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359 lines
14 KiB
C
359 lines
14 KiB
C
/* sem_waitcommon -- wait on a semaphore, shared code.
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Copyright (C) 2003-2024 Free Software Foundation, Inc.
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This file is part of the GNU C Library.
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The GNU C Library is free software; you can redistribute it and/or
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modify it under the terms of the GNU Lesser General Public
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License as published by the Free Software Foundation; either
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version 2.1 of the License, or (at your option) any later version.
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The GNU C Library is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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Lesser General Public License for more details.
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You should have received a copy of the GNU Lesser General Public
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License along with the GNU C Library; if not, see
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<https://www.gnu.org/licenses/>. */
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#include <kernel-features.h>
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#include <errno.h>
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#include <sysdep.h>
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#include <futex-internal.h>
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#include <internaltypes.h>
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#include <semaphore.h>
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#include <sys/time.h>
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#include <pthreadP.h>
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#include <shlib-compat.h>
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#include <atomic.h>
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/* The semaphore provides two main operations: sem_post adds a token to the
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semaphore; sem_wait grabs a token from the semaphore, potentially waiting
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until there is a token available. A sem_wait needs to synchronize with
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the sem_post that provided the token, so that whatever lead to the sem_post
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happens before the code after sem_wait.
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Conceptually, available tokens can simply be counted; let's call that the
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value of the semaphore. However, we also want to know whether there might
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be a sem_wait that is blocked on the value because it was zero (using a
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futex with the value being the futex variable); if there is no blocked
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sem_wait, sem_post does not need to execute a futex_wake call. Therefore,
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we also need to count the number of potentially blocked sem_wait calls
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(which we call nwaiters).
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What makes this tricky is that POSIX requires that a semaphore can be
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destroyed as soon as the last remaining sem_wait has returned, and no
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other sem_wait or sem_post calls are executing concurrently. However, the
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sem_post call whose token was consumed by the last sem_wait is considered
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to have finished once it provided the token to the sem_wait.
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Thus, sem_post must not access the semaphore struct anymore after it has
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made a token available; IOW, it needs to be able to atomically provide
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a token and check whether any blocked sem_wait calls might exist.
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This is straightforward to do if the architecture provides 64b atomics
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because we can just put both the value and nwaiters into one variable that
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we access atomically: This is the data field, the value is in the
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least-significant 32 bits, and nwaiters in the other bits. When sem_post
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makes a value available, it can atomically check nwaiters.
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If we have only 32b atomics available, we cannot put both nwaiters and
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value into one 32b value because then we might have too few bits for both
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of those counters. Therefore, we need to use two distinct fields.
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To allow sem_post to atomically make a token available and check for
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blocked sem_wait calls, we use one bit in value to indicate whether
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nwaiters is nonzero. That allows sem_post to use basically the same
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algorithm as with 64b atomics, but requires sem_wait to update the bit; it
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can't do this atomically with another access to nwaiters, but it can compute
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a conservative value for the bit because it's benign if the bit is set
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even if nwaiters is zero (all we get is an unnecessary futex wake call by
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sem_post).
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Specifically, sem_wait will unset the bit speculatively if it believes that
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there is no other concurrently executing sem_wait. If it misspeculated,
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it will have to clean up by waking any other sem_wait call (i.e., what
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sem_post would do otherwise). This does not conflict with the destruction
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requirement because the semaphore must not be destructed while any sem_wait
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is still executing. */
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#if !__HAVE_64B_ATOMICS
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static void
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__sem_wait_32_finish (struct new_sem *sem);
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#endif
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static void
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__sem_wait_cleanup (void *arg)
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{
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struct new_sem *sem = (struct new_sem *) arg;
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#if __HAVE_64B_ATOMICS
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/* Stop being registered as a waiter. See below for MO. */
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atomic_fetch_add_relaxed (&sem->data, -((uint64_t) 1 << SEM_NWAITERS_SHIFT));
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#else
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__sem_wait_32_finish (sem);
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#endif
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}
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/* Wait until at least one token is available, possibly with a timeout.
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This is in a separate function in order to make sure gcc
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puts the call site into an exception region, and thus the
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cleanups get properly run. TODO still necessary? Other futex_wait
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users don't seem to need it. */
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static int
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__attribute__ ((noinline))
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do_futex_wait (struct new_sem *sem, clockid_t clockid,
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const struct __timespec64 *abstime)
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{
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int err;
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#if __HAVE_64B_ATOMICS
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err = __futex_abstimed_wait_cancelable64 (
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(unsigned int *) &sem->data + SEM_VALUE_OFFSET, 0,
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clockid, abstime,
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sem->private);
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#else
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err = __futex_abstimed_wait_cancelable64 (&sem->value, SEM_NWAITERS_MASK,
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clockid, abstime, sem->private);
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#endif
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return err;
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}
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/* Fast path: Try to grab a token without blocking. */
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static int
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__new_sem_wait_fast (struct new_sem *sem, int definitive_result)
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{
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/* We need acquire MO if we actually grab a token, so that this
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synchronizes with all token providers (i.e., the RMW operation we read
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from or all those before it in modification order; also see sem_post).
