sys/kern/kern_rwlock.c

1.4  yamt /*	$NetBSD: kern_rwlock.c,v 1.4 2007/02/26 09:20:53 yamt Exp $	*/
1.2    ad
1.2    ad /*-
1.2    ad  * Copyright (c) 2002, 2006, 2007 The NetBSD Foundation, Inc.
1.2    ad  * All rights reserved.
1.2    ad  *
1.2    ad  * This code is derived from software contributed to The NetBSD Foundation
1.2    ad  * by Jason R. Thorpe and Andrew Doran.
1.2    ad  *
1.2    ad  * Redistribution and use in source and binary forms, with or without
1.2    ad  * modification, are permitted provided that the following conditions
1.2    ad  * are met:
1.2    ad  * 1. Redistributions of source code must retain the above copyright
1.2    ad  *    notice, this list of conditions and the following disclaimer.
1.2    ad  * 2. Redistributions in binary form must reproduce the above copyright
1.2    ad  *    notice, this list of conditions and the following disclaimer in the
1.2    ad  *    documentation and/or other materials provided with the distribution.
1.2    ad  * 3. All advertising materials mentioning features or use of this software
1.2    ad  *    must display the following acknowledgement:
1.2    ad  *	This product includes software developed by the NetBSD
1.2    ad  *	Foundation, Inc. and its contributors.
1.2    ad  * 4. Neither the name of The NetBSD Foundation nor the names of its
1.2    ad  *    contributors may be used to endorse or promote products derived
1.2    ad  *    from this software without specific prior written permission.
1.2    ad  *
1.2    ad  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
1.2    ad  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.2    ad  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.2    ad  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
1.2    ad  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.2    ad  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.2    ad  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.2    ad  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.2    ad  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.2    ad  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.2    ad  * POSSIBILITY OF SUCH DAMAGE.
1.2    ad  */
1.2    ad
1.2    ad /*
1.2    ad  * Kernel reader/writer lock implementation, modeled after those
1.2    ad  * found in Solaris, a description of which can be found in:
1.2    ad  *
1.2    ad  *	Solaris Internals: Core Kernel Architecture, Jim Mauro and
1.2    ad  *	    Richard McDougall.
1.2    ad  */
1.2    ad
1.2    ad #include "opt_multiprocessor.h"
1.2    ad
1.2    ad #include <sys/cdefs.h>
1.4  yamt __KERNEL_RCSID(0, "$NetBSD: kern_rwlock.c,v 1.4 2007/02/26 09:20:53 yamt Exp $");
1.2    ad
1.2    ad #define	__RWLOCK_PRIVATE
1.2    ad
1.2    ad #include <sys/param.h>
1.2    ad #include <sys/proc.h>
1.2    ad #include <sys/rwlock.h>
1.2    ad #include <sys/sched.h>
1.2    ad #include <sys/sleepq.h>
1.2    ad #include <sys/systm.h>
1.2    ad #include <sys/lockdebug.h>
1.2    ad
1.2    ad #include <dev/lockstat.h>
1.2    ad
1.2    ad #define RW_ABORT(rw, msg)						\
1.2    ad     LOCKDEBUG_ABORT(RW_GETID(rw), rw, &rwlock_lockops, __FUNCTION__, msg)
1.2    ad
1.2    ad /*
