1 /* $OpenBSD: subr_pool.c,v 1.45 2004/07/29 09:18:17 mickey Exp $ */
2 /* $NetBSD: subr_pool.c,v 1.61 2001/09/26 07:14:56 chs Exp $ */
3
4 /*-
5 * Copyright (c) 1997, 1999, 2000 The NetBSD Foundation, Inc.
6 * All rights reserved.
7 *
8 * This code is derived from software contributed to The NetBSD Foundation
9 * by Paul Kranenburg; by Jason R. Thorpe of the Numerical Aerospace
10 * Simulation Facility, NASA Ames Research Center.
11 *
12 * Redistribution and use in source and binary forms, with or without
13 * modification, are permitted provided that the following conditions
14 * are met:
15 * 1. Redistributions of source code must retain the above copyright
16 * notice, this list of conditions and the following disclaimer.
17 * 2. Redistributions in binary form must reproduce the above copyright
18 * notice, this list of conditions and the following disclaimer in the
19 * documentation and/or other materials provided with the distribution.
20 * 3. All advertising materials mentioning features or use of this software
21 * must display the following acknowledgement:
22 * This product includes software developed by the NetBSD
23 * Foundation, Inc. and its contributors.
24 * 4. Neither the name of The NetBSD Foundation nor the names of its
25 * contributors may be used to endorse or promote products derived
26 * from this software without specific prior written permission.
27 *
28 * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
29 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
30 * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
31 * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
32 * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
33 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
34 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
35 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
36 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
37 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
38 * POSSIBILITY OF SUCH DAMAGE.
39 */
40
41 #include <sys/param.h>
42 #include <sys/systm.h>
43 #include <sys/proc.h>
44 #include <sys/errno.h>
45 #include <sys/kernel.h>
46 #include <sys/malloc.h>
47 #include <sys/lock.h>
48 #include <sys/pool.h>
49 #include <sys/syslog.h>
50 #include <sys/sysctl.h>
51
52 #include <uvm/uvm.h>
53
54 /*
55 * XXX - for now.
56 */
57 #define SIMPLELOCK_INITIALIZER { SLOCK_UNLOCKED }
58 #ifdef LOCKDEBUG
59 #define simple_lock_freecheck(a, s) do { /* nothing */ } while (0)
60 #define simple_lock_only_held(lkp, str) do { /* nothing */ } while (0)
61 #endif
62
63 /*
64 * Pool resource management utility.
65 *
66 * Memory is allocated in pages which are split into pieces according to
67 * the pool item size. Each page is kept on one of three lists in the
68 * pool structure: `pr_emptypages', `pr_fullpages' and `pr_partpages',
69 * for empty, full and partially-full pages respectively. The individual
70 * pool items are on a linked list headed by `ph_itemlist' in each page
71 * header. The memory for building the page list is either taken from
72 * the allocated pages themselves (for small pool items) or taken from
73 * an internal pool of page headers (`phpool').
74 */
75
76 /* List of all pools */
77 TAILQ_HEAD(,pool) pool_head = TAILQ_HEAD_INITIALIZER(pool_head);
78
79 /* Private pool for page header structures */
80 static struct pool phpool;
81
82 /* # of seconds to retain page after last use */
83 int pool_inactive_time = 10;
84
85 /* Next candidate for drainage (see pool_drain()) */
86 static struct pool *drainpp;
87
88 /* This spin lock protects both pool_head and drainpp. */
89 struct simplelock pool_head_slock = SIMPLELOCK_INITIALIZER;
90
91 struct pool_item_header {
92 /* Page headers */
93 LIST_ENTRY(pool_item_header)
94 ph_pagelist; /* pool page list */
95 TAILQ_HEAD(,pool_item) ph_itemlist; /* chunk list for this page */
96 SPLAY_ENTRY(pool_item_header)
97 ph_node; /* Off-page page headers */
98 int ph_nmissing; /* # of chunks in use */
99 caddr_t ph_page; /* this page's address */
100 struct timeval ph_time; /* last referenced */
101 };
102
103 struct pool_item {
104 #ifdef DIAGNOSTIC
105 int pi_magic;
106 #endif
107 #define PI_MAGIC 0xdeafbeef
108 /* Other entries use only this list entry */
109 TAILQ_ENTRY(pool_item) pi_list;
110 };
111
112 #define POOL_NEEDS_CATCHUP(pp) \
113 ((pp)->pr_nitems < (pp)->pr_minitems)
114
115 /*
116 * Every pool get a unique serial number assigned to it. If this counter
117 * wraps, we're screwed, but we shouldn't create so many pools anyway.
118 */
119 unsigned int pool_serial;
120
121 /*
122 * Pool cache management.
123 *
124 * Pool caches provide a way for constructed objects to be cached by the
125 * pool subsystem. This can lead to performance improvements by avoiding
126 * needless object construction/destruction; it is deferred until absolutely
127 * necessary.
128 *
129 * Caches are grouped into cache groups. Each cache group references
130 * up to 16 constructed objects. When a cache allocates an object
131 * from the pool, it calls the object's constructor and places it into
132 * a cache group. When a cache group frees an object back to the pool,
133 * it first calls the object's destructor. This allows the object to
134 * persist in constructed form while freed to the cache.
135 *
136 * Multiple caches may exist for each pool. This allows a single
137 * object type to have multiple constructed forms. The pool references
138 * each cache, so that when a pool is drained by the pagedaemon, it can
139 * drain each individual cache as well. Each time a cache is drained,
140 * the most idle cache group is freed to the pool in its entirety.
141 *
142 * Pool caches are layed on top of pools. By layering them, we can avoid
143 * the complexity of cache management for pools which would not benefit
144 * from it.
145 */
146
147 /* The cache group pool. */
148 static struct pool pcgpool;
149
150 /* The pool cache group. */
151 #define PCG_NOBJECTS 16
152 struct pool_cache_group {
153 TAILQ_ENTRY(pool_cache_group)
154 pcg_list; /* link in the pool cache's group list */
155 u_int pcg_avail; /* # available objects */
156 /* pointers to the objects */
157 void *pcg_objects[PCG_NOBJECTS];
158 };
159
160 void pool_cache_reclaim(struct pool_cache *);
161 void pool_cache_do_invalidate(struct pool_cache *, int,
162 void (*)(struct pool *, void *));
163
164 int pool_catchup(struct pool *);
165 void pool_prime_page(struct pool *, caddr_t, struct pool_item_header *);
166 void pool_update_curpage(struct pool *);
167 void pool_do_put(struct pool *, void *);
168 void pr_rmpage(struct pool *, struct pool_item_header *,
169 struct pool_pagelist *);
170 int pool_chk_page(struct pool *, const char *, struct pool_item_header *);
171
172 void *pool_allocator_alloc(struct pool *, int);
173 void pool_allocator_free(struct pool *, void *);
174
175 #ifdef DDB
176 void pool_print_pagelist(struct pool_pagelist *, int (*)(const char *, ...));
177 void pool_print1(struct pool *, const char *, int (*)(const char *, ...));
178 #endif
179
180
181 /*
182 * Pool log entry. An array of these is allocated in pool_init().
183 */
184 struct pool_log {
185 const char *pl_file;
186 long pl_line;
187 int pl_action;
188 #define PRLOG_GET 1
189 #define PRLOG_PUT 2
190 void *pl_addr;
191 };
192
193 /* Number of entries in pool log buffers */
194 #ifndef POOL_LOGSIZE
195 #define POOL_LOGSIZE 10
196 #endif
197
198 int pool_logsize = POOL_LOGSIZE;
199
200 #ifdef POOL_DIAGNOSTIC
201 static __inline void
pr_log(struct pool * pp,void * v,int action,const char * file,long line)202 pr_log(struct pool *pp, void *v, int action, const char *file, long line)
203 {
204 int n = pp->pr_curlogentry;
205 struct pool_log *pl;
206
207 if ((pp->pr_roflags & PR_LOGGING) == 0)
208 return;
209
210 /*
211 * Fill in the current entry. Wrap around and overwrite
212 * the oldest entry if necessary.
213 */
214 pl = &pp->pr_log[n];
215 pl->pl_file = file;
216 pl->pl_line = line;
217 pl->pl_action = action;
218 pl->pl_addr = v;
219 if (++n >= pp->pr_logsize)
220 n = 0;
221 pp->pr_curlogentry = n;
222 }
223
224 static void
pr_printlog(struct pool * pp,struct pool_item * pi,int (* pr)(const char *,...))225 pr_printlog(struct pool *pp, struct pool_item *pi,
226 int (*pr)(const char *, ...))
227 {
228 int i = pp->pr_logsize;
229 int n = pp->pr_curlogentry;
230
231 if ((pp->pr_roflags & PR_LOGGING) == 0)
232 return;
233
234 /*
235 * Print all entries in this pool's log.
236 */
237 while (i-- > 0) {
238 struct pool_log *pl = &pp->pr_log[n];
239 if (pl->pl_action != 0) {
240 if (pi == NULL || pi == pl->pl_addr) {
241 (*pr)("\tlog entry %d:\n", i);
242 (*pr)("\t\taction = %s, addr = %p\n",
243 pl->pl_action == PRLOG_GET ? "get" : "put",
244 pl->pl_addr);
245 (*pr)("\t\tfile: %s at line %lu\n",
246 pl->pl_file, pl->pl_line);
247 }
248 }
249 if (++n >= pp->pr_logsize)
250 n = 0;
251 }
252 }
253
254 static __inline void
pr_enter(struct pool * pp,const char * file,long line)255 pr_enter(struct pool *pp, const char *file, long line)
256 {
257
258 if (__predict_false(pp->pr_entered_file != NULL)) {
259 printf("pool %s: reentrancy at file %s line %ld\n",
260 pp->pr_wchan, file, line);
261 printf(" previous entry at file %s line %ld\n",
262 pp->pr_entered_file, pp->pr_entered_line);
263 panic("pr_enter");
264 }
265
266 pp->pr_entered_file = file;
267 pp->pr_entered_line = line;
268 }
269
270 static __inline void
pr_leave(struct pool * pp)271 pr_leave(struct pool *pp)
272 {
273
274 if (__predict_false(pp->pr_entered_file == NULL)) {
275 printf("pool %s not entered?\n", pp->pr_wchan);
276 panic("pr_leave");
277 }
278
279 pp->pr_entered_file = NULL;
280 pp->pr_entered_line = 0;
281 }
282
283 static __inline void
pr_enter_check(struct pool * pp,int (* pr)(const char *,...))284 pr_enter_check(struct pool *pp, int (*pr)(const char *, ...))
