| blob | 36b4591a7a2d3b2eca7111b26bee3efa19c7c5c5 |
1 /*
2 * zsmalloc memory allocator
3 *
4 * Copyright (C) 2011 Nitin Gupta
5 * Copyright (C) 2012, 2013 Minchan Kim
6 *
7 * This code is released using a dual license strategy: BSD/GPL
8 * You can choose the license that better fits your requirements.
9 *
10 * Released under the terms of 3-clause BSD License
11 * Released under the terms of GNU General Public License Version 2.0
12 */
14 /*
15 * This allocator is designed for use with zram. Thus, the allocator is
16 * supposed to work well under low memory conditions. In particular, it
17 * never attempts higher order page allocation which is very likely to
18 * fail under memory pressure. On the other hand, if we just use single
19 * (0-order) pages, it would suffer from very high fragmentation --
20 * any object of size PAGE_SIZE/2 or larger would occupy an entire page.
21 * This was one of the major issues with its predecessor (xvmalloc).
22 *
23 * To overcome these issues, zsmalloc allocates a bunch of 0-order pages
24 * and links them together using various 'struct page' fields. These linked
25 * pages act as a single higher-order page i.e. an object can span 0-order
26 * page boundaries. The code refers to these linked pages as a single entity
27 * called zspage.
28 *
29 * For simplicity, zsmalloc can only allocate objects of size up to PAGE_SIZE
30 * since this satisfies the requirements of all its current users (in the
31 * worst case, page is incompressible and is thus stored "as-is" i.e. in
32 * uncompressed form). For allocation requests larger than this size, failure
33 * is returned (see zs_malloc).
34 *
35 * Additionally, zs_malloc() does not return a dereferenceable pointer.
36 * Instead, it returns an opaque handle (unsigned long) which encodes actual
37 * location of the allocated object. The reason for this indirection is that
38 * zsmalloc does not keep zspages permanently mapped since that would cause
39 * issues on 32-bit systems where the VA region for kernel space mappings
40 * is very small. So, before using the allocating memory, the object has to
41 * be mapped using zs_map_object() to get a usable pointer and subsequently
42 * unmapped using zs_unmap_object().
43 *
44 * Following is how we use various fields and flags of underlying
45 * struct page(s) to form a zspage.
46 *
47 * Usage of struct page fields:
48 * page->first_page: points to the first component (0-order) page
49 * page->index (union with page->freelist): offset of the first object
50 * starting in this page. For the first page, this is
51 * always 0, so we use this field (aka freelist) to point
52 * to the first free object in zspage.
53 * page->lru: links together all component pages (except the first page)
54 * of a zspage
55 *
56 * For _first_ page only:
57 *
58 * page->private (union with page->first_page): refers to the
59 * component page after the first page
60 * page->freelist: points to the first free object in zspage.
61 * Free objects are linked together using in-place
62 * metadata.
63 * page->objects: maximum number of objects we can store in this
64 * zspage (class->zspage_order * PAGE_SIZE / class->size)
65 * page->lru: links together first pages of various zspages.
66 * Basically forming list of zspages in a fullness group.
67 * page->mapping: class index and fullness group of the zspage
68 *
69 * Usage of struct page flags:
70 * PG_private: identifies the first component page
71 * PG_private2: identifies the last component page
72 *
73 */
75 #ifdef CONFIG_ZSMALLOC_DEBUG
76 #define DEBUG
77 #endif
79 #include <linux/module.h>
80 #include <linux/kernel.h>
81 #include <linux/bitops.h>
82 #include <linux/errno.h>
83 #include <linux/highmem.h>
84 #include <linux/string.h>
85 #include <linux/slab.h>
86 #include <asm/tlbflush.h>
87 #include <asm/pgtable.h>
88 #include <linux/cpumask.h>
89 #include <linux/cpu.h>
90 #include <linux/vmalloc.h>
91 #include <linux/hardirq.h>
92 #include <linux/spinlock.h>
93 #include <linux/types.h>
94 #include <linux/zsmalloc.h>
96 /*
97 * This must be power of 2 and greater than of equal to sizeof(link_free).
