1 // SPDX-License-Identifier: GPL-2.0
2 /*
3 * SLUB: A slab allocator that limits cache line use instead of queuing
4 * objects in per cpu and per node lists.
5 *
6 * The allocator synchronizes using per slab locks or atomic operatios
7 * and only uses a centralized lock to manage a pool of partial slabs.
8 *
9 * (C) 2007 SGI, Christoph Lameter
10 * (C) 2011 Linux Foundation, Christoph Lameter
11 */
13 #include <linux/mm.h>
14 #include <linux/swap.h> /* struct reclaim_state */
15 #include <linux/module.h>
16 #include <linux/bit_spinlock.h>
17 #include <linux/interrupt.h>
18 #include <linux/bitops.h>
19 #include <linux/slab.h>
20 #include "slab.h"
21 #include <linux/proc_fs.h>
22 #include <linux/seq_file.h>
23 #include <linux/kasan.h>
24 #include <linux/cpu.h>
25 #include <linux/cpuset.h>
26 #include <linux/mempolicy.h>
27 #include <linux/ctype.h>
28 #include <linux/debugobjects.h>
29 #include <linux/kallsyms.h>
30 #include <linux/memory.h>
31 #include <linux/math64.h>
32 #include <linux/fault-inject.h>
33 #include <linux/stacktrace.h>
34 #include <linux/prefetch.h>
35 #include <linux/memcontrol.h>
36 #include <linux/random.h>
38 #include <trace/events/kmem.h>
40 #include "internal.h"
42 /*
43 * Lock order:
44 * 1. slab_mutex (Global Mutex)
45 * 2. node->list_lock
46 * 3. slab_lock(page) (Only on some arches and for debugging)
47 *
48 * slab_mutex
49 *
50 * The role of the slab_mutex is to protect the list of all the slabs
51 * and to synchronize major metadata changes to slab cache structures.
52 *
53 * The slab_lock is only used for debugging and on arches that do not
54 * have the ability to do a cmpxchg_double. It only protects:
55 * A. page->freelist -> List of object free in a page
56 * B. page->inuse -> Number of objects in use
57 * C. page->objects -> Number of objects in page
58 * D. page->frozen -> frozen state
59 *
60 * If a slab is frozen then it is exempt from list management. It is not
61 * on any list. The processor that froze the slab is the one who can
62 * perform list operations on the page. Other processors may put objects
63 * onto the freelist but the processor that froze the slab is the only
64 * one that can retrieve the objects from the page's freelist.
65 *
66 * The list_lock protects the partial and full list on each node and
67 * the partial slab counter. If taken then no new slabs may be added or
68 * removed from the lists nor make the number of partial slabs be modified.
69 * (Note that the total number of slabs is an atomic value that may be
70 * modified without taking the list lock).
71 *
72 * The list_lock is a centralized lock and thus we avoid taking it as
73 * much as possible. As long as SLUB does not have to handle partial
74 * slabs, operations can continue without any centralized lock. F.e.
75 * allocating a long series of objects that fill up slabs does not require
76 * the list lock.
77 * Interrupts are disabled during allocation and deallocation in order to
78 * make the slab allocator safe to use in the context of an irq. In addition
79 * interrupts are disabled to ensure that the processor does not change
80 * while handling per_cpu slabs, due to kernel preemption.
81 *
82 * SLUB assigns one slab for allocation to each processor.
83 * Allocations only occur from these slabs called cpu slabs.
84 *
85 * Slabs with free elements are kept on a partial list and during regular
86 * operations no list for full slabs is used. If an object in a full slab is
87 * freed then the slab will show up again on the partial lists.
88 * We track full slabs for debugging purposes though because otherwise we
89 * cannot scan all objects.
90 *
91 * Slabs are freed when they become empty. Teardown and setup is
92 * minimal so we rely on the page allocators per cpu caches for
93 * fast frees and allocs.
94 *
95 * Overloading of page flags that are otherwise used for LRU management.
96 *
97 * PageActive The slab is frozen and exempt from list processing.
98 * This means that the slab is dedicated to a purpose
99 * such as satisfying allocations for a specific
100 * processor. Objects may be freed in the slab while
101 * it is frozen but slab_free will then skip the usual
102 * list operations. It is up to the processor holding
103 * the slab to integrate the slab into the slab lists
104 * when the slab is no longer needed.
105 *
106 * One use of this flag is to mark slabs that are
107 * used for allocations. Then such a slab becomes a cpu
108 * slab. The cpu slab may be equipped with an additional
109 * freelist that allows lockless access to
110 * free objects in addition to the regular freelist
111 * that requires the slab lock.
112 *
113 * PageError Slab requires special handling due to debug
114 * options set. This moves slab handling out of
115 * the fast path and disables lockless freelists.
116 */
118 static inline int kmem_cache_debug(struct kmem_cache *s)
119 {
120 #ifdef CONFIG_SLUB_DEBUG
121 return unlikely(s->flags & SLAB_DEBUG_FLAGS);
122 #else
123 return 0;
124 #endif
125 }
127 void *fixup_red_left(struct kmem_cache *s, void *p)
128 {
129 if (kmem_cache_debug(s) && s->flags & SLAB_RED_ZONE)
130 p += s->red_left_pad;
132 return p;
133 }
135 static inline bool kmem_cache_has_cpu_partial(struct kmem_cache *s)
136 {
137 #ifdef CONFIG_SLUB_CPU_PARTIAL
138 return !kmem_cache_debug(s);
139 #else
140 return false;
141 #endif
142 }
144 /*
145 * Issues still to be resolved:
146 *
147 * - Support PAGE_ALLOC_DEBUG. Should be easy to do.
148 *
149 * - Variable sizing of the per node arrays
150 */
152 /* Enable to test recovery from slab corruption on boot */
153 #undef SLUB_RESILIENCY_TEST
155 /* Enable to log cmpxchg failures */
156 #undef SLUB_DEBUG_CMPXCHG
158 /*
159 * Mininum number of partial slabs. These will be left on the partial
160 * lists even if they are empty. kmem_cache_shrink may reclaim them.
161 */
162 #define MIN_PARTIAL 5
164 /*
165 * Maximum number of desirable partial slabs.
166 * The existence of more partial slabs makes kmem_cache_shrink
167 * sort the partial list by the number of objects in use.
168 */
169 #define MAX_PARTIAL 10
171 #define DEBUG_DEFAULT_FLAGS (SLAB_CONSISTENCY_CHECKS | SLAB_RED_ZONE | \
172 SLAB_POISON | SLAB_STORE_USER)
174 /*
175 * These debug flags cannot use CMPXCHG because there might be consistency
176 * issues when checking or reading debug information
177 */
178 #define SLAB_NO_CMPXCHG (SLAB_CONSISTENCY_CHECKS | SLAB_STORE_USER | \
179 SLAB_TRACE)
182 /*
183 * Debugging flags that require metadata to be stored in the slab. These get
184 * disabled when slub_debug=O is used and a cache's min order increases with
185 * metadata.
186 */
187 #define DEBUG_METADATA_FLAGS (SLAB_RED_ZONE | SLAB_POISON | SLAB_STORE_USER)
189 #define OO_SHIFT 16
190 #define OO_MASK ((1 << OO_SHIFT) - 1)
191 #define MAX_OBJS_PER_PAGE 32767 /* since page.objects is u15 */
193 /* Internal SLUB flags */
194 /* Poison object */
195 #define __OBJECT_POISON ((slab_flags_t __force)0x80000000U)
196 /* Use cmpxchg_double */
197 #define __CMPXCHG_DOUBLE ((slab_flags_t __force)0x40000000U)
199 /*
200 * Tracking user of a slab.
201 */
202 #define TRACK_ADDRS_COUNT 16
203 struct track {
204 unsigned long addr; /* Called from address */
205 #ifdef CONFIG_STACKTRACE
206 unsigned long addrs[TRACK_ADDRS_COUNT]; /* Called from address */
207 #endif
208 int cpu; /* Was running on cpu */
209 int pid; /* Pid context */
210 unsigned long when; /* When did the operation occur */
211 };
213 enum track_item { TRACK_ALLOC, TRACK_FREE };
215 #ifdef CONFIG_SYSFS
216 static int sysfs_slab_add(struct kmem_cache *);
217 static int sysfs_slab_alias(struct kmem_cache *, const char *);
218 static void memcg_propagate_slab_attrs(struct kmem_cache *s);
219 static void sysfs_slab_remove(struct kmem_cache *s);
220 #else
221 static inline int sysfs_slab_add(struct kmem_cache *s) { return 0; }
222 static inline int sysfs_slab_alias(struct kmem_cache *s, const char *p)
223 { return 0; }
224 static inline void memcg_propagate_slab_attrs(struct kmem_cache *s) { }
225 static inline void sysfs_slab_remove(struct kmem_cache *s) { }
226 #endif
228 static inline void stat(const struct kmem_cache *s, enum stat_item si)
229 {
230 #ifdef CONFIG_SLUB_STATS
231 /*
232 * The rmw is racy on a preemptible kernel but this is acceptable, so
233 * avoid this_cpu_add()'s irq-disable overhead.
234 */
235 raw_cpu_inc(s->cpu_slab->stat[si]);
236 #endif
237 }
239 /********************************************************************
240 * Core slab cache functions
241 *******************************************************************/
243 /*
244 * Returns freelist pointer (ptr). With hardening, this is obfuscated
245 * with an XOR of the address where the pointer is held and a per-cache
246 * random number.
247 */
248 static inline void *freelist_ptr(const struct kmem_cache *s, void *ptr,
249 unsigned long ptr_addr)
250 {
251 #ifdef CONFIG_SLAB_FREELIST_HARDENED
252 return (void *)((unsigned long)ptr ^ s->random ^ ptr_addr);
253 #else
254 return ptr;
255 #endif
256 }
258 /* Returns the freelist pointer recorded at location ptr_addr. */
259 static inline void *freelist_dereference(const struct kmem_cache *s,
260 void *ptr_addr)
261 {
262 return freelist_ptr(s, (void *)*(unsigned long *)(ptr_addr),
263 (unsigned long)ptr_addr);
264 }
266 static inline void *get_freepointer(struct kmem_cache *s, void *object)
267 {
268 return freelist_dereference(s, object + s->offset);
269 }
271 static void prefetch_freepointer(const struct kmem_cache *s, void *object)
272 {
273 prefetch(object + s->offset);
274 }
276 static inline void *get_freepointer_safe(struct kmem_cache *s, void *object)
277 {
278 unsigned long freepointer_addr;
279 void *p;
281 if (!debug_pagealloc_enabled())
282 return get_freepointer(s, object);
284 freepointer_addr = (unsigned long)object + s->offset;
285 probe_kernel_read(&p, (void **)freepointer_addr, sizeof(p));
286 return freelist_ptr(s, p, freepointer_addr);
287 }
289 static inline void set_freepointer(struct kmem_cache *s, void *object, void *fp)
290 {
291 unsigned long freeptr_addr = (unsigned long)object + s->offset;
293 #ifdef CONFIG_SLAB_FREELIST_HARDENED
294 BUG_ON(object == fp); /* naive detection of double free or corruption */
295 #endif
297 *(void **)freeptr_addr = freelist_ptr(s, fp, freeptr_addr);
298 }
300 /* Loop over all objects in a slab */
301 #define for_each_object(__p, __s, __addr, __objects) \
302 for (__p = fixup_red_left(__s, __addr); \
303 __p < (__addr) + (__objects) * (__s)->size; \
304 __p += (__s)->size)
306 #define for_each_object_idx(__p, __idx, __s, __addr, __objects) \
307 for (__p = fixup_red_left(__s, __addr), __idx = 1; \
308 __idx <= __objects; \
309 __p += (__s)->size, __idx++)
311 /* Determine object index from a given position */
312 static inline unsigned int slab_index(void *p, struct kmem_cache *s, void *addr)
313 {
314 return (p - addr) / s->size;
315 }
317 static inline unsigned int order_objects(unsigned int order, unsigned int size)
318 {
319 return ((unsigned int)PAGE_SIZE << order) / size;
320 }
322 static inline struct kmem_cache_order_objects oo_make(unsigned int order,
323 unsigned int size)
324 {
325 struct kmem_cache_order_objects x = {
326 (order << OO_SHIFT) + order_objects(order, size)
327 };
329 return x;
330 }
332 static inline unsigned int oo_order(struct kmem_cache_order_objects x)
333 {
334 return x.x >> OO_SHIFT;
335 }
337 static inline unsigned int oo_objects(struct kmem_cache_order_objects x)
338 {
339 return x.x & OO_MASK;
340 }
342 /*
343 * Per slab locking using the pagelock
344 */
345 static __always_inline void slab_lock(struct page *page)
346 {
347 VM_BUG_ON_PAGE(PageTail(page), page);
348 bit_spin_lock(PG_locked, &page->flags);
349 }
351 static __always_inline void slab_unlock(struct page *page)
352 {
353 VM_BUG_ON_PAGE(PageTail(page), page);
354 __bit_spin_unlock(PG_locked, &page->flags);
355 }
357 /* Interrupts must be disabled (for the fallback code to work right) */
358 static inline bool __cmpxchg_double_slab(struct kmem_cache *s, struct page *page,
359 void *freelist_old, unsigned long counters_old,
360 void *freelist_new, unsigned long counters_new,
361 const char *n)
362 {
363 VM_BUG_ON(!irqs_disabled());
364 #if defined(CONFIG_HAVE_CMPXCHG_DOUBLE) && \
365 defined(CONFIG_HAVE_ALIGNED_STRUCT_PAGE)
366 if (s->flags & __CMPXCHG_DOUBLE) {
367 if (cmpxchg_double(&page->freelist, &page->counters,
368 freelist_old, counters_old,
369 freelist_new, counters_new))
370 return true;
371 } else
372 #endif
373 {
374 slab_lock(page);
375 if (page->freelist == freelist_old &&
376 page->counters == counters_old) {
377 page->freelist = freelist_new;
378 page->counters = counters_new;
379 slab_unlock(page);
380 return true;
381 }
382 slab_unlock(page);
383 }
385 cpu_relax();
386 stat(s, CMPXCHG_DOUBLE_FAIL);
388 #ifdef SLUB_DEBUG_CMPXCHG
389 pr_info("%s %s: cmpxchg double redo ", n, s->name);
390 #endif
392 return false;
393 }
395 static inline bool cmpxchg_double_slab(struct kmem_cache *s, struct page *page,
396 void *freelist_old, unsigned long counters_old,
397 void *freelist_new, unsigned long counters_new,
398 const char *n)
399 {
400 #if defined(CONFIG_HAVE_CMPXCHG_DOUBLE) && \
401 defined(CONFIG_HAVE_ALIGNED_STRUCT_PAGE)
402 if (s->flags & __CMPXCHG_DOUBLE) {
403 if (cmpxchg_double(&page->freelist, &page->counters,
404 freelist_old, counters_old,
405 freelist_new, counters_new))
406 return true;
407 } else
408 #endif
409 {
410 unsigned long flags;
412 local_irq_save(flags);
413 slab_lock(page);
414 if (page->freelist == freelist_old &&
415 page->counters == counters_old) {
416 page->freelist = freelist_new;
417 page->counters = counters_new;
418 slab_unlock(page);
419 local_irq_restore(flags);
420 return true;
421 }
422 slab_unlock(page);
423 local_irq_restore(flags);
424 }
426 cpu_relax();
427 stat(s, CMPXCHG_DOUBLE_FAIL);
429 #ifdef SLUB_DEBUG_CMPXCHG
430 pr_info("%s %s: cmpxchg double redo ", n, s->name);
431 #endif
433 return false;
434 }
436 #ifdef CONFIG_SLUB_DEBUG
437 /*
438 * Determine a map of object in use on a page.
439 *
440 * Node listlock must be held to guarantee that the page does
441 * not vanish from under us.
442 */
443 static void get_map(struct kmem_cache *s, struct page *page, unsigned long *map)
444 {
445 void *p;
446 void *addr = page_address(page);
448 for (p = page->freelist; p; p = get_freepointer(s, p))
449 set_bit(slab_index(p, s, addr), map);
450 }
452 static inline unsigned int size_from_object(struct kmem_cache *s)
453 {
454 if (s->flags & SLAB_RED_ZONE)
455 return s->size - s->red_left_pad;
457 return s->size;
458 }
460 static inline void *restore_red_left(struct kmem_cache *s, void *p)
461 {
462 if (s->flags & SLAB_RED_ZONE)
463 p -= s->red_left_pad;
465 return p;
466 }
468 /*
469 * Debug settings:
470 */
471 #if defined(CONFIG_SLUB_DEBUG_ON)
472 static slab_flags_t slub_debug = DEBUG_DEFAULT_FLAGS;
473 #else
474 static slab_flags_t slub_debug;
475 #endif
477 static char *slub_debug_slabs;
478 static int disable_higher_order_debug;
480 /*
481 * slub is about to manipulate internal object metadata. This memory lies
482 * outside the range of the allocated object, so accessing it would normally
483 * be reported by kasan as a bounds error. metadata_access_enable() is used
484 * to tell kasan that these accesses are OK.
485 */
486 static inline void metadata_access_enable(void)
487 {
488 kasan_disable_current();
489 }
491 static inline void metadata_access_disable(void)
492 {
493 kasan_enable_current();
494 }
496 /*
497 * Object debugging
498 */
500 /* Verify that a pointer has an address that is valid within a slab page */
501 static inline int check_valid_pointer(struct kmem_cache *s,
502 struct page *page, void *object)
503 {
504 void *base;
506 if (!object)
507 return 1;
509 base = page_address(page);
510 object = restore_red_left(s, object);
511 if (object < base || object >= base + page->objects * s->size ||
512 (object - base) % s->size) {
513 return 0;
514 }
516 return 1;
517 }
519 static void print_section(char *level, char *text, u8 *addr,
520 unsigned int length)
521 {
522 metadata_access_enable();
523 print_hex_dump(level, text, DUMP_PREFIX_ADDRESS, 16, 1, addr,
524 length, 1);
525 metadata_access_disable();
526 }
528 static struct track *get_track(struct kmem_cache *s, void *object,
529 enum track_item alloc)
530 {
531 struct track *p;
533 if (s->offset)
534 p = object + s->offset + sizeof(void *);
535 else
536 p = object + s->inuse;
538 return p + alloc;
539 }
541 static void set_track(struct kmem_cache *s, void *object,
542 enum track_item alloc, unsigned long addr)
543 {
544 struct track *p = get_track(s, object, alloc);
546 if (addr) {
547 #ifdef CONFIG_STACKTRACE
548 struct stack_trace trace;
549 int i;
551 trace.nr_entries = 0;
552 trace.max_entries = TRACK_ADDRS_COUNT;
553 trace.entries = p->addrs;
554 trace.skip = 3;
555 metadata_access_enable();
556 save_stack_trace(&trace);
557 metadata_access_disable();
559 /* See rant in lockdep.c */
560 if (trace.nr_entries != 0 &&
561 trace.entries[trace.nr_entries - 1] == ULONG_MAX)
562 trace.nr_entries--;
564 for (i = trace.nr_entries; i < TRACK_ADDRS_COUNT; i++)
565 p->addrs[i] = 0;
566 #endif
567 p->addr = addr;
568 p->cpu = smp_processor_id();
569 p->pid = current->pid;
570 p->when = jiffies;
571 } else
572 memset(p, 0, sizeof(struct track));
573 }
575 static void init_tracking(struct kmem_cache *s, void *object)
576 {
577 if (!(s->flags & SLAB_STORE_USER))
578 return;
580 set_track(s, object, TRACK_FREE, 0UL);
581 set_track(s, object, TRACK_ALLOC, 0UL);
582 }
584 static void print_track(const char *s, struct track *t, unsigned long pr_time)
585 {
586 if (!t->addr)
587 return;
589 pr_err("INFO: %s in %pS age=%lu cpu=%u pid=%d\n",
590 s, (void *)t->addr, pr_time - t->when, t->cpu, t->pid);
591 #ifdef CONFIG_STACKTRACE
592 {
593 int i;
594 for (i = 0; i < TRACK_ADDRS_COUNT; i++)
595 if (t->addrs[i])
596 pr_err("\t%pS\n", (void *)t->addrs[i]);
597 else
598 break;
599 }
600 #endif
601 }
603 static void print_tracking(struct kmem_cache *s, void *object)
604 {
605 unsigned long pr_time = jiffies;
606 if (!(s->flags & SLAB_STORE_USER))
607 return;
609 print_track("Allocated", get_track(s, object, TRACK_ALLOC), pr_time);
610 print_track("Freed", get_track(s, object, TRACK_FREE), pr_time);
611 }
613 static void print_page_info(struct page *page)
614 {
615 pr_err("INFO: Slab 0x%p objects=%u used=%u fp=0x%p flags=0x%04lx\n",
616 page, page->objects, page->inuse, page->freelist, page->flags);
618 }
620 static void slab_bug(struct kmem_cache *s, char *fmt, ...)
621 {
622 struct va_format vaf;
623 va_list args;
625 va_start(args, fmt);
626 vaf.fmt = fmt;
627 vaf.va = &args;
628 pr_err("=============================================================================\n");
629 pr_err("BUG %s (%s): %pV\n", s->name, print_tainted(), &vaf);
630 pr_err("-----------------------------------------------------------------------------\n\n");
632 add_taint(TAINT_BAD_PAGE, LOCKDEP_NOW_UNRELIABLE);
633 va_end(args);
634 }
636 static void slab_fix(struct kmem_cache *s, char *fmt, ...)
637 {
638 struct va_format vaf;
639 va_list args;
641 va_start(args, fmt);
642 vaf.fmt = fmt;
643 vaf.va = &args;
644 pr_err("FIX %s: %pV\n", s->name, &vaf);
645 va_end(args);
646 }
648 static void print_trailer(struct kmem_cache *s, struct page *page, u8 *p)
649 {
650 unsigned int off; /* Offset of last byte */
651 u8 *addr = page_address(page);
653 print_tracking(s, p);
655 print_page_info(page);
657 pr_err("INFO: Object 0x%p @offset=%tu fp=0x%p\n\n",
658 p, p - addr, get_freepointer(s, p));
660 if (s->flags & SLAB_RED_ZONE)
661 print_section(KERN_ERR, "Redzone ", p - s->red_left_pad,
662 s->red_left_pad);
663 else if (p > addr + 16)
664 print_section(KERN_ERR, "Bytes b4 ", p - 16, 16);
666 print_section(KERN_ERR, "Object ", p,
667 min_t(unsigned int, s->object_size, PAGE_SIZE));
668 if (s->flags & SLAB_RED_ZONE)
669 print_section(KERN_ERR, "Redzone ", p + s->object_size,
670 s->inuse - s->object_size);
672 if (s->offset)
673 off = s->offset + sizeof(void *);
674 else
675 off = s->inuse;
677 if (s->flags & SLAB_STORE_USER)
678 off += 2 * sizeof(struct track);
680 off += kasan_metadata_size(s);
682 if (off != size_from_object(s))
683 /* Beginning of the filler is the free pointer */
684 print_section(KERN_ERR, "Padding ", p + off,
685 size_from_object(s) - off);
687 dump_stack();
688 }
690 void object_err(struct kmem_cache *s, struct page *page,
691 u8 *object, char *reason)
692 {
693 slab_bug(s, "%s", reason);
694 print_trailer(s, page, object);
695 }
697 static __printf(3, 4) void slab_err(struct kmem_cache *s, struct page *page,
698 const char *fmt, ...)
699 {
700 va_list args;
701 char buf[100];
703 va_start(args, fmt);
704 vsnprintf(buf, sizeof(buf), fmt, args);
705 va_end(args);
706 slab_bug(s, "%s", buf);
707 print_page_info(page);
708 dump_stack();
709 }
711 static void init_object(struct kmem_cache *s, void *object, u8 val)
712 {
713 u8 *p = object;
715 if (s->flags & SLAB_RED_ZONE)
716 memset(p - s->red_left_pad, val, s->red_left_pad);
718 if (s->flags & __OBJECT_POISON) {
719 memset(p, POISON_FREE, s->object_size - 1);
720 p[s->object_size - 1] = POISON_END;
721 }
723 if (s->flags & SLAB_RED_ZONE)
724 memset(p + s->object_size, val, s->inuse - s->object_size);
725 }
727 static void restore_bytes(struct kmem_cache *s, char *message, u8 data,
728 void *from, void *to)
729 {
730 slab_fix(s, "Restoring 0x%p-0x%p=0x%x\n", from, to - 1, data);
731 memset(from, data, to - from);
732 }
734 static int check_bytes_and_report(struct kmem_cache *s, struct page *page,
735 u8 *object, char *what,
736 u8 *start, unsigned int value, unsigned int bytes)
737 {
738 u8 *fault;
739 u8 *end;
741 metadata_access_enable();
742 fault = memchr_inv(start, value, bytes);
743 metadata_access_disable();
744 if (!fault)
745 return 1;
747 end = start + bytes;
748 while (end > fault && end[-1] == value)
749 end--;
751 slab_bug(s, "%s overwritten", what);
752 pr_err("INFO: 0x%p-0x%p. First byte 0x%x instead of 0x%x\n",
753 fault, end - 1, fault[0], value);
754 print_trailer(s, page, object);
756 restore_bytes(s, what, value, fault, end);
757 return 0;
758 }
760 /*
761 * Object layout:
762 *
763 * object address
764 * Bytes of the object to be managed.