1.2    ad  * LOCKDEBUG
1.2    ad  */
1.2    ad
1.2    ad #if defined(LOCKDEBUG)
1.2    ad
1.2    ad #define	RW_WANTLOCK(rw, op)						\
1.2    ad 	LOCKDEBUG_WANTLOCK(RW_GETID(rw),				\
1.2    ad 	    (uintptr_t)__builtin_return_address(0), op == RW_READER);
1.2    ad #define	RW_LOCKED(rw, op)						\
1.2    ad 	LOCKDEBUG_LOCKED(RW_GETID(rw),					\
1.2    ad 	    (uintptr_t)__builtin_return_address(0), op == RW_READER);
1.2    ad #define	RW_UNLOCKED(rw, op)						\
1.2    ad 	LOCKDEBUG_UNLOCKED(RW_GETID(rw),				\
1.2    ad 	    (uintptr_t)__builtin_return_address(0), op == RW_READER);
1.2    ad #define	RW_DASSERT(rw, cond)						\
1.2    ad do {									\
1.2    ad 	if (!(cond))							\
1.2    ad 		RW_ABORT(rw, "assertion failed: " #cond);		\
1.2    ad } while (/* CONSTCOND */ 0);
1.2    ad
1.2    ad #else	/* LOCKDEBUG */
1.2    ad
1.2    ad #define	RW_WANTLOCK(rw, op)	/* nothing */
1.2    ad #define	RW_LOCKED(rw, op)	/* nothing */
1.2    ad #define	RW_UNLOCKED(rw, op)	/* nothing */
1.2    ad #define	RW_DASSERT(rw, cond)	/* nothing */
1.2    ad
1.2    ad #endif	/* LOCKDEBUG */
1.2    ad
1.2    ad /*
1.2    ad  * DIAGNOSTIC
1.2    ad  */
1.2    ad
1.2    ad #if defined(DIAGNOSTIC)
1.2    ad
1.2    ad #define	RW_ASSERT(rw, cond)						\
1.2    ad do {									\
1.2    ad 	if (!(cond))							\
1.2    ad 		RW_ABORT(rw, "assertion failed: " #cond);		\
1.2    ad } while (/* CONSTCOND */ 0)
1.2    ad
1.2    ad #else
1.2    ad
1.2    ad #define	RW_ASSERT(rw, cond)	/* nothing */
1.2    ad
1.2    ad #endif	/* DIAGNOSTIC */
1.2    ad
1.2    ad /*
1.2    ad  * For platforms that use 'simple' RW locks.
1.2    ad  */
1.2    ad #ifdef __HAVE_SIMPLE_RW_LOCKS
1.2    ad #define	RW_ACQUIRE(rw, old, new)	RW_CAS(&(rw)->rw_owner, old, new)
1.2    ad #define	RW_RELEASE(rw, old, new)	RW_CAS(&(rw)->rw_owner, old, new)
1.2    ad #define	RW_SETID(rw, id)		((rw)->rw_id = id)
1.2    ad #define	RW_GETID(rw)			((rw)->rw_id)
1.2    ad
1.2    ad static inline int
1.2    ad RW_SET_WAITERS(krwlock_t *rw, uintptr_t need, uintptr_t set)
1.2    ad {
1.2    ad 	uintptr_t old;
1.2    ad
1.2    ad 	if (((old = rw->rw_owner) & need) == 0)
1.2    ad 		return 0;
1.2    ad 	return RW_CAS(&rw->rw_owner, old, old | set);
1.2    ad }
1.2    ad #endif	/* __HAVE_SIMPLE_RW_LOCKS */
1.2    ad
1.2    ad /*
1.2    ad  * For platforms that do not provide stubs, or for the LOCKDEBUG case.
1.2    ad  */
1.2    ad #ifdef LOCKDEBUG
1.2    ad #undef	__HAVE_RW_STUBS
1.2    ad #endif
1.2    ad
1.2    ad #ifndef __HAVE_RW_STUBS
1.2    ad __strong_alias(rw_enter, rw_vector_enter);
1.2    ad __strong_alias(rw_exit, rw_vector_exit);
1.2    ad #endif
1.2    ad
1.2    ad void	rw_dump(volatile void *);
1.4  yamt static struct lwp *rw_owner(wchan_t);
1.2    ad
1.2    ad lockops_t rwlock_lockops = {
1.2    ad 	"Reader / writer lock",
1.2    ad 	1,
1.2    ad 	rw_dump
1.2    ad };
1.2    ad
1.4  yamt syncobj_t rw_syncobj = {
1.4  yamt 	SOBJ_SLEEPQ_SORTED,
1.4  yamt 	turnstile_unsleep,
1.4  yamt 	turnstile_changepri,
1.4  yamt 	sleepq_lendpri,
1.4  yamt 	rw_owner,
1.4  yamt };
1.4  yamt
1.2    ad /*
1.2    ad  * rw_dump:
1.2    ad  *
1.2    ad  *	Dump the contents of a rwlock structure.
