#ifndef JEMALLOC_INTERNAL_SC_H #define JEMALLOC_INTERNAL_SC_H #include "jemalloc/internal/jemalloc_internal_types.h" /* * Size class computations: * * These are a little tricky; we'll first start by describing how things * generally work, and then describe some of the details. * * Ignore the first few size classes for a moment. We can then split all the * remaining size classes into groups. The size classes in a group are spaced * such that they cover allocation request sizes in a power-of-2 range. The * power of two is called the base of the group, and the size classes in it * satisfy allocations in the half-open range (base, base * 2]. There are * SC_NGROUP size classes in each group, equally spaced in the range, so that * each one covers allocations for base / SC_NGROUP possible allocation sizes. * We call that value (base / SC_NGROUP) the delta of the group. Each size class * is delta larger than the one before it (including the initial size class in a * group, which is delta large than 2**base, the largest size class in the * previous group). * To make the math all work out nicely, we require that SC_NGROUP is a power of * two, and define it in terms of SC_LG_NGROUP. We'll often talk in terms of * lg_base and lg_delta. For each of these groups then, we have that * lg_delta == lg_base - SC_LG_NGROUP. * The size classes in a group with a given lg_base and lg_delta (which, recall, * can be computed from lg_base for these groups) are therefore: * base + 1 * delta * which covers allocations in (base, base + 1 * delta] * base + 2 * delta * which covers allocations in (base + 1 * delta, base + 2 * delta]. * base + 3 * delta * which covers allocations in (base + 2 * delta, base + 3 * delta]. * ... * base + SC_NGROUP * delta ( == 2 * base) * which covers allocations in (base + (SC_NGROUP - 1) * delta, 2 * base]. * (Note that currently SC_NGROUP is always 4, so the "..." is empty in * practice.) * Note that the last size class in the group is the next power of two (after * base), so that we've set up the induction correctly for the next group's * selection of delta. * * Now, let's start considering the first few size classes. Two extra constants * come into play here: LG_QUANTUM and SC_LG_TINY_MIN. LG_QUANTUM ensures * correct platform alignment; all objects of size (1 << LG_QUANTUM) or larger * are at least (1 << LG_QUANTUM) aligned; this can be used to ensure that we * never return improperly aligned memory, by making (1 << LG_QUANTUM) equal the * highest required alignment of a platform. For allocation sizes smaller than * (1 << LG_QUANTUM) though, we can be more relaxed (since we don't support * platforms with types with alignment larger than their size). To allow such * allocations (without wasting space unnecessarily), we introduce tiny size * classes; one per power of two, up until we hit the quantum size. There are * therefore LG_QUANTUM - SC_LG_TINY_MIN such size classes. * * Next, we have a size class of size LG_QUANTUM. This can't be the start of a * group in the sense we described above (covering a power of two range) since, * if we divided into it to pick a value of delta, we'd get a delta smaller than * (1 << LG_QUANTUM) for sizes >= (1 << LG_QUANTUM), which is against the rules. * * The first base we can divide by SC_NGROUP while still being at least * (1 << LG_QUANTUM) is SC_NGROUP * (1 << LG_QUANTUM). We can get there by * having SC_NGROUP size classes, spaced (1 << LG_QUANTUM) apart. These size * classes are: * 1 * (1 << LG_QUANTUM) * 2 * (1 << LG_QUANTUM) * 3 * (1 << LG_QUANTUM) * ... (although, as