1 #ifndef JEMALLOC_INTERNAL_SC_H 2 #define JEMALLOC_INTERNAL_SC_H 3 4 #include "jemalloc/internal/jemalloc_internal_types.h" 5 6 /* 7 * Size class computations: 8 * 9 * These are a little tricky; we'll first start by describing how things 10 * generally work, and then describe some of the details. 11 * 12 * Ignore the first few size classes for a moment. We can then split all the 13 * remaining size classes into groups. The size classes in a group are spaced 14 * such that they cover allocation request sizes in a power-of-2 range. The 15 * power of two is called the base of the group, and the size classes in it 16 * satisfy allocations in the half-open range (base, base * 2]. There are 17 * SC_NGROUP size classes in each group, equally spaced in the range, so that 18 * each one covers allocations for base / SC_NGROUP possible allocation sizes. 19 * We call that value (base / SC_NGROUP) the delta of the group. Each size class 20 * is delta larger than the one before it (including the initial size class in a 21 * group, which is delta larger than base, the largest size class in the 22 * previous group). 23 * To make the math all work out nicely, we require that SC_NGROUP is a power of 24 * two, and define it in terms of SC_LG_NGROUP. We'll often talk in terms of 25 * lg_base and lg_delta. For each of these groups then, we have that 26 * lg_delta == lg_base - SC_LG_NGROUP. 27 * The size classes in a group with a given lg_base and lg_delta (which, recall, 28 * can be computed from lg_base for these groups) are therefore: 29 * base + 1 * delta 30 * which covers allocations in (base, base + 1 * delta] 31 * base + 2 * delta 32 * which covers allocations in (base + 1 * delta, base + 2 * delta]. 33 * base + 3 * delta 34 * which covers allocations in (base + 2 * delta, base + 3 * delta]. 35 * ... 36 * base + SC_NGROUP * delta ( == 2 * base) 37 * which covers allocations in (base + (SC_NGROUP - 1) * delta, 2 * base]. 38 * (Note that currently SC_NGROUP is always 4, so the "..." is empty in 39 * practice.) 40 * Note that the last size class in the group is the next power of two (after 41 * base), so that we've set up the induction correctly for the next group's 42 * selection of delta. 43 * 44 * Now, let's start considering the first few size classes. Two extra constants 45 * come into play here: LG_QUANTUM and SC_LG_TINY_MIN. LG_QUANTUM ensures 46 * correct platform alignment; all objects of size (1 << LG_QUANTUM) or larger 47 * are at least (1 << LG_QUANTUM) aligned; this can be used to ensure that we 48 * never return improperly aligned memory, by making (1 << LG_QUANTUM) equal the 49 * highest required alignment of a platform. For allocation sizes smaller than 50 * (1 << LG_QUANTUM) though, we can be more relaxed (since we don't support 51 * platforms with types with alignment larger than their size). To allow such 52 * allocations (without wasting space unnecessarily), we introduce tiny size 53 * classes; one per power of two, up until we hit the quantum size. There are 54 * therefore LG_QUANTUM - SC_LG_TINY_MIN such size classes. 55 * 56 * Next, we have a size class of size (1 << LG_QUANTUM). This can't be the 57 * start of a group in the sense we described above (covering a power of two 58 * range) since, if we divided into it to pick a value of delta, we'd get a 59 * delta smaller than (1 << LG_QUANTUM) for sizes >= (1 << LG_QUANTUM), which 60 * is against the rules. 61 * 62 * The first base we can divide by SC_NGROUP while still being at least 63 * (1 << LG_QUANTUM) is SC_NGROUP * (1 << LG_QUANTUM). We can get there by 64 * having SC_NGROUP size classes, spaced (1 << LG_QUANTUM) apart. These size 65 * classes are: 66 * 1 * (1 << LG_QUANTUM) 67 * 2 * (1 << LG_QUANTUM) 68 * 3 * (1 << LG_QUANTUM) 69 * ... (although, as above, this "..." is empty in practice) 70 * SC_NGROUP * (1 << LG_QUANTUM). 