util/rcu.c - qemu - Git at Google

 /*
  * urcu-mb.c
  *
  * Userspace RCU library with explicit memory barriers
  *
  * Copyright (c) 2009 Mathieu Desnoyers <mathieu.desnoyers@efficios.com>
  * Copyright (c) 2009 Paul E. McKenney, IBM Corporation.
  * Copyright 2015 Red Hat, Inc.
  *
  * Ported to QEMU by Paolo Bonzini  <pbonzini@redhat.com>
  *
  * This library is free software; you can redistribute it and/or
  * modify it under the terms of the GNU Lesser General Public
  * License as published by the Free Software Foundation; either
  * version 2.1 of the License, or (at your option) any later version.
  *
  * This library is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  * Lesser General Public License for more details.
  *
  * You should have received a copy of the GNU Lesser General Public
  * License along with this library; if not, write to the Free Software
  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
  *
  * IBM's contributions to this file may be relicensed under LGPLv2 or later.
  */

 #include "qemu/osdep.h"
 #include "qemu-common.h"
 #include "qemu/rcu.h"
 #include "qemu/atomic.h"
 #include "qemu/thread.h"
 #include "qemu/main-loop.h"

 /*
  * Global grace period counter.  Bit 0 is always one in rcu_gp_ctr.
  * Bits 1 and above are defined in synchronize_rcu.
  */
 #define RCU_GP_LOCKED           (1UL << 0)
 #define RCU_GP_CTR              (1UL << 1)

 unsigned long rcu_gp_ctr = RCU_GP_LOCKED;

 QemuEvent rcu_gp_event;
 static QemuMutex rcu_registry_lock;
 static QemuMutex rcu_sync_lock;

 /*
  * Check whether a quiescent state was crossed between the beginning of
  * update_counter_and_wait and now.
  */
 static inline int rcu_gp_ongoing(unsigned long *ctr)
 {
     unsigned long v;

     v = atomic_read(ctr);
     return v && (v != rcu_gp_ctr);
 }

 /* Written to only by each individual reader. Read by both the reader and the
  * writers.
  */
 __thread struct rcu_reader_data rcu_reader;

 /* Protected by rcu_registry_lock.  */
 typedef QLIST_HEAD(, rcu_reader_data) ThreadList;
 static ThreadList registry = QLIST_HEAD_INITIALIZER(registry);

 /* Wait for previous parity/grace period to be empty of readers.  */
 static void wait_for_readers(void)
 {
     ThreadList qsreaders = QLIST_HEAD_INITIALIZER(qsreaders);
     struct rcu_reader_data *index, *tmp;

     for (;;) {
         /* We want to be notified of changes made to rcu_gp_ongoing
          * while we walk the list.
          */
         qemu_event_reset(&rcu_gp_event);

         /* Instead of using atomic_mb_set for index->waiting, and
          * atomic_mb_read for index->ctr, memory barriers are placed
          * manually since writes to different threads are independent.
          * qemu_event_reset has acquire semantics, so no memory barrier
          * is needed here.
          */
         QLIST_FOREACH(index, &registry, node) {
             atomic_set(&index->waiting, true);
         }

         /* Here, order the stores to index->waiting before the
          * loads of index->ctr.
          */
         smp_mb();

         QLIST_FOREACH_SAFE(index, &registry, node, tmp) {
             if (!rcu_gp_ongoing(&index->ctr)) {
                 QLIST_REMOVE(index, node);
                 QLIST_INSERT_HEAD(&qsreaders, index, node);

                 /* No need for mb_set here, worst of all we
                  * get some extra futex wakeups.
                  */
                 atomic_set(&index->waiting, false);
             }
         }

         if (QLIST_EMPTY(&registry)) {
             break;
         }

         /* Wait for one thread to report a quiescent state and try again.
          * Release rcu_registry_lock, so rcu_(un)register_thread() doesn't
          * wait too much time.
          *
          * rcu_register_thread() may add nodes to &registry; it will not
          * wake up synchronize_rcu, but that is okay because at least another
          * thread must exit its RCU read-side critical section before
          * synchronize_rcu is done.  The next iteration of the loop will
          * move the new thread's rcu_reader from &registry to &qsreaders,
          * because rcu_gp_ongoing() will return false.
          *
          * rcu_unregister_thread() may remove nodes from &qsreaders instead
          * of &registry if it runs during qemu_event_wait.  That's okay;
          * the node then will not be added back to &registry by QLIST_SWAP
          * below.  The invariant is that the node is part of one list when
          * rcu_registry_lock is released.
          */
         qemu_mutex_unlock(&rcu_registry_lock);
         qemu_event_wait(&rcu_gp_event);
         qemu_mutex_lock(&rcu_registry_lock);
     }