285 {
286
287 if (pp->pr_entered_file != NULL)
288 (*pr)("\n\tcurrently entered from file %s line %ld\n",
289 pp->pr_entered_file, pp->pr_entered_line);
290 }
291 #else
292 #define pr_log(pp, v, action, file, line)
293 #define pr_printlog(pp, pi, pr)
294 #define pr_enter(pp, file, line)
295 #define pr_leave(pp)
296 #define pr_enter_check(pp, pr)
297 #endif /* POOL_DIAGNOSTIC */
298
299 static __inline int
phtree_compare(struct pool_item_header * a,struct pool_item_header * b)300 phtree_compare(struct pool_item_header *a, struct pool_item_header *b)
301 {
302 if (a->ph_page < b->ph_page)
303 return (-1);
304 else if (a->ph_page > b->ph_page)
305 return (1);
306 else
307 return (0);
308 }
309
310 SPLAY_PROTOTYPE(phtree, pool_item_header, ph_node, phtree_compare);
311 SPLAY_GENERATE(phtree, pool_item_header, ph_node, phtree_compare);
312
313 /*
314 * Return the pool page header based on page address.
315 */
316 static __inline struct pool_item_header *
pr_find_pagehead(struct pool * pp,caddr_t page)317 pr_find_pagehead(struct pool *pp, caddr_t page)
318 {
319 struct pool_item_header *ph, tmp;
320
321 if ((pp->pr_roflags & PR_PHINPAGE) != 0)
322 return ((struct pool_item_header *)(page + pp->pr_phoffset));
323
324 tmp.ph_page = page;
325 ph = SPLAY_FIND(phtree, &pp->pr_phtree, &tmp);
326 return ph;
327 }
328
329 /*
330 * Remove a page from the pool.
331 */
332 void
pr_rmpage(struct pool * pp,struct pool_item_header * ph,struct pool_pagelist * pq)333 pr_rmpage(struct pool *pp, struct pool_item_header *ph,
334 struct pool_pagelist *pq)
335 {
336 int s;
337
338 /*
339 * If the page was idle, decrement the idle page count.
340 */
341 if (ph->ph_nmissing == 0) {
342 #ifdef DIAGNOSTIC
343 if (pp->pr_nidle == 0)
344 panic("pr_rmpage: nidle inconsistent");
345 if (pp->pr_nitems < pp->pr_itemsperpage)
346 panic("pr_rmpage: nitems inconsistent");
347 #endif
348 pp->pr_nidle--;
349 }
350
351 pp->pr_nitems -= pp->pr_itemsperpage;
352
353 /*
354 * Unlink a page from the pool and release it (or queue it for release).
355 */
356 LIST_REMOVE(ph, ph_pagelist);
357 if (pq) {
358 LIST_INSERT_HEAD(pq, ph, ph_pagelist);
359 } else {
360 pool_allocator_free(pp, ph->ph_page);
361 if ((pp->pr_roflags & PR_PHINPAGE) == 0) {
362 SPLAY_REMOVE(phtree, &pp->pr_phtree, ph);
363 s = splhigh();
364 pool_put(&phpool, ph);
365 splx(s);
366 }
367 }
368 pp->pr_npages--;
369 pp->pr_npagefree++;
370
371 pool_update_curpage(pp);
372 }
373
374 /*
375 * Initialize the given pool resource structure.
376 *
377 * We export this routine to allow other kernel parts to declare
378 * static pools that must be initialized before malloc() is available.
379 */
380 void
pool_init(struct pool * pp,size_t size,u_int align,u_int ioff,int flags,const char * wchan,struct pool_allocator * palloc)381 pool_init(struct pool *pp, size_t size, u_int align, u_int ioff, int flags,
382 const char *wchan, struct pool_allocator *palloc)
383 {
384 int off, slack;
385
386 #ifdef POOL_DIAGNOSTIC
387 /*
388 * Always log if POOL_DIAGNOSTIC is defined.
389 */
390 if (pool_logsize != 0)
391 flags |= PR_LOGGING;
392 #endif
393
394 #ifdef MALLOC_DEBUG
395 if ((flags & PR_DEBUG) && (ioff != 0 || align != 0))
396 flags &= ~PR_DEBUG;
397 #endif
398 /*
399 * Check arguments and construct default values.
400 */
401 if (palloc == NULL)
402 palloc = &pool_allocator_nointr;
403 if ((palloc->pa_flags & PA_INITIALIZED) == 0) {
404 if (palloc->pa_pagesz == 0)
405 palloc->pa_pagesz = PAGE_SIZE;
406
407 TAILQ_INIT(&palloc->pa_list);
408
409 simple_lock_init(&palloc->pa_slock);
410 palloc->pa_pagemask = ~(palloc->pa_pagesz - 1);
411 palloc->pa_pageshift = ffs(palloc->pa_pagesz) - 1;
412 palloc->pa_flags |= PA_INITIALIZED;
413 }
414
415 if (align == 0)
416 align = ALIGN(1);
417
418 if (size < sizeof(struct pool_item))
419 size = sizeof(struct pool_item);
420
421 size = roundup(size, align);
422 #ifdef DIAGNOSTIC
423 if (size > palloc->pa_pagesz)
424 panic("pool_init: pool item size (%lu) too large",
425 (u_long)size);
426 #endif
427
428 /*
429 * Initialize the pool structure.
430 */
431 LIST_INIT(&pp->pr_emptypages);
432 LIST_INIT(&pp->pr_fullpages);
433 LIST_INIT(&pp->pr_partpages);
434 TAILQ_INIT(&pp->pr_cachelist);
435 pp->pr_curpage = NULL;
436 pp->pr_npages = 0;
437 pp->pr_minitems = 0;
438 pp->pr_minpages = 0;
439 pp->pr_maxpages = 8;
440 pp->pr_roflags = flags;
441 pp->pr_flags = 0;
442 pp->pr_size = size;
443 pp->pr_align = align;
444 pp->pr_wchan = wchan;
445 pp->pr_alloc = palloc;
446 pp->pr_nitems = 0;
447 pp->pr_nout = 0;
448 pp->pr_hardlimit = UINT_MAX;
449 pp->pr_hardlimit_warning = NULL;
450 pp->pr_hardlimit_ratecap.tv_sec = 0;
451 pp->pr_hardlimit_ratecap.tv_usec = 0;
452 pp->pr_hardlimit_warning_last.tv_sec = 0;
453 pp->pr_hardlimit_warning_last.tv_usec = 0;
454 pp->pr_drain_hook = NULL;
455 pp->pr_drain_hook_arg = NULL;
456 pp->pr_serial = ++pool_serial;
457 if (pool_serial == 0)
458 panic("pool_init: too much uptime");
459
460 /*
461 * Decide whether to put the page header off page to avoid
462 * wasting too large a part of the page. Off-page page headers
463 * go on a hash table, so we can match a returned item
464 * with its header based on the page address.
465 * We use 1/16 of the page size as the threshold (XXX: tune)
466 */
467 if (pp->pr_size < palloc->pa_pagesz/16) {
468 /* Use the end of the page for the page header */
469 pp->pr_roflags |= PR_PHINPAGE;
470 pp->pr_phoffset = off = palloc->pa_pagesz -
471 ALIGN(sizeof(struct pool_item_header));
472 } else {
473 /* The page header will be taken from our page header pool */
474 pp->pr_phoffset = 0;
475 off = palloc->pa_pagesz;
476 SPLAY_INIT(&pp->pr_phtree);
477 }
478
479 /*
480 * Alignment is to take place at `ioff' within the item. This means
481 * we must reserve up to `align - 1' bytes on the page to allow
482 * appropriate positioning of each item.
483 *
484 * Silently enforce `0 <= ioff < align'.
485 */
486 pp->pr_itemoffset = ioff = ioff % align;
487 pp->pr_itemsperpage = (off - ((align - ioff) % align)) / pp->pr_size;
488 KASSERT(pp->pr_itemsperpage != 0);
489
490 /*
491 * Use the slack between the chunks and the page header
492 * for "cache coloring".
493 */
494 slack = off - pp->pr_itemsperpage * pp->pr_size;
495 pp->pr_maxcolor = (slack / align) * align;
496 pp->pr_curcolor = 0;
497
498 pp->pr_nget = 0;
499 pp->pr_nfail = 0;
500 pp->pr_nput = 0;
501 pp->pr_npagealloc = 0;
502 pp->pr_npagefree = 0;
503 pp->pr_hiwat = 0;
504 pp->pr_nidle = 0;
505
506 #ifdef POOL_DIAGNOSTIC
507 if (flags & PR_LOGGING) {
508 if (kmem_map == NULL ||
509 (pp->pr_log = malloc(pool_logsize * sizeof(struct pool_log),
510 M_TEMP, M_NOWAIT)) == NULL)
511 pp->pr_roflags &= ~PR_LOGGING;
512 pp->pr_curlogentry = 0;
513 pp->pr_logsize = pool_logsize;
514 }
515 #endif
516
517 pp->pr_entered_file = NULL;
518 pp->pr_entered_line = 0;
519
520 simple_lock_init(&pp->pr_slock);
521
522 /*
523 * Initialize private page header pool and cache magazine pool if we
524 * haven't done so yet.
525 * XXX LOCKING.
