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711 lines
31 KiB
C
711 lines
31 KiB
C
/* Copyright (C) 2003-2023 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 <endian.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 <pthread.h>
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#include <pthreadP.h>
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#include <sys/time.h>
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#include <atomic.h>
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#include <stdint.h>
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#include <stdbool.h>
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#include <shlib-compat.h>
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#include <stap-probe.h>
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#include <time.h>
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#include "pthread_cond_common.c"
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struct _condvar_cleanup_buffer
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{
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uint64_t wseq;
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pthread_cond_t *cond;
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pthread_mutex_t *mutex;
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int private;
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};
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/* Decrease the waiter reference count. */
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static void
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__condvar_confirm_wakeup (pthread_cond_t *cond, int private)
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{
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/* If destruction is pending (i.e., the wake-request flag is nonzero) and we
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are the last waiter (prior value of __wrefs was 1 << 3), then wake any
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threads waiting in pthread_cond_destroy. Release MO to synchronize with
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these threads. Don't bother clearing the wake-up request flag. */
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if ((atomic_fetch_add_release (&cond->__data.__wrefs, -8) >> 2) == 3)
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futex_wake (&cond->__data.__wrefs, INT_MAX, private);
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}
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/* Cancel waiting after having registered as a waiter previously. SEQ is our
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position and G is our group index.
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The goal of cancellation is to make our group smaller if that is still
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possible. If we are in a closed group, this is not possible anymore; in
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this case, we need to send a replacement signal for the one we effectively
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consumed because the signal should have gotten consumed by another waiter
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instead; we must not both cancel waiting and consume a signal.
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Must not be called while still holding a reference on the group.
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Returns true iff we consumed a signal.
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On some kind of timeouts, we may be able to pretend that a signal we
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effectively consumed happened before the timeout (i.e., similarly to first
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spinning on signals before actually checking whether the timeout has
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passed already). Doing this would allow us to skip sending a replacement
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signal, but this case might happen rarely because the end of the timeout
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must race with someone else sending a signal. Therefore, we don't bother
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trying to optimize this. */
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static void
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__condvar_cancel_waiting (pthread_cond_t *cond, uint64_t seq, unsigned int g,
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int private)
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{
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bool consumed_signal = false;
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/* No deadlock with group switching is possible here because we do
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not hold a reference on the group. */
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__condvar_acquire_lock (cond, private);
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uint64_t g1_start = __condvar_load_g1_start_relaxed (cond) >> 1;
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if (g1_start > seq)
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{
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/* Our group is closed, so someone provided enough signals for it.
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Thus, we effectively consumed a signal. */
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consumed_signal = true;
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}
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else
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{
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if (g1_start + __condvar_get_orig_size (cond) <= seq)
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{
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/* We are in the current G2 and thus cannot have consumed a signal.
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Reduce its effective size or handle overflow. Remember that in
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G2, unsigned int size is zero or a negative value. */
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if (cond->__data.__g_size[g] + __PTHREAD_COND_MAX_GROUP_SIZE > 0)
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{
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cond->__data.__g_size[g]--;
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}
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else
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{
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/* Cancellations would overflow the maximum group size. Just
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wake up everyone spuriously to create a clean state. This
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also means we do not consume a signal someone else sent. */
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__condvar_release_lock (cond, private);
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__pthread_cond_broadcast (cond);
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return;
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}
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}
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else
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{
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/* We are in current G1. If the group's size is zero, someone put
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a signal in the group that nobody else but us can consume. */
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if (cond->__data.__g_size[g] == 0)
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consumed_signal = true;
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else
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{
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/* Otherwise, we decrease the size of the group. This is
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equivalent to atomically putting in a signal just for us and
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consuming it right away. We do not consume a signal sent
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by someone else. We also cannot have consumed a futex
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wake-up because if we were cancelled or timed out in a futex
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call, the futex will wake another waiter. */
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cond->__data.__g_size[g]--;
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}
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}
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}
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__condvar_release_lock (cond, private);
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if (consumed_signal)
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{
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/* We effectively consumed a signal even though we didn't want to.