98 * These two conditions ensure that any 'struct link_free' itself doesn't
99 * span more than 1 page which avoids complex case of mapping 2 pages simply
100 * to restore link_free pointer values.
101 */
102 #define ZS_ALIGN 8
104 /*
105 * A single 'zspage' is composed of up to 2^N discontiguous 0-order (single)
106 * pages. ZS_MAX_ZSPAGE_ORDER defines upper limit on N.
107 */
108 #define ZS_MAX_ZSPAGE_ORDER 2
109 #define ZS_MAX_PAGES_PER_ZSPAGE (_AC(1, UL) << ZS_MAX_ZSPAGE_ORDER)
111 /*
112 * Object location (<PFN>, <obj_idx>) is encoded as
113 * as single (unsigned long) handle value.
114 *
115 * Note that object index <obj_idx> is relative to system
116 * page <PFN> it is stored in, so for each sub-page belonging
117 * to a zspage, obj_idx starts with 0.
118 *
119 * This is made more complicated by various memory models and PAE.
120 */
122 #ifndef MAX_PHYSMEM_BITS
123 #ifdef CONFIG_HIGHMEM64G
124 #define MAX_PHYSMEM_BITS 36
126 /*
127 * If this definition of MAX_PHYSMEM_BITS is used, OBJ_INDEX_BITS will just
128 * be PAGE_SHIFT
129 */
130 #define MAX_PHYSMEM_BITS BITS_PER_LONG
131 #endif
132 #endif
133 #define _PFN_BITS (MAX_PHYSMEM_BITS - PAGE_SHIFT)
134 #define OBJ_INDEX_BITS (BITS_PER_LONG - _PFN_BITS)
135 #define OBJ_INDEX_MASK ((_AC(1, UL) << OBJ_INDEX_BITS) - 1)
137 #define MAX(a, b) ((a) >= (b) ? (a) : (b))
138 /* ZS_MIN_ALLOC_SIZE must be multiple of ZS_ALIGN */
139 #define ZS_MIN_ALLOC_SIZE \
140 MAX(32, (ZS_MAX_PAGES_PER_ZSPAGE << PAGE_SHIFT >> OBJ_INDEX_BITS))
141 #define ZS_MAX_ALLOC_SIZE PAGE_SIZE
143 /*
144 * On systems with 4K page size, this gives 254 size classes! There is a
145 * trader-off here:
146 * - Large number of size classes is potentially wasteful as free page are
147 * spread across these classes
148 * - Small number of size classes causes large internal fragmentation
149 * - Probably its better to use specific size classes (empirically
150 * determined). NOTE: all those class sizes must be set as multiple of
151 * ZS_ALIGN to make sure link_free itself never has to span 2 pages.
152 *
153 * ZS_MIN_ALLOC_SIZE and ZS_SIZE_CLASS_DELTA must be multiple of ZS_ALIGN
154 * (reason above)
155 */
156 #define ZS_SIZE_CLASS_DELTA (PAGE_SIZE >> 8)
157 #define ZS_SIZE_CLASSES ((ZS_MAX_ALLOC_SIZE - ZS_MIN_ALLOC_SIZE) / \
158 ZS_SIZE_CLASS_DELTA + 1)
160 /*
161 * We do not maintain any list for completely empty or full pages
162 */
164 ZS_ALMOST_FULL,
165 ZS_ALMOST_EMPTY,
166 _ZS_NR_FULLNESS_GROUPS,
168 ZS_EMPTY,
169 ZS_FULL
170 };
172 /*
173 * We assign a page to ZS_ALMOST_EMPTY fullness group when:
174 * n <= N / f, where
175 * n = number of allocated objects
176 * N = total number of objects zspage can store
177 * f = 1/fullness_threshold_frac
178 *
179 * Similarly, we assign zspage to:
180 * ZS_ALMOST_FULL when n > N / f
181 * ZS_EMPTY when n == 0
182 * ZS_FULL when n == N
183 *
184 * (see: fix_fullness_group())
185 */
189 /*
190 * Size of objects stored in this class. Must be multiple
191 * of ZS_ALIGN.
