2 * Copyright (c) 2004 Joerg Sonnenberger <joerg@bec.de>. All rights reserved.
3 * Copyright (c) 2006 Matthew Dillon <dillon@backplane.com>. All rights reserved.
5 * Copyright (c) 1982, 1986, 1989, 1993
6 * The Regents of the University of California. All rights reserved.
8 * This code is derived from software contributed to Berkeley by
9 * Scooter Morris at Genentech Inc.
11 * Redistribution and use in source and binary forms, with or without
12 * modification, are permitted provided that the following conditions
14 * 1. Redistributions of source code must retain the above copyright
15 * notice, this list of conditions and the following disclaimer.
16 * 2. Redistributions in binary form must reproduce the above copyright
17 * notice, this list of conditions and the following disclaimer in the
18 * documentation and/or other materials provided with the distribution.
19 * 3. All advertising materials mentioning features or use of this software
20 * must display the following acknowledgement:
21 * This product includes software developed by the University of
22 * California, Berkeley and its contributors.
23 * 4. Neither the name of the University nor the names of its contributors
24 * may be used to endorse or promote products derived from this software
25 * without specific prior written permission.
27 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
28 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
29 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
30 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
31 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
32 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
33 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
34 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
35 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
36 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
39 * @(#)ufs_lockf.c 8.3 (Berkeley) 1/6/94
40 * $FreeBSD: src/sys/kern/kern_lockf.c,v 1.25 1999/11/16 16:28:56 phk Exp $
41 * $DragonFly: src/sys/kern/kern_lockf.c,v 1.37 2007/11/01 22:48:16 dillon Exp $
44 #include <sys/param.h>
45 #include <sys/systm.h>
46 #include <sys/kernel.h>
49 #include <sys/unistd.h>
50 #include <sys/vnode.h>
51 #include <sys/malloc.h>
52 #include <sys/fcntl.h>
53 #include <sys/resourcevar.h>
55 #include <sys/lockf.h>
56 #include <machine/limits.h> /* for LLONG_MAX */
57 #include <machine/stdarg.h>
59 #include <sys/spinlock2.h>
62 int lf_global_counter
= 0;
66 int lf_print_ranges
= 0;
68 static void _lf_print_lock(const struct lockf
*);
69 static void _lf_printf(const char *, ...);
71 #define lf_print_lock(lock) if (lf_print_ranges) _lf_print_lock(lock)
72 #define lf_printf(ctl, args...) if (lf_print_ranges) _lf_printf(ctl, args)
74 #define lf_print_lock(lock)
75 #define lf_printf(ctl, args...)
78 static MALLOC_DEFINE(M_LOCKF
, "lockf", "Byte-range locking structures");
80 static void lf_wakeup(struct lockf
*, off_t
, off_t
);
81 static struct lockf_range
*lf_alloc_range(void);
82 static void lf_create_range(struct lockf_range
*, struct proc
*, int, int,
84 static void lf_insert(struct lockf_range_list
*list
,
85 struct lockf_range
*elm
,
86 struct lockf_range
*insert_point
);
87 static void lf_destroy_range(struct lockf_range
*);
89 static int lf_setlock(struct lockf
*, struct proc
*, int, int,
91 static int lf_getlock(struct flock
*, struct lockf
*, struct proc
*,
92 int, int, off_t
, off_t
);
94 static int lf_count_change(struct proc
*, int);
97 * Return TRUE (non-zero) if the type and posix flags match.
101 lf_match(struct lockf_range
*range
, int type
, int flags
)
103 if (range
->lf_type
!= type
)
105 if ((range
->lf_flags
^ flags
) & F_POSIX
)
111 * Check whether range and [start, end] overlap.
115 lf_overlap(const struct lockf_range
*range
, off_t start
, off_t end
)
117 if (range
->lf_start
>= start
&& range
->lf_start
<= end
)
119 else if (start
>= range
->lf_start
&& start
<= range
->lf_end
)
127 * Change the POSIX lock accounting for the given process.