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Therefore, we need to send a replacement signal.
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If we would want to optimize this, we could do what
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pthread_cond_signal does right in the critical section above. */
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__pthread_cond_signal (cond);
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}
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}
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/* Wake up any signalers that might be waiting. */
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static void
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__condvar_dec_grefs (pthread_cond_t *cond, unsigned int g, int private)
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{
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/* Release MO to synchronize-with the acquire load in
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__condvar_quiesce_and_switch_g1. */
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if (atomic_fetch_add_release (cond->__data.__g_refs + g, -2) == 3)
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{
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/* Clear the wake-up request flag before waking up. We do not need more
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than relaxed MO and it doesn't matter if we apply this for an aliased
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group because we wake all futex waiters right after clearing the
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flag. */
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atomic_fetch_and_relaxed (cond->__data.__g_refs + g, ~(unsigned int) 1);
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futex_wake (cond->__data.__g_refs + g, INT_MAX, private);
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}
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}
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/* Clean-up for cancellation of waiters waiting for normal signals. We cancel
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our registration as a waiter, confirm we have woken up, and re-acquire the
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mutex. */
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static void
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__condvar_cleanup_waiting (void *arg)
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{
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struct _condvar_cleanup_buffer *cbuffer =
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(struct _condvar_cleanup_buffer *) arg;
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pthread_cond_t *cond = cbuffer->cond;
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unsigned g = cbuffer->wseq & 1;
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__condvar_dec_grefs (cond, g, cbuffer->private);
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__condvar_cancel_waiting (cond, cbuffer->wseq >> 1, g, cbuffer->private);
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/* FIXME With the current cancellation implementation, it is possible that
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a thread is cancelled after it has returned from a syscall. This could
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result in a cancelled waiter consuming a futex wake-up that is then
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causing another waiter in the same group to not wake up. To work around
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this issue until we have fixed cancellation, just add a futex wake-up
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conservatively. */
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futex_wake (cond->__data.__g_signals + g, 1, cbuffer->private);
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__condvar_confirm_wakeup (cond, cbuffer->private);
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/* XXX If locking the mutex fails, should we just stop execution? This
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might be better than silently ignoring the error. */
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__pthread_mutex_cond_lock (cbuffer->mutex);
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}
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/* This condvar implementation guarantees that all calls to signal and
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broadcast and all of the three virtually atomic parts of each call to wait
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(i.e., (1) releasing the mutex and blocking, (2) unblocking, and (3) re-
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acquiring the mutex) happen in some total order that is consistent with the
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happens-before relations in the calling program. However, this order does
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not necessarily result in additional happens-before relations being
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established (which aligns well with spurious wake-ups being allowed).
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All waiters acquire a certain position in a 64b waiter sequence (__wseq).
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This sequence determines which waiters are allowed to consume signals.
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A broadcast is equal to sending as many signals as are unblocked waiters.
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When a signal arrives, it samples the current value of __wseq with a
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relaxed-MO load (i.e., the position the next waiter would get). (This is
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sufficient because it is consistent with happens-before; the caller can
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enforce stronger ordering constraints by calling signal while holding the
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mutex.) Only waiters with a position less than the __wseq value observed
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by the signal are eligible to consume this signal.
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This would be straight-forward to implement if waiters would just spin but
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we need to let them block using futexes. Futexes give no guarantee of
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waking in FIFO order, so we cannot reliably wake eligible waiters if we
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just use a single futex. Also, futex words are 32b in size, but we need
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to distinguish more than 1<<32 states because we need to represent the
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order of wake-up (and thus which waiters are eligible to consume signals);
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blocking in a futex is not atomic with a waiter determining its position in
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the waiter sequence, so we need the futex word to reliably notify waiters
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that they should not attempt to block anymore because they have been
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already signaled in the meantime. While an ABA issue on a 32b value will
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be rare, ignoring it when we are aware of it is not the right thing to do
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either.
