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759 | palkovsky | 1 | /* |
2071 | jermar | 2 | * Copyright (c) 2006 Ondrej Palkovsky |
759 | palkovsky | 3 | * All rights reserved. |
4 | * |
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5 | * Redistribution and use in source and binary forms, with or without |
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6 | * modification, are permitted provided that the following conditions |
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7 | * are met: |
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8 | * |
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9 | * - Redistributions of source code must retain the above copyright |
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10 | * notice, this list of conditions and the following disclaimer. |
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11 | * - Redistributions in binary form must reproduce the above copyright |
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12 | * notice, this list of conditions and the following disclaimer in the |
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13 | * documentation and/or other materials provided with the distribution. |
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14 | * - The name of the author may not be used to endorse or promote products |
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15 | * derived from this software without specific prior written permission. |
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16 | * |
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17 | * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR |
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18 | * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES |
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19 | * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. |
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20 | * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, |
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21 | * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT |
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22 | * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
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23 | * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
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24 | * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
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25 | * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF |
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26 | * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
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27 | */ |
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28 | |||
1757 | jermar | 29 | /** @addtogroup genericmm |
1702 | cejka | 30 | * @{ |
31 | */ |
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32 | |||
1248 | jermar | 33 | /** |
1702 | cejka | 34 | * @file |
1248 | jermar | 35 | * @brief Slab allocator. |
769 | palkovsky | 36 | * |
1248 | jermar | 37 | * The slab allocator is closely modelled after OpenSolaris slab allocator. |
38 | * @see http://www.usenix.org/events/usenix01/full_papers/bonwick/bonwick_html/ |
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39 | * |
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769 | palkovsky | 40 | * with the following exceptions: |
1248 | jermar | 41 | * @li empty slabs are deallocated immediately |
769 | palkovsky | 42 | * (in Linux they are kept in linked list, in Solaris ???) |
1248 | jermar | 43 | * @li empty magazines are deallocated when not needed |
769 | palkovsky | 44 | * (in Solaris they are held in linked list in slab cache) |
45 | * |
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1248 | jermar | 46 | * Following features are not currently supported but would be easy to do: |
47 | * @li cache coloring |
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48 | * @li dynamic magazine growing (different magazine sizes are already |
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1144 | jermar | 49 | * supported, but we would need to adjust allocation strategy) |
769 | palkovsky | 50 | * |
1248 | jermar | 51 | * The slab allocator supports per-CPU caches ('magazines') to facilitate |
769 | palkovsky | 52 | * good SMP scaling. |
53 | * |
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54 | * When a new object is being allocated, it is first checked, if it is |
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1554 | jermar | 55 | * available in a CPU-bound magazine. If it is not found there, it is |
56 | * allocated from a CPU-shared slab - if a partially full one is found, |
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57 | * it is used, otherwise a new one is allocated. |
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769 | palkovsky | 58 | * |
1554 | jermar | 59 | * When an object is being deallocated, it is put to a CPU-bound magazine. |
60 | * If there is no such magazine, a new one is allocated (if this fails, |
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1248 | jermar | 61 | * the object is deallocated into slab). If the magazine is full, it is |
1554 | jermar | 62 | * put into cpu-shared list of magazines and a new one is allocated. |
769 | palkovsky | 63 | * |
1554 | jermar | 64 | * The CPU-bound magazine is actually a pair of magazines in order to avoid |
769 | palkovsky | 65 | * thrashing when somebody is allocating/deallocating 1 item at the magazine |
66 | * size boundary. LIFO order is enforced, which should avoid fragmentation |
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67 | * as much as possible. |
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68 | * |
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1554 | jermar | 69 | * Every cache contains list of full slabs and list of partially full slabs. |
1248 | jermar | 70 | * Empty slabs are immediately freed (thrashing will be avoided because |
769 | palkovsky | 71 | * of magazines). |
72 | * |
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1248 | jermar | 73 | * The slab information structure is kept inside the data area, if possible. |
769 | palkovsky | 74 | * The cache can be marked that it should not use magazines. This is used |
1248 | jermar | 75 | * only for slab related caches to avoid deadlocks and infinite recursion |
76 | * (the slab allocator uses itself for allocating all it's control structures). |
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769 | palkovsky | 77 | * |
