Bug Summary

File:obj-scan-build/../kern/slab.c
Location:line 707, column 16
Description:Assigned value is garbage or undefined

Annotated Source Code

1/*
2 * Copyright (c) 2011 Free Software Foundation.
3 *
4 * This program is free software; you can redistribute it and/or modify
5 * it under the terms of the GNU General Public License as published by
6 * the Free Software Foundation; either version 2 of the License, or
7 * (at your option) any later version.
8 *
9 * This program is distributed in the hope that it will be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 * GNU General Public License for more details.
13 *
14 * You should have received a copy of the GNU General Public License along
15 * with this program; if not, write to the Free Software Foundation, Inc.,
16 * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
17 */
18
19/*
20 * Copyright (c) 2010, 2011 Richard Braun.
21 * All rights reserved.
22 *
23 * Redistribution and use in source and binary forms, with or without
24 * modification, are permitted provided that the following conditions
25 * are met:
26 * 1. Redistributions of source code must retain the above copyright
27 * notice, this list of conditions and the following disclaimer.
28 * 2. Redistributions in binary form must reproduce the above copyright
29 * notice, this list of conditions and the following disclaimer in the
30 * documentation and/or other materials provided with the distribution.
31 *
32 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
33 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
34 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
35 * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
36 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
37 * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
38 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
39 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
40 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
41 * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
42 *
43 *
44 * Object caching and general purpose memory allocator.
45 *
46 * This allocator is based on the paper "The Slab Allocator: An Object-Caching
47 * Kernel Memory Allocator" by Jeff Bonwick.
48 *
49 * It allows the allocation of objects (i.e. fixed-size typed buffers) from
50 * caches and is efficient in both space and time. This implementation follows
51 * many of the indications from the paper mentioned. The most notable
52 * differences are outlined below.
53 *
54 * The per-cache self-scaling hash table for buffer-to-bufctl conversion,
55 * described in 3.2.3 "Slab Layout for Large Objects", has been replaced by
56 * a red-black tree storing slabs, sorted by address. The use of a
57 * self-balancing tree for buffer-to-slab conversions provides a few advantages
58 * over a hash table. Unlike a hash table, a BST provides a "lookup nearest"
59 * operation, so obtaining the slab data (whether it is embedded in the slab or
60 * off slab) from a buffer address simply consists of a "lookup nearest towards
61 * 0" tree search. Storing slabs instead of buffers also considerably reduces
62 * the number of elements to retain. Finally, a self-balancing tree is a true
63 * self-scaling data structure, whereas a hash table requires periodic
64 * maintenance and complete resizing, which is expensive. The only drawback is
65 * that releasing a buffer to the slab layer takes logarithmic time instead of
66 * constant time. But as the data set size is kept reasonable (because slabs
67 * are stored instead of buffers) and because the CPU pool layer services most
68 * requests, avoiding many accesses to the slab layer, it is considered an
69 * acceptable tradeoff.
70 *
71 * This implementation uses per-cpu pools of objects, which service most
72 * allocation requests. These pools act as caches (but are named differently
73 * to avoid confusion with CPU caches) that reduce contention on multiprocessor
74 * systems. When a pool is empty and cannot provide an object, it is filled by
75 * transferring multiple objects from the slab layer. The symmetric case is
76 * handled likewise.
77 */
78
79#include <string.h>
80#include <kern/assert.h>
81#include <kern/mach_clock.h>
82#include <kern/printf.h>
83#include <kern/slab.h>
84#include <kern/kalloc.h>
85#include <kern/cpu_number.h>
86#include <mach/vm_param.h>
87#include <mach/machine/vm_types.h>
88#include <vm/vm_kern.h>
89#include <vm/vm_types.h>
90#include <sys/types.h>
91
92#ifdef MACH_DEBUG1
93#include <mach_debug/slab_info.h>
94#endif
95
96/*
97 * Utility macros.
98 */
99#define ARRAY_SIZE(x)(sizeof(x) / sizeof((x)[0])) (sizeof(x) / sizeof((x)[0]))
100#define P2ALIGNED(x, a)(((x) & ((a) - 1)) == 0) (((x) & ((a) - 1)) == 0)
101#define ISP2(x)(((x) & ((x) - 1)) == 0) P2ALIGNED(x, x)(((x) & ((x) - 1)) == 0)
102#define P2ALIGN(x, a)((x) & -(a)) ((x) & -(a))
103#define P2ROUND(x, a)(-(-(x) & -(a))) (-(-(x) & -(a)))
104#define P2END(x, a)(-(~(x) & -(a))) (-(~(x) & -(a)))
105#define likely(expr)__builtin_expect(!!(expr), 1) __builtin_expect(!!(expr), 1)
106#define unlikely(expr)__builtin_expect(!!(expr), 0) __builtin_expect(!!(expr), 0)
107
108/*
109 * Minimum required alignment.
110 */
111#define KMEM_ALIGN_MIN8 8
112
113/*
114 * Minimum number of buffers per slab.
115 *
116 * This value is ignored when the slab size exceeds a threshold.
117 */
118#define KMEM_MIN_BUFS_PER_SLAB8 8
119
120/*
121 * Special slab size beyond which the minimum number of buffers per slab is
122 * ignored when computing the slab size of a cache.
123 */
124#define KMEM_SLAB_SIZE_THRESHOLD(8 * (1 << 12)) (8 * PAGE_SIZE(1 << 12))
125
126/*
127 * Special buffer size under which slab data is unconditionnally allocated
128 * from its associated slab.
129 */
130#define KMEM_BUF_SIZE_THRESHOLD((1 << 12) / 8) (PAGE_SIZE(1 << 12) / 8)
131
132/*
133 * Time (in ticks) between two garbage collection operations.
134 */
135#define KMEM_GC_INTERVAL(5 * hz) (5 * hz)
136
137/*
138 * The transfer size of a CPU pool is computed by dividing the pool size by
139 * this value.
140 */
141#define KMEM_CPU_POOL_TRANSFER_RATIO2 2
142
143/*
144 * Redzone guard word.
145 */
146#ifdef __LP64__
147#if _HOST_BIG_ENDIAN
148#define KMEM_REDZONE_WORD0xcefaedfeUL 0xfeedfacefeedfaceUL
149#else /* _HOST_BIG_ENDIAN */
150#define KMEM_REDZONE_WORD0xcefaedfeUL 0xcefaedfecefaedfeUL
151#endif /* _HOST_BIG_ENDIAN */
152#else /* __LP64__ */
153#if _HOST_BIG_ENDIAN
154#define KMEM_REDZONE_WORD0xcefaedfeUL 0xfeedfaceUL
155#else /* _HOST_BIG_ENDIAN */
156#define KMEM_REDZONE_WORD0xcefaedfeUL 0xcefaedfeUL
157#endif /* _HOST_BIG_ENDIAN */
158#endif /* __LP64__ */
159
160/*
161 * Redzone byte for padding.
162 */
163#define KMEM_REDZONE_BYTE0xbb 0xbb
164
165/*
166 * Size of the VM submap from which default backend functions allocate.
167 */
168#define KMEM_MAP_SIZE(128 * 1024 * 1024) (128 * 1024 * 1024)
169
170/*
171 * Shift for the first kalloc cache size.
172 */
173#define KALLOC_FIRST_SHIFT5 5
174
175/*
176 * Number of caches backing general purpose allocations.
177 */
178#define KALLOC_NR_CACHES13 13
179
180/*
181 * Values the buftag state member can take.
182 */
183#ifdef __LP64__
184#if _HOST_BIG_ENDIAN
185#define KMEM_BUFTAG_ALLOC0xedc810a1UL 0xa110c8eda110c8edUL
186#define KMEM_BUFTAG_FREE0x0cb1eef4UL 0xf4eeb10cf4eeb10cUL
187#else /* _HOST_BIG_ENDIAN */
188#define KMEM_BUFTAG_ALLOC0xedc810a1UL 0xedc810a1edc810a1UL
189#define KMEM_BUFTAG_FREE0x0cb1eef4UL 0x0cb1eef40cb1eef4UL
190#endif /* _HOST_BIG_ENDIAN */
191#else /* __LP64__ */
192#if _HOST_BIG_ENDIAN
193#define KMEM_BUFTAG_ALLOC0xedc810a1UL 0xa110c8edUL
194#define KMEM_BUFTAG_FREE0x0cb1eef4UL 0xf4eeb10cUL
195#else /* _HOST_BIG_ENDIAN */
196#define KMEM_BUFTAG_ALLOC0xedc810a1UL 0xedc810a1UL
197#define KMEM_BUFTAG_FREE0x0cb1eef4UL 0x0cb1eef4UL
198#endif /* _HOST_BIG_ENDIAN */
199#endif /* __LP64__ */
200
201/*
202 * Free and uninitialized patterns.
203 *
204 * These values are unconditionnally 64-bit wide since buffers are at least
205 * 8-byte aligned.
206 */
207#if _HOST_BIG_ENDIAN
208#define KMEM_FREE_PATTERN0xefbeaddeefbeaddeULL 0xdeadbeefdeadbeefULL
209#define KMEM_UNINIT_PATTERN0xfecaddbafecaddbaULL 0xbaddcafebaddcafeULL
210#else /* _HOST_BIG_ENDIAN */
211#define KMEM_FREE_PATTERN0xefbeaddeefbeaddeULL 0xefbeaddeefbeaddeULL
212#define KMEM_UNINIT_PATTERN0xfecaddbafecaddbaULL 0xfecaddbafecaddbaULL
213#endif /* _HOST_BIG_ENDIAN */
214
215/*
216 * Cache flags.