765 * If the freepointer may overlay the object then the free
766 * pointer is the first word of the object.
767 *
768 * Poisoning uses 0x6b (POISON_FREE) and the last byte is
769 * 0xa5 (POISON_END)
770 *
771 * object + s->object_size
772 * Padding to reach word boundary. This is also used for Redzoning.
773 * Padding is extended by another word if Redzoning is enabled and
774 * object_size == inuse.
775 *
776 * We fill with 0xbb (RED_INACTIVE) for inactive objects and with
777 * 0xcc (RED_ACTIVE) for objects in use.
778 *
779 * object + s->inuse
780 * Meta data starts here.
781 *
782 * A. Free pointer (if we cannot overwrite object on free)
783 * B. Tracking data for SLAB_STORE_USER
784 * C. Padding to reach required alignment boundary or at mininum
785 * one word if debugging is on to be able to detect writes
786 * before the word boundary.
787 *
788 * Padding is done using 0x5a (POISON_INUSE)
789 *
790 * object + s->size
791 * Nothing is used beyond s->size.
792 *
793 * If slabcaches are merged then the object_size and inuse boundaries are mostly
794 * ignored. And therefore no slab options that rely on these boundaries
795 * may be used with merged slabcaches.
796 */
798 static int check_pad_bytes(struct kmem_cache *s, struct page *page, u8 *p)
799 {
800 unsigned long off = s->inuse; /* The end of info */
802 if (s->offset)
803 /* Freepointer is placed after the object. */
804 off += sizeof(void *);
806 if (s->flags & SLAB_STORE_USER)
807 /* We also have user information there */
808 off += 2 * sizeof(struct track);
810 off += kasan_metadata_size(s);
812 if (size_from_object(s) == off)
813 return 1;
815 return check_bytes_and_report(s, page, p, "Object padding",
816 p + off, POISON_INUSE, size_from_object(s) - off);
817 }
819 /* Check the pad bytes at the end of a slab page */
820 static int slab_pad_check(struct kmem_cache *s, struct page *page)
821 {
822 u8 *start;
823 u8 *fault;
824 u8 *end;
825 u8 *pad;
826 int length;
827 int remainder;
829 if (!(s->flags & SLAB_POISON))
830 return 1;
832 start = page_address(page);
833 length = PAGE_SIZE << compound_order(page);
834 end = start + length;
835 remainder = length % s->size;
836 if (!remainder)
837 return 1;
839 pad = end - remainder;
840 metadata_access_enable();
841 fault = memchr_inv(pad, POISON_INUSE, remainder);
842 metadata_access_disable();
843 if (!fault)
844 return 1;
845 while (end > fault && end[-1] == POISON_INUSE)
846 end--;
848 slab_err(s, page, "Padding overwritten. 0x%p-0x%p", fault, end - 1);
849 print_section(KERN_ERR, "Padding ", pad, remainder);
851 restore_bytes(s, "slab padding", POISON_INUSE, fault, end);
852 return 0;
853 }
855 static int check_object(struct kmem_cache *s, struct page *page,
856 void *object, u8 val)
857 {
858 u8 *p = object;
859 u8 *endobject = object + s->object_size;
861 if (s->flags & SLAB_RED_ZONE) {
862 if (!check_bytes_and_report(s, page, object, "Redzone",
863 object - s->red_left_pad, val, s->red_left_pad))
864 return 0;
866 if (!check_bytes_and_report(s, page, object, "Redzone",
867 endobject, val, s->inuse - s->object_size))
868 return 0;
869 } else {
870 if ((s->flags & SLAB_POISON) && s->object_size < s->inuse) {
871 check_bytes_and_report(s, page, p, "Alignment padding",
872 endobject, POISON_INUSE,
873 s->inuse - s->object_size);
874 }
875 }
877 if (s->flags & SLAB_POISON) {
878 if (val != SLUB_RED_ACTIVE && (s->flags & __OBJECT_POISON) &&
879 (!check_bytes_and_report(s, page, p, "Poison", p,
880 POISON_FREE, s->object_size - 1) ||
881 !check_bytes_and_report(s, page, p, "Poison",
882 p + s->object_size - 1, POISON_END, 1)))
883 return 0;
884 /*
885 * check_pad_bytes cleans up on its own.
886 */
887 check_pad_bytes(s, page, p);
888 }
890 if (!s->offset && val == SLUB_RED_ACTIVE)
891 /*
892 * Object and freepointer overlap. Cannot check
893 * freepointer while object is allocated.
894 */
895 return 1;
897 /* Check free pointer validity */
898 if (!check_valid_pointer(s, page, get_freepointer(s, p))) {
899 object_err(s, page, p, "Freepointer corrupt");
900 /*
901 * No choice but to zap it and thus lose the remainder
902 * of the free objects in this slab. May cause
903 * another error because the object count is now wrong.
904 */
905 set_freepointer(s, p, NULL);
906 return 0;
907 }
908 return 1;
909 }
911 static int check_slab(struct kmem_cache *s, struct page *page)
912 {
913 int maxobj;
915 VM_BUG_ON(!irqs_disabled());
917 if (!PageSlab(page)) {
918 slab_err(s, page, "Not a valid slab page");
919 return 0;
920 }
922 maxobj = order_objects(compound_order(page), s->size);
923 if (page->objects > maxobj) {
924 slab_err(s, page, "objects %u > max %u",
925 page->objects, maxobj);
926 return 0;
927 }
928 if (page->inuse > page->objects) {
929 slab_err(s, page, "inuse %u > max %u",
930 page->inuse, page->objects);
931 return 0;
932 }
933 /* Slab_pad_check fixes things up after itself */
934 slab_pad_check(s, page);
935 return 1;
936 }
938 /*
939 * Determine if a certain object on a page is on the freelist. Must hold the
940 * slab lock to guarantee that the chains are in a consistent state.
941 */
942 static int on_freelist(struct kmem_cache *s, struct page *page, void *search)
943 {
944 int nr = 0;
945 void *fp;
946 void *object = NULL;
947 int max_objects;
949 fp = page->freelist;
950 while (fp && nr <= page->objects) {
951 if (fp == search)
952 return 1;
953 if (!check_valid_pointer(s, page, fp)) {
954 if (object) {
955 object_err(s, page, object,
956 "Freechain corrupt");
957 set_freepointer(s, object, NULL);
958 } else {
959 slab_err(s, page, "Freepointer corrupt");
960 page->freelist = NULL;
961 page->inuse = page->objects;
962 slab_fix(s, "Freelist cleared");
963 return 0;
964 }
965 break;
966 }
967 object = fp;
968 fp = get_freepointer(s, object);
969 nr++;
970 }
972 max_objects = order_objects(compound_order(page), s->size);
973 if (max_objects > MAX_OBJS_PER_PAGE)
974 max_objects = MAX_OBJS_PER_PAGE;
976 if (page->objects != max_objects) {
977 slab_err(s, page, "Wrong number of objects. Found %d but should be %d",
978 page->objects, max_objects);
979 page->objects = max_objects;
980 slab_fix(s, "Number of objects adjusted.");
981 }
982 if (page->inuse != page->objects - nr) {
983 slab_err(s, page, "Wrong object count. Counter is %d but counted were %d",
984 page->inuse, page->objects - nr);
985 page->inuse = page->objects - nr;
986 slab_fix(s, "Object count adjusted.");
987 }
988 return search == NULL;
989 }
991 static void trace(struct kmem_cache *s, struct page *page, void *object,
992 int alloc)
993 {
994 if (s->flags & SLAB_TRACE) {
995 pr_info("TRACE %s %s 0x%p inuse=%d fp=0x%p\n",
996 s->name,
997 alloc ? "alloc" : "free",
998 object, page->inuse,
999 page->freelist);
1001 if (!alloc)
1002 print_section(KERN_INFO, "Object ", (void *)object,
1003 s->object_size);
1005 dump_stack();
1006 }
1007 }
1009 /*
1010 * Tracking of fully allocated slabs for debugging purposes.
1011 */
1012 static void add_full(struct kmem_cache *s,
1013 struct kmem_cache_node *n, struct page *page)
1014 {
1015 if (!(s->flags & SLAB_STORE_USER))
1016 return;
1018 lockdep_assert_held(&n->list_lock);
1019 list_add(&page->lru, &n->full);
1020 }
1022 static void remove_full(struct kmem_cache *s, struct kmem_cache_node *n, struct page *page)
1023 {
1024 if (!(s->flags & SLAB_STORE_USER))
1025 return;
1027 lockdep_assert_held(&n->list_lock);
1028 list_del(&page->lru);
1029 }
1031 /* Tracking of the number of slabs for debugging purposes */
1032 static inline unsigned long slabs_node(struct kmem_cache *s, int node)
1033 {
1034 struct kmem_cache_node *n = get_node(s, node);
1036 return atomic_long_read(&n->nr_slabs);
1037 }
1039 static inline unsigned long node_nr_slabs(struct kmem_cache_node *n)
1040 {
1041 return atomic_long_read(&n->nr_slabs);
1042 }
1044 static inline void inc_slabs_node(struct kmem_cache *s, int node, int objects)
1045 {
1046 struct kmem_cache_node *n = get_node(s, node);
1048 /*
1049 * May be called early in order to allocate a slab for the
1050 * kmem_cache_node structure. Solve the chicken-egg
1051 * dilemma by deferring the increment of the count during
1052 * bootstrap (see early_kmem_cache_node_alloc).
1053 */
1054 if (likely(n)) {
1055 atomic_long_inc(&n->nr_slabs);
1056 atomic_long_add(objects, &n->total_objects);
1057 }
1058 }
1059 static inline void dec_slabs_node(struct kmem_cache *s, int node, int objects)
1060 {
1061 struct kmem_cache_node *n = get_node(s, node);
1063 atomic_long_dec(&n->nr_slabs);
1064 atomic_long_sub(objects, &n->total_objects);
1065 }
1067 /* Object debug checks for alloc/free paths */
1068 static void setup_object_debug(struct kmem_cache *s, struct page *page,
1069 void *object)
1070 {
1071 if (!(s->flags & (SLAB_STORE_USER|SLAB_RED_ZONE|__OBJECT_POISON)))
1072 return;
1074 init_object(s, object, SLUB_RED_INACTIVE);
1075 init_tracking(s, object);
1076 }
1078 static inline int alloc_consistency_checks(struct kmem_cache *s,
1079 struct page *page,
1080 void *object, unsigned long addr)
1081 {
1082 if (!check_slab(s, page))
1083 return 0;
1085 if (!check_valid_pointer(s, page, object)) {
1086 object_err(s, page, object, "Freelist Pointer check fails");
1087 return 0;
1088 }
1090 if (!check_object(s, page, object, SLUB_RED_INACTIVE))
1091 return 0;
1093 return 1;
1094 }
1096 static noinline int alloc_debug_processing(struct kmem_cache *s,
1097 struct page *page,
1098 void *object, unsigned long addr)
1099 {
1100 if (s->flags & SLAB_CONSISTENCY_CHECKS) {
1101 if (!alloc_consistency_checks(s, page, object, addr))
1102 goto bad;
1103 }
1105 /* Success perform special debug activities for allocs */
1106 if (s->flags & SLAB_STORE_USER)
1107 set_track(s, object, TRACK_ALLOC, addr);
1108 trace(s, page, object, 1);
1109 init_object(s, object, SLUB_RED_ACTIVE);
1110 return 1;
1112 bad:
1113 if (PageSlab(page)) {
1114 /*
1115 * If this is a slab page then lets do the best we can
1116 * to avoid issues in the future. Marking all objects
1117 * as used avoids touching the remaining objects.
1118 */
1119 slab_fix(s, "Marking all objects used");
1120 page->inuse = page->objects;
1121 page->freelist = NULL;
1122 }
1123 return 0;
1124 }
1126 static inline int free_consistency_checks(struct kmem_cache *s,
1127 struct page *page, void *object, unsigned long addr)
1128 {
1129 if (!check_valid_pointer(s, page, object)) {
1130 slab_err(s, page, "Invalid object pointer 0x%p", object);
1131 return 0;
1132 }
1134 if (on_freelist(s, page, object)) {
1135 object_err(s, page, object, "Object already free");
1136 return 0;
1137 }
1139 if (!check_object(s, page, object, SLUB_RED_ACTIVE))
1140 return 0;
1142 if (unlikely(s != page->slab_cache)) {
1143 if (!PageSlab(page)) {
1144 slab_err(s, page, "Attempt to free object(0x%p) outside of slab",
1145 object);
1146 } else if (!page->slab_cache) {
1147 pr_err("SLUB <none>: no slab for object 0x%p.\n",
1148 object);
1149 dump_stack();
1150 } else
1151 object_err(s, page, object,
1152 "page slab pointer corrupt.");
1153 return 0;
1154 }
1155 return 1;
1156 }
1158 /* Supports checking bulk free of a constructed freelist */
1159 static noinline int free_debug_processing(
1160 struct kmem_cache *s, struct page *page,
1161 void *head, void *tail, int bulk_cnt,
1162 unsigned long addr)
1163 {
1164 struct kmem_cache_node *n = get_node(s, page_to_nid(page));
1165 void *object = head;
1166 int cnt = 0;
1167 unsigned long uninitialized_var(flags);
1168 int ret = 0;
1170 spin_lock_irqsave(&n->list_lock, flags);
1171 slab_lock(page);
1173 if (s->flags & SLAB_CONSISTENCY_CHECKS) {
1174 if (!check_slab(s, page))
1175 goto out;
1176 }
1178 next_object:
1179 cnt++;
1181 if (s->flags & SLAB_CONSISTENCY_CHECKS) {
1182 if (!free_consistency_checks(s, page, object, addr))
1183 goto out;
1184 }
1186 if (s->flags & SLAB_STORE_USER)
1187 set_track(s, object, TRACK_FREE, addr);
1188 trace(s, page, object, 0);
1189 /* Freepointer not overwritten by init_object(), SLAB_POISON moved it */
1190 init_object(s, object, SLUB_RED_INACTIVE);
1192 /* Reached end of constructed freelist yet? */
1193 if (object != tail) {
1194 object = get_freepointer(s, object);
1195 goto next_object;
1196 }
1197 ret = 1;
1199 out:
1200 if (cnt != bulk_cnt)
1201 slab_err(s, page, "Bulk freelist count(%d) invalid(%d)\n",
1202 bulk_cnt, cnt);
1204 slab_unlock(page);
1205 spin_unlock_irqrestore(&n->list_lock, flags);
1206 if (!ret)
1207 slab_fix(s, "Object at 0x%p not freed", object);
1208 return ret;
1209 }
1211 static int __init setup_slub_debug(char *str)
1212 {
1213 slub_debug = DEBUG_DEFAULT_FLAGS;
1214 if (*str++ != '=' || !*str)
1215 /*
1216 * No options specified. Switch on full debugging.
1217 */
1218 goto out;
1220 if (*str == ',')
1221 /*
1222 * No options but restriction on slabs. This means full
1223 * debugging for slabs matching a pattern.
1224 */
1225 goto check_slabs;
1227 slub_debug = 0;
1228 if (*str == '-')
1229 /*
1230 * Switch off all debugging measures.
1231 */
1232 goto out;
1234 /*
1235 * Determine which debug features should be switched on
1236 */
1237 for (; *str && *str != ','; str++) {
1238 switch (tolower(*str)) {
1239 case 'f':
1240 slub_debug |= SLAB_CONSISTENCY_CHECKS;
1241 break;
1242 case 'z':
1243 slub_debug |= SLAB_RED_ZONE;
1244 break;
1245 case 'p':
1246 slub_debug |= SLAB_POISON;
1247 break;
1248 case 'u':
1249 slub_debug |= SLAB_STORE_USER;
1250 break;
1251 case 't':
1252 slub_debug |= SLAB_TRACE;
1253 break;
1254 case 'a':
1255 slub_debug |= SLAB_FAILSLAB;
1256 break;
1257 case 'o':
1258 /*
1259 * Avoid enabling debugging on caches if its minimum
1260 * order would increase as a result.
1261 */
1262 disable_higher_order_debug = 1;
1263 break;
1264 default:
1265 pr_err("slub_debug option '%c' unknown. skipped\n",
1266 *str);
1267 }
1268 }
1270 check_slabs:
1271 if (*str == ',')
1272 slub_debug_slabs = str + 1;
1273 out:
1274 return 1;
1275 }
1277 __setup("slub_debug", setup_slub_debug);
1279 /*
1280 * kmem_cache_flags - apply debugging options to the cache
1281 * @object_size: the size of an object without meta data
1282 * @flags: flags to set
1283 * @name: name of the cache
1284 * @ctor: constructor function
1285 *
1286 * Debug option(s) are applied to @flags. In addition to the debug
1287 * option(s), if a slab name (or multiple) is specified i.e.
1288 * slub_debug=<Debug-Options>,<slab name1>,<slab name2> ...
1289 * then only the select slabs will receive the debug option(s).
1290 */
1291 slab_flags_t kmem_cache_flags(unsigned int object_size,
1292 slab_flags_t flags, const char *name,
1293 void (*ctor)(void *))
1294 {
1295 char *iter;
1296 size_t len;
1298 /* If slub_debug = 0, it folds into the if conditional. */
1299 if (!slub_debug_slabs)
1300 return flags | slub_debug;
1302 len = strlen(name);
1303 iter = slub_debug_slabs;
1304 while (*iter) {
1305 char *end, *glob;
1306 size_t cmplen;
1308 end = strchr(iter, ',');
1309 if (!end)
1310 end = iter + strlen(iter);
1312 glob = strnchr(iter, end - iter, '*');
1313 if (glob)
1314 cmplen = glob - iter;
1315 else
1316 cmplen = max_t(size_t, len, (end - iter));
1318 if (!strncmp(name, iter, cmplen)) {
1319 flags |= slub_debug;
1320 break;
1321 }
1323 if (!*end)
1324 break;
1325 iter = end + 1;
1326 }
1328 return flags;
1329 }
1330 #else /* !CONFIG_SLUB_DEBUG */
1331 static inline void setup_object_debug(struct kmem_cache *s,
1332 struct page *page, void *object) {}
1334 static inline int alloc_debug_processing(struct kmem_cache *s,
1335 struct page *page, void *object, unsigned long addr) { return 0; }
1337 static inline int free_debug_processing(
1338 struct kmem_cache *s, struct page *page,
1339 void *head, void *tail, int bulk_cnt,
1340 unsigned long addr) { return 0; }
1342 static inline int slab_pad_check(struct kmem_cache *s, struct page *page)
1343 { return 1; }
1344 static inline int check_object(struct kmem_cache *s, struct page *page,
1345 void *object, u8 val) { return 1; }
1346 static inline void add_full(struct kmem_cache *s, struct kmem_cache_node *n,
1347 struct page *page) {}
1348 static inline void remove_full(struct kmem_cache *s, struct kmem_cache_node *n,
1349 struct page *page) {}
1350 slab_flags_t kmem_cache_flags(unsigned int object_size,
1351 slab_flags_t flags, const char *name,
1352 void (*ctor)(void *))
1353 {
1354 return flags;
1355 }
1356 #define slub_debug 0
1358 #define disable_higher_order_debug 0
1360 static inline unsigned long slabs_node(struct kmem_cache *s, int node)
1361 { return 0; }
1362 static inline unsigned long node_nr_slabs(struct kmem_cache_node *n)
1363 { return 0; }
1364 static inline void inc_slabs_node(struct kmem_cache *s, int node,
1365 int objects) {}
1366 static inline void dec_slabs_node(struct kmem_cache *s, int node,
1367 int objects) {}
1369 #endif /* CONFIG_SLUB_DEBUG */
1371 /*
1372 * Hooks for other subsystems that check memory allocations. In a typical
1373 * production configuration these hooks all should produce no code at all.
1374 */
1375 static inline void *kmalloc_large_node_hook(void *ptr, size_t size, gfp_t flags)
1376 {
1377 kmemleak_alloc(ptr, size, 1, flags);
1378 return kasan_kmalloc_large(ptr, size, flags);
1379 }
1381 static __always_inline void kfree_hook(void *x)
1382 {
1383 kmemleak_free(x);
1384 kasan_kfree_large(x, _RET_IP_);
1385 }
1387 static __always_inline bool slab_free_hook(struct kmem_cache *s, void *x)
1388 {
1389 kmemleak_free_recursive(x, s->flags);
1391 /*
1392 * Trouble is that we may no longer disable interrupts in the fast path
1393 * So in order to make the debug calls that expect irqs to be
1394 * disabled we need to disable interrupts temporarily.
1395 */
1396 #ifdef CONFIG_LOCKDEP
1397 {
1398 unsigned long flags;
1400 local_irq_save(flags);
1401 debug_check_no_locks_freed(x, s->object_size);
1402 local_irq_restore(flags);
1403 }
1404 #endif
1405 if (!(s->flags & SLAB_DEBUG_OBJECTS))
1406 debug_check_no_obj_freed(x, s->object_size);
1408 /* KASAN might put x into memory quarantine, delaying its reuse */
1409 return kasan_slab_free(s, x, _RET_IP_);
1410 }
1412 static inline bool slab_free_freelist_hook(struct kmem_cache *s,
1413 void **head, void **tail)
1414 {
1415 /*
1416 * Compiler cannot detect this function can be removed if slab_free_hook()
1417 * evaluates to nothing. Thus, catch all relevant config debug options here.
1418 */
1419 #if defined(CONFIG_LOCKDEP) || \
1420 defined(CONFIG_DEBUG_KMEMLEAK) || \
1421 defined(CONFIG_DEBUG_OBJECTS_FREE) || \
1422 defined(CONFIG_KASAN)
1424 void *object;
1425 void *next = *head;
1426 void *old_tail = *tail ? *tail : *head;
1428 /* Head and tail of the reconstructed freelist */
1429 *head = NULL;
1430 *tail = NULL;
1432 do {
1433 object = next;
1434 next = get_freepointer(s, object);
1435 /* If object's reuse doesn't have to be delayed */
1436 if (!slab_free_hook(s, object)) {
1437 /* Move object to the new freelist */
1438 set_freepointer(s, object, *head);
1439 *head = object;
1440 if (!*tail)
1441 *tail = object;
1442 }
1443 } while (object != old_tail);
1445 if (*head == *tail)
1446 *tail = NULL;
1448 return *head != NULL;
1449 #else
1450 return true;
1451 #endif
1452 }
1454 static void *setup_object(struct kmem_cache *s, struct page *page,
1455 void *object)
1456 {
1457 setup_object_debug(s, page, object);
1458 object = kasan_init_slab_obj(s, object);
1459 if (unlikely(s->ctor)) {
1460 kasan_unpoison_object_data(s, object);
1461 s->ctor(object);
1462 kasan_poison_object_data(s, object);
1463 }
1464 return object;
1465 }
1467 /*
1468 * Slab allocation and freeing
1469 */
1470 static inline struct page *alloc_slab_page(struct kmem_cache *s,
1471 gfp_t flags, int node, struct kmem_cache_order_objects oo)
1472 {
1473 struct page *page;
1474 unsigned int order = oo_order(oo);
1476 if (node == NUMA_NO_NODE)
1477 page = alloc_pages(flags, order);
1478 else
1479 page = __alloc_pages_node(node, flags, order);
1481 if (page && memcg_charge_slab(page, flags, order, s)) {
1482 __free_pages(page, order);
1483 page = NULL;
1484 }
1486 return page;
1487 }
1489 #ifdef CONFIG_SLAB_FREELIST_RANDOM
1490 /* Pre-initialize the random sequence cache */
1491 static int init_cache_random_seq(struct kmem_cache *s)
1492 {
1493 unsigned int count = oo_objects(s->oo);
1494 int err;
1496 /* Bailout if already initialised */
1497 if (s->random_seq)
1498 return 0;
1500 err = cache_random_seq_create(s, count, GFP_KERNEL);
1501 if (err) {
1502 pr_err("SLUB: Unable to initialize free list for %s\n",
1503 s->name);
1504 return err;
1505 }
1507 /* Transform to an offset on the set of pages */
1508 if (s->random_seq) {
1509 unsigned int i;
1511 for (i = 0; i < count; i++)
1512 s->random_seq[i] *= s->size;
1513 }
1514 return 0;
1515 }
1517 /* Initialize each random sequence freelist per cache */
1518 static void __init init_freelist_randomization(void)
1519 {
1520 struct kmem_cache *s;
1522 mutex_lock(&slab_mutex);
1524 list_for_each_entry(s, &slab_caches, list)
1525 init_cache_random_seq(s);
1527 mutex_unlock(&slab_mutex);
1528 }
1530 /* Get the next entry on the pre-computed freelist randomized */
1531 static void *next_freelist_entry(struct kmem_cache *s, struct page *page,
1532 unsigned long *pos, void *start,
1533 unsigned long page_limit,
1534 unsigned long freelist_count)
1535 {
1536 unsigned int idx;
1538 /*
1539 * If the target page allocation failed, the number of objects on the
1540 * page might be smaller than the usual size defined by the cache.