above, this "..." is empty in practice) * SC_NGROUP * (1 << LG_QUANTUM). * * There are SC_NGROUP of these size classes, so we can regard it as a sort of * pseudo-group, even though it spans multiple powers of 2, is divided * differently, and both starts and ends on a power of 2 (as opposed to just * ending). SC_NGROUP is itself a power of two, so the first group after the * pseudo-group has the power-of-two base SC_NGROUP * (1 << LG_QUANTUM), for a * lg_base of LG_QUANTUM + SC_LG_NGROUP. We can divide this base into SC_NGROUP * sizes without violating our LG_QUANTUM requirements, so we can safely set * lg_delta = lg_base - SC_LG_GROUP (== LG_QUANTUM). * * So, in order, the size classes are: * * Tiny size classes: * - Count: LG_QUANTUM - SC_LG_TINY_MIN. * - Sizes: * 1 << SC_LG_TINY_MIN * 1 << (SC_LG_TINY_MIN + 1) * 1 << (SC_LG_TINY_MIN + 2) * ... * 1 << (LG_QUANTUM - 1) * * Initial pseudo-group: * - Count: SC_NGROUP * - Sizes: * 1 * (1 << LG_QUANTUM) * 2 * (1 << LG_QUANTUM) * 3 * (1 << LG_QUANTUM) * ... * SC_NGROUP * (1 << LG_QUANTUM) * * Regular group 0: * - Count: SC_NGROUP * - Sizes: * (relative to lg_base of LG_QUANTUM + SC_LG_NGROUP and lg_delta of * lg_base - SC_LG_NGROUP) * (1 << lg_base) + 1 * (1 << lg_delta) * (1 << lg_base) + 2 * (1 << lg_delta) * (1 << lg_base) + 3 * (1 << lg_delta) * ... * (1 << lg_base) + SC_NGROUP * (1 << lg_delta) [ == (1 << (lg_base + 1)) ] * * Regular group 1: * - Count: SC_NGROUP * - Sizes: * (relative to lg_base of LG_QUANTUM + SC_LG_NGROUP + 1 and lg_delta of * lg_base - SC_LG_NGROUP) * (1 << lg_base) + 1 * (1 << lg_delta) * (1 << lg_base) + 2 * (1 << lg_delta) * (1 << lg_base) + 3 * (1 << lg_delta) * ... * (1 << lg_base) + SC_NGROUP * (1 << lg_delta) [ == (1 << (lg_base + 1)) ] * * ... * * Regular group N: * - Count: SC_NGROUP * - Sizes: * (relative to lg_base of LG_QUANTUM + SC_LG_NGROUP + N and lg_delta of * lg_base - SC_LG_NGROUP) * (1 << lg_base) + 1 * (1 << lg_delta) * (1 << lg_base) + 2 * (1 << lg_delta) * (1 << lg_base) + 3 * (1 << lg_delta) * ... * (1 << lg_base) + SC_NGROUP * (1 << lg_delta) [ == (1 << (lg_base + 1)) ] * * * Representation of metadata: * To make the math easy, we'll mostly work in lg quantities. We record lg_base, * lg_delta, and ndelta (i.e. number of deltas above the base) on a * per-size-class basis, and maintain the invariant that, across all size * classes, size == (1 << lg_base) + ndelta * (1 << lg_delta). * * For regular groups (i.e. those with lg_base >= LG_QUANTUM + SC_LG_NGROUP), * lg_delta is lg_base - SC_LG_NGROUP, and ndelta goes from 1 to SC_NGROUP. * * For the initial tiny size classes (if any), lg_base is lg(size class size). * lg_delta is lg_base for the first size class, and lg_base - 1 for all * subsequent ones. ndelta is always 0. * * For the pseudo-group, if there are no tiny size classes, then we set * lg_base == LG_QUANTUM, lg_delta == LG_QUANTUM, and have ndelta range from 0 * to SC_NGROUP - 1. (Note that delta == base, so base + (SC_NGROUP - 1) * delta * is just SC_NGROUP * base, or (1 << (SC_LG_NGROUP + LG_QUANTUM)), so we do * indeed get a power of two that way). If there *are* tiny size classes, then * the first size class needs to have lg_delta relative to the largest tiny size * class. We therefore set lg_base == LG_QUANTUM - 1, * lg_delta == LG_QUANTUM - 1, and ndelta == 1, keeping the rest of the * pseudo-group the same. * * * Other terminology: * "Small" size classes mean those that are allocated out of bins, which is the * same as those that are slab allocated. * "Large" size classes are those that are not small. The