217 *
218 * The flags don't change once set and can be tested without locking.
219 */
220#define KMEM_CF_NO_CPU_POOL0x01 0x01 /* CPU pool layer disabled */
221#define KMEM_CF_SLAB_EXTERNAL0x02 0x02 /* Slab data is off slab */
222#define KMEM_CF_NO_RECLAIM0x04 0x04 /* Slabs are not reclaimable */
223#define KMEM_CF_VERIFY0x08 0x08 /* Debugging facilities enabled */
224#define KMEM_CF_DIRECT0x10 0x10 /* No buf-to-slab tree lookup */
225
226/*
227 * Options for kmem_cache_alloc_verify().
228 */
229#define KMEM_AV_NOCONSTRUCT0 0
230#define KMEM_AV_CONSTRUCT1 1
231
232/*
233 * Error codes for kmem_cache_error().
234 */
235#define KMEM_ERR_INVALID0 0 /* Invalid address being freed */
236#define KMEM_ERR_DOUBLEFREE1 1 /* Freeing already free address */
237#define KMEM_ERR_BUFTAG2 2 /* Invalid buftag content */
238#define KMEM_ERR_MODIFIED3 3 /* Buffer modified while free */
239#define KMEM_ERR_REDZONE4 4 /* Redzone violation */
240
241#if SLAB_USE_CPU_POOLS0
242/*
243 * Available CPU pool types.
244 *
245 * For each entry, the CPU pool size applies from the entry buf_size
246 * (excluded) up to (and including) the buf_size of the preceding entry.
247 *
248 * See struct kmem_cpu_pool_type for a description of the values.
249 */
250static struct kmem_cpu_pool_type kmem_cpu_pool_types[] = {
251 { 32768, 1, 0, NULL((void *) 0) },
252 { 4096, 8, CPU_L1_SIZE, NULL((void *) 0) },
253 { 256, 64, CPU_L1_SIZE, NULL((void *) 0) },
254 { 0, 128, CPU_L1_SIZE, NULL((void *) 0) }
255};
256
257/*
258 * Caches where CPU pool arrays are allocated from.
259 */
260static struct kmem_cache kmem_cpu_array_caches[ARRAY_SIZE(kmem_cpu_pool_types)(sizeof(kmem_cpu_pool_types) / sizeof((kmem_cpu_pool_types)[0
]))
];
261#endif /* SLAB_USE_CPU_POOLS */
262
263/*
264 * Cache for off slab data.
265 */
266static struct kmem_cache kmem_slab_cache;
267
268/*
269 * General purpose caches array.
270 */
271static struct kmem_cache kalloc_caches[KALLOC_NR_CACHES13];
272
273/*
274 * List of all caches managed by the allocator.
275 */
276static struct list kmem_cache_list;
277static unsigned int kmem_nr_caches;
278static simple_lock_data_t __attribute__((used)) kmem_cache_list_lock;
279
280/*
281 * VM submap for slab caches.
282 */
283static struct vm_map kmem_map_store;
284vm_map_t kmem_map = &kmem_map_store;
285
286/*
287 * Time of the last memory reclaim, in clock ticks.
288 */
289static unsigned long kmem_gc_last_tick;
290
291#define kmem_error(format, ...)printf("mem: error: %s(): " format "\n", __func__, ...) \
292 printf("mem: error: %s(): " format "\n", __func__, \
293 ## __VA_ARGS__)
294
295#define kmem_warn(format, ...)printf("mem: warning: %s(): " format "\n", __func__, ...) \
296 printf("mem: warning: %s(): " format "\n", __func__, \
297 ## __VA_ARGS__)
298
299#define kmem_print(format, ...)printf(format "\n", ...) \
300 printf(format "\n", ## __VA_ARGS__)
301
302static void kmem_cache_error(struct kmem_cache *cache, void *buf, int error,
303 void *arg);
304static void * kmem_cache_alloc_from_slab(struct kmem_cache *cache);
305static void kmem_cache_free_to_slab(struct kmem_cache *cache, void *buf);
306
307static void * kmem_buf_verify_bytes(void *buf, void *pattern, size_t size)
308{
309 char *ptr, *pattern_ptr, *end;
310
311 end = buf + size;
312
313 for (ptr = buf, pattern_ptr = pattern; ptr < end; ptr++, pattern_ptr++)
314 if (*ptr != *pattern_ptr)
315 return ptr;
316
317 return NULL((void *) 0);
318}
319
320static void * kmem_buf_verify(void *buf, uint64_t pattern, vm_size_t size)
321{
322 uint64_t *ptr, *end;
323
324 assert(P2ALIGNED((unsigned long)buf, sizeof(uint64_t)))({ if (!(((((unsigned long)buf) & ((sizeof(uint64_t)) - 1
)) == 0))) Assert("P2ALIGNED((unsigned long)buf, sizeof(uint64_t))"
, "../kern/slab.c", 324); })
;
325 assert(P2ALIGNED(size, sizeof(uint64_t)))({ if (!((((size) & ((sizeof(uint64_t)) - 1)) == 0))) Assert
("P2ALIGNED(size, sizeof(uint64_t))", "../kern/slab.c", 325);
})
;
326
327 end = buf + size;
328
329 for (ptr = buf; ptr < end; ptr++)
330 if (*ptr != pattern)
331 return kmem_buf_verify_bytes(ptr, &pattern, sizeof(pattern));
332
333 return NULL((void *) 0);
334}
335
336static void kmem_buf_fill(void *buf, uint64_t pattern, size_t size)
337{
338 uint64_t *ptr, *end;
339
340 assert(P2ALIGNED((unsigned long)buf, sizeof(uint64_t)))({ if (!(((((unsigned long)buf) & ((sizeof(uint64_t)) - 1
)) == 0))) Assert("P2ALIGNED((unsigned long)buf, sizeof(uint64_t))"
, "../kern/slab.c", 340); })
;
341 assert(P2ALIGNED(size, sizeof(uint64_t)))({ if (!((((size) & ((sizeof(uint64_t)) - 1)) == 0))) Assert
("P2ALIGNED(size, sizeof(uint64_t))", "../kern/slab.c", 341);
})
;
342
343 end = buf + size;
344
345 for (ptr = buf; ptr < end; ptr++)
346 *ptr = pattern;
347}
348
349static void * kmem_buf_verify_fill(void *buf, uint64_t old, uint64_t new,
350 size_t size)
351{
352 uint64_t *ptr, *end;
353
354 assert(P2ALIGNED((unsigned long)buf, sizeof(uint64_t)))({ if (!(((((unsigned long)buf) & ((sizeof(uint64_t)) - 1
)) == 0))) Assert("P2ALIGNED((unsigned long)buf, sizeof(uint64_t))"
, "../kern/slab.c", 354); })
;
355 assert(P2ALIGNED(size, sizeof(uint64_t)))({ if (!((((size) & ((sizeof(uint64_t)) - 1)) == 0))) Assert
("P2ALIGNED(size, sizeof(uint64_t))", "../kern/slab.c", 355);
})
;
356
357 end = buf + size;
358
359 for (ptr = buf; ptr < end; ptr++) {
360 if (*ptr != old)
361 return kmem_buf_verify_bytes(ptr, &old, sizeof(old));
362
363 *ptr = new;
364 }
365
366 return NULL((void *) 0);
367}
368
369static inline union kmem_bufctl *
370kmem_buf_to_bufctl(void *buf, struct kmem_cache *cache)
371{
372 return (union kmem_bufctl *)(buf + cache->bufctl_dist);
373}
374
375static inline struct kmem_buftag *
376kmem_buf_to_buftag(void *buf, struct kmem_cache *cache)
377{
378 return (struct kmem_buftag *)(buf + cache->buftag_dist);
379}
380
381static inline void * kmem_bufctl_to_buf(union kmem_bufctl *bufctl,
382 struct kmem_cache *cache)
383{
384 return (void *)bufctl - cache->bufctl_dist;
385}
386
387static vm_offset_t kmem_pagealloc(vm_size_t size)
388{
389 vm_offset_t addr;
390 kern_return_t kr;
391
392 kr = kmem_alloc_wired(kmem_map, &addr, size);
393
394 if (kr != KERN_SUCCESS0)
395 return 0;
396
397 return addr;
398}
399
400static void kmem_pagefree(vm_offset_t ptr, vm_size_t size)
401{
402 kmem_free(kmem_map, ptr, size);
403}
404
405static void kmem_slab_create_verify(struct kmem_slab *slab,
406 struct kmem_cache *cache)
407{
408 struct kmem_buftag *buftag;
409 size_t buf_size;
410 unsigned long buffers;
411 void *buf;
412
413 buf_size = cache->buf_size;
414 buf = slab->addr;
415 buftag = kmem_buf_to_buftag(buf, cache);
416
417 for (buffers = cache->bufs_per_slab; buffers != 0; buffers--) {
418 kmem_buf_fill(buf, KMEM_FREE_PATTERN0xefbeaddeefbeaddeULL, cache->bufctl_dist);
419 buftag->state = KMEM_BUFTAG_FREE0x0cb1eef4UL;
420 buf += buf_size;
421 buftag = kmem_buf_to_buftag(buf, cache);
422 }
423}
424
425/*
426 * Create an empty slab for a cache.