1.2    ad  */
1.2    ad void
1.2    ad rw_dump(volatile void *cookie)
1.2    ad {
1.2    ad 	volatile krwlock_t *rw = cookie;
1.2    ad
1.2    ad 	printf_nolog("owner/count  : %#018lx flags    : %#018x\n",
1.2    ad 	    (long)RW_OWNER(rw), (int)RW_FLAGS(rw));
1.2    ad }
1.2    ad
1.2    ad /*
1.2    ad  * rw_init:
1.2    ad  *
1.2    ad  *	Initialize a rwlock for use.
1.2    ad  */
1.2    ad void
1.2    ad rw_init(krwlock_t *rw)
1.2    ad {
1.2    ad 	u_int id;
1.2    ad
1.2    ad 	memset(rw, 0, sizeof(*rw));
1.2    ad
1.2    ad 	id = LOCKDEBUG_ALLOC(rw, &rwlock_lockops);
1.2    ad 	RW_SETID(rw, id);
1.2    ad }
1.2    ad
1.2    ad /*
1.2    ad  * rw_destroy:
1.2    ad  *
1.2    ad  *	Tear down a rwlock.
1.2    ad  */
1.2    ad void
1.2    ad rw_destroy(krwlock_t *rw)
1.2    ad {
1.2    ad
1.2    ad 	LOCKDEBUG_FREE(rw, RW_GETID(rw));
1.2    ad 	RW_ASSERT(rw, rw->rw_owner == 0);
1.2    ad }
1.2    ad
1.2    ad /*
1.2    ad  * rw_vector_enter:
1.2    ad  *
1.2    ad  *	Acquire a rwlock.
1.2    ad  */
1.2    ad void
1.2    ad rw_vector_enter(krwlock_t *rw, const krw_t op)
1.2    ad {
1.2    ad 	uintptr_t owner, incr, need_wait, set_wait, curthread;
1.2    ad 	turnstile_t *ts;
1.2    ad 	int queue;
1.2    ad 	struct lwp *l;
1.2    ad 	LOCKSTAT_TIMER(slptime);
1.2    ad 	LOCKSTAT_FLAG(lsflag);
1.2    ad
1.2    ad 	l = curlwp;
1.2    ad 	curthread = (uintptr_t)l;
1.2    ad
1.2    ad 	RW_ASSERT(rw, curthread != 0);
1.2    ad 	RW_WANTLOCK(rw, op);
1.2    ad
1.2    ad #ifdef LOCKDEBUG
1.2    ad 	if (panicstr == NULL) {
1.2    ad 		simple_lock_only_held(NULL, "rw_enter");
1.2    ad #ifdef MULTIPROCESSOR
1.2    ad 		LOCKDEBUG_BARRIER(&kernel_lock, 1);
1.2    ad #else
1.2    ad 		LOCKDEBUG_BARRIER(NULL, 1);
1.2    ad #endif
1.2    ad 	}
1.2    ad #endif
1.2    ad
1.2    ad 	/*
1.2    ad 	 * We play a slight trick here.  If we're a reader, we want
1.2    ad 	 * increment the read count.  If we're a writer, we want to
1.2    ad 	 * set the owner field and whe WRITE_LOCKED bit.
1.2    ad 	 *
1.2    ad 	 * In the latter case, we expect those bits to be zero,
1.2    ad 	 * therefore we can use an add operation to set them, which
1.2    ad 	 * means an add operation for both cases.
1.2    ad 	 */
1.2    ad 	if (__predict_true(op == RW_READER)) {
1.2    ad 		incr = RW_READ_INCR;
1.2    ad 		set_wait = RW_HAS_WAITERS;
1.2    ad 		need_wait = RW_WRITE_LOCKED | RW_WRITE_WANTED;
1.2    ad 		queue = TS_READER_Q;
1.2    ad 	} else {
1.2    ad 		RW_DASSERT(rw, op == RW_WRITER);
1.2    ad 		incr = curthread | RW_WRITE_LOCKED;
1.2    ad 		set_wait = RW_HAS_WAITERS | RW_WRITE_WANTED;
1.2    ad 		need_wait = RW_WRITE_LOCKED | RW_THREAD;
1.2    ad 		queue = TS_WRITER_Q;
1.2    ad 	}
1.2    ad
1.2    ad 	LOCKSTAT_ENTER(lsflag);
1.2    ad
1.2    ad 	for (;;) {
1.2    ad 		/*
1.2    ad 		 * Read the lock owner field.  If the need-to-wait
1.2    ad 		 * indicator is clear, then try to acquire the lock.
