server-skynet-source-3rd-je.../jemalloc/src/arena.c

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#define JEMALLOC_ARENA_C_
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#include "jemalloc/internal/jemalloc_internal.h"
/******************************************************************************/
/* Data. */
size_t opt_lg_qspace_max = LG_QSPACE_MAX_DEFAULT;
size_t opt_lg_cspace_max = LG_CSPACE_MAX_DEFAULT;
ssize_t opt_lg_dirty_mult = LG_DIRTY_MULT_DEFAULT;
uint8_t const *small_size2bin;
/* Various bin-related settings. */
unsigned nqbins;
unsigned ncbins;
unsigned nsbins;
unsigned nbins;
size_t qspace_max;
size_t cspace_min;
size_t cspace_max;
size_t sspace_min;
size_t sspace_max;
size_t lg_mspace;
size_t mspace_mask;
/*
* const_small_size2bin is a static constant lookup table that in the common
* case can be used as-is for small_size2bin. For dynamically linked programs,
* this avoids a page of memory overhead per process.
*/
#define S2B_1(i) i,
#define S2B_2(i) S2B_1(i) S2B_1(i)
#define S2B_4(i) S2B_2(i) S2B_2(i)
#define S2B_8(i) S2B_4(i) S2B_4(i)
#define S2B_16(i) S2B_8(i) S2B_8(i)
#define S2B_32(i) S2B_16(i) S2B_16(i)
#define S2B_64(i) S2B_32(i) S2B_32(i)
#define S2B_128(i) S2B_64(i) S2B_64(i)
#define S2B_256(i) S2B_128(i) S2B_128(i)
/*
* The number of elements in const_small_size2bin is dependent on page size
* and on the definition for SUBPAGE. If SUBPAGE changes, the '- 255' must also
* change, along with the addition/removal of static lookup table element
* definitions.
*/
static const uint8_t const_small_size2bin[STATIC_PAGE_SIZE - 255] = {
S2B_1(0xffU) /* 0 */
#if (LG_QUANTUM == 4)
/* 16-byte quantum **********************/
# ifdef JEMALLOC_TINY
# if (LG_TINY_MIN == 2)
S2B_4(0) /* 4 */
S2B_4(1) /* 8 */
S2B_8(2) /* 16 */
# define S2B_QMIN 2
# elif (LG_TINY_MIN == 3)
S2B_8(0) /* 8 */
S2B_8(1) /* 16 */
# define S2B_QMIN 1
# else
# error "Unsupported LG_TINY_MIN"
# endif
# else
S2B_16(0) /* 16 */
# define S2B_QMIN 0
# endif
S2B_16(S2B_QMIN + 1) /* 32 */
S2B_16(S2B_QMIN + 2) /* 48 */
S2B_16(S2B_QMIN + 3) /* 64 */
S2B_16(S2B_QMIN + 4) /* 80 */
S2B_16(S2B_QMIN + 5) /* 96 */
S2B_16(S2B_QMIN + 6) /* 112 */
S2B_16(S2B_QMIN + 7) /* 128 */
# define S2B_CMIN (S2B_QMIN + 8)
#else
/* 8-byte quantum ***********************/
# ifdef JEMALLOC_TINY
# if (LG_TINY_MIN == 2)
S2B_4(0) /* 4 */
S2B_4(1) /* 8 */
# define S2B_QMIN 1
# else
# error "Unsupported LG_TINY_MIN"
# endif
# else
S2B_8(0) /* 8 */
# define S2B_QMIN 0
# endif
S2B_8(S2B_QMIN + 1) /* 16 */
S2B_8(S2B_QMIN + 2) /* 24 */
S2B_8(S2B_QMIN + 3) /* 32 */
S2B_8(S2B_QMIN + 4) /* 40 */
S2B_8(S2B_QMIN + 5) /* 48 */
S2B_8(S2B_QMIN + 6) /* 56 */
S2B_8(S2B_QMIN + 7) /* 64 */
S2B_8(S2B_QMIN + 8) /* 72 */
S2B_8(S2B_QMIN + 9) /* 80 */
S2B_8(S2B_QMIN + 10) /* 88 */
S2B_8(S2B_QMIN + 11) /* 96 */
S2B_8(S2B_QMIN + 12) /* 104 */
S2B_8(S2B_QMIN + 13) /* 112 */
S2B_8(S2B_QMIN + 14) /* 120 */
S2B_8(S2B_QMIN + 15) /* 128 */
# define S2B_CMIN (S2B_QMIN + 16)
#endif
/****************************************/
S2B_64(S2B_CMIN + 0) /* 192 */
S2B_64(S2B_CMIN + 1) /* 256 */
S2B_64(S2B_CMIN + 2) /* 320 */
S2B_64(S2B_CMIN + 3) /* 384 */
S2B_64(S2B_CMIN + 4) /* 448 */
S2B_64(S2B_CMIN + 5) /* 512 */
# define S2B_SMIN (S2B_CMIN + 6)
S2B_256(S2B_SMIN + 0) /* 768 */
S2B_256(S2B_SMIN + 1) /* 1024 */
S2B_256(S2B_SMIN + 2) /* 1280 */
S2B_256(S2B_SMIN + 3) /* 1536 */
S2B_256(S2B_SMIN + 4) /* 1792 */
S2B_256(S2B_SMIN + 5) /* 2048 */
S2B_256(S2B_SMIN + 6) /* 2304 */
S2B_256(S2B_SMIN + 7) /* 2560 */
S2B_256(S2B_SMIN + 8) /* 2816 */
S2B_256(S2B_SMIN + 9) /* 3072 */
S2B_256(S2B_SMIN + 10) /* 3328 */
S2B_256(S2B_SMIN + 11) /* 3584 */
S2B_256(S2B_SMIN + 12) /* 3840 */
#if (STATIC_PAGE_SHIFT == 13)
S2B_256(S2B_SMIN + 13) /* 4096 */
S2B_256(S2B_SMIN + 14) /* 4352 */
S2B_256(S2B_SMIN + 15) /* 4608 */
S2B_256(S2B_SMIN + 16) /* 4864 */
S2B_256(S2B_SMIN + 17) /* 5120 */
S2B_256(S2B_SMIN + 18) /* 5376 */
S2B_256(S2B_SMIN + 19) /* 5632 */
S2B_256(S2B_SMIN + 20) /* 5888 */
S2B_256(S2B_SMIN + 21) /* 6144 */
S2B_256(S2B_SMIN + 22) /* 6400 */
S2B_256(S2B_SMIN + 23) /* 6656 */
S2B_256(S2B_SMIN + 24) /* 6912 */
S2B_256(S2B_SMIN + 25) /* 7168 */
S2B_256(S2B_SMIN + 26) /* 7424 */
S2B_256(S2B_SMIN + 27) /* 7680 */
S2B_256(S2B_SMIN + 28) /* 7936 */
#endif
};
#undef S2B_1
#undef S2B_2
#undef S2B_4
#undef S2B_8
#undef S2B_16
#undef S2B_32
#undef S2B_64
#undef S2B_128
#undef S2B_256
#undef S2B_QMIN
#undef S2B_CMIN
#undef S2B_SMIN
/******************************************************************************/
/* Function prototypes for non-inline static functions. */
static void arena_run_split(arena_t *arena, arena_run_t *run, size_t size,
bool large, bool zero);
static arena_chunk_t *arena_chunk_alloc(arena_t *arena);
static void arena_chunk_dealloc(arena_t *arena, arena_chunk_t *chunk);
static arena_run_t *arena_run_alloc(arena_t *arena, size_t size, bool large,
bool zero);
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static void arena_purge(arena_t *arena, bool all);
static void arena_run_dalloc(arena_t *arena, arena_run_t *run, bool dirty);
static void arena_run_trim_head(arena_t *arena, arena_chunk_t *chunk,
arena_run_t *run, size_t oldsize, size_t newsize);