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Therefore, we use a 64b counter to represent the waiter sequence (on
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architectures which only support 32b atomics, we use a few bits less).
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To deal with the blocking using futexes, we maintain two groups of waiters:
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* Group G1 consists of waiters that are all eligible to consume signals;
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incoming signals will always signal waiters in this group until all
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waiters in G1 have been signaled.
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* Group G2 consists of waiters that arrive when a G1 is present and still
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contains waiters that have not been signaled. When all waiters in G1
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are signaled and a new signal arrives, the new signal will convert G2
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into the new G1 and create a new G2 for future waiters.
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We cannot allocate new memory because of process-shared condvars, so we
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have just two slots of groups that change their role between G1 and G2.
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Each has a separate futex word, a number of signals available for
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consumption, a size (number of waiters in the group that have not been
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signaled), and a reference count.
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The group reference count is used to maintain the number of waiters that
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are using the group's futex. Before a group can change its role, the
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reference count must show that no waiters are using the futex anymore; this
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prevents ABA issues on the futex word.
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To represent which intervals in the waiter sequence the groups cover (and
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thus also which group slot contains G1 or G2), we use a 64b counter to
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designate the start position of G1 (inclusive), and a single bit in the
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waiter sequence counter to represent which group slot currently contains
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G2. This allows us to switch group roles atomically wrt. waiters obtaining
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a position in the waiter sequence. The G1 start position allows waiters to
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figure out whether they are in a group that has already been completely
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signaled (i.e., if the current G1 starts at a later position that the
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waiter's position). Waiters cannot determine whether they are currently
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in G2 or G1 -- but they do not have too because all they are interested in
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is whether there are available signals, and they always start in G2 (whose
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group slot they know because of the bit in the waiter sequence. Signalers
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will simply fill the right group until it is completely signaled and can
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be closed (they do not switch group roles until they really have to to
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decrease the likelihood of having to wait for waiters still holding a
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reference on the now-closed G1).
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Signalers maintain the initial size of G1 to be able to determine where
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G2 starts (G2 is always open-ended until it becomes G1). They track the
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remaining size of a group; when waiters cancel waiting (due to PThreads
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cancellation or timeouts), they will decrease this remaining size as well.
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To implement condvar destruction requirements (i.e., that
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pthread_cond_destroy can be called as soon as all waiters have been
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signaled), waiters increment a reference count before starting to wait and
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decrement it after they stopped waiting but right before they acquire the
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mutex associated with the condvar.
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pthread_cond_t thus consists of the following (bits that are used for
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flags and are not part of the primary value of each field but necessary
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to make some things atomic or because there was no space for them
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elsewhere in the data structure):
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__wseq: Waiter sequence counter
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* LSB is index of current G2.
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* Waiters fetch-add while having acquire the mutex associated with the
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condvar. Signalers load it and fetch-xor it concurrently.
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__g1_start: Starting position of G1 (inclusive)
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* LSB is index of current G2.
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* Modified by signalers while having acquired the condvar-internal lock
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and observed concurrently by waiters.
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__g1_orig_size: Initial size of G1
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* The two least-significant bits represent the condvar-internal lock.
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* Only accessed while having acquired the condvar-internal lock.
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__wrefs: Waiter reference counter.
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* Bit 2 is true if waiters should run futex_wake when they remove the
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last reference. pthread_cond_destroy uses this as futex word.
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* Bit 1 is the clock ID (0 == CLOCK_REALTIME, 1 == CLOCK_MONOTONIC).
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* Bit 0 is true iff this is a process-shared condvar.
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* Simple reference count used by both waiters and pthread_cond_destroy.
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(If the format of __wrefs is changed, update nptl_lock_constants.pysym
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and the pretty printers.)
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For each of the two groups, we have:
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__g_refs: Futex waiter reference count.
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* LSB is true if waiters should run futex_wake when they remove the
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last reference.
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* Reference count used by waiters concurrently with signalers that have
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acquired the condvar-internal lock.