427 *
428 * The caller must drop all locks before calling this function.
429 */
430static struct kmem_slab * kmem_slab_create(struct kmem_cache *cache,
431 size_t color)
432{
433 struct kmem_slab *slab;
434 union kmem_bufctl *bufctl;
435 size_t buf_size;
436 unsigned long buffers;
437 void *slab_buf;
438
439 if (cache->slab_alloc_fn == NULL((void *) 0))
440 slab_buf = (void *)kmem_pagealloc(cache->slab_size);
441 else
442 slab_buf = (void *)cache->slab_alloc_fn(cache->slab_size);
443
444 if (slab_buf == NULL((void *) 0))
445 return NULL((void *) 0);
446
447 if (cache->flags & KMEM_CF_SLAB_EXTERNAL0x02) {
448 assert(!(cache->flags & KMEM_CF_NO_RECLAIM))({ if (!(!(cache->flags & 0x04))) Assert("!(cache->flags & KMEM_CF_NO_RECLAIM)"
, "../kern/slab.c", 448); })
;
449 slab = (struct kmem_slab *)kmem_cache_alloc(&kmem_slab_cache);
450
451 if (slab == NULL((void *) 0)) {
452 if (cache->slab_free_fn == NULL((void *) 0))
453 kmem_pagefree((vm_offset_t)slab_buf, cache->slab_size);
454 else
455 cache->slab_free_fn((vm_offset_t)slab_buf, cache->slab_size);
456
457 return NULL((void *) 0);
458 }
459 } else {
460 slab = (struct kmem_slab *)(slab_buf + cache->slab_size) - 1;
461 }
462
463 list_node_init(&slab->list_node);
464 rbtree_node_init(&slab->tree_node);
465 slab->nr_refs = 0;
466 slab->first_free = NULL((void *) 0);
467 slab->addr = slab_buf + color;
468
469 buf_size = cache->buf_size;
470 bufctl = kmem_buf_to_bufctl(slab->addr, cache);
471
472 for (buffers = cache->bufs_per_slab; buffers != 0; buffers--) {
473 bufctl->next = slab->first_free;
474 slab->first_free = bufctl;
475 bufctl = (union kmem_bufctl *)((void *)bufctl + buf_size);
476 }
477
478 if (cache->flags & KMEM_CF_VERIFY0x08)
479 kmem_slab_create_verify(slab, cache);
480
481 return slab;
482}
483
484static void kmem_slab_destroy_verify(struct kmem_slab *slab,
485 struct kmem_cache *cache)
486{
487 struct kmem_buftag *buftag;
488 size_t buf_size;
489 unsigned long buffers;
490 void *buf, *addr;
491
492 buf_size = cache->buf_size;
493 buf = slab->addr;
494 buftag = kmem_buf_to_buftag(buf, cache);
495
496 for (buffers = cache->bufs_per_slab; buffers != 0; buffers--) {
497 if (buftag->state != KMEM_BUFTAG_FREE0x0cb1eef4UL)
498 kmem_cache_error(cache, buf, KMEM_ERR_BUFTAG2, buftag);
499
500 addr = kmem_buf_verify(buf, KMEM_FREE_PATTERN0xefbeaddeefbeaddeULL, cache->bufctl_dist);
501
502 if (addr != NULL((void *) 0))
503 kmem_cache_error(cache, buf, KMEM_ERR_MODIFIED3, addr);
504
505 buf += buf_size;
506 buftag = kmem_buf_to_buftag(buf, cache);
507 }
508}
509
510/*
511 * Destroy a slab.
512 *
513 * The caller must drop all locks before calling this function.
514 */
515static void kmem_slab_destroy(struct kmem_slab *slab, struct kmem_cache *cache)
516{
517 vm_offset_t slab_buf;
518
519 assert(slab->nr_refs == 0)({ if (!(slab->nr_refs == 0)) Assert("slab->nr_refs == 0"
, "../kern/slab.c", 519); })
;
520 assert(slab->first_free != NULL)({ if (!(slab->first_free != ((void *) 0))) Assert("slab->first_free != NULL"
, "../kern/slab.c", 520); })
;
521 assert(!(cache->flags & KMEM_CF_NO_RECLAIM))({ if (!(!(cache->flags & 0x04))) Assert("!(cache->flags & KMEM_CF_NO_RECLAIM)"
, "../kern/slab.c", 521); })
;
522
523 if (cache->flags & KMEM_CF_VERIFY0x08)
524 kmem_slab_destroy_verify(slab, cache);
525
526 slab_buf = (vm_offset_t)P2ALIGN((unsigned long)slab->addr, PAGE_SIZE)(((unsigned long)slab->addr) & -((1 << 12)));
527
528 if (cache->slab_free_fn == NULL((void *) 0))
529 kmem_pagefree(slab_buf, cache->slab_size);
530 else
531 cache->slab_free_fn(slab_buf, cache->slab_size);
532
533 if (cache->flags & KMEM_CF_SLAB_EXTERNAL0x02)
534 kmem_cache_free(&kmem_slab_cache, (vm_offset_t)slab);
535}
536
537static inline int kmem_slab_use_tree(int flags)
538{
539 return !(flags & KMEM_CF_DIRECT0x10) || (flags & KMEM_CF_VERIFY0x08);
540}
541
542static inline int kmem_slab_cmp_lookup(const void *addr,
543 const struct rbtree_node *node)
544{
545 struct kmem_slab *slab;
546
547 slab = rbtree_entry(node, struct kmem_slab, tree_node)((struct kmem_slab *)((char *)node - __builtin_offsetof (struct
kmem_slab, tree_node)))
;
548
549 if (addr == slab->addr)
550 return 0;
551 else if (addr < slab->addr)
552 return -1;
553 else
554 return 1;
555}
556
557static inline int kmem_slab_cmp_insert(const struct rbtree_node *a,
558 const struct rbtree_node *b)
559{
560 struct kmem_slab *slab;
561
562 slab = rbtree_entry(a, struct kmem_slab, tree_node)((struct kmem_slab *)((char *)a - __builtin_offsetof (struct kmem_slab
, tree_node)))
;
563 return kmem_slab_cmp_lookup(slab->addr, b);
564}
565
566#if SLAB_USE_CPU_POOLS0
567static void kmem_cpu_pool_init(struct kmem_cpu_pool *cpu_pool,
568 struct kmem_cache *cache)
569{
570 simple_lock_init(&cpu_pool->lock);
571 cpu_pool->flags = cache->flags;
572 cpu_pool->size = 0;
573 cpu_pool->transfer_size = 0;
574 cpu_pool->nr_objs = 0;
575 cpu_pool->array = NULL((void *) 0);
576}
577
578/*
579 * Return a CPU pool.
580 *
581 * This function will generally return the pool matching the CPU running the
582 * calling thread. Because of context switches and thread migration, the
583 * caller might be running on another processor after this function returns.
584 * Although not optimal, this should rarely happen, and it doesn't affect the
585 * allocator operations in any other way, as CPU pools are always valid, and
586 * their access is serialized by a lock.
