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PTHREAD_MUTEXATTR_DESTROY(3POSIX Programmer's ManPTHREAD_MUTEXATTR_DESTROY(3P)

PROLOG
       This  manual  page is part of the POSIX Programmer's Manual.  The Linux
       implementation of this interface may differ (consult the	 corresponding
       Linux  manual page for details of Linux behavior), or the interface may
       not be implemented on Linux.

NAME
       pthread_mutexattr_destroy, pthread_mutexattr_init —  destroy  and  ini‐
       tialize the mutex attributes object

SYNOPSIS
       #include <pthread.h>

       int pthread_mutexattr_destroy(pthread_mutexattr_t *attr);
       int pthread_mutexattr_init(pthread_mutexattr_t *attr);

DESCRIPTION
       The   pthread_mutexattr_destroy()   function   shall  destroy  a	 mutex
       attributes object; the object becomes,  in  effect,  uninitialized.  An
       implementation  may cause pthread_mutexattr_destroy() to set the object
       referenced by attr to an invalid value.

       A  destroyed  attr  attributes  object  can  be	 reinitialized	 using
       pthread_mutexattr_init();  the  results	of  otherwise  referencing the
       object after it has been destroyed are undefined.

       The  pthread_mutexattr_init()  function	shall	initialize   a	 mutex
       attributes object attr with the default value for all of the attributes
       defined by the implementation.

       Results are undefined if pthread_mutexattr_init() is called  specifying
       an already initialized attr attributes object.

       After a mutex attributes object has been used to initialize one or more
       mutexes,	 any  function	affecting  the	attributes  object  (including
       destruction) shall not affect any previously initialized mutexes.

       The  behavior  is undefined if the value specified by the attr argument
       to pthread_mutexattr_destroy() does not refer to an  initialized	 mutex
       attributes object.

RETURN VALUE
       Upon    successful    completion,    pthread_mutexattr_destroy()	   and
       pthread_mutexattr_init() shall return zero; otherwise, an error	number
       shall be returned to indicate the error.

ERRORS
       The pthread_mutexattr_init() function shall fail if:

       ENOMEM Insufficient  memory  exists  to initialize the mutex attributes
	      object.

       These functions shall not return an error code of [EINTR].

       The following sections are informative.

EXAMPLES
       None.

APPLICATION USAGE
       None.

RATIONALE
       If an implementation detects that the value specified by the attr argu‐
       ment  to	 pthread_mutexattr_destroy()  does not refer to an initialized
       mutex attributes object, it is recommended  that	 the  function	should
       fail and report an [EINVAL] error.

       See  pthread_attr_destroy()  for	 a  general explanation of attributes.
       Attributes objects allow	 implementations  to  experiment  with	useful
       extensions  and permit extension of this volume of POSIX.1‐2008 without
       changing the existing functions. Thus, they provide for future extensi‐
       bility  of  this	 volume	 of  POSIX.1‐2008 and reduce the temptation to
       standardize prematurely on semantics that are  not  yet	widely	imple‐
       mented or understood.

       Examples	 of  possible  additional mutex attributes that have been dis‐
       cussed are spin_only, limited_spin, no_spin,  recursive,	 and  metered.
       (To  explain  what  the latter attributes might mean: recursive mutexes
       would allow for multiple	 re-locking  by	 the  current  owner;  metered
       mutexes	would  transparently  keep records of queue length, wait time,
       and so on.) Since there is not yet wide agreement on the usefulness  of
       these  resulting	 from shared implementation and usage experience, they
       are not yet specified in this volume of POSIX.1‐2008. Mutex  attributes
       objects,	 however, make it possible to test out these concepts for pos‐
       sible standardization at a later time.

   Mutex Attributes and Performance
       Care has been taken to ensure that the  default	values	of  the	 mutex
       attributes  have	 been  defined	such that mutexes initialized with the
       defaults have simple enough semantics so that the locking and unlocking
       can  be	done  with  the equivalent of a test-and-set instruction (plus
       possibly a few other basic instructions).