526 */
527 if (phpool.pr_size == 0) {
528 pool_init(&phpool, sizeof(struct pool_item_header), 0, 0,
529 0, "phpool", NULL);
530 pool_init(&pcgpool, sizeof(struct pool_cache_group), 0, 0,
531 0, "pcgpool", NULL);
532 }
533
534 /* Insert this into the list of all pools. */
535 simple_lock(&pool_head_slock);
536 TAILQ_INSERT_TAIL(&pool_head, pp, pr_poollist);
537 simple_unlock(&pool_head_slock);
538
539 /* Insert into the list of pools using this allocator. */
540 simple_lock(&palloc->pa_slock);
541 TAILQ_INSERT_TAIL(&palloc->pa_list, pp, pr_alloc_list);
542 simple_unlock(&palloc->pa_slock);
543 }
544
545 /*
546 * De-commision a pool resource.
547 */
548 void
pool_destroy(struct pool * pp)549 pool_destroy(struct pool *pp)
550 {
551 struct pool_item_header *ph;
552 struct pool_cache *pc;
553
554 /* Locking order: pool_allocator -> pool */
555 simple_lock(&pp->pr_alloc->pa_slock);
556 TAILQ_REMOVE(&pp->pr_alloc->pa_list, pp, pr_alloc_list);
557 simple_unlock(&pp->pr_alloc->pa_slock);
558
559 /* Destroy all caches for this pool. */
560 while ((pc = TAILQ_FIRST(&pp->pr_cachelist)) != NULL)
561 pool_cache_destroy(pc);
562
563 #ifdef DIAGNOSTIC
564 if (pp->pr_nout != 0) {
565 pr_printlog(pp, NULL, printf);
566 panic("pool_destroy: pool busy: still out: %u",
567 pp->pr_nout);
568 }
569 #endif
570
571 /* Remove all pages */
572 while ((ph = LIST_FIRST(&pp->pr_emptypages)) != NULL)
573 pr_rmpage(pp, ph, NULL);
574 KASSERT(LIST_EMPTY(&pp->pr_fullpages));
575 KASSERT(LIST_EMPTY(&pp->pr_partpages));
576
577 /* Remove from global pool list */
578 simple_lock(&pool_head_slock);
579 TAILQ_REMOVE(&pool_head, pp, pr_poollist);
580 if (drainpp == pp) {
581 drainpp = NULL;
582 }
583 simple_unlock(&pool_head_slock);
584
585 #ifdef POOL_DIAGNOSTIC
586 if ((pp->pr_roflags & PR_LOGGING) != 0)
587 free(pp->pr_log, M_TEMP);
588 #endif
589 }
590
591 void
pool_set_drain_hook(struct pool * pp,void (* fn)(void *,int),void * arg)592 pool_set_drain_hook(struct pool *pp, void (*fn)(void *, int), void *arg)
593 {
594 /* XXX no locking -- must be used just after pool_init() */
595 #ifdef DIAGNOSTIC
596 if (pp->pr_drain_hook != NULL)
597 panic("pool_set_drain_hook(%s): already set", pp->pr_wchan);
598 #endif
599 pp->pr_drain_hook = fn;
600 pp->pr_drain_hook_arg = arg;
601 }
602
603 static struct pool_item_header *
pool_alloc_item_header(struct pool * pp,caddr_t storage,int flags)604 pool_alloc_item_header(struct pool *pp, caddr_t storage, int flags)
605 {
606 struct pool_item_header *ph;
607 int s;
608
609 LOCK_ASSERT(simple_lock_held(&pp->pr_slock) == 0);
610
611 if ((pp->pr_roflags & PR_PHINPAGE) != 0)
612 ph = (struct pool_item_header *) (storage + pp->pr_phoffset);
613 else {
614 s = splhigh();
615 ph = pool_get(&phpool, flags);
616 splx(s);
617 }
618
619 return (ph);
620 }
621
622 /*
623 * Grab an item from the pool; must be called at appropriate spl level
624 */
625 void *
626 #ifdef POOL_DIAGNOSTIC
_pool_get(struct pool * pp,int flags,const char * file,long line)627 _pool_get(struct pool *pp, int flags, const char *file, long line)
628 #else
629 pool_get(struct pool *pp, int flags)
630 #endif
631 {
632 struct pool_item *pi;
633 struct pool_item_header *ph;
634 void *v;
635
636 #ifdef DIAGNOSTIC
637 if ((flags & PR_WAITOK) != 0)
638 splassert(IPL_NONE);
639 if (__predict_false(curproc == NULL && /* doing_shutdown == 0 && XXX*/
640 (flags & PR_WAITOK) != 0))
641 panic("pool_get: %s:must have NOWAIT", pp->pr_wchan);
642
643 #ifdef LOCKDEBUG
644 if (flags & PR_WAITOK)
645 simple_lock_only_held(NULL, "pool_get(PR_WAITOK)");
646 #endif
647 #endif /* DIAGNOSTIC */
648
649 #ifdef MALLOC_DEBUG
650 if (pp->pr_roflags & PR_DEBUG) {
651 void *addr;
652
653 addr = NULL;
654 debug_malloc(pp->pr_size, M_DEBUG,
655 (flags & PR_WAITOK) ? M_WAITOK : M_NOWAIT, &addr);
656 return (addr);
657 }
658 #endif
659
660 simple_lock(&pp->pr_slock);
661 pr_enter(pp, file, line);
662
663 startover:
664 /*
665 * Check to see if we've reached the hard limit. If we have,
666 * and we can wait, then wait until an item has been returned to
667 * the pool.
668 */
669 #ifdef DIAGNOSTIC
670 if (__predict_false(pp->pr_nout > pp->pr_hardlimit)) {
671 pr_leave(pp);
672 simple_unlock(&pp->pr_slock);
673 panic("pool_get: %s: crossed hard limit", pp->pr_wchan);
674 }
675 #endif
676 if (__predict_false(pp->pr_nout == pp->pr_hardlimit)) {
677 if (pp->pr_drain_hook != NULL) {
678 /*
679 * Since the drain hook is going to free things
680 * back to the pool, unlock, call hook, re-lock
681 * and check hardlimit condition again.
682 */
683 pr_leave(pp);
684 simple_unlock(&pp->pr_slock);
685 (*pp->pr_drain_hook)(pp->pr_drain_hook_arg, flags);
686 simple_lock(&pp->pr_slock);
687 pr_enter(pp, file, line);
688 if (pp->pr_nout < pp->pr_hardlimit)
689 goto startover;
690 }
691
692 if ((flags & PR_WAITOK) && !(flags & PR_LIMITFAIL)) {
693 /*
694 * XXX: A warning isn't logged in this case. Should
695 * it be?
696 */
697 pp->pr_flags |= PR_WANTED;
698 pr_leave(pp);
699 ltsleep(pp, PSWP, pp->pr_wchan, 0, &pp->pr_slock);
700 pr_enter(pp, file, line);
701 goto startover;
702 }
703
704 /*
705 * Log a message that the hard limit has been hit.
706 */
707 if (pp->pr_hardlimit_warning != NULL &&
708 ratecheck(&pp->pr_hardlimit_warning_last,
709 &pp->pr_hardlimit_ratecap))
710 log(LOG_ERR, "%s\n", pp->pr_hardlimit_warning);
711
712 pp->pr_nfail++;
713
714 pr_leave(pp);
715 simple_unlock(&pp->pr_slock);
716 return (NULL);
717 }
718
719 /*
720 * The convention we use is that if `curpage' is not NULL, then
721 * it points at a non-empty bucket. In particular, `curpage'
722 * never points at a page header which has PR_PHINPAGE set and
723 * has no items in its bucket.
724 */
725 if ((ph = pp->pr_curpage) == NULL) {
726 #ifdef DIAGNOSTIC
727 if (pp->pr_nitems != 0) {
728 simple_unlock(&pp->pr_slock);
729 printf("pool_get: %s: curpage NULL, nitems %u\n",
730 pp->pr_wchan, pp->pr_nitems);
731 panic("pool_get: nitems inconsistent");
732 }
733 #endif
734
735 /*
736 * Call the back-end page allocator for more memory.
737 * Release the pool lock, as the back-end page allocator
738 * may block.
739 */
740 pr_leave(pp);
741 simple_unlock(&pp->pr_slock);
742 v = pool_allocator_alloc(pp, flags);
743 if (__predict_true(v != NULL))
744 ph = pool_alloc_item_header(pp, v, flags);
745 simple_lock(&pp->pr_slock);
746 pr_enter(pp, file, line);
747
748 if (__predict_false(v == NULL || ph == NULL)) {
749 if (v != NULL)
750 pool_allocator_free(pp, v);
751
752 /*
753 * We were unable to allocate a page or item
754 * header, but we released the lock during
755 * allocation, so perhaps items were freed
756 * back to the pool. Check for this case.
757 */
758 if (pp->pr_curpage != NULL)
759 goto startover;
760
761 if ((flags & PR_WAITOK) == 0) {
762 pp->pr_nfail++;
763 pr_leave(pp);
764 simple_unlock(&pp->pr_slock);
765 return (NULL);
766 }
767
768 /*
769 * Wait for items to be returned to this pool.
770 *
771 * XXX: maybe we should wake up once a second and
772 * try again?
773 */
774 pp->pr_flags |= PR_WANTED;
775 /* PA_WANTED is already set on the allocator. */
776 pr_leave(pp);
777 ltsleep(pp, PSWP, pp->pr_wchan, 0, &pp->pr_slock);
778 pr_enter(pp, file, line);
779 goto startover;
780 }
781
782 /* We have more memory; add it to the pool */
783 pool_prime_page(pp, v, ph);
784 pp->pr_npagealloc++;
785
786 /* Start the allocation process over. */
787 goto startover;
788 }
789 if (__predict_false((v = pi = TAILQ_FIRST(&ph->ph_itemlist)) == NULL)) {
790 pr_leave(pp);
791 simple_unlock(&pp->pr_slock);
792 panic("pool_get: %s: page empty", pp->pr_wchan);
793 }
794 #ifdef DIAGNOSTIC
795 if (__predict_false(pp->pr_nitems == 0)) {
796 pr_leave(pp);
797 simple_unlock(&pp->pr_slock);
798 printf("pool_get: %s: items on itemlist, nitems %u\n",
799 pp->pr_wchan, pp->pr_nitems);
800 panic("pool_get: nitems inconsistent");
801 }
802 #endif
803
804 #ifdef POOL_DIAGNOSTIC
805 pr_log(pp, v, PRLOG_GET, file, line);
806 #endif
807
808 #ifdef DIAGNOSTIC
809 if (__predict_false(pi->pi_magic != PI_MAGIC)) {
810 pr_printlog(pp, pi, printf);
811 panic("pool_get(%s): free list modified: magic=%x; page %p;"
812 " item addr %p",
813 pp->pr_wchan, pi->pi_magic, ph->ph_page, pi);
814 }
815 #endif
816
817 /*
818 * Remove from item list.
