2014-09-21 17:33:12 +00:00
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/* Copyright (C) 2011-2014 Free Software Foundation, Inc.
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2012-03-27 23:13:14 +00:00
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Contributed by Torvald Riegel <triegel@redhat.com>.
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This file is part of the GNU Transactional Memory Library (libitm).
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Libitm is free software; you can redistribute it and/or modify it
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under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 3 of the License, or
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(at your option) any later version.
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Libitm is distributed in the hope that it will be useful, but WITHOUT ANY
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WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
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FOR A PARTICULAR PURPOSE. See the GNU General Public License for
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more details.
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Under Section 7 of GPL version 3, you are granted additional
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permissions described in the GCC Runtime Library Exception, version
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3.1, as published by the Free Software Foundation.
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You should have received a copy of the GNU General Public License and
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a copy of the GCC Runtime Library Exception along with this program;
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see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
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<http://www.gnu.org/licenses/>. */
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#include "libitm_i.h"
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#include "futex.h"
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#include <limits.h>
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namespace GTM HIDDEN {
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// Acquire a RW lock for reading.
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void
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gtm_rwlock::read_lock (gtm_thread *tx)
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{
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for (;;)
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{
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// Fast path: first announce our intent to read, then check for
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// conflicting intents to write. The fence ensures that this happens
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// in exactly this order.
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tx->shared_state.store (0, memory_order_relaxed);
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atomic_thread_fence (memory_order_seq_cst);
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if (likely (writers.load (memory_order_relaxed) == 0))
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return;
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// There seems to be an active, waiting, or confirmed writer, so enter
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// the futex-based slow path.
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// Before waiting, we clear our read intent check whether there are any
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// writers that might potentially wait for readers. If so, wake them.
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// We need the barrier here for the same reason that we need it in
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// read_unlock().
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// TODO Potentially too many wake-ups. See comments in read_unlock().
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tx->shared_state.store (-1, memory_order_relaxed);
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atomic_thread_fence (memory_order_seq_cst);
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if (writer_readers.load (memory_order_relaxed) > 0)
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{
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writer_readers.store (0, memory_order_relaxed);
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futex_wake(&writer_readers, 1);
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}
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// Signal that there are waiting readers and wait until there is no
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// writer anymore.
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// TODO Spin here on writers for a while. Consider whether we woke
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// any writers before?
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while (writers.load (memory_order_relaxed))
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{
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// An active writer. Wait until it has finished. To avoid lost
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// wake-ups, we need to use Dekker-like synchronization.
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// Note that we cannot reset readers to zero when we see that there
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// are no writers anymore after the barrier because this pending
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// store could then lead to lost wake-ups at other readers.
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readers.store (1, memory_order_relaxed);
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atomic_thread_fence (memory_order_seq_cst);
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if (writers.load (memory_order_relaxed))
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futex_wait(&readers, 1);
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else
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{
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// There is no writer, actually. However, we can have enabled
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// a futex_wait in other readers by previously setting readers
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// to 1, so we have to wake them up because there is no writer
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// that will do that. We don't know whether the wake-up is
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// really necessary, but we can get lost wake-up situations
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// otherwise.
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// No additional barrier nor a nonrelaxed load is required due
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// to coherency constraints. write_unlock() checks readers to
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// see if any wake-up is necessary, but it is not possible that
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// a reader's store prevents a required later writer wake-up;
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// If the waking reader's store (value 0) is in modification
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// order after the waiting readers store (value 1), then the
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// latter will have to read 0 in the futex due to coherency
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// constraints and the happens-before enforced by the futex
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// (paragraph 6.10 in the standard, 6.19.4 in the Batty et al
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// TR); second, the writer will be forced to read in
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// modification order too due to Dekker-style synchronization
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// with the waiting reader (see write_unlock()).
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// ??? Can we avoid the wake-up if readers is zero (like in
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// write_unlock())? Anyway, this might happen too infrequently
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// to improve performance significantly.
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readers.store (0, memory_order_relaxed);
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futex_wake(&readers, INT_MAX);
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}
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}
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// And we try again to acquire a read lock.
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}
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}
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// Acquire a RW lock for writing. Generic version that also works for
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// upgrades.
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// Note that an upgrade might fail (and thus waste previous work done during
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// this transaction) if there is another thread that tried to go into serial
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// mode earlier (i.e., upgrades do not have higher priority than pure writers).
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// However, this seems rare enough to not consider it further as we need both
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// a non-upgrade writer and a writer to happen to switch to serial mode
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// concurrently. If we'd want to handle this, a writer waiting for readers
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// would have to coordinate with later arriving upgrades and hand over the
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// lock to them, including the the reader-waiting state. We can try to support
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// this if this will actually happen often enough in real workloads.
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bool
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gtm_rwlock::write_lock_generic (gtm_thread *tx)
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{
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// Try to acquire the write lock.
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int w = 0;
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if (unlikely (!writers.compare_exchange_strong (w, 1)))
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{
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// If this is an upgrade, we must not wait for other writers or
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// upgrades.