static void arena_run_trim_tail(arena_t *arena, arena_chunk_t *chunk,
arena_run_t *run, size_t oldsize, size_t newsize, bool dirty);
static arena_run_t *arena_bin_nonfull_run_get(arena_t *arena, arena_bin_t *bin);
static void *arena_bin_malloc_hard(arena_t *arena, arena_bin_t *bin);
static size_t arena_bin_run_size_calc(arena_bin_t *bin, size_t min_run_size);
static void arena_dalloc_bin_run(arena_t *arena, arena_chunk_t *chunk,
arena_run_t *run, arena_bin_t *bin);
static void arena_ralloc_large_shrink(arena_t *arena, arena_chunk_t *chunk,
void *ptr, size_t oldsize, size_t size);
static bool arena_ralloc_large_grow(arena_t *arena, arena_chunk_t *chunk,
void *ptr, size_t oldsize, size_t size, size_t extra, bool zero);
static bool arena_ralloc_large(void *ptr, size_t oldsize, size_t size,
size_t extra, bool zero);
static bool small_size2bin_init(void);
#ifdef JEMALLOC_DEBUG
static void small_size2bin_validate(void);
#endif
static bool small_size2bin_init_hard(void);
/******************************************************************************/
static inline int
arena_run_comp(arena_chunk_map_t *a, arena_chunk_map_t *b)
{
uintptr_t a_mapelm = (uintptr_t)a;
uintptr_t b_mapelm = (uintptr_t)b;
assert(a != NULL);
assert(b != NULL);
return ((a_mapelm > b_mapelm) - (a_mapelm < b_mapelm));
}
/* Generate red-black tree functions. */
rb_gen(static JEMALLOC_ATTR(unused), arena_run_tree_, arena_run_tree_t,
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arena_chunk_map_t, u.rb_link, arena_run_comp)
static inline int
arena_avail_comp(arena_chunk_map_t *a, arena_chunk_map_t *b)
{
int ret;
size_t a_size = a->bits & ~PAGE_MASK;
size_t b_size = b->bits & ~PAGE_MASK;
assert((a->bits & CHUNK_MAP_KEY) == CHUNK_MAP_KEY || (a->bits &
CHUNK_MAP_DIRTY) == (b->bits & CHUNK_MAP_DIRTY));
ret = (a_size > b_size) - (a_size < b_size);
if (ret == 0) {
uintptr_t a_mapelm, b_mapelm;
if ((a->bits & CHUNK_MAP_KEY) != CHUNK_MAP_KEY)
a_mapelm = (uintptr_t)a;
else {
/*
* Treat keys as though they are lower than anything
* else.
*/
a_mapelm = 0;
}
b_mapelm = (uintptr_t)b;
ret = (a_mapelm > b_mapelm) - (a_mapelm < b_mapelm);
}
return (ret);
}
/* Generate red-black tree functions. */
rb_gen(static JEMALLOC_ATTR(unused), arena_avail_tree_, arena_avail_tree_t,
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arena_chunk_map_t, u.rb_link, arena_avail_comp)
static inline void *
arena_run_reg_alloc(arena_run_t *run, arena_bin_t *bin)
{
void *ret;
assert(run->magic == ARENA_RUN_MAGIC);
assert(run->nfree > 0);
run->nfree--;
ret = run->avail;
if (ret != NULL) {
/* Double free can cause assertion failure.*/
assert(ret != NULL);
/* Write-after free can cause assertion failure. */
assert((uintptr_t)ret >= (uintptr_t)run +
(uintptr_t)bin->reg0_offset);
assert((uintptr_t)ret < (uintptr_t)run->next);
assert(((uintptr_t)ret - ((uintptr_t)run +
(uintptr_t)bin->reg0_offset)) % (uintptr_t)bin->reg_size ==
0);
run->avail = *(void **)ret;
return (ret);
}
ret = run->next;
run->next = (void *)((uintptr_t)ret + (uintptr_t)bin->reg_size);
assert(ret != NULL);
return (ret);
}
static inline void
arena_run_reg_dalloc(arena_run_t *run, void *ptr)
{
assert(run->nfree < run->bin->nregs);
/* Freeing an interior pointer can cause assertion failure. */
assert(((uintptr_t)ptr - ((uintptr_t)run +
(uintptr_t)run->bin->reg0_offset)) % (uintptr_t)run->bin->reg_size
== 0);
*(void **)ptr = run->avail;
run->avail = ptr;
run->nfree++;
}
static void
arena_run_split(arena_t *arena, arena_run_t *run, size_t size, bool large,
bool zero)
{
arena_chunk_t *chunk;
size_t old_ndirty, run_ind, total_pages, need_pages, rem_pages, i;
size_t flag_dirty;
arena_avail_tree_t *runs_avail;
chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(run);
old_ndirty = chunk->ndirty;
run_ind = (unsigned)(((uintptr_t)run - (uintptr_t)chunk)
>> PAGE_SHIFT);
flag_dirty = chunk->map[run_ind].bits & CHUNK_MAP_DIRTY;
runs_avail = (flag_dirty != 0) ? &arena->runs_avail_dirty :
&arena->runs_avail_clean;
total_pages = (chunk->map[run_ind].bits & ~PAGE_MASK) >>
PAGE_SHIFT;
assert((chunk->map[run_ind+total_pages-1].bits & CHUNK_MAP_DIRTY) ==
flag_dirty);
need_pages = (size >> PAGE_SHIFT);
assert(need_pages > 0);
assert(need_pages <= total_pages);
rem_pages = total_pages - need_pages;
arena_avail_tree_remove(runs_avail, &chunk->map[run_ind]);
arena->nactive += need_pages;
/* Keep track of trailing unused pages for later use. */
if (rem_pages > 0) {
if (flag_dirty != 0) {
chunk->map[run_ind+need_pages].bits = (rem_pages <<
PAGE_SHIFT) | CHUNK_MAP_DIRTY;
chunk->map[run_ind+total_pages-1].bits = (rem_pages <<
PAGE_SHIFT) | CHUNK_MAP_DIRTY;
} else {
chunk->map[run_ind+need_pages].bits = (rem_pages <<
PAGE_SHIFT) | (chunk->map[run_ind+need_pages].bits &
CHUNK_MAP_ZEROED);
chunk->map[run_ind+total_pages-1].bits = (rem_pages <<
PAGE_SHIFT) |
(chunk->map[run_ind+total_pages-1].bits &
CHUNK_MAP_ZEROED);
}
arena_avail_tree_insert(runs_avail,
&chunk->map[run_ind+need_pages]);
}
/* Update dirty page accounting. */
if (flag_dirty != 0) {
chunk->ndirty -= need_pages;
arena->ndirty -= need_pages;
}
/*
* Update the page map separately for large vs. small runs, since it is
* possible to avoid iteration for large mallocs.
