710 lines
22 KiB
C
710 lines
22 KiB
C
/******************************************************************************/
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#ifdef JEMALLOC_H_TYPES
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/*
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* Subpages are an artificially designated partitioning of pages. Their only
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* purpose is to support subpage-spaced size classes.
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*
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* There must be at least 4 subpages per page, due to the way size classes are
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* handled.
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*/
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#define LG_SUBPAGE 8
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#define SUBPAGE ((size_t)(1U << LG_SUBPAGE))
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#define SUBPAGE_MASK (SUBPAGE - 1)
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/* Return the smallest subpage multiple that is >= s. */
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#define SUBPAGE_CEILING(s) \
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(((s) + SUBPAGE_MASK) & ~SUBPAGE_MASK)
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/* Smallest size class to support. */
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#define LG_TINY_MIN 3
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#define TINY_MIN (1U << LG_TINY_MIN)
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/*
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* Maximum size class that is a multiple of the quantum, but not (necessarily)
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* a power of 2. Above this size, allocations are rounded up to the nearest
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* power of 2.
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*/
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#define LG_QSPACE_MAX_DEFAULT 7
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/*
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* Maximum size class that is a multiple of the cacheline, but not (necessarily)
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* a power of 2. Above this size, allocations are rounded up to the nearest
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* power of 2.
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*/
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#define LG_CSPACE_MAX_DEFAULT 9
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/*
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* RUN_MAX_OVRHD indicates maximum desired run header overhead. Runs are sized
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* as small as possible such that this setting is still honored, without
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* violating other constraints. The goal is to make runs as small as possible
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* without exceeding a per run external fragmentation threshold.
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*
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* We use binary fixed point math for overhead computations, where the binary
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* point is implicitly RUN_BFP bits to the left.
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*
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* Note that it is possible to set RUN_MAX_OVRHD low enough that it cannot be
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* honored for some/all object sizes, since when heap profiling is enabled
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* there is one pointer of header overhead per object (plus a constant). This
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* constraint is relaxed (ignored) for runs that are so small that the
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* per-region overhead is greater than:
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*
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* (RUN_MAX_OVRHD / (reg_size << (3+RUN_BFP))
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*/
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#define RUN_BFP 12
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/* \/ Implicit binary fixed point. */
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#define RUN_MAX_OVRHD 0x0000003dU
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#define RUN_MAX_OVRHD_RELAX 0x00001800U
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/* Maximum number of regions in one run. */
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#define LG_RUN_MAXREGS 11
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#define RUN_MAXREGS (1U << LG_RUN_MAXREGS)
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/*
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* The minimum ratio of active:dirty pages per arena is computed as:
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*
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* (nactive >> opt_lg_dirty_mult) >= ndirty
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*
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* So, supposing that opt_lg_dirty_mult is 5, there can be no less than 32
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* times as many active pages as dirty pages.
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*/
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#define LG_DIRTY_MULT_DEFAULT 5
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typedef struct arena_chunk_map_s arena_chunk_map_t;
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typedef struct arena_chunk_s arena_chunk_t;
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typedef struct arena_run_s arena_run_t;
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typedef struct arena_bin_info_s arena_bin_info_t;
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typedef struct arena_bin_s arena_bin_t;
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typedef struct arena_s arena_t;
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#endif /* JEMALLOC_H_TYPES */
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/******************************************************************************/
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#ifdef JEMALLOC_H_STRUCTS
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/* Each element of the chunk map corresponds to one page within the chunk. */
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struct arena_chunk_map_s {
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#ifndef JEMALLOC_PROF
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/*
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* Overlay prof_ctx in order to allow it to be referenced by dead code.
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* Such antics aren't warranted for per arena data structures, but
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* chunk map overhead accounts for a percentage of memory, rather than
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* being just a fixed cost.
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*/
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union {
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#endif
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union {
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/*
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* Linkage for run trees. There are two disjoint uses:
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*
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* 1) arena_t's runs_avail_{clean,dirty} trees.
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* 2) arena_run_t conceptually uses this linkage for in-use
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* non-full runs, rather than directly embedding linkage.