       There is at least one implementation method that can be used to	reduce
       the cost of testing at lock-time if a mutex has non-default attributes.
       One such method that an implementation can employ (and this can be made
       fully  transparent  to  fully  conforming  POSIX	 applications)	is  to
       secretly pre-lock any  mutexes  that  are  initialized  to  non-default
       attributes. Any later attempt to lock such a mutex causes the implemen‐
       tation to branch to the ``slow path'' as if the mutex were unavailable;
       then,  on the slow path, the implementation can do the ``real work'' to
       lock a non-default mutex. The underlying unlock operation is more  com‐
       plicated	 since	the  implementation  never really wants to release the
       pre-lock on this kind of mutex. This illustrates that, depending on the
       hardware,  there	 may be certain optimizations that can be used so that
       whatever mutex attributes are considered ``most frequently  used''  can
       be processed most efficiently.

   Process Shared Memory and Synchronization
       The   existence	 of   memory  mapping  functions  in  this  volume  of
       POSIX.1‐2008 leads to the possibility that an application may  allocate
       the  synchronization  objects  from  this  section  in  memory  that is
       accessed by multiple processes (and therefore, by threads  of  multiple
       processes).

       In order to permit such usage, while at the same time keeping the usual
       case (that is, usage within a single  process)  efficient,  a  process-
       shared option has been defined.

       If  an implementation supports the _POSIX_THREAD_PROCESS_SHARED option,
       then the process-shared attribute can be used to indicate that  mutexes
       or  condition  variables	 may  be  accessed by threads of multiple pro‐
       cesses.

       The default setting of PTHREAD_PROCESS_PRIVATE has been chosen for  the
       process-shared attribute so that the most efficient forms of these syn‐
       chronization objects are created by default.

       Synchronization	 variables   that    are    initialized	   with	   the
       PTHREAD_PROCESS_PRIVATE	process-shared	attribute may only be operated
       on by threads in the process  that  initialized	them.  Synchronization
       variables that are initialized with the PTHREAD_PROCESS_SHARED process-
       shared attribute may be operated on by any thread in any	 process  that
       has  access  to it. In particular, these processes may exist beyond the
       lifetime of the initializing process. For example, the  following  code
       implements  a  simple  counting	semaphore in a mapped file that may be
       used by many processes.

	   /* sem.h */
	   struct semaphore {
	       pthread_mutex_t lock;
	       pthread_cond_t nonzero;
	       unsigned count;
	   };
	   typedef struct semaphore semaphore_t;

	   semaphore_t *semaphore_create(char *semaphore_name);
	   semaphore_t *semaphore_open(char *semaphore_name);
	   void semaphore_post(semaphore_t *semap);
	   void semaphore_wait(semaphore_t *semap);
	   void semaphore_close(semaphore_t *semap);

	   /* sem.c */
	   #include <sys/types.h>
	   #include <sys/stat.h>
	   #include <sys/mman.h>
	   #include <fcntl.h>
	   #include <pthread.h>
	   #include "sem.h"

	   semaphore_t *
	   semaphore_create(char *semaphore_name)
	   {
	   int fd;
	       semaphore_t *semap;
	       pthread_mutexattr_t psharedm;
	       pthread_condattr_t psharedc;

	       fd = open(semaphore_name, O_RDWR | O_CREAT | O_EXCL, 0666);
	       if (fd < 0)
		   return (NULL);
	       (void) ftruncate(fd, sizeof(semaphore_t));
	       (void) pthread_mutexattr_init(&psharedm);
	       (void) pthread_mutexattr_setpshared(&psharedm,
		   PTHREAD_PROCESS_SHARED);
	       (void) pthread_condattr_init(&psharedc);
	       (void) pthread_condattr_setpshared(&psharedc,
		   PTHREAD_PROCESS_SHARED);
	       semap = (semaphore_t *) mmap(NULL, sizeof(semaphore_t),
		       PROT_READ | PROT_WRITE, MAP_SHARED,
		       fd, 0);
	       close (fd);
	       (void) pthread_mutex_init(&semap->lock, &psharedm);
	       (void) pthread_cond_init(&semap->nonzero, &psharedc);
	       semap->count = 0;
	       return (semap);
	   }