*/
if (large) {
if (zero) {
if (flag_dirty == 0) {
/*
* The run is clean, so some pages may be
* zeroed (i.e. never before touched).
*/
for (i = 0; i < need_pages; i++) {
if ((chunk->map[run_ind + i].bits &
CHUNK_MAP_ZEROED) == 0) {
memset((void *)((uintptr_t)
chunk + ((run_ind + i) <<
PAGE_SHIFT)), 0,
PAGE_SIZE);
}
}
} else {
/*
* The run is dirty, so all pages must be
* zeroed.
*/
memset((void *)((uintptr_t)chunk + (run_ind <<
PAGE_SHIFT)), 0, (need_pages <<
PAGE_SHIFT));
}
}
/*
* Set the last element first, in case the run only contains one
* page (i.e. both statements set the same element).
*/
chunk->map[run_ind+need_pages-1].bits = CHUNK_MAP_LARGE |
CHUNK_MAP_ALLOCATED | flag_dirty;
chunk->map[run_ind].bits = size | CHUNK_MAP_LARGE |
#ifdef JEMALLOC_PROF
CHUNK_MAP_CLASS_MASK |
#endif
CHUNK_MAP_ALLOCATED | flag_dirty;
} else {
assert(zero == false);
/*
* Propagate the dirty flag to the allocated small run, so that
* arena_dalloc_bin_run() has the ability to conditionally trim
* clean pages.
*/
chunk->map[run_ind].bits = CHUNK_MAP_ALLOCATED | flag_dirty;
for (i = 1; i < need_pages - 1; i++) {
chunk->map[run_ind + i].bits = (i << PAGE_SHIFT)
| CHUNK_MAP_ALLOCATED;
}
chunk->map[run_ind + need_pages - 1].bits = ((need_pages - 1) <<
PAGE_SHIFT) | CHUNK_MAP_ALLOCATED | flag_dirty;
}
}
static arena_chunk_t *
arena_chunk_alloc(arena_t *arena)
{
arena_chunk_t *chunk;
size_t i;
if (arena->spare != NULL) {
arena_avail_tree_t *runs_avail;
chunk = arena->spare;
arena->spare = NULL;
/* Insert the run into the appropriate runs_avail_* tree. */
if ((chunk->map[arena_chunk_header_npages].bits &
CHUNK_MAP_DIRTY) == 0)
runs_avail = &arena->runs_avail_clean;
else
runs_avail = &arena->runs_avail_dirty;
arena_avail_tree_insert(runs_avail,
&chunk->map[arena_chunk_header_npages]);
} else {
bool zero;
size_t zeroed;
zero = false;
malloc_mutex_unlock(&arena->lock);
chunk = (arena_chunk_t *)chunk_alloc(chunksize, false, &zero);
malloc_mutex_lock(&arena->lock);
if (chunk == NULL)
return (NULL);
#ifdef JEMALLOC_STATS
arena->stats.mapped += chunksize;
#endif
chunk->arena = arena;
ql_elm_new(chunk, link_dirty);
chunk->dirtied = false;
/*
* Claim that no pages are in use, since the header is merely
* overhead.
*/
chunk->ndirty = 0;
/*
* Initialize the map to contain one maximal free untouched run.
* Mark the pages as zeroed iff chunk_alloc() returned a zeroed
* chunk.
*/
zeroed = zero ? CHUNK_MAP_ZEROED : 0;
for (i = 0; i < arena_chunk_header_npages; i++)
chunk->map[i].bits = 0;
chunk->map[i].bits = arena_maxclass | zeroed;
for (i++; i < chunk_npages-1; i++)
chunk->map[i].bits = zeroed;
chunk->map[chunk_npages-1].bits = arena_maxclass | zeroed;
/* Insert the run into the runs_avail_clean tree. */
arena_avail_tree_insert(&arena->runs_avail_clean,
&chunk->map[arena_chunk_header_npages]);
}
return (chunk);
}
static void
arena_chunk_dealloc(arena_t *arena, arena_chunk_t *chunk)
{
arena_avail_tree_t *runs_avail;
/*
* Remove run from the appropriate runs_avail_* tree, so that the arena
* does not use it.
*/
if ((chunk->map[arena_chunk_header_npages].bits &
CHUNK_MAP_DIRTY) == 0)
runs_avail = &arena->runs_avail_clean;
else
runs_avail = &arena->runs_avail_dirty;
arena_avail_tree_remove(runs_avail,
&chunk->map[arena_chunk_header_npages]);
if (arena->spare != NULL) {
arena_chunk_t *spare = arena->spare;
arena->spare = chunk;
if (spare->dirtied) {
ql_remove(&chunk->arena->chunks_dirty, spare,
link_dirty);
arena->ndirty -= spare->ndirty;
}
malloc_mutex_unlock(&arena->lock);
chunk_dealloc((void *)spare, chunksize);
malloc_mutex_lock(&arena->lock);
#ifdef JEMALLOC_STATS
arena->stats.mapped -= chunksize;
#endif
} else
arena->spare = chunk;
}
static arena_run_t *
arena_run_alloc(arena_t *arena, size_t size, bool large, bool zero)
{
arena_chunk_t *chunk;
arena_run_t *run;
arena_chunk_map_t *mapelm, key;
assert(size <= arena_maxclass);
assert((size & PAGE_MASK) == 0);
/* Search the arena's chunks for the lowest best fit. */
key.bits = size | CHUNK_MAP_KEY;
mapelm = arena_avail_tree_nsearch(&arena->runs_avail_dirty, &key);
if (mapelm != NULL) {
arena_chunk_t *run_chunk = CHUNK_ADDR2BASE(mapelm);
size_t pageind = ((uintptr_t)mapelm - (uintptr_t)run_chunk->map)
/ sizeof(arena_chunk_map_t);
run = (arena_run_t *)((uintptr_t)run_chunk + (pageind <<
PAGE_SHIFT));
arena_run_split(arena, run, size, large, zero);
return (run);
}
mapelm = arena_avail_tree_nsearch(&arena->runs_avail_clean, &key);
if (mapelm != NULL) {
arena_chunk_t *run_chunk = CHUNK_ADDR2BASE(mapelm);
size_t pageind = ((uintptr_t)mapelm - (uintptr_t)run_chunk->map)
/ sizeof(arena_chunk_map_t);
run = (arena_run_t *)((uintptr_t)run_chunk + (pageind <<
PAGE_SHIFT));
arena_run_split(arena, run, size, large, zero);
return (run);
}
/*
* No usable runs. Create a new chunk from which to allocate the run.
*/
chunk = arena_chunk_alloc(arena);
if (chunk != NULL) {
run = (arena_run_t *)((uintptr_t)chunk +
(arena_chunk_header_npages << PAGE_SHIFT));
arena_run_split(arena, run, size, large, zero);
return (run);
}
/*
* arena_chunk_alloc() failed, but another thread may have made
* sufficient memory available while this one dropped arena->lock in
* arena_chunk_alloc(), so search one more time.
