ap/libc/glibc/glibc-2.23/nptl/pthread_once.c - T106_DC - Gitiles

 /* Copyright (C) 2003-2016 Free Software Foundation, Inc.
    This file is part of the GNU C Library.
    Contributed by Jakub Jelinek <jakub@redhat.com>, 2003.

    The GNU C Library is free software; you can redistribute it and/or
    modify it under the terms of the GNU Lesser General Public
    License as published by the Free Software Foundation; either
    version 2.1 of the License, or (at your option) any later version.

    The GNU C Library is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.	 See the GNU
    Lesser General Public License for more details.

    You should have received a copy of the GNU Lesser General Public
    License along with the GNU C Library; if not, see
    <http://www.gnu.org/licenses/>.  */

 #include "pthreadP.h"
 #include <futex-internal.h>
 #include <atomic.h>


 unsigned long int __fork_generation attribute_hidden;


 static void
 clear_once_control (void *arg)
 {
   pthread_once_t *once_control = (pthread_once_t *) arg;

   /* Reset to the uninitialized state here.  We don't need a stronger memory
      order because we do not need to make any other of our writes visible to
      other threads that see this value: This function will be called if we
      get interrupted (see __pthread_once), so all we need to relay to other
      threads is the state being reset again.  */
   atomic_store_relaxed (once_control, 0);
   futex_wake ((unsigned int *) once_control, INT_MAX, FUTEX_PRIVATE);
 }


 /* This is similar to a lock implementation, but we distinguish between three
    states: not yet initialized (0), initialization in progress
    (__fork_generation | __PTHREAD_ONCE_INPROGRESS), and initialization
    finished (__PTHREAD_ONCE_DONE); __fork_generation does not use the bits
    that are used for __PTHREAD_ONCE_INPROGRESS and __PTHREAD_ONCE_DONE (which
    is what __PTHREAD_ONCE_FORK_GEN_INCR is used for).  If in the first state,
    threads will try to run the initialization by moving to the second state;
    the first thread to do so via a CAS on once_control runs init_routine,
    other threads block.
    When forking the process, some threads can be interrupted during the second
    state; they won't be present in the forked child, so we need to restart
    initialization in the child.  To distinguish an in-progress initialization
    from an interrupted initialization (in which case we need to reclaim the
    lock), we look at the fork generation that's part of the second state: We
    can reclaim iff it differs from the current fork generation.
    XXX: This algorithm has an ABA issue on the fork generation: If an
    initialization is interrupted, we then fork 2^30 times (30 bits of
    once_control are used for the fork generation), and try to initialize
    again, we can deadlock because we can't distinguish the in-progress and
    interrupted cases anymore.
    XXX: We split out this slow path because current compilers do not generate
    as efficient code when the fast path in __pthread_once below is not in a
    separate function.  */
 static int
 __attribute__ ((noinline))
 __pthread_once_slow (pthread_once_t *once_control, void (*init_routine) (void))
 {
   while (1)
     {
       int val, newval;

       /* We need acquire memory order for this load because if the value
          signals that initialization has finished, we need to see any
          data modifications done during initialization.  */
       val = atomic_load_acquire (once_control);
       do
 	{
 	  /* Check if the initialization has already been done.  */
 	  if (__glibc_likely ((val & __PTHREAD_ONCE_DONE) != 0))
 	    return 0;

 	  /* We try to set the state to in-progress and having the current
 	     fork generation.  We don't need atomic accesses for the fork
 	     generation because it's immutable in a particular process, and
 	     forked child processes start with a single thread that modified
 	     the generation.  */
 	  newval = __fork_generation | __PTHREAD_ONCE_INPROGRESS;
 	  /* We need acquire memory order here for the same reason as for the
 	     load from once_control above.  */
 	}
       while (__glibc_unlikely (!atomic_compare_exchange_weak_acquire (
 	  once_control, &val, newval)));

       /* Check if another thread already runs the initializer.	*/
       if ((val & __PTHREAD_ONCE_INPROGRESS) != 0)
 	{
 	  /* Check whether the initializer execution was interrupted by a
 	     fork.  We know that for both values, __PTHREAD_ONCE_INPROGRESS
 	     is set and __PTHREAD_ONCE_DONE is not.  */
 	  if (val == newval)
 	    {
 	      /* Same generation, some other thread was faster.  Wait and
 		 retry.  */
 	      futex_wait_simple ((unsigned int *) once_control,
 				 (unsigned int) newval, FUTEX_PRIVATE);
 	      continue;
 	    }
 	}

       /* This thread is the first here.  Do the initialization.
 	 Register a cleanup handler so that in case the thread gets
 	 interrupted the initialization can be restarted.  */
       pthread_cleanup_push (clear_once_control, once_control);

       init_routine ();

       pthread_cleanup_pop (0);


       /* Mark *once_control as having finished the initialization.  We need
          release memory order here because we need to synchronize with other
          threads that want to use the initialized data.  */
       atomic_store_release (once_control, __PTHREAD_ONCE_DONE);

       /* Wake up all other threads.  */
       futex_wake ((unsigned int *) once_control, INT_MAX, FUTEX_PRIVATE);
       break;
     }

   return 0;
 }

 int
 __pthread_once (pthread_once_t *once_control, void (*init_routine) (void))
 {
   /* Fast path.  See __pthread_once_slow.  */
   int val;
   val = atomic_load_acquire (once_control);
   if (__glibc_likely ((val & __PTHREAD_ONCE_DONE) != 0))
     return 0;
   else
     return __pthread_once_slow (once_control, init_routine);
 }
 weak_alias (__pthread_once, pthread_once)
 hidden_def (__pthread_once)
	/* Copyright (C) 2003-2016 Free Software Foundation, Inc.
	This file is part of the GNU C Library.
	Contributed by Jakub Jelinek <jakub@redhat.com>, 2003.