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*/
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rb_node(arena_chunk_map_t) rb_link;
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/*
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* List of runs currently in purgatory. arena_chunk_purge()
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* temporarily allocates runs that contain dirty pages while
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* purging, so that other threads cannot use the runs while the
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* purging thread is operating without the arena lock held.
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*/
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ql_elm(arena_chunk_map_t) ql_link;
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} u;
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/* Profile counters, used for large object runs. */
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prof_ctx_t *prof_ctx;
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#ifndef JEMALLOC_PROF
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}; /* union { ... }; */
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#endif
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/*
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* Run address (or size) and various flags are stored together. The bit
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* layout looks like (assuming 32-bit system):
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*
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* ???????? ???????? ????---- ----dula
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*
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* ? : Unallocated: Run address for first/last pages, unset for internal
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* pages.
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* Small: Run page offset.
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* Large: Run size for first page, unset for trailing pages.
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* - : Unused.
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* d : dirty?
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* u : unzeroed?
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* l : large?
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* a : allocated?
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*
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* Following are example bit patterns for the three types of runs.
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*
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* p : run page offset
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* s : run size
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* c : (binind+1) for size class (used only if prof_promote is true)
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* x : don't care
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* - : 0
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* + : 1
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* [DULA] : bit set
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* [dula] : bit unset
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*
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* Unallocated (clean):
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* ssssssss ssssssss ssss---- ----du-a
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* xxxxxxxx xxxxxxxx xxxx---- -----Uxx
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* ssssssss ssssssss ssss---- ----dU-a
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*
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* Unallocated (dirty):
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* ssssssss ssssssss ssss---- ----D--a
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* xxxxxxxx xxxxxxxx xxxx---- ----xxxx
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* ssssssss ssssssss ssss---- ----D--a
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*
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* Small:
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* pppppppp pppppppp pppp---- ----d--A
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* pppppppp pppppppp pppp---- -------A
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* pppppppp pppppppp pppp---- ----d--A
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*
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* Large:
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* ssssssss ssssssss ssss---- ----D-LA
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* xxxxxxxx xxxxxxxx xxxx---- ----xxxx
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* -------- -------- -------- ----D-LA
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*
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* Large (sampled, size <= PAGE_SIZE):
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* ssssssss ssssssss sssscccc ccccD-LA
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*
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* Large (not sampled, size == PAGE_SIZE):
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* ssssssss ssssssss ssss---- ----D-LA
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*/
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size_t bits;
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#define CHUNK_MAP_CLASS_SHIFT 4
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#define CHUNK_MAP_CLASS_MASK ((size_t)0xff0U)
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#define CHUNK_MAP_FLAGS_MASK ((size_t)0xfU)
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#define CHUNK_MAP_DIRTY ((size_t)0x8U)
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#define CHUNK_MAP_UNZEROED ((size_t)0x4U)
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#define CHUNK_MAP_LARGE ((size_t)0x2U)
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#define CHUNK_MAP_ALLOCATED ((size_t)0x1U)
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#define CHUNK_MAP_KEY CHUNK_MAP_ALLOCATED
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};
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typedef rb_tree(arena_chunk_map_t) arena_avail_tree_t;
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typedef rb_tree(arena_chunk_map_t) arena_run_tree_t;
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/* Arena chunk header. */
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struct arena_chunk_s {
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/* Arena that owns the chunk. */
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arena_t *arena;
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/* Linkage for the arena's chunks_dirty list. */
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ql_elm(arena_chunk_t) link_dirty;
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/*
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* True if the chunk is currently in the chunks_dirty list, due to
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* having at some point contained one or more dirty pages. Removal
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* from chunks_dirty is lazy, so (dirtied && ndirty == 0) is possible.
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*/
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bool dirtied;
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/* Number of dirty pages. */
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size_t ndirty;
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/*
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* Map of pages within chunk that keeps track of free/large/small. The
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* first map_bias entries are omitted, since the chunk header does not
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* need to be tracked in the map. This omission saves a header page
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* for common chunk sizes (e.g. 4 MiB).