1.2    ad 		 */
1.2    ad 		owner = rw->rw_owner;
1.2    ad 		if ((owner & need_wait) == 0) {
1.2    ad 			if (RW_ACQUIRE(rw, owner, owner + incr)) {
1.2    ad 				/* Got it! */
1.2    ad 				break;
1.2    ad 			}
1.2    ad
1.2    ad 			/*
1.2    ad 			 * Didn't get it -- spin around again (we'll
1.2    ad 			 * probably sleep on the next iteration).
1.2    ad 			 */
1.2    ad 			continue;
1.2    ad 		}
1.2    ad
1.2    ad 		if (panicstr != NULL)
1.2    ad 			return;
1.2    ad 		if (RW_OWNER(rw) == curthread)
1.2    ad 			RW_ABORT(rw, "locking against myself");
1.2    ad
1.2    ad 		/*
1.2    ad 		 * Grab the turnstile chain lock.  Once we have that, we
1.2    ad 		 * can adjust the waiter bits and sleep queue.
1.2    ad 		 */
1.2    ad 		ts = turnstile_lookup(rw);
1.2    ad
1.2    ad 		/*
1.2    ad 		 * XXXSMP if this is a high priority LWP (interrupt handler
1.2    ad 		 * or realtime) and acquiring a read hold, then we shouldn't
1.2    ad 		 * wait for RW_WRITE_WANTED if our priority is >= that of
1.2    ad 		 * the highest priority writer that is waiting.
1.2    ad 		 */
1.2    ad
1.2    ad 		/*
1.2    ad 		 * Mark the rwlock as having waiters.  If the set fails,
1.2    ad 		 * then we may not need to sleep and should spin again.
1.2    ad 		 */
1.2    ad 		if (!RW_SET_WAITERS(rw, need_wait, set_wait)) {
1.2    ad 			turnstile_exit(rw);
1.2    ad 			continue;
1.2    ad 		}
1.2    ad
1.2    ad 		LOCKSTAT_START_TIMER(lsflag, slptime);
1.2    ad
1.4  yamt 		turnstile_block(ts, queue, rw, &rw_syncobj);
1.2    ad
1.2    ad 		/* If we wake up and arrive here, we've been handed the lock. */
1.2    ad 		RW_RECEIVE(rw);
1.2    ad
1.2    ad 		LOCKSTAT_STOP_TIMER(lsflag, slptime);
1.2    ad 		LOCKSTAT_EVENT(lsflag, rw,
1.2    ad 		    LB_RWLOCK | (op == RW_WRITER ? LB_SLEEP1 : LB_SLEEP2),
1.2    ad 		    1, slptime);
1.2    ad
1.2    ad 		turnstile_unblock();
1.2    ad 		break;
1.2    ad 	}
1.2    ad
1.2    ad 	LOCKSTAT_EXIT(lsflag);
1.2    ad
1.2    ad 	RW_DASSERT(rw, (op != RW_READER && RW_OWNER(rw) == curthread) ||
1.2    ad 	    (op == RW_READER && RW_COUNT(rw) != 0));
1.2    ad 	RW_LOCKED(rw, op);
1.2    ad }
1.2    ad
1.2    ad /*
1.2    ad  * rw_vector_exit:
1.2    ad  *
1.2    ad  *	Release a rwlock.
1.2    ad  */
1.2    ad void
1.2    ad rw_vector_exit(krwlock_t *rw)
1.2    ad {
1.2    ad 	uintptr_t curthread, owner, decr, new;
1.2    ad 	turnstile_t *ts;
1.2    ad 	int rcnt, wcnt;
1.2    ad 	struct lwp *l;
1.2    ad
1.2    ad 	curthread = (uintptr_t)curlwp;
1.2    ad 	RW_ASSERT(rw, curthread != 0);
1.2    ad
1.2    ad 	if (panicstr != NULL) {
1.2    ad 		/*
1.2    ad 		 * XXX What's the correct thing to do here?  We should at
1.2    ad 		 * least release the lock.