192 */
196 /* Number of PAGE_SIZE sized pages to combine to form a 'zspage' */
199 spinlock_t lock;
201 /* stats */
202 u64 pages_allocated;
205 };
207 /*
208 * Placed within free objects to form a singly linked list.
209 * For every zspage, first_page->freelist gives head of this list.
210 *
211 * This must be power of 2 and less than or equal to ZS_ALIGN
212 */
214 /* Handle of next free chunk (encodes <PFN, obj_idx>) */
216 };
222 };
224 /*
225 * A zspage's class index and fullness group
226 * are encoded in its (first)page->mapping
227 */
228 #define CLASS_IDX_BITS 28
229 #define FULLNESS_BITS 4
230 #define CLASS_IDX_MASK ((1 << CLASS_IDX_BITS) - 1)
231 #define FULLNESS_MASK ((1 << FULLNESS_BITS) - 1)
234 #ifdef CONFIG_PGTABLE_MAPPING
236 #else
238 #endif
241 };
244 /* per-cpu VM mapping areas for zspage accesses that cross page boundaries */
248 {
250 }
253 {
255 }
259 {
266 }
270 {
277 }
279 /*
280 * zsmalloc divides the pool into various size classes where each
281 * class maintains a list of zspages where each zspage is divided
282 * into equal sized chunks. Each allocation falls into one of these
283 * classes depending on its size. This function returns index of the
284 * size class which has chunk size big enough to hold the give size.
285 */
287 {
292 ZS_SIZE_CLASS_DELTA);
295 }
297 /*
298 * For each size class, zspages are divided into different groups
299 * depending on how "full" they are. This was done so that we could
300 * easily find empty or nearly empty zspages when we try to shrink
301 * the pool (not yet implemented). This function returns fullness
302 * status of the given page.
303 */
305 {
319 else
323 }
325 /*
326 * Each size class maintains various freelists and zspages are assigned
327 * to one of these freelists based on the number of live objects they
328 * have. This functions inserts the given zspage into the freelist
329 * identified by <class, fullness_group>.
330 */
333 {
346 }
348 /*
349 * This function removes the given zspage from the freelist identified
350 * by <class, fullness_group>.
351 */
354 {
371 }
373 /*
374 * Each size class maintains zspages in different fullness groups depending
375 * on the number of live objects they contain. When allocating or freeing
376 * objects, the fullness status of the page can change, say, from ALMOST_FULL
377 * to ALMOST_EMPTY when freeing an object. This function checks if such
378 * a status change has occurred for the given page and accordingly moves the
379 * page from the freelist of the old fullness group to that of the new
380 * fullness group.
381 */
384 {
401 out:
403 }
405 /*
406 * We have to decide on how many pages to link together
407 * to form a zspage for each size class. This is important
408 * to reduce wastage due to unusable space left at end of
409 * each zspage which is given as:
410 * wastage = Zp - Zp % size_class
411 * where Zp = zspage size = k * PAGE_SIZE where k = 1, 2, ...
412 *
413 * For example, for size class of 3/8 * PAGE_SIZE, we should
414 * link together 3 PAGE_SIZE sized pages to form a zspage
415 * since then we can perfectly fit in 8 such objects.
416 */
418 {
420 /* zspage order which gives maximum used size per KB */
434 }
435 }
438 }
440 /*
441 * A single 'zspage' is composed of many system pages which are
442 * linked together using fields in struct page. This function finds
443 * the first/head page, given any component page of a zspage.
444 */
446 {
449 else
451 }
454 {
461 else
465 }
467 /*
468 * Encode <page, obj_idx> as a single handle value.
469 * On hardware platforms with physical memory starting at 0x0 the pfn
470 * could be 0 so we ensure that the handle will never be 0 by adjusting the
471 * encoded obj_idx value before encoding.
472 */
474 {
480 }
486 }
488 /*
489 * Decode <page, obj_idx> pair from the given object handle. We adjust the
490 * decoded obj_idx back to its original value since it was adjusted in
491 * obj_location_to_handle().