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*/
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arena_chunk_map_t map[1]; /* Dynamically sized. */
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};
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typedef rb_tree(arena_chunk_t) arena_chunk_tree_t;
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struct arena_run_s {
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/* Bin this run is associated with. */
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arena_bin_t *bin;
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/* Index of next region that has never been allocated, or nregs. */
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uint32_t nextind;
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/* Number of free regions in run. */
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unsigned nfree;
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};
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/*
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* Read-only information associated with each element of arena_t's bins array
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* is stored separately, partly to reduce memory usage (only one copy, rather
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* than one per arena), but mainly to avoid false cacheline sharing.
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*/
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struct arena_bin_info_s {
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/* Size of regions in a run for this bin's size class. */
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size_t reg_size;
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/* Total size of a run for this bin's size class. */
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size_t run_size;
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/* Total number of regions in a run for this bin's size class. */
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uint32_t nregs;
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/*
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* Offset of first bitmap_t element in a run header for this bin's size
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* class.
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*/
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uint32_t bitmap_offset;
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/*
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* Metadata used to manipulate bitmaps for runs associated with this
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* bin.
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*/
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bitmap_info_t bitmap_info;
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/*
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* Offset of first (prof_ctx_t *) in a run header for this bin's size
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* class, or 0 if (config_prof == false || opt_prof == false).
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*/
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uint32_t ctx0_offset;
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/* Offset of first region in a run for this bin's size class. */
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uint32_t reg0_offset;
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};
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struct arena_bin_s {
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/*
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* All operations on runcur, runs, and stats require that lock be
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* locked. Run allocation/deallocation are protected by the arena lock,
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* which may be acquired while holding one or more bin locks, but not
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* vise versa.
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*/
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malloc_mutex_t lock;
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/*
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* Current run being used to service allocations of this bin's size
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* class.
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*/
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arena_run_t *runcur;
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/*
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* Tree of non-full runs. This tree is used when looking for an
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* existing run when runcur is no longer usable. We choose the
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* non-full run that is lowest in memory; this policy tends to keep
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* objects packed well, and it can also help reduce the number of
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* almost-empty chunks.
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*/
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arena_run_tree_t runs;
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/* Bin statistics. */
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malloc_bin_stats_t stats;
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};
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struct arena_s {
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/* This arena's index within the arenas array. */
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unsigned ind;
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/*
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* Number of threads currently assigned to this arena. This field is
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* protected by arenas_lock.
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*/
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unsigned nthreads;
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/*
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* There are three classes of arena operations from a locking
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* perspective:
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* 1) Thread asssignment (modifies nthreads) is protected by
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* arenas_lock.
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* 2) Bin-related operations are protected by bin locks.
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* 3) Chunk- and run-related operations are protected by this mutex.
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*/
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malloc_mutex_t lock;
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arena_stats_t stats;
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/*
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* List of tcaches for extant threads associated with this arena.
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* Stats from these are merged incrementally, and at exit.
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*/
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ql_head(tcache_t) tcache_ql;
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uint64_t prof_accumbytes;
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/* List of dirty-page-containing chunks this arena manages. */
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ql_head(arena_chunk_t) chunks_dirty;
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/*
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* In order to avoid rapid chunk allocation/deallocation when an arena
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* oscillates right on the cusp of needing a new chunk, cache the most
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* recently freed chunk. The spare is left in the arena's chunk trees
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* until it is deleted.
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*
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* There is one spare chunk per arena, rather than one spare total, in
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* order to avoid interactions between multiple threads that could make
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* a single spare inadequate.
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*/
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arena_chunk_t *spare;
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/* Number of pages in active runs. */
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size_t nactive;
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/*
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* Current count of pages within unused runs that are potentially
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* dirty, and for which madvise(... MADV_DONTNEED) has not been called.
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* By tracking this, we can institute a limit on how much dirty unused
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* memory is mapped for each arena.
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*/
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size_t ndirty;
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/*
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* Approximate number of pages being purged. It is possible for
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* multiple threads to purge dirty pages concurrently, and they use
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* npurgatory to indicate the total number of pages all threads are
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* attempting to purge.