1.2    ad 		 */
1.2    ad 		return;
1.2    ad 	}
1.2    ad
1.2    ad 	/*
1.2    ad 	 * Again, we use a trick.  Since we used an add operation to
1.2    ad 	 * set the required lock bits, we can use a subtract to clear
1.2    ad 	 * them, which makes the read-release and write-release path
1.2    ad 	 * the same.
1.2    ad 	 */
1.2    ad 	owner = rw->rw_owner;
1.2    ad 	if (__predict_false((owner & RW_WRITE_LOCKED) != 0)) {
1.2    ad 		RW_UNLOCKED(rw, RW_WRITER);
1.2    ad 		RW_DASSERT(rw, (rw->rw_owner & RW_WRITE_LOCKED) != 0);
1.2    ad 		RW_ASSERT(rw, RW_OWNER(rw) == curthread);
1.2    ad 		decr = curthread | RW_WRITE_LOCKED;
1.2    ad 	} else {
1.2    ad 		RW_UNLOCKED(rw, RW_READER);
1.2    ad 		RW_ASSERT(rw, (rw->rw_owner & RW_WRITE_LOCKED) == 0);
1.2    ad 		RW_ASSERT(rw, RW_COUNT(rw) != 0);
1.2    ad 		decr = RW_READ_INCR;
1.2    ad 	}
1.2    ad
1.2    ad 	/*
1.2    ad 	 * Compute what we expect the new value of the lock to be. Only
1.2    ad 	 * proceed to do direct handoff if there are waiters, and if the
1.2    ad 	 * lock would become unowned.
1.2    ad 	 */
1.2    ad 	for (;; owner = rw->rw_owner) {
1.2    ad 		new = (owner - decr);
1.2    ad 		if ((new & (RW_THREAD | RW_HAS_WAITERS)) == RW_HAS_WAITERS)
1.2    ad 			break;
1.2    ad 		if (RW_RELEASE(rw, owner, new))
1.2    ad 			return;
1.2    ad 	}
1.2    ad
1.2    ad 	for (;;) {
1.2    ad 		/*
1.2    ad 		 * Grab the turnstile chain lock.  This gets the interlock
1.2    ad 		 * on the sleep queue.  Once we have that, we can adjust the
1.2    ad 		 * waiter bits.
1.2    ad 		 */
1.2    ad 		ts = turnstile_lookup(rw);
1.2    ad 		RW_DASSERT(rw, ts != NULL);
1.3    ad 		RW_DASSERT(rw, (rw->rw_owner & RW_HAS_WAITERS) != 0);
1.2    ad
1.2    ad 		owner = rw->rw_owner;
1.2    ad 		wcnt = TS_WAITERS(ts, TS_WRITER_Q);
1.2    ad 		rcnt = TS_WAITERS(ts, TS_READER_Q);
1.2    ad
1.2    ad 		/*
1.2    ad 		 * Give the lock away.
1.2    ad 		 *
1.2    ad 		 * If we are releasing a write lock, then wake all
1.2    ad 		 * outstanding readers.  If we are releasing a read
1.2    ad 		 * lock, then wake one writer.
1.2    ad 		 */
1.2    ad 		if (rcnt == 0 || (decr == RW_READ_INCR && wcnt != 0)) {
1.2    ad 			RW_DASSERT(rw, wcnt != 0);
1.2    ad 			RW_DASSERT(rw, (rw->rw_owner & RW_WRITE_WANTED) != 0);
1.2    ad
1.2    ad 			/*
1.2    ad 			 * Give the lock to the longest waiting
1.2    ad 			 * writer.
1.2    ad 			 */
1.2    ad 			l = TS_FIRST(ts, TS_WRITER_Q);
1.2    ad 			new = (uintptr_t)l | RW_WRITE_LOCKED;
1.2    ad
1.2    ad 			if (wcnt > 1)
1.2    ad 				new |= RW_HAS_WAITERS | RW_WRITE_WANTED;
1.2    ad 			else if (rcnt != 0)
1.2    ad 				new |= RW_HAS_WAITERS;
1.2    ad
1.2    ad 			RW_GIVE(rw);
1.2    ad 			if (!RW_RELEASE(rw, owner, new)) {
1.2    ad 				/* Oops, try again. */
1.2    ad 				turnstile_exit(rw);
1.2    ad 				continue;
1.2    ad 			}
1.2    ad
1.2    ad 			/* Wake the writer. */
1.2    ad 			turnstile_wakeup(ts, TS_WRITER_Q, wcnt, l);
1.2    ad 		} else {
1.2    ad 			RW_DASSERT(rw, rcnt != 0);
1.2    ad
1.2    ad 			/*
1.3    ad 			 * Give the lock to all blocked readers.  If there
1.3    ad 			 * is a writer waiting, new readers that arrive
1.3    ad 			 * after the release will be blocked out.