130 lf_count_adjust(struct proc
*p
, int increase
)
136 uip
= p
->p_ucred
->cr_uidinfo
;
137 spin_lock_wr(&uip
->ui_lock
);
140 uip
->ui_posixlocks
+= p
->p_numposixlocks
;
142 uip
->ui_posixlocks
-= p
->p_numposixlocks
;
144 KASSERT(uip
->ui_posixlocks
>= 0,
145 ("Negative number of POSIX locks held by %s user: %d.",
146 increase
? "new" : "old", uip
->ui_posixlocks
));
147 spin_unlock_wr(&uip
->ui_lock
);
151 lf_count_change(struct proc
*owner
, int diff
)
156 /* we might actually not have a process context */
160 uip
= owner
->p_ucred
->cr_uidinfo
;
162 max
= MIN(owner
->p_rlimit
[RLIMIT_POSIXLOCKS
].rlim_cur
,
163 maxposixlocksperuid
);
165 spin_lock_wr(&uip
->ui_lock
);
166 if (diff
> 0 && owner
->p_ucred
->cr_uid
!= 0 && max
!= -1 &&
167 uip
->ui_posixlocks
>= max
) {
170 uip
->ui_posixlocks
+= diff
;
171 owner
->p_numposixlocks
+= diff
;
172 KASSERT(uip
->ui_posixlocks
>= 0,
173 ("Negative number of POSIX locks held by user: %d.",
174 uip
->ui_posixlocks
));
175 KASSERT(owner
->p_numposixlocks
>= 0,
176 ("Negative number of POSIX locks held by proc: %d.",
177 uip
->ui_posixlocks
));
180 spin_unlock_wr(&uip
->ui_lock
);
185 * Advisory record locking support
188 lf_advlock(struct vop_advlock_args
*ap
, struct lockf
*lock
, u_quad_t size
)
190 struct flock
*fl
= ap
->a_fl
;
193 int type
, flags
, error
;
197 * Convert the flock structure into a start and end.
199 switch (fl
->l_whence
) {
203 * Caller is responsible for adding any necessary offset
204 * when SEEK_CUR is used.
210 start
= size
+ fl
->l_start
;
220 if (fl
->l_len
== 0) {
224 end
= start
+ fl
->l_len
- 1;
231 * This isn't really correct for flock-style locks,
232 * but the current handling is somewhat broken anyway.
234 owner
= (struct proc
*)ap
->a_id
;
237 * Do the requested operation.
239 lwkt_gettoken(&ilock
, lwkt_token_pool_get(lock
));
241 if (lock
->init_done
== 0) {
242 TAILQ_INIT(&lock
->lf_range
);
243 TAILQ_INIT(&lock
->lf_blocked
);
250 * NOTE: It is possible for both lf_range and lf_blocked to
251 * be empty if we block and get woken up, but another process
252 * then gets in and issues an unlock. So VMAYHAVELOCKS must
253 * be set after the lf_setlock() operation completes rather
256 error
= lf_setlock(lock
, owner
, type
, flags
, start
, end
);
257 ap
->a_vp
->v_flag
|= VMAYHAVELOCKS
;
261 error
= lf_setlock(lock
, owner
, type
, flags
, start
, end
);
262 if (TAILQ_EMPTY(&lock
->lf_range
) &&
263 TAILQ_EMPTY(&lock
->lf_blocked
)) {
264 ap
->a_vp
->v_flag
&= ~VMAYHAVELOCKS
;
269 error
= lf_getlock(fl
, lock
, owner
, type
, flags
, start
, end
);
276 lwkt_reltoken(&ilock
);
281 lf_setlock(struct lockf
*lock
, struct proc
*owner
, int type
, int flags
,
282 off_t start
, off_t end
)
284 struct lockf_range
*range
;
285 struct lockf_range
*brange
;
286 struct lockf_range
*next
;
287 struct lockf_range
*first_match
;
288 struct lockf_range
*last_match
;
289 struct lockf_range
*insert_point
;
290 struct lockf_range
*new_range1
;
291 struct lockf_range
*new_range2
;
296 struct lockf_range_list deadlist
;
304 * Preallocate two ranges so we don't have to worry about blocking
305 * in the middle of the lock code.
307 if (new_range1
== NULL
)
308 new_range1
= lf_alloc_range();
309 if (new_range2
== NULL
)
310 new_range2
= lf_alloc_range();
319 * Locate the insertion point for the new lock (the first range
320 * with an lf_start >= start).