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*/
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size_t npurgatory;
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/*
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* Size/address-ordered trees of this arena's available runs. The trees
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* are used for first-best-fit run allocation. The dirty tree contains
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* runs with dirty pages (i.e. very likely to have been touched and
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* therefore have associated physical pages), whereas the clean tree
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* contains runs with pages that either have no associated physical
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* pages, or have pages that the kernel may recycle at any time due to
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* previous madvise(2) calls. The dirty tree is used in preference to
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* the clean tree for allocations, because using dirty pages reduces
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* the amount of dirty purging necessary to keep the active:dirty page
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* ratio below the purge threshold.
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*/
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arena_avail_tree_t runs_avail_clean;
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arena_avail_tree_t runs_avail_dirty;
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/*
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* bins is used to store trees of free regions of the following sizes,
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* assuming a 64-bit system with 16-byte quantum, 4 KiB page size, and
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* default MALLOC_CONF.
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*
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* bins[i] | size |
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* --------+--------+
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* 0 | 8 |
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* --------+--------+
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* 1 | 16 |
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* 2 | 32 |
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* 3 | 48 |
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* : :
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* 6 | 96 |
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* 7 | 112 |
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* 8 | 128 |
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* --------+--------+
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* 9 | 192 |
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* 10 | 256 |
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* 11 | 320 |
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* 12 | 384 |
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* 13 | 448 |
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* 14 | 512 |
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* --------+--------+
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* 15 | 768 |
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* 16 | 1024 |
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* 17 | 1280 |
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* : :
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* 25 | 3328 |
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* 26 | 3584 |
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* 27 | 3840 |
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* --------+--------+
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*/
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arena_bin_t bins[1]; /* Dynamically sized. */
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};
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#endif /* JEMALLOC_H_STRUCTS */
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/******************************************************************************/
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#ifdef JEMALLOC_H_EXTERNS
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extern size_t opt_lg_qspace_max;
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extern size_t opt_lg_cspace_max;
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extern ssize_t opt_lg_dirty_mult;
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/*
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* small_size2bin is a compact lookup table that rounds request sizes up to
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* size classes. In order to reduce cache footprint, the table is compressed,
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* and all accesses are via the SMALL_SIZE2BIN macro.
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*/
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extern uint8_t const *small_size2bin;
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#define SMALL_SIZE2BIN(s) (small_size2bin[(s-1) >> LG_TINY_MIN])
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extern arena_bin_info_t *arena_bin_info;
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/* Various bin-related settings. */
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/* Number of (2^n)-spaced tiny bins. */
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#define ntbins ((unsigned)(LG_QUANTUM - LG_TINY_MIN))
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extern unsigned nqbins; /* Number of quantum-spaced bins. */
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extern unsigned ncbins; /* Number of cacheline-spaced bins. */
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extern unsigned nsbins; /* Number of subpage-spaced bins. */
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extern unsigned nbins;
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#define tspace_max ((size_t)(QUANTUM >> 1))