1.2    ad 			 */
1.2    ad 			new = rcnt << RW_READ_COUNT_SHIFT;
1.2    ad 			if (wcnt != 0)
1.2    ad 				new |= RW_HAS_WAITERS | RW_WRITE_WANTED;
1.2    ad
1.2    ad 			RW_GIVE(rw);
1.2    ad 			if (!RW_RELEASE(rw, owner, new)) {
1.2    ad 				/* Oops, try again. */
1.2    ad 				turnstile_exit(rw);
1.2    ad 				continue;
1.2    ad 			}
1.2    ad
1.2    ad 			/* Wake up all sleeping readers. */
1.2    ad 			turnstile_wakeup(ts, TS_READER_Q, rcnt, NULL);
1.2    ad 		}
1.2    ad
1.2    ad 		break;
1.2    ad 	}
1.2    ad }
1.2    ad
1.2    ad /*
1.2    ad  * rw_tryenter:
1.2    ad  *
1.2    ad  *	Try to acquire a rwlock.
1.2    ad  */
1.2    ad int
1.2    ad rw_tryenter(krwlock_t *rw, const krw_t op)
1.2    ad {
1.2    ad 	uintptr_t curthread, owner, incr, need_wait;
1.2    ad
1.2    ad 	curthread = (uintptr_t)curlwp;
1.2    ad
1.2    ad 	RW_ASSERT(rw, curthread != 0);
1.2    ad 	RW_WANTLOCK(rw, op);
1.2    ad
1.2    ad 	if (op == RW_READER) {
1.2    ad 		incr = RW_READ_INCR;
1.2    ad 		need_wait = RW_WRITE_LOCKED | RW_WRITE_WANTED;
1.2    ad 	} else {
1.2    ad 		RW_DASSERT(rw, op == RW_WRITER);
1.2    ad 		incr = curthread | RW_WRITE_LOCKED;
1.2    ad 		need_wait = RW_WRITE_LOCKED | RW_THREAD;
1.2    ad 	}
1.2    ad
1.2    ad 	for (;;) {
1.2    ad 		owner = rw->rw_owner;
1.2    ad 		if ((owner & need_wait) == 0) {
1.2    ad 			if (RW_ACQUIRE(rw, owner, owner + incr)) {
1.2    ad 				/* Got it! */
1.2    ad 				break;
1.2    ad 			}
1.2    ad 			continue;
1.2    ad 		}
1.2    ad 		return 0;
1.2    ad 	}
1.2    ad
1.2    ad 	RW_LOCKED(rw, op);
1.2    ad 	RW_DASSERT(rw, (op != RW_READER && RW_OWNER(rw) == curthread) ||
1.2    ad 	    (op == RW_READER && RW_COUNT(rw) != 0));
1.2    ad 	return 1;
1.2    ad }
1.2    ad
1.2    ad /*
1.2    ad  * rw_downgrade:
1.2    ad  *
1.2    ad  *	Downgrade a write lock to a read lock.
1.2    ad  */
1.2    ad void
1.2    ad rw_downgrade(krwlock_t *rw)
1.2    ad {
1.2    ad 	uintptr_t owner, curthread, new;
1.2    ad 	turnstile_t *ts;
1.2    ad 	int rcnt, wcnt;
1.2    ad
1.2    ad 	curthread = (uintptr_t)curlwp;
1.2    ad 	RW_ASSERT(rw, curthread != 0);
1.2    ad 	RW_DASSERT(rw, (rw->rw_owner & RW_WRITE_LOCKED) != 0);
1.2    ad 	RW_ASSERT(rw, RW_OWNER(rw) == curthread);
1.2    ad 	RW_UNLOCKED(rw, RW_WRITER);
1.2    ad
1.2    ad 	owner = rw->rw_owner;
1.2    ad 	if ((owner & RW_HAS_WAITERS) == 0) {
1.2    ad 		/*
1.2    ad 		 * There are no waiters, so we can do this the easy way.