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We do not need to guarantee any ordering if we observed that there is
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no token (POSIX leaves it unspecified whether functions that fail
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synchronize memory); thus, relaxed MO is sufficient for the initial load
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and the failure path of the CAS. If the weak CAS fails and we need a
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definitive result, retry. */
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#if __HAVE_64B_ATOMICS
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uint64_t d = atomic_load_relaxed (&sem->data);
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do
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{
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if ((d & SEM_VALUE_MASK) == 0)
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break;
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if (atomic_compare_exchange_weak_acquire (&sem->data, &d, d - 1))
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return 0;
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}
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while (definitive_result);
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return -1;
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#else
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unsigned int v = atomic_load_relaxed (&sem->value);
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do
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{
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if ((v >> SEM_VALUE_SHIFT) == 0)
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break;
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if (atomic_compare_exchange_weak_acquire (&sem->value,
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&v, v - (1 << SEM_VALUE_SHIFT)))
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return 0;
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}
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while (definitive_result);
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return -1;
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#endif
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}
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/* Slow path that blocks. */
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static int
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__attribute__ ((noinline))
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__new_sem_wait_slow64 (struct new_sem *sem, clockid_t clockid,
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const struct __timespec64 *abstime)
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{
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int err = 0;
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#if __HAVE_64B_ATOMICS
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/* Add a waiter. Relaxed MO is sufficient because we can rely on the
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ordering provided by the RMW operations we use. */
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uint64_t d = atomic_fetch_add_relaxed (&sem->data,
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(uint64_t) 1 << SEM_NWAITERS_SHIFT);
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pthread_cleanup_push (__sem_wait_cleanup, sem);
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/* Wait for a token to be available. Retry until we can grab one. */
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for (;;)
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{
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/* If there is no token available, sleep until there is. */
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if ((d & SEM_VALUE_MASK) == 0)
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{
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err = do_futex_wait (sem, clockid, abstime);
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/* A futex return value of 0 or EAGAIN is due to a real or spurious
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wake-up, or due to a change in the number of tokens. We retry in
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these cases.
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If we timed out, forward this to the caller.
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EINTR is returned if we are interrupted by a signal; we
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forward this to the caller. (See futex_wait and related
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documentation. Before Linux 2.6.22, EINTR was also returned on
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spurious wake-ups; we only support more recent Linux versions,
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so do not need to consider this here.) */
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if (err == ETIMEDOUT || err == EINTR || err == EOVERFLOW)
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{
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__set_errno (err);
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err = -1;
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/* Stop being registered as a waiter. */
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atomic_fetch_add_relaxed (&sem->data,
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-((uint64_t) 1 << SEM_NWAITERS_SHIFT));
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break;
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}
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/* Relaxed MO is sufficient; see below. */
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d = atomic_load_relaxed (&sem->data);
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}
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else
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{
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/* Try to grab both a token and stop being a waiter. We need
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acquire MO so this synchronizes with all token providers (i.e.,
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the RMW operation we read from or all those before it in
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modification order; also see sem_post). On the failure path,
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relaxed MO is sufficient because we only eventually need the
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up-to-date value; the futex_wait or the CAS perform the real
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work. */
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if (atomic_compare_exchange_weak_acquire (&sem->data,
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&d, d - 1 - ((uint64_t) 1 << SEM_NWAITERS_SHIFT)))
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{
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err = 0;
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break;
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}
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}
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}
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pthread_cleanup_pop (0);
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#else
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/* The main difference to the 64b-atomics implementation is that we need to
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access value and nwaiters in separate steps, and that the nwaiters bit
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in the value can temporarily not be set even if nwaiters is nonzero.
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We work around incorrectly unsetting the nwaiters bit by letting sem_wait
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set the bit again and waking the number of waiters that could grab a
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token. There are two additional properties we need to ensure:
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(1) We make sure that whenever unsetting the bit, we see the increment of
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nwaiters by the other thread that set the bit. IOW, we will notice if
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we make a mistake.
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(2) When setting the nwaiters bit, we make sure that we see the unsetting
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of the bit by another waiter that happened before us. This avoids having
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to blindly set the bit whenever we need to block on it. We set/unset
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the bit while having incremented nwaiters (i.e., are a registered
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waiter), and the problematic case only happens when one waiter indeed
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followed another (i.e., nwaiters was never larger than 1); thus, this
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works similarly as with a critical section using nwaiters (see the MOs
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and related comments below).