1554 | jermar | 78 | * The slab allocator allocates a lot of space and does not free it. When |
79 | * the frame allocator fails to allocate a frame, it calls slab_reclaim(). |
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769 | palkovsky | 80 | * It tries 'light reclaim' first, then brutal reclaim. The light reclaim |
81 | * releases slabs from cpu-shared magazine-list, until at least 1 slab |
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82 | * is deallocated in each cache (this algorithm should probably change). |
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83 | * The brutal reclaim removes all cached objects, even from CPU-bound |
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84 | * magazines. |
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85 | * |
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1757 | jermar | 86 | * @todo |
1248 | jermar | 87 | * For better CPU-scaling the magazine allocation strategy should |
775 | palkovsky | 88 | * be extended. Currently, if the cache does not have magazine, it asks |
89 | * for non-cpu cached magazine cache to provide one. It might be feasible |
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90 | * to add cpu-cached magazine cache (which would allocate it's magazines |
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91 | * from non-cpu-cached mag. cache). This would provide a nice per-cpu |
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92 | * buffer. The other possibility is to use the per-cache |
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93 | * 'empty-magazine-list', which decreases competing for 1 per-system |
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94 | * magazine cache. |
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95 | * |
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1757 | jermar | 96 | * @todo |
97 | * it might be good to add granularity of locks even to slab level, |
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98 | * we could then try_spinlock over all partial slabs and thus improve |
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99 | * scalability even on slab level |
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769 | palkovsky | 100 | */ |
101 | |||
759 | palkovsky | 102 | #include <synch/spinlock.h> |
103 | #include <mm/slab.h> |
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788 | jermar | 104 | #include <adt/list.h> |
759 | palkovsky | 105 | #include <memstr.h> |
106 | #include <align.h> |
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762 | palkovsky | 107 | #include <mm/frame.h> |
759 | palkovsky | 108 | #include <config.h> |
109 | #include <print.h> |
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110 | #include <arch.h> |
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111 | #include <panic.h> |
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762 | palkovsky | 112 | #include <debug.h> |
771 | palkovsky | 113 | #include <bitops.h> |
2124 | decky | 114 | #include <macros.h> |
759 | palkovsky | 115 | |
116 | SPINLOCK_INITIALIZE(slab_cache_lock); |
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769 | palkovsky | 117 | static LIST_INITIALIZE(slab_cache_list); |
759 | palkovsky | 118 | |
769 | palkovsky | 119 | /** Magazine cache */ |
120 | static slab_cache_t mag_cache; |
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121 | /** Cache for cache descriptors */ |
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122 | static slab_cache_t slab_cache_cache; |
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123 | /** Cache for external slab descriptors |
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124 | * This time we want per-cpu cache, so do not make it static |
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1248 | jermar | 125 | * - using slab for internal slab structures will not deadlock, |
769 | palkovsky | 126 | * as all slab structures are 'small' - control structures of |
127 | * their caches do not require further allocation |
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128 | */ |
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129 | static slab_cache_t *slab_extern_cache; |
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771 | palkovsky | 130 | /** Caches for malloc */ |
2124 | decky | 131 | static slab_cache_t *malloc_caches[SLAB_MAX_MALLOC_W - SLAB_MIN_MALLOC_W + 1]; |
771 | palkovsky | 132 | char *malloc_names[] = { |
2124 | decky | 133 | "malloc-16", |
134 | "malloc-32", |
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135 | "malloc-64", |
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136 | "malloc-128", |
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137 | "malloc-256", |
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138 | "malloc-512", |
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139 | "malloc-1K", |
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140 | "malloc-2K", |
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141 | "malloc-4K", |
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142 | "malloc-8K", |
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143 | "malloc-16K", |
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144 | "malloc-32K", |
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145 | "malloc-64K", |
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146 | "malloc-128K", |
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147 | "malloc-256K" |
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771 | palkovsky | 148 | }; |
762 | palkovsky | 149 | |
769 | palkovsky | 150 | /** Slab descriptor */ |
762 | palkovsky | 151 | typedef struct { |
1950 | jermar | 152 | slab_cache_t *cache; /**< Pointer to parent cache. */ |
153 | link_t link; /**< List of full/partial slabs. */ |
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154 | void *start; /**< Start address of first available item. */ |
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155 | count_t available; /**< Count of available items in this slab. */ |
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156 | index_t nextavail; /**< The index of next available item. */ |
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2124 | decky | 157 | } slab_t; |
762 | palkovsky | 158 | |
791 | palkovsky | 159 | #ifdef CONFIG_DEBUG |
160 | static int _slab_initialized = 0; |
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161 | #endif |
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162 | |||
759 | palkovsky | 163 | /**************************************/ |
1248 | jermar | 164 | /* Slab allocation functions */ |