*/
mapelm = arena_avail_tree_nsearch(&arena->runs_avail_dirty, &key);
if (mapelm != NULL) {
arena_chunk_t *run_chunk = CHUNK_ADDR2BASE(mapelm);
size_t pageind = ((uintptr_t)mapelm - (uintptr_t)run_chunk->map)
/ sizeof(arena_chunk_map_t);
run = (arena_run_t *)((uintptr_t)run_chunk + (pageind <<
PAGE_SHIFT));
arena_run_split(arena, run, size, large, zero);
return (run);
}
mapelm = arena_avail_tree_nsearch(&arena->runs_avail_clean, &key);
if (mapelm != NULL) {
arena_chunk_t *run_chunk = CHUNK_ADDR2BASE(mapelm);
size_t pageind = ((uintptr_t)mapelm - (uintptr_t)run_chunk->map)
/ sizeof(arena_chunk_map_t);
run = (arena_run_t *)((uintptr_t)run_chunk + (pageind <<
PAGE_SHIFT));
arena_run_split(arena, run, size, large, zero);
return (run);
}
return (NULL);
}
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static inline void
arena_maybe_purge(arena_t *arena)
{
/* Enforce opt_lg_dirty_mult. */
if (opt_lg_dirty_mult >= 0 && arena->ndirty > arena->npurgatory &&
(arena->ndirty - arena->npurgatory) > chunk_npages &&
(arena->nactive >> opt_lg_dirty_mult) < (arena->ndirty -
arena->npurgatory))
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arena_purge(arena, false);
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}
static inline void
arena_chunk_purge(arena_t *arena, arena_chunk_t *chunk)
{
ql_head(arena_chunk_map_t) mapelms;
arena_chunk_map_t *mapelm;
size_t pageind, flag_zeroed;
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#ifdef JEMALLOC_DEBUG
size_t ndirty;
#endif
#ifdef JEMALLOC_STATS
size_t nmadvise;
#endif
ql_new(&mapelms);
flag_zeroed =
#ifdef JEMALLOC_PURGE_MADVISE_DONTNEED
/*
* madvise(..., MADV_DONTNEED) results in zero-filled pages for anonymous
* mappings, but not for file-backed mappings.
*/
# ifdef JEMALLOC_SWAP
swap_enabled ? 0 :
# endif
CHUNK_MAP_ZEROED;
#else
0;
#endif
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/*
* If chunk is the spare, temporarily re-allocate it, 1) so that its
* run is reinserted into runs_avail_dirty, and 2) so that it cannot be
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* completely discarded by another thread while arena->lock is dropped
* by this thread. Note that the arena_run_dalloc() call will
* implicitly deallocate the chunk, so no explicit action is required
* in this function to deallocate the chunk.
*
* Note that once a chunk contains dirty pages, it cannot again contain
* a single run unless 1) it is a dirty run, or 2) this function purges
* dirty pages and causes the transition to a single clean run. Thus
* (chunk == arena->spare) is possible, but it is not possible for
* this function to be called on the spare unless it contains a dirty
* run.
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*/
if (chunk == arena->spare) {
assert((chunk->map[arena_chunk_header_npages].bits &
CHUNK_MAP_DIRTY) != 0);
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arena_chunk_alloc(arena);
}
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/* Temporarily allocate all free dirty runs within chunk. */
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for (pageind = arena_chunk_header_npages; pageind < chunk_npages;) {
mapelm = &chunk->map[pageind];
if ((mapelm->bits & CHUNK_MAP_ALLOCATED) == 0) {
size_t npages;
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npages = mapelm->bits >> PAGE_SHIFT;
assert(pageind + npages <= chunk_npages);
if (mapelm->bits & CHUNK_MAP_DIRTY) {
size_t i;
arena_avail_tree_remove(
&arena->runs_avail_dirty, mapelm);
/*
* Update internal elements in the page map, so
* that CHUNK_MAP_ZEROED is properly set.
*/
mapelm->bits = (npages << PAGE_SHIFT) |
CHUNK_MAP_LARGE | CHUNK_MAP_ALLOCATED |
flag_zeroed;
for (i = 1; i < npages - 1; i++) {
chunk->map[pageind + i].bits =
flag_zeroed;
}
if (npages > 1) {
chunk->map[pageind + npages - 1].bits =
(npages << PAGE_SHIFT) |
CHUNK_MAP_LARGE | CHUNK_MAP_ALLOCATED |
flag_zeroed;
}
arena->nactive += npages;
/* Append to list for later processing. */
ql_elm_new(mapelm, u.ql_link);
ql_tail_insert(&mapelms, mapelm, u.ql_link);
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}
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pageind += npages;
} else {
/* Skip allocated run. */
if (mapelm->bits & CHUNK_MAP_LARGE)
pageind += mapelm->bits >> PAGE_SHIFT;
else {
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arena_run_t *run = (arena_run_t *)((uintptr_t)
chunk + (uintptr_t)(pageind << PAGE_SHIFT));
assert((mapelm->bits >> PAGE_SHIFT) == 0);
assert(run->magic == ARENA_RUN_MAGIC);
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pageind += run->bin->run_size >> PAGE_SHIFT;
}
}
}
assert(pageind == chunk_npages);
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#ifdef JEMALLOC_DEBUG
ndirty = chunk->ndirty;
#endif
#ifdef JEMALLOC_STATS
arena->stats.purged += chunk->ndirty;
#endif
arena->ndirty -= chunk->ndirty;
chunk->ndirty = 0;
ql_remove(&arena->chunks_dirty, chunk, link_dirty);
chunk->dirtied = false;
malloc_mutex_unlock(&arena->lock);
#ifdef JEMALLOC_STATS
nmadvise = 0;
#endif
ql_foreach(mapelm, &mapelms, u.ql_link) {
size_t pageind = ((uintptr_t)mapelm - (uintptr_t)chunk->map) /
sizeof(arena_chunk_map_t);
size_t npages = mapelm->bits >> PAGE_SHIFT;
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assert(pageind + npages <= chunk_npages);
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#ifdef JEMALLOC_DEBUG
assert(ndirty >= npages);
ndirty -= npages;
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#endif
#ifdef JEMALLOC_PURGE_MADVISE_DONTNEED
madvise((void *)((uintptr_t)chunk + (pageind << PAGE_SHIFT)),
(npages << PAGE_SHIFT), MADV_DONTNEED);
#elif defined(JEMALLOC_PURGE_MADVISE_FREE)
madvise((void *)((uintptr_t)chunk + (pageind << PAGE_SHIFT)),
(npages << PAGE_SHIFT), MADV_FREE);
#elif defined(JEMALLOC_PURGE_MSYNC_KILLPAGES)
msync((void *)((uintptr_t)chunk + (pageind << PAGE_SHIFT)),
(npages << PAGE_SHIFT), MS_KILLPAGES);
#else
# error "No method defined for purging unused dirty pages."
#endif
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#ifdef JEMALLOC_STATS
nmadvise++;
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#endif
}
#ifdef JEMALLOC_DEBUG
assert(ndirty == 0);
#endif
malloc_mutex_lock(&arena->lock);
#ifdef JEMALLOC_STATS
arena->stats.nmadvise += nmadvise;
#endif
/* Deallocate runs. */
for (mapelm = ql_first(&mapelms); mapelm != NULL;
mapelm = ql_first(&mapelms)) {
size_t pageind = ((uintptr_t)mapelm - (uintptr_t)chunk->map) /
sizeof(arena_chunk_map_t);
arena_run_t *run = (arena_run_t *)((uintptr_t)chunk +
(uintptr_t)(pageind << PAGE_SHIFT));
ql_remove(&mapelms, mapelm, u.ql_link);
arena_run_dalloc(arena, run, false);
}
}
static void
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arena_purge(arena_t *arena, bool all)
{
arena_chunk_t *chunk;
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size_t npurgatory;
#ifdef JEMALLOC_DEBUG
size_t ndirty = 0;
ql_foreach(chunk, &arena->chunks_dirty, link_dirty) {
assert(chunk->dirtied);
ndirty += chunk->ndirty;
}
assert(ndirty == arena->ndirty);
#endif
assert(arena->ndirty > arena->npurgatory);
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assert(arena->ndirty > chunk_npages || all);
assert((arena->nactive >> opt_lg_dirty_mult) < arena->ndirty || all);
#ifdef JEMALLOC_STATS
arena->stats.npurge++;
#endif
/*
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* Compute the minimum number of pages that this thread should try to
* purge, and add the result to arena->npurgatory. This will keep
* multiple threads from racing to reduce ndirty below the threshold.