     /* put back the reader list in the registry */
     QLIST_SWAP(&registry, &qsreaders, node);
 }

 void synchronize_rcu(void)
 {
     qemu_mutex_lock(&rcu_sync_lock);
     qemu_mutex_lock(&rcu_registry_lock);

     if (!QLIST_EMPTY(&registry)) {
         /* In either case, the atomic_mb_set below blocks stores that free
          * old RCU-protected pointers.
          */
         if (sizeof(rcu_gp_ctr) < 8) {
             /* For architectures with 32-bit longs, a two-subphases algorithm
              * ensures we do not encounter overflow bugs.
              *
              * Switch parity: 0 -> 1, 1 -> 0.
              */
             atomic_mb_set(&rcu_gp_ctr, rcu_gp_ctr ^ RCU_GP_CTR);
             wait_for_readers();
             atomic_mb_set(&rcu_gp_ctr, rcu_gp_ctr ^ RCU_GP_CTR);
         } else {
             /* Increment current grace period.  */
             atomic_mb_set(&rcu_gp_ctr, rcu_gp_ctr + RCU_GP_CTR);
         }

         wait_for_readers();
     }

     qemu_mutex_unlock(&rcu_registry_lock);
     qemu_mutex_unlock(&rcu_sync_lock);
 }


 #define RCU_CALL_MIN_SIZE        30

 /* Multi-producer, single-consumer queue based on urcu/static/wfqueue.h
  * from liburcu.  Note that head is only used by the consumer.
  */
 static struct rcu_head dummy;
 static struct rcu_head *head = &dummy, **tail = &dummy.next;
 static int rcu_call_count;
 static QemuEvent rcu_call_ready_event;

 static void enqueue(struct rcu_head *node)
 {
     struct rcu_head **old_tail;

     node->next = NULL;
     old_tail = atomic_xchg(&tail, &node->next);
     atomic_mb_set(old_tail, node);
 }

 static struct rcu_head *try_dequeue(void)
 {
     struct rcu_head *node, *next;

 retry:
     /* Test for an empty list, which we do not expect.  Note that for
      * the consumer head and tail are always consistent.  The head
      * is consistent because only the consumer reads/writes it.
      * The tail, because it is the first step in the enqueuing.
      * It is only the next pointers that might be inconsistent.
      */
     if (head == &dummy && atomic_mb_read(&tail) == &dummy.next) {
         abort();
     }

     /* If the head node has NULL in its next pointer, the value is
      * wrong and we need to wait until its enqueuer finishes the update.
      */
     node = head;
     next = atomic_mb_read(&head->next);
     if (!next) {
         return NULL;
     }

     /* Since we are the sole consumer, and we excluded the empty case
      * above, the queue will always have at least two nodes: the
      * dummy node, and the one being removed.  So we do not need to update
      * the tail pointer.
      */
     head = next;

     /* If we dequeued the dummy node, add it back at the end and retry.  */
     if (node == &dummy) {
         enqueue(node);
         goto retry;
     }

     return node;
 }

 static void *call_rcu_thread(void *opaque)
 {
     struct rcu_head *node;

     rcu_register_thread();

     for (;;) {
         int tries = 0;
         int n = atomic_read(&rcu_call_count);

         /* Heuristically wait for a decent number of callbacks to pile up.
          * Fetch rcu_call_count now, we only must process elements that were
          * added before synchronize_rcu() starts.
          */
         while (n == 0 || (n < RCU_CALL_MIN_SIZE && ++tries <= 5)) {
             g_usleep(10000);
             if (n == 0) {
                 qemu_event_reset(&rcu_call_ready_event);
                 n = atomic_read(&rcu_call_count);
                 if (n == 0) {
                     qemu_event_wait(&rcu_call_ready_event);
                 }
             }
             n = atomic_read(&rcu_call_count);
         }

         atomic_sub(&rcu_call_count, n);
         synchronize_rcu();
         qemu_mutex_lock_iothread();
         while (n > 0) {
             node = try_dequeue();
             while (!node) {
                 qemu_mutex_unlock_iothread();
                 qemu_event_reset(&rcu_call_ready_event);
                 node = try_dequeue();
                 if (!node) {
                     qemu_event_wait(&rcu_call_ready_event);
                     node = try_dequeue();
                 }
                 qemu_mutex_lock_iothread();
             }