322 * Locate the first and latch ranges owned by us that overlap
323 * the requested range.
325 TAILQ_FOREACH(range
, &lock
->lf_range
, lf_link
) {
326 if (insert_point
== NULL
&& range
->lf_start
>= start
)
327 insert_point
= range
;
330 * Skip non-overlapping locks. Locks are sorted by lf_start
331 * So we can terminate the search when lf_start exceeds the
332 * requested range (insert_point is still guarenteed to be
335 if (range
->lf_end
< start
)
337 if (range
->lf_start
> end
) {
343 * Overlapping lock. Set first_match and last_match if we
346 if (range
->lf_owner
== owner
) {
347 if (first_match
== NULL
)
354 * If we aren't the owner check for a conflicting lock. Only
357 if (type
!= F_UNLCK
) {
358 if (type
== F_WRLCK
|| range
->lf_type
== F_WRLCK
)
364 * If a conflicting lock was observed, block or fail as appropriate.
365 * (this code is skipped when unlocking)
368 if ((flags
& F_WAIT
) == 0) {
374 * We are blocked. For POSIX locks we have to check
375 * for deadlocks and return with EDEADLK. This is done
376 * by checking whether range->lf_owner is already
379 * Since flock-style locks cover the whole file, a
380 * deadlock between those is nearly impossible.
381 * This can only occur if a process tries to lock the
382 * same inode exclusively while holding a shared lock
383 * with another descriptor.
384 * XXX How can we cleanly detect this?
385 * XXX The current mixing of flock & fcntl/lockf is evil.
387 * Handle existing locks of flock-style like POSIX locks.
389 if (flags
& F_POSIX
) {
390 TAILQ_FOREACH(brange
, &lock
->lf_blocked
, lf_link
)
391 if (brange
->lf_owner
== range
->lf_owner
) {
398 * For flock-style locks, we must first remove
399 * any shared locks that we hold before we sleep
400 * waiting for an exclusive lock.
402 if ((flags
& F_POSIX
) == 0 && type
== F_WRLCK
)
403 lf_setlock(lock
, owner
, F_UNLCK
, 0, start
, end
);
407 lf_create_range(brange
, owner
, type
, 0, start
, end
);
408 TAILQ_INSERT_TAIL(&lock
->lf_blocked
, brange
, lf_link
);
409 error
= tsleep(brange
, PCATCH
, "lockf", 0);
412 * We may have been awaked by a signal and/or by a
413 * debugger continuing us (in which case we must remove
414 * ourselves from the blocked list) and/or by another
415 * process releasing/downgrading a lock (in which case
416 * we have already been removed from the blocked list
417 * and our lf_flags field is 1).
419 * Sleep if it looks like we might be livelocking.
421 if (brange
->lf_flags
== 0)
422 TAILQ_REMOVE(&lock
->lf_blocked
, brange
, lf_link
);
424 tsleep(brange
, 0, "lockfz", 2);
427 lf_destroy_range(brange
);
435 * If there are no overlapping locks owned by us then creating
436 * the new lock is easy. This is the most common case.
438 if (first_match
== NULL
) {
441 if (flags
& F_POSIX
) {
442 if (lf_count_change(owner
, 1)) {
449 lf_create_range(range
, owner
, type
, flags
, start
, end
);
450 lf_insert(&lock
->lf_range
, range
, insert_point
);
455 * This is a special case that we need to check for in a couple
458 if (first_match
== last_match
&& first_match
->lf_start
< start
&&
459 last_match
->lf_end
> end
) {
466 * Figure out the worst case net increase in POSIX locks and account
467 * for it now before we start modifying things. If neither the
468 * first or last locks match we have an issue. If there is only
469 * one overlapping range which needs to be clipped on both ends
470 * we wind up having to create up to two new locks, else only one.
472 * When unlocking the worst case is always 1 new lock if our
473 * unlock request cuts the middle out of an existing lock range.
475 * count represents the 'cleanup' adjustment needed. It starts
476 * negative, is incremented whenever we create a new POSIX lock,
477 * and decremented whenever we delete an existing one. At the
478 * end of the day it had better be <= 0 or we didn't calculate the
479 * worse case properly here.