1.2    ad 		 * Try swapping us down to one read hold.  If it fails, the
1.2    ad 		 * lock condition has changed and we most likely now have
1.2    ad 		 * waiters.
1.2    ad 		 */
1.2    ad 		if (RW_RELEASE(rw, owner, RW_READ_INCR)) {
1.2    ad 			RW_LOCKED(rw, RW_READER);
1.2    ad 			RW_DASSERT(rw, (rw->rw_owner & RW_WRITE_LOCKED) == 0);
1.2    ad 			RW_DASSERT(rw, RW_COUNT(rw) != 0);
1.2    ad 			return;
1.2    ad 		}
1.2    ad 	}
1.2    ad
1.2    ad 	/*
1.2    ad 	 * Grab the turnstile chain lock.  This gets the interlock
1.2    ad 	 * on the sleep queue.  Once we have that, we can adjust the
1.2    ad 	 * waiter bits.
1.2    ad 	 */
1.2    ad 	for (;;) {
1.2    ad 		ts = turnstile_lookup(rw);
1.2    ad 		RW_DASSERT(rw, ts != NULL);
1.2    ad
1.2    ad 		owner = rw->rw_owner;
1.2    ad 		rcnt = TS_WAITERS(ts, TS_READER_Q);
1.2    ad 		wcnt = TS_WAITERS(ts, TS_WRITER_Q);
1.2    ad
1.2    ad 		/*
1.2    ad 		 * If there are no readers, just preserve the waiters
1.2    ad 		 * bits, swap us down to one read hold and return.
1.2    ad 		 */
1.2    ad 		if (rcnt == 0) {
1.2    ad 			RW_DASSERT(rw, wcnt != 0);
1.2    ad 			RW_DASSERT(rw, (rw->rw_owner & RW_WRITE_WANTED) != 0);
1.2    ad 			RW_DASSERT(rw, (rw->rw_owner & RW_HAS_WAITERS) != 0);
1.2    ad
1.2    ad 			new = RW_READ_INCR | RW_HAS_WAITERS | RW_WRITE_WANTED;
1.2    ad 			if (!RW_RELEASE(rw, owner, new)) {
1.2    ad 				/* Oops, try again. */
1.2    ad 				turnstile_exit(ts);
1.2    ad 				continue;
1.2    ad 			}
1.2    ad 			break;
1.2    ad 		}
1.2    ad
1.2    ad 		/*
1.2    ad 		 * Give the lock to all blocked readers.  We may
1.2    ad 		 * retain one read hold if downgrading.  If there
1.2    ad 		 * is a writer waiting, new readers will be blocked
1.2    ad 		 * out.
1.2    ad 		 */
1.2    ad 		new = (rcnt << RW_READ_COUNT_SHIFT) + RW_READ_INCR;
1.2    ad 		if (wcnt != 0)
1.2    ad 			new |= RW_HAS_WAITERS | RW_WRITE_WANTED;
1.2    ad
1.2    ad 		RW_GIVE(rw);
1.2    ad 		if (!RW_RELEASE(rw, owner, new)) {
1.2    ad 			/* Oops, try again. */
1.2    ad 			turnstile_exit(rw);
1.2    ad 			continue;
1.2    ad 		}
1.2    ad
1.2    ad 		/* Wake up all sleeping readers. */
1.2    ad 		turnstile_wakeup(ts, TS_READER_Q, rcnt, NULL);
1.2    ad 		break;
1.2    ad 	}
1.2    ad
1.2    ad 	RW_LOCKED(rw, RW_READER);
1.2    ad 	RW_DASSERT(rw, (rw->rw_owner & RW_WRITE_LOCKED) == 0);
1.2    ad 	RW_DASSERT(rw, RW_COUNT(rw) != 0);
1.2    ad }
1.2    ad
1.2    ad /*
1.2    ad  * rw_tryupgrade:
1.2    ad  *
1.2    ad  *	Try to upgrade a read lock to a write lock.  We must be the
1.2    ad  *	only reader.