	The GNU C Library is free software; you can redistribute it and/or
	modify it under the terms of the GNU Lesser General Public
	License as published by the Free Software Foundation; either
	version 2.1 of the License, or (at your option) any later version.

	The GNU C Library is distributed in the hope that it will be useful,
	but WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	Lesser General Public License for more details.

	You should have received a copy of the GNU Lesser General Public
	License along with the GNU C Library; if not, see
	<http://www.gnu.org/licenses/>. */

	#include "pthreadP.h"
	#include <futex-internal.h>
	#include <atomic.h>


	unsigned long int __fork_generation attribute_hidden;


	static void
	clear_once_control (void *arg)
	{
	pthread_once_t once_control = (pthread_once_t ) arg;

	/* Reset to the uninitialized state here. We don't need a stronger memory
	order because we do not need to make any other of our writes visible to
	other threads that see this value: This function will be called if we
	get interrupted (see __pthread_once), so all we need to relay to other
	threads is the state being reset again. */
	atomic_store_relaxed (once_control, 0);
	futex_wake ((unsigned int *) once_control, INT_MAX, FUTEX_PRIVATE);
	}


	/* This is similar to a lock implementation, but we distinguish between three
	states: not yet initialized (0), initialization in progress
	(__fork_generation \| __PTHREAD_ONCE_INPROGRESS), and initialization
	finished (__PTHREAD_ONCE_DONE); __fork_generation does not use the bits
	that are used for __PTHREAD_ONCE_INPROGRESS and __PTHREAD_ONCE_DONE (which
	is what __PTHREAD_ONCE_FORK_GEN_INCR is used for). If in the first state,
	threads will try to run the initialization by moving to the second state;
	the first thread to do so via a CAS on once_control runs init_routine,
	other threads block.
	When forking the process, some threads can be interrupted during the second
	state; they won't be present in the forked child, so we need to restart
	initialization in the child. To distinguish an in-progress initialization
	from an interrupted initialization (in which case we need to reclaim the
	lock), we look at the fork generation that's part of the second state: We
	can reclaim iff it differs from the current fork generation.
	XXX: This algorithm has an ABA issue on the fork generation: If an
	initialization is interrupted, we then fork 2^30 times (30 bits of
	once_control are used for the fork generation), and try to initialize
	again, we can deadlock because we can't distinguish the in-progress and
	interrupted cases anymore.
	XXX: We split out this slow path because current compilers do not generate
	as efficient code when the fast path in __pthread_once below is not in a
	separate function. */
	static int
	__attribute__ ((noinline))
	__pthread_once_slow (pthread_once_t once_control, void (init_routine) (void))
	{
	while (1)
	{
	int val, newval;

	/* We need acquire memory order for this load because if the value
	signals that initialization has finished, we need to see any
	data modifications done during initialization. */
	val = atomic_load_acquire (once_control);
	do
	{
	/* Check if the initialization has already been done. */
	if (__glibc_likely ((val & __PTHREAD_ONCE_DONE) != 0))
	return 0;

	/* We try to set the state to in-progress and having the current
	fork generation. We don't need atomic accesses for the fork
	generation because it's immutable in a particular process, and
	forked child processes start with a single thread that modified
	the generation. */
	newval = __fork_generation \| __PTHREAD_ONCE_INPROGRESS;
	/* We need acquire memory order here for the same reason as for the
	load from once_control above. */
	}
	while (__glibc_unlikely (!atomic_compare_exchange_weak_acquire (
	once_control, &val, newval)));

	/* Check if another thread already runs the initializer. */
	if ((val & __PTHREAD_ONCE_INPROGRESS) != 0)
	{
	/* Check whether the initializer execution was interrupted by a
	fork. We know that for both values, __PTHREAD_ONCE_INPROGRESS
	is set and __PTHREAD_ONCE_DONE is not. */
	if (val == newval)
	{
	/* Same generation, some other thread was faster. Wait and
	retry. */
	futex_wait_simple ((unsigned int *) once_control,
	(unsigned int) newval, FUTEX_PRIVATE);
	continue;
	}
	}

	/* This thread is the first here. Do the initialization.
	Register a cleanup handler so that in case the thread gets
	interrupted the initialization can be restarted. */
	pthread_cleanup_push (clear_once_control, once_control);

	init_routine ();

	pthread_cleanup_pop (0);


	/* Mark *once_control as having finished the initialization. We need
	release memory order here because we need to synchronize with other
	threads that want to use the initialized data. */
	atomic_store_release (once_control, __PTHREAD_ONCE_DONE);

	/* Wake up all other threads. */
	futex_wake ((unsigned int *) once_control, INT_MAX, FUTEX_PRIVATE);
	break;
	}

	return 0;
	}

	int
	__pthread_once (pthread_once_t once_control, void (init_routine) (void))
	{
	/* Fast path. See __pthread_once_slow. */
	int val;
	val = atomic_load_acquire (once_control);
	if (__glibc_likely ((val & __PTHREAD_ONCE_DONE) != 0))
	return 0;
	else
	return __pthread_once_slow (once_control, init_routine);
	}
	weak_alias (__pthread_once, pthread_once)
	hidden_def (__pthread_once)