482 if (flags
& F_POSIX
) {
483 if (!lf_match(first_match
, type
, flags
) &&
484 !lf_match(last_match
, type
, flags
)
486 if (double_clip
&& type
!= F_UNLCK
)
491 if (count
&& lf_count_change(owner
, -count
)) {
496 /* else flock style lock which encompasses entire range */
499 * Create and insert the lock represented the requested range.
500 * Adjust the net POSIX lock count. We have to move our insertion
501 * point since brange now represents the first record >= start.
503 * When unlocking, no new lock is inserted but we still clip.
505 if (type
!= F_UNLCK
) {
508 lf_create_range(brange
, owner
, type
, flags
, start
, end
);
509 lf_insert(&lock
->lf_range
, brange
, insert_point
);
510 insert_point
= brange
;
518 * Handle the double_clip case. This is the only case where
519 * we wind up having to add TWO locks.
522 KKASSERT(first_match
== last_match
);
523 last_match
= new_range2
;
525 lf_create_range(last_match
, first_match
->lf_owner
,
526 first_match
->lf_type
, first_match
->lf_flags
,
527 end
+ 1, first_match
->lf_end
);
528 first_match
->lf_end
= start
- 1;
529 first_match
->lf_flags
&= ~F_NOEND
;
532 * Figure out where to insert the right side clip.
534 lf_insert(&lock
->lf_range
, last_match
, first_match
);
535 if (last_match
->lf_flags
& F_POSIX
)
540 * Clip or destroy the locks between first_match and last_match,
541 * inclusive. Ignore the primary lock we created (brange). Note
542 * that if double-clipped, first_match and last_match will be
543 * outside our clipping range. Otherwise first_match and last_match
546 * We have already taken care of any double clipping.
548 * The insert_point may become invalid as we delete records, do not
549 * use that pointer any more. Also, when removing something other
550 * then 'range' we have to check to see if the item we are removing
551 * is 'next' and adjust 'next' properly.
553 * NOTE: brange will be NULL if F_UNLCKing.
555 TAILQ_INIT(&deadlist
);
558 while ((range
= next
) != NULL
) {
559 next
= TAILQ_NEXT(range
, lf_link
);
562 * Ignore elements that we do not own and ignore the
563 * primary request range which we just created.
565 if (range
->lf_owner
!= owner
|| range
== brange
)
569 * We may have to wakeup a waiter when downgrading a lock.
573 if (type
== F_RDLCK
&& range
->lf_type
== F_WRLCK
)
577 * Clip left. This can only occur on first_match.
579 * Merge the left clip with brange if possible. This must
580 * be done specifically, not in the optimized merge heuristic
581 * below, since we may have counted on it in our 'count'
584 if (range
->lf_start
< start
) {
585 KKASSERT(range
== first_match
);
587 range
->lf_end
>= start
- 1 &&
588 lf_match(range
, type
, flags
)) {
589 range
->lf_end
= brange
->lf_end
;
590 range
->lf_flags
|= brange
->lf_flags
& F_NOEND
;
592 * Removing something other then 'range',
593 * adjust 'next' if necessary.
596 next
= TAILQ_NEXT(next
, lf_link
);
597 TAILQ_REMOVE(&lock
->lf_range
, brange
, lf_link
);
598 if (brange
->lf_flags
& F_POSIX
)
600 TAILQ_INSERT_TAIL(&deadlist
, brange
, lf_link
);
602 } else if (range
->lf_end
>= start
) {
603 range
->lf_end
= start
- 1;
605 range
->lf_flags
&= ~F_NOEND
;
607 if (range
== last_match
)
613 * Clip right. This can only occur on last_match.
615 * Merge the right clip if possible. This must be done
616 * specifically, not in the optimized merge heuristic
617 * below, since we may have counted on it in our 'count'
620 * Since we are adjusting lf_start, we have to move the
621 * record to maintain the sorted list. Since lf_start is
622 * only getting larger we can use the next element as the
623 * insert point (we don't have to backtrack).