819 */
820 TAILQ_REMOVE(&ph->ph_itemlist, pi, pi_list);
821 pp->pr_nitems--;
822 pp->pr_nout++;
823 if (ph->ph_nmissing == 0) {
824 #ifdef DIAGNOSTIC
825 if (__predict_false(pp->pr_nidle == 0))
826 panic("pool_get: nidle inconsistent");
827 #endif
828 pp->pr_nidle--;
829
830 /*
831 * This page was previously empty. Move it to the list of
832 * partially-full pages. This page is already curpage.
833 */
834 LIST_REMOVE(ph, ph_pagelist);
835 LIST_INSERT_HEAD(&pp->pr_partpages, ph, ph_pagelist);
836 }
837 ph->ph_nmissing++;
838 if (TAILQ_EMPTY(&ph->ph_itemlist)) {
839 #ifdef DIAGNOSTIC
840 if (__predict_false(ph->ph_nmissing != pp->pr_itemsperpage)) {
841 pr_leave(pp);
842 simple_unlock(&pp->pr_slock);
843 panic("pool_get: %s: nmissing inconsistent",
844 pp->pr_wchan);
845 }
846 #endif
847 /*
848 * This page is now full. Move it to the full list
849 * and select a new current page.
850 */
851 LIST_REMOVE(ph, ph_pagelist);
852 LIST_INSERT_HEAD(&pp->pr_fullpages, ph, ph_pagelist);
853 pool_update_curpage(pp);
854 }
855
856 pp->pr_nget++;
857
858 /*
859 * If we have a low water mark and we are now below that low
860 * water mark, add more items to the pool.
861 */
862 if (POOL_NEEDS_CATCHUP(pp) && pool_catchup(pp) != 0) {
863 /*
864 * XXX: Should we log a warning? Should we set up a timeout
865 * to try again in a second or so? The latter could break
866 * a caller's assumptions about interrupt protection, etc.
867 */
868 }
869
870 pr_leave(pp);
871 simple_unlock(&pp->pr_slock);
872 return (v);
873 }
874
875 /*
876 * Internal version of pool_put(). Pool is already locked/entered.
877 */
878 void
pool_do_put(struct pool * pp,void * v)879 pool_do_put(struct pool *pp, void *v)
880 {
881 struct pool_item *pi = v;
882 struct pool_item_header *ph;
883 caddr_t page;
884 int s;
885
886 #ifdef MALLOC_DEBUG
887 if (pp->pr_roflags & PR_DEBUG) {
888 debug_free(v, M_DEBUG);
889 return;
890 }
891 #endif
892
893 LOCK_ASSERT(simple_lock_held(&pp->pr_slock));
894
895 page = (caddr_t)((vaddr_t)v & pp->pr_alloc->pa_pagemask);
896
897 #ifdef DIAGNOSTIC
898 if (__predict_false(pp->pr_nout == 0)) {
899 printf("pool %s: putting with none out\n",
900 pp->pr_wchan);
901 panic("pool_put");
902 }
903 #endif
904
905 if (__predict_false((ph = pr_find_pagehead(pp, page)) == NULL)) {
906 pr_printlog(pp, NULL, printf);
907 panic("pool_put: %s: page header missing", pp->pr_wchan);
908 }
909
910 #ifdef LOCKDEBUG
911 /*
912 * Check if we're freeing a locked simple lock.
913 */
914 simple_lock_freecheck((caddr_t)pi, ((caddr_t)pi) + pp->pr_size);
915 #endif
916
917 /*
918 * Return to item list.
919 */
920 #ifdef DIAGNOSTIC
921 pi->pi_magic = PI_MAGIC;
922 #endif
923 #ifdef DEBUG
924 {
925 int i, *ip = v;
926
927 for (i = 0; i < pp->pr_size / sizeof(int); i++) {
928 *ip++ = PI_MAGIC;
929 }
930 }
931 #endif
932
933 TAILQ_INSERT_HEAD(&ph->ph_itemlist, pi, pi_list);
934 ph->ph_nmissing--;
935 pp->pr_nput++;
936 pp->pr_nitems++;
937 pp->pr_nout--;
938
939 /* Cancel "pool empty" condition if it exists */
940 if (pp->pr_curpage == NULL)
941 pp->pr_curpage = ph;
942
943 if (pp->pr_flags & PR_WANTED) {
944 pp->pr_flags &= ~PR_WANTED;
945 if (ph->ph_nmissing == 0)
946 pp->pr_nidle++;
947 wakeup((caddr_t)pp);
948 return;
949 }
950
951 /*
952 * If this page is now empty, do one of two things:
953 *
954 * (1) If we have more pages than the page high water mark,
955 * free the page back to the system.
956 *
957 * (2) Otherwise, move the page to the empty page list.
958 *
959 * Either way, select a new current page (so we use a partially-full
960 * page if one is available).
961 */
962 if (ph->ph_nmissing == 0) {
963 pp->pr_nidle++;
964 if (pp->pr_nidle > pp->pr_maxpages ||
965 (pp->pr_alloc->pa_flags & PA_WANT) != 0) {
966 pr_rmpage(pp, ph, NULL);
967 } else {
968 LIST_REMOVE(ph, ph_pagelist);
969 LIST_INSERT_HEAD(&pp->pr_emptypages, ph, ph_pagelist);
970
971 /*
972 * Update the timestamp on the page. A page must
973 * be idle for some period of time before it can
974 * be reclaimed by the pagedaemon. This minimizes
975 * ping-pong'ing for memory.
976 */
977 s = splclock();
978 ph->ph_time = mono_time;
979 splx(s);
980 }
981 pool_update_curpage(pp);
982 }
983
984 /*
985 * If the page was previously completely full, move it to the
986 * partially-full list and make it the current page. The next
987 * allocation will get the item from this page, instead of
988 * further fragmenting the pool.
989 */
990 else if (ph->ph_nmissing == (pp->pr_itemsperpage - 1)) {
991 LIST_REMOVE(ph, ph_pagelist);
992 LIST_INSERT_HEAD(&pp->pr_partpages, ph, ph_pagelist);
993 pp->pr_curpage = ph;
994 }
995 }
996
997 /*
998 * Return resource to the pool; must be called at appropriate spl level
999 */
1000 #ifdef POOL_DIAGNOSTIC
1001 void
_pool_put(struct pool * pp,void * v,const char * file,long line)1002 _pool_put(struct pool *pp, void *v, const char *file, long line)
1003 {
1004
1005 simple_lock(&pp->pr_slock);
1006 pr_enter(pp, file, line);
1007
1008 pr_log(pp, v, PRLOG_PUT, file, line);
1009
1010 pool_do_put(pp, v);
1011
1012 pr_leave(pp);
1013 simple_unlock(&pp->pr_slock);
1014 }
1015 #undef pool_put
1016 #endif /* POOL_DIAGNOSTIC */
1017
1018 void
pool_put(struct pool * pp,void * v)1019 pool_put(struct pool *pp, void *v)
1020 {
1021
1022 simple_lock(&pp->pr_slock);
1023
1024 pool_do_put(pp, v);
1025
1026 simple_unlock(&pp->pr_slock);
1027 }
1028
1029 #ifdef POOL_DIAGNOSTIC
1030 #define pool_put(h, v) _pool_put((h), (v), __FILE__, __LINE__)
1031 #endif
1032
1033 /*
1034 * Add N items to the pool.
1035 */
1036 int
pool_prime(struct pool * pp,int n)1037 pool_prime(struct pool *pp, int n)
1038 {
1039 struct pool_item_header *ph;
1040 caddr_t cp;
1041 int newpages;
1042
1043 simple_lock(&pp->pr_slock);
1044
1045 newpages = roundup(n, pp->pr_itemsperpage) / pp->pr_itemsperpage;
1046
1047 while (newpages-- > 0) {
1048 simple_unlock(&pp->pr_slock);
1049 cp = pool_allocator_alloc(pp, PR_NOWAIT);
1050 if (__predict_true(cp != NULL))
1051 ph = pool_alloc_item_header(pp, cp, PR_NOWAIT);
1052 simple_lock(&pp->pr_slock);
1053
1054 if (__predict_false(cp == NULL || ph == NULL)) {
1055 if (cp != NULL)
1056 pool_allocator_free(pp, cp);
1057 break;
1058 }
1059
1060 pool_prime_page(pp, cp, ph);
1061 pp->pr_npagealloc++;
1062 pp->pr_minpages++;
1063 }
1064
1065 if (pp->pr_minpages >= pp->pr_maxpages)
1066 pp->pr_maxpages = pp->pr_minpages + 1; /* XXX */
1067
1068 simple_unlock(&pp->pr_slock);
1069 return (0);
1070 }
1071
1072 /*
1073 * Add a page worth of items to the pool.
1074 *
1075 * Note, we must be called with the pool descriptor LOCKED.
1076 */
1077 void
pool_prime_page(struct pool * pp,caddr_t storage,struct pool_item_header * ph)1078 pool_prime_page(struct pool *pp, caddr_t storage, struct pool_item_header *ph)
1079 {
1080 struct pool_item *pi;
1081 caddr_t cp = storage;
1082 unsigned int align = pp->pr_align;
1083 unsigned int ioff = pp->pr_itemoffset;
1084 int n;
1085
1086 #ifdef DIAGNOSTIC
1087 if (((u_long)cp & (pp->pr_alloc->pa_pagesz - 1)) != 0)
1088 panic("pool_prime_page: %s: unaligned page", pp->pr_wchan);
1089 #endif
1090
1091 /*
1092 * Insert page header.
