthread_t @var{th})
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@code{pthread_detach} puts the thread @var{th} in the detached
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state. This guarantees that the memory resources consumed by @var{th}
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will be freed immediately when @var{th} terminates. However, this
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prevents other threads from synchronizing on the termination of @var{th}
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using @code{pthread_join}.
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A thread can be created initially in the detached state, using the
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@code{detachstate} attribute to @code{pthread_create}. In contrast,
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@code{pthread_detach} applies to threads created in the joinable state,
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and which need to be put in the detached state later.
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After @code{pthread_detach} completes, subsequent attempts to perform
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@code{pthread_join} on @var{th} will fail. If another thread is already
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joining the thread @var{th} at the time @code{pthread_detach} is called,
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@code{pthread_detach} does nothing and leaves @var{th} in the joinable
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state.
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On success, 0 is returned. On error, one of the following codes is
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returned:
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@table @code
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@item ESRCH
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No thread could be found corresponding to that specified by @var{th}
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@item EINVAL
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The thread @var{th} is already in the detached state
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@end table
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@end deftypefun
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@comment pthread.h
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@comment GNU
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@deftypefun void pthread_kill_other_threads_np (@var{void})
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@code{pthread_kill_other_threads_np} is a non-portable LinuxThreads extension.
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It causes all threads in the program to terminate immediately, except
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the calling thread which proceeds normally. It is intended to be
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called just before a thread calls one of the @code{exec} functions,
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e.g. @code{execve}.
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Termination of the other threads is not performed through
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@code{pthread_cancel} and completely bypasses the cancellation
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mechanism. Hence, the current settings for cancellation state and
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cancellation type are ignored, and the cleanup handlers are not
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executed in the terminated threads.
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According to POSIX 1003.1c, a successful @code{exec*} in one of the
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threads should automatically terminate all other threads in the program.
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This behavior is not yet implemented in LinuxThreads. Calling
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@code{pthread_kill_other_threads_np} before @code{exec*} achieves much
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of the same behavior, except that if @code{exec*} ultimately fails, then
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all other threads are already killed.
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_once (pthread_once_t *once_@var{control}, void (*@var{init_routine}) (void))
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The purpose of @code{pthread_once} is to ensure that a piece of
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initialization code is executed at most once. The @var{once_control}
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argument points to a static or extern variable statically initialized
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to @code{PTHREAD_ONCE_INIT}.
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The first time @code{pthread_once} is called with a given
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@var{once_control} argument, it calls @var{init_routine} with no
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argument and changes the value of the @var{once_control} variable to
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record that initialization has been performed. Subsequent calls to
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@code{pthread_once} with the same @code{once_control} argument do
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nothing.
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If a thread is cancelled while executing @var{init_routine}
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the state of the @var{once_control} variable is reset so that
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a future call to @code{pthread_once} will call the routine again.
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If the process forks while one or more threads are executing
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@code{pthread_once} initialization routines, the states of their respective
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@var{once_control} variables will appear to be reset in the child process so
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that if the child calls @code{pthread_once}, the routines will be executed.
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@code{pthread_once} always returns 0.
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_setschedparam (pthread_t target_@var{thread}, int @var{policy}, const struct sched_param *@var{param})
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@code{pthread_setschedparam} sets the scheduling parameters for the
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thread @var{target_thread} as indicated by @var{policy} and
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@var{param}. @var{policy} can be either @code{SCHED_OTHER} (regular,
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non-realtime scheduling), @code{SCHED_RR} (realtime, round-robin) or
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@code{SCHED_FIFO} (realtime, first-in first-out). @var{param} specifies
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the scheduling priority for the two realtime policies. See
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@code{sched_setpolicy} for more information on scheduling policies.
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The realtime scheduling policies @code{SCHED_RR} and @code{SCHED_FIFO}
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are available only to processes with superuser privileges.
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On success, @code{pthread_setschedparam} returns 0. On error it returns
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one of the following codes:
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@table @code
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@item EINVAL
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@var{policy} is not one of @code{SCHED_OTHER}, @code{SCHED_RR},
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@code{SCHED_FIFO}, or the priority value specified by @var{param} is not
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valid for the specified policy
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@item EPERM
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Realtime scheduling was requested but the calling process does not have
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sufficient privileges.
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@item ESRCH
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The @var{target_thread} is invalid or has already terminated
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@item EFAULT
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@var{param} points outside the process memory space
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@end table
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_getschedparam (pthread_t target_@var{thread}, int *@var{policy}, struct sched_param *@var{param})
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@code{pthread_getschedparam} retrieves the scheduling policy and
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scheduling parameters for the thread @var{target_thread} and stores them
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in the locations pointed to by @var{policy} and @var{param},
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respectively.
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@code{pthread_getschedparam} returns 0 on success, or one of the
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following error codes on failure:
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@table @code
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@item ESRCH
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The @var{target_thread} is invalid or has already terminated.
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@item EFAULT
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@var{policy} or @var{param} point outside the process memory space.
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@end table
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_setconcurrency (int @var{level})
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@code{pthread_setconcurrency} is unused in LinuxThreads due to the lack
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of a mapping of user threads to kernel threads. It exists for source
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compatibility. It does store the value @var{level} so that it can be
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returned by a subsequent call to @code{pthread_getconcurrency}. It takes
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no other action however.
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@end deftypefun
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@comment pthread.h
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@comment POSIX
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@deftypefun int pthread_getconcurrency ()
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@code{pthread_getconcurrency} is unused in LinuxThreads due to the lack
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of a mapping of user threads to kernel threads. It exists for source
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compatibility. However, it will return the value that was set by the
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last call to @code{pthread_setconcurrency}.
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@end deftypefun
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