	   semaphore_t *
	   semaphore_open(char *semaphore_name)
	   {
	       int fd;
	       semaphore_t *semap;

	       fd = open(semaphore_name, O_RDWR, 0666);
	       if (fd < 0)
		   return (NULL);
	       semap = (semaphore_t *) mmap(NULL, sizeof(semaphore_t),
		       PROT_READ | PROT_WRITE, MAP_SHARED,
		       fd, 0);
	       close (fd);
	       return (semap);
	   }

	   void
	   semaphore_post(semaphore_t *semap)
	   {
	       pthread_mutex_lock(&semap->lock);
	       if (semap->count == 0)
		   pthread_cond_signal(&semapx->nonzero);
	       semap->count++;
	       pthread_mutex_unlock(&semap->lock);
	   }

	   void
	   semaphore_wait(semaphore_t *semap)
	   {
	       pthread_mutex_lock(&semap->lock);
	       while (semap->count == 0)
		   pthread_cond_wait(&semap->nonzero, &semap->lock);
	       semap->count--;
	       pthread_mutex_unlock(&semap->lock);
	   }

	   void
	   semaphore_close(semaphore_t *semap)
	   {
	       munmap((void *) semap, sizeof(semaphore_t));
	   }

       The following code is for three separate processes that	create,	 post,
       and  wait  on a semaphore in the file /tmp/semaphore.  Once the file is
       created, the post and wait programs increment and decrement the	count‐
       ing semaphore (waiting and waking as required) even though they did not
       initialize the semaphore.

	   /* create.c */
	   #include "pthread.h"
	   #include "sem.h"

	   int
	   main()
	   {
	       semaphore_t *semap;

	       semap = semaphore_create("/tmp/semaphore");
	       if (semap == NULL)
		   exit(1);
	       semaphore_close(semap);
	       return (0);
	   }

	   /* post */
	   #include "pthread.h"
	   #include "sem.h"

	   int
	   main()
	   {
	       semaphore_t *semap;

	       semap = semaphore_open("/tmp/semaphore");
	       if (semap == NULL)
		   exit(1);
	       semaphore_post(semap);
	       semaphore_close(semap);
	       return (0);
	   }

	   /* wait */
	   #include "pthread.h"
	   #include "sem.h"

	   int
	   main()
	   {
	       semaphore_t *semap;

	       semap = semaphore_open("/tmp/semaphore");
	       if (semap == NULL)
		   exit(1);
	       semaphore_wait(semap);
	       semaphore_close(semap);
	       return (0);
	   }

FUTURE DIRECTIONS
       None.

SEE ALSO
       pthread_cond_destroy(), pthread_create(), pthread_mutex_destroy()

       The Base Definitions volume of POSIX.1‐2008, <pthread.h>

COPYRIGHT
       Portions of this text are reprinted and reproduced in  electronic  form
       from IEEE Std 1003.1, 2013 Edition, Standard for Information Technology
       -- Portable Operating System Interface (POSIX),	The  Open  Group  Base
       Specifications Issue 7, Copyright (C) 2013 by the Institute of Electri‐
       cal and Electronics Engineers,  Inc  and	 The  Open  Group.   (This  is
       POSIX.1-2008  with  the	2013  Technical Corrigendum 1 applied.) In the
       event of any discrepancy between this version and the original IEEE and
       The  Open Group Standard, the original IEEE and The Open Group Standard
       is the referee document. The original Standard can be  obtained	online
       at http://www.unix.org/online.html .

       Any  typographical  or  formatting  errors that appear in this page are
       most likely to have been introduced during the conversion of the source
       files  to  man page format. To report such errors, see https://www.ker‐
       nel.org/doc/man-pages/reporting_bugs.html .

IEEE/The Open Group		     2013	 PTHREAD_MUTEXATTR_DESTROY(3P)
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