1093 */
1094 LIST_INSERT_HEAD(&pp->pr_emptypages, ph, ph_pagelist);
1095 TAILQ_INIT(&ph->ph_itemlist);
1096 ph->ph_page = storage;
1097 ph->ph_nmissing = 0;
1098 memset(&ph->ph_time, 0, sizeof(ph->ph_time));
1099 if ((pp->pr_roflags & PR_PHINPAGE) == 0)
1100 SPLAY_INSERT(phtree, &pp->pr_phtree, ph);
1101
1102 pp->pr_nidle++;
1103
1104 /*
1105 * Color this page.
1106 */
1107 cp = (caddr_t)(cp + pp->pr_curcolor);
1108 if ((pp->pr_curcolor += align) > pp->pr_maxcolor)
1109 pp->pr_curcolor = 0;
1110
1111 /*
1112 * Adjust storage to apply aligment to `pr_itemoffset' in each item.
1113 */
1114 if (ioff != 0)
1115 cp = (caddr_t)(cp + (align - ioff));
1116
1117 /*
1118 * Insert remaining chunks on the bucket list.
1119 */
1120 n = pp->pr_itemsperpage;
1121 pp->pr_nitems += n;
1122
1123 while (n--) {
1124 pi = (struct pool_item *)cp;
1125
1126 KASSERT(((((vaddr_t)pi) + ioff) & (align - 1)) == 0);
1127
1128 /* Insert on page list */
1129 TAILQ_INSERT_TAIL(&ph->ph_itemlist, pi, pi_list);
1130 #ifdef DIAGNOSTIC
1131 pi->pi_magic = PI_MAGIC;
1132 #endif
1133 cp = (caddr_t)(cp + pp->pr_size);
1134 }
1135
1136 /*
1137 * If the pool was depleted, point at the new page.
1138 */
1139 if (pp->pr_curpage == NULL)
1140 pp->pr_curpage = ph;
1141
1142 if (++pp->pr_npages > pp->pr_hiwat)
1143 pp->pr_hiwat = pp->pr_npages;
1144 }
1145
1146 /*
1147 * Used by pool_get() when nitems drops below the low water mark. This
1148 * is used to catch up pr_nitems with the low water mark.
1149 *
1150 * Note 1, we never wait for memory here, we let the caller decide what to do.
1151 *
1152 * Note 2, we must be called with the pool already locked, and we return
1153 * with it locked.
1154 */
1155 int
pool_catchup(struct pool * pp)1156 pool_catchup(struct pool *pp)
1157 {
1158 struct pool_item_header *ph;
1159 caddr_t cp;
1160 int error = 0;
1161
1162 while (POOL_NEEDS_CATCHUP(pp)) {
1163 /*
1164 * Call the page back-end allocator for more memory.
1165 *
1166 * XXX: We never wait, so should we bother unlocking
1167 * the pool descriptor?
1168 */
1169 simple_unlock(&pp->pr_slock);
1170 cp = pool_allocator_alloc(pp, PR_NOWAIT);
1171 if (__predict_true(cp != NULL))
1172 ph = pool_alloc_item_header(pp, cp, PR_NOWAIT);
1173 simple_lock(&pp->pr_slock);
1174 if (__predict_false(cp == NULL || ph == NULL)) {
1175 if (cp != NULL)
1176 pool_allocator_free(pp, cp);
1177 error = ENOMEM;
1178 break;
1179 }
1180 pool_prime_page(pp, cp, ph);
1181 pp->pr_npagealloc++;
1182 }
1183
1184 return (error);
1185 }
1186
1187 void
pool_update_curpage(struct pool * pp)1188 pool_update_curpage(struct pool *pp)
1189 {
1190
1191 pp->pr_curpage = LIST_FIRST(&pp->pr_partpages);
1192 if (pp->pr_curpage == NULL) {
1193 pp->pr_curpage = LIST_FIRST(&pp->pr_emptypages);
1194 }
1195 }
1196
1197 void
pool_setlowat(struct pool * pp,int n)1198 pool_setlowat(struct pool *pp, int n)
1199 {
1200
1201 simple_lock(&pp->pr_slock);
1202
1203 pp->pr_minitems = n;
1204 pp->pr_minpages = (n == 0)
1205 ? 0
1206 : roundup(n, pp->pr_itemsperpage) / pp->pr_itemsperpage;
1207
1208 /* Make sure we're caught up with the newly-set low water mark. */
1209 if (POOL_NEEDS_CATCHUP(pp) && pool_catchup(pp) != 0) {
1210 /*
1211 * XXX: Should we log a warning? Should we set up a timeout
1212 * to try again in a second or so? The latter could break
1213 * a caller's assumptions about interrupt protection, etc.
1214 */
1215 }
1216
1217 simple_unlock(&pp->pr_slock);
1218 }
1219
1220 void
pool_sethiwat(struct pool * pp,int n)1221 pool_sethiwat(struct pool *pp, int n)
1222 {
1223
1224 simple_lock(&pp->pr_slock);
1225
1226 pp->pr_maxpages = (n == 0)
1227 ? 0
1228 : roundup(n, pp->pr_itemsperpage) / pp->pr_itemsperpage;
1229
1230 simple_unlock(&pp->pr_slock);
1231 }
1232
1233 int
pool_sethardlimit(struct pool * pp,unsigned n,const char * warnmess,int ratecap)1234 pool_sethardlimit(struct pool *pp, unsigned n, const char *warnmess, int ratecap)
1235 {
1236 int error = 0;
1237
1238 simple_lock(&pp->pr_slock);
1239
1240 if (n < pp->pr_nout) {
1241 error = EINVAL;
1242 goto done;
1243 }
1244
1245 pp->pr_hardlimit = n;
1246 pp->pr_hardlimit_warning = warnmess;
1247 pp->pr_hardlimit_ratecap.tv_sec = ratecap;
1248 pp->pr_hardlimit_warning_last.tv_sec = 0;
1249 pp->pr_hardlimit_warning_last.tv_usec = 0;
1250
1251 /*
1252 * In-line version of pool_sethiwat(), because we don't want to
1253 * release the lock.
1254 */
1255 pp->pr_maxpages = (n == 0 || n == UINT_MAX)
1256 ? n
1257 : roundup(n, pp->pr_itemsperpage) / pp->pr_itemsperpage;
1258
1259 done:
1260 simple_unlock(&pp->pr_slock);
1261
1262 return (error);
1263 }
1264
1265 /*
1266 * Release all complete pages that have not been used recently.
1267 *
1268 * Returns non-zero if any pages have been reclaimed.
1269 */
1270 int
1271 #ifdef POOL_DIAGNOSTIC
_pool_reclaim(struct pool * pp,const char * file,long line)1272 _pool_reclaim(struct pool *pp, const char *file, long line)
1273 #else
1274 pool_reclaim(struct pool *pp)
1275 #endif
1276 {
1277 struct pool_item_header *ph, *phnext;
1278 struct pool_cache *pc;
1279 struct timeval curtime;
1280 struct pool_pagelist pq;
1281 struct timeval diff;
1282 int s;
1283
1284 if (pp->pr_drain_hook != NULL) {
1285 /*
1286 * The drain hook must be called with the pool unlocked.
1287 */
1288 (*pp->pr_drain_hook)(pp->pr_drain_hook_arg, PR_NOWAIT);
1289 }
1290
1291 if (simple_lock_try(&pp->pr_slock) == 0)
1292 return (0);
1293 pr_enter(pp, file, line);
1294
1295 LIST_INIT(&pq);
1296
1297 /*
1298 * Reclaim items from the pool's caches.
1299 */
1300 TAILQ_FOREACH(pc, &pp->pr_cachelist, pc_poollist)
1301 pool_cache_reclaim(pc);
1302
1303 s = splclock();
1304 curtime = mono_time;
1305 splx(s);
1306
1307 for (ph = LIST_FIRST(&pp->pr_emptypages); ph != NULL; ph = phnext) {
1308 phnext = LIST_NEXT(ph, ph_pagelist);
1309
1310 /* Check our minimum page claim */
1311 if (pp->pr_npages <= pp->pr_minpages)
1312 break;
1313
1314 KASSERT(ph->ph_nmissing == 0);
1315 timersub(&curtime, &ph->ph_time, &diff);
1316 if (diff.tv_sec < pool_inactive_time)
1317 continue;
1318
1319 /*
1320 * If freeing this page would put us below
1321 * the low water mark, stop now.
1322 */
1323 if ((pp->pr_nitems - pp->pr_itemsperpage) <
1324 pp->pr_minitems)
1325 break;
1326
1327 pr_rmpage(pp, ph, &pq);
1328 }
1329
1330 pr_leave(pp);
1331 simple_unlock(&pp->pr_slock);
1332 if (LIST_EMPTY(&pq))
1333 return (0);
1334 while ((ph = LIST_FIRST(&pq)) != NULL) {
1335 LIST_REMOVE(ph, ph_pagelist);
1336 pool_allocator_free(pp, ph->ph_page);
1337 if (pp->pr_roflags & PR_PHINPAGE) {
1338 continue;
1339 }
1340 SPLAY_REMOVE(phtree, &pp->pr_phtree, ph);
1341 s = splhigh();
1342 pool_put(&phpool, ph);
1343 splx(s);
1344 }
1345
1346 return (1);
1347 }
1348
1349
1350 /*
1351 * Drain pools, one at a time.
1352 *
1353 * Note, we must never be called from an interrupt context.