587 */
588static inline struct kmem_cpu_pool * kmem_cpu_pool_get(struct kmem_cache *cache)
589{
590 return &cache->cpu_pools[cpu_number()(0)];
591}
592
593static inline void kmem_cpu_pool_build(struct kmem_cpu_pool *cpu_pool,
594 struct kmem_cache *cache, void **array)
595{
596 cpu_pool->size = cache->cpu_pool_type->array_size;
597 cpu_pool->transfer_size = (cpu_pool->size
598 + KMEM_CPU_POOL_TRANSFER_RATIO2 - 1)
599 / KMEM_CPU_POOL_TRANSFER_RATIO2;
600 cpu_pool->array = array;
601}
602
603static inline void * kmem_cpu_pool_pop(struct kmem_cpu_pool *cpu_pool)
604{
605 cpu_pool->nr_objs--;
606 return cpu_pool->array[cpu_pool->nr_objs];
607}
608
609static inline void kmem_cpu_pool_push(struct kmem_cpu_pool *cpu_pool, void *obj)
610{
611 cpu_pool->array[cpu_pool->nr_objs] = obj;
612 cpu_pool->nr_objs++;
613}
614
615static int kmem_cpu_pool_fill(struct kmem_cpu_pool *cpu_pool,
616 struct kmem_cache *cache)
617{
618 kmem_cache_ctor_t ctor;
619 void *buf;
620 int i;
621
622 ctor = (cpu_pool->flags & KMEM_CF_VERIFY0x08) ? NULL((void *) 0) : cache->ctor;
623
624 simple_lock(&cache->lock);
625
626 for (i = 0; i < cpu_pool->transfer_size; i++) {
627 buf = kmem_cache_alloc_from_slab(cache);
628
629 if (buf == NULL((void *) 0))
630 break;
631
632 if (ctor != NULL((void *) 0))
633 ctor(buf);
634
635 kmem_cpu_pool_push(cpu_pool, buf);
636 }
637
638 simple_unlock(&cache->lock);
639
640 return i;
641}
642
643static void kmem_cpu_pool_drain(struct kmem_cpu_pool *cpu_pool,
644 struct kmem_cache *cache)
645{
646 void *obj;
647 int i;
648
649 simple_lock(&cache->lock);
650
651 for (i = cpu_pool->transfer_size; i > 0; i--) {
652 obj = kmem_cpu_pool_pop(cpu_pool);
653 kmem_cache_free_to_slab(cache, obj);
654 }
655
656 simple_unlock(&cache->lock);
657}
658#endif /* SLAB_USE_CPU_POOLS */
659
660static void kmem_cache_error(struct kmem_cache *cache, void *buf, int error,
661 void *arg)
662{
663 struct kmem_buftag *buftag;
664
665 kmem_error("cache: %s, buffer: %p", cache->name, (void *)buf)printf("mem: error: %s(): " "cache: %s, buffer: %p" "\n", __func__
, cache->name, (void *)buf)
;
666
667 switch(error) {
668 case KMEM_ERR_INVALID0:
669 kmem_error("freeing invalid address")printf("mem: error: %s(): " "freeing invalid address" "\n", __func__
)
;
670 break;
671 case KMEM_ERR_DOUBLEFREE1:
672 kmem_error("attempting to free the same address twice")printf("mem: error: %s(): " "attempting to free the same address twice"
"\n", __func__)
;
673 break;
674 case KMEM_ERR_BUFTAG2:
675 buftag = arg;
676 kmem_error("invalid buftag content, buftag state: %p",printf("mem: error: %s(): " "invalid buftag content, buftag state: %p"
"\n", __func__, (void *)buftag->state)
677 (void *)buftag->state)printf("mem: error: %s(): " "invalid buftag content, buftag state: %p"
"\n", __func__, (void *)buftag->state)
;
678 break;
679 case KMEM_ERR_MODIFIED3:
680 kmem_error("free buffer modified, fault address: %p, "printf("mem: error: %s(): " "free buffer modified, fault address: %p, "
"offset in buffer: %td" "\n", __func__, arg, arg - buf)
681 "offset in buffer: %td", arg, arg - buf)printf("mem: error: %s(): " "free buffer modified, fault address: %p, "
"offset in buffer: %td" "\n", __func__, arg, arg - buf)
;
682 break;
683 case KMEM_ERR_REDZONE4:
684 kmem_error("write beyond end of buffer, fault address: %p, "printf("mem: error: %s(): " "write beyond end of buffer, fault address: %p, "
"offset in buffer: %td" "\n", __func__, arg, arg - buf)
685 "offset in buffer: %td", arg, arg - buf)printf("mem: error: %s(): " "write beyond end of buffer, fault address: %p, "
"offset in buffer: %td" "\n", __func__, arg, arg - buf)
;
686 break;
687 default:
688 kmem_error("unknown error")printf("mem: error: %s(): " "unknown error" "\n", __func__);
689 }
690
691 /*
692 * Never reached.
693 */
694}
695
696/*
697 * Compute an appropriate slab size for the given cache.
698 *
699 * Once the slab size is known, this function sets the related properties
700 * (buffers per slab and maximum color). It can also set the KMEM_CF_DIRECT
701 * and/or KMEM_CF_SLAB_EXTERNAL flags depending on the resulting layout.
702 */
703static void kmem_cache_compute_sizes(struct kmem_cache *cache, int flags)
704{
705 size_t i, buffers, buf_size, slab_size, free_slab_size, optimal_size;
706 size_t waste, waste_min;
707 int embed, optimal_embed = optimal_embed;
8
Assigned value is garbage or undefined
708
709 buf_size = cache->buf_size;
710
711 if (buf_size < KMEM_BUF_SIZE_THRESHOLD((1 << 12) / 8))
712 flags |= KMEM_CACHE_NOOFFSLAB0x2;
713
714 i = 0;
715 waste_min = (size_t)-1;
716
717 do {
718 i++;
719 slab_size = P2ROUND(i * buf_size, PAGE_SIZE)(-(-(i * buf_size) & -((1 << 12))));
720 free_slab_size = slab_size;
721
722 if (flags & KMEM_CACHE_NOOFFSLAB0x2)
723 free_slab_size -= sizeof(struct kmem_slab);
724
725 buffers = free_slab_size / buf_size;
726 waste = free_slab_size % buf_size;
727
728 if (buffers > i)
729 i = buffers;
730
731 if (flags & KMEM_CACHE_NOOFFSLAB0x2)
732 embed = 1;
733 else if (sizeof(struct kmem_slab) <= waste) {
734 embed = 1;
735 waste -= sizeof(struct kmem_slab);
736 } else {
737 embed = 0;
738 }
739
740 if (waste <= waste_min) {
741 waste_min = waste;
742 optimal_size = slab_size;
743 optimal_embed = embed;
744 }
745 } while ((buffers < KMEM_MIN_BUFS_PER_SLAB8)
746 && (slab_size < KMEM_SLAB_SIZE_THRESHOLD(8 * (1 << 12))));
747
748 assert(!(flags & KMEM_CACHE_NOOFFSLAB) || optimal_embed)({ if (!(!(flags & 0x2) || optimal_embed)) Assert("!(flags & KMEM_CACHE_NOOFFSLAB) || optimal_embed"
, "../kern/slab.c", 748); })
;
749
750 cache->slab_size = optimal_size;
751 slab_size = cache->slab_size - (optimal_embed
752 ? sizeof(struct kmem_slab)
753 : 0);
754 cache->bufs_per_slab = slab_size / buf_size;
755 cache->color_max = slab_size % buf_size;
756
757 if (cache->color_max >= PAGE_SIZE(1 << 12))
758 cache->color_max = PAGE_SIZE(1 << 12) - 1;
759
760 if (optimal_embed) {
761 if (cache->slab_size == PAGE_SIZE(1 << 12))
762 cache->flags |= KMEM_CF_DIRECT0x10;
763 } else {
764 cache->flags |= KMEM_CF_SLAB_EXTERNAL0x02;
765 }
766}
767
768void kmem_cache_init(struct kmem_cache *cache, const char *name,
769 size_t obj_size, size_t align, kmem_cache_ctor_t ctor,
770 kmem_slab_alloc_fn_t slab_alloc_fn,
771 kmem_slab_free_fn_t slab_free_fn, int flags)
772{
773#if SLAB_USE_CPU_POOLS0
774 struct kmem_cpu_pool_type *cpu_pool_type;
775 size_t i;
776#endif /* SLAB_USE_CPU_POOLS */
777 size_t buf_size;
778
779#if SLAB_VERIFY0
780 cache->flags = KMEM_CF_VERIFY0x08;
781#else /* SLAB_VERIFY */
782 cache->flags = 0;
783#endif /* SLAB_VERIFY */
784
785 if (flags & KMEM_CACHE_NOCPUPOOL0x1)
2
Taking false branch
786 cache->flags |= KMEM_CF_NO_CPU_POOL0x01;
787
788 if (flags & KMEM_CACHE_NORECLAIM0x4) {
3
Taking false branch
789 assert(slab_free_fn == NULL)({ if (!(slab_free_fn == ((void *) 0))) Assert("slab_free_fn == NULL"
, "../kern/slab.c", 789); })
;
790 flags |= KMEM_CACHE_NOOFFSLAB0x2;
791 cache->flags |= KMEM_CF_NO_RECLAIM0x04;
792 }
793
794 if (flags & KMEM_CACHE_VERIFY0x8)
4
Taking false branch
795 cache->flags |= KMEM_CF_VERIFY0x08;
796
797 if (align < KMEM_ALIGN_MIN8)
5
Taking true branch
798 align = KMEM_ALIGN_MIN8;
799
800 assert(obj_size > 0)({ if (!(obj_size > 0)) Assert("obj_size > 0", "../kern/slab.c"
, 800); })
;
801 assert(ISP2(align))({ if (!((((align) & ((align) - 1)) == 0))) Assert("ISP2(align)"
, "../kern/slab.c", 801); })
;
802 assert(align < PAGE_SIZE)({ if (!(align < (1 << 12))) Assert("align < PAGE_SIZE"
, "../kern/slab.c", 802); })
;
803
804 buf_size = P2ROUND(obj_size, align)(-(-(obj_size) & -(align)));
805
806 simple_lock_init(&cache->lock);
807 list_node_init(&cache->node);
808 list_init(&cache->partial_slabs);
809 list_init(&cache->free_slabs);
810 rbtree_init(&cache->active_slabs);
811 cache->obj_size = obj_size;
812 cache->align = align;
813 cache->buf_size = buf_size;
814 cache->bufctl_dist = buf_size - sizeof(union kmem_bufctl);
815 cache->color = 0;
816 cache->nr_objs = 0;
817 cache->nr_bufs = 0;
818 cache->nr_slabs = 0;
819 cache->nr_free_slabs = 0;
820 cache->ctor = ctor;
821 cache->slab_alloc_fn = slab_alloc_fn;
822 cache->slab_free_fn = slab_free_fn;
823 strncpy(cache->name, name, sizeof(cache->name));
824 cache->name[sizeof(cache->name) - 1] = '\0';
825 cache->buftag_dist = 0;
826 cache->redzone_pad = 0;
827
828 if (cache->flags & KMEM_CF_VERIFY0x08) {
6
Taking false branch
829 cache->bufctl_dist = buf_size;
830 cache->buftag_dist = cache->bufctl_dist + sizeof(union kmem_bufctl);
831 cache->redzone_pad = cache->bufctl_dist - cache->obj_size;
832 buf_size += sizeof(union kmem_bufctl) + sizeof(struct kmem_buftag);
833 buf_size = P2ROUND(buf_size, align)(-(-(buf_size) & -(align)));
834 cache->buf_size = buf_size;
835 }
836
837 kmem_cache_compute_sizes(cache, flags);
7
Calling 'kmem_cache_compute_sizes'
838
839#if SLAB_USE_CPU_POOLS0
840 for (cpu_pool_type = kmem_cpu_pool_types;
841 buf_size <= cpu_pool_type->buf_size;
842 cpu_pool_type++);
843
844 cache->cpu_pool_type = cpu_pool_type;
845
846 for (i = 0; i < ARRAY_SIZE(cache->cpu_pools)(sizeof(cache->cpu_pools) / sizeof((cache->cpu_pools)[0
]))
; i++)
847 kmem_cpu_pool_init(&cache->cpu_pools[i], cache);
848#endif /* SLAB_USE_CPU_POOLS */
849
850 simple_lock(&kmem_cache_list_lock);
851 list_insert_tail(&kmem_cache_list, &cache->node);
852 kmem_nr_caches++;
853 simple_unlock(&kmem_cache_list_lock);
854}
855
856static inline int kmem_cache_empty(struct kmem_cache *cache)
857{
858 return cache->nr_objs == cache->nr_bufs;
859}
860
861static int kmem_cache_grow(struct kmem_cache *cache)
862{
863 struct kmem_slab *slab;
864 size_t color;
865 int empty;
866
867 simple_lock(&cache->lock);
868
869 if (!kmem_cache_empty(cache)) {
870 simple_unlock(&cache->lock);
871 return 1;
872 }
873
874 color = cache->color;
875 cache->color += cache->align;
876
877 if (cache->color > cache->color_max)
878 cache->color = 0;
879
880 simple_unlock(&cache->lock);
881
882 slab = kmem_slab_create(cache, color);
883
884 simple_lock(&cache->lock);
885
886 if (slab != NULL((void *) 0)) {
887 list_insert_head(&cache->free_slabs, &slab->list_node);
888 cache->nr_bufs += cache->bufs_per_slab;
889 cache->nr_slabs++;
890 cache->nr_free_slabs++;
891 }
892
893 /*
894 * Even if our slab creation failed, another thread might have succeeded
895 * in growing the cache.
