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NAME

       pthread_mutexattr_destroy,   pthread_mutexattr_init   -   destroy   and
       initialize 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.

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_destroy() function may fail if:

       EINVAL The value specified by attr is invalid.

       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

       See  pthread_attr_init()  for  a  general  explanation  of  attributes.
       Attributes  objects  allow  implementations  to  experiment with useful
       extensions and permit extension of this volume of  IEEE Std 1003.1-2001
       without  changing the existing functions. Thus, they provide for future
       extensibility of this volume of  IEEE Std 1003.1-2001  and  reduce  the
       temptation  to  standardize  prematurely  on semantics that are not yet
       widely implemented or understood.

       Examples  of  possible  additional  mutex  attributes  that  have  been
       discussed 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 IEEE Std 1003.1-2001.  Mutex
       attributes objects,  however,  make  it  possible  to  test  out  these
       concepts for possible 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
       implementation  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 complicated 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
       IEEE Std 1003.1-2001  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
       processes.

       The  default setting of PTHREAD_PROCESS_PRIVATE has been chosen for the
       process-shared attribute so that the  most  efficient  forms  of  these
       synchronization 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
       counting 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() ,
       pthread_mutexattr_destroy   ,   the   Base   Definitions   volume    of
       IEEE Std 1003.1-2001, <pthread.h>

COPYRIGHT

       Portions  of  this text are reprinted and reproduced in electronic form
       from IEEE Std 1003.1, 2003 Edition, Standard for Information Technology
       --  Portable  Operating  System  Interface (POSIX), The Open Group Base
       Specifications Issue 6, Copyright (C) 2001-2003  by  the  Institute  of
       Electrical  and  Electronics  Engineers, Inc and The Open Group. 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.opengroup.org/unix/online.html .