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An alternative approach would be to unset the bit after decrementing
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nwaiters; however, that would result in needing Dekker-like
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synchronization and thus full memory barriers. We also would not be able
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to prevent misspeculation, so this alternative scheme does not seem
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beneficial. */
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unsigned int v;
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/* Add a waiter. We need acquire MO so this synchronizes with the release
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MO we use when decrementing nwaiters below; it ensures that if another
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waiter unset the bit before us, we see that and set it again. Also see
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property (2) above. */
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atomic_fetch_add_acquire (&sem->nwaiters, 1);
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pthread_cleanup_push (__sem_wait_cleanup, sem);
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/* Wait for a token to be available. Retry until we can grab one. */
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/* We do not need any ordering wrt. to this load's reads-from, so relaxed
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MO is sufficient. The acquire MO above ensures that in the problematic
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case, we do see the unsetting of the bit by another waiter. */
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v = atomic_load_relaxed (&sem->value);
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do
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{
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do
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{
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/* We are about to block, so make sure that the nwaiters bit is
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set. We need release MO on the CAS to ensure that when another
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waiter unsets the nwaiters bit, it will also observe that we
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incremented nwaiters in the meantime (also see the unsetting of
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the bit below). Relaxed MO on CAS failure is sufficient (see
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above). */
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do
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{
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if ((v & SEM_NWAITERS_MASK) != 0)
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break;
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}
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while (!atomic_compare_exchange_weak_release (&sem->value,
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&v, v | SEM_NWAITERS_MASK));
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/* If there is no token, wait. */
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if ((v >> SEM_VALUE_SHIFT) == 0)
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{
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/* See __HAVE_64B_ATOMICS variant. */
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err = do_futex_wait (sem, clockid, abstime);
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if (err == ETIMEDOUT || err == EINTR)
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{
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__set_errno (err);
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err = -1;
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goto error;
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}
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err = 0;
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/* We blocked, so there might be a token now. Relaxed MO is
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sufficient (see above). */
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v = atomic_load_relaxed (&sem->value);
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}
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}
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/* If there is no token, we must not try to grab one. */
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while ((v >> SEM_VALUE_SHIFT) == 0);
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}
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/* Try to grab a token. We need acquire MO so this synchronizes with
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all token providers (i.e., the RMW operation we read from or all those
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before it in modification order; also see sem_post). */
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while (!atomic_compare_exchange_weak_acquire (&sem->value,
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&v, v - (1 << SEM_VALUE_SHIFT)));
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error:
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pthread_cleanup_pop (0);
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__sem_wait_32_finish (sem);
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#endif
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return err;
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}
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/* Stop being a registered waiter (non-64b-atomics code only). */
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#if !__HAVE_64B_ATOMICS
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static void
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__sem_wait_32_finish (struct new_sem *sem)
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{
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/* The nwaiters bit is still set, try to unset it now if this seems
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necessary. We do this before decrementing nwaiters so that the unsetting
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is visible to other waiters entering after us. Relaxed MO is sufficient
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because we are just speculating here; a stronger MO would not prevent
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misspeculation. */
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unsigned int wguess = atomic_load_relaxed (&sem->nwaiters);
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if (wguess == 1)
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/* We might be the last waiter, so unset. This needs acquire MO so that
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it synchronizes with the release MO when setting the bit above; if we
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overwrite someone else that set the bit, we'll read in the following
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decrement of nwaiters at least from that release sequence, so we'll
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see if the other waiter is still active or if another writer entered
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in the meantime (i.e., using the check below). */
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atomic_fetch_and_acquire (&sem->value, ~SEM_NWAITERS_MASK);
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/* Now stop being a waiter, and see whether our guess was correct.
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This needs release MO so that it synchronizes with the acquire MO when
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a waiter increments nwaiters; this makes sure that newer writers see that
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we reset the waiters_present bit. */
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unsigned int wfinal = atomic_fetch_add_release (&sem->nwaiters, -1);
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if (wfinal > 1 && wguess == 1)
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{
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/* We guessed wrong, and so need to clean up after the mistake and
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unblock any waiters that could have not been woken. There is no
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additional ordering that we need to set up, so relaxed MO is
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sufficient. */
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unsigned int v = atomic_fetch_or_relaxed (&sem->value,
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SEM_NWAITERS_MASK);
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/* If there are available tokens, then wake as many waiters. If there
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aren't any, then there is no need to wake anyone because there is
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none to grab for another waiter. If tokens become available
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subsequently, then the respective sem_post calls will do the wake-up
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due to us having set the nwaiters bit again. */
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v >>= SEM_VALUE_SHIFT;
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if (v > 0)
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futex_wake (&sem->value, v, sem->private);
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}
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}
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#endif
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