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if (tx != 0)
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return false;
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// There is already a writer. If there are no other waiting writers,
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// switch to contended mode. We need seq_cst memory order to make the
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// Dekker-style synchronization work.
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if (w != 2)
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w = writers.exchange (2);
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while (w != 0)
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{
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futex_wait(&writers, 2);
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w = writers.exchange (2);
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}
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}
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// We have acquired the writer side of the R/W lock. Now wait for any
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// readers that might still be active.
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// We don't need an extra barrier here because the CAS and the xchg
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// operations have full barrier semantics already.
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// TODO In the worst case, this requires one wait/wake pair for each
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// active reader. Reduce this!
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for (gtm_thread *it = gtm_thread::list_of_threads; it != 0;
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it = it->next_thread)
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{
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if (it == tx)
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continue;
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// Use a loop here to check reader flags again after waiting.
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while (it->shared_state.load (memory_order_relaxed)
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!= ~(typeof it->shared_state)0)
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{
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// An active reader. Wait until it has finished. To avoid lost
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// wake-ups, we need to use Dekker-like synchronization.
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// Note that we can reset writer_readers to zero when we see after
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// the barrier that the reader has finished in the meantime;
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// however, this is only possible because we are the only writer.
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// TODO Spin for a while on this reader flag.
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writer_readers.store (1, memory_order_relaxed);
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atomic_thread_fence (memory_order_seq_cst);
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if (it->shared_state.load (memory_order_relaxed)
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!= ~(typeof it->shared_state)0)
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futex_wait(&writer_readers, 1);
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else
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writer_readers.store (0, memory_order_relaxed);
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}
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}
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return true;
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}
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// Acquire a RW lock for writing.
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void
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gtm_rwlock::write_lock ()
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{
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write_lock_generic (0);
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}
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// Upgrade a RW lock that has been locked for reading to a writing lock.
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// Do this without possibility of another writer incoming. Return false
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// if this attempt fails (i.e. another thread also upgraded).
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bool
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gtm_rwlock::write_upgrade (gtm_thread *tx)
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{
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return write_lock_generic (tx);
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}
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// Has to be called iff the previous upgrade was successful and after it is
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// safe for the transaction to not be marked as a reader anymore.
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void
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gtm_rwlock::write_upgrade_finish (gtm_thread *tx)
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{
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// We are not a reader anymore. This is only safe to do after we have
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// acquired the writer lock.
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tx->shared_state.store (-1, memory_order_release);
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}
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// Release a RW lock from reading.
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void
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gtm_rwlock::read_unlock (gtm_thread *tx)
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{
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// We only need release memory order here because of privatization safety
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// (this ensures that marking the transaction as inactive happens after
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// any prior data accesses by this transaction, and that neither the
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// compiler nor the hardware order this store earlier).
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// ??? We might be able to avoid this release here if the compiler can't
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// merge the release fence with the subsequent seq_cst fence.
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tx->shared_state.store (-1, memory_order_release);
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// If there is a writer waiting for readers, wake it up. We need the fence
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// to avoid lost wake-ups. Furthermore, the privatization safety
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// implementation in gtm_thread::try_commit() relies on the existence of
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// this seq_cst fence.
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// ??? We might not be the last active reader, so the wake-up might happen
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// too early. How do we avoid this without slowing down readers too much?
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// Each reader could scan the list of txns for other active readers but
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// this can result in many cache misses. Use combining instead?
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// TODO Sends out one wake-up for each reader in the worst case.
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atomic_thread_fence (memory_order_seq_cst);
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if (unlikely (writer_readers.load (memory_order_relaxed) > 0))
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{
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// No additional barrier needed here (see write_unlock()).
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writer_readers.store (0, memory_order_relaxed);
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futex_wake(&writer_readers, 1);
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}
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}
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// Release a RW lock from writing.
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void
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gtm_rwlock::write_unlock ()
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{
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// This needs to have seq_cst memory order.
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if (writers.fetch_sub (1) == 2)
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{
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// There might be waiting writers, so wake them.
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writers.store (0, memory_order_relaxed);
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if (futex_wake(&writers, 1) == 0)
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{
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// If we did not wake any waiting writers, we might indeed be the
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// last writer (this can happen because write_lock_generic()
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// exchanges 0 or 1 to 2 and thus might go to contended mode even if
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// no other thread holds the write lock currently). Therefore, we
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// have to wake up readers here as well. Execute a barrier after
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// the previous relaxed reset of writers (Dekker-style), and fall
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// through to the normal reader wake-up code.
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atomic_thread_fence (memory_order_seq_cst);
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}
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else
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return;
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}
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// No waiting writers, so wake up all waiting readers.
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// Because the fetch_and_sub is a full barrier already, we don't need
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// another barrier here (as in read_unlock()).
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if (readers.load (memory_order_relaxed) > 0)
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{
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// No additional barrier needed here. The previous load must be in
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// modification order because of the coherency constraints. Late stores
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// by a reader are not a problem because readers do Dekker-style
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// synchronization on writers.
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readers.store (0, memory_order_relaxed);
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futex_wake(&readers, INT_MAX);
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}
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}
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} // namespace GTM
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