759 | palkovsky | 165 | |
762 | palkovsky | 166 | /** |
167 | * Allocate frames for slab space and initialize |
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168 | * |
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169 | */ |
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3180 | jermar | 170 | static slab_t *slab_space_alloc(slab_cache_t *cache, int flags) |
762 | palkovsky | 171 | { |
172 | void *data; |
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173 | slab_t *slab; |
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174 | size_t fsize; |
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2745 | decky | 175 | unsigned int i; |
3972 | decky | 176 | count_t zone = 0; |
814 | palkovsky | 177 | |
1766 | palkovsky | 178 | data = frame_alloc_generic(cache->order, FRAME_KA | flags, &zone); |
179 | if (!data) { |
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762 | palkovsky | 180 | return NULL; |
764 | palkovsky | 181 | } |
3180 | jermar | 182 | if (!(cache->flags & SLAB_CACHE_SLINSIDE)) { |
769 | palkovsky | 183 | slab = slab_alloc(slab_extern_cache, flags); |
762 | palkovsky | 184 | if (!slab) { |
1760 | palkovsky | 185 | frame_free(KA2PA(data)); |
762 | palkovsky | 186 | return NULL; |
187 | } |
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188 | } else { |
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189 | fsize = (PAGE_SIZE << cache->order); |
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190 | slab = data + fsize - sizeof(*slab); |
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191 | } |
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1288 | jermar | 192 | |
762 | palkovsky | 193 | /* Fill in slab structures */ |
2745 | decky | 194 | for (i = 0; i < ((unsigned int) 1 << cache->order); i++) |
195 | frame_set_parent(ADDR2PFN(KA2PA(data)) + i, slab, zone); |
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762 | palkovsky | 196 | |
197 | slab->start = data; |
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198 | slab->available = cache->objects; |
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199 | slab->nextavail = 0; |
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767 | palkovsky | 200 | slab->cache = cache; |
762 | palkovsky | 201 | |
2745 | decky | 202 | for (i = 0; i < cache->objects; i++) |
3180 | jermar | 203 | *((int *) (slab->start + i*cache->size)) = i + 1; |
764 | palkovsky | 204 | |
205 | atomic_inc(&cache->allocated_slabs); |
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762 | palkovsky | 206 | return slab; |
207 | } |
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208 | |||
759 | palkovsky | 209 | /** |
1248 | jermar | 210 | * Deallocate space associated with slab |
762 | palkovsky | 211 | * |
212 | * @return number of freed frames |
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213 | */ |
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214 | static count_t slab_space_free(slab_cache_t *cache, slab_t *slab) |
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215 | { |
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1760 | palkovsky | 216 | frame_free(KA2PA(slab->start)); |
768 | palkovsky | 217 | if (! (cache->flags & SLAB_CACHE_SLINSIDE)) |
769 | palkovsky | 218 | slab_free(slab_extern_cache, slab); |
764 | palkovsky | 219 | |
220 | atomic_dec(&cache->allocated_slabs); |
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221 | |||
762 | palkovsky | 222 | return 1 << cache->order; |
223 | } |
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224 | |||
225 | /** Map object to slab structure */ |
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226 | static slab_t * obj2slab(void *obj) |
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227 | { |
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2124 | decky | 228 | return (slab_t *) frame_get_parent(ADDR2PFN(KA2PA(obj)), 0); |
762 | palkovsky | 229 | } |
230 | |||
231 | /**************************************/ |
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1248 | jermar | 232 | /* Slab functions */ |
762 | palkovsky | 233 | |
234 | |||
235 | /** |
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759 | palkovsky | 236 | * Return object to slab and call a destructor |
237 | * |
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762 | palkovsky | 238 | * @param slab If the caller knows directly slab of the object, otherwise NULL |
239 | * |
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759 | palkovsky | 240 | * @return Number of freed pages |
241 | */ |
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3180 | jermar | 242 | static count_t slab_obj_destroy(slab_cache_t *cache, void *obj, slab_t *slab) |
759 | palkovsky | 243 | { |
787 | palkovsky | 244 | int freed = 0; |
245 | |||
762 | palkovsky | 246 | if (!slab) |
247 | slab = obj2slab(obj); |
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248 | |||
767 | palkovsky | 249 | ASSERT(slab->cache == cache); |
250 | |||
787 | palkovsky | 251 | if (cache->destructor) |
252 | freed = cache->destructor(obj); |
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253 | |||
776 | palkovsky | 254 | spinlock_lock(&cache->slablock); |
789 | palkovsky | 255 | ASSERT(slab->available < cache->objects); |
776 | palkovsky | 256 | |
762 | palkovsky | 257 | *((int *)obj) = slab->nextavail; |
3180 | jermar | 258 | slab->nextavail = (obj - slab->start) / cache->size; |
762 | palkovsky | 259 | slab->available++; |
260 | |||
261 | /* Move it to correct list */ |
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262 | if (slab->available == cache->objects) { |
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263 | /* Free associated memory */ |
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264 | list_remove(&slab->link); |
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782 | palkovsky | 265 | spinlock_unlock(&cache->slablock); |
266 | |||
787 | palkovsky | 267 | return freed + slab_space_free(cache, slab); |
782 | palkovsky | 268 | |
780 | palkovsky | 269 | } else if (slab->available == 1) { |
270 | /* It was in full, move to partial */ |
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271 | list_remove(&slab->link); |
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272 | list_prepend(&slab->link, &cache->partial_slabs); |
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762 | palkovsky | 273 | } |
783 | palkovsky | 274 | spinlock_unlock(&cache->slablock); |
787 | palkovsky | 275 | return freed; |
759 | palkovsky | 276 | } |
277 | |||
278 | /** |