71 * 72 * There are SC_NGROUP of these size classes, so we can regard it as a sort of 73 * pseudo-group, even though it spans multiple powers of 2, is divided 74 * differently, and both starts and ends on a power of 2 (as opposed to just 75 * ending). SC_NGROUP is itself a power of two, so the first group after the 76 * pseudo-group has the power-of-two base SC_NGROUP * (1 << LG_QUANTUM), for a 77 * lg_base of LG_QUANTUM + SC_LG_NGROUP. We can divide this base into SC_NGROUP 78 * sizes without violating our LG_QUANTUM requirements, so we can safely set 79 * lg_delta = lg_base - SC_LG_GROUP (== LG_QUANTUM). 80 * 81 * So, in order, the size classes are: 82 * 83 * Tiny size classes: 84 * - Count: LG_QUANTUM - SC_LG_TINY_MIN. 85 * - Sizes: 86 * 1 << SC_LG_TINY_MIN 87 * 1 << (SC_LG_TINY_MIN + 1) 88 * 1 << (SC_LG_TINY_MIN + 2) 89 * ... 90 * 1 << (LG_QUANTUM - 1) 91 * 92 * Initial pseudo-group: 93 * - Count: SC_NGROUP 94 * - Sizes: 95 * 1 * (1 << LG_QUANTUM) 96 * 2 * (1 << LG_QUANTUM) 97 * 3 * (1 << LG_QUANTUM) 98 * ... 99 * SC_NGROUP * (1 << LG_QUANTUM) 100 * 101 * Regular group 0: 102 * - Count: SC_NGROUP 103 * - Sizes: 104 * (relative to lg_base of LG_QUANTUM + SC_LG_NGROUP and lg_delta of 105 * lg_base - SC_LG_NGROUP) 106 * (1 << lg_base) + 1 * (1 << lg_delta) 107 * (1 << lg_base) + 2 * (1 << lg_delta) 108 * (1 << lg_base) + 3 * (1 << lg_delta) 109 * ... 110 * (1 << lg_base) + SC_NGROUP * (1 << lg_delta) [ == (1 << (lg_base + 1)) ] 111 * 112 * Regular group 1: 113 * - Count: SC_NGROUP 114 * - Sizes: 115 * (relative to lg_base of LG_QUANTUM + SC_LG_NGROUP + 1 and lg_delta of 116 * lg_base - SC_LG_NGROUP) 117 * (1 << lg_base) + 1 * (1 << lg_delta) 118 * (1 << lg_base) + 2 * (1 << lg_delta) 119 * (1 << lg_base) + 3 * (1 << lg_delta) 120 * ... 121 * (1 << lg_base) + SC_NGROUP * (1 << lg_delta) [ == (1 << (lg_base + 1)) ] 122 * 123 * ... 124 * 125 * Regular group N: 126 * - Count: SC_NGROUP 127 * - Sizes: 128 * (relative to lg_base of LG_QUANTUM + SC_LG_NGROUP + N and lg_delta of 129 * lg_base - SC_LG_NGROUP) 130 * (1 << lg_base) + 1 * (1 << lg_delta) 131 * (1 << lg_base) + 2 * (1 << lg_delta) 132 * (1 << lg_base) + 3 * (1 << lg_delta) 133 * ... 134 * (1 << lg_base) + SC_NGROUP * (1 << lg_delta) [ == (1 << (lg_base + 1)) ] 135 * 136 * 137 * Representation of metadata: 138 * To make the math easy, we'll mostly work in lg quantities. We record lg_base, 139 * lg_delta, and ndelta (i.e. number of deltas above the base) on a 140 * per-size-class basis, and maintain the invariant that, across all size 141 * classes, size == (1 << lg_base) + ndelta * (1 << lg_delta). 142 * 143 * For regular groups (i.e. those with lg_base >= LG_QUANTUM + SC_LG_NGROUP), 144 * lg_delta is lg_base - SC_LG_NGROUP, and ndelta goes from 1 to SC_NGROUP. 145 * 146 * For the initial tiny size classes (if any), lg_base is lg(size class size). 147 * lg_delta is lg_base for the first size class, and lg_base - 1 for all 148 * subsequent ones. ndelta is always 0. 149 * 150 * For the pseudo-group, if there are no tiny size classes, then we set 151 * lg_base == LG_QUANTUM, lg_delta == LG_QUANTUM, and have ndelta range from 0 152 * to SC_NGROUP - 1. (Note that delta == base, so base + (SC_NGROUP - 1) * delta 153 * is just SC_NGROUP * base, or (1 << (SC_LG_NGROUP + LG_QUANTUM)), so we do 154 * indeed get a power of two that way). If there *are* tiny size classes, then 155 * the first size class needs to have lg_delta relative to the largest tiny size 156 * class. We therefore set lg_base == LG_QUANTUM - 1, 157 * lg_delta == LG_QUANTUM - 1, and ndelta == 1, keeping the rest of the 158 * pseudo-group the same. 159 * 160 * 161 * Other terminology: 162 * "Small" size classes mean those that are allocated out of bins, which is the 163 * same as those that are slab allocated. 