1.2    ad  */
1.2    ad int
1.2    ad rw_tryupgrade(krwlock_t *rw)
1.2    ad {
1.2    ad 	uintptr_t owner, curthread, new;
1.2    ad
1.2    ad 	curthread = (uintptr_t)curlwp;
1.2    ad 	RW_ASSERT(rw, curthread != 0);
1.2    ad 	RW_WANTLOCK(rw, RW_WRITER);
1.2    ad
1.2    ad 	for (;;) {
1.2    ad 		owner = rw->rw_owner;
1.2    ad 		RW_ASSERT(rw, (owner & RW_WRITE_LOCKED) == 0);
1.2    ad 		if ((owner & RW_THREAD) != RW_READ_INCR) {
1.2    ad 			RW_ASSERT(rw, (owner & RW_THREAD) != 0);
1.2    ad 			return 0;
1.2    ad 		}
1.2    ad 		new = curthread | RW_WRITE_LOCKED | (owner & ~RW_THREAD);
1.2    ad 		if (RW_ACQUIRE(rw, owner, new))
1.2    ad 			break;
1.2    ad 	}
1.2    ad
1.2    ad 	RW_UNLOCKED(rw, RW_READER);
1.2    ad 	RW_LOCKED(rw, RW_WRITER);
1.2    ad 	RW_DASSERT(rw, rw->rw_owner & RW_WRITE_LOCKED);
1.2    ad 	RW_DASSERT(rw, RW_OWNER(rw) == curthread);
1.2    ad
1.2    ad 	return 1;
1.2    ad }
1.2    ad
1.2    ad /*
1.2    ad  * rw_read_held:
1.2    ad  *
1.2    ad  *	Returns true if the rwlock is held for reading.  Must only be
1.2    ad  *	used for diagnostic assertions, and never be used to make
1.2    ad  * 	decisions about how to use a rwlock.
1.2    ad  */
1.2    ad int
1.2    ad rw_read_held(krwlock_t *rw)
1.2    ad {
1.2    ad 	uintptr_t owner;
1.2    ad
1.2    ad 	if (panicstr != NULL)
1.2    ad 		return 1;
1.2    ad
1.2    ad 	owner = rw->rw_owner;
1.2    ad 	return (owner & RW_WRITE_LOCKED) == 0 && (owner & RW_THREAD) != 0;
1.2    ad }
1.2    ad
1.2    ad /*
1.2    ad  * rw_write_held:
1.2    ad  *
1.2    ad  *	Returns true if the rwlock is held for writing.  Must only be
1.2    ad  *	used for diagnostic assertions, and never be used to make
1.2    ad  *	decisions about how to use a rwlock.
1.2    ad  */
1.2    ad int
1.2    ad rw_write_held(krwlock_t *rw)
1.2    ad {
1.2    ad
1.2    ad 	if (panicstr != NULL)
1.2    ad 		return 1;
1.2    ad
1.2    ad 	return (rw->rw_owner & RW_WRITE_LOCKED) != 0;
1.2    ad }
1.2    ad
1.2    ad /*
1.2    ad  * rw_lock_held:
1.2    ad  *
1.2    ad  *	Returns true if the rwlock is held for reading or writing.  Must
1.2    ad  *	only be used for diagnostic assertions, and never be used to make
1.2    ad  *	decisions about how to use a rwlock.
1.2    ad  */
1.2    ad int
1.2    ad rw_lock_held(krwlock_t *rw)
1.2    ad {
1.2    ad
1.2    ad 	if (panicstr != NULL)
1.2    ad 		return 1;
1.2    ad
1.2    ad 	return (rw->rw_owner & RW_THREAD) != 0;
1.2    ad }
1.4  yamt
1.4  yamt static struct lwp *
1.4  yamt rw_owner(wchan_t obj)
1.4  yamt {
1.4  yamt 	krwlock_t *rw = (void *)(uintptr_t)obj; /* discard qualifiers */
1.4  yamt 	uintptr_t owner = rw->rw_owner;
1.4  yamt
1.4  yamt 	if ((owner & RW_WRITE_LOCKED) == 0)
1.4  yamt 		return NULL;
1.4  yamt
1.4  yamt 	return (void *)(owner & RW_THREAD);
1.4  yamt }