cutoff for counting as * large is page size * group size. */ /* * Size class N + (1 << SC_LG_NGROUP) twice the size of size class N. */ #define SC_LG_NGROUP 2 #define SC_LG_TINY_MIN 3 #if SC_LG_TINY_MIN == 0 /* The div module doesn't support division by 1, which this would require. */ #error "Unsupported LG_TINY_MIN" #endif /* * The definitions below are all determined by the above settings and system * characteristics. */ #define SC_NGROUP (1ULL << SC_LG_NGROUP) #define SC_PTR_BITS ((1ULL << LG_SIZEOF_PTR) * 8) #define SC_NTINY (LG_QUANTUM - SC_LG_TINY_MIN) #define SC_LG_TINY_MAXCLASS (LG_QUANTUM > SC_LG_TINY_MIN ? LG_QUANTUM - 1 : -1) #define SC_NPSEUDO SC_NGROUP #define SC_LG_FIRST_REGULAR_BASE (LG_QUANTUM + SC_LG_NGROUP) /* * We cap allocations to be less than 2 ** (ptr_bits - 1), so the highest base * we need is 2 ** (ptr_bits - 2). (This also means that the last group is 1 * size class shorter than the others). * We could probably save some space in arenas by capping this at LG_VADDR size. */ #define SC_LG_BASE_MAX (SC_PTR_BITS - 2) #define SC_NREGULAR (SC_NGROUP * \ (SC_LG_BASE_MAX - SC_LG_FIRST_REGULAR_BASE + 1) - 1) #define SC_NSIZES (SC_NTINY + SC_NPSEUDO + SC_NREGULAR) /* * The number of size classes that are at least a page in size. Note that * because delta may be smaller than a page, this is not the same as the number * of size classes that are *multiples* of the page size. */ #define SC_NPSIZES ( \ /* Start with all the size classes. */ \ SC_NSIZES \ /* Subtract out those groups with too small a base. */ \ - (LG_PAGE - 1 - SC_LG_FIRST_REGULAR_BASE) * SC_NGROUP \ /* And the pseudo-group. */ \ - SC_NPSEUDO \ /* And the tiny group. */ \ - SC_NTINY \ /* Groups where ndelta*delta is not a multiple of the page size. */ \ - (2 * (SC_NGROUP))) /* * We declare a size class is binnable if size < page size * group. Or, in other * words, lg(size) < lg(page size) + lg(group size). */ #define SC_NBINS ( \ /* Sub-regular size classes. */ \ SC_NTINY + SC_NPSEUDO \ /* Groups with lg_regular_min_base <= lg_base <= lg_base_max */ \ + SC_NGROUP * (LG_PAGE + SC_LG_NGROUP - SC_LG_FIRST_REGULAR_BASE) \ /* Last SC of the last group hits the bound exactly; exclude it. */ \ - 1) /* * The size2index_tab lookup table uses uint8_t to encode each bin index, so we * cannot support more than 256 small size classes. */ #if (SC_NBINS > 256) # error "Too many small size classes" #endif /* The largest size class in the lookup table. */ #define SC_LOOKUP_MAXCLASS ((size_t)1 << 12) /* Internal, only used for the definition of SC_SMALL_MAXCLASS. */ #define SC_SMALL_MAX_BASE ((size_t)1 << (LG_PAGE + SC_LG_NGROUP - 1)) #define SC_SMALL_MAX_DELTA ((size_t)1 << (LG_PAGE - 1)) /* The largest size class allocated out of a slab. */ #define SC_SMALL_MAXCLASS (SC_SMALL_MAX_BASE \ + (SC_NGROUP - 1) * SC_SMALL_MAX_DELTA) /* The smallest size class not allocated out of a slab. */ #define SC_LARGE_MINCLASS ((size_t)1ULL << (LG_PAGE + SC_LG_NGROUP)) #define SC_LG_LARGE_MINCLASS (LG_PAGE + SC_LG_NGROUP) /* Internal; only used for the definition of SC_LARGE_MAXCLASS. */ #define SC_MAX_BASE ((size_t)1 << (SC_PTR_BITS - 2)) #define SC_MAX_DELTA ((size_t)1 << (SC_PTR_BITS - 2 - SC_LG_NGROUP)) /* The largest size class supported. */ #define SC_LARGE_MAXCLASS (SC_MAX_BASE + (SC_NGROUP - 1) * SC_MAX_DELTA) typedef struct sc_s sc_t; struct sc_s { /* Size class index, or -1 if not a valid size class. */ int index; /* Lg group base size (no deltas added). */ int lg_base; /* Lg delta to previous size class. */ int lg_delta; /* Delta multiplier. size == 1<