896 */
897 empty = kmem_cache_empty(cache);
898
899 simple_unlock(&cache->lock);
900
901 return !empty;
902}
903
904static void kmem_cache_reap(struct kmem_cache *cache)
905{
906 struct kmem_slab *slab;
907 struct list dead_slabs;
908 unsigned long nr_free_slabs;
909
910 if (cache->flags & KMEM_CF_NO_RECLAIM0x04)
911 return;
912
913 simple_lock(&cache->lock);
914 list_set_head(&dead_slabs, &cache->free_slabs);
915 list_init(&cache->free_slabs);
916 nr_free_slabs = cache->nr_free_slabs;
917 cache->nr_bufs -= cache->bufs_per_slab * nr_free_slabs;
918 cache->nr_slabs -= nr_free_slabs;
919 cache->nr_free_slabs = 0;
920 simple_unlock(&cache->lock);
921
922 while (!list_empty(&dead_slabs)) {
923 slab = list_first_entry(&dead_slabs, struct kmem_slab, list_node)((struct kmem_slab *)((char *)list_first(&dead_slabs) - __builtin_offsetof
(struct kmem_slab, list_node)))
;
924 list_remove(&slab->list_node);
925 kmem_slab_destroy(slab, cache);
926 nr_free_slabs--;
927 }
928
929 assert(nr_free_slabs == 0)({ if (!(nr_free_slabs == 0)) Assert("nr_free_slabs == 0", "../kern/slab.c"
, 929); })
;
930}
931
932/*
933 * Allocate a raw (unconstructed) buffer from the slab layer of a cache.
934 *
935 * The cache must be locked before calling this function.
936 */
937static void * kmem_cache_alloc_from_slab(struct kmem_cache *cache)
938{
939 struct kmem_slab *slab;
940 union kmem_bufctl *bufctl;
941
942 if (!list_empty(&cache->partial_slabs))
943 slab = list_first_entry(&cache->partial_slabs, struct kmem_slab,((struct kmem_slab *)((char *)list_first(&cache->partial_slabs
) - __builtin_offsetof (struct kmem_slab, list_node)))
944 list_node)((struct kmem_slab *)((char *)list_first(&cache->partial_slabs
) - __builtin_offsetof (struct kmem_slab, list_node)))
;
945 else if (!list_empty(&cache->free_slabs))
946 slab = list_first_entry(&cache->free_slabs, struct kmem_slab,((struct kmem_slab *)((char *)list_first(&cache->free_slabs
) - __builtin_offsetof (struct kmem_slab, list_node)))
947 list_node)((struct kmem_slab *)((char *)list_first(&cache->free_slabs
) - __builtin_offsetof (struct kmem_slab, list_node)))
;
948 else
949 return NULL((void *) 0);
950
951 bufctl = slab->first_free;
952 assert(bufctl != NULL)({ if (!(bufctl != ((void *) 0))) Assert("bufctl != NULL", "../kern/slab.c"
, 952); })
;
953 slab->first_free = bufctl->next;
954 slab->nr_refs++;
955 cache->nr_objs++;
956
957 if (slab->nr_refs == cache->bufs_per_slab) {
958 /* The slab has become complete */
959 list_remove(&slab->list_node);
960
961 if (slab->nr_refs == 1)
962 cache->nr_free_slabs--;
963 } else if (slab->nr_refs == 1) {
964 /*
965 * The slab has become partial. Insert the new slab at the end of
966 * the list to reduce fragmentation.
967 */
968 list_remove(&slab->list_node);
969 list_insert_tail(&cache->partial_slabs, &slab->list_node);
970 cache->nr_free_slabs--;
971 }
972
973 if ((slab->nr_refs == 1) && kmem_slab_use_tree(cache->flags))
974 rbtree_insert(&cache->active_slabs, &slab->tree_node,({ struct rbtree_node *___cur, *___prev; int ___diff, ___index
; ___prev = ((void *) 0); ___index = -1; ___cur = (&cache
->active_slabs)->root; while (___cur != ((void *) 0)) {
___diff = kmem_slab_cmp_insert(&slab->tree_node, ___cur
); ({ if (!(___diff != 0)) Assert("___diff != 0", "../kern/slab.c"
, 975); }); ___prev = ___cur; ___index = rbtree_d2i(___diff);
___cur = ___cur->children[___index]; } rbtree_insert_rebalance
(&cache->active_slabs, ___prev, ___index, &slab->
tree_node); })
975 kmem_slab_cmp_insert)({ struct rbtree_node *___cur, *___prev; int ___diff, ___index
; ___prev = ((void *) 0); ___index = -1; ___cur = (&cache
->active_slabs)->root; while (___cur != ((void *) 0)) {
___diff = kmem_slab_cmp_insert(&slab->tree_node, ___cur
); ({ if (!(___diff != 0)) Assert("___diff != 0", "../kern/slab.c"
, 975); }); ___prev = ___cur; ___index = rbtree_d2i(___diff);
___cur = ___cur->children[___index]; } rbtree_insert_rebalance
(&cache->active_slabs, ___prev, ___index, &slab->
tree_node); })
;
976
977 return kmem_bufctl_to_buf(bufctl, cache);
978}
979
980/*
981 * Release a buffer to the slab layer of a cache.
982 *
983 * The cache must be locked before calling this function.