1541 */
1542 do {
1543 idx = s->random_seq[*pos];
1544 *pos += 1;
1545 if (*pos >= freelist_count)
1546 *pos = 0;
1547 } while (unlikely(idx >= page_limit));
1549 return (char *)start + idx;
1550 }
1552 /* Shuffle the single linked freelist based on a random pre-computed sequence */
1553 static bool shuffle_freelist(struct kmem_cache *s, struct page *page)
1554 {
1555 void *start;
1556 void *cur;
1557 void *next;
1558 unsigned long idx, pos, page_limit, freelist_count;
1560 if (page->objects < 2 || !s->random_seq)
1561 return false;
1563 freelist_count = oo_objects(s->oo);
1564 pos = get_random_int() % freelist_count;
1566 page_limit = page->objects * s->size;
1567 start = fixup_red_left(s, page_address(page));
1569 /* First entry is used as the base of the freelist */
1570 cur = next_freelist_entry(s, page, &pos, start, page_limit,
1571 freelist_count);
1572 cur = setup_object(s, page, cur);
1573 page->freelist = cur;
1575 for (idx = 1; idx < page->objects; idx++) {
1576 next = next_freelist_entry(s, page, &pos, start, page_limit,
1577 freelist_count);
1578 next = setup_object(s, page, next);
1579 set_freepointer(s, cur, next);
1580 cur = next;
1581 }
1582 set_freepointer(s, cur, NULL);
1584 return true;
1585 }
1586 #else
1587 static inline int init_cache_random_seq(struct kmem_cache *s)
1588 {
1589 return 0;
1590 }
1591 static inline void init_freelist_randomization(void) { }
1592 static inline bool shuffle_freelist(struct kmem_cache *s, struct page *page)
1593 {
1594 return false;
1595 }
1596 #endif /* CONFIG_SLAB_FREELIST_RANDOM */
1598 static struct page *allocate_slab(struct kmem_cache *s, gfp_t flags, int node)
1599 {
1600 struct page *page;
1601 struct kmem_cache_order_objects oo = s->oo;
1602 gfp_t alloc_gfp;
1603 void *start, *p, *next;
1604 int idx, order;
1605 bool shuffle;
1607 flags &= gfp_allowed_mask;
1609 if (gfpflags_allow_blocking(flags))
1610 local_irq_enable();
1612 flags |= s->allocflags;
1614 /*
1615 * Let the initial higher-order allocation fail under memory pressure
1616 * so we fall-back to the minimum order allocation.
1617 */
1618 alloc_gfp = (flags | __GFP_NOWARN | __GFP_NORETRY) & ~__GFP_NOFAIL;
1619 if ((alloc_gfp & __GFP_DIRECT_RECLAIM) && oo_order(oo) > oo_order(s->min))
1620 alloc_gfp = (alloc_gfp | __GFP_NOMEMALLOC) & ~(__GFP_RECLAIM|__GFP_NOFAIL);
1622 page = alloc_slab_page(s, alloc_gfp, node, oo);
1623 if (unlikely(!page)) {
1624 oo = s->min;
1625 alloc_gfp = flags;
1626 /*
1627 * Allocation may have failed due to fragmentation.
1628 * Try a lower order alloc if possible
1629 */
1630 page = alloc_slab_page(s, alloc_gfp, node, oo);
1631 if (unlikely(!page))
1632 goto out;
1633 stat(s, ORDER_FALLBACK);
1634 }
1636 page->objects = oo_objects(oo);
1638 order = compound_order(page);
1639 page->slab_cache = s;
1640 __SetPageSlab(page);
1641 if (page_is_pfmemalloc(page))
1642 SetPageSlabPfmemalloc(page);
1644 start = page_address(page);
1646 if (unlikely(s->flags & SLAB_POISON))
1647 memset(start, POISON_INUSE, PAGE_SIZE << order);
1649 kasan_poison_slab(page);
1651 shuffle = shuffle_freelist(s, page);
1653 if (!shuffle) {
1654 for_each_object_idx(p, idx, s, start, page->objects) {
1655 if (likely(idx < page->objects)) {
1656 next = p + s->size;
1657 next = setup_object(s, page, next);
1658 set_freepointer(s, p, next);
1659 } else
1660 set_freepointer(s, p, NULL);
1661 }
1662 start = fixup_red_left(s, start);
1663 start = setup_object(s, page, start);
1664 page->freelist = start;
1665 }
1667 page->inuse = page->objects;
1668 page->frozen = 1;
1670 out:
1671 if (gfpflags_allow_blocking(flags))
1672 local_irq_disable();
1673 if (!page)
1674 return NULL;
1676 mod_lruvec_page_state(page,
1677 (s->flags & SLAB_RECLAIM_ACCOUNT) ?
1678 NR_SLAB_RECLAIMABLE : NR_SLAB_UNRECLAIMABLE,
1679 1 << oo_order(oo));
1681 inc_slabs_node(s, page_to_nid(page), page->objects);
1683 return page;
1684 }
1686 static struct page *new_slab(struct kmem_cache *s, gfp_t flags, int node)
1687 {
1688 if (unlikely(flags & GFP_SLAB_BUG_MASK)) {
1689 gfp_t invalid_mask = flags & GFP_SLAB_BUG_MASK;
1690 flags &= ~GFP_SLAB_BUG_MASK;
1691 pr_warn("Unexpected gfp: %#x (%pGg). Fixing up to gfp: %#x (%pGg). Fix your code!\n",
1692 invalid_mask, &invalid_mask, flags, &flags);
1693 dump_stack();
1694 }
1696 return allocate_slab(s,
1697 flags & (GFP_RECLAIM_MASK | GFP_CONSTRAINT_MASK), node);
1698 }
1700 static void __free_slab(struct kmem_cache *s, struct page *page)
1701 {
1702 int order = compound_order(page);
1703 int pages = 1 << order;
1705 if (s->flags & SLAB_CONSISTENCY_CHECKS) {
1706 void *p;
1708 slab_pad_check(s, page);
1709 for_each_object(p, s, page_address(page),
1710 page->objects)
1711 check_object(s, page, p, SLUB_RED_INACTIVE);
1712 }
1714 mod_lruvec_page_state(page,
1715 (s->flags & SLAB_RECLAIM_ACCOUNT) ?
1716 NR_SLAB_RECLAIMABLE : NR_SLAB_UNRECLAIMABLE,
1717 -pages);
1719 __ClearPageSlabPfmemalloc(page);
1720 __ClearPageSlab(page);
1722 page->mapping = NULL;
1723 if (current->reclaim_state)
1724 current->reclaim_state->reclaimed_slab += pages;
1725 memcg_uncharge_slab(page, order, s);
1726 __free_pages(page, order);
1727 }
1729 static void rcu_free_slab(struct rcu_head *h)
1730 {
1731 struct page *page = container_of(h, struct page, rcu_head);
1733 __free_slab(page->slab_cache, page);
1734 }
1736 static void free_slab(struct kmem_cache *s, struct page *page)
1737 {
1738 if (unlikely(s->flags & SLAB_TYPESAFE_BY_RCU)) {
1739 call_rcu(&page->rcu_head, rcu_free_slab);
1740 } else
1741 __free_slab(s, page);
1742 }
1744 static void discard_slab(struct kmem_cache *s, struct page *page)
1745 {
1746 dec_slabs_node(s, page_to_nid(page), page->objects);
1747 free_slab(s, page);
1748 }
1750 /*
1751 * Management of partially allocated slabs.
1752 */
1753 static inline void
1754 __add_partial(struct kmem_cache_node *n, struct page *page, int tail)
1755 {
1756 n->nr_partial++;
1757 if (tail == DEACTIVATE_TO_TAIL)
1758 list_add_tail(&page->lru, &n->partial);
1759 else
1760 list_add(&page->lru, &n->partial);
1761 }
1763 static inline void add_partial(struct kmem_cache_node *n,
1764 struct page *page, int tail)
1765 {
1766 lockdep_assert_held(&n->list_lock);
1767 __add_partial(n, page, tail);
1768 }
1770 static inline void remove_partial(struct kmem_cache_node *n,
1771 struct page *page)
1772 {
1773 lockdep_assert_held(&n->list_lock);
1774 list_del(&page->lru);
1775 n->nr_partial--;
1776 }
1778 /*
1779 * Remove slab from the partial list, freeze it and
1780 * return the pointer to the freelist.
1781 *
1782 * Returns a list of objects or NULL if it fails.
1783 */
1784 static inline void *acquire_slab(struct kmem_cache *s,
1785 struct kmem_cache_node *n, struct page *page,
1786 int mode, int *objects)
1787 {
1788 void *freelist;
1789 unsigned long counters;
1790 struct page new;
1792 lockdep_assert_held(&n->list_lock);
1794 /*
1795 * Zap the freelist and set the frozen bit.
1796 * The old freelist is the list of objects for the
1797 * per cpu allocation list.
1798 */
1799 freelist = page->freelist;
1800 counters = page->counters;
1801 new.counters = counters;
1802 *objects = new.objects - new.inuse;
1803 if (mode) {
1804 new.inuse = page->objects;
1805 new.freelist = NULL;
1806 } else {
1807 new.freelist = freelist;
1808 }
1810 VM_BUG_ON(new.frozen);
1811 new.frozen = 1;
1813 if (!__cmpxchg_double_slab(s, page,
1814 freelist, counters,
1815 new.freelist, new.counters,
1816 "acquire_slab"))
1817 return NULL;
1819 remove_partial(n, page);
1820 WARN_ON(!freelist);
1821 return freelist;
1822 }
1824 static void put_cpu_partial(struct kmem_cache *s, struct page *page, int drain);
1825 static inline bool pfmemalloc_match(struct page *page, gfp_t gfpflags);
1827 /*
1828 * Try to allocate a partial slab from a specific node.
1829 */
1830 static void *get_partial_node(struct kmem_cache *s, struct kmem_cache_node *n,
1831 struct kmem_cache_cpu *c, gfp_t flags)
1832 {
1833 struct page *page, *page2;
1834 void *object = NULL;
1835 unsigned int available = 0;
1836 int objects;
1838 /*
1839 * Racy check. If we mistakenly see no partial slabs then we
1840 * just allocate an empty slab. If we mistakenly try to get a
1841 * partial slab and there is none available then get_partials()
1842 * will return NULL.
1843 */
1844 if (!n || !n->nr_partial)
1845 return NULL;
1847 spin_lock(&n->list_lock);
1848 list_for_each_entry_safe(page, page2, &n->partial, lru) {
1849 void *t;
1851 if (!pfmemalloc_match(page, flags))
1852 continue;
1854 t = acquire_slab(s, n, page, object == NULL, &objects);
1855 if (!t)
1856 break;
1858 available += objects;
1859 if (!object) {
1860 c->page = page;
1861 stat(s, ALLOC_FROM_PARTIAL);
1862 object = t;
1863 } else {
1864 put_cpu_partial(s, page, 0);
1865 stat(s, CPU_PARTIAL_NODE);
1866 }
1867 if (!kmem_cache_has_cpu_partial(s)
1868 || available > slub_cpu_partial(s) / 2)
1869 break;
1871 }
1872 spin_unlock(&n->list_lock);
1873 return object;
1874 }
1876 /*
1877 * Get a page from somewhere. Search in increasing NUMA distances.
1878 */
1879 static void *get_any_partial(struct kmem_cache *s, gfp_t flags,
1880 struct kmem_cache_cpu *c)
1881 {
1882 #ifdef CONFIG_NUMA
1883 struct zonelist *zonelist;
1884 struct zoneref *z;
1885 struct zone *zone;
1886 enum zone_type high_zoneidx = gfp_zone(flags);
1887 void *object;
1888 unsigned int cpuset_mems_cookie;
1890 /*
1891 * The defrag ratio allows a configuration of the tradeoffs between
1892 * inter node defragmentation and node local allocations. A lower
1893 * defrag_ratio increases the tendency to do local allocations
1894 * instead of attempting to obtain partial slabs from other nodes.
1895 *
1896 * If the defrag_ratio is set to 0 then kmalloc() always
1897 * returns node local objects. If the ratio is higher then kmalloc()
1898 * may return off node objects because partial slabs are obtained
1899 * from other nodes and filled up.
1900 *
1901 * If /sys/kernel/slab/xx/remote_node_defrag_ratio is set to 100
1902 * (which makes defrag_ratio = 1000) then every (well almost)
1903 * allocation will first attempt to defrag slab caches on other nodes.
1904 * This means scanning over all nodes to look for partial slabs which
1905 * may be expensive if we do it every time we are trying to find a slab
1906 * with available objects.
1907 */
1908 if (!s->remote_node_defrag_ratio ||
1909 get_cycles() % 1024 > s->remote_node_defrag_ratio)
1910 return NULL;
1912 do {
1913 cpuset_mems_cookie = read_mems_allowed_begin();
1914 zonelist = node_zonelist(mempolicy_slab_node(), flags);
1915 for_each_zone_zonelist(zone, z, zonelist, high_zoneidx) {
1916 struct kmem_cache_node *n;
1918 n = get_node(s, zone_to_nid(zone));
1920 if (n && cpuset_zone_allowed(zone, flags) &&
1921 n->nr_partial > s->min_partial) {
1922 object = get_partial_node(s, n, c, flags);
1923 if (object) {
1924 /*
1925 * Don't check read_mems_allowed_retry()
1926 * here - if mems_allowed was updated in
1927 * parallel, that was a harmless race
1928 * between allocation and the cpuset
1929 * update
1930 */
1931 return object;
1932 }
1933 }
1934 }
1935 } while (read_mems_allowed_retry(cpuset_mems_cookie));
1936 #endif
1937 return NULL;
1938 }
1940 /*
1941 * Get a partial page, lock it and return it.
1942 */
1943 static void *get_partial(struct kmem_cache *s, gfp_t flags, int node,
1944 struct kmem_cache_cpu *c)
1945 {
1946 void *object;
1947 int searchnode = node;
1949 if (node == NUMA_NO_NODE)
1950 searchnode = numa_mem_id();
1951 else if (!node_present_pages(node))
1952 searchnode = node_to_mem_node(node);
1954 object = get_partial_node(s, get_node(s, searchnode), c, flags);
1955 if (object || node != NUMA_NO_NODE)
1956 return object;
1958 return get_any_partial(s, flags, c);
1959 }
1961 #ifdef CONFIG_PREEMPT
1962 /*
1963 * Calculate the next globally unique transaction for disambiguiation
1964 * during cmpxchg. The transactions start with the cpu number and are then
1965 * incremented by CONFIG_NR_CPUS.
1966 */
1967 #define TID_STEP roundup_pow_of_two(CONFIG_NR_CPUS)
1968 #else
1969 /*
1970 * No preemption supported therefore also no need to check for
1971 * different cpus.
1972 */
1973 #define TID_STEP 1
1974 #endif
1976 static inline unsigned long next_tid(unsigned long tid)
1977 {
1978 return tid + TID_STEP;
1979 }
1981 static inline unsigned int tid_to_cpu(unsigned long tid)
1982 {
1983 return tid % TID_STEP;
1984 }
1986 static inline unsigned long tid_to_event(unsigned long tid)
1987 {
1988 return tid / TID_STEP;
1989 }
1991 static inline unsigned int init_tid(int cpu)
1992 {
1993 return cpu;
1994 }
1996 static inline void note_cmpxchg_failure(const char *n,
1997 const struct kmem_cache *s, unsigned long tid)
1998 {
1999 #ifdef SLUB_DEBUG_CMPXCHG
2000 unsigned long actual_tid = __this_cpu_read(s->cpu_slab->tid);
2002 pr_info("%s %s: cmpxchg redo ", n, s->name);
2004 #ifdef CONFIG_PREEMPT
2005 if (tid_to_cpu(tid) != tid_to_cpu(actual_tid))
2006 pr_warn("due to cpu change %d -> %d\n",
2007 tid_to_cpu(tid), tid_to_cpu(actual_tid));
2008 else
2009 #endif
2010 if (tid_to_event(tid) != tid_to_event(actual_tid))
2011 pr_warn("due to cpu running other code. Event %ld->%ld\n",
2012 tid_to_event(tid), tid_to_event(actual_tid));
2013 else
2014 pr_warn("for unknown reason: actual=%lx was=%lx target=%lx\n",
2015 actual_tid, tid, next_tid(tid));
2016 #endif
2017 stat(s, CMPXCHG_DOUBLE_CPU_FAIL);
2018 }
2020 static void init_kmem_cache_cpus(struct kmem_cache *s)
2021 {
2022 int cpu;
2024 for_each_possible_cpu(cpu)
2025 per_cpu_ptr(s->cpu_slab, cpu)->tid = init_tid(cpu);
2026 }
2028 /*
2029 * Remove the cpu slab
2030 */
2031 static void deactivate_slab(struct kmem_cache *s, struct page *page,
2032 void *freelist, struct kmem_cache_cpu *c)
2033 {
2034 enum slab_modes { M_NONE, M_PARTIAL, M_FULL, M_FREE };
2035 struct kmem_cache_node *n = get_node(s, page_to_nid(page));
2036 int lock = 0;
2037 enum slab_modes l = M_NONE, m = M_NONE;
2038 void *nextfree;
2039 int tail = DEACTIVATE_TO_HEAD;
2040 struct page new;
2041 struct page old;
2043 if (page->freelist) {
2044 stat(s, DEACTIVATE_REMOTE_FREES);
2045 tail = DEACTIVATE_TO_TAIL;
2046 }
2048 /*
2049 * Stage one: Free all available per cpu objects back
2050 * to the page freelist while it is still frozen. Leave the
2051 * last one.
2052 *
2053 * There is no need to take the list->lock because the page
2054 * is still frozen.
2055 */
2056 while (freelist && (nextfree = get_freepointer(s, freelist))) {
2057 void *prior;
2058 unsigned long counters;
2060 do {
2061 prior = page->freelist;
2062 counters = page->counters;
2063 set_freepointer(s, freelist, prior);
2064 new.counters = counters;
2065 new.inuse--;
2066 VM_BUG_ON(!new.frozen);
2068 } while (!__cmpxchg_double_slab(s, page,
2069 prior, counters,
2070 freelist, new.counters,
2071 "drain percpu freelist"));
2073 freelist = nextfree;
2074 }
2076 /*
2077 * Stage two: Ensure that the page is unfrozen while the
2078 * list presence reflects the actual number of objects
2079 * during unfreeze.
2080 *
2081 * We setup the list membership and then perform a cmpxchg
2082 * with the count. If there is a mismatch then the page
2083 * is not unfrozen but the page is on the wrong list.
2084 *
2085 * Then we restart the process which may have to remove
2086 * the page from the list that we just put it on again
2087 * because the number of objects in the slab may have
2088 * changed.
2089 */
2090 redo:
2092 old.freelist = page->freelist;
2093 old.counters = page->counters;
2094 VM_BUG_ON(!old.frozen);
2096 /* Determine target state of the slab */
2097 new.counters = old.counters;
2098 if (freelist) {
2099 new.inuse--;
2100 set_freepointer(s, freelist, old.freelist);
2101 new.freelist = freelist;
2102 } else
2103 new.freelist = old.freelist;
2105 new.frozen = 0;
2107 if (!new.inuse && n->nr_partial >= s->min_partial)
2108 m = M_FREE;
2109 else if (new.freelist) {
2110 m = M_PARTIAL;
2111 if (!lock) {
2112 lock = 1;
2113 /*
2114 * Taking the spinlock removes the possiblity
2115 * that acquire_slab() will see a slab page that
2116 * is frozen
2117 */
2118 spin_lock(&n->list_lock);
2119 }
2120 } else {
2121 m = M_FULL;
2122 if (kmem_cache_debug(s) && !lock) {
2123 lock = 1;
2124 /*
2125 * This also ensures that the scanning of full
2126 * slabs from diagnostic functions will not see
2127 * any frozen slabs.
2128 */
2129 spin_lock(&n->list_lock);
2130 }
2131 }
2133 if (l != m) {
2134 if (l == M_PARTIAL)
2135 remove_partial(n, page);
2136 else if (l == M_FULL)
2137 remove_full(s, n, page);
2139 if (m == M_PARTIAL)
2140 add_partial(n, page, tail);
2141 else if (m == M_FULL)
2142 add_full(s, n, page);
2143 }
2145 l = m;
2146 if (!__cmpxchg_double_slab(s, page,
2147 old.freelist, old.counters,
2148 new.freelist, new.counters,
2149 "unfreezing slab"))
2150 goto redo;
2152 if (lock)
2153 spin_unlock(&n->list_lock);
2155 if (m == M_PARTIAL)
2156 stat(s, tail);
2157 else if (m == M_FULL)
2158 stat(s, DEACTIVATE_FULL);
2159 else if (m == M_FREE) {
2160 stat(s, DEACTIVATE_EMPTY);
2161 discard_slab(s, page);
2162 stat(s, FREE_SLAB);
2163 }
2165 c->page = NULL;
2166 c->freelist = NULL;
2167 }
2169 /*
2170 * Unfreeze all the cpu partial slabs.
2171 *
2172 * This function must be called with interrupts disabled
2173 * for the cpu using c (or some other guarantee must be there
2174 * to guarantee no concurrent accesses).
2175 */
2176 static void unfreeze_partials(struct kmem_cache *s,
2177 struct kmem_cache_cpu *c)
2178 {
2179 #ifdef CONFIG_SLUB_CPU_PARTIAL
2180 struct kmem_cache_node *n = NULL, *n2 = NULL;
2181 struct page *page, *discard_page = NULL;
2183 while ((page = c->partial)) {
2184 struct page new;
2185 struct page old;
2187 c->partial = page->next;
2189 n2 = get_node(s, page_to_nid(page));
2190 if (n != n2) {
2191 if (n)
2192 spin_unlock(&n->list_lock);
2194 n = n2;
2195 spin_lock(&n->list_lock);
2196 }
2198 do {
2200 old.freelist = page->freelist;
2201 old.counters = page->counters;
2202 VM_BUG_ON(!old.frozen);
2204 new.counters = old.counters;
2205 new.freelist = old.freelist;
2207 new.frozen = 0;
2209 } while (!__cmpxchg_double_slab(s, page,
2210 old.freelist, old.counters,
2211 new.freelist, new.counters,
2212 "unfreezing slab"));
2214 if (unlikely(!new.inuse && n->nr_partial >= s->min_partial)) {
2215 page->next = discard_page;
2216 discard_page = page;
2217 } else {
2218 add_partial(n, page, DEACTIVATE_TO_TAIL);
2219 stat(s, FREE_ADD_PARTIAL);
2220 }
2221 }
2223 if (n)
2224 spin_unlock(&n->list_lock);
2226 while (discard_page) {
2227 page = discard_page;
2228 discard_page = discard_page->next;
2230 stat(s, DEACTIVATE_EMPTY);
2231 discard_slab(s, page);
2232 stat(s, FREE_SLAB);
2233 }
2234 #endif
2235 }
2237 /*
2238 * Put a page that was just frozen (in __slab_free) into a partial page
2239 * slot if available.
2240 *
2241 * If we did not find a slot then simply move all the partials to the
2242 * per node partial list.
2243 */
2244 static void put_cpu_partial(struct kmem_cache *s, struct page *page, int drain)
2245 {
2246 #ifdef CONFIG_SLUB_CPU_PARTIAL
2247 struct page *oldpage;
2248 int pages;
2249 int pobjects;
2251 preempt_disable();
2252 do {
2253 pages = 0;
2254 pobjects = 0;
2255 oldpage = this_cpu_read(s->cpu_slab->partial);
2257 if (oldpage) {
2258 pobjects = oldpage->pobjects;
2259 pages = oldpage->pages;
2260 if (drain && pobjects > s->cpu_partial) {
2261 unsigned long flags;
2262 /*
2263 * partial array is full. Move the existing
2264 * set to the per node partial list.