1354 */
1355 void
pool_drain(void * arg)1356 pool_drain(void *arg)
1357 {
1358 struct pool *pp;
1359 int s;
1360
1361 pp = NULL;
1362 s = splvm();
1363 simple_lock(&pool_head_slock);
1364 if (drainpp == NULL) {
1365 drainpp = TAILQ_FIRST(&pool_head);
1366 }
1367 if (drainpp) {
1368 pp = drainpp;
1369 drainpp = TAILQ_NEXT(pp, pr_poollist);
1370 }
1371 simple_unlock(&pool_head_slock);
1372 pool_reclaim(pp);
1373 splx(s);
1374 }
1375
1376 #ifdef DDB
1377 /*
1378 * Diagnostic helpers.
1379 */
1380 void
pool_printit(struct pool * pp,const char * modif,int (* pr)(const char *,...))1381 pool_printit(struct pool *pp, const char *modif, int (*pr)(const char *, ...))
1382 {
1383 int s;
1384
1385 s = splvm();
1386 if (simple_lock_try(&pp->pr_slock) == 0) {
1387 pr("pool %s is locked; try again later\n",
1388 pp->pr_wchan);
1389 splx(s);
1390 return;
1391 }
1392 pool_print1(pp, modif, pr);
1393 simple_unlock(&pp->pr_slock);
1394 splx(s);
1395 }
1396
1397 void
pool_print_pagelist(struct pool_pagelist * pl,int (* pr)(const char *,...))1398 pool_print_pagelist(struct pool_pagelist *pl, int (*pr)(const char *, ...))
1399 {
1400 struct pool_item_header *ph;
1401 #ifdef DIAGNOSTIC
1402 struct pool_item *pi;
1403 #endif
1404
1405 LIST_FOREACH(ph, pl, ph_pagelist) {
1406 (*pr)("\t\tpage %p, nmissing %d, time %lld,%lu\n",
1407 ph->ph_page, ph->ph_nmissing,
1408 (int64_t)ph->ph_time.tv_sec,
1409 (u_long)ph->ph_time.tv_usec);
1410 #ifdef DIAGNOSTIC
1411 TAILQ_FOREACH(pi, &ph->ph_itemlist, pi_list) {
1412 if (pi->pi_magic != PI_MAGIC) {
1413 (*pr)("\t\t\titem %p, magic 0x%x\n",
1414 pi, pi->pi_magic);
1415 }
1416 }
1417 #endif
1418 }
1419 }
1420
1421 void
pool_print1(struct pool * pp,const char * modif,int (* pr)(const char *,...))1422 pool_print1(struct pool *pp, const char *modif, int (*pr)(const char *, ...))
1423 {
1424 struct pool_item_header *ph;
1425 struct pool_cache *pc;
1426 struct pool_cache_group *pcg;
1427 int i, print_log = 0, print_pagelist = 0, print_cache = 0;
1428 char c;
1429
1430 while ((c = *modif++) != '\0') {
1431 if (c == 'l')
1432 print_log = 1;
1433 if (c == 'p')
1434 print_pagelist = 1;
1435 if (c == 'c')
1436 print_cache = 1;
1437 modif++;
1438 }
1439
1440 (*pr)("POOL %s: size %u, align %u, ioff %u, roflags 0x%08x\n",
1441 pp->pr_wchan, pp->pr_size, pp->pr_align, pp->pr_itemoffset,
1442 pp->pr_roflags);
1443 (*pr)("\talloc %p\n", pp->pr_alloc);
1444 (*pr)("\tminitems %u, minpages %u, maxpages %u, npages %u\n",
1445 pp->pr_minitems, pp->pr_minpages, pp->pr_maxpages, pp->pr_npages);
1446 (*pr)("\titemsperpage %u, nitems %u, nout %u, hardlimit %u\n",
1447 pp->pr_itemsperpage, pp->pr_nitems, pp->pr_nout, pp->pr_hardlimit);
1448
1449 (*pr)("\n\tnget %lu, nfail %lu, nput %lu\n",
1450 pp->pr_nget, pp->pr_nfail, pp->pr_nput);
1451 (*pr)("\tnpagealloc %lu, npagefree %lu, hiwat %u, nidle %lu\n",
1452 pp->pr_npagealloc, pp->pr_npagefree, pp->pr_hiwat, pp->pr_nidle);
1453
1454 if (print_pagelist == 0)
1455 goto skip_pagelist;
1456
1457 if ((ph = LIST_FIRST(&pp->pr_emptypages)) != NULL)
1458 (*pr)("\n\tempty page list:\n");
1459 pool_print_pagelist(&pp->pr_emptypages, pr);
1460 if ((ph = LIST_FIRST(&pp->pr_fullpages)) != NULL)
1461 (*pr)("\n\tfull page list:\n");
1462 pool_print_pagelist(&pp->pr_fullpages, pr);
1463 if ((ph = LIST_FIRST(&pp->pr_partpages)) != NULL)
1464 (*pr)("\n\tpartial-page list:\n");
1465 pool_print_pagelist(&pp->pr_partpages, pr);
1466
1467 if (pp->pr_curpage == NULL)
1468 (*pr)("\tno current page\n");
1469 else
1470 (*pr)("\tcurpage %p\n", pp->pr_curpage->ph_page);
1471
1472 skip_pagelist:
1473 if (print_log == 0)
1474 goto skip_log;
1475
1476 (*pr)("\n");
1477 if ((pp->pr_roflags & PR_LOGGING) == 0)
1478 (*pr)("\tno log\n");
1479 else
1480 pr_printlog(pp, NULL, pr);
1481
1482 skip_log:
1483 if (print_cache == 0)
1484 goto skip_cache;
1485
1486 TAILQ_FOREACH(pc, &pp->pr_cachelist, pc_poollist) {
1487 (*pr)("\tcache %p: allocfrom %p freeto %p\n", pc,
1488 pc->pc_allocfrom, pc->pc_freeto);
1489 (*pr)("\t hits %lu misses %lu ngroups %lu nitems %lu\n",
1490 pc->pc_hits, pc->pc_misses, pc->pc_ngroups, pc->pc_nitems);
1491 TAILQ_FOREACH(pcg, &pc->pc_grouplist, pcg_list) {
1492 (*pr)("\t\tgroup %p: avail %d\n", pcg, pcg->pcg_avail);
1493 for (i = 0; i < PCG_NOBJECTS; i++)
1494 (*pr)("\t\t\t%p\n", pcg->pcg_objects[i]);
1495 }
1496 }
1497
1498 skip_cache:
1499 pr_enter_check(pp, pr);
1500 }
1501
1502 int
pool_chk_page(struct pool * pp,const char * label,struct pool_item_header * ph)1503 pool_chk_page(struct pool *pp, const char *label, struct pool_item_header *ph)
1504 {
1505 struct pool_item *pi;
1506 caddr_t page;
1507 int n;
1508
1509 page = (caddr_t)((u_long)ph & pp->pr_alloc->pa_pagemask);
1510 if (page != ph->ph_page &&
1511 (pp->pr_roflags & PR_PHINPAGE) != 0) {
1512 if (label != NULL)
1513 printf("%s: ", label);
1514 printf("pool(%p:%s): page inconsistency: page %p;"
1515 " at page head addr %p (p %p)\n", pp,
1516 pp->pr_wchan, ph->ph_page,
1517 ph, page);
1518 return 1;
1519 }
1520
1521 for (pi = TAILQ_FIRST(&ph->ph_itemlist), n = 0;
1522 pi != NULL;
1523 pi = TAILQ_NEXT(pi,pi_list), n++) {
1524
1525 #ifdef DIAGNOSTIC
1526 if (pi->pi_magic != PI_MAGIC) {
1527 if (label != NULL)
1528 printf("%s: ", label);
1529 printf("pool(%s): free list modified: magic=%x;"
1530 " page %p; item ordinal %d;"
1531 " addr %p (p %p)\n",
1532 pp->pr_wchan, pi->pi_magic, ph->ph_page,
1533 n, pi, page);
1534 panic("pool");
1535 }
1536 #endif
1537 page =
1538 (caddr_t)((u_long)pi & pp->pr_alloc->pa_pagemask);
1539 if (page == ph->ph_page)
1540 continue;
1541
1542 if (label != NULL)
1543 printf("%s: ", label);
1544 printf("pool(%p:%s): page inconsistency: page %p;"
1545 " item ordinal %d; addr %p (p %p)\n", pp,
1546 pp->pr_wchan, ph->ph_page,
1547 n, pi, page);
1548 return 1;
1549 }
1550 return 0;
1551 }
1552
1553 int
pool_chk(struct pool * pp,const char * label)1554 pool_chk(struct pool *pp, const char *label)
1555 {
1556 struct pool_item_header *ph;
1557 int r = 0;
1558
1559 simple_lock(&pp->pr_slock);
1560 LIST_FOREACH(ph, &pp->pr_emptypages, ph_pagelist) {
1561 r = pool_chk_page(pp, label, ph);
1562 if (r) {
1563 goto out;
1564 }
1565 }
1566 LIST_FOREACH(ph, &pp->pr_fullpages, ph_pagelist) {
1567 r = pool_chk_page(pp, label, ph);
1568 if (r) {
1569 goto out;
1570 }
1571 }
1572 LIST_FOREACH(ph, &pp->pr_partpages, ph_pagelist) {
1573 r = pool_chk_page(pp, label, ph);
1574 if (r) {
1575 goto out;
1576 }
1577 }
1578
1579 out:
1580 simple_unlock(&pp->pr_slock);
1581 return (r);
1582 }
1583 #endif
1584
1585 /*
1586 * pool_cache_init:
1587 *
1588 * Initialize a pool cache.
1589 *
1590 * NOTE: If the pool must be protected from interrupts, we expect
1591 * to be called at the appropriate interrupt priority level.