984 */
985static void kmem_cache_free_to_slab(struct kmem_cache *cache, void *buf)
986{
987 struct kmem_slab *slab;
988 union kmem_bufctl *bufctl;
989
990 if (cache->flags & KMEM_CF_DIRECT0x10) {
991 assert(cache->slab_size == PAGE_SIZE)({ if (!(cache->slab_size == (1 << 12))) Assert("cache->slab_size == PAGE_SIZE"
, "../kern/slab.c", 991); })
;
992 slab = (struct kmem_slab *)P2END((unsigned long)buf, cache->slab_size)(-(~((unsigned long)buf) & -(cache->slab_size)))
993 - 1;
994 } else {
995 struct rbtree_node *node;
996
997 node = rbtree_lookup_nearest(&cache->active_slabs, buf,({ struct rbtree_node *___cur, *___prev; int ___diff, ___index
; ___prev = ((void *) 0); ___index = -1; ___cur = (&cache
->active_slabs)->root; while (___cur != ((void *) 0)) {
___diff = kmem_slab_cmp_lookup(buf, ___cur); if (___diff == 0
) break; ___prev = ___cur; ___index = rbtree_d2i(___diff); ___cur
= ___cur->children[___index]; } if (___cur == ((void *) 0
)) ___cur = rbtree_nearest(___prev, ___index, 0); ___cur; })
998 kmem_slab_cmp_lookup, RBTREE_LEFT)({ struct rbtree_node *___cur, *___prev; int ___diff, ___index
; ___prev = ((void *) 0); ___index = -1; ___cur = (&cache
->active_slabs)->root; while (___cur != ((void *) 0)) {
___diff = kmem_slab_cmp_lookup(buf, ___cur); if (___diff == 0
) break; ___prev = ___cur; ___index = rbtree_d2i(___diff); ___cur
= ___cur->children[___index]; } if (___cur == ((void *) 0
)) ___cur = rbtree_nearest(___prev, ___index, 0); ___cur; })
;
999 assert(node != NULL)({ if (!(node != ((void *) 0))) Assert("node != NULL", "../kern/slab.c"
, 999); })
;
1000 slab = rbtree_entry(node, struct kmem_slab, tree_node)((struct kmem_slab *)((char *)node - __builtin_offsetof (struct
kmem_slab, tree_node)))
;
1001 assert((unsigned long)buf < (P2ALIGN((unsigned long)slab->addr({ if (!((unsigned long)buf < ((((unsigned long)slab->addr
+ cache->slab_size) & -((1 << 12)))))) Assert("(unsigned long)buf < (P2ALIGN((unsigned long)slab->addr + cache->slab_size, PAGE_SIZE))"
, "../kern/slab.c", 1002); })
1002 + cache->slab_size, PAGE_SIZE)))({ if (!((unsigned long)buf < ((((unsigned long)slab->addr
+ cache->slab_size) & -((1 << 12)))))) Assert("(unsigned long)buf < (P2ALIGN((unsigned long)slab->addr + cache->slab_size, PAGE_SIZE))"
, "../kern/slab.c", 1002); })
;
1003 }
1004
1005 assert(slab->nr_refs >= 1)({ if (!(slab->nr_refs >= 1)) Assert("slab->nr_refs >= 1"
, "../kern/slab.c", 1005); })
;
1006 assert(slab->nr_refs <= cache->bufs_per_slab)({ if (!(slab->nr_refs <= cache->bufs_per_slab)) Assert
("slab->nr_refs <= cache->bufs_per_slab", "../kern/slab.c"
, 1006); })
;
1007 bufctl = kmem_buf_to_bufctl(buf, cache);
1008 bufctl->next = slab->first_free;
1009 slab->first_free = bufctl;
1010 slab->nr_refs--;
1011 cache->nr_objs--;
1012
1013 if (slab->nr_refs == 0) {
1014 /* The slab has become free */
1015
1016 if (kmem_slab_use_tree(cache->flags))
1017 rbtree_remove(&cache->active_slabs, &slab->tree_node);
1018
1019 if (cache->bufs_per_slab > 1)
1020 list_remove(&slab->list_node);
1021
1022 list_insert_head(&cache->free_slabs, &slab->list_node);
1023 cache->nr_free_slabs++;
1024 } else if (slab->nr_refs == (cache->bufs_per_slab - 1)) {
1025 /* The slab has become partial */
1026 list_insert_head(&cache->partial_slabs, &slab->list_node);
1027 }
1028}
1029
1030static void kmem_cache_alloc_verify(struct kmem_cache *cache, void *buf,
1031 int construct)
1032{
1033 struct kmem_buftag *buftag;
1034 union kmem_bufctl *bufctl;
1035 void *addr;
1036
1037 buftag = kmem_buf_to_buftag(buf, cache);
1038
1039 if (buftag->state != KMEM_BUFTAG_FREE0x0cb1eef4UL)
1040 kmem_cache_error(cache, buf, KMEM_ERR_BUFTAG2, buftag);
1041
1042 addr = kmem_buf_verify_fill(buf, KMEM_FREE_PATTERN0xefbeaddeefbeaddeULL, KMEM_UNINIT_PATTERN0xfecaddbafecaddbaULL,
1043 cache->bufctl_dist);
1044
1045 if (addr != NULL((void *) 0))
1046 kmem_cache_error(cache, buf, KMEM_ERR_MODIFIED3, addr);
1047
1048 addr = buf + cache->obj_size;
1049 memset(addr, KMEM_REDZONE_BYTE0xbb, cache->redzone_pad);
1050
1051 bufctl = kmem_buf_to_bufctl(buf, cache);
1052 bufctl->redzone = KMEM_REDZONE_WORD0xcefaedfeUL;
1053 buftag->state = KMEM_BUFTAG_ALLOC0xedc810a1UL;
1054
1055 if (construct && (cache->ctor != NULL((void *) 0)))
1056 cache->ctor(buf);
1057}
1058
1059vm_offset_t kmem_cache_alloc(struct kmem_cache *cache)
1060{
1061 int filled;
1062 void *buf;
1063
1064#if SLAB_USE_CPU_POOLS0
1065 struct kmem_cpu_pool *cpu_pool;
1066
1067 cpu_pool = kmem_cpu_pool_get(cache);
1068
1069 if (cpu_pool->flags & KMEM_CF_NO_CPU_POOL0x01)
1070 goto slab_alloc;
1071
1072 simple_lock(&cpu_pool->lock);
1073
1074fast_alloc:
1075 if (likely(cpu_pool->nr_objs > 0)__builtin_expect(!!(cpu_pool->nr_objs > 0), 1)) {
1076 buf = kmem_cpu_pool_pop(cpu_pool);
1077 simple_unlock(&cpu_pool->lock);
1078
1079 if (cpu_pool->flags & KMEM_CF_VERIFY0x08)
1080 kmem_cache_alloc_verify(cache, buf, KMEM_AV_CONSTRUCT1);
1081
1082 return (vm_offset_t)buf;
1083 }
1084
1085 if (cpu_pool->array != NULL((void *) 0)) {
1086 filled = kmem_cpu_pool_fill(cpu_pool, cache);
1087
1088 if (!filled) {
1089 simple_unlock(&cpu_pool->lock);
1090
1091 filled = kmem_cache_grow(cache);
1092
1093 if (!filled)
1094 return 0;
1095
1096 simple_lock(&cpu_pool->lock);
1097 }
1098
1099 goto fast_alloc;
1100 }
1101
1102 simple_unlock(&cpu_pool->lock);
1103#endif /* SLAB_USE_CPU_POOLS */
1104
1105slab_alloc:
1106 simple_lock(&cache->lock);
1107 buf = kmem_cache_alloc_from_slab(cache);
1108 simple_unlock(&cache->lock);
1109
1110 if (buf == NULL((void *) 0)) {
1111 filled = kmem_cache_grow(cache);
1112
1113 if (!filled)
1114 return 0;
1115
1116 goto slab_alloc;
1117 }
1118
1119 if (cache->flags & KMEM_CF_VERIFY0x08)
1120 kmem_cache_alloc_verify(cache, buf, KMEM_AV_NOCONSTRUCT0);
1121
1122 if (cache->ctor != NULL((void *) 0))
1123 cache->ctor(buf);
1124
1125 return (vm_offset_t)buf;
1126}
1127
1128static void kmem_cache_free_verify(struct kmem_cache *cache, void *buf)
1129{
1130 struct rbtree_node *node;
1131 struct kmem_buftag *buftag;
1132 struct kmem_slab *slab;
1133 union kmem_bufctl *bufctl;
1134 unsigned char *redzone_byte;
1135 unsigned long slabend;
1136
1137 simple_lock(&cache->lock);
1138 node = rbtree_lookup_nearest(&cache->active_slabs, buf,({ struct rbtree_node *___cur, *___prev; int ___diff, ___index
; ___prev = ((void *) 0); ___index = -1; ___cur = (&cache
->active_slabs)->root; while (___cur != ((void *) 0)) {
___diff = kmem_slab_cmp_lookup(buf, ___cur); if (___diff == 0
) break; ___prev = ___cur; ___index = rbtree_d2i(___diff); ___cur
= ___cur->children[___index]; } if (___cur == ((void *) 0
)) ___cur = rbtree_nearest(___prev, ___index, 0); ___cur; })
1139 kmem_slab_cmp_lookup, RBTREE_LEFT)({ struct rbtree_node *___cur, *___prev; int ___diff, ___index
; ___prev = ((void *) 0); ___index = -1; ___cur = (&cache
->active_slabs)->root; while (___cur != ((void *) 0)) {
___diff = kmem_slab_cmp_lookup(buf, ___cur); if (___diff == 0
) break; ___prev = ___cur; ___index = rbtree_d2i(___diff); ___cur
= ___cur->children[___index]; } if (___cur == ((void *) 0
)) ___cur = rbtree_nearest(___prev, ___index, 0); ___cur; })
;
1140 simple_unlock(&cache->lock);
1141
1142 if (node == NULL((void *) 0))
1143 kmem_cache_error(cache, buf, KMEM_ERR_INVALID0, NULL((void *) 0));
1144
1145 slab = rbtree_entry(node, struct kmem_slab, tree_node)((struct kmem_slab *)((char *)node - __builtin_offsetof (struct
kmem_slab, tree_node)))
;
1146 slabend = P2ALIGN((unsigned long)slab->addr + cache->slab_size, PAGE_SIZE)(((unsigned long)slab->addr + cache->slab_size) & -
((1 << 12)))
;
1147
1148 if ((unsigned long)buf >= slabend)
1149 kmem_cache_error(cache, buf, KMEM_ERR_INVALID0, NULL((void *) 0));
1150
1151 if ((((unsigned long)buf - (unsigned long)slab->addr) % cache->buf_size)
1152 != 0)
1153 kmem_cache_error(cache, buf, KMEM_ERR_INVALID0, NULL((void *) 0));
1154
1155 /*
1156 * As the buffer address is valid, accessing its buftag is safe.
