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With the addition of the thread specific data interfaces to the SPL it is safe to enable compilation of the re-enterant read reader/writer locks.
265 lines
7.5 KiB
C
265 lines
7.5 KiB
C
/*
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* CDDL HEADER START
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*
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* The contents of this file are subject to the terms of the
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* Common Development and Distribution License (the "License").
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* You may not use this file except in compliance with the License.
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*
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* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
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* or http://www.opensolaris.org/os/licensing.
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* See the License for the specific language governing permissions
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* and limitations under the License.
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*
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* When distributing Covered Code, include this CDDL HEADER in each
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* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
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* If applicable, add the following below this CDDL HEADER, with the
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* fields enclosed by brackets "[]" replaced with your own identifying
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* information: Portions Copyright [yyyy] [name of copyright owner]
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*
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* CDDL HEADER END
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*/
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/*
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* Copyright 2009 Sun Microsystems, Inc. All rights reserved.
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* Use is subject to license terms.
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*/
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#include <sys/refcount.h>
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#include <sys/rrwlock.h>
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/*
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* This file contains the implementation of a re-entrant read
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* reader/writer lock (aka "rrwlock").
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*
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* This is a normal reader/writer lock with the additional feature
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* of allowing threads who have already obtained a read lock to
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* re-enter another read lock (re-entrant read) - even if there are
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* waiting writers.
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*
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* Callers who have not obtained a read lock give waiting writers priority.
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*
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* The rrwlock_t lock does not allow re-entrant writers, nor does it
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* allow a re-entrant mix of reads and writes (that is, it does not
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* allow a caller who has already obtained a read lock to be able to
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* then grab a write lock without first dropping all read locks, and
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* vice versa).
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*
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* The rrwlock_t uses tsd (thread specific data) to keep a list of
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* nodes (rrw_node_t), where each node keeps track of which specific
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* lock (rrw_node_t::rn_rrl) the thread has grabbed. Since re-entering
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* should be rare, a thread that grabs multiple reads on the same rrwlock_t
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* will store multiple rrw_node_ts of the same 'rrn_rrl'. Nodes on the
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* tsd list can represent a different rrwlock_t. This allows a thread
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* to enter multiple and unique rrwlock_ts for read locks at the same time.
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*
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* Since using tsd exposes some overhead, the rrwlock_t only needs to
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* keep tsd data when writers are waiting. If no writers are waiting, then
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* a reader just bumps the anonymous read count (rr_anon_rcount) - no tsd
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* is needed. Once a writer attempts to grab the lock, readers then
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* keep tsd data and bump the linked readers count (rr_linked_rcount).
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*
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* If there are waiting writers and there are anonymous readers, then a
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* reader doesn't know if it is a re-entrant lock. But since it may be one,
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* we allow the read to proceed (otherwise it could deadlock). Since once
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* waiting writers are active, readers no longer bump the anonymous count,
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* the anonymous readers will eventually flush themselves out. At this point,
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* readers will be able to tell if they are a re-entrant lock (have a
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* rrw_node_t entry for the lock) or not. If they are a re-entrant lock, then
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* we must let the proceed. If they are not, then the reader blocks for the
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* waiting writers. Hence, we do not starve writers.
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*/
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/* global key for TSD */
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uint_t rrw_tsd_key;
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typedef struct rrw_node {
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struct rrw_node *rn_next;
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rrwlock_t *rn_rrl;
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} rrw_node_t;
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static rrw_node_t *
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rrn_find(rrwlock_t *rrl)
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{
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rrw_node_t *rn;
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if (refcount_count(&rrl->rr_linked_rcount) == 0)
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return (NULL);
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for (rn = tsd_get(rrw_tsd_key); rn != NULL; rn = rn->rn_next) {
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if (rn->rn_rrl == rrl)
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return (rn);
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}
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return (NULL);
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}
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/*
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* Add a node to the head of the singly linked list.
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*/
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static void
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rrn_add(rrwlock_t *rrl)
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{
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rrw_node_t *rn;
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rn = kmem_alloc(sizeof (*rn), KM_SLEEP);
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rn->rn_rrl = rrl;
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rn->rn_next = tsd_get(rrw_tsd_key);
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VERIFY(tsd_set(rrw_tsd_key, rn) == 0);
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}
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/*
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* If a node is found for 'rrl', then remove the node from this
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* thread's list and return TRUE; otherwise return FALSE.