             n--;
             node->func(node);
         }
         qemu_mutex_unlock_iothread();
     }
     abort();
 }

 void call_rcu1(struct rcu_head *node, void (*func)(struct rcu_head *node))
 {
     node->func = func;
     enqueue(node);
     atomic_inc(&rcu_call_count);
     qemu_event_set(&rcu_call_ready_event);
 }

 void rcu_register_thread(void)
 {
     assert(rcu_reader.ctr == 0);
     qemu_mutex_lock(&rcu_registry_lock);
     QLIST_INSERT_HEAD(&registry, &rcu_reader, node);
     qemu_mutex_unlock(&rcu_registry_lock);
 }

 void rcu_unregister_thread(void)
 {
     qemu_mutex_lock(&rcu_registry_lock);
     QLIST_REMOVE(&rcu_reader, node);
     qemu_mutex_unlock(&rcu_registry_lock);
 }

 static void rcu_init_complete(void)
 {
     QemuThread thread;

     qemu_mutex_init(&rcu_registry_lock);
     qemu_mutex_init(&rcu_sync_lock);
     qemu_event_init(&rcu_gp_event, true);

     qemu_event_init(&rcu_call_ready_event, false);

     /* The caller is assumed to have iothread lock, so the call_rcu thread
      * must have been quiescent even after forking, just recreate it.
      */
     qemu_thread_create(&thread, "call_rcu", call_rcu_thread,
                        NULL, QEMU_THREAD_DETACHED);

     rcu_register_thread();
 }

 #ifdef CONFIG_POSIX
 static void rcu_init_lock(void)
 {
     qemu_mutex_lock(&rcu_sync_lock);
     qemu_mutex_lock(&rcu_registry_lock);
 }

 static void rcu_init_unlock(void)
 {
     qemu_mutex_unlock(&rcu_registry_lock);
     qemu_mutex_unlock(&rcu_sync_lock);
 }
 #endif

 void rcu_after_fork(void)
 {
     memset(&registry, 0, sizeof(registry));
     rcu_init_complete();
 }

 static void __attribute__((__constructor__)) rcu_init(void)
 {
 #ifdef CONFIG_POSIX
     pthread_atfork(rcu_init_lock, rcu_init_unlock, rcu_init_unlock);
 #endif
     rcu_init_complete();
 }
	/*
	* urcu-mb.c
	*
	* Userspace RCU library with explicit memory barriers
	*
	* Copyright (c) 2009 Mathieu Desnoyers <mathieu.desnoyers@efficios.com>
	* Copyright (c) 2009 Paul E. McKenney, IBM Corporation.
	* Copyright 2015 Red Hat, Inc.
	*
	* Ported to QEMU by Paolo Bonzini <pbonzini@redhat.com>
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Lesser General Public
	* License as published by the Free Software Foundation; either
	* version 2.1 of the License, or (at your option) any later version.
	*
	* This library is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* Lesser General Public License for more details.
	*
	* You should have received a copy of the GNU Lesser General Public
	* License along with this library; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
	*
	* IBM's contributions to this file may be relicensed under LGPLv2 or later.
	*/

	#include "qemu/osdep.h"
	#include "qemu-common.h"
	#include "qemu/rcu.h"
	#include "qemu/atomic.h"
	#include "qemu/thread.h"
	#include "qemu/main-loop.h"

	/*
	* Global grace period counter. Bit 0 is always one in rcu_gp_ctr.
	* Bits 1 and above are defined in synchronize_rcu.
	*/
	#define RCU_GP_LOCKED (1UL << 0)
	#define RCU_GP_CTR (1UL << 1)

	unsigned long rcu_gp_ctr = RCU_GP_LOCKED;

	QemuEvent rcu_gp_event;
	static QemuMutex rcu_registry_lock;
	static QemuMutex rcu_sync_lock;

	/*
	* Check whether a quiescent state was crossed between the beginning of
	* update_counter_and_wait and now.
	*/
	static inline int rcu_gp_ongoing(unsigned long *ctr)
	{
	unsigned long v;

	v = atomic_read(ctr);
	return v && (v != rcu_gp_ctr);
	}

	/* Written to only by each individual reader. Read by both the reader and the
	* writers.
	*/
	__thread struct rcu_reader_data rcu_reader;

	/* Protected by rcu_registry_lock. */
	typedef QLIST_HEAD(, rcu_reader_data) ThreadList;
	static ThreadList registry = QLIST_HEAD_INITIALIZER(registry);