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#define qspace_min QUANTUM
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extern size_t qspace_max;
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extern size_t cspace_min;
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extern size_t cspace_max;
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extern size_t sspace_min;
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extern size_t sspace_max;
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#define small_maxclass sspace_max
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#define nlclasses (chunk_npages - map_bias)
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void arena_purge_all(arena_t *arena);
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void arena_prof_accum(arena_t *arena, uint64_t accumbytes);
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void arena_tcache_fill_small(arena_t *arena, tcache_bin_t *tbin,
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size_t binind, uint64_t prof_accumbytes);
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void *arena_malloc_small(arena_t *arena, size_t size, bool zero);
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void *arena_malloc_large(arena_t *arena, size_t size, bool zero);
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void *arena_palloc(arena_t *arena, size_t size, size_t alloc_size,
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size_t alignment, bool zero);
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size_t arena_salloc(const void *ptr);
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void arena_prof_promoted(const void *ptr, size_t size);
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size_t arena_salloc_demote(const void *ptr);
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void arena_dalloc_bin(arena_t *arena, arena_chunk_t *chunk, void *ptr,
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arena_chunk_map_t *mapelm);
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void arena_dalloc_large(arena_t *arena, arena_chunk_t *chunk, void *ptr);
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void arena_stats_merge(arena_t *arena, size_t *nactive, size_t *ndirty,
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arena_stats_t *astats, malloc_bin_stats_t *bstats,
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malloc_large_stats_t *lstats);
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void *arena_ralloc_no_move(void *ptr, size_t oldsize, size_t size,
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size_t extra, bool zero);
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void *arena_ralloc(void *ptr, size_t oldsize, size_t size, size_t extra,
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size_t alignment, bool zero);
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bool arena_new(arena_t *arena, unsigned ind);
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bool arena_boot(void);
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#endif /* JEMALLOC_H_EXTERNS */
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/******************************************************************************/
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#ifdef JEMALLOC_H_INLINES
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#ifndef JEMALLOC_ENABLE_INLINE
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size_t arena_bin_index(arena_t *arena, arena_bin_t *bin);
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unsigned arena_run_regind(arena_run_t *run, arena_bin_info_t *bin_info,
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const void *ptr);
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prof_ctx_t *arena_prof_ctx_get(const void *ptr);
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void arena_prof_ctx_set(const void *ptr, prof_ctx_t *ctx);
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void *arena_malloc(size_t size, bool zero);
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void arena_dalloc(arena_t *arena, arena_chunk_t *chunk, void *ptr);
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#endif
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#if (defined(JEMALLOC_ENABLE_INLINE) || defined(JEMALLOC_ARENA_C_))
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JEMALLOC_INLINE size_t
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arena_bin_index(arena_t *arena, arena_bin_t *bin)
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{
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size_t binind = bin - arena->bins;
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assert(binind < nbins);
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return (binind);
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}
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JEMALLOC_INLINE unsigned
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arena_run_regind(arena_run_t *run, arena_bin_info_t *bin_info, const void *ptr)
|
|
{
|
|
unsigned shift, diff, regind;
|
|
size_t size;
|
|
|
|
/*
|
|
* Freeing a pointer lower than region zero can cause assertion
|
|
* failure.
|
|
*/
|
|
assert((uintptr_t)ptr >= (uintptr_t)run +
|
|
(uintptr_t)bin_info->reg0_offset);
|
|
|
|
/*
|
|
* Avoid doing division with a variable divisor if possible. Using
|
|
* actual division here can reduce allocator throughput by over 20%!
|
|
*/
|
|
diff = (unsigned)((uintptr_t)ptr - (uintptr_t)run -
|
|
bin_info->reg0_offset);
|
|
|
|
/* Rescale (factor powers of 2 out of the numerator and denominator). */
|
|
size = bin_info->reg_size;
|
|
shift = ffs(size) - 1;
|
|
diff >>= shift;
|
|
size >>= shift;
|
|
|
|
if (size == 1) {
|
|
/* The divisor was a power of 2. */
|
|
regind = diff;
|
|
} else {
|
|
/*
|
|
* To divide by a number D that is not a power of two we
|
|
* multiply by (2^21 / D) and then right shift by 21 positions.
|
|
*
|
|
* X / D
|
|
*
|
|
* becomes
|
|
*
|
|
* (X * size_invs[D - 3]) >> SIZE_INV_SHIFT
|
|
*
|
|
* We can omit the first three elements, because we never
|
|
* divide by 0, and 1 and 2 are both powers of two, which are
|
|
* handled above.