*/
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npurgatory = arena->ndirty - arena->npurgatory;
if (all == false)
npurgatory -= arena->nactive >> opt_lg_dirty_mult;
arena->npurgatory += npurgatory;
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while (npurgatory > 0) {
/* Get next chunk with dirty pages. */
chunk = ql_first(&arena->chunks_dirty);
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if (chunk == NULL) {
/*
* This thread was unable to purge as many pages as
* originally intended, due to races with other threads
* that either did some of the purging work, or re-used
* dirty pages.
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*/
arena->npurgatory -= npurgatory;
return;
}
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while (chunk->ndirty == 0) {
ql_remove(&arena->chunks_dirty, chunk, link_dirty);
chunk->dirtied = false;
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chunk = ql_first(&arena->chunks_dirty);
if (chunk == NULL) {
/* Same logic as for above. */
arena->npurgatory -= npurgatory;
return;
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}
}
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if (chunk->ndirty > npurgatory) {
/*
* This thread will, at a minimum, purge all the dirty
* pages in chunk, so set npurgatory to reflect this
* thread's commitment to purge the pages. This tends
* to reduce the chances of the following scenario:
*
* 1) This thread sets arena->npurgatory such that
* (arena->ndirty - arena->npurgatory) is at the
* threshold.
* 2) This thread drops arena->lock.
* 3) Another thread causes one or more pages to be
* dirtied, and immediately determines that it must
* purge dirty pages.
*
* If this scenario *does* play out, that's okay,
* because all of the purging work being done really
* needs to happen.
*/
arena->npurgatory += chunk->ndirty - npurgatory;
npurgatory = chunk->ndirty;
}
arena->npurgatory -= chunk->ndirty;
npurgatory -= chunk->ndirty;
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arena_chunk_purge(arena, chunk);
}
}
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void
arena_purge_all(arena_t *arena)
{
malloc_mutex_lock(&arena->lock);
arena_purge(arena, true);
malloc_mutex_unlock(&arena->lock);
}
static void
arena_run_dalloc(arena_t *arena, arena_run_t *run, bool dirty)
{
arena_chunk_t *chunk;
size_t size, run_ind, run_pages, flag_dirty;
arena_avail_tree_t *runs_avail;
chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(run);
run_ind = (size_t)(((uintptr_t)run - (uintptr_t)chunk)
>> PAGE_SHIFT);
assert(run_ind >= arena_chunk_header_npages);
assert(run_ind < chunk_npages);
if ((chunk->map[run_ind].bits & CHUNK_MAP_LARGE) != 0)
size = chunk->map[run_ind].bits & ~PAGE_MASK;
else
size = run->bin->run_size;
run_pages = (size >> PAGE_SHIFT);
arena->nactive -= run_pages;
/*
* The run is dirty if the caller claims to have dirtied it, as well as
* if it was already dirty before being allocated.
*/
if ((chunk->map[run_ind].bits & CHUNK_MAP_DIRTY) != 0)
dirty = true;
flag_dirty = dirty ? CHUNK_MAP_DIRTY : 0;
runs_avail = dirty ? &arena->runs_avail_dirty :
&arena->runs_avail_clean;
/* Mark pages as unallocated in the chunk map. */
if (dirty) {
chunk->map[run_ind].bits = size | flag_dirty;
chunk->map[run_ind+run_pages-1].bits = size | flag_dirty;
chunk->ndirty += run_pages;
arena->ndirty += run_pages;
} else {
chunk->map[run_ind].bits = size | (chunk->map[run_ind].bits &
CHUNK_MAP_ZEROED);
chunk->map[run_ind+run_pages-1].bits = size |
(chunk->map[run_ind+run_pages-1].bits & CHUNK_MAP_ZEROED);
}
/* Try to coalesce forward. */
if (run_ind + run_pages < chunk_npages &&
(chunk->map[run_ind+run_pages].bits & CHUNK_MAP_ALLOCATED) == 0 &&
(chunk->map[run_ind+run_pages].bits & CHUNK_MAP_DIRTY) ==
flag_dirty) {
size_t nrun_size = chunk->map[run_ind+run_pages].bits &
~PAGE_MASK;
/*
* Remove successor from runs_avail; the coalesced run is
* inserted later.
*/
arena_avail_tree_remove(runs_avail,
&chunk->map[run_ind+run_pages]);
size += nrun_size;
run_pages = size >> PAGE_SHIFT;
assert((chunk->map[run_ind+run_pages-1].bits & ~PAGE_MASK)
== nrun_size);
chunk->map[run_ind].bits = size | (chunk->map[run_ind].bits &
CHUNK_MAP_FLAGS_MASK);
chunk->map[run_ind+run_pages-1].bits = size |
(chunk->map[run_ind+run_pages-1].bits &
CHUNK_MAP_FLAGS_MASK);
}
/* Try to coalesce backward. */
if (run_ind > arena_chunk_header_npages && (chunk->map[run_ind-1].bits &
CHUNK_MAP_ALLOCATED) == 0 && (chunk->map[run_ind-1].bits &
CHUNK_MAP_DIRTY) == flag_dirty) {
size_t prun_size = chunk->map[run_ind-1].bits & ~PAGE_MASK;
run_ind -= prun_size >> PAGE_SHIFT;
/*
* Remove predecessor from runs_avail; the coalesced run is
* inserted later.
*/
arena_avail_tree_remove(runs_avail, &chunk->map[run_ind]);
size += prun_size;
run_pages = size >> PAGE_SHIFT;
assert((chunk->map[run_ind].bits & ~PAGE_MASK) == prun_size);
chunk->map[run_ind].bits = size | (chunk->map[run_ind].bits &
CHUNK_MAP_FLAGS_MASK);
chunk->map[run_ind+run_pages-1].bits = size |
(chunk->map[run_ind+run_pages-1].bits &
CHUNK_MAP_FLAGS_MASK);
}
/* Insert into runs_avail, now that coalescing is complete. */
arena_avail_tree_insert(runs_avail, &chunk->map[run_ind]);
if (dirty) {
/*
* Insert into chunks_dirty before potentially calling
* arena_chunk_dealloc(), so that chunks_dirty and
* arena->ndirty are consistent.
*/
if (chunk->dirtied == false) {
ql_tail_insert(&arena->chunks_dirty, chunk, link_dirty);
chunk->dirtied = true;
}
}
/*
* Deallocate chunk if it is now completely unused. The bit
* manipulation checks whether the first run is unallocated and extends
* to the end of the chunk.