	/* Wait for previous parity/grace period to be empty of readers. */
	static void wait_for_readers(void)
	{
	ThreadList qsreaders = QLIST_HEAD_INITIALIZER(qsreaders);
	struct rcu_reader_data index, tmp;

	for (;;) {
	/* We want to be notified of changes made to rcu_gp_ongoing
	* while we walk the list.
	*/
	qemu_event_reset(&rcu_gp_event);

	/* Instead of using atomic_mb_set for index->waiting, and
	* atomic_mb_read for index->ctr, memory barriers are placed
	* manually since writes to different threads are independent.
	* qemu_event_reset has acquire semantics, so no memory barrier
	* is needed here.
	*/
	QLIST_FOREACH(index, &registry, node) {
	atomic_set(&index->waiting, true);
	}

	/* Here, order the stores to index->waiting before the
	* loads of index->ctr.
	*/
	smp_mb();

	QLIST_FOREACH_SAFE(index, &registry, node, tmp) {
	if (!rcu_gp_ongoing(&index->ctr)) {
	QLIST_REMOVE(index, node);
	QLIST_INSERT_HEAD(&qsreaders, index, node);

	/* No need for mb_set here, worst of all we
	* get some extra futex wakeups.
	*/
	atomic_set(&index->waiting, false);
	}
	}

	if (QLIST_EMPTY(&registry)) {
	break;
	}

	/* Wait for one thread to report a quiescent state and try again.
	* Release rcu_registry_lock, so rcu_(un)register_thread() doesn't
	* wait too much time.
	*
	* rcu_register_thread() may add nodes to &registry; it will not
	* wake up synchronize_rcu, but that is okay because at least another
	* thread must exit its RCU read-side critical section before
	* synchronize_rcu is done. The next iteration of the loop will
	* move the new thread's rcu_reader from &registry to &qsreaders,
	* because rcu_gp_ongoing() will return false.
	*
	* rcu_unregister_thread() may remove nodes from &qsreaders instead
	* of &registry if it runs during qemu_event_wait. That's okay;
	* the node then will not be added back to &registry by QLIST_SWAP
	* below. The invariant is that the node is part of one list when
	* rcu_registry_lock is released.
	*/
	qemu_mutex_unlock(&rcu_registry_lock);
	qemu_event_wait(&rcu_gp_event);
	qemu_mutex_lock(&rcu_registry_lock);
	}

	/* put back the reader list in the registry */
	QLIST_SWAP(&registry, &qsreaders, node);
	}

	void synchronize_rcu(void)
	{
	qemu_mutex_lock(&rcu_sync_lock);
	qemu_mutex_lock(&rcu_registry_lock);

	if (!QLIST_EMPTY(&registry)) {
	/* In either case, the atomic_mb_set below blocks stores that free
	* old RCU-protected pointers.
	*/
	if (sizeof(rcu_gp_ctr) < 8) {
	/* For architectures with 32-bit longs, a two-subphases algorithm
	* ensures we do not encounter overflow bugs.
	*
	* Switch parity: 0 -> 1, 1 -> 0.
	*/
	atomic_mb_set(&rcu_gp_ctr, rcu_gp_ctr ^ RCU_GP_CTR);
	wait_for_readers();
	atomic_mb_set(&rcu_gp_ctr, rcu_gp_ctr ^ RCU_GP_CTR);
	} else {
	/* Increment current grace period. */
	atomic_mb_set(&rcu_gp_ctr, rcu_gp_ctr + RCU_GP_CTR);
	}

	wait_for_readers();
	}

	qemu_mutex_unlock(&rcu_registry_lock);
	qemu_mutex_unlock(&rcu_sync_lock);
	}


	#define RCU_CALL_MIN_SIZE 30

	/* Multi-producer, single-consumer queue based on urcu/static/wfqueue.h
	* from liburcu. Note that head is only used by the consumer.
	*/
	static struct rcu_head dummy;
	static struct rcu_head head = &dummy, *tail = &dummy.next;
	static int rcu_call_count;
	static QemuEvent rcu_call_ready_event;

	static void enqueue(struct rcu_head *node)
	{
	struct rcu_head **old_tail;

	node->next = NULL;
	old_tail = atomic_xchg(&tail, &node->next);
	atomic_mb_set(old_tail, node);
	}

	static struct rcu_head *try_dequeue(void)
	{
	struct rcu_head node, next;

	retry:
	/* Test for an empty list, which we do not expect. Note that for
	* the consumer head and tail are always consistent. The head
	* is consistent because only the consumer reads/writes it.
	* The tail, because it is the first step in the enqueuing.
	* It is only the next pointers that might be inconsistent.
	*/
	if (head == &dummy && atomic_mb_read(&tail) == &dummy.next) {
	abort();
	}