1157 */
1158 buftag = kmem_buf_to_buftag(buf, cache);
1159
1160 if (buftag->state != KMEM_BUFTAG_ALLOC0xedc810a1UL) {
1161 if (buftag->state == KMEM_BUFTAG_FREE0x0cb1eef4UL)
1162 kmem_cache_error(cache, buf, KMEM_ERR_DOUBLEFREE1, NULL((void *) 0));
1163 else
1164 kmem_cache_error(cache, buf, KMEM_ERR_BUFTAG2, buftag);
1165 }
1166
1167 redzone_byte = buf + cache->obj_size;
1168 bufctl = kmem_buf_to_bufctl(buf, cache);
1169
1170 while (redzone_byte < (unsigned char *)bufctl) {
1171 if (*redzone_byte != KMEM_REDZONE_BYTE0xbb)
1172 kmem_cache_error(cache, buf, KMEM_ERR_REDZONE4, redzone_byte);
1173
1174 redzone_byte++;
1175 }
1176
1177 if (bufctl->redzone != KMEM_REDZONE_WORD0xcefaedfeUL) {
1178 unsigned long word;
1179
1180 word = KMEM_REDZONE_WORD0xcefaedfeUL;
1181 redzone_byte = kmem_buf_verify_bytes(&bufctl->redzone, &word,
1182 sizeof(bufctl->redzone));
1183 kmem_cache_error(cache, buf, KMEM_ERR_REDZONE4, redzone_byte);
1184 }
1185
1186 kmem_buf_fill(buf, KMEM_FREE_PATTERN0xefbeaddeefbeaddeULL, cache->bufctl_dist);
1187 buftag->state = KMEM_BUFTAG_FREE0x0cb1eef4UL;
1188}
1189
1190void kmem_cache_free(struct kmem_cache *cache, vm_offset_t obj)
1191{
1192#if SLAB_USE_CPU_POOLS0
1193 struct kmem_cpu_pool *cpu_pool;
1194 void **array;
1195
1196 cpu_pool = kmem_cpu_pool_get(cache);
1197
1198 if (cpu_pool->flags & KMEM_CF_VERIFY0x08) {
1199#else /* SLAB_USE_CPU_POOLS */
1200 if (cache->flags & KMEM_CF_VERIFY0x08) {
1201#endif /* SLAB_USE_CPU_POOLS */
1202 kmem_cache_free_verify(cache, (void *)obj);
1203 }
1204
1205#if SLAB_USE_CPU_POOLS0
1206 if (cpu_pool->flags & KMEM_CF_NO_CPU_POOL0x01)
1207 goto slab_free;
1208
1209 simple_lock(&cpu_pool->lock);
1210
1211fast_free:
1212 if (likely(cpu_pool->nr_objs < cpu_pool->size)__builtin_expect(!!(cpu_pool->nr_objs < cpu_pool->size
), 1)
) {
1213 kmem_cpu_pool_push(cpu_pool, (void *)obj);
1214 simple_unlock(&cpu_pool->lock);
1215 return;
1216 }
1217
1218 if (cpu_pool->array != NULL((void *) 0)) {
1219 kmem_cpu_pool_drain(cpu_pool, cache);
1220 goto fast_free;
1221 }
1222
1223 simple_unlock(&cpu_pool->lock);
1224
1225 array = (void *)kmem_cache_alloc(cache->cpu_pool_type->array_cache);
1226
1227 if (array != NULL((void *) 0)) {
1228 simple_lock(&cpu_pool->lock);
1229
1230 /*
1231 * Another thread may have built the CPU pool while the lock was
1232 * dropped.
1233 */
1234 if (cpu_pool->array != NULL((void *) 0)) {
1235 simple_unlock(&cpu_pool->lock);
1236 kmem_cache_free(cache->cpu_pool_type->array_cache,
1237 (vm_offset_t)array);
1238 simple_lock(&cpu_pool->lock);
1239 goto fast_free;
1240 }
1241
1242 kmem_cpu_pool_build(cpu_pool, cache, array);
1243 goto fast_free;
1244 }
1245
1246slab_free:
1247#endif /* SLAB_USE_CPU_POOLS */
1248
1249 simple_lock(&cache->lock);
1250 kmem_cache_free_to_slab(cache, (void *)obj);
1251 simple_unlock(&cache->lock);
1252}
1253
1254void slab_collect(void)
1255{
1256 struct kmem_cache *cache;
1257
1258 if (elapsed_ticks <= (kmem_gc_last_tick + KMEM_GC_INTERVAL(5 * hz)))
1259 return;
1260
1261 kmem_gc_last_tick = elapsed_ticks;
1262
1263 simple_lock(&kmem_cache_list_lock);
1264
1265 list_for_each_entry(&kmem_cache_list, cache, node)for (cache = ((typeof(*cache) *)((char *)list_first(&kmem_cache_list
) - __builtin_offsetof (typeof(*cache), node))); !list_end(&
kmem_cache_list, &cache->node); cache = ((typeof(*cache
) *)((char *)list_next(&cache->node) - __builtin_offsetof
(typeof(*cache), node))))
1266 kmem_cache_reap(cache);
1267
1268 simple_unlock(&kmem_cache_list_lock);
1269}
1270
1271void slab_bootstrap(void)
1272{
1273 /* Make sure a bufctl can always be stored in a buffer */
1274 assert(sizeof(union kmem_bufctl) <= KMEM_ALIGN_MIN)({ if (!(sizeof(union kmem_bufctl) <= 8)) Assert("sizeof(union kmem_bufctl) <= KMEM_ALIGN_MIN"
, "../kern/slab.c", 1274); })
;
1275
1276 list_init(&kmem_cache_list);
1277 simple_lock_init(&kmem_cache_list_lock);
1278}
1279
1280void slab_init(void)
1281{
1282 vm_offset_t min, max;
1283
1284#if SLAB_USE_CPU_POOLS0
1285 struct kmem_cpu_pool_type *cpu_pool_type;
1286 char name[KMEM_CACHE_NAME_SIZE32];
1287 size_t i, size;
1288#endif /* SLAB_USE_CPU_POOLS */
1289
1290 kmem_submap(kmem_map, kernel_map, &min, &max, KMEM_MAP_SIZE(128 * 1024 * 1024), FALSE((boolean_t) 0));
1291
1292#if SLAB_USE_CPU_POOLS0
1293 for (i = 0; i < ARRAY_SIZE(kmem_cpu_pool_types)(sizeof(kmem_cpu_pool_types) / sizeof((kmem_cpu_pool_types)[0
]))
; i++) {
1294 cpu_pool_type = &kmem_cpu_pool_types[i];
1295 cpu_pool_type->array_cache = &kmem_cpu_array_caches[i];
1296 sprintf(name, "kmem_cpu_array_%d", cpu_pool_type->array_size);
1297 size = sizeof(void *) * cpu_pool_type->array_size;
1298 kmem_cache_init(cpu_pool_type->array_cache, name, size,
1299 cpu_pool_type->array_align, NULL((void *) 0), NULL((void *) 0), NULL((void *) 0), 0);
1300 }
1301#endif /* SLAB_USE_CPU_POOLS */
1302
1303 /*
1304 * Prevent off slab data for the slab cache to avoid infinite recursion.
1305 */
1306 kmem_cache_init(&kmem_slab_cache, "kmem_slab", sizeof(struct kmem_slab),
1
Calling 'kmem_cache_init'
1307 0, NULL((void *) 0), NULL((void *) 0), NULL((void *) 0), KMEM_CACHE_NOOFFSLAB0x2);
1308}
1309
1310static vm_offset_t kalloc_pagealloc(vm_size_t size)
1311{
1312 vm_offset_t addr;
1313 kern_return_t kr;
1314
1315 kr = kmem_alloc_wired(kmem_map, &addr, size);
1316
1317 if (kr != KERN_SUCCESS0)
1318 return 0;
1319
1320 return addr;
1321}
1322
1323static void kalloc_pagefree(vm_offset_t ptr, vm_size_t size)
1324{
1325 kmem_free(kmem_map, ptr, size);
1326}
1327
1328void kalloc_init(void)
1329{
1330 char name[KMEM_CACHE_NAME_SIZE32];
1331 size_t i, size;
1332
1333 size = 1 << KALLOC_FIRST_SHIFT5;
1334
1335 for (i = 0; i < ARRAY_SIZE(kalloc_caches)(sizeof(kalloc_caches) / sizeof((kalloc_caches)[0])); i++) {
1336 sprintf(name, "kalloc_%lu", size);
1337 kmem_cache_init(&kalloc_caches[i], name, size, 0, NULL((void *) 0),
1338 kalloc_pagealloc, kalloc_pagefree, 0);
1339 size <<= 1;
1340 }
1341}
1342
1343/*
1344 * Return the kalloc cache index matching the given allocation size, which
1345 * must be strictly greater than 0.