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__g_signals: The number of signals that can still be consumed.
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* Used as a futex word by waiters. Used concurrently by waiters and
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signalers.
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* LSB is true iff this group has been completely signaled (i.e., it is
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closed).
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__g_size: Waiters remaining in this group (i.e., which have not been
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signaled yet.
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* Accessed by signalers and waiters that cancel waiting (both do so only
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when having acquired the condvar-internal lock.
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* The size of G2 is always zero because it cannot be determined until
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the group becomes G1.
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* Although this is of unsigned type, we rely on using unsigned overflow
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rules to make this hold effectively negative values too (in
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particular, when waiters in G2 cancel waiting).
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A PTHREAD_COND_INITIALIZER condvar has all fields set to zero, which yields
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a condvar that has G2 starting at position 0 and a G1 that is closed.
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Because waiters do not claim ownership of a group right when obtaining a
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position in __wseq but only reference count the group when using futexes
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to block, it can happen that a group gets closed before a waiter can
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increment the reference count. Therefore, waiters have to check whether
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their group is already closed using __g1_start. They also have to perform
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this check when spinning when trying to grab a signal from __g_signals.
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Note that for these checks, using relaxed MO to load __g1_start is
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sufficient because if a waiter can see a sufficiently large value, it could
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have also consume a signal in the waiters group.
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Waiters try to grab a signal from __g_signals without holding a reference
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count, which can lead to stealing a signal from a more recent group after
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their own group was already closed. They cannot always detect whether they
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in fact did because they do not know when they stole, but they can
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conservatively add a signal back to the group they stole from; if they
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did so unnecessarily, all that happens is a spurious wake-up. To make this
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even less likely, __g1_start contains the index of the current g2 too,
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which allows waiters to check if there aliasing on the group slots; if
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there wasn't, they didn't steal from the current G1, which means that the
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G1 they stole from must have been already closed and they do not need to
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fix anything.
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It is essential that the last field in pthread_cond_t is __g_signals[1]:
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The previous condvar used a pointer-sized field in pthread_cond_t, so a
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PTHREAD_COND_INITIALIZER from that condvar implementation might only
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initialize 4 bytes to zero instead of the 8 bytes we need (i.e., 44 bytes
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in total instead of the 48 we need). __g_signals[1] is not accessed before
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the first group switch (G2 starts at index 0), which will set its value to
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zero after a harmless fetch-or whose return value is ignored. This
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effectively completes initialization.
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Limitations:
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* This condvar isn't designed to allow for more than
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__PTHREAD_COND_MAX_GROUP_SIZE * (1 << 31) calls to __pthread_cond_wait.
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* More than __PTHREAD_COND_MAX_GROUP_SIZE concurrent waiters are not
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supported.
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* Beyond what is allowed as errors by POSIX or documented, we can also
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return the following errors:
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* EPERM if MUTEX is a recursive mutex and the caller doesn't own it.
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* EOWNERDEAD or ENOTRECOVERABLE when using robust mutexes. Unlike
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for other errors, this can happen when we re-acquire the mutex; this
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isn't allowed by POSIX (which requires all errors to virtually happen
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before we release the mutex or change the condvar state), but there's
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nothing we can do really.
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* When using PTHREAD_MUTEX_PP_* mutexes, we can also return all errors
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returned by __pthread_tpp_change_priority. We will already have
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released the mutex in such cases, so the caller cannot expect to own
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MUTEX.
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Other notes:
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* Instead of the normal mutex unlock / lock functions, we use
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__pthread_mutex_unlock_usercnt(m, 0) / __pthread_mutex_cond_lock(m)
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because those will not change the mutex-internal users count, so that it
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can be detected when a condvar is still associated with a particular
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mutex because there is a waiter blocked on this condvar using this mutex.