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279 | * Take new object from slab or create new if needed |
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280 | * |
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281 | * @return Object address or null |
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282 | */ |
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3180 | jermar | 283 | static void *slab_obj_create(slab_cache_t *cache, int flags) |
759 | palkovsky | 284 | { |
762 | palkovsky | 285 | slab_t *slab; |
286 | void *obj; |
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287 | |||
776 | palkovsky | 288 | spinlock_lock(&cache->slablock); |
289 | |||
762 | palkovsky | 290 | if (list_empty(&cache->partial_slabs)) { |
291 | /* Allow recursion and reclaiming |
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1248 | jermar | 292 | * - this should work, as the slab control structures |
1288 | jermar | 293 | * are small and do not need to allocate with anything |
294 | * other than frame_alloc when they are allocating, |
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762 | palkovsky | 295 | * that's why we should get recursion at most 1-level deep |
296 | */ |
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776 | palkovsky | 297 | spinlock_unlock(&cache->slablock); |
762 | palkovsky | 298 | slab = slab_space_alloc(cache, flags); |
780 | palkovsky | 299 | if (!slab) |
300 | return NULL; |
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776 | palkovsky | 301 | spinlock_lock(&cache->slablock); |
762 | palkovsky | 302 | } else { |
3180 | jermar | 303 | slab = list_get_instance(cache->partial_slabs.next, slab_t, |
304 | link); |
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762 | palkovsky | 305 | list_remove(&slab->link); |
306 | } |
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307 | obj = slab->start + slab->nextavail * cache->size; |
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308 | slab->nextavail = *((int *)obj); |
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309 | slab->available--; |
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787 | palkovsky | 310 | |
1950 | jermar | 311 | if (!slab->available) |
764 | palkovsky | 312 | list_prepend(&slab->link, &cache->full_slabs); |
762 | palkovsky | 313 | else |
764 | palkovsky | 314 | list_prepend(&slab->link, &cache->partial_slabs); |
776 | palkovsky | 315 | |
316 | spinlock_unlock(&cache->slablock); |
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787 | palkovsky | 317 | |
318 | if (cache->constructor && cache->constructor(obj, flags)) { |
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319 | /* Bad, bad, construction failed */ |
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320 | slab_obj_destroy(cache, obj, slab); |
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321 | return NULL; |
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322 | } |
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762 | palkovsky | 323 | return obj; |
759 | palkovsky | 324 | } |
325 | |||
326 | /**************************************/ |
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327 | /* CPU-Cache slab functions */ |
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328 | |||
329 | /** |
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781 | palkovsky | 330 | * Finds a full magazine in cache, takes it from list |
331 | * and returns it |
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332 | * |
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333 | * @param first If true, return first, else last mag |
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334 | */ |
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3180 | jermar | 335 | static slab_magazine_t *get_mag_from_cache(slab_cache_t *cache, int first) |
781 | palkovsky | 336 | { |
337 | slab_magazine_t *mag = NULL; |
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338 | link_t *cur; |
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339 | |||
340 | spinlock_lock(&cache->maglock); |
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341 | if (!list_empty(&cache->magazines)) { |
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342 | if (first) |
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343 | cur = cache->magazines.next; |
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344 | else |
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345 | cur = cache->magazines.prev; |
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346 | mag = list_get_instance(cur, slab_magazine_t, link); |
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347 | list_remove(&mag->link); |
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348 | atomic_dec(&cache->magazine_counter); |
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349 | } |
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350 | spinlock_unlock(&cache->maglock); |
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351 | return mag; |
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352 | } |
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353 | |||
354 | /** Prepend magazine to magazine list in cache */ |
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355 | static void put_mag_to_cache(slab_cache_t *cache, slab_magazine_t *mag) |
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356 | { |
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357 | spinlock_lock(&cache->maglock); |
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358 | |||
359 | list_prepend(&mag->link, &cache->magazines); |
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360 | atomic_inc(&cache->magazine_counter); |
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361 | |||
362 | spinlock_unlock(&cache->maglock); |
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363 | } |
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364 | |||
365 | /** |
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759 | palkovsky | 366 | * Free all objects in magazine and free memory associated with magazine |
367 | * |
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368 | * @return Number of freed pages |
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369 | */ |
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3180 | jermar | 370 | static count_t magazine_destroy(slab_cache_t *cache, slab_magazine_t *mag) |
759 | palkovsky | 371 | { |
2745 | decky | 372 | unsigned int i; |
759 | palkovsky | 373 | count_t frames = 0; |
374 | |||
2745 | decky | 375 | for (i = 0; i < mag->busy; i++) { |
762 | palkovsky | 376 | frames += slab_obj_destroy(cache, mag->objs[i], NULL); |