2265 */
2266 local_irq_save(flags);
2267 unfreeze_partials(s, this_cpu_ptr(s->cpu_slab));
2268 local_irq_restore(flags);
2269 oldpage = NULL;
2270 pobjects = 0;
2271 pages = 0;
2272 stat(s, CPU_PARTIAL_DRAIN);
2273 }
2274 }
2276 pages++;
2277 pobjects += page->objects - page->inuse;
2279 page->pages = pages;
2280 page->pobjects = pobjects;
2281 page->next = oldpage;
2283 } while (this_cpu_cmpxchg(s->cpu_slab->partial, oldpage, page)
2284 != oldpage);
2285 if (unlikely(!s->cpu_partial)) {
2286 unsigned long flags;
2288 local_irq_save(flags);
2289 unfreeze_partials(s, this_cpu_ptr(s->cpu_slab));
2290 local_irq_restore(flags);
2291 }
2292 preempt_enable();
2293 #endif
2294 }
2296 static inline void flush_slab(struct kmem_cache *s, struct kmem_cache_cpu *c)
2297 {
2298 stat(s, CPUSLAB_FLUSH);
2299 deactivate_slab(s, c->page, c->freelist, c);
2301 c->tid = next_tid(c->tid);
2302 }
2304 /*
2305 * Flush cpu slab.
2306 *
2307 * Called from IPI handler with interrupts disabled.
2308 */
2309 static inline void __flush_cpu_slab(struct kmem_cache *s, int cpu)
2310 {
2311 struct kmem_cache_cpu *c = per_cpu_ptr(s->cpu_slab, cpu);
2313 if (c->page)
2314 flush_slab(s, c);
2316 unfreeze_partials(s, c);
2317 }
2319 static void flush_cpu_slab(void *d)
2320 {
2321 struct kmem_cache *s = d;
2323 __flush_cpu_slab(s, smp_processor_id());
2324 }
2326 static bool has_cpu_slab(int cpu, void *info)
2327 {
2328 struct kmem_cache *s = info;
2329 struct kmem_cache_cpu *c = per_cpu_ptr(s->cpu_slab, cpu);
2331 return c->page || slub_percpu_partial(c);
2332 }
2334 static void flush_all(struct kmem_cache *s)
2335 {
2336 on_each_cpu_cond(has_cpu_slab, flush_cpu_slab, s, 1, GFP_ATOMIC);
2337 }
2339 /*
2340 * Use the cpu notifier to insure that the cpu slabs are flushed when
2341 * necessary.
2342 */
2343 static int slub_cpu_dead(unsigned int cpu)
2344 {
2345 struct kmem_cache *s;
2346 unsigned long flags;
2348 mutex_lock(&slab_mutex);
2349 list_for_each_entry(s, &slab_caches, list) {
2350 local_irq_save(flags);
2351 __flush_cpu_slab(s, cpu);
2352 local_irq_restore(flags);
2353 }
2354 mutex_unlock(&slab_mutex);
2355 return 0;
2356 }
2358 /*
2359 * Check if the objects in a per cpu structure fit numa
2360 * locality expectations.
2361 */
2362 static inline int node_match(struct page *page, int node)
2363 {
2364 #ifdef CONFIG_NUMA
2365 if (node != NUMA_NO_NODE && page_to_nid(page) != node)
2366 return 0;
2367 #endif
2368 return 1;
2369 }
2371 #ifdef CONFIG_SLUB_DEBUG
2372 static int count_free(struct page *page)
2373 {
2374 return page->objects - page->inuse;
2375 }
2377 static inline unsigned long node_nr_objs(struct kmem_cache_node *n)
2378 {
2379 return atomic_long_read(&n->total_objects);
2380 }
2381 #endif /* CONFIG_SLUB_DEBUG */
2383 #if defined(CONFIG_SLUB_DEBUG) || defined(CONFIG_SYSFS)
2384 static unsigned long count_partial(struct kmem_cache_node *n,
2385 int (*get_count)(struct page *))
2386 {
2387 unsigned long flags;
2388 unsigned long x = 0;
2389 struct page *page;
2391 spin_lock_irqsave(&n->list_lock, flags);
2392 list_for_each_entry(page, &n->partial, lru)
2393 x += get_count(page);
2394 spin_unlock_irqrestore(&n->list_lock, flags);
2395 return x;
2396 }
2397 #endif /* CONFIG_SLUB_DEBUG || CONFIG_SYSFS */
2399 static noinline void
2400 slab_out_of_memory(struct kmem_cache *s, gfp_t gfpflags, int nid)
2401 {
2402 #ifdef CONFIG_SLUB_DEBUG
2403 static DEFINE_RATELIMIT_STATE(slub_oom_rs, DEFAULT_RATELIMIT_INTERVAL,
2404 DEFAULT_RATELIMIT_BURST);
2405 int node;
2406 struct kmem_cache_node *n;
2408 if ((gfpflags & __GFP_NOWARN) || !__ratelimit(&slub_oom_rs))
2409 return;
2411 pr_warn("SLUB: Unable to allocate memory on node %d, gfp=%#x(%pGg)\n",
2412 nid, gfpflags, &gfpflags);
2413 pr_warn(" cache: %s, object size: %u, buffer size: %u, default order: %u, min order: %u\n",
2414 s->name, s->object_size, s->size, oo_order(s->oo),
2415 oo_order(s->min));
2417 if (oo_order(s->min) > get_order(s->object_size))
2418 pr_warn(" %s debugging increased min order, use slub_debug=O to disable.\n",
2419 s->name);
2421 for_each_kmem_cache_node(s, node, n) {
2422 unsigned long nr_slabs;
2423 unsigned long nr_objs;
2424 unsigned long nr_free;
2426 nr_free = count_partial(n, count_free);
2427 nr_slabs = node_nr_slabs(n);
2428 nr_objs = node_nr_objs(n);
2430 pr_warn(" node %d: slabs: %ld, objs: %ld, free: %ld\n",
2431 node, nr_slabs, nr_objs, nr_free);
2432 }
2433 #endif
2434 }
2436 static inline void *new_slab_objects(struct kmem_cache *s, gfp_t flags,
2437 int node, struct kmem_cache_cpu **pc)
2438 {
2439 void *freelist;
2440 struct kmem_cache_cpu *c = *pc;
2441 struct page *page;
2443 WARN_ON_ONCE(s->ctor && (flags & __GFP_ZERO));
2445 freelist = get_partial(s, flags, node, c);
2447 if (freelist)
2448 return freelist;
2450 page = new_slab(s, flags, node);
2451 if (page) {
2452 c = raw_cpu_ptr(s->cpu_slab);
2453 if (c->page)
2454 flush_slab(s, c);
2456 /*
2457 * No other reference to the page yet so we can
2458 * muck around with it freely without cmpxchg
2459 */
2460 freelist = page->freelist;
2461 page->freelist = NULL;
2463 stat(s, ALLOC_SLAB);
2464 c->page = page;
2465 *pc = c;
2466 } else
2467 freelist = NULL;
2469 return freelist;
2470 }
2472 static inline bool pfmemalloc_match(struct page *page, gfp_t gfpflags)
2473 {
2474 if (unlikely(PageSlabPfmemalloc(page)))
2475 return gfp_pfmemalloc_allowed(gfpflags);
2477 return true;
2478 }
2480 /*
2481 * Check the page->freelist of a page and either transfer the freelist to the
2482 * per cpu freelist or deactivate the page.
2483 *
2484 * The page is still frozen if the return value is not NULL.
2485 *
2486 * If this function returns NULL then the page has been unfrozen.
2487 *
2488 * This function must be called with interrupt disabled.
2489 */
2490 static inline void *get_freelist(struct kmem_cache *s, struct page *page)
2491 {
2492 struct page new;
2493 unsigned long counters;
2494 void *freelist;
2496 do {
2497 freelist = page->freelist;
2498 counters = page->counters;
2500 new.counters = counters;
2501 VM_BUG_ON(!new.frozen);
2503 new.inuse = page->objects;
2504 new.frozen = freelist != NULL;
2506 } while (!__cmpxchg_double_slab(s, page,
2507 freelist, counters,
2508 NULL, new.counters,
2509 "get_freelist"));
2511 return freelist;
2512 }
2514 /*
2515 * Slow path. The lockless freelist is empty or we need to perform
2516 * debugging duties.
2517 *
2518 * Processing is still very fast if new objects have been freed to the
2519 * regular freelist. In that case we simply take over the regular freelist
2520 * as the lockless freelist and zap the regular freelist.
2521 *
2522 * If that is not working then we fall back to the partial lists. We take the
2523 * first element of the freelist as the object to allocate now and move the
2524 * rest of the freelist to the lockless freelist.
2525 *
2526 * And if we were unable to get a new slab from the partial slab lists then
2527 * we need to allocate a new slab. This is the slowest path since it involves
2528 * a call to the page allocator and the setup of a new slab.
2529 *
2530 * Version of __slab_alloc to use when we know that interrupts are
2531 * already disabled (which is the case for bulk allocation).
2532 */
2533 static void *___slab_alloc(struct kmem_cache *s, gfp_t gfpflags, int node,
2534 unsigned long addr, struct kmem_cache_cpu *c)
2535 {
2536 void *freelist;
2537 struct page *page;
2539 page = c->page;
2540 if (!page)
2541 goto new_slab;
2542 redo:
2544 if (unlikely(!node_match(page, node))) {
2545 int searchnode = node;
2547 if (node != NUMA_NO_NODE && !node_present_pages(node))
2548 searchnode = node_to_mem_node(node);
2550 if (unlikely(!node_match(page, searchnode))) {
2551 stat(s, ALLOC_NODE_MISMATCH);
2552 deactivate_slab(s, page, c->freelist, c);
2553 goto new_slab;
2554 }
2555 }
2557 /*
2558 * By rights, we should be searching for a slab page that was
2559 * PFMEMALLOC but right now, we are losing the pfmemalloc
2560 * information when the page leaves the per-cpu allocator
2561 */
2562 if (unlikely(!pfmemalloc_match(page, gfpflags))) {
2563 deactivate_slab(s, page, c->freelist, c);
2564 goto new_slab;
2565 }
2567 /* must check again c->freelist in case of cpu migration or IRQ */
2568 freelist = c->freelist;
2569 if (freelist)
2570 goto load_freelist;
2572 freelist = get_freelist(s, page);
2574 if (!freelist) {
2575 c->page = NULL;
2576 stat(s, DEACTIVATE_BYPASS);
2577 goto new_slab;
2578 }
2580 stat(s, ALLOC_REFILL);
2582 load_freelist:
2583 /*
2584 * freelist is pointing to the list of objects to be used.
2585 * page is pointing to the page from which the objects are obtained.
2586 * That page must be frozen for per cpu allocations to work.
2587 */
2588 VM_BUG_ON(!c->page->frozen);
2589 c->freelist = get_freepointer(s, freelist);
2590 c->tid = next_tid(c->tid);
2591 return freelist;
2593 new_slab:
2595 if (slub_percpu_partial(c)) {
2596 page = c->page = slub_percpu_partial(c);
2597 slub_set_percpu_partial(c, page);
2598 stat(s, CPU_PARTIAL_ALLOC);
2599 goto redo;
2600 }
2602 freelist = new_slab_objects(s, gfpflags, node, &c);
2604 if (unlikely(!freelist)) {
2605 slab_out_of_memory(s, gfpflags, node);
2606 return NULL;
2607 }
2609 page = c->page;
2610 if (likely(!kmem_cache_debug(s) && pfmemalloc_match(page, gfpflags)))
2611 goto load_freelist;
2613 /* Only entered in the debug case */
2614 if (kmem_cache_debug(s) &&
2615 !alloc_debug_processing(s, page, freelist, addr))
2616 goto new_slab; /* Slab failed checks. Next slab needed */
2618 deactivate_slab(s, page, get_freepointer(s, freelist), c);
2619 return freelist;
2620 }
2622 /*
2623 * Another one that disabled interrupt and compensates for possible
2624 * cpu changes by refetching the per cpu area pointer.
2625 */
2626 static void *__slab_alloc(struct kmem_cache *s, gfp_t gfpflags, int node,
2627 unsigned long addr, struct kmem_cache_cpu *c)
2628 {
2629 void *p;
2630 unsigned long flags;
2632 local_irq_save(flags);
2633 #ifdef CONFIG_PREEMPT
2634 /*
2635 * We may have been preempted and rescheduled on a different
2636 * cpu before disabling interrupts. Need to reload cpu area
2637 * pointer.
2638 */
2639 c = this_cpu_ptr(s->cpu_slab);
2640 #endif
2642 p = ___slab_alloc(s, gfpflags, node, addr, c);
2643 local_irq_restore(flags);
2644 return p;
2645 }
2647 /*
2648 * Inlined fastpath so that allocation functions (kmalloc, kmem_cache_alloc)
2649 * have the fastpath folded into their functions. So no function call
2650 * overhead for requests that can be satisfied on the fastpath.
2651 *
2652 * The fastpath works by first checking if the lockless freelist can be used.
2653 * If not then __slab_alloc is called for slow processing.
2654 *
2655 * Otherwise we can simply pick the next object from the lockless free list.
2656 */
2657 static __always_inline void *slab_alloc_node(struct kmem_cache *s,
2658 gfp_t gfpflags, int node, unsigned long addr)
2659 {
2660 void *object;
2661 struct kmem_cache_cpu *c;
2662 struct page *page;
2663 unsigned long tid;
2665 s = slab_pre_alloc_hook(s, gfpflags);
2666 if (!s)
2667 return NULL;
2668 redo:
2669 /*
2670 * Must read kmem_cache cpu data via this cpu ptr. Preemption is
2671 * enabled. We may switch back and forth between cpus while
2672 * reading from one cpu area. That does not matter as long
2673 * as we end up on the original cpu again when doing the cmpxchg.
2674 *
2675 * We should guarantee that tid and kmem_cache are retrieved on
2676 * the same cpu. It could be different if CONFIG_PREEMPT so we need
2677 * to check if it is matched or not.
2678 */
2679 do {
2680 tid = this_cpu_read(s->cpu_slab->tid);
2681 c = raw_cpu_ptr(s->cpu_slab);
2682 } while (IS_ENABLED(CONFIG_PREEMPT) &&
2683 unlikely(tid != READ_ONCE(c->tid)));
2685 /*
2686 * Irqless object alloc/free algorithm used here depends on sequence
2687 * of fetching cpu_slab's data. tid should be fetched before anything
2688 * on c to guarantee that object and page associated with previous tid
2689 * won't be used with current tid. If we fetch tid first, object and
2690 * page could be one associated with next tid and our alloc/free
2691 * request will be failed. In this case, we will retry. So, no problem.
2692 */
2693 barrier();
2695 /*
2696 * The transaction ids are globally unique per cpu and per operation on
2697 * a per cpu queue. Thus they can be guarantee that the cmpxchg_double
2698 * occurs on the right processor and that there was no operation on the
2699 * linked list in between.
2700 */
2702 object = c->freelist;
2703 page = c->page;
2704 if (unlikely(!object || !node_match(page, node))) {
2705 object = __slab_alloc(s, gfpflags, node, addr, c);
2706 stat(s, ALLOC_SLOWPATH);
2707 } else {
2708 void *next_object = get_freepointer_safe(s, object);
2710 /*
2711 * The cmpxchg will only match if there was no additional
2712 * operation and if we are on the right processor.
2713 *
2714 * The cmpxchg does the following atomically (without lock
2715 * semantics!)
2716 * 1. Relocate first pointer to the current per cpu area.
2717 * 2. Verify that tid and freelist have not been changed
2718 * 3. If they were not changed replace tid and freelist
2719 *
2720 * Since this is without lock semantics the protection is only
2721 * against code executing on this cpu *not* from access by
2722 * other cpus.
2723 */
2724 if (unlikely(!this_cpu_cmpxchg_double(
2725 s->cpu_slab->freelist, s->cpu_slab->tid,
2726 object, tid,
2727 next_object, next_tid(tid)))) {
2729 note_cmpxchg_failure("slab_alloc", s, tid);
2730 goto redo;
2731 }
2732 prefetch_freepointer(s, next_object);
2733 stat(s, ALLOC_FASTPATH);
2734 }
2736 if (unlikely(gfpflags & __GFP_ZERO) && object)
2737 memset(object, 0, s->object_size);
2739 slab_post_alloc_hook(s, gfpflags, 1, &object);
2741 return object;
2742 }
2744 static __always_inline void *slab_alloc(struct kmem_cache *s,
2745 gfp_t gfpflags, unsigned long addr)
2746 {
2747 return slab_alloc_node(s, gfpflags, NUMA_NO_NODE, addr);
2748 }
2750 void *kmem_cache_alloc(struct kmem_cache *s, gfp_t gfpflags)
2751 {
2752 void *ret = slab_alloc(s, gfpflags, _RET_IP_);
2754 trace_kmem_cache_alloc(_RET_IP_, ret, s->object_size,
2755 s->size, gfpflags);
2757 return ret;
2758 }
2759 EXPORT_SYMBOL(kmem_cache_alloc);
2761 #ifdef CONFIG_TRACING
2762 void *kmem_cache_alloc_trace(struct kmem_cache *s, gfp_t gfpflags, size_t size)
2763 {
2764 void *ret = slab_alloc(s, gfpflags, _RET_IP_);
2765 trace_kmalloc(_RET_IP_, ret, size, s->size, gfpflags);
2766 ret = kasan_kmalloc(s, ret, size, gfpflags);
2767 return ret;
2768 }
2769 EXPORT_SYMBOL(kmem_cache_alloc_trace);
2770 #endif
2772 #ifdef CONFIG_NUMA
2773 void *kmem_cache_alloc_node(struct kmem_cache *s, gfp_t gfpflags, int node)
2774 {
2775 void *ret = slab_alloc_node(s, gfpflags, node, _RET_IP_);
2777 trace_kmem_cache_alloc_node(_RET_IP_, ret,
2778 s->object_size, s->size, gfpflags, node);
2780 return ret;
2781 }
2782 EXPORT_SYMBOL(kmem_cache_alloc_node);
2784 #ifdef CONFIG_TRACING
2785 void *kmem_cache_alloc_node_trace(struct kmem_cache *s,
2786 gfp_t gfpflags,
2787 int node, size_t size)
2788 {
2789 void *ret = slab_alloc_node(s, gfpflags, node, _RET_IP_);
2791 trace_kmalloc_node(_RET_IP_, ret,
2792 size, s->size, gfpflags, node);
2794 ret = kasan_kmalloc(s, ret, size, gfpflags);
2795 return ret;
2796 }
2797 EXPORT_SYMBOL(kmem_cache_alloc_node_trace);
2798 #endif
2799 #endif
2801 /*
2802 * Slow path handling. This may still be called frequently since objects
2803 * have a longer lifetime than the cpu slabs in most processing loads.
2804 *
2805 * So we still attempt to reduce cache line usage. Just take the slab
2806 * lock and free the item. If there is no additional partial page
2807 * handling required then we can return immediately.
2808 */
2809 static void __slab_free(struct kmem_cache *s, struct page *page,
2810 void *head, void *tail, int cnt,
2811 unsigned long addr)
2813 {
2814 void *prior;
2815 int was_frozen;
2816 struct page new;
2817 unsigned long counters;
2818 struct kmem_cache_node *n = NULL;
2819 unsigned long uninitialized_var(flags);
2821 stat(s, FREE_SLOWPATH);
2823 if (kmem_cache_debug(s) &&
2824 !free_debug_processing(s, page, head, tail, cnt, addr))
2825 return;
2827 do {
2828 if (unlikely(n)) {
2829 spin_unlock_irqrestore(&n->list_lock, flags);
2830 n = NULL;
2831 }
2832 prior = page->freelist;
2833 counters = page->counters;
2834 set_freepointer(s, tail, prior);
2835 new.counters = counters;
2836 was_frozen = new.frozen;
2837 new.inuse -= cnt;
2838 if ((!new.inuse || !prior) && !was_frozen) {
2840 if (kmem_cache_has_cpu_partial(s) && !prior) {
2842 /*
2843 * Slab was on no list before and will be
2844 * partially empty
2845 * We can defer the list move and instead
2846 * freeze it.
2847 */
2848 new.frozen = 1;
2850 } else { /* Needs to be taken off a list */
2852 n = get_node(s, page_to_nid(page));
2853 /*
2854 * Speculatively acquire the list_lock.
2855 * If the cmpxchg does not succeed then we may
2856 * drop the list_lock without any processing.
2857 *
2858 * Otherwise the list_lock will synchronize with
2859 * other processors updating the list of slabs.
2860 */
2861 spin_lock_irqsave(&n->list_lock, flags);
2863 }
2864 }
2866 } while (!cmpxchg_double_slab(s, page,
2867 prior, counters,
2868 head, new.counters,
2869 "__slab_free"));
2871 if (likely(!n)) {
2873 /*
2874 * If we just froze the page then put it onto the
2875 * per cpu partial list.
2876 */
2877 if (new.frozen && !was_frozen) {
2878 put_cpu_partial(s, page, 1);
2879 stat(s, CPU_PARTIAL_FREE);
2880 }
2881 /*
2882 * The list lock was not taken therefore no list
2883 * activity can be necessary.
2884 */
2885 if (was_frozen)
2886 stat(s, FREE_FROZEN);
2887 return;
2888 }
2890 if (unlikely(!new.inuse && n->nr_partial >= s->min_partial))
2891 goto slab_empty;
2893 /*
2894 * Objects left in the slab. If it was not on the partial list before
2895 * then add it.
2896 */
2897 if (!kmem_cache_has_cpu_partial(s) && unlikely(!prior)) {
2898 if (kmem_cache_debug(s))
2899 remove_full(s, n, page);
2900 add_partial(n, page, DEACTIVATE_TO_TAIL);
2901 stat(s, FREE_ADD_PARTIAL);
2902 }
2903 spin_unlock_irqrestore(&n->list_lock, flags);
2904 return;
2906 slab_empty:
2907 if (prior) {
2908 /*
2909 * Slab on the partial list.
2910 */
2911 remove_partial(n, page);
2912 stat(s, FREE_REMOVE_PARTIAL);
2913 } else {
2914 /* Slab must be on the full list */
2915 remove_full(s, n, page);
2916 }
2918 spin_unlock_irqrestore(&n->list_lock, flags);
2919 stat(s, FREE_SLAB);
2920 discard_slab(s, page);
2921 }
2923 /*
2924 * Fastpath with forced inlining to produce a kfree and kmem_cache_free that
2925 * can perform fastpath freeing without additional function calls.
2926 *
2927 * The fastpath is only possible if we are freeing to the current cpu slab
2928 * of this processor. This typically the case if we have just allocated
2929 * the item before.
2930 *
2931 * If fastpath is not possible then fall back to __slab_free where we deal
2932 * with all sorts of special processing.
2933 *
2934 * Bulk free of a freelist with several objects (all pointing to the
2935 * same page) possible by specifying head and tail ptr, plus objects
2936 * count (cnt). Bulk free indicated by tail pointer being set.
2937 */
2938 static __always_inline void do_slab_free(struct kmem_cache *s,
2939 struct page *page, void *head, void *tail,
2940 int cnt, unsigned long addr)
2941 {
2942 void *tail_obj = tail ? : head;
2943 struct kmem_cache_cpu *c;
2944 unsigned long tid;
2945 redo:
2946 /*
2947 * Determine the currently cpus per cpu slab.
2948 * The cpu may change afterward. However that does not matter since
2949 * data is retrieved via this pointer. If we are on the same cpu
2950 * during the cmpxchg then the free will succeed.
2951 */
2952 do {
2953 tid = this_cpu_read(s->cpu_slab->tid);
2954 c = raw_cpu_ptr(s->cpu_slab);
2955 } while (IS_ENABLED(CONFIG_PREEMPT) &&
2956 unlikely(tid != READ_ONCE(c->tid)));
2958 /* Same with comment on barrier() in slab_alloc_node() */
2959 barrier();
2961 if (likely(page == c->page)) {
2962 set_freepointer(s, tail_obj, c->freelist);
2964 if (unlikely(!this_cpu_cmpxchg_double(
2965 s->cpu_slab->freelist, s->cpu_slab->tid,
2966 c->freelist, tid,
2967 head, next_tid(tid)))) {
2969 note_cmpxchg_failure("slab_free", s, tid);
2970 goto redo;
2971 }
2972 stat(s, FREE_FASTPATH);
2973 } else
2974 __slab_free(s, page, head, tail_obj, cnt, addr);
2976 }
2978 static __always_inline void slab_free(struct kmem_cache *s, struct page *page,
2979 void *head, void *tail, int cnt,
2980 unsigned long addr)
2981 {
2982 /*
2983 * With KASAN enabled slab_free_freelist_hook modifies the freelist
2984 * to remove objects, whose reuse must be delayed.