*/
if ((chunk->map[arena_chunk_header_npages].bits & (~PAGE_MASK |
CHUNK_MAP_ALLOCATED)) == arena_maxclass)
arena_chunk_dealloc(arena, chunk);
/*
* It is okay to do dirty page processing here even if the chunk was
* deallocated above, since in that case it is the spare. Waiting
* until after possible chunk deallocation to do dirty processing
* allows for an old spare to be fully deallocated, thus decreasing the
* chances of spuriously crossing the dirty page purging threshold.
*/
if (dirty)
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arena_maybe_purge(arena);
}
static void
arena_run_trim_head(arena_t *arena, arena_chunk_t *chunk, arena_run_t *run,
size_t oldsize, size_t newsize)
{
size_t pageind = ((uintptr_t)run - (uintptr_t)chunk) >> PAGE_SHIFT;
size_t head_npages = (oldsize - newsize) >> PAGE_SHIFT;
size_t flags = chunk->map[pageind].bits & CHUNK_MAP_FLAGS_MASK;
assert(oldsize > newsize);
/*
* Update the chunk map so that arena_run_dalloc() can treat the
* leading run as separately allocated.
*/
assert(chunk->map[pageind].bits & CHUNK_MAP_LARGE);
assert(chunk->map[pageind].bits & CHUNK_MAP_ALLOCATED);
chunk->map[pageind].bits = (oldsize - newsize) | flags;
chunk->map[pageind+head_npages].bits = newsize | flags;
arena_run_dalloc(arena, run, false);
}
static void
arena_run_trim_tail(arena_t *arena, arena_chunk_t *chunk, arena_run_t *run,
size_t oldsize, size_t newsize, bool dirty)
{
size_t pageind = ((uintptr_t)run - (uintptr_t)chunk) >> PAGE_SHIFT;
size_t npages = newsize >> PAGE_SHIFT;
size_t flags = chunk->map[pageind].bits & CHUNK_MAP_FLAGS_MASK;
assert(oldsize > newsize);
/*
* Update the chunk map so that arena_run_dalloc() can treat the
* trailing run as separately allocated.
*/
assert(chunk->map[pageind].bits & CHUNK_MAP_LARGE);
assert(chunk->map[pageind].bits & CHUNK_MAP_ALLOCATED);
chunk->map[pageind].bits = newsize | flags;
chunk->map[pageind+npages-1].bits = newsize | flags;
chunk->map[pageind+npages].bits = (oldsize - newsize) | flags;
arena_run_dalloc(arena, (arena_run_t *)((uintptr_t)run + newsize),
dirty);
}
static arena_run_t *
arena_bin_nonfull_run_get(arena_t *arena, arena_bin_t *bin)
{
arena_chunk_map_t *mapelm;
arena_run_t *run;
/* Look for a usable run. */
mapelm = arena_run_tree_first(&bin->runs);
if (mapelm != NULL) {
arena_chunk_t *chunk;
size_t pageind;
/* run is guaranteed to have available space. */
arena_run_tree_remove(&bin->runs, mapelm);
chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(mapelm);
pageind = (((uintptr_t)mapelm - (uintptr_t)chunk->map) /
sizeof(arena_chunk_map_t));
run = (arena_run_t *)((uintptr_t)chunk + (uintptr_t)((pageind -
(mapelm->bits >> PAGE_SHIFT))
<< PAGE_SHIFT));
#ifdef JEMALLOC_STATS
bin->stats.reruns++;
#endif
return (run);
}
/* No existing runs have any space available. */
/* Allocate a new run. */
malloc_mutex_unlock(&bin->lock);
/******************************/
malloc_mutex_lock(&arena->lock);
run = arena_run_alloc(arena, bin->run_size, false, false);
if (run != NULL) {
/* Initialize run internals. */
run->bin = bin;
run->avail = NULL;
run->next = (void *)(((uintptr_t)run) +
(uintptr_t)bin->reg0_offset);
run->nfree = bin->nregs;
#ifdef JEMALLOC_DEBUG
run->magic = ARENA_RUN_MAGIC;
#endif
}
malloc_mutex_unlock(&arena->lock);
/********************************/
malloc_mutex_lock(&bin->lock);
if (run != NULL) {
#ifdef JEMALLOC_STATS
bin->stats.nruns++;
bin->stats.curruns++;
if (bin->stats.curruns > bin->stats.highruns)
bin->stats.highruns = bin->stats.curruns;
#endif
return (run);
}
/*
* arena_run_alloc() failed, but another thread may have made
* sufficient memory available while this one dopped bin->lock above,
* so search one more time.
*/
mapelm = arena_run_tree_first(&bin->runs);
if (mapelm != NULL) {
arena_chunk_t *chunk;
size_t pageind;
/* run is guaranteed to have available space. */
arena_run_tree_remove(&bin->runs, mapelm);
chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(mapelm);
pageind = (((uintptr_t)mapelm - (uintptr_t)chunk->map) /
sizeof(arena_chunk_map_t));
run = (arena_run_t *)((uintptr_t)chunk + (uintptr_t)((pageind -
(mapelm->bits >> PAGE_SHIFT))
<< PAGE_SHIFT));
#ifdef JEMALLOC_STATS
bin->stats.reruns++;
#endif
return (run);
}
return (NULL);
}
/* Re-fill bin->runcur, then call arena_run_reg_alloc(). */
static void *
arena_bin_malloc_hard(arena_t *arena, arena_bin_t *bin)
{
void *ret;
arena_run_t *run;
bin->runcur = NULL;
run = arena_bin_nonfull_run_get(arena, bin);
if (bin->runcur != NULL && bin->runcur->nfree > 0) {
/*
* Another thread updated runcur while this one ran without the
* bin lock in arena_bin_nonfull_run_get().
*/
assert(bin->runcur->magic == ARENA_RUN_MAGIC);
assert(bin->runcur->nfree > 0);
ret = arena_run_reg_alloc(bin->runcur, bin);
if (run != NULL) {
malloc_mutex_unlock(&bin->lock);
malloc_mutex_lock(&arena->lock);
arena_run_dalloc(arena, run, false);
malloc_mutex_unlock(&arena->lock);
malloc_mutex_lock(&bin->lock);
}
return (ret);
}
if (run == NULL)
return (NULL);
bin->runcur = run;
assert(bin->runcur->magic == ARENA_RUN_MAGIC);
assert(bin->runcur->nfree > 0);
return (arena_run_reg_alloc(bin->runcur, bin));
}
#ifdef JEMALLOC_PROF
void
arena_prof_accum(arena_t *arena, uint64_t accumbytes)
{
if (prof_interval != 0) {
arena->prof_accumbytes += accumbytes;
if (arena->prof_accumbytes >= prof_interval) {
prof_idump();
arena->prof_accumbytes -= prof_interval;
}
}
}
#endif
#ifdef JEMALLOC_TCACHE
void
arena_tcache_fill_small(arena_t *arena, tcache_bin_t *tbin, size_t binind
# ifdef JEMALLOC_PROF
, uint64_t prof_accumbytes
# endif
)
{
unsigned i, nfill;
arena_bin_t *bin;
arena_run_t *run;
void *ptr;
assert(tbin->ncached == 0);
#ifdef JEMALLOC_PROF
malloc_mutex_lock(&arena->lock);
arena_prof_accum(arena, prof_accumbytes);
malloc_mutex_unlock(&arena->lock);
#endif
bin = &arena->bins[binind];
malloc_mutex_lock(&bin->lock);
for (i = 0, nfill = (tbin->ncached_max >> 1); i < nfill; i++) {
if ((run = bin->runcur) != NULL && run->nfree > 0)
ptr = arena_run_reg_alloc(run, bin);
else
ptr = arena_bin_malloc_hard(arena, bin);
if (ptr == NULL)
break;
*(void **)ptr = tbin->avail;
tbin->avail = ptr;
}
#ifdef JEMALLOC_STATS
bin->stats.allocated += (i - tbin->ncached) * bin->reg_size;
bin->stats.nmalloc += i;
bin->stats.nrequests += tbin->tstats.nrequests;
bin->stats.nfills++;
tbin->tstats.nrequests = 0;
#endif
malloc_mutex_unlock(&bin->lock);
tbin->ncached = i;
if (tbin->ncached > tbin->high_water)
tbin->high_water = tbin->ncached;
}
#endif
/*
* Calculate bin->run_size such that it meets the following constraints:
*
* *) bin->run_size >= min_run_size
* *) bin->run_size <= arena_maxclass
* *) run header overhead <= RUN_MAX_OVRHD (or header overhead relaxed).
