libitm/config/posix/rwlock.cc - gcc - Git at Google

 /* Copyright (C) 2008-2021 Free Software Foundation, Inc.
    Contributed by Richard Henderson <rth@redhat.com>.

    This file is part of the GNU Transactional Memory Library (libitm).

    Libitm is free software; you can redistribute it and/or modify it
    under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 3 of the License, or
    (at your option) any later version.

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

    Under Section 7 of GPL version 3, you are granted additional
    permissions described in the GCC Runtime Library Exception, version
    3.1, as published by the Free Software Foundation.

    You should have received a copy of the GNU General Public License and
    a copy of the GCC Runtime Library Exception along with this program;
    see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
    <http://www.gnu.org/licenses/>.  */

 #include "libitm_i.h"

 namespace GTM HIDDEN {

 // Initialize a new RW lock.
 // ??? Move this back to the header file when constexpr is implemented.

 gtm_rwlock::gtm_rwlock()
   : summary (0),
     htm_fastpath (0),
     mutex (PTHREAD_MUTEX_INITIALIZER),
     c_readers (PTHREAD_COND_INITIALIZER),
     c_writers (PTHREAD_COND_INITIALIZER),
     c_confirmed_writers (PTHREAD_COND_INITIALIZER),
     a_readers (0),
     w_readers (0),
     w_writers (0)
 { }

 gtm_rwlock::~gtm_rwlock()
 {
   pthread_mutex_destroy (&this->mutex);
   pthread_cond_destroy (&this->c_readers);
   pthread_cond_destroy (&this->c_writers);
 }

 // Acquire a RW lock for reading.

 void
 gtm_rwlock::read_lock (gtm_thread *tx)
 {
   // Fast path: first announce our intent to read, then check for conflicting
   // intents to write.  The fence ensure that this happens in exactly this
   // order.
   tx->shared_state.store (0, memory_order_relaxed);
   atomic_thread_fence (memory_order_seq_cst);
   unsigned int sum = this->summary.load (memory_order_relaxed);
   if (likely(!(sum & (a_writer | w_writer))))
     return;

   // There seems to be an active, waiting, or confirmed writer, so enter the
   // mutex-based slow path. To try to keep the number of readers small that
   // the writer will see, we clear our read flag right away before entering
   // the critical section. Otherwise, the writer would have to wait for us to
   // get into the critical section. (Note that for correctness, this only has
   // to happen before we leave the slow path and before we wait for any
   // writer).
   // ??? Add a barrier to enforce early visibility of this?
   tx->shared_state.store(-1, memory_order_relaxed);

   pthread_mutex_lock (&this->mutex);

   // Read summary again after acquiring the mutex because it might have
   // changed during waiting for the mutex to become free.
   sum = this->summary.load (memory_order_relaxed);

   // If there is a writer waiting for readers, wake it up. Only do that if we
   // might be the last reader that could do the wake-up, otherwise skip the
   // wake-up but decrease a_readers to show that we have entered the slow path.
   // This has to happen before we wait for any writers or upgraders.
   // See write_lock_generic() for further explanations.
   if (this->a_readers > 0)
     {
       this->a_readers--;
       if (this->a_readers == 0)
 	pthread_cond_signal(&this->c_confirmed_writers);
     }

   // If there is an active or waiting writer, we must wait.
   while (sum & (a_writer | w_writer))
     {
       this->summary.store (sum | w_reader, memory_order_relaxed);
       this->w_readers++;
       pthread_cond_wait (&this->c_readers, &this->mutex);
       sum = this->summary.load (memory_order_relaxed);
       if (--this->w_readers == 0)
 	sum &= ~w_reader;
     }

   // Otherwise we can acquire the lock for read.
   tx->shared_state.store(0, memory_order_relaxed);

   pthread_mutex_unlock(&this->mutex);
 }


 // Acquire a RW lock for writing. Generic version that also works for
 // upgrades.
 // Note that an upgrade might fail (and thus waste previous work done during
 // this transaction) if there is another thread that tried to go into serial
 // mode earlier (i.e., upgrades do not have higher priority than pure writers).
 // However, this seems rare enough to not consider it further as we need both
 // a non-upgrade writer and a writer to happen to switch to serial mode
 // concurrently. If we'd want to handle this, a writer waiting for readers
 // would have to coordinate with later arriving upgrades and hand over the
 // lock to them, including the the reader-waiting state. We can try to support
 // this if this will actually happen often enough in real workloads.