2985 */
2986 if (slab_free_freelist_hook(s, &head, &tail))
2987 do_slab_free(s, page, head, tail, cnt, addr);
2988 }
2990 #ifdef CONFIG_KASAN_GENERIC
2991 void ___cache_free(struct kmem_cache *cache, void *x, unsigned long addr)
2992 {
2993 do_slab_free(cache, virt_to_head_page(x), x, NULL, 1, addr);
2994 }
2995 #endif
2997 void kmem_cache_free(struct kmem_cache *s, void *x)
2998 {
2999 s = cache_from_obj(s, x);
3000 if (!s)
3001 return;
3002 slab_free(s, virt_to_head_page(x), x, NULL, 1, _RET_IP_);
3003 trace_kmem_cache_free(_RET_IP_, x);
3004 }
3005 EXPORT_SYMBOL(kmem_cache_free);
3007 struct detached_freelist {
3008 struct page *page;
3009 void *tail;
3010 void *freelist;
3011 int cnt;
3012 struct kmem_cache *s;
3013 };
3015 /*
3016 * This function progressively scans the array with free objects (with
3017 * a limited look ahead) and extract objects belonging to the same
3018 * page. It builds a detached freelist directly within the given
3019 * page/objects. This can happen without any need for
3020 * synchronization, because the objects are owned by running process.
3021 * The freelist is build up as a single linked list in the objects.
3022 * The idea is, that this detached freelist can then be bulk
3023 * transferred to the real freelist(s), but only requiring a single
3024 * synchronization primitive. Look ahead in the array is limited due
3025 * to performance reasons.
3026 */
3027 static inline
3028 int build_detached_freelist(struct kmem_cache *s, size_t size,
3029 void **p, struct detached_freelist *df)
3030 {
3031 size_t first_skipped_index = 0;
3032 int lookahead = 3;
3033 void *object;
3034 struct page *page;
3036 /* Always re-init detached_freelist */
3037 df->page = NULL;
3039 do {
3040 object = p[--size];
3041 /* Do we need !ZERO_OR_NULL_PTR(object) here? (for kfree) */
3042 } while (!object && size);
3044 if (!object)
3045 return 0;
3047 page = virt_to_head_page(object);
3048 if (!s) {
3049 /* Handle kalloc'ed objects */
3050 if (unlikely(!PageSlab(page))) {
3051 BUG_ON(!PageCompound(page));
3052 kfree_hook(object);
3053 __free_pages(page, compound_order(page));
3054 p[size] = NULL; /* mark object processed */
3055 return size;
3056 }
3057 /* Derive kmem_cache from object */
3058 df->s = page->slab_cache;
3059 } else {
3060 df->s = cache_from_obj(s, object); /* Support for memcg */
3061 }
3063 /* Start new detached freelist */
3064 df->page = page;
3065 set_freepointer(df->s, object, NULL);
3066 df->tail = object;
3067 df->freelist = object;
3068 p[size] = NULL; /* mark object processed */
3069 df->cnt = 1;
3071 while (size) {
3072 object = p[--size];
3073 if (!object)
3074 continue; /* Skip processed objects */
3076 /* df->page is always set at this point */
3077 if (df->page == virt_to_head_page(object)) {
3078 /* Opportunity build freelist */
3079 set_freepointer(df->s, object, df->freelist);
3080 df->freelist = object;
3081 df->cnt++;
3082 p[size] = NULL; /* mark object processed */
3084 continue;
3085 }
3087 /* Limit look ahead search */
3088 if (!--lookahead)
3089 break;
3091 if (!first_skipped_index)
3092 first_skipped_index = size + 1;
3093 }
3095 return first_skipped_index;
3096 }
3098 /* Note that interrupts must be enabled when calling this function. */
3099 void kmem_cache_free_bulk(struct kmem_cache *s, size_t size, void **p)
3100 {
3101 if (WARN_ON(!size))
3102 return;
3104 do {
3105 struct detached_freelist df;
3107 size = build_detached_freelist(s, size, p, &df);
3108 if (!df.page)
3109 continue;
3111 slab_free(df.s, df.page, df.freelist, df.tail, df.cnt,_RET_IP_);
3112 } while (likely(size));
3113 }
3114 EXPORT_SYMBOL(kmem_cache_free_bulk);
3116 /* Note that interrupts must be enabled when calling this function. */
3117 int kmem_cache_alloc_bulk(struct kmem_cache *s, gfp_t flags, size_t size,
3118 void **p)
3119 {
3120 struct kmem_cache_cpu *c;
3121 int i;
3123 /* memcg and kmem_cache debug support */
3124 s = slab_pre_alloc_hook(s, flags);
3125 if (unlikely(!s))
3126 return false;
3127 /*
3128 * Drain objects in the per cpu slab, while disabling local
3129 * IRQs, which protects against PREEMPT and interrupts
3130 * handlers invoking normal fastpath.
3131 */
3132 local_irq_disable();
3133 c = this_cpu_ptr(s->cpu_slab);
3135 for (i = 0; i < size; i++) {
3136 void *object = c->freelist;
3138 if (unlikely(!object)) {
3139 /*
3140 * Invoking slow path likely have side-effect
3141 * of re-populating per CPU c->freelist
3142 */
3143 p[i] = ___slab_alloc(s, flags, NUMA_NO_NODE,
3144 _RET_IP_, c);
3145 if (unlikely(!p[i]))
3146 goto error;
3148 c = this_cpu_ptr(s->cpu_slab);
3149 continue; /* goto for-loop */
3150 }
3151 c->freelist = get_freepointer(s, object);
3152 p[i] = object;
3153 }
3154 c->tid = next_tid(c->tid);
3155 local_irq_enable();
3157 /* Clear memory outside IRQ disabled fastpath loop */
3158 if (unlikely(flags & __GFP_ZERO)) {
3159 int j;
3161 for (j = 0; j < i; j++)
3162 memset(p[j], 0, s->object_size);
3163 }
3165 /* memcg and kmem_cache debug support */
3166 slab_post_alloc_hook(s, flags, size, p);
3167 return i;
3168 error:
3169 local_irq_enable();
3170 slab_post_alloc_hook(s, flags, i, p);
3171 __kmem_cache_free_bulk(s, i, p);
3172 return 0;
3173 }
3174 EXPORT_SYMBOL(kmem_cache_alloc_bulk);
3177 /*
3178 * Object placement in a slab is made very easy because we always start at
3179 * offset 0. If we tune the size of the object to the alignment then we can
3180 * get the required alignment by putting one properly sized object after
3181 * another.
3182 *
3183 * Notice that the allocation order determines the sizes of the per cpu
3184 * caches. Each processor has always one slab available for allocations.
3185 * Increasing the allocation order reduces the number of times that slabs
3186 * must be moved on and off the partial lists and is therefore a factor in
3187 * locking overhead.
3188 */
3190 /*
3191 * Mininum / Maximum order of slab pages. This influences locking overhead
3192 * and slab fragmentation. A higher order reduces the number of partial slabs
3193 * and increases the number of allocations possible without having to
3194 * take the list_lock.
3195 */
3196 static unsigned int slub_min_order;
3197 static unsigned int slub_max_order = PAGE_ALLOC_COSTLY_ORDER;
3198 static unsigned int slub_min_objects;
3200 /*
3201 * Calculate the order of allocation given an slab object size.
3202 *
3203 * The order of allocation has significant impact on performance and other
3204 * system components. Generally order 0 allocations should be preferred since
3205 * order 0 does not cause fragmentation in the page allocator. Larger objects
3206 * be problematic to put into order 0 slabs because there may be too much
3207 * unused space left. We go to a higher order if more than 1/16th of the slab
3208 * would be wasted.
3209 *
3210 * In order to reach satisfactory performance we must ensure that a minimum
3211 * number of objects is in one slab. Otherwise we may generate too much
3212 * activity on the partial lists which requires taking the list_lock. This is
3213 * less a concern for large slabs though which are rarely used.
3214 *
3215 * slub_max_order specifies the order where we begin to stop considering the
3216 * number of objects in a slab as critical. If we reach slub_max_order then
3217 * we try to keep the page order as low as possible. So we accept more waste
3218 * of space in favor of a small page order.
3219 *
3220 * Higher order allocations also allow the placement of more objects in a
3221 * slab and thereby reduce object handling overhead. If the user has
3222 * requested a higher mininum order then we start with that one instead of
3223 * the smallest order which will fit the object.
3224 */
3225 static inline unsigned int slab_order(unsigned int size,
3226 unsigned int min_objects, unsigned int max_order,
3227 unsigned int fract_leftover)
3228 {
3229 unsigned int min_order = slub_min_order;
3230 unsigned int order;
3232 if (order_objects(min_order, size) > MAX_OBJS_PER_PAGE)
3233 return get_order(size * MAX_OBJS_PER_PAGE) - 1;
3235 for (order = max(min_order, (unsigned int)get_order(min_objects * size));
3236 order <= max_order; order++) {
3238 unsigned int slab_size = (unsigned int)PAGE_SIZE << order;
3239 unsigned int rem;
3241 rem = slab_size % size;
3243 if (rem <= slab_size / fract_leftover)
3244 break;
3245 }
3247 return order;
3248 }
3250 static inline int calculate_order(unsigned int size)
3251 {
3252 unsigned int order;
3253 unsigned int min_objects;
3254 unsigned int max_objects;
3256 /*
3257 * Attempt to find best configuration for a slab. This
3258 * works by first attempting to generate a layout with
3259 * the best configuration and backing off gradually.
3260 *
3261 * First we increase the acceptable waste in a slab. Then
3262 * we reduce the minimum objects required in a slab.
3263 */
3264 min_objects = slub_min_objects;
3265 if (!min_objects)
3266 min_objects = 4 * (fls(nr_cpu_ids) + 1);
3267 max_objects = order_objects(slub_max_order, size);
3268 min_objects = min(min_objects, max_objects);
3270 while (min_objects > 1) {
3271 unsigned int fraction;
3273 fraction = 16;
3274 while (fraction >= 4) {
3275 order = slab_order(size, min_objects,
3276 slub_max_order, fraction);
3277 if (order <= slub_max_order)
3278 return order;
3279 fraction /= 2;
3280 }
3281 min_objects--;
3282 }
3284 /*
3285 * We were unable to place multiple objects in a slab. Now
3286 * lets see if we can place a single object there.
3287 */
3288 order = slab_order(size, 1, slub_max_order, 1);
3289 if (order <= slub_max_order)
3290 return order;
3292 /*
3293 * Doh this slab cannot be placed using slub_max_order.
3294 */
3295 order = slab_order(size, 1, MAX_ORDER, 1);
3296 if (order < MAX_ORDER)
3297 return order;
3298 return -ENOSYS;
3299 }
3301 static void
3302 init_kmem_cache_node(struct kmem_cache_node *n)
3303 {
3304 n->nr_partial = 0;
3305 spin_lock_init(&n->list_lock);
3306 INIT_LIST_HEAD(&n->partial);
3307 #ifdef CONFIG_SLUB_DEBUG
3308 atomic_long_set(&n->nr_slabs, 0);
3309 atomic_long_set(&n->total_objects, 0);
3310 INIT_LIST_HEAD(&n->full);
3311 #endif
3312 }
3314 static inline int alloc_kmem_cache_cpus(struct kmem_cache *s)
3315 {
3316 BUILD_BUG_ON(PERCPU_DYNAMIC_EARLY_SIZE <
3317 KMALLOC_SHIFT_HIGH * sizeof(struct kmem_cache_cpu));
3319 /*
3320 * Must align to double word boundary for the double cmpxchg
3321 * instructions to work; see __pcpu_double_call_return_bool().
3322 */
3323 s->cpu_slab = __alloc_percpu(sizeof(struct kmem_cache_cpu),
3324 2 * sizeof(void *));
3326 if (!s->cpu_slab)
3327 return 0;
3329 init_kmem_cache_cpus(s);
3331 return 1;
3332 }
3334 static struct kmem_cache *kmem_cache_node;
3336 /*
3337 * No kmalloc_node yet so do it by hand. We know that this is the first
3338 * slab on the node for this slabcache. There are no concurrent accesses
3339 * possible.
3340 *
3341 * Note that this function only works on the kmem_cache_node
3342 * when allocating for the kmem_cache_node. This is used for bootstrapping
3343 * memory on a fresh node that has no slab structures yet.
3344 */
3345 static void early_kmem_cache_node_alloc(int node)
3346 {
3347 struct page *page;
3348 struct kmem_cache_node *n;
3350 BUG_ON(kmem_cache_node->size < sizeof(struct kmem_cache_node));
3352 page = new_slab(kmem_cache_node, GFP_NOWAIT, node);
3354 BUG_ON(!page);
3355 if (page_to_nid(page) != node) {
3356 pr_err("SLUB: Unable to allocate memory from node %d\n", node);
3357 pr_err("SLUB: Allocating a useless per node structure in order to be able to continue\n");
3358 }
3360 n = page->freelist;
3361 BUG_ON(!n);
3362 #ifdef CONFIG_SLUB_DEBUG
3363 init_object(kmem_cache_node, n, SLUB_RED_ACTIVE);
3364 init_tracking(kmem_cache_node, n);
3365 #endif
3366 n = kasan_kmalloc(kmem_cache_node, n, sizeof(struct kmem_cache_node),
3367 GFP_KERNEL);
3368 page->freelist = get_freepointer(kmem_cache_node, n);
3369 page->inuse = 1;
3370 page->frozen = 0;
3371 kmem_cache_node->node[node] = n;
3372 init_kmem_cache_node(n);
3373 inc_slabs_node(kmem_cache_node, node, page->objects);
3375 /*
3376 * No locks need to be taken here as it has just been
3377 * initialized and there is no concurrent access.
3378 */
3379 __add_partial(n, page, DEACTIVATE_TO_HEAD);
3380 }
3382 static void free_kmem_cache_nodes(struct kmem_cache *s)
3383 {
3384 int node;
3385 struct kmem_cache_node *n;
3387 for_each_kmem_cache_node(s, node, n) {
3388 s->node[node] = NULL;
3389 kmem_cache_free(kmem_cache_node, n);
3390 }
3391 }
3393 void __kmem_cache_release(struct kmem_cache *s)
3394 {
3395 cache_random_seq_destroy(s);
3396 free_percpu(s->cpu_slab);
3397 free_kmem_cache_nodes(s);
3398 }
3400 static int init_kmem_cache_nodes(struct kmem_cache *s)
3401 {
3402 int node;
3404 for_each_node_state(node, N_NORMAL_MEMORY) {
3405 struct kmem_cache_node *n;
3407 if (slab_state == DOWN) {
3408 early_kmem_cache_node_alloc(node);
3409 continue;
3410 }
3411 n = kmem_cache_alloc_node(kmem_cache_node,
3412 GFP_KERNEL, node);
3414 if (!n) {
3415 free_kmem_cache_nodes(s);
3416 return 0;
3417 }
3419 init_kmem_cache_node(n);
3420 s->node[node] = n;
3421 }
3422 return 1;
3423 }
3425 static void set_min_partial(struct kmem_cache *s, unsigned long min)
3426 {
3427 if (min < MIN_PARTIAL)
3428 min = MIN_PARTIAL;
3429 else if (min > MAX_PARTIAL)
3430 min = MAX_PARTIAL;
3431 s->min_partial = min;
3432 }
3434 static void set_cpu_partial(struct kmem_cache *s)
3435 {
3436 #ifdef CONFIG_SLUB_CPU_PARTIAL
3437 /*
3438 * cpu_partial determined the maximum number of objects kept in the
3439 * per cpu partial lists of a processor.
3440 *
3441 * Per cpu partial lists mainly contain slabs that just have one
3442 * object freed. If they are used for allocation then they can be
3443 * filled up again with minimal effort. The slab will never hit the
3444 * per node partial lists and therefore no locking will be required.
3445 *
3446 * This setting also determines
3447 *
3448 * A) The number of objects from per cpu partial slabs dumped to the
3449 * per node list when we reach the limit.
3450 * B) The number of objects in cpu partial slabs to extract from the
3451 * per node list when we run out of per cpu objects. We only fetch
3452 * 50% to keep some capacity around for frees.
3453 */
3454 if (!kmem_cache_has_cpu_partial(s))
3455 s->cpu_partial = 0;
3456 else if (s->size >= PAGE_SIZE)
3457 s->cpu_partial = 2;
3458 else if (s->size >= 1024)
3459 s->cpu_partial = 6;
3460 else if (s->size >= 256)
3461 s->cpu_partial = 13;
3462 else
3463 s->cpu_partial = 30;
3464 #endif
3465 }
3467 /*
3468 * calculate_sizes() determines the order and the distribution of data within
3469 * a slab object.
3470 */
3471 static int calculate_sizes(struct kmem_cache *s, int forced_order)
3472 {
3473 slab_flags_t flags = s->flags;
3474 unsigned int size = s->object_size;
3475 unsigned int order;
3477 /*
3478 * Round up object size to the next word boundary. We can only
3479 * place the free pointer at word boundaries and this determines
3480 * the possible location of the free pointer.
3481 */
3482 size = ALIGN(size, sizeof(void *));
3484 #ifdef CONFIG_SLUB_DEBUG
3485 /*
3486 * Determine if we can poison the object itself. If the user of
3487 * the slab may touch the object after free or before allocation
3488 * then we should never poison the object itself.
3489 */
3490 if ((flags & SLAB_POISON) && !(flags & SLAB_TYPESAFE_BY_RCU) &&
3491 !s->ctor)
3492 s->flags |= __OBJECT_POISON;
3493 else
3494 s->flags &= ~__OBJECT_POISON;
3497 /*
3498 * If we are Redzoning then check if there is some space between the
3499 * end of the object and the free pointer. If not then add an
3500 * additional word to have some bytes to store Redzone information.
3501 */
3502 if ((flags & SLAB_RED_ZONE) && size == s->object_size)
3503 size += sizeof(void *);
3504 #endif
3506 /*
3507 * With that we have determined the number of bytes in actual use
3508 * by the object. This is the potential offset to the free pointer.
3509 */
3510 s->inuse = size;
3512 if (((flags & (SLAB_TYPESAFE_BY_RCU | SLAB_POISON)) ||
3513 s->ctor)) {
3514 /*
3515 * Relocate free pointer after the object if it is not
3516 * permitted to overwrite the first word of the object on
3517 * kmem_cache_free.
3518 *
3519 * This is the case if we do RCU, have a constructor or
3520 * destructor or are poisoning the objects.
3521 */
3522 s->offset = size;
3523 size += sizeof(void *);
3524 }
3526 #ifdef CONFIG_SLUB_DEBUG
3527 if (flags & SLAB_STORE_USER)
3528 /*
3529 * Need to store information about allocs and frees after
3530 * the object.
3531 */
3532 size += 2 * sizeof(struct track);
3533 #endif
3535 kasan_cache_create(s, &size, &s->flags);
3536 #ifdef CONFIG_SLUB_DEBUG
3537 if (flags & SLAB_RED_ZONE) {
3538 /*
3539 * Add some empty padding so that we can catch
3540 * overwrites from earlier objects rather than let
3541 * tracking information or the free pointer be
3542 * corrupted if a user writes before the start
3543 * of the object.
3544 */
3545 size += sizeof(void *);
3547 s->red_left_pad = sizeof(void *);
3548 s->red_left_pad = ALIGN(s->red_left_pad, s->align);
3549 size += s->red_left_pad;
3550 }
3551 #endif
3553 /*
3554 * SLUB stores one object immediately after another beginning from
3555 * offset 0. In order to align the objects we have to simply size
3556 * each object to conform to the alignment.
3557 */
3558 size = ALIGN(size, s->align);
3559 s->size = size;
3560 if (forced_order >= 0)
3561 order = forced_order;
3562 else
3563 order = calculate_order(size);
3565 if ((int)order < 0)
3566 return 0;
3568 s->allocflags = 0;
3569 if (order)
3570 s->allocflags |= __GFP_COMP;
3572 if (s->flags & SLAB_CACHE_DMA)
3573 s->allocflags |= GFP_DMA;
3575 if (s->flags & SLAB_RECLAIM_ACCOUNT)
3576 s->allocflags |= __GFP_RECLAIMABLE;
3578 /*
3579 * Determine the number of objects per slab
3580 */
3581 s->oo = oo_make(order, size);
3582 s->min = oo_make(get_order(size), size);
3583 if (oo_objects(s->oo) > oo_objects(s->max))
3584 s->max = s->oo;
3586 return !!oo_objects(s->oo);
3587 }
3589 static int kmem_cache_open(struct kmem_cache *s, slab_flags_t flags)
3590 {
3591 s->flags = kmem_cache_flags(s->size, flags, s->name, s->ctor);
3592 #ifdef CONFIG_SLAB_FREELIST_HARDENED
3593 s->random = get_random_long();
3594 #endif
3596 if (!calculate_sizes(s, -1))
3597 goto error;
3598 if (disable_higher_order_debug) {
3599 /*
3600 * Disable debugging flags that store metadata if the min slab
3601 * order increased.
3602 */
3603 if (get_order(s->size) > get_order(s->object_size)) {
3604 s->flags &= ~DEBUG_METADATA_FLAGS;
3605 s->offset = 0;
3606 if (!calculate_sizes(s, -1))
3607 goto error;
3608 }
3609 }
3611 #if defined(CONFIG_HAVE_CMPXCHG_DOUBLE) && \
3612 defined(CONFIG_HAVE_ALIGNED_STRUCT_PAGE)
3613 if (system_has_cmpxchg_double() && (s->flags & SLAB_NO_CMPXCHG) == 0)
3614 /* Enable fast mode */
3615 s->flags |= __CMPXCHG_DOUBLE;
3616 #endif
3618 /*
3619 * The larger the object size is, the more pages we want on the partial
3620 * list to avoid pounding the page allocator excessively.
3621 */
3622 set_min_partial(s, ilog2(s->size) / 2);
3624 set_cpu_partial(s);
3626 #ifdef CONFIG_NUMA
3627 s->remote_node_defrag_ratio = 1000;
3628 #endif
3630 /* Initialize the pre-computed randomized freelist if slab is up */
3631 if (slab_state >= UP) {
3632 if (init_cache_random_seq(s))
3633 goto error;
3634 }
3636 if (!init_kmem_cache_nodes(s))
3637 goto error;
3639 if (alloc_kmem_cache_cpus(s))
3640 return 0;
3642 free_kmem_cache_nodes(s);
3643 error:
3644 if (flags & SLAB_PANIC)
3645 panic("Cannot create slab %s size=%u realsize=%u order=%u offset=%u flags=%lx\n",
3646 s->name, s->size, s->size,
3647 oo_order(s->oo), s->offset, (unsigned long)flags);
3648 return -EINVAL;
3649 }
3651 static void list_slab_objects(struct kmem_cache *s, struct page *page,
3652 const char *text)
3653 {
3654 #ifdef CONFIG_SLUB_DEBUG
3655 void *addr = page_address(page);
3656 void *p;
3657 unsigned long *map = bitmap_zalloc(page->objects, GFP_ATOMIC);
3658 if (!map)
3659 return;
3660 slab_err(s, page, text, s->name);
3661 slab_lock(page);
3663 get_map(s, page, map);
3664 for_each_object(p, s, addr, page->objects) {
3666 if (!test_bit(slab_index(p, s, addr), map)) {
3667 pr_err("INFO: Object 0x%p @offset=%tu\n", p, p - addr);
3668 print_tracking(s, p);
3669 }
3670 }
3671 slab_unlock(page);
3672 bitmap_free(map);
3673 #endif
3674 }
3676 /*
3677 * Attempt to free all partial slabs on a node.
3678 * This is called from __kmem_cache_shutdown(). We must take list_lock
3679 * because sysfs file might still access partial list after the shutdowning.
3680 */
3681 static void free_partial(struct kmem_cache *s, struct kmem_cache_node *n)
3682 {
3683 LIST_HEAD(discard);
3684 struct page *page, *h;
3686 BUG_ON(irqs_disabled());
3687 spin_lock_irq(&n->list_lock);
3688 list_for_each_entry_safe(page, h, &n->partial, lru) {
3689 if (!page->inuse) {
3690 remove_partial(n, page);
3691 list_add(&page->lru, &discard);
3692 } else {
3693 list_slab_objects(s, page,
3694 "Objects remaining in %s on __kmem_cache_shutdown()");
3695 }
3696 }
3697 spin_unlock_irq(&n->list_lock);
3699 list_for_each_entry_safe(page, h, &discard, lru)
3700 discard_slab(s, page);
3701 }
3703 bool __kmem_cache_empty(struct kmem_cache *s)
3704 {
3705 int node;
3706 struct kmem_cache_node *n;
3708 for_each_kmem_cache_node(s, node, n)
3709 if (n->nr_partial || slabs_node(s, node))
3710 return false;
3711 return true;
3712 }
3714 /*
3715 * Release all resources used by a slab cache.