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*/
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static __always_inline int
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__pthread_cond_wait_common (pthread_cond_t *cond, pthread_mutex_t *mutex,
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clockid_t clockid, const struct __timespec64 *abstime)
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{
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const int maxspin = 0;
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int err;
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int result = 0;
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LIBC_PROBE (cond_wait, 2, cond, mutex);
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/* clockid will already have been checked by
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__pthread_cond_clockwait or pthread_condattr_setclock, or we
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don't use it if abstime is NULL, so we don't need to check it
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here. */
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/* Acquire a position (SEQ) in the waiter sequence (WSEQ). We use an
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atomic operation because signals and broadcasts may update the group
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switch without acquiring the mutex. We do not need release MO here
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because we do not need to establish any happens-before relation with
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signalers (see __pthread_cond_signal); modification order alone
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establishes a total order of waiters/signals. We do need acquire MO
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to synchronize with group reinitialization in
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__condvar_quiesce_and_switch_g1. */
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uint64_t wseq = __condvar_fetch_add_wseq_acquire (cond, 2);
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/* Find our group's index. We always go into what was G2 when we acquired
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our position. */
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unsigned int g = wseq & 1;
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uint64_t seq = wseq >> 1;
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/* Increase the waiter reference count. Relaxed MO is sufficient because
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we only need to synchronize when decrementing the reference count. */
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unsigned int flags = atomic_fetch_add_relaxed (&cond->__data.__wrefs, 8);
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int private = __condvar_get_private (flags);
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/* Now that we are registered as a waiter, we can release the mutex.
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Waiting on the condvar must be atomic with releasing the mutex, so if
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the mutex is used to establish a happens-before relation with any
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signaler, the waiter must be visible to the latter; thus, we release the
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mutex after registering as waiter.
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If releasing the mutex fails, we just cancel our registration as a
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waiter and confirm that we have woken up. */
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err = __pthread_mutex_unlock_usercnt (mutex, 0);
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if (__glibc_unlikely (err != 0))
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{
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__condvar_cancel_waiting (cond, seq, g, private);
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__condvar_confirm_wakeup (cond, private);
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return err;
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}
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/* Now wait until a signal is available in our group or it is closed.
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Acquire MO so that if we observe a value of zero written after group
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switching in __condvar_quiesce_and_switch_g1, we synchronize with that
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|
store and will see the prior update of __g1_start done while switching
|
|
groups too. */
|
|
unsigned int signals = atomic_load_acquire (cond->__data.__g_signals + g);
|
|
|
|
do
|
|
{
|
|
while (1)
|
|
{
|
|
/* Spin-wait first.
|
|
Note that spinning first without checking whether a timeout
|
|
passed might lead to what looks like a spurious wake-up even
|
|
though we should return ETIMEDOUT (e.g., if the caller provides
|
|
an absolute timeout that is clearly in the past). However,
|
|
(1) spurious wake-ups are allowed, (2) it seems unlikely that a
|
|
user will (ab)use pthread_cond_wait as a check for whether a
|
|
point in time is in the past, and (3) spinning first without
|
|
having to compare against the current time seems to be the right
|
|
choice from a performance perspective for most use cases. */
|
|
unsigned int spin = maxspin;
|
|
while (signals == 0 && spin > 0)
|
|
{
|
|
/* Check that we are not spinning on a group that's already
|
|
closed. */
|
|
if (seq < (__condvar_load_g1_start_relaxed (cond) >> 1))
|
|
goto done;
|
|
|
|
/* TODO Back off. */
|
|
|
|
/* Reload signals. See above for MO. */
|
|
signals = atomic_load_acquire (cond->__data.__g_signals + g);
|
|
spin--;
|
|
}
|
|
|
|
/* If our group will be closed as indicated by the flag on signals,
|
|
don't bother grabbing a signal. */
|
|
if (signals & 1)
|
|
goto done;
|
|
|
|
/* If there is an available signal, don't block. */
|
|
if (signals != 0)
|
|
break;
|
|
|
|
/* No signals available after spinning, so prepare to block.