	/* If the head node has NULL in its next pointer, the value is
	* wrong and we need to wait until its enqueuer finishes the update.
	*/
	node = head;
	next = atomic_mb_read(&head->next);
	if (!next) {
	return NULL;
	}

	/* Since we are the sole consumer, and we excluded the empty case
	* above, the queue will always have at least two nodes: the
	* dummy node, and the one being removed. So we do not need to update
	* the tail pointer.
	*/
	head = next;

	/* If we dequeued the dummy node, add it back at the end and retry. */
	if (node == &dummy) {
	enqueue(node);
	goto retry;
	}

	return node;
	}

	static void call_rcu_thread(void opaque)
	{
	struct rcu_head *node;

	rcu_register_thread();

	for (;;) {
	int tries = 0;
	int n = atomic_read(&rcu_call_count);

	/* Heuristically wait for a decent number of callbacks to pile up.
	* Fetch rcu_call_count now, we only must process elements that were
	* added before synchronize_rcu() starts.
	*/
	while (n == 0 \|\| (n < RCU_CALL_MIN_SIZE && ++tries <= 5)) {
	g_usleep(10000);
	if (n == 0) {
	qemu_event_reset(&rcu_call_ready_event);
	n = atomic_read(&rcu_call_count);
	if (n == 0) {
	qemu_event_wait(&rcu_call_ready_event);
	}
	}
	n = atomic_read(&rcu_call_count);
	}

	atomic_sub(&rcu_call_count, n);
	synchronize_rcu();
	qemu_mutex_lock_iothread();
	while (n > 0) {
	node = try_dequeue();
	while (!node) {
	qemu_mutex_unlock_iothread();
	qemu_event_reset(&rcu_call_ready_event);
	node = try_dequeue();
	if (!node) {
	qemu_event_wait(&rcu_call_ready_event);
	node = try_dequeue();
	}
	qemu_mutex_lock_iothread();
	}

	n--;
	node->func(node);
	}
	qemu_mutex_unlock_iothread();
	}
	abort();
	}

	void call_rcu1(struct rcu_head node, void (func)(struct rcu_head *node))
	{
	node->func = func;
	enqueue(node);
	atomic_inc(&rcu_call_count);
	qemu_event_set(&rcu_call_ready_event);
	}

	void rcu_register_thread(void)
	{
	assert(rcu_reader.ctr == 0);
	qemu_mutex_lock(&rcu_registry_lock);
	QLIST_INSERT_HEAD(&registry, &rcu_reader, node);
	qemu_mutex_unlock(&rcu_registry_lock);
	}

	void rcu_unregister_thread(void)
	{
	qemu_mutex_lock(&rcu_registry_lock);
	QLIST_REMOVE(&rcu_reader, node);
	qemu_mutex_unlock(&rcu_registry_lock);
	}

	static void rcu_init_complete(void)
	{
	QemuThread thread;

	qemu_mutex_init(&rcu_registry_lock);
	qemu_mutex_init(&rcu_sync_lock);
	qemu_event_init(&rcu_gp_event, true);

	qemu_event_init(&rcu_call_ready_event, false);

	/* The caller is assumed to have iothread lock, so the call_rcu thread
	* must have been quiescent even after forking, just recreate it.
	*/
	qemu_thread_create(&thread, "call_rcu", call_rcu_thread,
	NULL, QEMU_THREAD_DETACHED);

	rcu_register_thread();
	}

	#ifdef CONFIG_POSIX
	static void rcu_init_lock(void)
	{
	qemu_mutex_lock(&rcu_sync_lock);
	qemu_mutex_lock(&rcu_registry_lock);
	}

	static void rcu_init_unlock(void)
	{
	qemu_mutex_unlock(&rcu_registry_lock);
	qemu_mutex_unlock(&rcu_sync_lock);
	}
	#endif

	void rcu_after_fork(void)
	{
	memset(&registry, 0, sizeof(registry));
	rcu_init_complete();
	}

	static void __attribute__((__constructor__)) rcu_init(void)
	{
	#ifdef CONFIG_POSIX
	pthread_atfork(rcu_init_lock, rcu_init_unlock, rcu_init_unlock);
	#endif
	rcu_init_complete();
	}