767 | palkovsky | 377 | atomic_dec(&cache->cached_objs); |
378 | } |
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759 | palkovsky | 379 | |
380 | slab_free(&mag_cache, mag); |
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381 | |||
382 | return frames; |
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383 | } |
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384 | |||
385 | /** |
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769 | palkovsky | 386 | * Find full magazine, set it as current and return it |
387 | * |
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388 | * Assume cpu_magazine lock is held |
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389 | */ |
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3180 | jermar | 390 | static slab_magazine_t *get_full_current_mag(slab_cache_t *cache) |
769 | palkovsky | 391 | { |
392 | slab_magazine_t *cmag, *lastmag, *newmag; |
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393 | |||
394 | cmag = cache->mag_cache[CPU->id].current; |
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395 | lastmag = cache->mag_cache[CPU->id].last; |
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396 | if (cmag) { /* First try local CPU magazines */ |
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397 | if (cmag->busy) |
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398 | return cmag; |
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399 | |||
400 | if (lastmag && lastmag->busy) { |
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401 | cache->mag_cache[CPU->id].current = lastmag; |
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402 | cache->mag_cache[CPU->id].last = cmag; |
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403 | return lastmag; |
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404 | } |
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405 | } |
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406 | /* Local magazines are empty, import one from magazine list */ |
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781 | palkovsky | 407 | newmag = get_mag_from_cache(cache, 1); |
408 | if (!newmag) |
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769 | palkovsky | 409 | return NULL; |
410 | |||
411 | if (lastmag) |
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781 | palkovsky | 412 | magazine_destroy(cache, lastmag); |
413 | |||
769 | palkovsky | 414 | cache->mag_cache[CPU->id].last = cmag; |
415 | cache->mag_cache[CPU->id].current = newmag; |
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416 | return newmag; |
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417 | } |
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418 | |||
419 | /** |
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759 | palkovsky | 420 | * Try to find object in CPU-cache magazines |
421 | * |
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422 | * @return Pointer to object or NULL if not available |
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423 | */ |
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3180 | jermar | 424 | static void *magazine_obj_get(slab_cache_t *cache) |
759 | palkovsky | 425 | { |
426 | slab_magazine_t *mag; |
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767 | palkovsky | 427 | void *obj; |
759 | palkovsky | 428 | |
772 | palkovsky | 429 | if (!CPU) |
430 | return NULL; |
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431 | |||
759 | palkovsky | 432 | spinlock_lock(&cache->mag_cache[CPU->id].lock); |
433 | |||
769 | palkovsky | 434 | mag = get_full_current_mag(cache); |
435 | if (!mag) { |
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436 | spinlock_unlock(&cache->mag_cache[CPU->id].lock); |
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437 | return NULL; |
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759 | palkovsky | 438 | } |
767 | palkovsky | 439 | obj = mag->objs[--mag->busy]; |
759 | palkovsky | 440 | spinlock_unlock(&cache->mag_cache[CPU->id].lock); |
767 | palkovsky | 441 | atomic_dec(&cache->cached_objs); |
442 | |||
443 | return obj; |
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759 | palkovsky | 444 | } |
445 | |||
446 | /** |
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768 | palkovsky | 447 | * Assure that the current magazine is empty, return pointer to it, or NULL if |
769 | palkovsky | 448 | * no empty magazine is available and cannot be allocated |
759 | palkovsky | 449 | * |
773 | palkovsky | 450 | * Assume mag_cache[CPU->id].lock is held |
451 | * |
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759 | palkovsky | 452 | * We have 2 magazines bound to processor. |
453 | * First try the current. |
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454 | * If full, try the last. |
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455 | * If full, put to magazines list. |
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456 | * allocate new, exchange last & current |
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457 | * |
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768 | palkovsky | 458 | */ |
3180 | jermar | 459 | static slab_magazine_t *make_empty_current_mag(slab_cache_t *cache) |
768 | palkovsky | 460 | { |
461 | slab_magazine_t *cmag,*lastmag,*newmag; |
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462 | |||
463 | cmag = cache->mag_cache[CPU->id].current; |
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464 | lastmag = cache->mag_cache[CPU->id].last; |
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465 | |||
466 | if (cmag) { |
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467 | if (cmag->busy < cmag->size) |
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468 | return cmag; |
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469 | if (lastmag && lastmag->busy < lastmag->size) { |
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470 | cache->mag_cache[CPU->id].last = cmag; |
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471 | cache->mag_cache[CPU->id].current = lastmag; |
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472 | return lastmag; |
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473 | } |
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474 | } |
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475 | /* current | last are full | nonexistent, allocate new */ |
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476 | /* We do not want to sleep just because of caching */ |