164 * "Large" size classes are those that are not small. The cutoff for counting as 165 * large is page size * group size. 166 */ 167 168 /* 169 * Size class N + (1 << SC_LG_NGROUP) twice the size of size class N. 170 */ 171 #define SC_LG_NGROUP 2 172 #define SC_LG_TINY_MIN 3 173 174 #if SC_LG_TINY_MIN == 0 175 /* The div module doesn't support division by 1, which this would require. */ 176 #error "Unsupported LG_TINY_MIN" 177 #endif 178 179 /* 180 * The definitions below are all determined by the above settings and system 181 * characteristics. 182 */ 183 #define SC_NGROUP (1ULL << SC_LG_NGROUP) 184 #define SC_PTR_BITS ((1ULL << LG_SIZEOF_PTR) * 8) 185 #define SC_NTINY (LG_QUANTUM - SC_LG_TINY_MIN) 186 #define SC_LG_TINY_MAXCLASS (LG_QUANTUM > SC_LG_TINY_MIN ? LG_QUANTUM - 1 : -1) 187 #define SC_NPSEUDO SC_NGROUP 188 #define SC_LG_FIRST_REGULAR_BASE (LG_QUANTUM + SC_LG_NGROUP) 189 /* 190 * We cap allocations to be less than 2 ** (ptr_bits - 1), so the highest base 191 * we need is 2 ** (ptr_bits - 2). (This also means that the last group is 1 192 * size class shorter than the others). 193 * We could probably save some space in arenas by capping this at LG_VADDR size. 194 */ 195 #define SC_LG_BASE_MAX (SC_PTR_BITS - 2) 196 #define SC_NREGULAR (SC_NGROUP * \ 197 (SC_LG_BASE_MAX - SC_LG_FIRST_REGULAR_BASE + 1) - 1) 198 #define SC_NSIZES (SC_NTINY + SC_NPSEUDO + SC_NREGULAR) 199 200 /* 201 * The number of size classes that are a multiple of the page size. 202 * 203 * Here are the first few bases that have a page-sized SC. 204 * 205 * lg(base) | base | highest SC | page-multiple SCs 206 * --------------|------------------------------------------ 207 * LG_PAGE - 1 | PAGE / 2 | PAGE | 1 208 * LG_PAGE | PAGE | 2 * PAGE | 1 209 * LG_PAGE + 1 | 2 * PAGE | 4 * PAGE | 2 210 * LG_PAGE + 2 | 4 * PAGE | 8 * PAGE | 4 211 * 212 * The number of page-multiple SCs continues to grow in powers of two, up until 213 * lg_delta == lg_page, which corresponds to setting lg_base to lg_page + 214 * SC_LG_NGROUP. So, then, the number of size classes that are multiples of the 215 * page size whose lg_delta is less than the page size are 216 * is 1 + (2**0 + 2**1 + ... + 2**(lg_ngroup - 1) == 2**lg_ngroup. 217 * 218 * For each base with lg_base in [lg_page + lg_ngroup, lg_base_max), there are 219 * NGROUP page-sized size classes, and when lg_base == lg_base_max, there are 220 * NGROUP - 1. 221 * 222 * This gives us the quantity we seek. 223 */ 224 #define SC_NPSIZES ( \ 225 SC_NGROUP \ 226 + (SC_LG_BASE_MAX - (LG_PAGE + SC_LG_NGROUP)) * SC_NGROUP \ 227 + SC_NGROUP - 1) 228 229 /* 230 * We declare a size class is binnable if size < page size * group. Or, in other 231 * words, lg(size) < lg(page size) + lg(group size). 232 */ 233 #define SC_NBINS ( \ 234 /* Sub-regular size classes. */ \ 235 SC_NTINY + SC_NPSEUDO \ 236 /* Groups with lg_regular_min_base <= lg_base <= lg_base_max */ \ 237 + SC_NGROUP * (LG_PAGE + SC_LG_NGROUP - SC_LG_FIRST_REGULAR_BASE) \ 238 /* Last SC of the last group hits the bound exactly; exclude it. */ \ 239 - 1) 240 241 /* 242 * The size2index_tab lookup table uses uint8_t to encode each bin index, so we 243 * cannot support more than 256 small size classes. 