492 */
495 {
498 }
502 {
509 }
512 {
519 }
522 {
533 /* zspage with only 1 system page */
541 }
544 }
546 /* Initialize a newly allocated zspage */
548 {
558 /*
559 * page->index stores offset of first object starting
560 * in the page. For the first page, this is always 0,
561 * so we use first_page->index (aka ->freelist) to store
562 * head of corresponding zspage's freelist.
563 */
576 }
577 }
579 /*
580 * We now come to the last (full or partial) object on this
581 * page, which must point to the first object on the next
582 * page (if present)
583 */
589 }
590 }
592 /*
593 * Allocate a zspage for the given size class
594 */
596 {
600 /*
601 * Allocate individual pages and link them together as:
602 * 1. first page->private = first sub-page
603 * 2. all sub-pages are linked together using page->lru
604 * 3. each sub-page is linked to the first page using page->first_page
605 *
606 * For each size class, First/Head pages are linked together using
607 * page->lru. Also, we set PG_private to identify the first page
608 * (i.e. no other sub-page has this flag set) and PG_private_2 to
609 * identify the last page.
610 */
625 }
635 }
640 /* Maximum number of objects we can store in this zspage */
645 cleanup:
649 }
652 }
655 {
663 }
666 }
668 #ifdef CONFIG_PGTABLE_MAPPING
670 {
671 /*
672 * Make sure we don't leak memory if a cpu UP notification
673 * and zs_init() race and both call zs_cpu_up() on the same cpu
674 */
681 }
684 {
688 }
692 {
696 }
700 {
704 }
709 {
710 /*
711 * Make sure we don't leak memory if a cpu UP notification
712 * and zs_init() race and both call zs_cpu_up() on the same cpu
713 */
720 }
723 {
727 }
731 {
736 /* disable page faults to match kmap_atomic() return conditions */
739 /* no read fastpath */
746 /* copy object to per-cpu buffer */
753 out:
755 }
759 {
764 /* no write fastpath */
771 /* copy per-cpu buffer to object */
779 out:
780 /* enable page faults to match kunmap_atomic() return conditions */
782 }
788 {
804 }
807 }
811 };
814 {
824 }
827 {
838 }
839 }
844 fail:
847 }
849 /**
850 * zs_create_pool - Creates an allocation pool to work from.
851 * @flags: allocation flags used to allocate pool metadata
852 *
853 * This function must be called before anything when using
854 * the zsmalloc allocator.
855 *
856 * On success, a pointer to the newly created pool is returned,
857 * otherwise NULL.
858 */
860 {
883 }
888 }
892 {
903 }
904 }
905 }
907 }
910 /**
911 * zs_malloc - Allocate block of given size from pool.
912 * @pool: pool to allocate from
913 * @size: size of block to allocate
914 *
915 * On success, handle to the allocated object is returned,
916 * otherwise 0.
917 * Allocation requests with size > ZS_MAX_ALLOC_SIZE will fail.
918 */
920 {
948 }
961 /* Now move the zspage to another fullness group, if required */
966 }
970 {
991 /* Insert this object in containing zspage's freelist */
1008 }
1011 /**
1012 * zs_map_object - get address of allocated object from handle.
1013 * @pool: pool from which the object was allocated
1014 * @handle: handle returned from zs_malloc
1015 *
1016 * Before using an object allocated from zs_malloc, it must be mapped using
1017 * this function. When done with the object, it must be unmapped using
1018 * zs_unmap_object.
1019 *
1020 * Only one object can be mapped per cpu at a time. There is no protection
1021 * against nested mappings.
1022 *
1023 * This function returns with preemption and page faults disabled.
1024 */
1027 {
1039 /*
1040 * Because we use per-cpu mapping areas shared among the
1041 * pools/users, we can't allow mapping in interrupt context
1042 * because it can corrupt another users mappings.
1043 */
1054 /* this object is contained entirely within a page */
1057 }
1059 /* this object spans two pages */
1065 }
1069 {
1096 }
1098 }
1102 {
1110 }