1346 */
1347static inline size_t kalloc_get_index(unsigned long size)
1348{
1349 assert(size != 0)({ if (!(size != 0)) Assert("size != 0", "../kern/slab.c", 1349
); })
;
1350
1351 size = (size - 1) >> KALLOC_FIRST_SHIFT5;
1352
1353 if (size == 0)
1354 return 0;
1355 else
1356 return (sizeof(long) * 8) - __builtin_clzl(size);
1357}
1358
1359static void kalloc_verify(struct kmem_cache *cache, void *buf, size_t size)
1360{
1361 size_t redzone_size;
1362 void *redzone;
1363
1364 assert(size <= cache->obj_size)({ if (!(size <= cache->obj_size)) Assert("size <= cache->obj_size"
, "../kern/slab.c", 1364); })
;
1365
1366 redzone = buf + size;
1367 redzone_size = cache->obj_size - size;
1368 memset(redzone, KMEM_REDZONE_BYTE0xbb, redzone_size);
1369}
1370
1371vm_offset_t kalloc(vm_size_t size)
1372{
1373 size_t index;
1374 void *buf;
1375
1376 if (size == 0)
1377 return 0;
1378
1379 index = kalloc_get_index(size);
1380
1381 if (index < ARRAY_SIZE(kalloc_caches)(sizeof(kalloc_caches) / sizeof((kalloc_caches)[0]))) {
1382 struct kmem_cache *cache;
1383
1384 cache = &kalloc_caches[index];
1385 buf = (void *)kmem_cache_alloc(cache);
1386
1387 if ((buf != 0) && (cache->flags & KMEM_CF_VERIFY0x08))
1388 kalloc_verify(cache, buf, size);
1389 } else
1390 buf = (void *)kalloc_pagealloc(size);
1391
1392 return (vm_offset_t)buf;
1393}
1394
1395static void kfree_verify(struct kmem_cache *cache, void *buf, size_t size)
1396{
1397 unsigned char *redzone_byte, *redzone_end;
1398
1399 assert(size <= cache->obj_size)({ if (!(size <= cache->obj_size)) Assert("size <= cache->obj_size"
, "../kern/slab.c", 1399); })
;
1400
1401 redzone_byte = buf + size;
1402 redzone_end = buf + cache->obj_size;
1403
1404 while (redzone_byte < redzone_end) {
1405 if (*redzone_byte != KMEM_REDZONE_BYTE0xbb)
1406 kmem_cache_error(cache, buf, KMEM_ERR_REDZONE4, redzone_byte);
1407
1408 redzone_byte++;
1409 }
1410}
1411
1412void kfree(vm_offset_t data, vm_size_t size)
1413{
1414 size_t index;
1415
1416 if ((data == 0) || (size == 0))
1417 return;
1418
1419 index = kalloc_get_index(size);
1420
1421 if (index < ARRAY_SIZE(kalloc_caches)(sizeof(kalloc_caches) / sizeof((kalloc_caches)[0]))) {
1422 struct kmem_cache *cache;
1423
1424 cache = &kalloc_caches[index];
1425
1426 if (cache->flags & KMEM_CF_VERIFY0x08)
1427 kfree_verify(cache, (void *)data, size);
1428
1429 kmem_cache_free(cache, data);
1430 } else {
1431 kalloc_pagefree(data, size);
1432 }
1433}
1434
1435void slab_info(void)
1436{
1437 struct kmem_cache *cache;
1438 vm_size_t mem_usage, mem_reclaimable;
1439
1440 printf("cache obj slab bufs objs bufs "
1441 " total reclaimable\n"
1442 "name size size /slab usage count "
1443 " memory memory\n");
1444
1445 simple_lock(&kmem_cache_list_lock);
1446
1447 list_for_each_entry(&kmem_cache_list, cache, node)for (cache = ((typeof(*cache) *)((char *)list_first(&kmem_cache_list
) - __builtin_offsetof (typeof(*cache), node))); !list_end(&
kmem_cache_list, &cache->node); cache = ((typeof(*cache
) *)((char *)list_next(&cache->node) - __builtin_offsetof
(typeof(*cache), node))))
{
1448 simple_lock(&cache->lock);
1449
1450 mem_usage = (cache->nr_slabs * cache->slab_size) >> 10;
1451 mem_reclaimable = (cache->nr_free_slabs * cache->slab_size) >> 10;
1452
1453 printf("%-19s %6lu %3luk %4lu %6lu %6lu %7uk %10uk\n",
1454 cache->name, cache->obj_size, cache->slab_size >> 10,
1455 cache->bufs_per_slab, cache->nr_objs, cache->nr_bufs,
1456 mem_usage, mem_reclaimable);
1457
1458 simple_unlock(&cache->lock);
1459 }
1460
1461 simple_unlock(&kmem_cache_list_lock);
1462}
1463
1464#if MACH_DEBUG1
1465kern_return_t host_slab_info(host_t host, cache_info_array_t *infop,
1466 unsigned int *infoCntp)
1467{
1468 struct kmem_cache *cache;
1469 cache_info_t *info;
1470 unsigned int i, nr_caches;
1471 vm_size_t info_size = info_size;
1472 kern_return_t kr;
1473
1474 if (host == HOST_NULL((host_t)0))
1475 return KERN_INVALID_HOST22;
1476
1477 /*
1478 * Assume the cache list is unaltered once the kernel is ready.
1479 */
1480
1481 simple_lock(&kmem_cache_list_lock);
1482 nr_caches = kmem_nr_caches;
1483 simple_unlock(&kmem_cache_list_lock);
1484
1485 if (nr_caches <= *infoCntp)
1486 info = *infop;
1487 else {
1488 vm_offset_t info_addr;
1489
1490 info_size = round_page(nr_caches * sizeof(*info))((vm_offset_t)((((vm_offset_t)(nr_caches * sizeof(*info))) + (
(1 << 12)-1)) & ~((1 << 12)-1)))
;
1491 kr = kmem_alloc_pageable(ipc_kernel_map, &info_addr, info_size);
1492
1493 if (kr != KERN_SUCCESS0)
1494 return kr;
1495
1496 info = (cache_info_t *)info_addr;
1497 }
1498
1499 if (info == NULL((void *) 0))
1500 return KERN_RESOURCE_SHORTAGE6;
1501
1502 i = 0;
1503
1504 list_for_each_entry(&kmem_cache_list, cache, node)for (cache = ((typeof(*cache) *)((char *)list_first(&kmem_cache_list
) - __builtin_offsetof (typeof(*cache), node))); !list_end(&
kmem_cache_list, &cache->node); cache = ((typeof(*cache
) *)((char *)list_next(&cache->node) - __builtin_offsetof
(typeof(*cache), node))))
{
1505 simple_lock(&cache_lock);
1506 info[i].flags = ((cache->flags & KMEM_CF_NO_CPU_POOL0x01)
1507 ? CACHE_FLAGS_NO_CPU_POOL0x01 : 0)
1508 | ((cache->flags & KMEM_CF_SLAB_EXTERNAL0x02)
1509 ? CACHE_FLAGS_SLAB_EXTERNAL0x02 : 0)
1510 | ((cache->flags & KMEM_CF_NO_RECLAIM0x04)
1511 ? CACHE_FLAGS_NO_RECLAIM0x04 : 0)
1512 | ((cache->flags & KMEM_CF_VERIFY0x08)
1513 ? CACHE_FLAGS_VERIFY0x08 : 0)
1514 | ((cache->flags & KMEM_CF_DIRECT0x10)
1515 ? CACHE_FLAGS_DIRECT0x10 : 0);
1516#if SLAB_USE_CPU_POOLS0
1517 info[i].cpu_pool_size = cache->cpu_pool_type->array_size;
1518#else /* SLAB_USE_CPU_POOLS */
1519 info[i].cpu_pool_size = 0;
1520#endif /* SLAB_USE_CPU_POOLS */
1521 info[i].obj_size = cache->obj_size;
1522 info[i].align = cache->align;
1523 info[i].buf_size = cache->buf_size;
1524 info[i].slab_size = cache->slab_size;
1525 info[i].bufs_per_slab = cache->bufs_per_slab;
1526 info[i].nr_objs = cache->nr_objs;
1527 info[i].nr_bufs = cache->nr_bufs;
1528 info[i].nr_slabs = cache->nr_slabs;
1529 info[i].nr_free_slabs = cache->nr_free_slabs;
1530 strncpy(info[i].name, cache->name, sizeof(info[i].name));
1531 info[i].name[sizeof(info[i].name) - 1] = '\0';
1532 simple_unlock(&cache->lock);
1533
1534 i++;
1535 }
1536
1537 if (info != *infop) {
1538 vm_map_copy_t copy;
1539 vm_size_t used;
1540
1541 used = nr_caches * sizeof(*info);
1542
1543 if (used != info_size)
1544 memset((char *)info + used, 0, info_size - used);
1545
1546 kr = vm_map_copyin(ipc_kernel_map, (vm_offset_t)info, used, TRUE((boolean_t) 1),
1547 &copy);
1548
1549 assert(kr == KERN_SUCCESS)({ if (!(kr == 0)) Assert("kr == KERN_SUCCESS", "../kern/slab.c"
, 1549); })
;
1550 *infop = (cache_info_t *)copy;
1551 }
1552
1553 *infoCntp = nr_caches;
1554
1555 return KERN_SUCCESS0;
1556}
1557#endif /* MACH_DEBUG */