 bool
 gtm_rwlock::write_lock_generic (gtm_thread *tx)
 {
   pthread_mutex_lock (&this->mutex);

   unsigned int sum = this->summary.load (memory_order_relaxed);

   // If there is an active writer, wait.
   while (sum & a_writer)
     {
       if (tx != 0)
 	{
 	  // If this is an upgrade, we must not wait for other writers or
 	  // upgrades that already have gone in
 	  pthread_mutex_unlock (&this->mutex);
 	  return false;
 	}

       this->summary.store (sum | w_writer, memory_order_relaxed);
       this->w_writers++;
       pthread_cond_wait (&this->c_writers, &this->mutex);
       sum = this->summary.load (memory_order_relaxed);
       if (--this->w_writers == 0)
 	sum &= ~w_writer;
     }

   // Otherwise we can acquire the lock for write. As a writer, we have
   // priority, so we don't need to take this back.
   this->summary.store (sum | a_writer, memory_order_relaxed);

   // We still need to wait for active readers to finish. The barrier makes
   // sure that we first set our write intent and check for active readers
   // after that, in strictly this order (similar to the barrier in the fast
   // path of read_lock()).
   atomic_thread_fence(memory_order_seq_cst);

   // Count the number of active readers to be able to decrease the number of
   // wake-ups and wait calls that are necessary.
   //
   // This number is an upper bound of the number of readers that actually
   // are still active and which we need to wait for:
   // - We set our write flag before checking the reader flags, and readers
   //   check our write flag after clearing their read flags in read_unlock().
   //   Therefore, they will enter the slow path whenever we have seen them.
   // - Readers will have cleared their read flags before leaving the slow
   //   path in read_lock() (prevents lost wake-ups), and before waiting for
   //   any writer (prevents deadlocks).
   //
   // However, this number is also just a lower bound of the number of readers
   // that will actually enter the slow path in read_unlock() or read_lock():
   // - Because the read flag is cleared outside of a critical section, writers
   //   can see it as cleared while the reader still goes into the slow path.
   //
   // Therefore, readers can skip (lower bound - 1) wake-ups, but we do need
   // the following loop to check that the readers that we wanted to wait for
   // are actually those that entered the slow path so far (and either skipped
   // or sent a wake-up).
   //
   // ??? Do we need to optimize further? (The writer could publish a list of
   // readers that it suspects to be active. Readers could check this list and
   // only decrement a_readers if they are in this list.)
   for (;;)
     {
       // ??? Keep a list of active readers that we saw and update it on the
       // next retry instead? This might reduce the number of cache misses that
       // we get when checking reader flags.
       int readers = 0;
       for (gtm_thread *it = gtm_thread::list_of_threads; it != 0;
 	  it = it->next_thread)
 	{
 	  // Don't count ourself if this is an upgrade.
           if (it == tx)
             continue;
 	  if (it->shared_state.load(memory_order_relaxed) != (gtm_word)-1)
 	    readers++;
 	}

       // If we have not seen any readers, we will not wait.
       if (readers == 0)
 	break;

       // If this is an upgrade, we have to break deadlocks with
       // privatization safety.  This may fail on our side, in which
       // case we need to cancel our attempt to upgrade.  Also, we do not
       // block using the convdar but just spin so that we never have to be
       // woken.
       // FIXME This is horribly inefficient -- but so is not being able
       // to use futexes in this case.
       if (tx != 0)
 	{
 	  pthread_mutex_unlock (&this->mutex);
 	  if (!abi_disp ()->snapshot_most_recent ())
 	    {
 	      write_unlock ();
 	      return false;
 	    }
 	  pthread_mutex_lock (&this->mutex);
 	  continue;
 	}


       // We've seen a number of readers, so we publish this number and wait.
       this->a_readers = readers;
       pthread_cond_wait (&this->c_confirmed_writers, &this->mutex);
     }

   pthread_mutex_unlock (&this->mutex);
   return true;
 }

 // Acquire a RW lock for writing.

 void
 gtm_rwlock::write_lock ()
 {
   write_lock_generic (0);
 }


 // Upgrade a RW lock that has been locked for reading to a writing lock.
 // Do this without possibility of another writer incoming.  Return false
 // if this attempt fails (i.e. another thread also upgraded).

 bool
 gtm_rwlock::write_upgrade (gtm_thread *tx)
 {
   return write_lock_generic (tx);
 }


 // Has to be called iff the previous upgrade was successful and after it is
 // safe for the transaction to not be marked as a reader anymore.

 void
 gtm_rwlock::write_upgrade_finish (gtm_thread *tx)
 {
   // We are not a reader anymore.  This is only safe to do after we have
   // acquired the writer lock.
   tx->shared_state.store (-1, memory_order_release);
 }