244 */ 245 #if (SC_NBINS > 256) 246 # error "Too many small size classes" 247 #endif 248 249 /* The largest size class in the lookup table, and its binary log. */ 250 #define SC_LG_MAX_LOOKUP 12 251 #define SC_LOOKUP_MAXCLASS (1 << SC_LG_MAX_LOOKUP) 252 253 /* Internal, only used for the definition of SC_SMALL_MAXCLASS. */ 254 #define SC_SMALL_MAX_BASE (1 << (LG_PAGE + SC_LG_NGROUP - 1)) 255 #define SC_SMALL_MAX_DELTA (1 << (LG_PAGE - 1)) 256 257 /* The largest size class allocated out of a slab. */ 258 #define SC_SMALL_MAXCLASS (SC_SMALL_MAX_BASE \ 259 + (SC_NGROUP - 1) * SC_SMALL_MAX_DELTA) 260 261 /* The fastpath assumes all lookup-able sizes are small. */ 262 #if (SC_SMALL_MAXCLASS < SC_LOOKUP_MAXCLASS) 263 # error "Lookup table sizes must be small" 264 #endif 265 266 /* The smallest size class not allocated out of a slab. */ 267 #define SC_LARGE_MINCLASS ((size_t)1ULL << (LG_PAGE + SC_LG_NGROUP)) 268 #define SC_LG_LARGE_MINCLASS (LG_PAGE + SC_LG_NGROUP) 269 270 /* Internal; only used for the definition of SC_LARGE_MAXCLASS. */ 271 #define SC_MAX_BASE ((size_t)1 << (SC_PTR_BITS - 2)) 272 #define SC_MAX_DELTA ((size_t)1 << (SC_PTR_BITS - 2 - SC_LG_NGROUP)) 273 274 /* The largest size class supported. */ 275 #define SC_LARGE_MAXCLASS (SC_MAX_BASE + (SC_NGROUP - 1) * SC_MAX_DELTA) 276 277 /* Maximum number of regions in one slab. */ 278 #ifndef CONFIG_LG_SLAB_MAXREGS 279 # define SC_LG_SLAB_MAXREGS (LG_PAGE - SC_LG_TINY_MIN) 280 #else 281 # if CONFIG_LG_SLAB_MAXREGS < (LG_PAGE - SC_LG_TINY_MIN) 282 # error "Unsupported SC_LG_SLAB_MAXREGS" 283 # else 284 # define SC_LG_SLAB_MAXREGS CONFIG_LG_SLAB_MAXREGS 285 # endif 286 #endif 287 288 #define SC_SLAB_MAXREGS (1U << SC_LG_SLAB_MAXREGS) 289 290 typedef struct sc_s sc_t; 291 struct sc_s { 292 /* Size class index, or -1 if not a valid size class. */ 293 int index; 294 /* Lg group base size (no deltas added). */ 295 int lg_base; 296 /* Lg delta to previous size class. */ 297 int lg_delta; 298 /* Delta multiplier. size == 1<<lg_base + ndelta<<lg_delta */ 299 int ndelta; 300 /* 301 * True if the size class is a multiple of the page size, false 302 * otherwise. 303 */ 304 bool psz; 305 /* 306 * True if the size class is a small, bin, size class. False otherwise. 307 */ 308 bool bin; 309 /* The slab page count if a small bin size class, 0 otherwise. */ 310 int pgs; 311 /* Same as lg_delta if a lookup table size class, 0 otherwise. */ 312 int lg_delta_lookup; 313 }; 314 315 typedef struct sc_data_s sc_data_t; 316 struct sc_data_s { 317 /* Number of tiny size classes. */ 318 unsigned ntiny; 319 /* Number of bins supported by the lookup table. */ 320 int nlbins; 321 /* Number of small size class bins. */ 322 int nbins; 323 /* Number of size classes. */ 324 int nsizes; 325 /* Number of bits required to store NSIZES. */ 326 int lg_ceil_nsizes; 327 /* Number of size classes that are a multiple of (1U << LG_PAGE). */ 328 unsigned npsizes; 329 /* Lg of maximum tiny size class (or -1, if none). */ 330 int lg_tiny_maxclass; 331 /* Maximum size class included in lookup table. */ 332 size_t lookup_maxclass; 333 /* Maximum small size class. */ 334 size_t small_maxclass; 335 /* Lg of minimum large size class. */ 336 int lg_large_minclass; 337 /* The minimum large size class. */ 338 size_t large_minclass; 339 /* Maximum (large) size class. */ 340 size_t large_maxclass; 341 /* True if the sc_data_t has been initialized (for debugging only). */ 342 bool initialized; 343 344 sc_t sc[SC_NSIZES]; 345 }; 346 347 size_t reg_size_compute(int lg_base, int lg_delta, int ndelta); 348 void sc_data_init(sc_data_t *data); 349 /* 350 * Updates slab sizes in [begin, end] to be pgs pages in length, if possible. 351 * Otherwise, does its best to accommodate the request. 352 */ 353 void sc_data_update_slab_size(sc_data_t *data, size_t begin, size_t end, 354 int pgs); 355 void sc_boot(sc_data_t *data); 356 357 #endif /* JEMALLOC_INTERNAL_SC_H */ 358
Indexes created Sun Apr 19 00:22:55 UTC 2026