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*/
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static boolean_t
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rrn_find_and_remove(rrwlock_t *rrl)
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{
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rrw_node_t *rn;
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rrw_node_t *prev = NULL;
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if (refcount_count(&rrl->rr_linked_rcount) == 0)
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return (B_FALSE);
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for (rn = tsd_get(rrw_tsd_key); rn != NULL; rn = rn->rn_next) {
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if (rn->rn_rrl == rrl) {
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if (prev)
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prev->rn_next = rn->rn_next;
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else
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VERIFY(tsd_set(rrw_tsd_key, rn->rn_next) == 0);
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kmem_free(rn, sizeof (*rn));
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return (B_TRUE);
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}
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prev = rn;
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}
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return (B_FALSE);
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}
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void
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rrw_init(rrwlock_t *rrl)
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{
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mutex_init(&rrl->rr_lock, NULL, MUTEX_DEFAULT, NULL);
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cv_init(&rrl->rr_cv, NULL, CV_DEFAULT, NULL);
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rrl->rr_writer = NULL;
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refcount_create(&rrl->rr_anon_rcount);
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refcount_create(&rrl->rr_linked_rcount);
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rrl->rr_writer_wanted = B_FALSE;
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}
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void
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rrw_destroy(rrwlock_t *rrl)
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{
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mutex_destroy(&rrl->rr_lock);
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cv_destroy(&rrl->rr_cv);
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ASSERT(rrl->rr_writer == NULL);
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refcount_destroy(&rrl->rr_anon_rcount);
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refcount_destroy(&rrl->rr_linked_rcount);
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}
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static void
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rrw_enter_read(rrwlock_t *rrl, void *tag)
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{
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mutex_enter(&rrl->rr_lock);
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#if !defined(DEBUG) && defined(_KERNEL)
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if (!rrl->rr_writer && !rrl->rr_writer_wanted) {
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rrl->rr_anon_rcount.rc_count++;
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mutex_exit(&rrl->rr_lock);
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return;
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}
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DTRACE_PROBE(zfs__rrwfastpath__rdmiss);
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#endif
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ASSERT(rrl->rr_writer != curthread);
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ASSERT(refcount_count(&rrl->rr_anon_rcount) >= 0);
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while (rrl->rr_writer || (rrl->rr_writer_wanted &&
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refcount_is_zero(&rrl->rr_anon_rcount) &&
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rrn_find(rrl) == NULL))
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cv_wait(&rrl->rr_cv, &rrl->rr_lock);
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if (rrl->rr_writer_wanted) {
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/* may or may not be a re-entrant enter */
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rrn_add(rrl);
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(void) refcount_add(&rrl->rr_linked_rcount, tag);
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} else {
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(void) refcount_add(&rrl->rr_anon_rcount, tag);
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}
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ASSERT(rrl->rr_writer == NULL);
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mutex_exit(&rrl->rr_lock);
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}
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static void
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rrw_enter_write(rrwlock_t *rrl)
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{
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mutex_enter(&rrl->rr_lock);
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ASSERT(rrl->rr_writer != curthread);
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while (refcount_count(&rrl->rr_anon_rcount) > 0 ||
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refcount_count(&rrl->rr_linked_rcount) > 0 ||
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rrl->rr_writer != NULL) {
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rrl->rr_writer_wanted = B_TRUE;
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cv_wait(&rrl->rr_cv, &rrl->rr_lock);
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}
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rrl->rr_writer_wanted = B_FALSE;
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rrl->rr_writer = curthread;
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mutex_exit(&rrl->rr_lock);
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}
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void
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rrw_enter(rrwlock_t *rrl, krw_t rw, void *tag)
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{
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if (rw == RW_READER)
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rrw_enter_read(rrl, tag);
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else
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rrw_enter_write(rrl);
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}
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void
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rrw_exit(rrwlock_t *rrl, void *tag)
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{
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mutex_enter(&rrl->rr_lock);
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#if !defined(DEBUG) && defined(_KERNEL)
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if (!rrl->rr_writer && rrl->rr_linked_rcount.rc_count == 0) {
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rrl->rr_anon_rcount.rc_count--;
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if (rrl->rr_anon_rcount.rc_count == 0)
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cv_broadcast(&rrl->rr_cv);
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mutex_exit(&rrl->rr_lock);
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return;
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}
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DTRACE_PROBE(zfs__rrwfastpath__exitmiss);
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#endif
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ASSERT(!refcount_is_zero(&rrl->rr_anon_rcount) ||
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!refcount_is_zero(&rrl->rr_linked_rcount) ||
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rrl->rr_writer != NULL);
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if (rrl->rr_writer == NULL) {
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int64_t count;
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if (rrn_find_and_remove(rrl))
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count = refcount_remove(&rrl->rr_linked_rcount, tag);
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else
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count = refcount_remove(&rrl->rr_anon_rcount, tag);
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if (count == 0)
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cv_broadcast(&rrl->rr_cv);
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} else {
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ASSERT(rrl->rr_writer == curthread);
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ASSERT(refcount_is_zero(&rrl->rr_anon_rcount) &&
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refcount_is_zero(&rrl->rr_linked_rcount));
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rrl->rr_writer = NULL;
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cv_broadcast(&rrl->rr_cv);
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}
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mutex_exit(&rrl->rr_lock);
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}
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boolean_t
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rrw_held(rrwlock_t *rrl, krw_t rw)
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{
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boolean_t held;
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mutex_enter(&rrl->rr_lock);
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if (rw == RW_WRITER) {
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held = (rrl->rr_writer == curthread);
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} else {
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held = (!refcount_is_zero(&rrl->rr_anon_rcount) ||
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!refcount_is_zero(&rrl->rr_linked_rcount));
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}
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mutex_exit(&rrl->rr_lock);
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return (held);
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}
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