* *) run header size < PAGE_SIZE
*
* bin->nregs and bin->reg0_offset are also calculated here, since these
* settings are all interdependent.
*/
static size_t
arena_bin_run_size_calc(arena_bin_t *bin, size_t min_run_size)
{
size_t try_run_size, good_run_size;
uint32_t try_nregs, good_nregs;
uint32_t try_hdr_size, good_hdr_size;
#ifdef JEMALLOC_PROF
uint32_t try_ctx0_offset, good_ctx0_offset;
#endif
uint32_t try_reg0_offset, good_reg0_offset;
assert(min_run_size >= PAGE_SIZE);
assert(min_run_size <= arena_maxclass);
/*
* Calculate known-valid settings before entering the run_size
* expansion loop, so that the first part of the loop always copies
* valid settings.
*
* The do..while loop iteratively reduces the number of regions until
* the run header and the regions no longer overlap. A closed formula
* would be quite messy, since there is an interdependency between the
* header's mask length and the number of regions.
*/
try_run_size = min_run_size;
try_nregs = ((try_run_size - sizeof(arena_run_t)) / bin->reg_size)
+ 1; /* Counter-act try_nregs-- in loop. */
do {
try_nregs--;
try_hdr_size = sizeof(arena_run_t);
#ifdef JEMALLOC_PROF
if (opt_prof && prof_promote == false) {
/* Pad to a quantum boundary. */
try_hdr_size = QUANTUM_CEILING(try_hdr_size);
try_ctx0_offset = try_hdr_size;
/* Add space for one (prof_ctx_t *) per region. */
try_hdr_size += try_nregs * sizeof(prof_ctx_t *);
} else
try_ctx0_offset = 0;
#endif
try_reg0_offset = try_run_size - (try_nregs * bin->reg_size);
} while (try_hdr_size > try_reg0_offset);
/* run_size expansion loop. */
do {
/*
* Copy valid settings before trying more aggressive settings.
*/
good_run_size = try_run_size;
good_nregs = try_nregs;
good_hdr_size = try_hdr_size;
#ifdef JEMALLOC_PROF
good_ctx0_offset = try_ctx0_offset;
#endif
good_reg0_offset = try_reg0_offset;
/* Try more aggressive settings. */
try_run_size += PAGE_SIZE;
try_nregs = ((try_run_size - sizeof(arena_run_t)) /
bin->reg_size) + 1; /* Counter-act try_nregs-- in loop. */
do {
try_nregs--;
try_hdr_size = sizeof(arena_run_t);
#ifdef JEMALLOC_PROF
if (opt_prof && prof_promote == false) {
/* Pad to a quantum boundary. */
try_hdr_size = QUANTUM_CEILING(try_hdr_size);
try_ctx0_offset = try_hdr_size;
/*
* Add space for one (prof_ctx_t *) per region.
*/
try_hdr_size += try_nregs *
sizeof(prof_ctx_t *);
}
#endif
try_reg0_offset = try_run_size - (try_nregs *
bin->reg_size);
} while (try_hdr_size > try_reg0_offset);
} while (try_run_size <= arena_maxclass
&& try_run_size <= arena_maxclass
&& RUN_MAX_OVRHD * (bin->reg_size << 3) > RUN_MAX_OVRHD_RELAX
&& (try_reg0_offset << RUN_BFP) > RUN_MAX_OVRHD * try_run_size
&& try_hdr_size < PAGE_SIZE);
assert(good_hdr_size <= good_reg0_offset);
/* Copy final settings. */
bin->run_size = good_run_size;
bin->nregs = good_nregs;
#ifdef JEMALLOC_PROF
bin->ctx0_offset = good_ctx0_offset;
#endif
bin->reg0_offset = good_reg0_offset;
return (good_run_size);
}
void *
arena_malloc_small(arena_t *arena, size_t size, bool zero)
{
void *ret;
arena_bin_t *bin;
arena_run_t *run;
size_t binind;
binind = small_size2bin[size];
assert(binind < nbins);
bin = &arena->bins[binind];
size = bin->reg_size;
malloc_mutex_lock(&bin->lock);
if ((run = bin->runcur) != NULL && run->nfree > 0)
ret = arena_run_reg_alloc(run, bin);
else
ret = arena_bin_malloc_hard(arena, bin);
if (ret == NULL) {
malloc_mutex_unlock(&bin->lock);
return (NULL);
}
#ifdef JEMALLOC_STATS
bin->stats.allocated += size;
bin->stats.nmalloc++;
bin->stats.nrequests++;
#endif
malloc_mutex_unlock(&bin->lock);
#ifdef JEMALLOC_PROF
if (isthreaded == false) {
malloc_mutex_lock(&arena->lock);
arena_prof_accum(arena, size);
malloc_mutex_unlock(&arena->lock);
}
#endif
if (zero == false) {
#ifdef JEMALLOC_FILL
if (opt_junk)
memset(ret, 0xa5, size);
else if (opt_zero)
memset(ret, 0, size);
#endif
} else
memset(ret, 0, size);
return (ret);
}
void *
arena_malloc_large(arena_t *arena, size_t size, bool zero)
{
void *ret;
/* Large allocation. */
size = PAGE_CEILING(size);
malloc_mutex_lock(&arena->lock);
ret = (void *)arena_run_alloc(arena, size, true, zero);
if (ret == NULL) {
malloc_mutex_unlock(&arena->lock);
return (NULL);
}
#ifdef JEMALLOC_STATS
arena->stats.nmalloc_large++;
arena->stats.nrequests_large++;
arena->stats.allocated_large += size;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].nmalloc++;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].nrequests++;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns++;
if (arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns >
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].highruns) {
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].highruns =
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns;
}
#endif
#ifdef JEMALLOC_PROF
arena_prof_accum(arena, size);
#endif
malloc_mutex_unlock(&arena->lock);
if (zero == false) {
#ifdef JEMALLOC_FILL
if (opt_junk)
memset(ret, 0xa5, size);
else if (opt_zero)
memset(ret, 0, size);
#endif
}
return (ret);
}
void *
arena_malloc(size_t size, bool zero)
{
assert(size != 0);
assert(QUANTUM_CEILING(size) <= arena_maxclass);
if (size <= small_maxclass) {
#ifdef JEMALLOC_TCACHE
tcache_t *tcache;
if ((tcache = tcache_get()) != NULL)
return (tcache_alloc_small(tcache, size, zero));
else
#endif
return (arena_malloc_small(choose_arena(), size, zero));
} else {
#ifdef JEMALLOC_TCACHE
if (size <= tcache_maxclass) {
tcache_t *tcache;
if ((tcache = tcache_get()) != NULL)
return (tcache_alloc_large(tcache, size, zero));
else {
return (arena_malloc_large(choose_arena(),
size, zero));
}
} else
#endif
return (arena_malloc_large(choose_arena(), size, zero));
}
}