3716 */
3717 int __kmem_cache_shutdown(struct kmem_cache *s)
3718 {
3719 int node;
3720 struct kmem_cache_node *n;
3722 flush_all(s);
3723 /* Attempt to free all objects */
3724 for_each_kmem_cache_node(s, node, n) {
3725 free_partial(s, n);
3726 if (n->nr_partial || slabs_node(s, node))
3727 return 1;
3728 }
3729 sysfs_slab_remove(s);
3730 return 0;
3731 }
3733 /********************************************************************
3734 * Kmalloc subsystem
3735 *******************************************************************/
3737 static int __init setup_slub_min_order(char *str)
3738 {
3739 get_option(&str, (int *)&slub_min_order);
3741 return 1;
3742 }
3744 __setup("slub_min_order=", setup_slub_min_order);
3746 static int __init setup_slub_max_order(char *str)
3747 {
3748 get_option(&str, (int *)&slub_max_order);
3749 slub_max_order = min(slub_max_order, (unsigned int)MAX_ORDER - 1);
3751 return 1;
3752 }
3754 __setup("slub_max_order=", setup_slub_max_order);
3756 static int __init setup_slub_min_objects(char *str)
3757 {
3758 get_option(&str, (int *)&slub_min_objects);
3760 return 1;
3761 }
3763 __setup("slub_min_objects=", setup_slub_min_objects);
3765 void *__kmalloc(size_t size, gfp_t flags)
3766 {
3767 struct kmem_cache *s;
3768 void *ret;
3770 if (unlikely(size > KMALLOC_MAX_CACHE_SIZE))
3771 return kmalloc_large(size, flags);
3773 s = kmalloc_slab(size, flags);
3775 if (unlikely(ZERO_OR_NULL_PTR(s)))
3776 return s;
3778 ret = slab_alloc(s, flags, _RET_IP_);
3780 trace_kmalloc(_RET_IP_, ret, size, s->size, flags);
3782 ret = kasan_kmalloc(s, ret, size, flags);
3784 return ret;
3785 }
3786 EXPORT_SYMBOL(__kmalloc);
3788 #ifdef CONFIG_NUMA
3789 static void *kmalloc_large_node(size_t size, gfp_t flags, int node)
3790 {
3791 struct page *page;
3792 void *ptr = NULL;
3794 flags |= __GFP_COMP;
3795 page = alloc_pages_node(node, flags, get_order(size));
3796 if (page)
3797 ptr = page_address(page);
3799 return kmalloc_large_node_hook(ptr, size, flags);
3800 }
3802 void *__kmalloc_node(size_t size, gfp_t flags, int node)
3803 {
3804 struct kmem_cache *s;
3805 void *ret;
3807 if (unlikely(size > KMALLOC_MAX_CACHE_SIZE)) {
3808 ret = kmalloc_large_node(size, flags, node);
3810 trace_kmalloc_node(_RET_IP_, ret,
3811 size, PAGE_SIZE << get_order(size),
3812 flags, node);
3814 return ret;
3815 }
3817 s = kmalloc_slab(size, flags);
3819 if (unlikely(ZERO_OR_NULL_PTR(s)))
3820 return s;
3822 ret = slab_alloc_node(s, flags, node, _RET_IP_);
3824 trace_kmalloc_node(_RET_IP_, ret, size, s->size, flags, node);
3826 ret = kasan_kmalloc(s, ret, size, flags);
3828 return ret;
3829 }
3830 EXPORT_SYMBOL(__kmalloc_node);
3831 #endif
3833 #ifdef CONFIG_HARDENED_USERCOPY
3834 /*
3835 * Rejects incorrectly sized objects and objects that are to be copied
3836 * to/from userspace but do not fall entirely within the containing slab
3837 * cache's usercopy region.
3838 *
3839 * Returns NULL if check passes, otherwise const char * to name of cache
3840 * to indicate an error.
3841 */
3842 void __check_heap_object(const void *ptr, unsigned long n, struct page *page,
3843 bool to_user)
3844 {
3845 struct kmem_cache *s;
3846 unsigned int offset;
3847 size_t object_size;
3849 ptr = kasan_reset_tag(ptr);
3851 /* Find object and usable object size. */
3852 s = page->slab_cache;
3854 /* Reject impossible pointers. */
3855 if (ptr < page_address(page))
3856 usercopy_abort("SLUB object not in SLUB page?!", NULL,
3857 to_user, 0, n);
3859 /* Find offset within object. */
3860 offset = (ptr - page_address(page)) % s->size;
3862 /* Adjust for redzone and reject if within the redzone. */
3863 if (kmem_cache_debug(s) && s->flags & SLAB_RED_ZONE) {
3864 if (offset < s->red_left_pad)
3865 usercopy_abort("SLUB object in left red zone",
3866 s->name, to_user, offset, n);
3867 offset -= s->red_left_pad;
3868 }
3870 /* Allow address range falling entirely within usercopy region. */
3871 if (offset >= s->useroffset &&
3872 offset - s->useroffset <= s->usersize &&
3873 n <= s->useroffset - offset + s->usersize)
3874 return;
3876 /*
3877 * If the copy is still within the allocated object, produce
3878 * a warning instead of rejecting the copy. This is intended
3879 * to be a temporary method to find any missing usercopy
3880 * whitelists.
3881 */
3882 object_size = slab_ksize(s);
3883 if (usercopy_fallback &&
3884 offset <= object_size && n <= object_size - offset) {
3885 usercopy_warn("SLUB object", s->name, to_user, offset, n);
3886 return;
3887 }
3889 usercopy_abort("SLUB object", s->name, to_user, offset, n);
3890 }
3891 #endif /* CONFIG_HARDENED_USERCOPY */
3893 static size_t __ksize(const void *object)
3894 {
3895 struct page *page;
3897 if (unlikely(object == ZERO_SIZE_PTR))
3898 return 0;
3900 page = virt_to_head_page(object);
3902 if (unlikely(!PageSlab(page))) {
3903 WARN_ON(!PageCompound(page));
3904 return PAGE_SIZE << compound_order(page);
3905 }
3907 return slab_ksize(page->slab_cache);
3908 }
3910 size_t ksize(const void *object)
3911 {
3912 size_t size = __ksize(object);
3913 /* We assume that ksize callers could use whole allocated area,
3914 * so we need to unpoison this area.
3915 */
3916 kasan_unpoison_shadow(object, size);
3917 return size;
3918 }
3919 EXPORT_SYMBOL(ksize);
3921 void kfree(const void *x)
3922 {
3923 struct page *page;
3924 void *object = (void *)x;
3926 trace_kfree(_RET_IP_, x);
3928 if (unlikely(ZERO_OR_NULL_PTR(x)))
3929 return;
3931 page = virt_to_head_page(x);
3932 if (unlikely(!PageSlab(page))) {
3933 BUG_ON(!PageCompound(page));
3934 kfree_hook(object);
3935 __free_pages(page, compound_order(page));
3936 return;
3937 }
3938 slab_free(page->slab_cache, page, object, NULL, 1, _RET_IP_);
3939 }
3940 EXPORT_SYMBOL(kfree);
3942 #define SHRINK_PROMOTE_MAX 32
3944 /*
3945 * kmem_cache_shrink discards empty slabs and promotes the slabs filled
3946 * up most to the head of the partial lists. New allocations will then
3947 * fill those up and thus they can be removed from the partial lists.
3948 *
3949 * The slabs with the least items are placed last. This results in them
3950 * being allocated from last increasing the chance that the last objects
3951 * are freed in them.
3952 */
3953 int __kmem_cache_shrink(struct kmem_cache *s)
3954 {
3955 int node;
3956 int i;
3957 struct kmem_cache_node *n;
3958 struct page *page;
3959 struct page *t;
3960 struct list_head discard;
3961 struct list_head promote[SHRINK_PROMOTE_MAX];
3962 unsigned long flags;
3963 int ret = 0;
3965 flush_all(s);
3966 for_each_kmem_cache_node(s, node, n) {
3967 INIT_LIST_HEAD(&discard);
3968 for (i = 0; i < SHRINK_PROMOTE_MAX; i++)
3969 INIT_LIST_HEAD(promote + i);
3971 spin_lock_irqsave(&n->list_lock, flags);
3973 /*
3974 * Build lists of slabs to discard or promote.
3975 *
3976 * Note that concurrent frees may occur while we hold the
3977 * list_lock. page->inuse here is the upper limit.
3978 */
3979 list_for_each_entry_safe(page, t, &n->partial, lru) {
3980 int free = page->objects - page->inuse;
3982 /* Do not reread page->inuse */
3983 barrier();
3985 /* We do not keep full slabs on the list */
3986 BUG_ON(free <= 0);
3988 if (free == page->objects) {
3989 list_move(&page->lru, &discard);
3990 n->nr_partial--;
3991 } else if (free <= SHRINK_PROMOTE_MAX)
3992 list_move(&page->lru, promote + free - 1);
3993 }
3995 /*
3996 * Promote the slabs filled up most to the head of the
3997 * partial list.
3998 */
3999 for (i = SHRINK_PROMOTE_MAX - 1; i >= 0; i--)
4000 list_splice(promote + i, &n->partial);
4002 spin_unlock_irqrestore(&n->list_lock, flags);
4004 /* Release empty slabs */
4005 list_for_each_entry_safe(page, t, &discard, lru)
4006 discard_slab(s, page);
4008 if (slabs_node(s, node))
4009 ret = 1;
4010 }
4012 return ret;
4013 }
4015 #ifdef CONFIG_MEMCG
4016 static void kmemcg_cache_deact_after_rcu(struct kmem_cache *s)
4017 {
4018 /*
4019 * Called with all the locks held after a sched RCU grace period.
4020 * Even if @s becomes empty after shrinking, we can't know that @s
4021 * doesn't have allocations already in-flight and thus can't
4022 * destroy @s until the associated memcg is released.
4023 *
4024 * However, let's remove the sysfs files for empty caches here.
4025 * Each cache has a lot of interface files which aren't
4026 * particularly useful for empty draining caches; otherwise, we can
4027 * easily end up with millions of unnecessary sysfs files on
4028 * systems which have a lot of memory and transient cgroups.
4029 */
4030 if (!__kmem_cache_shrink(s))
4031 sysfs_slab_remove(s);
4032 }
4034 void __kmemcg_cache_deactivate(struct kmem_cache *s)
4035 {
4036 /*
4037 * Disable empty slabs caching. Used to avoid pinning offline
4038 * memory cgroups by kmem pages that can be freed.
4039 */
4040 slub_set_cpu_partial(s, 0);
4041 s->min_partial = 0;
4043 /*
4044 * s->cpu_partial is checked locklessly (see put_cpu_partial), so
4045 * we have to make sure the change is visible before shrinking.
4046 */
4047 slab_deactivate_memcg_cache_rcu_sched(s, kmemcg_cache_deact_after_rcu);
4048 }
4049 #endif
4051 static int slab_mem_going_offline_callback(void *arg)
4052 {
4053 struct kmem_cache *s;
4055 mutex_lock(&slab_mutex);
4056 list_for_each_entry(s, &slab_caches, list)
4057 __kmem_cache_shrink(s);
4058 mutex_unlock(&slab_mutex);
4060 return 0;
4061 }
4063 static void slab_mem_offline_callback(void *arg)
4064 {
4065 struct kmem_cache_node *n;
4066 struct kmem_cache *s;
4067 struct memory_notify *marg = arg;
4068 int offline_node;
4070 offline_node = marg->status_change_nid_normal;
4072 /*
4073 * If the node still has available memory. we need kmem_cache_node
4074 * for it yet.
4075 */
4076 if (offline_node < 0)
4077 return;
4079 mutex_lock(&slab_mutex);
4080 list_for_each_entry(s, &slab_caches, list) {
4081 n = get_node(s, offline_node);
4082 if (n) {
4083 /*
4084 * if n->nr_slabs > 0, slabs still exist on the node
4085 * that is going down. We were unable to free them,
4086 * and offline_pages() function shouldn't call this
4087 * callback. So, we must fail.
4088 */
4089 BUG_ON(slabs_node(s, offline_node));
4091 s->node[offline_node] = NULL;
4092 kmem_cache_free(kmem_cache_node, n);
4093 }
4094 }
4095 mutex_unlock(&slab_mutex);
4096 }
4098 static int slab_mem_going_online_callback(void *arg)
4099 {
4100 struct kmem_cache_node *n;
4101 struct kmem_cache *s;
4102 struct memory_notify *marg = arg;
4103 int nid = marg->status_change_nid_normal;
4104 int ret = 0;
4106 /*
4107 * If the node's memory is already available, then kmem_cache_node is
4108 * already created. Nothing to do.
4109 */
4110 if (nid < 0)
4111 return 0;
4113 /*
4114 * We are bringing a node online. No memory is available yet. We must
4115 * allocate a kmem_cache_node structure in order to bring the node
4116 * online.
4117 */
4118 mutex_lock(&slab_mutex);
4119 list_for_each_entry(s, &slab_caches, list) {
4120 /*
4121 * XXX: kmem_cache_alloc_node will fallback to other nodes
4122 * since memory is not yet available from the node that
4123 * is brought up.
4124 */
4125 n = kmem_cache_alloc(kmem_cache_node, GFP_KERNEL);
4126 if (!n) {
4127 ret = -ENOMEM;
4128 goto out;
4129 }
4130 init_kmem_cache_node(n);
4131 s->node[nid] = n;
4132 }
4133 out:
4134 mutex_unlock(&slab_mutex);
4135 return ret;
4136 }
4138 static int slab_memory_callback(struct notifier_block *self,
4139 unsigned long action, void *arg)
4140 {
4141 int ret = 0;
4143 switch (action) {
4144 case MEM_GOING_ONLINE:
4145 ret = slab_mem_going_online_callback(arg);
4146 break;
4147 case MEM_GOING_OFFLINE:
4148 ret = slab_mem_going_offline_callback(arg);
4149 break;
4150 case MEM_OFFLINE:
4151 case MEM_CANCEL_ONLINE:
4152 slab_mem_offline_callback(arg);
4153 break;
4154 case MEM_ONLINE:
4155 case MEM_CANCEL_OFFLINE:
4156 break;
4157 }
4158 if (ret)
4159 ret = notifier_from_errno(ret);
4160 else
4161 ret = NOTIFY_OK;
4162 return ret;
4163 }
4165 static struct notifier_block slab_memory_callback_nb = {
4166 .notifier_call = slab_memory_callback,
4167 .priority = SLAB_CALLBACK_PRI,
4168 };
4170 /********************************************************************
4171 * Basic setup of slabs
4172 *******************************************************************/
4174 /*
4175 * Used for early kmem_cache structures that were allocated using
4176 * the page allocator. Allocate them properly then fix up the pointers
4177 * that may be pointing to the wrong kmem_cache structure.
4178 */
4180 static struct kmem_cache * __init bootstrap(struct kmem_cache *static_cache)
4181 {
4182 int node;
4183 struct kmem_cache *s = kmem_cache_zalloc(kmem_cache, GFP_NOWAIT);
4184 struct kmem_cache_node *n;
4186 memcpy(s, static_cache, kmem_cache->object_size);
4188 /*
4189 * This runs very early, and only the boot processor is supposed to be
4190 * up. Even if it weren't true, IRQs are not up so we couldn't fire
4191 * IPIs around.
4192 */
4193 __flush_cpu_slab(s, smp_processor_id());
4194 for_each_kmem_cache_node(s, node, n) {
4195 struct page *p;
4197 list_for_each_entry(p, &n->partial, lru)
4198 p->slab_cache = s;
4200 #ifdef CONFIG_SLUB_DEBUG
4201 list_for_each_entry(p, &n->full, lru)
4202 p->slab_cache = s;
4203 #endif
4204 }
4205 slab_init_memcg_params(s);
4206 list_add(&s->list, &slab_caches);
4207 memcg_link_cache(s);
4208 return s;
4209 }
4211 void __init kmem_cache_init(void)
4212 {
4213 static __initdata struct kmem_cache boot_kmem_cache,
4214 boot_kmem_cache_node;
4216 if (debug_guardpage_minorder())
4217 slub_max_order = 0;
4219 kmem_cache_node = &boot_kmem_cache_node;
4220 kmem_cache = &boot_kmem_cache;
4222 create_boot_cache(kmem_cache_node, "kmem_cache_node",
4223 sizeof(struct kmem_cache_node), SLAB_HWCACHE_ALIGN, 0, 0);
4225 register_hotmemory_notifier(&slab_memory_callback_nb);
4227 /* Able to allocate the per node structures */
4228 slab_state = PARTIAL;
4230 create_boot_cache(kmem_cache, "kmem_cache",
4231 offsetof(struct kmem_cache, node) +
4232 nr_node_ids * sizeof(struct kmem_cache_node *),
4233 SLAB_HWCACHE_ALIGN, 0, 0);
4235 kmem_cache = bootstrap(&boot_kmem_cache);
4236 kmem_cache_node = bootstrap(&boot_kmem_cache_node);
4238 /* Now we can use the kmem_cache to allocate kmalloc slabs */
4239 setup_kmalloc_cache_index_table();
4240 create_kmalloc_caches(0);
4242 /* Setup random freelists for each cache */
4243 init_freelist_randomization();
4245 cpuhp_setup_state_nocalls(CPUHP_SLUB_DEAD, "slub:dead", NULL,
4246 slub_cpu_dead);
4248 pr_info("SLUB: HWalign=%d, Order=%u-%u, MinObjects=%u, CPUs=%u, Nodes=%d\n",
4249 cache_line_size(),
4250 slub_min_order, slub_max_order, slub_min_objects,
4251 nr_cpu_ids, nr_node_ids);
4252 }
4254 void __init kmem_cache_init_late(void)
4255 {
4256 }
4258 struct kmem_cache *
4259 __kmem_cache_alias(const char *name, unsigned int size, unsigned int align,
4260 slab_flags_t flags, void (*ctor)(void *))
4261 {
4262 struct kmem_cache *s, *c;
4264 s = find_mergeable(size, align, flags, name, ctor);
4265 if (s) {
4266 s->refcount++;
4268 /*
4269 * Adjust the object sizes so that we clear
4270 * the complete object on kzalloc.
4271 */
4272 s->object_size = max(s->object_size, size);
4273 s->inuse = max(s->inuse, ALIGN(size, sizeof(void *)));
4275 for_each_memcg_cache(c, s) {
4276 c->object_size = s->object_size;
4277 c->inuse = max(c->inuse, ALIGN(size, sizeof(void *)));
4278 }
4280 if (sysfs_slab_alias(s, name)) {
4281 s->refcount--;
4282 s = NULL;
4283 }
4284 }
4286 return s;
4287 }
4289 int __kmem_cache_create(struct kmem_cache *s, slab_flags_t flags)
4290 {
4291 int err;
4293 err = kmem_cache_open(s, flags);
4294 if (err)
4295 return err;
4297 /* Mutex is not taken during early boot */
4298 if (slab_state <= UP)
4299 return 0;
4301 memcg_propagate_slab_attrs(s);
4302 err = sysfs_slab_add(s);
4303 if (err)
4304 __kmem_cache_release(s);
4306 return err;
4307 }
4309 void *__kmalloc_track_caller(size_t size, gfp_t gfpflags, unsigned long caller)
4310 {
4311 struct kmem_cache *s;
4312 void *ret;
4314 if (unlikely(size > KMALLOC_MAX_CACHE_SIZE))
4315 return kmalloc_large(size, gfpflags);
4317 s = kmalloc_slab(size, gfpflags);
4319 if (unlikely(ZERO_OR_NULL_PTR(s)))
4320 return s;
4322 ret = slab_alloc(s, gfpflags, caller);
4324 /* Honor the call site pointer we received. */
4325 trace_kmalloc(caller, ret, size, s->size, gfpflags);
4327 return ret;
4328 }
4330 #ifdef CONFIG_NUMA
4331 void *__kmalloc_node_track_caller(size_t size, gfp_t gfpflags,
4332 int node, unsigned long caller)
4333 {
4334 struct kmem_cache *s;
4335 void *ret;
4337 if (unlikely(size > KMALLOC_MAX_CACHE_SIZE)) {
4338 ret = kmalloc_large_node(size, gfpflags, node);
4340 trace_kmalloc_node(caller, ret,
4341 size, PAGE_SIZE << get_order(size),
4342 gfpflags, node);
4344 return ret;
4345 }
4347 s = kmalloc_slab(size, gfpflags);
4349 if (unlikely(ZERO_OR_NULL_PTR(s)))
4350 return s;
4352 ret = slab_alloc_node(s, gfpflags, node, caller);
4354 /* Honor the call site pointer we received. */
4355 trace_kmalloc_node(caller, ret, size, s->size, gfpflags, node);
4357 return ret;
4358 }
4359 #endif
4361 #ifdef CONFIG_SYSFS
4362 static int count_inuse(struct page *page)
4363 {
4364 return page->inuse;
4365 }
4367 static int count_total(struct page *page)
4368 {
4369 return page->objects;
4370 }
4371 #endif
4373 #ifdef CONFIG_SLUB_DEBUG
4374 static int validate_slab(struct kmem_cache *s, struct page *page,
4375 unsigned long *map)
4376 {
4377 void *p;
4378 void *addr = page_address(page);
4380 if (!check_slab(s, page) ||
4381 !on_freelist(s, page, NULL))
4382 return 0;
4384 /* Now we know that a valid freelist exists */
4385 bitmap_zero(map, page->objects);
4387 get_map(s, page, map);
4388 for_each_object(p, s, addr, page->objects) {
4389 if (test_bit(slab_index(p, s, addr), map))
4390 if (!check_object(s, page, p, SLUB_RED_INACTIVE))
4391 return 0;
4392 }
4394 for_each_object(p, s, addr, page->objects)
4395 if (!test_bit(slab_index(p, s, addr), map))
4396 if (!check_object(s, page, p, SLUB_RED_ACTIVE))
4397 return 0;
4398 return 1;
4399 }
4401 static void validate_slab_slab(struct kmem_cache *s, struct page *page,
4402 unsigned long *map)
4403 {
4404 slab_lock(page);
4405 validate_slab(s, page, map);
4406 slab_unlock(page);
4407 }
4409 static int validate_slab_node(struct kmem_cache *s,
4410 struct kmem_cache_node *n, unsigned long *map)
4411 {
4412 unsigned long count = 0;
4413 struct page *page;
4414 unsigned long flags;
4416 spin_lock_irqsave(&n->list_lock, flags);
4418 list_for_each_entry(page, &n->partial, lru) {
4419 validate_slab_slab(s, page, map);
4420 count++;
4421 }
4422 if (count != n->nr_partial)
4423 pr_err("SLUB %s: %ld partial slabs counted but counter=%ld\n",
4424 s->name, count, n->nr_partial);
4426 if (!(s->flags & SLAB_STORE_USER))
4427 goto out;
4429 list_for_each_entry(page, &n->full, lru) {
4430 validate_slab_slab(s, page, map);
4431 count++;
4432 }
4433 if (count != atomic_long_read(&n->nr_slabs))
4434 pr_err("SLUB: %s %ld slabs counted but counter=%ld\n",
4435 s->name, count, atomic_long_read(&n->nr_slabs));
4437 out:
4438 spin_unlock_irqrestore(&n->list_lock, flags);
4439 return count;
4440 }
4442 static long validate_slab_cache(struct kmem_cache *s)
4443 {
4444 int node;
4445 unsigned long count = 0;
4446 struct kmem_cache_node *n;
4447 unsigned long *map = bitmap_alloc(oo_objects(s->max), GFP_KERNEL);
4449 if (!map)
4450 return -ENOMEM;
4452 flush_all(s);
4453 for_each_kmem_cache_node(s, node, n)
4454 count += validate_slab_node(s, n, map);
4455 bitmap_free(map);
4456 return count;
4457 }
4458 /*
4459 * Generate lists of code addresses where slabcache objects are allocated
4460 * and freed.