|
|
*/
|
|
#define SIZE_INV_SHIFT ((sizeof(unsigned) << 3) - LG_RUN_MAXREGS)
|
|
#define SIZE_INV(s) (((1U << SIZE_INV_SHIFT) / (s)) + 1)
|
|
static const unsigned size_invs[] = {
|
|
SIZE_INV(3),
|
|
SIZE_INV(4), SIZE_INV(5), SIZE_INV(6), SIZE_INV(7),
|
|
SIZE_INV(8), SIZE_INV(9), SIZE_INV(10), SIZE_INV(11),
|
|
SIZE_INV(12), SIZE_INV(13), SIZE_INV(14), SIZE_INV(15),
|
|
SIZE_INV(16), SIZE_INV(17), SIZE_INV(18), SIZE_INV(19),
|
|
SIZE_INV(20), SIZE_INV(21), SIZE_INV(22), SIZE_INV(23),
|
|
SIZE_INV(24), SIZE_INV(25), SIZE_INV(26), SIZE_INV(27),
|
|
SIZE_INV(28), SIZE_INV(29), SIZE_INV(30), SIZE_INV(31)
|
|
};
|
|
|
|
if (size <= ((sizeof(size_invs) / sizeof(unsigned)) + 2))
|
|
regind = (diff * size_invs[size - 3]) >> SIZE_INV_SHIFT;
|
|
else
|
|
regind = diff / size;
|
|
#undef SIZE_INV
|
|
#undef SIZE_INV_SHIFT
|
|
}
|
|
assert(diff == regind * size);
|
|
assert(regind < bin_info->nregs);
|
|
|
|
return (regind);
|
|
}
|
|
|
|
JEMALLOC_INLINE prof_ctx_t *
|
|
arena_prof_ctx_get(const void *ptr)
|
|
{
|
|
prof_ctx_t *ret;
|
|
arena_chunk_t *chunk;
|
|
size_t pageind, mapbits;
|
|
|
|
cassert(config_prof);
|
|
assert(ptr != NULL);
|
|
assert(CHUNK_ADDR2BASE(ptr) != ptr);
|
|
|
|
chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ptr);
|
|
pageind = ((uintptr_t)ptr - (uintptr_t)chunk) >> PAGE_SHIFT;
|
|
mapbits = chunk->map[pageind-map_bias].bits;
|
|
assert((mapbits & CHUNK_MAP_ALLOCATED) != 0);
|
|
if ((mapbits & CHUNK_MAP_LARGE) == 0) {
|
|
if (prof_promote)
|
|
ret = (prof_ctx_t *)(uintptr_t)1U;
|
|
else {
|
|
arena_run_t *run = (arena_run_t *)((uintptr_t)chunk +
|
|
(uintptr_t)((pageind - (mapbits >> PAGE_SHIFT)) <<
|
|
PAGE_SHIFT));
|
|
size_t binind = arena_bin_index(chunk->arena, run->bin);
|
|
arena_bin_info_t *bin_info = &arena_bin_info[binind];
|
|
unsigned regind;
|
|
|
|
regind = arena_run_regind(run, bin_info, ptr);
|
|
ret = *(prof_ctx_t **)((uintptr_t)run +
|
|
bin_info->ctx0_offset + (regind *
|
|
sizeof(prof_ctx_t *)));
|
|
}
|
|
} else
|
|
ret = chunk->map[pageind-map_bias].prof_ctx;
|
|
|
|
return (ret);
|
|
}
|
|
|
|
JEMALLOC_INLINE void
|
|
arena_prof_ctx_set(const void *ptr, prof_ctx_t *ctx)
|
|
{
|
|
arena_chunk_t *chunk;
|
|
size_t pageind, mapbits;
|
|
|
|
cassert(config_prof);
|
|
assert(ptr != NULL);
|
|
assert(CHUNK_ADDR2BASE(ptr) != ptr);
|
|
|
|
chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ptr);
|
|
pageind = ((uintptr_t)ptr - (uintptr_t)chunk) >> PAGE_SHIFT;
|
|
mapbits = chunk->map[pageind-map_bias].bits;
|
|
assert((mapbits & CHUNK_MAP_ALLOCATED) != 0);
|
|
if ((mapbits & CHUNK_MAP_LARGE) == 0) {
|
|
if (prof_promote == false) {
|
|
arena_run_t *run = (arena_run_t *)((uintptr_t)chunk +
|
|
(uintptr_t)((pageind - (mapbits >> PAGE_SHIFT)) <<
|
|
PAGE_SHIFT));
|
|
arena_bin_t *bin = run->bin;
|
|
size_t binind;
|
|
arena_bin_info_t *bin_info;
|
|
unsigned regind;
|
|
|
|
binind = arena_bin_index(chunk->arena, bin);
|
|
bin_info = &arena_bin_info[binind];
|
|
regind = arena_run_regind(run, bin_info, ptr);
|
|
|
|
*((prof_ctx_t **)((uintptr_t)run + bin_info->ctx0_offset
|
|
+ (regind * sizeof(prof_ctx_t *)))) = ctx;
|
|
} else
|
|
assert((uintptr_t)ctx == (uintptr_t)1U);
|
|
} else
|
|
chunk->map[pageind-map_bias].prof_ctx = ctx;
|
|
}
|
|
|
|
JEMALLOC_INLINE void *
|
|
arena_malloc(size_t size, bool zero)
|
|
{
|
|
tcache_t *tcache;
|
|
|
|
assert(size != 0);
|
|
assert(QUANTUM_CEILING(size) <= arena_maxclass);
|
|
|
|
if (size <= small_maxclass) {
|
|
if ((tcache = tcache_get()) != NULL)
|
|
return (tcache_alloc_small(tcache, size, zero));
|
|
else
|
|
return (arena_malloc_small(choose_arena(), size, zero));
|
|
} else {
|
|
/*
|
|
* Initialize tcache after checking size in order to avoid
|
|
* infinite recursion during tcache initialization.