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477 | /* Especially we do not want reclaiming to start, as |
||
478 | * this would deadlock */ |
||
479 | newmag = slab_alloc(&mag_cache, FRAME_ATOMIC | FRAME_NO_RECLAIM); |
||
480 | if (!newmag) |
||
481 | return NULL; |
||
482 | newmag->size = SLAB_MAG_SIZE; |
||
483 | newmag->busy = 0; |
||
484 | |||
485 | /* Flush last to magazine list */ |
||
781 | palkovsky | 486 | if (lastmag) |
487 | put_mag_to_cache(cache, lastmag); |
||
488 | |||
768 | palkovsky | 489 | /* Move current as last, save new as current */ |
490 | cache->mag_cache[CPU->id].last = cmag; |
||
491 | cache->mag_cache[CPU->id].current = newmag; |
||
492 | |||
493 | return newmag; |
||
494 | } |
||
495 | |||
496 | /** |
||
497 | * Put object into CPU-cache magazine |
||
498 | * |
||
759 | palkovsky | 499 | * @return 0 - success, -1 - could not get memory |
500 | */ |
||
501 | static int magazine_obj_put(slab_cache_t *cache, void *obj) |
||
502 | { |
||
503 | slab_magazine_t *mag; |
||
504 | |||
772 | palkovsky | 505 | if (!CPU) |
506 | return -1; |
||
507 | |||
759 | palkovsky | 508 | spinlock_lock(&cache->mag_cache[CPU->id].lock); |
768 | palkovsky | 509 | |
510 | mag = make_empty_current_mag(cache); |
||
769 | palkovsky | 511 | if (!mag) { |
512 | spinlock_unlock(&cache->mag_cache[CPU->id].lock); |
||
513 | return -1; |
||
514 | } |
||
759 | palkovsky | 515 | |
516 | mag->objs[mag->busy++] = obj; |
||
517 | |||
518 | spinlock_unlock(&cache->mag_cache[CPU->id].lock); |
||
767 | palkovsky | 519 | atomic_inc(&cache->cached_objs); |
759 | palkovsky | 520 | return 0; |
521 | } |
||
522 | |||
523 | |||
524 | /**************************************/ |
||
1248 | jermar | 525 | /* Slab cache functions */ |
759 | palkovsky | 526 | |
762 | palkovsky | 527 | /** Return number of objects that fit in certain cache size */ |
2745 | decky | 528 | static unsigned int comp_objects(slab_cache_t *cache) |
762 | palkovsky | 529 | { |
530 | if (cache->flags & SLAB_CACHE_SLINSIDE) |
||
3180 | jermar | 531 | return ((PAGE_SIZE << cache->order) - sizeof(slab_t)) / |
532 | cache->size; |
||
762 | palkovsky | 533 | else |
534 | return (PAGE_SIZE << cache->order) / cache->size; |
||
535 | } |
||
536 | |||
537 | /** Return wasted space in slab */ |
||
2745 | decky | 538 | static unsigned int badness(slab_cache_t *cache) |
762 | palkovsky | 539 | { |
2745 | decky | 540 | unsigned int objects; |
541 | unsigned int ssize; |
||
762 | palkovsky | 542 | |
543 | objects = comp_objects(cache); |
||
544 | ssize = PAGE_SIZE << cache->order; |
||
545 | if (cache->flags & SLAB_CACHE_SLINSIDE) |
||
546 | ssize -= sizeof(slab_t); |
||
2745 | decky | 547 | return ssize - objects * cache->size; |
762 | palkovsky | 548 | } |
549 | |||
789 | palkovsky | 550 | /** |
551 | * Initialize mag_cache structure in slab cache |
||
552 | */ |
||
553 | static void make_magcache(slab_cache_t *cache) |
||
554 | { |
||
2745 | decky | 555 | unsigned int i; |
791 | palkovsky | 556 | |
557 | ASSERT(_slab_initialized >= 2); |
||
789 | palkovsky | 558 | |
3180 | jermar | 559 | cache->mag_cache = malloc(sizeof(slab_mag_cache_t) * config.cpu_count, |
560 | 0); |
||
2745 | decky | 561 | for (i = 0; i < config.cpu_count; i++) { |
3104 | svoboda | 562 | memsetb(&cache->mag_cache[i], sizeof(cache->mag_cache[i]), 0); |
3180 | jermar | 563 | spinlock_initialize(&cache->mag_cache[i].lock, |
564 | "slab_maglock_cpu"); |
||
789 | palkovsky | 565 | } |
566 | } |
||
567 | |||
759 | palkovsky | 568 | /** Initialize allocated memory as a slab cache */ |
569 | static void |
||
3180 | jermar | 570 | _slab_cache_create(slab_cache_t *cache, char *name, size_t size, size_t align, |
571 | int (*constructor)(void *obj, int kmflag), int (*destructor)(void *obj), |
||
572 | int flags) |
||
759 | palkovsky | 573 | { |
771 | palkovsky | 574 | int pages; |
783 | palkovsky | 575 | ipl_t ipl; |
759 | palkovsky | 576 | |
3104 | svoboda | 577 | memsetb(cache, sizeof(*cache), 0); |
759 | palkovsky | 578 | cache->name = name; |
579 | |||
1780 | jermar | 580 | if (align < sizeof(unative_t)) |
581 | align = sizeof(unative_t); |
||
766 | palkovsky | 582 | size = ALIGN_UP(size, align); |
583 | |||
762 | palkovsky | 584 | cache->size = size; |
759 | palkovsky | 585 | |
586 | cache->constructor = constructor; |
||
587 | cache->destructor = destructor; |
||
588 | cache->flags = flags; |
||
589 | |||
590 | list_initialize(&cache->full_slabs); |
||
591 | list_initialize(&cache->partial_slabs); |
||
592 | list_initialize(&cache->magazines); |
||
776 | palkovsky | 593 | spinlock_initialize(&cache->slablock, "slab_lock"); |
594 | spinlock_initialize(&cache->maglock, "slab_maglock"); |
||
3180 | jermar | 595 | if (!(cache->flags & SLAB_CACHE_NOMAGAZINE)) |
789 | palkovsky | 596 | make_magcache(cache); |
759 | palkovsky | 597 | |
598 | /* Compute slab sizes, object counts in slabs etc. */ |
||
599 | if (cache->size < SLAB_INSIDE_SIZE) |
||
600 | cache->flags |= SLAB_CACHE_SLINSIDE; |
||
601 | |||
762 | palkovsky | 602 | /* Minimum slab order */ |
1682 | palkovsky | 603 | pages = SIZE2FRAMES(cache->size); |
1677 | palkovsky | 604 | /* We need the 2^order >= pages */ |
605 | if (pages == 1) |
||
606 | cache->order = 0; |
||
607 | else |
||
3180 | jermar | 608 | cache->order = fnzb(pages - 1) + 1; |
766 | palkovsky | 609 | |
762 | palkovsky | 610 | while (badness(cache) > SLAB_MAX_BADNESS(cache)) { |
611 | cache->order += 1; |
||
612 | } |
||
613 | cache->objects = comp_objects(cache); |
||
766 | palkovsky | 614 | /* If info fits in, put it inside */ |
615 | if (badness(cache) > sizeof(slab_t)) |
||
616 | cache->flags |= SLAB_CACHE_SLINSIDE; |
||
762 | palkovsky | 617 | |
783 | palkovsky | 618 | /* Add cache to cache list */ |
619 | ipl = interrupts_disable(); |
||
759 | palkovsky | 620 | spinlock_lock(&slab_cache_lock); |
621 | |||
622 | list_append(&cache->link, &slab_cache_list); |
||
623 | |||
624 | spinlock_unlock(&slab_cache_lock); |
||
783 | palkovsky | 625 | interrupts_restore(ipl); |
759 | palkovsky | 626 | } |
627 | |||
628 | /** Create slab cache */ |
||
3180 | jermar | 629 | slab_cache_t * |
630 | slab_cache_create(char *name, size_t size, size_t align, |
||
631 | int (*constructor)(void *obj, int kmflag), int (*destructor)(void *obj), |
||
632 | int flags) |
||
759 | palkovsky | 633 | { |
634 | slab_cache_t *cache; |
||
635 | |||
769 | palkovsky | 636 | cache = slab_alloc(&slab_cache_cache, 0); |
759 | palkovsky | 637 | _slab_cache_create(cache, name, size, align, constructor, destructor, |
3180 | jermar | 638 | flags); |
759 | palkovsky | 639 | return cache; |
640 | } |
||
641 | |||
642 | /** |
||