4461 */
4463 struct location {
4464 unsigned long count;
4465 unsigned long addr;
4466 long long sum_time;
4467 long min_time;
4468 long max_time;
4469 long min_pid;
4470 long max_pid;
4471 DECLARE_BITMAP(cpus, NR_CPUS);
4472 nodemask_t nodes;
4473 };
4475 struct loc_track {
4476 unsigned long max;
4477 unsigned long count;
4478 struct location *loc;
4479 };
4481 static void free_loc_track(struct loc_track *t)
4482 {
4483 if (t->max)
4484 free_pages((unsigned long)t->loc,
4485 get_order(sizeof(struct location) * t->max));
4486 }
4488 static int alloc_loc_track(struct loc_track *t, unsigned long max, gfp_t flags)
4489 {
4490 struct location *l;
4491 int order;
4493 order = get_order(sizeof(struct location) * max);
4495 l = (void *)__get_free_pages(flags, order);
4496 if (!l)
4497 return 0;
4499 if (t->count) {
4500 memcpy(l, t->loc, sizeof(struct location) * t->count);
4501 free_loc_track(t);
4502 }
4503 t->max = max;
4504 t->loc = l;
4505 return 1;
4506 }
4508 static int add_location(struct loc_track *t, struct kmem_cache *s,
4509 const struct track *track)
4510 {
4511 long start, end, pos;
4512 struct location *l;
4513 unsigned long caddr;
4514 unsigned long age = jiffies - track->when;
4516 start = -1;
4517 end = t->count;
4519 for ( ; ; ) {
4520 pos = start + (end - start + 1) / 2;
4522 /*
4523 * There is nothing at "end". If we end up there
4524 * we need to add something to before end.
4525 */
4526 if (pos == end)
4527 break;
4529 caddr = t->loc[pos].addr;
4530 if (track->addr == caddr) {
4532 l = &t->loc[pos];
4533 l->count++;
4534 if (track->when) {
4535 l->sum_time += age;
4536 if (age < l->min_time)
4537 l->min_time = age;
4538 if (age > l->max_time)
4539 l->max_time = age;
4541 if (track->pid < l->min_pid)
4542 l->min_pid = track->pid;
4543 if (track->pid > l->max_pid)
4544 l->max_pid = track->pid;
4546 cpumask_set_cpu(track->cpu,
4547 to_cpumask(l->cpus));
4548 }
4549 node_set(page_to_nid(virt_to_page(track)), l->nodes);
4550 return 1;
4551 }
4553 if (track->addr < caddr)
4554 end = pos;
4555 else
4556 start = pos;
4557 }
4559 /*
4560 * Not found. Insert new tracking element.
4561 */
4562 if (t->count >= t->max && !alloc_loc_track(t, 2 * t->max, GFP_ATOMIC))
4563 return 0;
4565 l = t->loc + pos;
4566 if (pos < t->count)
4567 memmove(l + 1, l,
4568 (t->count - pos) * sizeof(struct location));
4569 t->count++;
4570 l->count = 1;
4571 l->addr = track->addr;
4572 l->sum_time = age;
4573 l->min_time = age;
4574 l->max_time = age;
4575 l->min_pid = track->pid;
4576 l->max_pid = track->pid;
4577 cpumask_clear(to_cpumask(l->cpus));
4578 cpumask_set_cpu(track->cpu, to_cpumask(l->cpus));
4579 nodes_clear(l->nodes);
4580 node_set(page_to_nid(virt_to_page(track)), l->nodes);
4581 return 1;
4582 }
4584 static void process_slab(struct loc_track *t, struct kmem_cache *s,
4585 struct page *page, enum track_item alloc,
4586 unsigned long *map)
4587 {
4588 void *addr = page_address(page);
4589 void *p;
4591 bitmap_zero(map, page->objects);
4592 get_map(s, page, map);
4594 for_each_object(p, s, addr, page->objects)
4595 if (!test_bit(slab_index(p, s, addr), map))
4596 add_location(t, s, get_track(s, p, alloc));
4597 }
4599 static int list_locations(struct kmem_cache *s, char *buf,
4600 enum track_item alloc)
4601 {
4602 int len = 0;
4603 unsigned long i;
4604 struct loc_track t = { 0, 0, NULL };
4605 int node;
4606 struct kmem_cache_node *n;
4607 unsigned long *map = bitmap_alloc(oo_objects(s->max), GFP_KERNEL);
4609 if (!map || !alloc_loc_track(&t, PAGE_SIZE / sizeof(struct location),
4610 GFP_KERNEL)) {
4611 bitmap_free(map);
4612 return sprintf(buf, "Out of memory\n");
4613 }
4614 /* Push back cpu slabs */
4615 flush_all(s);
4617 for_each_kmem_cache_node(s, node, n) {
4618 unsigned long flags;
4619 struct page *page;
4621 if (!atomic_long_read(&n->nr_slabs))
4622 continue;
4624 spin_lock_irqsave(&n->list_lock, flags);
4625 list_for_each_entry(page, &n->partial, lru)
4626 process_slab(&t, s, page, alloc, map);
4627 list_for_each_entry(page, &n->full, lru)
4628 process_slab(&t, s, page, alloc, map);
4629 spin_unlock_irqrestore(&n->list_lock, flags);
4630 }
4632 for (i = 0; i < t.count; i++) {
4633 struct location *l = &t.loc[i];
4635 if (len > PAGE_SIZE - KSYM_SYMBOL_LEN - 100)
4636 break;
4637 len += sprintf(buf + len, "%7ld ", l->count);
4639 if (l->addr)
4640 len += sprintf(buf + len, "%pS", (void *)l->addr);
4641 else
4642 len += sprintf(buf + len, "<not-available>");
4644 if (l->sum_time != l->min_time) {
4645 len += sprintf(buf + len, " age=%ld/%ld/%ld",
4646 l->min_time,
4647 (long)div_u64(l->sum_time, l->count),
4648 l->max_time);
4649 } else
4650 len += sprintf(buf + len, " age=%ld",
4651 l->min_time);
4653 if (l->min_pid != l->max_pid)
4654 len += sprintf(buf + len, " pid=%ld-%ld",
4655 l->min_pid, l->max_pid);
4656 else
4657 len += sprintf(buf + len, " pid=%ld",
4658 l->min_pid);
4660 if (num_online_cpus() > 1 &&
4661 !cpumask_empty(to_cpumask(l->cpus)) &&
4662 len < PAGE_SIZE - 60)
4663 len += scnprintf(buf + len, PAGE_SIZE - len - 50,
4664 " cpus=%*pbl",
4665 cpumask_pr_args(to_cpumask(l->cpus)));
4667 if (nr_online_nodes > 1 && !nodes_empty(l->nodes) &&
4668 len < PAGE_SIZE - 60)
4669 len += scnprintf(buf + len, PAGE_SIZE - len - 50,
4670 " nodes=%*pbl",
4671 nodemask_pr_args(&l->nodes));
4673 len += sprintf(buf + len, "\n");
4674 }
4676 free_loc_track(&t);
4677 bitmap_free(map);
4678 if (!t.count)
4679 len += sprintf(buf, "No data\n");
4680 return len;
4681 }
4682 #endif
4684 #ifdef SLUB_RESILIENCY_TEST
4685 static void __init resiliency_test(void)
4686 {
4687 u8 *p;
4688 int type = KMALLOC_NORMAL;
4690 BUILD_BUG_ON(KMALLOC_MIN_SIZE > 16 || KMALLOC_SHIFT_HIGH < 10);
4692 pr_err("SLUB resiliency testing\n");
4693 pr_err("-----------------------\n");
4694 pr_err("A. Corruption after allocation\n");
4696 p = kzalloc(16, GFP_KERNEL);
4697 p[16] = 0x12;
4698 pr_err("\n1. kmalloc-16: Clobber Redzone/next pointer 0x12->0x%p\n\n",
4699 p + 16);
4701 validate_slab_cache(kmalloc_caches[type][4]);
4703 /* Hmmm... The next two are dangerous */
4704 p = kzalloc(32, GFP_KERNEL);
4705 p[32 + sizeof(void *)] = 0x34;
4706 pr_err("\n2. kmalloc-32: Clobber next pointer/next slab 0x34 -> -0x%p\n",
4707 p);
4708 pr_err("If allocated object is overwritten then not detectable\n\n");
4710 validate_slab_cache(kmalloc_caches[type][5]);
4711 p = kzalloc(64, GFP_KERNEL);
4712 p += 64 + (get_cycles() & 0xff) * sizeof(void *);
4713 *p = 0x56;
4714 pr_err("\n3. kmalloc-64: corrupting random byte 0x56->0x%p\n",
4715 p);
4716 pr_err("If allocated object is overwritten then not detectable\n\n");
4717 validate_slab_cache(kmalloc_caches[type][6]);
4719 pr_err("\nB. Corruption after free\n");
4720 p = kzalloc(128, GFP_KERNEL);
4721 kfree(p);
4722 *p = 0x78;
4723 pr_err("1. kmalloc-128: Clobber first word 0x78->0x%p\n\n", p);
4724 validate_slab_cache(kmalloc_caches[type][7]);
4726 p = kzalloc(256, GFP_KERNEL);
4727 kfree(p);
4728 p[50] = 0x9a;
4729 pr_err("\n2. kmalloc-256: Clobber 50th byte 0x9a->0x%p\n\n", p);
4730 validate_slab_cache(kmalloc_caches[type][8]);
4732 p = kzalloc(512, GFP_KERNEL);
4733 kfree(p);
4734 p[512] = 0xab;
4735 pr_err("\n3. kmalloc-512: Clobber redzone 0xab->0x%p\n\n", p);
4736 validate_slab_cache(kmalloc_caches[type][9]);
4737 }
4738 #else
4739 #ifdef CONFIG_SYSFS
4740 static void resiliency_test(void) {};
4741 #endif
4742 #endif
4744 #ifdef CONFIG_SYSFS
4745 enum slab_stat_type {
4746 SL_ALL, /* All slabs */
4747 SL_PARTIAL, /* Only partially allocated slabs */
4748 SL_CPU, /* Only slabs used for cpu caches */
4749 SL_OBJECTS, /* Determine allocated objects not slabs */
4750 SL_TOTAL /* Determine object capacity not slabs */
4751 };
4753 #define SO_ALL (1 << SL_ALL)
4754 #define SO_PARTIAL (1 << SL_PARTIAL)
4755 #define SO_CPU (1 << SL_CPU)
4756 #define SO_OBJECTS (1 << SL_OBJECTS)
4757 #define SO_TOTAL (1 << SL_TOTAL)
4759 #ifdef CONFIG_MEMCG
4760 static bool memcg_sysfs_enabled = IS_ENABLED(CONFIG_SLUB_MEMCG_SYSFS_ON);
4762 static int __init setup_slub_memcg_sysfs(char *str)
4763 {
4764 int v;
4766 if (get_option(&str, &v) > 0)
4767 memcg_sysfs_enabled = v;
4769 return 1;
4770 }
4772 __setup("slub_memcg_sysfs=", setup_slub_memcg_sysfs);
4773 #endif
4775 static ssize_t show_slab_objects(struct kmem_cache *s,
4776 char *buf, unsigned long flags)
4777 {
4778 unsigned long total = 0;
4779 int node;
4780 int x;
4781 unsigned long *nodes;
4783 nodes = kcalloc(nr_node_ids, sizeof(unsigned long), GFP_KERNEL);
4784 if (!nodes)
4785 return -ENOMEM;
4787 if (flags & SO_CPU) {
4788 int cpu;
4790 for_each_possible_cpu(cpu) {
4791 struct kmem_cache_cpu *c = per_cpu_ptr(s->cpu_slab,
4792 cpu);
4793 int node;
4794 struct page *page;
4796 page = READ_ONCE(c->page);
4797 if (!page)
4798 continue;
4800 node = page_to_nid(page);
4801 if (flags & SO_TOTAL)
4802 x = page->objects;
4803 else if (flags & SO_OBJECTS)
4804 x = page->inuse;
4805 else
4806 x = 1;
4808 total += x;
4809 nodes[node] += x;
4811 page = slub_percpu_partial_read_once(c);
4812 if (page) {
4813 node = page_to_nid(page);
4814 if (flags & SO_TOTAL)
4815 WARN_ON_ONCE(1);
4816 else if (flags & SO_OBJECTS)
4817 WARN_ON_ONCE(1);
4818 else
4819 x = page->pages;
4820 total += x;
4821 nodes[node] += x;
4822 }
4823 }
4824 }
4826 get_online_mems();
4827 #ifdef CONFIG_SLUB_DEBUG
4828 if (flags & SO_ALL) {
4829 struct kmem_cache_node *n;
4831 for_each_kmem_cache_node(s, node, n) {
4833 if (flags & SO_TOTAL)
4834 x = atomic_long_read(&n->total_objects);
4835 else if (flags & SO_OBJECTS)
4836 x = atomic_long_read(&n->total_objects) -
4837 count_partial(n, count_free);
4838 else
4839 x = atomic_long_read(&n->nr_slabs);
4840 total += x;
4841 nodes[node] += x;
4842 }
4844 } else
4845 #endif
4846 if (flags & SO_PARTIAL) {
4847 struct kmem_cache_node *n;
4849 for_each_kmem_cache_node(s, node, n) {
4850 if (flags & SO_TOTAL)
4851 x = count_partial(n, count_total);
4852 else if (flags & SO_OBJECTS)
4853 x = count_partial(n, count_inuse);
4854 else
4855 x = n->nr_partial;
4856 total += x;
4857 nodes[node] += x;
4858 }
4859 }
4860 x = sprintf(buf, "%lu", total);
4861 #ifdef CONFIG_NUMA
4862 for (node = 0; node < nr_node_ids; node++)
4863 if (nodes[node])
4864 x += sprintf(buf + x, " N%d=%lu",
4865 node, nodes[node]);
4866 #endif
4867 put_online_mems();
4868 kfree(nodes);
4869 return x + sprintf(buf + x, "\n");
4870 }
4872 #ifdef CONFIG_SLUB_DEBUG
4873 static int any_slab_objects(struct kmem_cache *s)
4874 {
4875 int node;
4876 struct kmem_cache_node *n;
4878 for_each_kmem_cache_node(s, node, n)
4879 if (atomic_long_read(&n->total_objects))
4880 return 1;
4882 return 0;
4883 }
4884 #endif
4886 #define to_slab_attr(n) container_of(n, struct slab_attribute, attr)
4887 #define to_slab(n) container_of(n, struct kmem_cache, kobj)
4889 struct slab_attribute {
4890 struct attribute attr;
4891 ssize_t (*show)(struct kmem_cache *s, char *buf);
4892 ssize_t (*store)(struct kmem_cache *s, const char *x, size_t count);
4893 };
4895 #define SLAB_ATTR_RO(_name) \
4896 static struct slab_attribute _name##_attr = \
4897 __ATTR(_name, 0400, _name##_show, NULL)
4899 #define SLAB_ATTR(_name) \
4900 static struct slab_attribute _name##_attr = \
4901 __ATTR(_name, 0600, _name##_show, _name##_store)
4903 static ssize_t slab_size_show(struct kmem_cache *s, char *buf)
4904 {
4905 return sprintf(buf, "%u\n", s->size);
4906 }
4907 SLAB_ATTR_RO(slab_size);
4909 static ssize_t align_show(struct kmem_cache *s, char *buf)
4910 {
4911 return sprintf(buf, "%u\n", s->align);
4912 }
4913 SLAB_ATTR_RO(align);
4915 static ssize_t object_size_show(struct kmem_cache *s, char *buf)
4916 {
4917 return sprintf(buf, "%u\n", s->object_size);
4918 }
4919 SLAB_ATTR_RO(object_size);
4921 static ssize_t objs_per_slab_show(struct kmem_cache *s, char *buf)
4922 {
4923 return sprintf(buf, "%u\n", oo_objects(s->oo));
4924 }
4925 SLAB_ATTR_RO(objs_per_slab);
4927 static ssize_t order_store(struct kmem_cache *s,
4928 const char *buf, size_t length)
4929 {
4930 unsigned int order;
4931 int err;
4933 err = kstrtouint(buf, 10, &order);
4934 if (err)
4935 return err;
4937 if (order > slub_max_order || order < slub_min_order)
4938 return -EINVAL;
4940 calculate_sizes(s, order);
4941 return length;
4942 }
4944 static ssize_t order_show(struct kmem_cache *s, char *buf)
4945 {
4946 return sprintf(buf, "%u\n", oo_order(s->oo));
4947 }
4948 SLAB_ATTR(order);
4950 static ssize_t min_partial_show(struct kmem_cache *s, char *buf)
4951 {
4952 return sprintf(buf, "%lu\n", s->min_partial);
4953 }
4955 static ssize_t min_partial_store(struct kmem_cache *s, const char *buf,
4956 size_t length)
4957 {
4958 unsigned long min;
4959 int err;
4961 err = kstrtoul(buf, 10, &min);
4962 if (err)
4963 return err;
4965 set_min_partial(s, min);
4966 return length;
4967 }
4968 SLAB_ATTR(min_partial);
4970 static ssize_t cpu_partial_show(struct kmem_cache *s, char *buf)
4971 {
4972 return sprintf(buf, "%u\n", slub_cpu_partial(s));
4973 }
4975 static ssize_t cpu_partial_store(struct kmem_cache *s, const char *buf,
4976 size_t length)
4977 {
4978 unsigned int objects;
4979 int err;
4981 err = kstrtouint(buf, 10, &objects);
4982 if (err)
4983 return err;
4984 if (objects && !kmem_cache_has_cpu_partial(s))
4985 return -EINVAL;
4987 slub_set_cpu_partial(s, objects);
4988 flush_all(s);
4989 return length;
4990 }
4991 SLAB_ATTR(cpu_partial);
4993 static ssize_t ctor_show(struct kmem_cache *s, char *buf)
4994 {
4995 if (!s->ctor)
4996 return 0;
4997 return sprintf(buf, "%pS\n", s->ctor);
4998 }
4999 SLAB_ATTR_RO(ctor);
5001 static ssize_t aliases_show(struct kmem_cache *s, char *buf)
5002 {
5003 return sprintf(buf, "%d\n", s->refcount < 0 ? 0 : s->refcount - 1);
5004 }
5005 SLAB_ATTR_RO(aliases);
5007 static ssize_t partial_show(struct kmem_cache *s, char *buf)
5008 {
5009 return show_slab_objects(s, buf, SO_PARTIAL);
5010 }
5011 SLAB_ATTR_RO(partial);
5013 static ssize_t cpu_slabs_show(struct kmem_cache *s, char *buf)
5014 {
5015 return show_slab_objects(s, buf, SO_CPU);
5016 }
5017 SLAB_ATTR_RO(cpu_slabs);
5019 static ssize_t objects_show(struct kmem_cache *s, char *buf)
5020 {
5021 return show_slab_objects(s, buf, SO_ALL|SO_OBJECTS);
5022 }
5023 SLAB_ATTR_RO(objects);
5025 static ssize_t objects_partial_show(struct kmem_cache *s, char *buf)
5026 {
5027 return show_slab_objects(s, buf, SO_PARTIAL|SO_OBJECTS);
5028 }
5029 SLAB_ATTR_RO(objects_partial);
5031 static ssize_t slabs_cpu_partial_show(struct kmem_cache *s, char *buf)
5032 {
5033 int objects = 0;
5034 int pages = 0;
5035 int cpu;
5036 int len;
5038 for_each_online_cpu(cpu) {
5039 struct page *page;
5041 page = slub_percpu_partial(per_cpu_ptr(s->cpu_slab, cpu));
5043 if (page) {
5044 pages += page->pages;
5045 objects += page->pobjects;
5046 }
5047 }
5049 len = sprintf(buf, "%d(%d)", objects, pages);
5051 #ifdef CONFIG_SMP
5052 for_each_online_cpu(cpu) {
5053 struct page *page;
5055 page = slub_percpu_partial(per_cpu_ptr(s->cpu_slab, cpu));
5057 if (page && len < PAGE_SIZE - 20)
5058 len += sprintf(buf + len, " C%d=%d(%d)", cpu,
5059 page->pobjects, page->pages);
5060 }
5061 #endif
5062 return len + sprintf(buf + len, "\n");
5063 }
5064 SLAB_ATTR_RO(slabs_cpu_partial);
5066 static ssize_t reclaim_account_show(struct kmem_cache *s, char *buf)
5067 {
5068 return sprintf(buf, "%d\n", !!(s->flags & SLAB_RECLAIM_ACCOUNT));
5069 }
5071 static ssize_t reclaim_account_store(struct kmem_cache *s,
5072 const char *buf, size_t length)
5073 {
5074 s->flags &= ~SLAB_RECLAIM_ACCOUNT;
5075 if (buf[0] == '1')
5076 s->flags |= SLAB_RECLAIM_ACCOUNT;
5077 return length;
5078 }
5079 SLAB_ATTR(reclaim_account);
5081 static ssize_t hwcache_align_show(struct kmem_cache *s, char *buf)
5082 {
5083 return sprintf(buf, "%d\n", !!(s->flags & SLAB_HWCACHE_ALIGN));
5084 }
5085 SLAB_ATTR_RO(hwcache_align);
5087 #ifdef CONFIG_ZONE_DMA
5088 static ssize_t cache_dma_show(struct kmem_cache *s, char *buf)
5089 {
5090 return sprintf(buf, "%d\n", !!(s->flags & SLAB_CACHE_DMA));
5091 }
5092 SLAB_ATTR_RO(cache_dma);
5093 #endif
5095 static ssize_t usersize_show(struct kmem_cache *s, char *buf)
5096 {
5097 return sprintf(buf, "%u\n", s->usersize);
5098 }
5099 SLAB_ATTR_RO(usersize);
5101 static ssize_t destroy_by_rcu_show(struct kmem_cache *s, char *buf)
5102 {
5103 return sprintf(buf, "%d\n", !!(s->flags & SLAB_TYPESAFE_BY_RCU));
5104 }
5105 SLAB_ATTR_RO(destroy_by_rcu);
5107 #ifdef CONFIG_SLUB_DEBUG
5108 static ssize_t slabs_show(struct kmem_cache *s, char *buf)
5109 {
5110 return show_slab_objects(s, buf, SO_ALL);
5111 }
5112 SLAB_ATTR_RO(slabs);
5114 static ssize_t total_objects_show(struct kmem_cache *s, char *buf)
5115 {
5116 return show_slab_objects(s, buf, SO_ALL|SO_TOTAL);
5117 }
5118 SLAB_ATTR_RO(total_objects);
5120 static ssize_t sanity_checks_show(struct kmem_cache *s, char *buf)
5121 {
5122 return sprintf(buf, "%d\n", !!(s->flags & SLAB_CONSISTENCY_CHECKS));
5123 }
5125 static ssize_t sanity_checks_store(struct kmem_cache *s,
5126 const char *buf, size_t length)
5127 {
5128 s->flags &= ~SLAB_CONSISTENCY_CHECKS;
5129 if (buf[0] == '1') {
5130 s->flags &= ~__CMPXCHG_DOUBLE;
5131 s->flags |= SLAB_CONSISTENCY_CHECKS;
5132 }
5133 return length;
5134 }
5135 SLAB_ATTR(sanity_checks);
5137 static ssize_t trace_show(struct kmem_cache *s, char *buf)
5138 {
5139 return sprintf(buf, "%d\n", !!(s->flags & SLAB_TRACE));
5140 }
5142 static ssize_t trace_store(struct kmem_cache *s, const char *buf,
5143 size_t length)
5144 {
5145 /*
5146 * Tracing a merged cache is going to give confusing results
5147 * as well as cause other issues like converting a mergeable
5148 * cache into an umergeable one.