 // Release a RW lock from reading.

 void
 gtm_rwlock::read_unlock (gtm_thread *tx)
 {
   // We only need release memory order here because of privatization safety
   // (this ensures that marking the transaction as inactive happens after
   // any prior data accesses by this transaction, and that neither the
   // compiler nor the hardware order this store earlier).
   // ??? We might be able to avoid this release here if the compiler can't
   // merge the release fence with the subsequent seq_cst fence.
   tx->shared_state.store (-1, memory_order_release);
   // We need this seq_cst fence here to avoid lost wake-ups.  Furthermore,
   // the privatization safety implementation in gtm_thread::try_commit()
   // relies on the existence of this seq_cst fence.
   atomic_thread_fence (memory_order_seq_cst);
   unsigned int sum = this->summary.load (memory_order_relaxed);
   if (likely(!(sum & (a_writer | w_writer))))
     return;

   // There is a writer, either active or waiting for other readers or writers.
   // Thus, enter the mutex-based slow path.
   pthread_mutex_lock (&this->mutex);

   // If there is a writer waiting for readers, wake it up. Only do that if we
   // might be the last reader that could do the wake-up, otherwise skip the
   // wake-up and decrease a_readers to publish that we have entered the slow
   // path but skipped the wake-up.
   if (this->a_readers > 0)
     {
       this->a_readers--;
       if (this->a_readers == 0)
 	pthread_cond_signal(&this->c_confirmed_writers);
     }

   // We don't need to wake up any writers waiting for other writers. Active
   // writers will take care of that.

   pthread_mutex_unlock (&this->mutex);
 }


 // Release a RW lock from writing.

 void
 gtm_rwlock::write_unlock ()
 {
   pthread_mutex_lock (&this->mutex);

   unsigned int sum = this->summary.load (memory_order_relaxed);
   this->summary.store (sum & ~a_writer, memory_order_relaxed);

   // If there is a waiting writer, wake it.
   if (unlikely (sum & w_writer))
     pthread_cond_signal (&this->c_writers);

   // If there are waiting readers, wake them.
   else if (unlikely (sum & w_reader))
     pthread_cond_broadcast (&this->c_readers);

   pthread_mutex_unlock (&this->mutex);
 }

 } // namespace GTM
	/* Copyright (C) 2008-2021 Free Software Foundation, Inc.
	Contributed by Richard Henderson <rth@redhat.com>.

	This file is part of the GNU Transactional Memory Library (libitm).

	Libitm is free software; you can redistribute it and/or modify it
	under the terms of the GNU General Public License as published by
	the Free Software Foundation; either version 3 of the License, or
	(at your option) any later version.

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

	Under Section 7 of GPL version 3, you are granted additional
	permissions described in the GCC Runtime Library Exception, version
	3.1, as published by the Free Software Foundation.

	You should have received a copy of the GNU General Public License and
	a copy of the GCC Runtime Library Exception along with this program;
	see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
	<http://www.gnu.org/licenses/>. */

	#include "libitm_i.h"

	namespace GTM HIDDEN {

	// Initialize a new RW lock.
	// ??? Move this back to the header file when constexpr is implemented.

	gtm_rwlock::gtm_rwlock()
	: summary (0),
	htm_fastpath (0),
	mutex (PTHREAD_MUTEX_INITIALIZER),
	c_readers (PTHREAD_COND_INITIALIZER),
	c_writers (PTHREAD_COND_INITIALIZER),
	c_confirmed_writers (PTHREAD_COND_INITIALIZER),
	a_readers (0),
	w_readers (0),
	w_writers (0)
	{ }

	gtm_rwlock::~gtm_rwlock()
	{
	pthread_mutex_destroy (&this->mutex);
	pthread_cond_destroy (&this->c_readers);
	pthread_cond_destroy (&this->c_writers);
	}

	// Acquire a RW lock for reading.

	void
	gtm_rwlock::read_lock (gtm_thread *tx)
	{
	// Fast path: first announce our intent to read, then check for conflicting
	// intents to write. The fence ensure that this happens in exactly this
	// order.
	tx->shared_state.store (0, memory_order_relaxed);
	atomic_thread_fence (memory_order_seq_cst);
	unsigned int sum = this->summary.load (memory_order_relaxed);
	if (likely(!(sum & (a_writer \| w_writer))))
	return;