|
|
*/
|
|
if (size <= tcache_maxclass && (tcache = tcache_get()) != NULL)
|
|
return (tcache_alloc_large(tcache, size, zero));
|
|
else
|
|
return (arena_malloc_large(choose_arena(), size, zero));
|
|
}
|
|
}
|
|
|
|
JEMALLOC_INLINE void
|
|
arena_dalloc(arena_t *arena, arena_chunk_t *chunk, void *ptr)
|
|
{
|
|
size_t pageind;
|
|
arena_chunk_map_t *mapelm;
|
|
tcache_t *tcache = tcache_get();
|
|
|
|
assert(arena != NULL);
|
|
assert(chunk->arena == arena);
|
|
assert(ptr != NULL);
|
|
assert(CHUNK_ADDR2BASE(ptr) != ptr);
|
|
|
|
pageind = ((uintptr_t)ptr - (uintptr_t)chunk) >> PAGE_SHIFT;
|
|
mapelm = &chunk->map[pageind-map_bias];
|
|
assert((mapelm->bits & CHUNK_MAP_ALLOCATED) != 0);
|
|
if ((mapelm->bits & CHUNK_MAP_LARGE) == 0) {
|
|
/* Small allocation. */
|
|
if (tcache != NULL)
|
|
tcache_dalloc_small(tcache, ptr);
|
|
else {
|
|
arena_run_t *run;
|
|
arena_bin_t *bin;
|
|
|
|
run = (arena_run_t *)((uintptr_t)chunk +
|
|
(uintptr_t)((pageind - (mapelm->bits >>
|
|
PAGE_SHIFT)) << PAGE_SHIFT));
|
|
bin = run->bin;
|
|
if (config_debug) {
|
|
size_t binind = arena_bin_index(arena, bin);
|
|
UNUSED arena_bin_info_t *bin_info =
|
|
&arena_bin_info[binind];
|
|
assert(((uintptr_t)ptr - ((uintptr_t)run +
|
|
(uintptr_t)bin_info->reg0_offset)) %
|
|
bin_info->reg_size == 0);
|
|
}
|
|
malloc_mutex_lock(&bin->lock);
|
|
arena_dalloc_bin(arena, chunk, ptr, mapelm);
|
|
malloc_mutex_unlock(&bin->lock);
|
|
}
|
|
} else {
|
|
size_t size = mapelm->bits & ~PAGE_MASK;
|
|
|
|
assert(((uintptr_t)ptr & PAGE_MASK) == 0);
|
|
|
|
if (size <= tcache_maxclass && tcache != NULL) {
|
|
tcache_dalloc_large(tcache, ptr, size);
|
|
} else {
|
|
malloc_mutex_lock(&arena->lock);
|
|
arena_dalloc_large(arena, chunk, ptr);
|
|
malloc_mutex_unlock(&arena->lock);
|
|
}
|
|
}
|
|
}
|
|
#endif
|
|
|
|
#endif /* JEMALLOC_H_INLINES */
|
|
/******************************************************************************/
|