5149 */
5150 if (s->refcount > 1)
5151 return -EINVAL;
5153 s->flags &= ~SLAB_TRACE;
5154 if (buf[0] == '1') {
5155 s->flags &= ~__CMPXCHG_DOUBLE;
5156 s->flags |= SLAB_TRACE;
5157 }
5158 return length;
5159 }
5160 SLAB_ATTR(trace);
5162 static ssize_t red_zone_show(struct kmem_cache *s, char *buf)
5163 {
5164 return sprintf(buf, "%d\n", !!(s->flags & SLAB_RED_ZONE));
5165 }
5167 static ssize_t red_zone_store(struct kmem_cache *s,
5168 const char *buf, size_t length)
5169 {
5170 if (any_slab_objects(s))
5171 return -EBUSY;
5173 s->flags &= ~SLAB_RED_ZONE;
5174 if (buf[0] == '1') {
5175 s->flags |= SLAB_RED_ZONE;
5176 }
5177 calculate_sizes(s, -1);
5178 return length;
5179 }
5180 SLAB_ATTR(red_zone);
5182 static ssize_t poison_show(struct kmem_cache *s, char *buf)
5183 {
5184 return sprintf(buf, "%d\n", !!(s->flags & SLAB_POISON));
5185 }
5187 static ssize_t poison_store(struct kmem_cache *s,
5188 const char *buf, size_t length)
5189 {
5190 if (any_slab_objects(s))
5191 return -EBUSY;
5193 s->flags &= ~SLAB_POISON;
5194 if (buf[0] == '1') {
5195 s->flags |= SLAB_POISON;
5196 }
5197 calculate_sizes(s, -1);
5198 return length;
5199 }
5200 SLAB_ATTR(poison);
5202 static ssize_t store_user_show(struct kmem_cache *s, char *buf)
5203 {
5204 return sprintf(buf, "%d\n", !!(s->flags & SLAB_STORE_USER));
5205 }
5207 static ssize_t store_user_store(struct kmem_cache *s,
5208 const char *buf, size_t length)
5209 {
5210 if (any_slab_objects(s))
5211 return -EBUSY;
5213 s->flags &= ~SLAB_STORE_USER;
5214 if (buf[0] == '1') {
5215 s->flags &= ~__CMPXCHG_DOUBLE;
5216 s->flags |= SLAB_STORE_USER;
5217 }
5218 calculate_sizes(s, -1);
5219 return length;
5220 }
5221 SLAB_ATTR(store_user);
5223 static ssize_t validate_show(struct kmem_cache *s, char *buf)
5224 {
5225 return 0;
5226 }
5228 static ssize_t validate_store(struct kmem_cache *s,
5229 const char *buf, size_t length)
5230 {
5231 int ret = -EINVAL;
5233 if (buf[0] == '1') {
5234 ret = validate_slab_cache(s);
5235 if (ret >= 0)
5236 ret = length;
5237 }
5238 return ret;
5239 }
5240 SLAB_ATTR(validate);
5242 static ssize_t alloc_calls_show(struct kmem_cache *s, char *buf)
5243 {
5244 if (!(s->flags & SLAB_STORE_USER))
5245 return -ENOSYS;
5246 return list_locations(s, buf, TRACK_ALLOC);
5247 }
5248 SLAB_ATTR_RO(alloc_calls);
5250 static ssize_t free_calls_show(struct kmem_cache *s, char *buf)
5251 {
5252 if (!(s->flags & SLAB_STORE_USER))
5253 return -ENOSYS;
5254 return list_locations(s, buf, TRACK_FREE);
5255 }
5256 SLAB_ATTR_RO(free_calls);
5257 #endif /* CONFIG_SLUB_DEBUG */
5259 #ifdef CONFIG_FAILSLAB
5260 static ssize_t failslab_show(struct kmem_cache *s, char *buf)
5261 {
5262 return sprintf(buf, "%d\n", !!(s->flags & SLAB_FAILSLAB));
5263 }
5265 static ssize_t failslab_store(struct kmem_cache *s, const char *buf,
5266 size_t length)
5267 {
5268 if (s->refcount > 1)
5269 return -EINVAL;
5271 s->flags &= ~SLAB_FAILSLAB;
5272 if (buf[0] == '1')
5273 s->flags |= SLAB_FAILSLAB;
5274 return length;
5275 }
5276 SLAB_ATTR(failslab);
5277 #endif
5279 static ssize_t shrink_show(struct kmem_cache *s, char *buf)
5280 {
5281 return 0;
5282 }
5284 static ssize_t shrink_store(struct kmem_cache *s,
5285 const char *buf, size_t length)
5286 {
5287 if (buf[0] == '1')
5288 kmem_cache_shrink(s);
5289 else
5290 return -EINVAL;
5291 return length;
5292 }
5293 SLAB_ATTR(shrink);
5295 #ifdef CONFIG_NUMA
5296 static ssize_t remote_node_defrag_ratio_show(struct kmem_cache *s, char *buf)
5297 {
5298 return sprintf(buf, "%u\n", s->remote_node_defrag_ratio / 10);
5299 }
5301 static ssize_t remote_node_defrag_ratio_store(struct kmem_cache *s,
5302 const char *buf, size_t length)
5303 {
5304 unsigned int ratio;
5305 int err;
5307 err = kstrtouint(buf, 10, &ratio);
5308 if (err)
5309 return err;
5310 if (ratio > 100)
5311 return -ERANGE;
5313 s->remote_node_defrag_ratio = ratio * 10;
5315 return length;
5316 }
5317 SLAB_ATTR(remote_node_defrag_ratio);
5318 #endif
5320 #ifdef CONFIG_SLUB_STATS
5321 static int show_stat(struct kmem_cache *s, char *buf, enum stat_item si)
5322 {
5323 unsigned long sum = 0;
5324 int cpu;
5325 int len;
5326 int *data = kmalloc_array(nr_cpu_ids, sizeof(int), GFP_KERNEL);
5328 if (!data)
5329 return -ENOMEM;
5331 for_each_online_cpu(cpu) {
5332 unsigned x = per_cpu_ptr(s->cpu_slab, cpu)->stat[si];
5334 data[cpu] = x;
5335 sum += x;
5336 }
5338 len = sprintf(buf, "%lu", sum);
5340 #ifdef CONFIG_SMP
5341 for_each_online_cpu(cpu) {
5342 if (data[cpu] && len < PAGE_SIZE - 20)
5343 len += sprintf(buf + len, " C%d=%u", cpu, data[cpu]);
5344 }
5345 #endif
5346 kfree(data);
5347 return len + sprintf(buf + len, "\n");
5348 }
5350 static void clear_stat(struct kmem_cache *s, enum stat_item si)
5351 {
5352 int cpu;
5354 for_each_online_cpu(cpu)
5355 per_cpu_ptr(s->cpu_slab, cpu)->stat[si] = 0;
5356 }
5358 #define STAT_ATTR(si, text) \
5359 static ssize_t text##_show(struct kmem_cache *s, char *buf) \
5360 { \
5361 return show_stat(s, buf, si); \
5362 } \
5363 static ssize_t text##_store(struct kmem_cache *s, \
5364 const char *buf, size_t length) \
5365 { \
5366 if (buf[0] != '0') \
5367 return -EINVAL; \
5368 clear_stat(s, si); \
5369 return length; \
5370 } \
5371 SLAB_ATTR(text); \
5373 STAT_ATTR(ALLOC_FASTPATH, alloc_fastpath);
5374 STAT_ATTR(ALLOC_SLOWPATH, alloc_slowpath);
5375 STAT_ATTR(FREE_FASTPATH, free_fastpath);
5376 STAT_ATTR(FREE_SLOWPATH, free_slowpath);
5377 STAT_ATTR(FREE_FROZEN, free_frozen);
5378 STAT_ATTR(FREE_ADD_PARTIAL, free_add_partial);
5379 STAT_ATTR(FREE_REMOVE_PARTIAL, free_remove_partial);
5380 STAT_ATTR(ALLOC_FROM_PARTIAL, alloc_from_partial);
5381 STAT_ATTR(ALLOC_SLAB, alloc_slab);
5382 STAT_ATTR(ALLOC_REFILL, alloc_refill);
5383 STAT_ATTR(ALLOC_NODE_MISMATCH, alloc_node_mismatch);
5384 STAT_ATTR(FREE_SLAB, free_slab);
5385 STAT_ATTR(CPUSLAB_FLUSH, cpuslab_flush);
5386 STAT_ATTR(DEACTIVATE_FULL, deactivate_full);
5387 STAT_ATTR(DEACTIVATE_EMPTY, deactivate_empty);
5388 STAT_ATTR(DEACTIVATE_TO_HEAD, deactivate_to_head);
5389 STAT_ATTR(DEACTIVATE_TO_TAIL, deactivate_to_tail);
5390 STAT_ATTR(DEACTIVATE_REMOTE_FREES, deactivate_remote_frees);
5391 STAT_ATTR(DEACTIVATE_BYPASS, deactivate_bypass);
5392 STAT_ATTR(ORDER_FALLBACK, order_fallback);
5393 STAT_ATTR(CMPXCHG_DOUBLE_CPU_FAIL, cmpxchg_double_cpu_fail);
5394 STAT_ATTR(CMPXCHG_DOUBLE_FAIL, cmpxchg_double_fail);
5395 STAT_ATTR(CPU_PARTIAL_ALLOC, cpu_partial_alloc);
5396 STAT_ATTR(CPU_PARTIAL_FREE, cpu_partial_free);
5397 STAT_ATTR(CPU_PARTIAL_NODE, cpu_partial_node);
5398 STAT_ATTR(CPU_PARTIAL_DRAIN, cpu_partial_drain);
5399 #endif
5401 static struct attribute *slab_attrs[] = {
5402 &slab_size_attr.attr,
5403 &object_size_attr.attr,
5404 &objs_per_slab_attr.attr,
5405 &order_attr.attr,
5406 &min_partial_attr.attr,
5407 &cpu_partial_attr.attr,
5408 &objects_attr.attr,
5409 &objects_partial_attr.attr,
5410 &partial_attr.attr,
5411 &cpu_slabs_attr.attr,
5412 &ctor_attr.attr,
5413 &aliases_attr.attr,
5414 &align_attr.attr,
5415 &hwcache_align_attr.attr,
5416 &reclaim_account_attr.attr,
5417 &destroy_by_rcu_attr.attr,
5418 &shrink_attr.attr,
5419 &slabs_cpu_partial_attr.attr,
5420 #ifdef CONFIG_SLUB_DEBUG
5421 &total_objects_attr.attr,
5422 &slabs_attr.attr,
5423 &sanity_checks_attr.attr,
5424 &trace_attr.attr,
5425 &red_zone_attr.attr,
5426 &poison_attr.attr,
5427 &store_user_attr.attr,
5428 &validate_attr.attr,
5429 &alloc_calls_attr.attr,
5430 &free_calls_attr.attr,
5431 #endif
5432 #ifdef CONFIG_ZONE_DMA
5433 &cache_dma_attr.attr,
5434 #endif
5435 #ifdef CONFIG_NUMA
5436 &remote_node_defrag_ratio_attr.attr,
5437 #endif
5438 #ifdef CONFIG_SLUB_STATS
5439 &alloc_fastpath_attr.attr,
5440 &alloc_slowpath_attr.attr,
5441 &free_fastpath_attr.attr,
5442 &free_slowpath_attr.attr,
5443 &free_frozen_attr.attr,
5444 &free_add_partial_attr.attr,
5445 &free_remove_partial_attr.attr,
5446 &alloc_from_partial_attr.attr,
5447 &alloc_slab_attr.attr,
5448 &alloc_refill_attr.attr,
5449 &alloc_node_mismatch_attr.attr,
5450 &free_slab_attr.attr,
5451 &cpuslab_flush_attr.attr,
5452 &deactivate_full_attr.attr,
5453 &deactivate_empty_attr.attr,
5454 &deactivate_to_head_attr.attr,
5455 &deactivate_to_tail_attr.attr,
5456 &deactivate_remote_frees_attr.attr,
5457 &deactivate_bypass_attr.attr,
5458 &order_fallback_attr.attr,
5459 &cmpxchg_double_fail_attr.attr,
5460 &cmpxchg_double_cpu_fail_attr.attr,
5461 &cpu_partial_alloc_attr.attr,
5462 &cpu_partial_free_attr.attr,
5463 &cpu_partial_node_attr.attr,
5464 &cpu_partial_drain_attr.attr,
5465 #endif
5466 #ifdef CONFIG_FAILSLAB
5467 &failslab_attr.attr,
5468 #endif
5469 &usersize_attr.attr,
5471 NULL
5472 };
5474 static const struct attribute_group slab_attr_group = {
5475 .attrs = slab_attrs,
5476 };
5478 static ssize_t slab_attr_show(struct kobject *kobj,
5479 struct attribute *attr,
5480 char *buf)
5481 {
5482 struct slab_attribute *attribute;
5483 struct kmem_cache *s;
5484 int err;
5486 attribute = to_slab_attr(attr);
5487 s = to_slab(kobj);
5489 if (!attribute->show)
5490 return -EIO;
5492 err = attribute->show(s, buf);
5494 return err;
5495 }
5497 static ssize_t slab_attr_store(struct kobject *kobj,
5498 struct attribute *attr,
5499 const char *buf, size_t len)
5500 {
5501 struct slab_attribute *attribute;
5502 struct kmem_cache *s;
5503 int err;
5505 attribute = to_slab_attr(attr);
5506 s = to_slab(kobj);
5508 if (!attribute->store)
5509 return -EIO;
5511 err = attribute->store(s, buf, len);
5512 #ifdef CONFIG_MEMCG
5513 if (slab_state >= FULL && err >= 0 && is_root_cache(s)) {
5514 struct kmem_cache *c;
5516 mutex_lock(&slab_mutex);
5517 if (s->max_attr_size < len)
5518 s->max_attr_size = len;
5520 /*
5521 * This is a best effort propagation, so this function's return
5522 * value will be determined by the parent cache only. This is
5523 * basically because not all attributes will have a well
5524 * defined semantics for rollbacks - most of the actions will
5525 * have permanent effects.
5526 *
5527 * Returning the error value of any of the children that fail
5528 * is not 100 % defined, in the sense that users seeing the
5529 * error code won't be able to know anything about the state of
5530 * the cache.
5531 *
5532 * Only returning the error code for the parent cache at least
5533 * has well defined semantics. The cache being written to
5534 * directly either failed or succeeded, in which case we loop
5535 * through the descendants with best-effort propagation.
5536 */
5537 for_each_memcg_cache(c, s)
5538 attribute->store(c, buf, len);
5539 mutex_unlock(&slab_mutex);
5540 }
5541 #endif
5542 return err;
5543 }
5545 static void memcg_propagate_slab_attrs(struct kmem_cache *s)
5546 {
5547 #ifdef CONFIG_MEMCG
5548 int i;
5549 char *buffer = NULL;
5550 struct kmem_cache *root_cache;
5552 if (is_root_cache(s))
5553 return;
5555 root_cache = s->memcg_params.root_cache;
5557 /*
5558 * This mean this cache had no attribute written. Therefore, no point
5559 * in copying default values around
5560 */
5561 if (!root_cache->max_attr_size)
5562 return;
5564 for (i = 0; i < ARRAY_SIZE(slab_attrs); i++) {
5565 char mbuf[64];
5566 char *buf;
5567 struct slab_attribute *attr = to_slab_attr(slab_attrs[i]);
5568 ssize_t len;
5570 if (!attr || !attr->store || !attr->show)
5571 continue;
5573 /*
5574 * It is really bad that we have to allocate here, so we will
5575 * do it only as a fallback. If we actually allocate, though,
5576 * we can just use the allocated buffer until the end.
5577 *
5578 * Most of the slub attributes will tend to be very small in
5579 * size, but sysfs allows buffers up to a page, so they can
5580 * theoretically happen.
5581 */
5582 if (buffer)
5583 buf = buffer;
5584 else if (root_cache->max_attr_size < ARRAY_SIZE(mbuf))
5585 buf = mbuf;
5586 else {
5587 buffer = (char *) get_zeroed_page(GFP_KERNEL);
5588 if (WARN_ON(!buffer))
5589 continue;
5590 buf = buffer;
5591 }
5593 len = attr->show(root_cache, buf);
5594 if (len > 0)
5595 attr->store(s, buf, len);
5596 }
5598 if (buffer)
5599 free_page((unsigned long)buffer);
5600 #endif
5601 }
5603 static void kmem_cache_release(struct kobject *k)
5604 {
5605 slab_kmem_cache_release(to_slab(k));
5606 }
5608 static const struct sysfs_ops slab_sysfs_ops = {
5609 .show = slab_attr_show,
5610 .store = slab_attr_store,
5611 };
5613 static struct kobj_type slab_ktype = {
5614 .sysfs_ops = &slab_sysfs_ops,
5615 .release = kmem_cache_release,
5616 };
5618 static int uevent_filter(struct kset *kset, struct kobject *kobj)
5619 {
5620 struct kobj_type *ktype = get_ktype(kobj);
5622 if (ktype == &slab_ktype)
5623 return 1;
5624 return 0;
5625 }
5627 static const struct kset_uevent_ops slab_uevent_ops = {
5628 .filter = uevent_filter,
5629 };
5631 static struct kset *slab_kset;
5633 static inline struct kset *cache_kset(struct kmem_cache *s)
5634 {
5635 #ifdef CONFIG_MEMCG
5636 if (!is_root_cache(s))
5637 return s->memcg_params.root_cache->memcg_kset;
5638 #endif
5639 return slab_kset;
5640 }
5642 #define ID_STR_LENGTH 64
5644 /* Create a unique string id for a slab cache:
5645 *
5646 * Format :[flags-]size
5647 */
5648 static char *create_unique_id(struct kmem_cache *s)
5649 {
5650 char *name = kmalloc(ID_STR_LENGTH, GFP_KERNEL);
5651 char *p = name;
5653 BUG_ON(!name);
5655 *p++ = ':';
5656 /*
5657 * First flags affecting slabcache operations. We will only
5658 * get here for aliasable slabs so we do not need to support
5659 * too many flags. The flags here must cover all flags that
5660 * are matched during merging to guarantee that the id is
5661 * unique.
5662 */
5663 if (s->flags & SLAB_CACHE_DMA)
5664 *p++ = 'd';
5665 if (s->flags & SLAB_RECLAIM_ACCOUNT)
5666 *p++ = 'a';
5667 if (s->flags & SLAB_CONSISTENCY_CHECKS)
5668 *p++ = 'F';
5669 if (s->flags & SLAB_ACCOUNT)
5670 *p++ = 'A';
5671 if (p != name + 1)
5672 *p++ = '-';
5673 p += sprintf(p, "%07u", s->size);
5675 BUG_ON(p > name + ID_STR_LENGTH - 1);
5676 return name;
5677 }
5679 static void sysfs_slab_remove_workfn(struct work_struct *work)
5680 {
5681 struct kmem_cache *s =
5682 container_of(work, struct kmem_cache, kobj_remove_work);
5684 if (!s->kobj.state_in_sysfs)
5685 /*
5686 * For a memcg cache, this may be called during
5687 * deactivation and again on shutdown. Remove only once.
5688 * A cache is never shut down before deactivation is
5689 * complete, so no need to worry about synchronization.
5690 */
5691 goto out;
5693 #ifdef CONFIG_MEMCG
5694 kset_unregister(s->memcg_kset);
5695 #endif
5696 kobject_uevent(&s->kobj, KOBJ_REMOVE);
5697 out:
5698 kobject_put(&s->kobj);
5699 }
5701 static int sysfs_slab_add(struct kmem_cache *s)
5702 {
5703 int err;
5704 const char *name;
5705 struct kset *kset = cache_kset(s);
5706 int unmergeable = slab_unmergeable(s);
5708 INIT_WORK(&s->kobj_remove_work, sysfs_slab_remove_workfn);
5710 if (!kset) {
5711 kobject_init(&s->kobj, &slab_ktype);
5712 return 0;
5713 }
5715 if (!unmergeable && disable_higher_order_debug &&
5716 (slub_debug & DEBUG_METADATA_FLAGS))
5717 unmergeable = 1;
5719 if (unmergeable) {
5720 /*
5721 * Slabcache can never be merged so we can use the name proper.
5722 * This is typically the case for debug situations. In that
5723 * case we can catch duplicate names easily.
5724 */
5725 sysfs_remove_link(&slab_kset->kobj, s->name);
5726 name = s->name;
5727 } else {
5728 /*
5729 * Create a unique name for the slab as a target
5730 * for the symlinks.
5731 */
5732 name = create_unique_id(s);
5733 }
5735 s->kobj.kset = kset;
5736 err = kobject_init_and_add(&s->kobj, &slab_ktype, NULL, "%s", name);
5737 if (err)
5738 goto out;
5740 err = sysfs_create_group(&s->kobj, &slab_attr_group);
5741 if (err)
5742 goto out_del_kobj;
5744 #ifdef CONFIG_MEMCG
5745 if (is_root_cache(s) && memcg_sysfs_enabled) {
5746 s->memcg_kset = kset_create_and_add("cgroup", NULL, &s->kobj);
5747 if (!s->memcg_kset) {
5748 err = -ENOMEM;
5749 goto out_del_kobj;
5750 }
5751 }
5752 #endif
5754 kobject_uevent(&s->kobj, KOBJ_ADD);
5755 if (!unmergeable) {
5756 /* Setup first alias */
5757 sysfs_slab_alias(s, s->name);
5758 }
5759 out:
5760 if (!unmergeable)
5761 kfree(name);
5762 return err;
5763 out_del_kobj:
5764 kobject_del(&s->kobj);
5765 goto out;
5766 }
5768 static void sysfs_slab_remove(struct kmem_cache *s)
5769 {
5770 if (slab_state < FULL)
5771 /*
5772 * Sysfs has not been setup yet so no need to remove the
5773 * cache from sysfs.
5774 */
5775 return;
5777 kobject_get(&s->kobj);
5778 schedule_work(&s->kobj_remove_work);
5779 }
5781 void sysfs_slab_unlink(struct kmem_cache *s)
5782 {
5783 if (slab_state >= FULL)
5784 kobject_del(&s->kobj);
5785 }
5787 void sysfs_slab_release(struct kmem_cache *s)
5788 {
5789 if (slab_state >= FULL)
5790 kobject_put(&s->kobj);
5791 }
5793 /*
5794 * Need to buffer aliases during bootup until sysfs becomes
5795 * available lest we lose that information.
5796 */
5797 struct saved_alias {
5798 struct kmem_cache *s;
5799 const char *name;
5800 struct saved_alias *next;
5801 };
5803 static struct saved_alias *alias_list;
5805 static int sysfs_slab_alias(struct kmem_cache *s, const char *name)
5806 {
5807 struct saved_alias *al;
5809 if (slab_state == FULL) {
5810 /*
5811 * If we have a leftover link then remove it.
5812 */
5813 sysfs_remove_link(&slab_kset->kobj, name);
5814 return sysfs_create_link(&slab_kset->kobj, &s->kobj, name);
5815 }
5817 al = kmalloc(sizeof(struct saved_alias), GFP_KERNEL);
5818 if (!al)
5819 return -ENOMEM;
5821 al->s = s;
5822 al->name = name;
5823 al->next = alias_list;
5824 alias_list = al;
5825 return 0;
5826 }
5828 static int __init slab_sysfs_init(void)
5829 {
5830 struct kmem_cache *s;
5831 int err;
5833 mutex_lock(&slab_mutex);
5835 slab_kset = kset_create_and_add("slab", &slab_uevent_ops, kernel_kobj);
5836 if (!slab_kset) {
5837 mutex_unlock(&slab_mutex);
5838 pr_err("Cannot register slab subsystem.\n");
5839 return -ENOSYS;
5840 }
5842 slab_state = FULL;
5844 list_for_each_entry(s, &slab_caches, list) {
5845 err = sysfs_slab_add(s);
5846 if (err)
5847 pr_err("SLUB: Unable to add boot slab %s to sysfs\n",
5848 s->name);
5849 }
5851 while (alias_list) {
5852 struct saved_alias *al = alias_list;
5854 alias_list = alias_list->next;
5855 err = sysfs_slab_alias(al->s, al->name);
5856 if (err)
5857 pr_err("SLUB: Unable to add boot slab alias %s to sysfs\n",
5858 al->name);
5859 kfree(al);
5860 }
5862 mutex_unlock(&slab_mutex);
5863 resiliency_test();
5864 return 0;
5865 }
5867 __initcall(slab_sysfs_init);
5868 #endif /* CONFIG_SYSFS */
5870 /*
5871 * The /proc/slabinfo ABI
5872 */
5873 #ifdef CONFIG_SLUB_DEBUG
5874 void get_slabinfo(struct kmem_cache *s, struct slabinfo *sinfo)
5875 {
5876 unsigned long nr_slabs = 0;
5877 unsigned long nr_objs = 0;
5878 unsigned long nr_free = 0;
5879 int node;
5880 struct kmem_cache_node *n;
5882 for_each_kmem_cache_node(s, node, n) {
5883 nr_slabs += node_nr_slabs(n);
5884 nr_objs += node_nr_objs(n);
5885 nr_free += count_partial(n, count_free);
5886 }
5888 sinfo->active_objs = nr_objs - nr_free;
5889 sinfo->num_objs = nr_objs;
5890 sinfo->active_slabs = nr_slabs;
5891 sinfo->num_slabs = nr_slabs;
5892 sinfo->objects_per_slab = oo_objects(s->oo);
5893 sinfo->cache_order = oo_order(s->oo);
5894 }
5896 void slabinfo_show_stats(struct seq_file *m, struct kmem_cache *s)
5897 {
5898 }
5900 ssize_t slabinfo_write(struct file *file, const char __user *buffer,
5901 size_t count, loff_t *ppos)
5902 {
5903 return -EIO;
5904 }
5905 #endif /* CONFIG_SLUB_DEBUG */