1592 */
1593 void
pool_cache_init(struct pool_cache * pc,struct pool * pp,int (* ctor)(void *,void *,int),void (* dtor)(void *,void *),void * arg)1594 pool_cache_init(struct pool_cache *pc, struct pool *pp,
1595 int (*ctor)(void *, void *, int),
1596 void (*dtor)(void *, void *),
1597 void *arg)
1598 {
1599
1600 TAILQ_INIT(&pc->pc_grouplist);
1601 simple_lock_init(&pc->pc_slock);
1602
1603 pc->pc_allocfrom = NULL;
1604 pc->pc_freeto = NULL;
1605 pc->pc_pool = pp;
1606
1607 pc->pc_ctor = ctor;
1608 pc->pc_dtor = dtor;
1609 pc->pc_arg = arg;
1610
1611 pc->pc_hits = 0;
1612 pc->pc_misses = 0;
1613
1614 pc->pc_ngroups = 0;
1615
1616 pc->pc_nitems = 0;
1617
1618 simple_lock(&pp->pr_slock);
1619 TAILQ_INSERT_TAIL(&pp->pr_cachelist, pc, pc_poollist);
1620 simple_unlock(&pp->pr_slock);
1621 }
1622
1623 /*
1624 * pool_cache_destroy:
1625 *
1626 * Destroy a pool cache.
1627 */
1628 void
pool_cache_destroy(struct pool_cache * pc)1629 pool_cache_destroy(struct pool_cache *pc)
1630 {
1631 struct pool *pp = pc->pc_pool;
1632
1633 /* First, invalidate the entire cache. */
1634 pool_cache_invalidate(pc);
1635
1636 /* ...and remove it from the pool's cache list. */
1637 simple_lock(&pp->pr_slock);
1638 TAILQ_REMOVE(&pp->pr_cachelist, pc, pc_poollist);
1639 simple_unlock(&pp->pr_slock);
1640 }
1641
1642 static __inline void *
pcg_get(struct pool_cache_group * pcg)1643 pcg_get(struct pool_cache_group *pcg)
1644 {
1645 void *object;
1646 u_int idx;
1647
1648 KASSERT(pcg->pcg_avail <= PCG_NOBJECTS);
1649 KASSERT(pcg->pcg_avail != 0);
1650 idx = --pcg->pcg_avail;
1651
1652 KASSERT(pcg->pcg_objects[idx] != NULL);
1653 object = pcg->pcg_objects[idx];
1654 pcg->pcg_objects[idx] = NULL;
1655
1656 return (object);
1657 }
1658
1659 static __inline void
pcg_put(struct pool_cache_group * pcg,void * object)1660 pcg_put(struct pool_cache_group *pcg, void *object)
1661 {
1662 u_int idx;
1663
1664 KASSERT(pcg->pcg_avail < PCG_NOBJECTS);
1665 idx = pcg->pcg_avail++;
1666
1667 KASSERT(pcg->pcg_objects[idx] == NULL);
1668 pcg->pcg_objects[idx] = object;
1669 }
1670
1671 /*
1672 * pool_cache_get:
1673 *
1674 * Get an object from a pool cache.
1675 */
1676 void *
pool_cache_get(struct pool_cache * pc,int flags)1677 pool_cache_get(struct pool_cache *pc, int flags)
1678 {
1679 struct pool_cache_group *pcg;
1680 void *object;
1681
1682 #ifdef LOCKDEBUG
1683 if (flags & PR_WAITOK)
1684 simple_lock_only_held(NULL, "pool_cache_get(PR_WAITOK)");
1685 #endif
1686
1687 simple_lock(&pc->pc_slock);
1688
1689 if ((pcg = pc->pc_allocfrom) == NULL) {
1690 TAILQ_FOREACH(pcg, &pc->pc_grouplist, pcg_list) {
1691 if (pcg->pcg_avail != 0) {
1692 pc->pc_allocfrom = pcg;
1693 goto have_group;
1694 }
1695 }
1696
1697 /*
1698 * No groups with any available objects. Allocate
1699 * a new object, construct it, and return it to
1700 * the caller. We will allocate a group, if necessary,
1701 * when the object is freed back to the cache.
1702 */
1703 pc->pc_misses++;
1704 simple_unlock(&pc->pc_slock);
1705 object = pool_get(pc->pc_pool, flags);
1706 if (object != NULL && pc->pc_ctor != NULL) {
1707 if ((*pc->pc_ctor)(pc->pc_arg, object, flags) != 0) {
1708 pool_put(pc->pc_pool, object);
1709 return (NULL);
1710 }
1711 }
1712 return (object);
1713 }
1714
1715 have_group:
1716 pc->pc_hits++;
1717 pc->pc_nitems--;
1718 object = pcg_get(pcg);
1719
1720 if (pcg->pcg_avail == 0)
1721 pc->pc_allocfrom = NULL;
1722
1723 simple_unlock(&pc->pc_slock);
1724
1725 return (object);
1726 }
1727
1728 /*
1729 * pool_cache_put:
1730 *
1731 * Put an object back to the pool cache.
1732 */
1733 void
pool_cache_put(struct pool_cache * pc,void * object)1734 pool_cache_put(struct pool_cache *pc, void *object)
1735 {
1736 struct pool_cache_group *pcg;
1737 int s;
1738
1739 simple_lock(&pc->pc_slock);
1740
1741 if ((pcg = pc->pc_freeto) == NULL) {
1742 TAILQ_FOREACH(pcg, &pc->pc_grouplist, pcg_list) {
1743 if (pcg->pcg_avail != PCG_NOBJECTS) {
1744 pc->pc_freeto = pcg;
1745 goto have_group;
1746 }
1747 }
1748
1749 /*
1750 * No empty groups to free the object to. Attempt to
1751 * allocate one.
1752 */
1753 simple_unlock(&pc->pc_slock);
1754 s = splvm();
1755 pcg = pool_get(&pcgpool, PR_NOWAIT);
1756 splx(s);
1757 if (pcg != NULL) {
1758 memset(pcg, 0, sizeof(*pcg));
1759 simple_lock(&pc->pc_slock);
1760 pc->pc_ngroups++;
1761 TAILQ_INSERT_TAIL(&pc->pc_grouplist, pcg, pcg_list);
1762 if (pc->pc_freeto == NULL)
1763 pc->pc_freeto = pcg;
1764 goto have_group;
1765 }
1766
1767 /*
1768 * Unable to allocate a cache group; destruct the object
1769 * and free it back to the pool.
1770 */
1771 pool_cache_destruct_object(pc, object);
1772 return;
1773 }
1774
1775 have_group:
1776 pc->pc_nitems++;
1777 pcg_put(pcg, object);
1778
1779 if (pcg->pcg_avail == PCG_NOBJECTS)
1780 pc->pc_freeto = NULL;
1781
1782 simple_unlock(&pc->pc_slock);
1783 }
1784
1785 /*
1786 * pool_cache_destruct_object:
1787 *
1788 * Force destruction of an object and its release back into
1789 * the pool.
1790 */
1791 void
pool_cache_destruct_object(struct pool_cache * pc,void * object)1792 pool_cache_destruct_object(struct pool_cache *pc, void *object)
1793 {
1794
1795 if (pc->pc_dtor != NULL)
1796 (*pc->pc_dtor)(pc->pc_arg, object);
1797 pool_put(pc->pc_pool, object);
1798 }
1799
1800 /*
1801 * pool_cache_do_invalidate:
1802 *
1803 * This internal function implements pool_cache_invalidate() and
1804 * pool_cache_reclaim().
1805 */
1806 void
pool_cache_do_invalidate(struct pool_cache * pc,int free_groups,void (* putit)(struct pool *,void *))1807 pool_cache_do_invalidate(struct pool_cache *pc, int free_groups,
1808 void (*putit)(struct pool *, void *))
1809 {
1810 struct pool_cache_group *pcg, *npcg;
1811 void *object;
1812 int s;
1813
1814 for (pcg = TAILQ_FIRST(&pc->pc_grouplist); pcg != NULL;
1815 pcg = npcg) {
1816 npcg = TAILQ_NEXT(pcg, pcg_list);
1817 while (pcg->pcg_avail != 0) {
1818 pc->pc_nitems--;
1819 object = pcg_get(pcg);
1820 if (pcg->pcg_avail == 0 && pc->pc_allocfrom == pcg)
1821 pc->pc_allocfrom = NULL;
1822 if (pc->pc_dtor != NULL)
1823 (*pc->pc_dtor)(pc->pc_arg, object);
1824 (*putit)(pc->pc_pool, object);
1825 }
1826 if (free_groups) {
1827 pc->pc_ngroups--;
1828 TAILQ_REMOVE(&pc->pc_grouplist, pcg, pcg_list);
1829 if (pc->pc_freeto == pcg)
1830 pc->pc_freeto = NULL;
1831 s = splvm();
1832 pool_put(&pcgpool, pcg);
1833 splx(s);
1834 }
1835 }
1836 }
1837
1838 /*
1839 * pool_cache_invalidate:
1840 *
1841 * Invalidate a pool cache (destruct and release all of the
1842 * cached objects).
1843 */
1844 void
pool_cache_invalidate(struct pool_cache * pc)1845 pool_cache_invalidate(struct pool_cache *pc)
1846 {
1847
1848 simple_lock(&pc->pc_slock);
1849 pool_cache_do_invalidate(pc, 0, pool_put);
1850 simple_unlock(&pc->pc_slock);
1851 }
1852
1853 /*
1854 * pool_cache_reclaim:
1855 *
1856 * Reclaim a pool cache for pool_reclaim().
1857 */
1858 void
pool_cache_reclaim(struct pool_cache * pc)1859 pool_cache_reclaim(struct pool_cache *pc)
1860 {
1861
1862 simple_lock(&pc->pc_slock);
1863 pool_cache_do_invalidate(pc, 1, pool_do_put);
1864 simple_unlock(&pc->pc_slock);
1865 }
1866
1867 /*
1868 * We have three different sysctls.
1869 * kern.pool.npools - the number of pools.
1870 * kern.pool.pool.<pool#> - the pool struct for the pool#.