|
|
We first acquire a group reference and use acquire MO for that so
|
|
that we synchronize with the dummy read-modify-write in
|
|
__condvar_quiesce_and_switch_g1 if we read from that. In turn,
|
|
in this case this will make us see the closed flag on __g_signals
|
|
that designates a concurrent attempt to reuse the group's slot.
|
|
We use acquire MO for the __g_signals check to make the
|
|
__g1_start check work (see spinning above).
|
|
Note that the group reference acquisition will not mask the
|
|
release MO when decrementing the reference count because we use
|
|
an atomic read-modify-write operation and thus extend the release
|
|
sequence. */
|
|
atomic_fetch_add_acquire (cond->__data.__g_refs + g, 2);
|
|
if (((atomic_load_acquire (cond->__data.__g_signals + g) & 1) != 0)
|
|
|| (seq < (__condvar_load_g1_start_relaxed (cond) >> 1)))
|
|
{
|
|
/* Our group is closed. Wake up any signalers that might be
|
|
waiting. */
|
|
__condvar_dec_grefs (cond, g, private);
|
|
goto done;
|
|
}
|
|
|
|
// Now block.
|
|
struct _pthread_cleanup_buffer buffer;
|
|
struct _condvar_cleanup_buffer cbuffer;
|
|
cbuffer.wseq = wseq;
|
|
cbuffer.cond = cond;
|
|
cbuffer.mutex = mutex;
|
|
cbuffer.private = private;
|
|
__pthread_cleanup_push (&buffer, __condvar_cleanup_waiting, &cbuffer);
|
|
|
|
err = __futex_abstimed_wait_cancelable64 (
|
|
cond->__data.__g_signals + g, 0, clockid, abstime, private);
|
|
|
|
__pthread_cleanup_pop (&buffer, 0);
|
|
|
|
if (__glibc_unlikely (err == ETIMEDOUT || err == EOVERFLOW))
|
|
{
|
|
__condvar_dec_grefs (cond, g, private);
|
|
/* If we timed out, we effectively cancel waiting. Note that
|
|
we have decremented __g_refs before cancellation, so that a
|
|
deadlock between waiting for quiescence of our group in
|
|
__condvar_quiesce_and_switch_g1 and us trying to acquire
|
|
the lock during cancellation is not possible. */
|
|
__condvar_cancel_waiting (cond, seq, g, private);
|
|
result = err;
|
|
goto done;
|
|
}
|
|
else
|
|
__condvar_dec_grefs (cond, g, private);
|
|
|
|
/* Reload signals. See above for MO. */
|
|
signals = atomic_load_acquire (cond->__data.__g_signals + g);
|
|
}
|
|
|
|
}
|
|
/* Try to grab a signal. Use acquire MO so that we see an up-to-date value
|
|
of __g1_start below (see spinning above for a similar case). In
|
|
particular, if we steal from a more recent group, we will also see a
|
|
more recent __g1_start below. */
|
|
while (!atomic_compare_exchange_weak_acquire (cond->__data.__g_signals + g,
|
|
&signals, signals - 2));
|
|
|
|
/* We consumed a signal but we could have consumed from a more recent group
|
|
that aliased with ours due to being in the same group slot. If this
|
|
might be the case our group must be closed as visible through
|
|
__g1_start. */
|
|
uint64_t g1_start = __condvar_load_g1_start_relaxed (cond);
|
|
if (seq < (g1_start >> 1))
|
|
{
|
|
/* We potentially stole a signal from a more recent group but we do not
|
|
know which group we really consumed from.
|
|
We do not care about groups older than current G1 because they are
|
|
closed; we could have stolen from these, but then we just add a
|
|
spurious wake-up for the current groups.
|
|
We will never steal a signal from current G2 that was really intended
|
|
for G2 because G2 never receives signals (until it becomes G1). We
|
|
could have stolen a signal from G2 that was conservatively added by a
|
|
previous waiter that also thought it stole a signal -- but given that
|
|
that signal was added unnecessarily, it's not a problem if we steal
|
|
it.