643 | * Reclaim space occupied by objects that are already free |
||
644 | * |
||
645 | * @param flags If contains SLAB_RECLAIM_ALL, do aggressive freeing |
||
646 | * @return Number of freed pages |
||
647 | */ |
||
648 | static count_t _slab_reclaim(slab_cache_t *cache, int flags) |
||
649 | { |
||
2745 | decky | 650 | unsigned int i; |
759 | palkovsky | 651 | slab_magazine_t *mag; |
652 | count_t frames = 0; |
||
781 | palkovsky | 653 | int magcount; |
759 | palkovsky | 654 | |
655 | if (cache->flags & SLAB_CACHE_NOMAGAZINE) |
||
656 | return 0; /* Nothing to do */ |
||
781 | palkovsky | 657 | |
658 | /* We count up to original magazine count to avoid |
||
659 | * endless loop |
||
660 | */ |
||
661 | magcount = atomic_get(&cache->magazine_counter); |
||
3180 | jermar | 662 | while (magcount-- && (mag=get_mag_from_cache(cache, 0))) { |
781 | palkovsky | 663 | frames += magazine_destroy(cache,mag); |
664 | if (!(flags & SLAB_RECLAIM_ALL) && frames) |
||
665 | break; |
||
769 | palkovsky | 666 | } |
759 | palkovsky | 667 | |
668 | if (flags & SLAB_RECLAIM_ALL) { |
||
781 | palkovsky | 669 | /* Free cpu-bound magazines */ |
759 | palkovsky | 670 | /* Destroy CPU magazines */ |
2745 | decky | 671 | for (i = 0; i < config.cpu_count; i++) { |
781 | palkovsky | 672 | spinlock_lock(&cache->mag_cache[i].lock); |
673 | |||
759 | palkovsky | 674 | mag = cache->mag_cache[i].current; |
675 | if (mag) |
||
676 | frames += magazine_destroy(cache, mag); |
||
677 | cache->mag_cache[i].current = NULL; |
||
678 | |||
679 | mag = cache->mag_cache[i].last; |
||
680 | if (mag) |
||
681 | frames += magazine_destroy(cache, mag); |
||
682 | cache->mag_cache[i].last = NULL; |
||
781 | palkovsky | 683 | |
684 | spinlock_unlock(&cache->mag_cache[i].lock); |
||
759 | palkovsky | 685 | } |
686 | } |
||
767 | palkovsky | 687 | |
759 | palkovsky | 688 | return frames; |
689 | } |
||
690 | |||
691 | /** Check that there are no slabs and remove cache from system */ |
||
692 | void slab_cache_destroy(slab_cache_t *cache) |
||
693 | { |
||
781 | palkovsky | 694 | ipl_t ipl; |
695 | |||
696 | /* First remove cache from link, so that we don't need |
||
697 | * to disable interrupts later |
||
698 | */ |
||
699 | |||
700 | ipl = interrupts_disable(); |
||
701 | spinlock_lock(&slab_cache_lock); |
||
702 | |||
703 | list_remove(&cache->link); |
||
704 | |||
705 | spinlock_unlock(&slab_cache_lock); |
||
706 | interrupts_restore(ipl); |
||
707 | |||
759 | palkovsky | 708 | /* Do not lock anything, we assume the software is correct and |
709 | * does not touch the cache when it decides to destroy it */ |
||
710 | |||
711 | /* Destroy all magazines */ |
||
712 | _slab_reclaim(cache, SLAB_RECLAIM_ALL); |
||
713 | |||
714 | /* All slabs must be empty */ |
||
3180 | jermar | 715 | if (!list_empty(&cache->full_slabs) || |
716 | !list_empty(&cache->partial_slabs)) |
||
759 | palkovsky | 717 | panic("Destroying cache that is not empty."); |
718 | |||
789 | palkovsky | 719 | if (!(cache->flags & SLAB_CACHE_NOMAGAZINE)) |
822 | palkovsky | 720 | free(cache->mag_cache); |
769 | palkovsky | 721 | slab_free(&slab_cache_cache, cache); |
759 | palkovsky | 722 | } |
723 | |||
3180 | jermar | 724 | /** Allocate new object from cache - if no flags given, always returns memory */ |
725 | void *slab_alloc(slab_cache_t *cache, int flags) |
||
759 | palkovsky | 726 | { |
727 | ipl_t ipl; |
||
728 | void *result = NULL; |
||
773 | palkovsky | 729 | |
759 | palkovsky | 730 | /* Disable interrupts to avoid deadlocks with interrupt handlers */ |
731 | ipl = interrupts_disable(); |
||
771 | palkovsky | 732 | |
814 | palkovsky | 733 | if (!(cache->flags & SLAB_CACHE_NOMAGAZINE)) { |
759 | palkovsky | 734 | result = magazine_obj_get(cache); |
814 | palkovsky | 735 | } |
776 | palkovsky | 736 | if (!result) |
759 | palkovsky | 737 | result = slab_obj_create(cache, flags); |
738 | |||
769 | palkovsky | 739 | interrupts_restore(ipl); |
740 | |||
764 | palkovsky | 741 | if (result) |
742 | atomic_inc(&cache->allocated_objs); |
||
743 | |||
759 | palkovsky | 744 | return result; |
745 | } |
||
746 | |||
771 | palkovsky | 747 | /** Return object to cache, use slab if known */ |
748 | static void _slab_free(slab_cache_t *cache, void *obj, slab_t *slab) |
||
759 | palkovsky | 749 | { |
750 | ipl_t ipl; |
||
751 | |||
752 | ipl = interrupts_disable(); |
||
753 | |||
3180 | jermar | 754 | if ((cache->flags & SLAB_CACHE_NOMAGAZINE) || |
755 | magazine_obj_put(cache, obj)) { |
||
771 | palkovsky | 756 | slab_obj_destroy(cache, obj, slab); |
776 | palkovsky | 757 | |
759 | palkovsky | 758 | } |
769 | palkovsky | 759 | interrupts_restore(ipl); |
764 | palkovsky | 760 | atomic_dec(&cache->allocated_objs); |
759 | palkovsky | 761 | } |
762 | |||
771 | palkovsky | 763 | /** Return slab object to cache */ |
764 | void slab_free(slab_cache_t *cache, void *obj) |
||
765 | { |
||
2124 | decky | 766 | _slab_free(cache, obj, NULL); |
771 | palkovsky | 767 | } |
768 | |||
759 | palkovsky | 769 | /* Go through all caches and reclaim what is possible */ |
770 | count_t slab_reclaim(int flags) |
||
771 | { |
||
772 | slab_cache_t *cache; |
||
773 | link_t *cur; |
||
774 | count_t frames = 0; |
||
775 | |||
776 | spinlock_lock(&slab_cache_lock); |
||
777 | |||
776 | palkovsky | 778 | /* TODO: Add assert, that interrupts are disabled, otherwise |
779 | * memory allocation from interrupts can deadlock. |
||
780 | */ |
||
781 | |||
3180 | jermar | 782 | for (cur = slab_cache_list.next; cur != &slab_cache_list; |
783 | cur = cur->next) { |
||
759 | palkovsky | 784 | cache = list_get_instance(cur, slab_cache_t, link); |
785 | frames += _slab_reclaim(cache, flags); |
||
786 | } |
||
787 | |||
788 | spinlock_unlock(&slab_cache_lock); |
||
789 | |||
790 | return frames; |
||
791 | } |
||
792 | |||
793 | |||
794 | /* Print list of slabs */ |
||
795 | void slab_print_list(void) |
||
796 | { |
||
3183 | jermar | 797 | int skip = 0; |
798 | |||
3180 | jermar | 799 | printf("slab name size pages obj/pg slabs cached allocated" |
800 | " ctl\n"); |
||
801 | printf("---------------- -------- ------ ------ ------ ------ ---------" |
||
802 | " ---\n"); |
||
3183 | jermar | 803 | |
804 | while (true) { |
||
805 | slab_cache_t *cache; |
||
806 | link_t *cur; |
||
807 | ipl_t ipl; |
||
808 | int i; |
||
809 | |||
810 | /* |
||
811 | * We must not hold the slab_cache_lock spinlock when printing |
||
812 | * the statistics. Otherwise we can easily deadlock if the print |
||
813 | * needs to allocate memory. |
||
814 | * |
||
815 | * Therefore, we walk through the slab cache list, skipping some |
||
816 | * amount of already processed caches during each iteration and |