625 if (range
->lf_end
> end
) {
626 KKASSERT(range
== last_match
);
628 range
->lf_start
<= end
+ 1 &&
629 lf_match(range
, type
, flags
)) {
630 brange
->lf_end
= range
->lf_end
;
631 brange
->lf_flags
|= range
->lf_flags
& F_NOEND
;
632 TAILQ_REMOVE(&lock
->lf_range
, range
, lf_link
);
633 if (range
->lf_flags
& F_POSIX
)
635 TAILQ_INSERT_TAIL(&deadlist
, range
, lf_link
);
636 } else if (range
->lf_start
<= end
) {
637 range
->lf_start
= end
+ 1;
638 TAILQ_REMOVE(&lock
->lf_range
, range
, lf_link
);
639 lf_insert(&lock
->lf_range
, range
, next
);
641 /* range == last_match, we are done */
646 * The record must be entirely enclosed. Note that the
647 * record could be first_match or last_match, and will be
650 KKASSERT(range
->lf_start
>= start
&& range
->lf_end
<= end
);
651 TAILQ_REMOVE(&lock
->lf_range
, range
, lf_link
);
652 if (range
->lf_flags
& F_POSIX
)
654 TAILQ_INSERT_TAIL(&deadlist
, range
, lf_link
);
655 if (range
== last_match
)
660 * Attempt to merge locks adjacent to brange. For example, we may
661 * have had to clip first_match and/or last_match, and they might
662 * be adjacent. Or there might simply have been an adjacent lock
665 * Don't get fancy, just check adjacent elements in the list if they
666 * happen to be owned by us.
668 * This case only gets hit if we have a situation where a shared
669 * and exclusive lock are adjacent, and the exclusive lock is
670 * downgraded to shared or the shared lock is upgraded to exclusive.
673 range
= TAILQ_PREV(brange
, lockf_range_list
, lf_link
);
675 range
->lf_owner
== owner
&&
676 range
->lf_end
== brange
->lf_start
- 1 &&
677 lf_match(range
, type
, flags
)
680 * Extend range to cover brange and scrap brange.
682 range
->lf_end
= brange
->lf_end
;
683 range
->lf_flags
|= brange
->lf_flags
& F_NOEND
;
684 TAILQ_REMOVE(&lock
->lf_range
, brange
, lf_link
);
685 if (brange
->lf_flags
& F_POSIX
)
687 TAILQ_INSERT_TAIL(&deadlist
, brange
, lf_link
);
690 range
= TAILQ_NEXT(brange
, lf_link
);
692 range
->lf_owner
== owner
&&
693 range
->lf_start
== brange
->lf_end
+ 1 &&
694 lf_match(range
, type
, flags
)
697 * Extend brange to cover range and scrap range.
699 brange
->lf_end
= range
->lf_end
;
700 brange
->lf_flags
|= range
->lf_flags
& F_NOEND
;
701 TAILQ_REMOVE(&lock
->lf_range
, range
, lf_link
);
702 if (range
->lf_flags
& F_POSIX
)
704 TAILQ_INSERT_TAIL(&deadlist
, range
, lf_link
);
709 * Destroy deleted elements. We didn't want to do it in the loop
710 * because the free() might have blocked.
712 * Adjust the count for any posix locks we thought we might create
715 while ((range
= TAILQ_FIRST(&deadlist
)) != NULL
) {
716 TAILQ_REMOVE(&deadlist
, range
, lf_link
);
717 lf_destroy_range(range
);
720 KKASSERT(count
<= 0);
722 lf_count_change(owner
, count
);
726 lf_wakeup(lock
, start
, end
);
729 if (new_range1
!= NULL
)
730 lf_destroy_range(new_range1
);
731 if (new_range2
!= NULL
)
732 lf_destroy_range(new_range2
);
737 * Check whether there is a blocking lock,
738 * and if so return its process identifier.