|
|
Thus, the remaining case is that we could have stolen from the current
|
|
G1, where "current" means the __g1_start value we observed. However,
|
|
if the current G1 does not have the same slot index as we do, we did
|
|
not steal from it and do not need to undo that. This is the reason
|
|
for putting a bit with G2's index into__g1_start as well. */
|
|
if (((g1_start & 1) ^ 1) == g)
|
|
{
|
|
/* We have to conservatively undo our potential mistake of stealing
|
|
a signal. We can stop trying to do that when the current G1
|
|
changes because other spinning waiters will notice this too and
|
|
__condvar_quiesce_and_switch_g1 has checked that there are no
|
|
futex waiters anymore before switching G1.
|
|
Relaxed MO is fine for the __g1_start load because we need to
|
|
merely be able to observe this fact and not have to observe
|
|
something else as well.
|
|
??? Would it help to spin for a little while to see whether the
|
|
current G1 gets closed? This might be worthwhile if the group is
|
|
small or close to being closed. */
|
|
unsigned int s = atomic_load_relaxed (cond->__data.__g_signals + g);
|
|
while (__condvar_load_g1_start_relaxed (cond) == g1_start)
|
|
{
|
|
/* Try to add a signal. We don't need to acquire the lock
|
|
because at worst we can cause a spurious wake-up. If the
|
|
group is in the process of being closed (LSB is true), this
|
|
has an effect similar to us adding a signal. */
|
|
if (((s & 1) != 0)
|
|
|| atomic_compare_exchange_weak_relaxed
|
|
(cond->__data.__g_signals + g, &s, s + 2))
|
|
{
|
|
/* If we added a signal, we also need to add a wake-up on
|
|
the futex. We also need to do that if we skipped adding
|
|
a signal because the group is being closed because
|
|
while __condvar_quiesce_and_switch_g1 could have closed
|
|
the group, it might still be waiting for futex waiters to
|
|
leave (and one of those waiters might be the one we stole
|
|
the signal from, which cause it to block using the
|
|
futex). */
|
|
futex_wake (cond->__data.__g_signals + g, 1, private);
|
|
break;
|
|
}
|
|
/* TODO Back off. */
|
|
}
|
|
}
|
|
}
|
|
|
|
done:
|
|
|
|
/* Confirm that we have been woken. We do that before acquiring the mutex
|
|
to allow for execution of pthread_cond_destroy while having acquired the
|
|
mutex. */
|
|
__condvar_confirm_wakeup (cond, private);
|
|
|
|
/* Woken up; now re-acquire the mutex. If this doesn't fail, return RESULT,
|
|
which is set to ETIMEDOUT if a timeout occurred, or zero otherwise. */
|
|
err = __pthread_mutex_cond_lock (mutex);
|
|
/* XXX Abort on errors that are disallowed by POSIX? */
|
|
return (err != 0) ? err : result;
|
|
}
|
|
|
|
|
|
/* See __pthread_cond_wait_common. */
|
|
int
|
|
___pthread_cond_wait (pthread_cond_t *cond, pthread_mutex_t *mutex)
|
|
{
|
|
/* clockid is unused when abstime is NULL. */
|
|
return __pthread_cond_wait_common (cond, mutex, 0, NULL);
|
|
}
|
|
|
|
versioned_symbol (libc, ___pthread_cond_wait, pthread_cond_wait,
|
|
GLIBC_2_3_2);
|
|
libc_hidden_ver (___pthread_cond_wait, __pthread_cond_wait)
|
|
#ifndef SHARED
|
|
strong_alias (___pthread_cond_wait, __pthread_cond_wait)