||
817 | * gathering statistics about the first unprocessed cache. For |
||
818 | * the sake of printing the statistics, we realese the |
||
819 | * slab_cache_lock and reacquire it afterwards. Then the walk |
||
820 | * starts again. |
||
821 | * |
||
822 | * This limits both the efficiency and also accuracy of the |
||
823 | * obtained statistics. The efficiency is decreased because the |
||
824 | * time complexity of the algorithm is quadratic instead of |
||
825 | * linear. The accuracy is impacted because we drop the lock |
||
826 | * after processing one cache. If there is someone else |
||
827 | * manipulating the cache list, we might omit an arbitrary |
||
828 | * number of caches or process one cache multiple times. |
||
829 | * However, we don't bleed for this algorithm for it is only |
||
830 | * statistics. |
||
831 | */ |
||
832 | |||
833 | ipl = interrupts_disable(); |
||
834 | spinlock_lock(&slab_cache_lock); |
||
835 | |||
836 | for (i = 0, cur = slab_cache_list.next; |
||
837 | i < skip && cur != &slab_cache_list; |
||
838 | i++, cur = cur->next) |
||
839 | ; |
||
840 | |||
841 | if (cur == &slab_cache_list) { |
||
842 | spinlock_unlock(&slab_cache_lock); |
||
843 | interrupts_restore(ipl); |
||
844 | break; |
||
845 | } |
||
846 | |||
847 | skip++; |
||
848 | |||
759 | palkovsky | 849 | cache = list_get_instance(cur, slab_cache_t, link); |
3183 | jermar | 850 | |
851 | char *name = cache->name; |
||
852 | uint8_t order = cache->order; |
||
853 | size_t size = cache->size; |
||
854 | unsigned int objects = cache->objects; |
||
855 | long allocated_slabs = atomic_get(&cache->allocated_slabs); |
||
856 | long cached_objs = atomic_get(&cache->cached_objs); |
||
857 | long allocated_objs = atomic_get(&cache->allocated_objs); |
||
858 | int flags = cache->flags; |
||
2052 | decky | 859 | |
3183 | jermar | 860 | spinlock_unlock(&slab_cache_lock); |
861 | interrupts_restore(ipl); |
||
862 | |||
3057 | decky | 863 | printf("%-16s %8" PRIs " %6d %6u %6ld %6ld %9ld %-3s\n", |
3183 | jermar | 864 | name, size, (1 << order), objects, allocated_slabs, |
865 | cached_objs, allocated_objs, |
||
866 | flags & SLAB_CACHE_SLINSIDE ? "in" : "out"); |
||
759 | palkovsky | 867 | } |
868 | } |
||
869 | |||
870 | void slab_cache_init(void) |
||
871 | { |
||
771 | palkovsky | 872 | int i, size; |
873 | |||
759 | palkovsky | 874 | /* Initialize magazine cache */ |
3180 | jermar | 875 | _slab_cache_create(&mag_cache, "slab_magazine", |
876 | sizeof(slab_magazine_t) + SLAB_MAG_SIZE * sizeof(void*), |
||
877 | sizeof(uintptr_t), NULL, NULL, SLAB_CACHE_NOMAGAZINE | |
||
878 | SLAB_CACHE_SLINSIDE); |
||
769 | palkovsky | 879 | /* Initialize slab_cache cache */ |
3180 | jermar | 880 | _slab_cache_create(&slab_cache_cache, "slab_cache", |
881 | sizeof(slab_cache_cache), sizeof(uintptr_t), NULL, NULL, |
||
882 | SLAB_CACHE_NOMAGAZINE | SLAB_CACHE_SLINSIDE); |
||
769 | palkovsky | 883 | /* Initialize external slab cache */ |
3180 | jermar | 884 | slab_extern_cache = slab_cache_create("slab_extern", sizeof(slab_t), 0, |
885 | NULL, NULL, SLAB_CACHE_SLINSIDE | SLAB_CACHE_MAGDEFERRED); |
||
759 | palkovsky | 886 | |
887 | /* Initialize structures for malloc */ |
||
3180 | jermar | 888 | for (i = 0, size = (1 << SLAB_MIN_MALLOC_W); |
889 | i < (SLAB_MAX_MALLOC_W - SLAB_MIN_MALLOC_W + 1); |
||
890 | i++, size <<= 1) { |
||
891 | malloc_caches[i] = slab_cache_create(malloc_names[i], size, 0, |
||
892 | NULL, NULL, SLAB_CACHE_MAGDEFERRED); |
||
771 | palkovsky | 893 | } |
778 | palkovsky | 894 | #ifdef CONFIG_DEBUG |
895 | _slab_initialized = 1; |
||
896 | #endif |
||
759 | palkovsky | 897 | } |
771 | palkovsky | 898 | |
789 | palkovsky | 899 | /** Enable cpu_cache |
900 | * |
||
901 | * Kernel calls this function, when it knows the real number of |
||
902 | * processors. |
||
903 | * Allocate slab for cpucache and enable it on all existing |
||
904 | * slabs that are SLAB_CACHE_MAGDEFERRED |
||
905 | */ |
||
906 | void slab_enable_cpucache(void) |
||
907 | { |
||
908 | link_t *cur; |
||
909 | slab_cache_t *s; |
||
910 | |||
791 | palkovsky | 911 | #ifdef CONFIG_DEBUG |
912 | _slab_initialized = 2; |
||
913 | #endif |
||
914 | |||
789 | palkovsky | 915 | spinlock_lock(&slab_cache_lock); |
916 | |||
3180 | jermar | 917 | for (cur = slab_cache_list.next; cur != &slab_cache_list; |
918 | cur = cur->next){ |
||
789 | palkovsky | 919 | s = list_get_instance(cur, slab_cache_t, link); |
3180 | jermar | 920 | if ((s->flags & SLAB_CACHE_MAGDEFERRED) != |
921 | SLAB_CACHE_MAGDEFERRED) |
||
789 | palkovsky | 922 | continue; |
923 | make_magcache(s); |
||
924 | s->flags &= ~SLAB_CACHE_MAGDEFERRED; |
||
925 | } |
||
926 | |||
927 | spinlock_unlock(&slab_cache_lock); |
||
928 | } |
||
929 | |||
771 | palkovsky | 930 | /**************************************/ |
931 | /* kalloc/kfree functions */ |
||
3180 | jermar | 932 | void *malloc(unsigned int size, int flags) |
771 | palkovsky | 933 | { |
778 | palkovsky | 934 | ASSERT(_slab_initialized); |
1288 | jermar | 935 | ASSERT(size && size <= (1 << SLAB_MAX_MALLOC_W)); |
771 | palkovsky | 936 | |
937 | if (size < (1 << SLAB_MIN_MALLOC_W)) |
||
938 | size = (1 << SLAB_MIN_MALLOC_W); |
||
939 | |||
2124 | decky | 940 | int idx = fnzb(size - 1) - SLAB_MIN_MALLOC_W + 1; |
771 | palkovsky | 941 | |
942 | return slab_alloc(malloc_caches[idx], flags); |
||
943 | } |
||
944 | |||
3180 | jermar | 945 | void *realloc(void *ptr, unsigned int size, int flags) |
771 | palkovsky | 946 | { |
2124 | decky | 947 | ASSERT(_slab_initialized); |
948 | ASSERT(size <= (1 << SLAB_MAX_MALLOC_W)); |
||
949 | |||
950 | void *new_ptr; |
||
951 | |||
952 | if (size > 0) { |
||
953 | if (size < (1 << SLAB_MIN_MALLOC_W)) |
||
954 | size = (1 << SLAB_MIN_MALLOC_W); |
||
955 | int idx = fnzb(size - 1) - SLAB_MIN_MALLOC_W + 1; |
||
956 | |||
957 | new_ptr = slab_alloc(malloc_caches[idx], flags); |
||
958 | } else |
||
959 | new_ptr = NULL; |
||
960 | |||
961 | if ((new_ptr != NULL) && (ptr != NULL)) { |
||
962 | slab_t *slab = obj2slab(ptr); |
||
963 | memcpy(new_ptr, ptr, min(size, slab->cache->size)); |
||
964 | } |
||
965 | |||
966 | if (ptr != NULL) |
||
967 | free(ptr); |
||
968 | |||
969 | return new_ptr; |
||
970 | } |
||
781 | palkovsky | 971 | |
2124 | decky | 972 | void free(void *ptr) |
973 | { |
||
974 | if (!ptr) |
||
1950 | jermar | 975 | return; |
781 | palkovsky | 976 | |
2124 | decky | 977 | slab_t *slab = obj2slab(ptr); |
978 | _slab_free(slab->cache, ptr, slab); |
||
771 | palkovsky | 979 | } |
1702 | cejka | 980 | |
1757 | jermar | 981 | /** @} |
1702 | cejka | 982 | */ |