1871 * kern.pool.name.<pool#> - the name for pool#.[6~
1872 */
1873 int
sysctl_dopool(int * name,u_int namelen,char * where,size_t * sizep)1874 sysctl_dopool(int *name, u_int namelen, char *where, size_t *sizep)
1875 {
1876 struct pool *pp, *foundpool = NULL;
1877 size_t buflen = where != NULL ? *sizep : 0;
1878 int npools = 0, s;
1879 unsigned int lookfor;
1880 size_t len;
1881
1882 switch (*name) {
1883 case KERN_POOL_NPOOLS:
1884 if (namelen != 1 || buflen != sizeof(int))
1885 return (EINVAL);
1886 lookfor = 0;
1887 break;
1888 case KERN_POOL_NAME:
1889 if (namelen != 2 || buflen < 1)
1890 return (EINVAL);
1891 lookfor = name[1];
1892 break;
1893 case KERN_POOL_POOL:
1894 if (namelen != 2 || buflen != sizeof(struct pool))
1895 return (EINVAL);
1896 lookfor = name[1];
1897 break;
1898 default:
1899 return (EINVAL);
1900 }
1901
1902 s = splvm();
1903 simple_lock(&pool_head_slock);
1904
1905 TAILQ_FOREACH(pp, &pool_head, pr_poollist) {
1906 npools++;
1907 if (lookfor == pp->pr_serial) {
1908 foundpool = pp;
1909 break;
1910 }
1911 }
1912
1913 simple_unlock(&pool_head_slock);
1914 splx(s);
1915
1916 if (lookfor != 0 && foundpool == NULL)
1917 return (ENOENT);
1918
1919 switch (*name) {
1920 case KERN_POOL_NPOOLS:
1921 return copyout(&npools, where, buflen);
1922 case KERN_POOL_NAME:
1923 len = strlen(foundpool->pr_wchan) + 1;
1924 if (*sizep < len)
1925 return (ENOMEM);
1926 *sizep = len;
1927 return copyout(foundpool->pr_wchan, where, len);
1928 case KERN_POOL_POOL:
1929 return copyout(foundpool, where, buflen);
1930 }
1931 /* NOTREACHED */
1932 return (0); /* XXX - Stupid gcc */
1933 }
1934
1935 /*
1936 * Pool backend allocators.
1937 *
1938 * Each pool has a backend allocator that handles allocation, deallocation
1939 * and any additional draining that might be needed.
1940 */
1941 void *pool_page_alloc_kmem(struct pool *, int);
1942 void pool_page_free_kmem(struct pool *, void *);
1943 void *pool_page_alloc_oldnointr(struct pool *, int);
1944 void pool_page_free_oldnointr(struct pool *, void *);
1945 void *pool_page_alloc(struct pool *, int);
1946 void pool_page_free(struct pool *, void *);
1947
1948 /* old default allocator, interrupt safe */
1949 struct pool_allocator pool_allocator_kmem = {
1950 pool_page_alloc_kmem, pool_page_free_kmem, 0,
1951 };
1952 /* previous nointr. handles large allocations safely */
1953 struct pool_allocator pool_allocator_oldnointr = {
1954 pool_page_alloc_oldnointr, pool_page_free_oldnointr, 0,
1955 };
1956 /* safe for interrupts, name preserved for compat
1957 * this is the default allocator */
1958 struct pool_allocator pool_allocator_nointr = {
1959 pool_page_alloc, pool_page_free, 0,
1960 };
1961
1962 /*
1963 * XXX - we have at least three different resources for the same allocation
1964 * and each resource can be depleted. First we have the ready elements in
1965 * the pool. Then we have the resource (typically a vm_map) for this
1966 * allocator, then we have physical memory. Waiting for any of these can
1967 * be unnecessary when any other is freed, but the kernel doesn't support
1968 * sleeping on multiple addresses, so we have to fake. The caller sleeps on
1969 * the pool (so that we can be awakened when an item is returned to the pool),
1970 * but we set PA_WANT on the allocator. When a page is returned to
1971 * the allocator and PA_WANT is set pool_allocator_free will wakeup all
1972 * sleeping pools belonging to this allocator. (XXX - thundering herd).
1973 * We also wake up the allocator in case someone without a pool (malloc)
1974 * is sleeping waiting for this allocator.
1975 */
1976
1977 void *
pool_allocator_alloc(struct pool * org,int flags)1978 pool_allocator_alloc(struct pool *org, int flags)
1979 {
1980 struct pool_allocator *pa = org->pr_alloc;
1981 int freed;
1982 void *res;
1983 int s;
1984
1985 do {
1986 if ((res = (*pa->pa_alloc)(org, flags)) != NULL)
1987 return (res);
1988 if ((flags & PR_WAITOK) == 0) {
1989 /*
1990 * We only run the drain hook here if PR_NOWAIT.
1991 * In other cases the hook will be run in
1992 * pool_reclaim.
1993 */
1994 if (org->pr_drain_hook != NULL) {
1995 (*org->pr_drain_hook)(org->pr_drain_hook_arg,
1996 flags);
1997 if ((res = (*pa->pa_alloc)(org, flags)) != NULL)
1998 return (res);
1999 }
2000 break;
2001 }
2002 s = splvm();
2003 simple_lock(&pa->pa_slock);
2004 freed = pool_allocator_drain(pa, org, 1);
2005 simple_unlock(&pa->pa_slock);
2006 splx(s);
2007 } while (freed);
2008 return (NULL);
2009 }
2010
2011 void
pool_allocator_free(struct pool * pp,void * v)2012 pool_allocator_free(struct pool *pp, void *v)
2013 {
2014 struct pool_allocator *pa = pp->pr_alloc;
2015 int s;
2016
2017 (*pa->pa_free)(pp, v);
2018
2019 s = splvm();
2020 simple_lock(&pa->pa_slock);
2021 if ((pa->pa_flags & PA_WANT) == 0) {
2022 simple_unlock(&pa->pa_slock);
2023 splx(s);
2024 return;
2025 }
2026
2027 TAILQ_FOREACH(pp, &pa->pa_list, pr_alloc_list) {
2028 simple_lock(&pp->pr_slock);
2029 if ((pp->pr_flags & PR_WANTED) != 0) {
2030 pp->pr_flags &= ~PR_WANTED;
2031 wakeup(pp);
2032 }
2033 simple_unlock(&pp->pr_slock);
2034 }
2035 pa->pa_flags &= ~PA_WANT;
2036 simple_unlock(&pa->pa_slock);
2037 splx(s);
2038 }
2039
2040 /*
2041 * Drain all pools, except 'org', that use this allocator.
2042 *
2043 * Must be called at appropriate spl level and with the allocator locked.
2044 *
2045 * We do this to reclaim va space. pa_alloc is responsible
2046 * for waiting for physical memory.
2047 * XXX - we risk looping forever if start if someone calls
2048 * pool_destroy on 'start'. But there is no other way to
2049 * have potentially sleeping pool_reclaim, non-sleeping
2050 * locks on pool_allocator and some stirring of drained
2051 * pools in the allocator.
2052 * XXX - maybe we should use pool_head_slock for locking
2053 * the allocators?
2054 */
2055 int
pool_allocator_drain(struct pool_allocator * pa,struct pool * org,int need)2056 pool_allocator_drain(struct pool_allocator *pa, struct pool *org, int need)
2057 {
2058 struct pool *pp, *start;
2059 int freed;
2060
2061 freed = 0;
2062
2063 pp = start = TAILQ_FIRST(&pa->pa_list);
2064 do {
2065 TAILQ_REMOVE(&pa->pa_list, pp, pr_alloc_list);
2066 TAILQ_INSERT_TAIL(&pa->pa_list, pp, pr_alloc_list);
2067 if (pp == org)
2068 continue;
2069 simple_unlock(&pa->pa_list);
2070 freed = pool_reclaim(pp)
2071 simple_lock(&pa->pa_list);
2072 } while ((pp = TAILQ_FIRST(&pa->pa_list)) != start && (freed < need));
2073
2074 if (!freed) {
2075 /*
2076 * We set PA_WANT here, the caller will most likely
2077 * sleep waiting for pages (if not, this won't hurt
2078 * that much) and there is no way to set this in the
2079 * caller without violating locking order.
2080 */
2081 pa->pa_flags |= PA_WANT;
2082 }
2083
2084 return (freed);
2085 }
2086
2087 void *
pool_page_alloc(struct pool * pp,int flags)2088 pool_page_alloc(struct pool *pp, int flags)
2089 {
2090 boolean_t waitok = (flags & PR_WAITOK) ? TRUE : FALSE;
2091
2092 return (uvm_km_getpage(waitok));
2093 }
2094
2095 void
pool_page_free(struct pool * pp,void * v)2096 pool_page_free(struct pool *pp, void *v)
2097 {
2098
2099 uvm_km_putpage(v);
2100 }
2101
2102 void *
pool_page_alloc_kmem(struct pool * pp,int flags)2103 pool_page_alloc_kmem(struct pool *pp, int flags)
2104 {
2105 boolean_t waitok = (flags & PR_WAITOK) ? TRUE : FALSE;
2106
2107 return ((void *)uvm_km_alloc_poolpage1(kmem_map, uvmexp.kmem_object,
2108 waitok));
2109 }
2110
2111 void
pool_page_free_kmem(struct pool * pp,void * v)2112 pool_page_free_kmem(struct pool *pp, void *v)
2113 {
2114
2115 uvm_km_free_poolpage1(kmem_map, (vaddr_t)v);
2116 }
2117
2118 void *
pool_page_alloc_oldnointr(struct pool * pp,int flags)2119 pool_page_alloc_oldnointr(struct pool *pp, int flags)
2120 {
2121 boolean_t waitok = (flags & PR_WAITOK) ? TRUE : FALSE;
2122
2123 splassert(IPL_NONE);
2124
2125 return ((void *)uvm_km_alloc_poolpage1(kernel_map, uvm.kernel_object,
2126 waitok));
2127 }
2128
2129 void
pool_page_free_oldnointr(struct pool * pp,void * v)2130 pool_page_free_oldnointr(struct pool *pp, void *v)
2131 {
2132 splassert(IPL_NONE);
2133
2134 uvm_km_free_poolpage1(kernel_map, (vaddr_t)v);
2135 }
2136