|
|
#endif
|
|
|
|
/* See __pthread_cond_wait_common. */
|
|
int
|
|
___pthread_cond_timedwait64 (pthread_cond_t *cond, pthread_mutex_t *mutex,
|
|
const struct __timespec64 *abstime)
|
|
{
|
|
/* Check parameter validity. This should also tell the compiler that
|
|
it can assume that abstime is not NULL. */
|
|
if (! valid_nanoseconds (abstime->tv_nsec))
|
|
return EINVAL;
|
|
|
|
/* Relaxed MO is suffice because clock ID bit is only modified
|
|
in condition creation. */
|
|
unsigned int flags = atomic_load_relaxed (&cond->__data.__wrefs);
|
|
clockid_t clockid = (flags & __PTHREAD_COND_CLOCK_MONOTONIC_MASK)
|
|
? CLOCK_MONOTONIC : CLOCK_REALTIME;
|
|
return __pthread_cond_wait_common (cond, mutex, clockid, abstime);
|
|
}
|
|
|
|
#if __TIMESIZE == 64
|
|
strong_alias (___pthread_cond_timedwait64, ___pthread_cond_timedwait)
|
|
#else
|
|
strong_alias (___pthread_cond_timedwait64, __pthread_cond_timedwait64)
|
|
libc_hidden_def (__pthread_cond_timedwait64)
|
|
|
|
int
|
|
___pthread_cond_timedwait (pthread_cond_t *cond, pthread_mutex_t *mutex,
|
|
const struct timespec *abstime)
|
|
{
|
|
struct __timespec64 ts64 = valid_timespec_to_timespec64 (*abstime);
|
|
|
|
return __pthread_cond_timedwait64 (cond, mutex, &ts64);
|
|
}
|
|
#endif /* __TIMESIZE == 64 */
|
|
versioned_symbol (libc, ___pthread_cond_timedwait,
|
|
pthread_cond_timedwait, GLIBC_2_3_2);
|
|
libc_hidden_ver (___pthread_cond_timedwait, __pthread_cond_timedwait)
|
|
#ifndef SHARED
|
|
strong_alias (___pthread_cond_timedwait, __pthread_cond_timedwait)
|
|
#endif
|
|
|
|
/* See __pthread_cond_wait_common. */
|
|
int
|
|
___pthread_cond_clockwait64 (pthread_cond_t *cond, pthread_mutex_t *mutex,
|
|
clockid_t clockid,
|
|
const struct __timespec64 *abstime)
|
|
{
|
|
/* Check parameter validity. This should also tell the compiler that
|
|
it can assume that abstime is not NULL. */
|
|
if (! valid_nanoseconds (abstime->tv_nsec))
|
|
return EINVAL;
|
|
|
|
if (!futex_abstimed_supported_clockid (clockid))
|
|
return EINVAL;
|
|
|
|
return __pthread_cond_wait_common (cond, mutex, clockid, abstime);
|
|
}
|
|
|
|
#if __TIMESIZE == 64
|
|
strong_alias (___pthread_cond_clockwait64, ___pthread_cond_clockwait)
|
|
#else
|
|
strong_alias (___pthread_cond_clockwait64, __pthread_cond_clockwait64);
|
|
libc_hidden_def (__pthread_cond_clockwait64)
|
|
|
|
int
|
|
___pthread_cond_clockwait (pthread_cond_t *cond, pthread_mutex_t *mutex,
|
|
clockid_t clockid,
|
|
const struct timespec *abstime)
|
|
{
|
|
struct __timespec64 ts64 = valid_timespec_to_timespec64 (*abstime);
|
|
|
|
return __pthread_cond_clockwait64 (cond, mutex, clockid, &ts64);
|
|
}
|
|
#endif /* __TIMESIZE == 64 */
|
|
libc_hidden_ver (___pthread_cond_clockwait, __pthread_cond_clockwait)
|
|
#ifndef SHARED
|
|
strong_alias (___pthread_cond_clockwait, __pthread_cond_clockwait)
|
|
#endif
|
|
versioned_symbol (libc, ___pthread_cond_clockwait,
|
|
pthread_cond_clockwait, GLIBC_2_34);
|
|
#if OTHER_SHLIB_COMPAT (libpthread, GLIBC_2_30, GLIBC_2_34)
|
|
compat_symbol (libpthread, ___pthread_cond_clockwait,
|
|
pthread_cond_clockwait, GLIBC_2_30);
|
|
#endif
|