	// There seems to be an active, waiting, or confirmed writer, so enter the
	// mutex-based slow path. To try to keep the number of readers small that
	// the writer will see, we clear our read flag right away before entering
	// the critical section. Otherwise, the writer would have to wait for us to
	// get into the critical section. (Note that for correctness, this only has
	// to happen before we leave the slow path and before we wait for any
	// writer).
	// ??? Add a barrier to enforce early visibility of this?
	tx->shared_state.store(-1, memory_order_relaxed);

	pthread_mutex_lock (&this->mutex);

	// Read summary again after acquiring the mutex because it might have
	// changed during waiting for the mutex to become free.
	sum = this->summary.load (memory_order_relaxed);

	// If there is a writer waiting for readers, wake it up. Only do that if we
	// might be the last reader that could do the wake-up, otherwise skip the
	// wake-up but decrease a_readers to show that we have entered the slow path.
	// This has to happen before we wait for any writers or upgraders.
	// See write_lock_generic() for further explanations.
	if (this->a_readers > 0)
	{
	this->a_readers--;
	if (this->a_readers == 0)
	pthread_cond_signal(&this->c_confirmed_writers);
	}

	// If there is an active or waiting writer, we must wait.
	while (sum & (a_writer \| w_writer))
	{
	this->summary.store (sum \| w_reader, memory_order_relaxed);
	this->w_readers++;
	pthread_cond_wait (&this->c_readers, &this->mutex);
	sum = this->summary.load (memory_order_relaxed);
	if (--this->w_readers == 0)
	sum &= ~w_reader;
	}

	// Otherwise we can acquire the lock for read.
	tx->shared_state.store(0, memory_order_relaxed);

	pthread_mutex_unlock(&this->mutex);
	}


	// Acquire a RW lock for writing. Generic version that also works for
	// upgrades.
	// Note that an upgrade might fail (and thus waste previous work done during
	// this transaction) if there is another thread that tried to go into serial
	// mode earlier (i.e., upgrades do not have higher priority than pure writers).
	// However, this seems rare enough to not consider it further as we need both
	// a non-upgrade writer and a writer to happen to switch to serial mode
	// concurrently. If we'd want to handle this, a writer waiting for readers
	// would have to coordinate with later arriving upgrades and hand over the
	// lock to them, including the the reader-waiting state. We can try to support
	// this if this will actually happen often enough in real workloads.

	bool
	gtm_rwlock::write_lock_generic (gtm_thread *tx)
	{
	pthread_mutex_lock (&this->mutex);

	unsigned int sum = this->summary.load (memory_order_relaxed);

	// If there is an active writer, wait.
	while (sum & a_writer)
	{
	if (tx != 0)
	{
	// If this is an upgrade, we must not wait for other writers or
	// upgrades that already have gone in
	pthread_mutex_unlock (&this->mutex);
	return false;
	}

	this->summary.store (sum \| w_writer, memory_order_relaxed);
	this->w_writers++;
	pthread_cond_wait (&this->c_writers, &this->mutex);
	sum = this->summary.load (memory_order_relaxed);
	if (--this->w_writers == 0)
	sum &= ~w_writer;
	}

	// Otherwise we can acquire the lock for write. As a writer, we have
	// priority, so we don't need to take this back.
	this->summary.store (sum \| a_writer, memory_order_relaxed);

	// We still need to wait for active readers to finish. The barrier makes
	// sure that we first set our write intent and check for active readers
	// after that, in strictly this order (similar to the barrier in the fast
	// path of read_lock()).
	atomic_thread_fence(memory_order_seq_cst);

	// Count the number of active readers to be able to decrease the number of
	// wake-ups and wait calls that are necessary.
	//
	// This number is an upper bound of the number of readers that actually
	// are still active and which we need to wait for:
	// - We set our write flag before checking the reader flags, and readers
	// check our write flag after clearing their read flags in read_unlock().
	// Therefore, they will enter the slow path whenever we have seen them.
	// - Readers will have cleared their read flags before leaving the slow
	// path in read_lock() (prevents lost wake-ups), and before waiting for
	// any writer (prevents deadlocks).
	//
	// However, this number is also just a lower bound of the number of readers
	// that will actually enter the slow path in read_unlock() or read_lock():
	// - Because the read flag is cleared outside of a critical section, writers
	// can see it as cleared while the reader still goes into the slow path.
	//
	// Therefore, readers can skip (lower bound - 1) wake-ups, but we do need
	// the following loop to check that the readers that we wanted to wait for
	// are actually those that entered the slow path so far (and either skipped
	// or sent a wake-up).
	//
	// ??? Do we need to optimize further? (The writer could publish a list of
	// readers that it suspects to be active. Readers could check this list and
	// only decrement a_readers if they are in this list.)
	for (;;)
	{
	// ??? Keep a list of active readers that we saw and update it on the
	// next retry instead? This might reduce the number of cache misses that
	// we get when checking reader flags.
	int readers = 0;
	for (gtm_thread *it = gtm_thread::list_of_threads; it != 0;
	it = it->next_thread)
	{
	// Don't count ourself if this is an upgrade.
	if (it == tx)
	continue;
	if (it->shared_state.load(memory_order_relaxed) != (gtm_word)-1)
	readers++;
	}