741 lf_getlock(struct flock
*fl
, struct lockf
*lock
, struct proc
*owner
,
742 int type
, int flags
, off_t start
, off_t end
)
744 struct lockf_range
*range
;
746 TAILQ_FOREACH(range
, &lock
->lf_range
, lf_link
)
747 if (range
->lf_owner
!= owner
&&
748 lf_overlap(range
, start
, end
) &&
749 (type
== F_WRLCK
|| range
->lf_type
== F_WRLCK
))
752 fl
->l_type
= F_UNLCK
;
755 fl
->l_type
= range
->lf_type
;
756 fl
->l_whence
= SEEK_SET
;
757 fl
->l_start
= range
->lf_start
;
758 if (range
->lf_flags
& F_NOEND
)
761 fl
->l_len
= range
->lf_end
- range
->lf_start
+ 1;
762 if (range
->lf_owner
!= NULL
&& (range
->lf_flags
& F_POSIX
))
763 fl
->l_pid
= range
->lf_owner
->p_pid
;
770 * Wakeup pending lock attempts. Theoretically we can stop as soon as
771 * we encounter an exclusive request that covers the whole range (at least
772 * insofar as the sleep code above calls lf_wakeup() if it would otherwise
773 * exit instead of loop), but for now just wakeup all overlapping
777 lf_wakeup(struct lockf
*lock
, off_t start
, off_t end
)
779 struct lockf_range
*range
, *nrange
;
781 TAILQ_FOREACH_MUTABLE(range
, &lock
->lf_blocked
, lf_link
, nrange
) {
782 if (lf_overlap(range
, start
, end
) == 0)
784 TAILQ_REMOVE(&lock
->lf_blocked
, range
, lf_link
);
791 * Allocate a range structure and initialize it sufficiently such that
792 * lf_destroy_range() does not barf.
794 static struct lockf_range
*
797 struct lockf_range
*range
;
802 range
= kmalloc(sizeof(struct lockf_range
), M_LOCKF
, M_WAITOK
);
803 range
->lf_owner
= NULL
;
808 lf_insert(struct lockf_range_list
*list
, struct lockf_range
*elm
,
809 struct lockf_range
*insert_point
)
811 while (insert_point
&& insert_point
->lf_start
< elm
->lf_start
)
812 insert_point
= TAILQ_NEXT(insert_point
, lf_link
);
813 if (insert_point
!= NULL
)
814 TAILQ_INSERT_BEFORE(insert_point
, elm
, lf_link
);
816 TAILQ_INSERT_TAIL(list
, elm
, lf_link
);
820 lf_create_range(struct lockf_range
*range
, struct proc
*owner
, int type
,
821 int flags
, off_t start
, off_t end
)
823 KKASSERT(start
<= end
);
824 range
->lf_type
= type
;
825 range
->lf_flags
= flags
;
826 range
->lf_start
= start
;
828 range
->lf_owner
= owner
;
830 lf_printf("lf_create_range: %lld..%lld\n",
831 range
->lf_start
, range
->lf_end
);
835 lf_destroy_range(struct lockf_range
*range
)
837 lf_printf("lf_destroy_range: %lld..%lld\n",
838 range
->lf_start
, range
->lf_end
);
839 kfree(range
, M_LOCKF
);
842 KKASSERT(lf_global_counter
>=0);
849 _lf_printf(const char *ctl
, ...)
854 if (lf_print_ranges
) {
855 if ((p
= curproc
) != NULL
)
856 kprintf("pid %d (%s): ", p
->p_pid
, p
->p_comm
);
864 _lf_print_lock(const struct lockf
*lock
)
866 struct lockf_range
*range
;
868 if (lf_print_ranges
== 0)
871 if (TAILQ_EMPTY(&lock
->lf_range
)) {
872 lf_printf("lockf %p: no ranges locked\n", lock
);
874 lf_printf("lockf %p:\n", lock
);
876 TAILQ_FOREACH(range
, &lock
->lf_range
, lf_link
)
877 kprintf("\t%lld..%lld type %s owned by %d\n",
878 range
->lf_start
, range
->lf_end
,
879 range
->lf_type
== F_RDLCK
? "shared" : "exclusive",
880 range
->lf_flags
& F_POSIX
? range
->lf_owner
->p_pid
: -1);
881 if (TAILQ_EMPTY(&lock
->lf_blocked
))
882 kprintf("no process waiting for range\n");
884 kprintf("blocked locks:");
885 TAILQ_FOREACH(range
, &lock
->lf_blocked
, lf_link
)
886 kprintf("\t%lld..%lld type %s waiting on %p\n",
887 range
->lf_start
, range
->lf_end
,
888 range
->lf_type
== F_RDLCK
? "shared" : "exclusive",
891 #endif /* LOCKF_DEBUG */