	// If we have not seen any readers, we will not wait.
	if (readers == 0)
	break;

	// If this is an upgrade, we have to break deadlocks with
	// privatization safety. This may fail on our side, in which
	// case we need to cancel our attempt to upgrade. Also, we do not
	// block using the convdar but just spin so that we never have to be
	// woken.
	// FIXME This is horribly inefficient -- but so is not being able
	// to use futexes in this case.
	if (tx != 0)
	{
	pthread_mutex_unlock (&this->mutex);
	if (!abi_disp ()->snapshot_most_recent ())
	{
	write_unlock ();
	return false;
	}
	pthread_mutex_lock (&this->mutex);
	continue;
	}


	// We've seen a number of readers, so we publish this number and wait.
	this->a_readers = readers;
	pthread_cond_wait (&this->c_confirmed_writers, &this->mutex);
	}

	pthread_mutex_unlock (&this->mutex);
	return true;
	}

	// Acquire a RW lock for writing.

	void
	gtm_rwlock::write_lock ()
	{
	write_lock_generic (0);
	}


	// Upgrade a RW lock that has been locked for reading to a writing lock.
	// Do this without possibility of another writer incoming. Return false
	// if this attempt fails (i.e. another thread also upgraded).

	bool
	gtm_rwlock::write_upgrade (gtm_thread *tx)
	{
	return write_lock_generic (tx);
	}


	// Has to be called iff the previous upgrade was successful and after it is
	// safe for the transaction to not be marked as a reader anymore.

	void
	gtm_rwlock::write_upgrade_finish (gtm_thread *tx)
	{
	// We are not a reader anymore. This is only safe to do after we have
	// acquired the writer lock.
	tx->shared_state.store (-1, memory_order_release);
	}


	// Release a RW lock from reading.

	void
	gtm_rwlock::read_unlock (gtm_thread *tx)
	{
	// We only need release memory order here because of privatization safety
	// (this ensures that marking the transaction as inactive happens after
	// any prior data accesses by this transaction, and that neither the
	// compiler nor the hardware order this store earlier).
	// ??? We might be able to avoid this release here if the compiler can't
	// merge the release fence with the subsequent seq_cst fence.
	tx->shared_state.store (-1, memory_order_release);
	// We need this seq_cst fence here to avoid lost wake-ups. Furthermore,
	// the privatization safety implementation in gtm_thread::try_commit()
	// relies on the existence of this seq_cst fence.
	atomic_thread_fence (memory_order_seq_cst);
	unsigned int sum = this->summary.load (memory_order_relaxed);
	if (likely(!(sum & (a_writer \| w_writer))))
	return;

	// There is a writer, either active or waiting for other readers or writers.
	// Thus, enter the mutex-based slow path.
	pthread_mutex_lock (&this->mutex);

	// If there is a writer waiting for readers, wake it up. Only do that if we
	// might be the last reader that could do the wake-up, otherwise skip the
	// wake-up and decrease a_readers to publish that we have entered the slow
	// path but skipped the wake-up.
	if (this->a_readers > 0)
	{
	this->a_readers--;
	if (this->a_readers == 0)
	pthread_cond_signal(&this->c_confirmed_writers);
	}

	// We don't need to wake up any writers waiting for other writers. Active
	// writers will take care of that.

	pthread_mutex_unlock (&this->mutex);
	}


	// Release a RW lock from writing.

	void
	gtm_rwlock::write_unlock ()
	{
	pthread_mutex_lock (&this->mutex);

	unsigned int sum = this->summary.load (memory_order_relaxed);
	this->summary.store (sum & ~a_writer, memory_order_relaxed);

	// If there is a waiting writer, wake it.
	if (unlikely (sum & w_writer))
	pthread_cond_signal (&this->c_writers);

	// If there are waiting readers, wake them.
	else if (unlikely (sum & w_reader))
	pthread_cond_broadcast (&this->c_readers);

	pthread_mutex_unlock (&this->mutex);
	}

	} // namespace GTM