/* Only handles large allocations that require more than page alignment. */
void *
arena_palloc(arena_t *arena, size_t size, size_t alloc_size, size_t alignment,
bool zero)
{
void *ret;
size_t offset;
arena_chunk_t *chunk;
assert((size & PAGE_MASK) == 0);
assert((alignment & PAGE_MASK) == 0);
malloc_mutex_lock(&arena->lock);
ret = (void *)arena_run_alloc(arena, alloc_size, true, zero);
if (ret == NULL) {
malloc_mutex_unlock(&arena->lock);
return (NULL);
}
chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ret);
offset = (uintptr_t)ret & (alignment - 1);
assert((offset & PAGE_MASK) == 0);
assert(offset < alloc_size);
if (offset == 0)
arena_run_trim_tail(arena, chunk, ret, alloc_size, size, false);
else {
size_t leadsize, trailsize;
leadsize = alignment - offset;
if (leadsize > 0) {
arena_run_trim_head(arena, chunk, ret, alloc_size,
alloc_size - leadsize);
ret = (void *)((uintptr_t)ret + leadsize);
}
trailsize = alloc_size - leadsize - size;
if (trailsize != 0) {
/* Trim trailing space. */
assert(trailsize < alloc_size);
arena_run_trim_tail(arena, chunk, ret, size + trailsize,
size, false);
}
}
#ifdef JEMALLOC_STATS
arena->stats.nmalloc_large++;
arena->stats.nrequests_large++;
arena->stats.allocated_large += size;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].nmalloc++;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].nrequests++;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns++;
if (arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns >
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].highruns) {
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].highruns =
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns;
}
#endif
malloc_mutex_unlock(&arena->lock);
#ifdef JEMALLOC_FILL
if (zero == false) {
if (opt_junk)
memset(ret, 0xa5, size);
else if (opt_zero)
memset(ret, 0, size);
}
#endif
return (ret);
}
/* Return the size of the allocation pointed to by ptr. */
size_t
arena_salloc(const void *ptr)
{
size_t ret;
arena_chunk_t *chunk;
size_t pageind, mapbits;
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].bits;
assert((mapbits & CHUNK_MAP_ALLOCATED) != 0);
if ((mapbits & CHUNK_MAP_LARGE) == 0) {
arena_run_t *run = (arena_run_t *)((uintptr_t)chunk +
(uintptr_t)((pageind - (mapbits >> PAGE_SHIFT)) <<
PAGE_SHIFT));
assert(run->magic == ARENA_RUN_MAGIC);
assert(((uintptr_t)ptr - ((uintptr_t)run +
(uintptr_t)run->bin->reg0_offset)) % run->bin->reg_size ==
0);
ret = run->bin->reg_size;
} else {
assert(((uintptr_t)ptr & PAGE_MASK) == 0);
ret = mapbits & ~PAGE_MASK;
assert(ret != 0);
}
return (ret);
}
#ifdef JEMALLOC_PROF
void
arena_prof_promoted(const void *ptr, size_t size)
{
arena_chunk_t *chunk;
size_t pageind, binind;
assert(ptr != NULL);
assert(CHUNK_ADDR2BASE(ptr) != ptr);
assert(isalloc(ptr) == PAGE_SIZE);
chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ptr);
pageind = (((uintptr_t)ptr - (uintptr_t)chunk) >> PAGE_SHIFT);
binind = small_size2bin[size];
assert(binind < nbins);
chunk->map[pageind].bits = (chunk->map[pageind].bits &
~CHUNK_MAP_CLASS_MASK) | (binind << CHUNK_MAP_CLASS_SHIFT);
}
size_t
arena_salloc_demote(const void *ptr)
{
size_t ret;
arena_chunk_t *chunk;
size_t pageind, mapbits;
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].bits;
assert((mapbits & CHUNK_MAP_ALLOCATED) != 0);
if ((mapbits & CHUNK_MAP_LARGE) == 0) {
arena_run_t *run = (arena_run_t *)((uintptr_t)chunk +
(uintptr_t)((pageind - (mapbits >> PAGE_SHIFT)) <<
PAGE_SHIFT));
assert(run->magic == ARENA_RUN_MAGIC);
assert(((uintptr_t)ptr - ((uintptr_t)run +
(uintptr_t)run->bin->reg0_offset)) % run->bin->reg_size ==
0);
ret = run->bin->reg_size;
} else {
assert(((uintptr_t)ptr & PAGE_MASK) == 0);
ret = mapbits & ~PAGE_MASK;
if (prof_promote && ret == PAGE_SIZE && (mapbits &
CHUNK_MAP_CLASS_MASK) != CHUNK_MAP_CLASS_MASK) {
size_t binind = ((mapbits & CHUNK_MAP_CLASS_MASK) >>
CHUNK_MAP_CLASS_SHIFT);
assert(binind < nbins);
ret = chunk->arena->bins[binind].reg_size;
}
assert(ret != 0);
}
return (ret);
}
static inline unsigned
arena_run_regind(arena_run_t *run, arena_bin_t *bin, const void *ptr,
size_t size)
{
unsigned shift, diff, regind;
assert(run->magic == ARENA_RUN_MAGIC);
/*
* 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->reg0_offset);
/* Rescale (factor powers of 2 out of the numerator and denominator). */
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 21
#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->nregs);
return (regind);
}
prof_ctx_t *
arena_prof_ctx_get(const void *ptr)
{
prof_ctx_t *ret;
arena_chunk_t *chunk;
size_t pageind, mapbits;
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].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));
arena_bin_t *bin = run->bin;
unsigned regind;
assert(run->magic == ARENA_RUN_MAGIC);
regind = arena_run_regind(run, bin, ptr, bin->reg_size);
ret = *(prof_ctx_t **)((uintptr_t)run +
bin->ctx0_offset + (regind *
sizeof(prof_ctx_t *)));
}
} else
ret = chunk->map[pageind].prof_ctx;
return (ret);
}
void
arena_prof_ctx_set(const void *ptr, prof_ctx_t *ctx)
{
arena_chunk_t *chunk;
size_t pageind, mapbits;
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].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;
unsigned regind;
assert(run->magic == ARENA_RUN_MAGIC);
regind = arena_run_regind(run, bin, ptr, bin->reg_size);
*((prof_ctx_t **)((uintptr_t)run + bin->ctx0_offset
+ (regind * sizeof(prof_ctx_t *)))) = ctx;
} else
assert((uintptr_t)ctx == (uintptr_t)1U);
} else
chunk->map[pageind].prof_ctx = ctx;
}
#endif
static void
arena_dalloc_bin_run(arena_t *arena, arena_chunk_t *chunk, arena_run_t *run,
arena_bin_t *bin)
{
size_t npages, run_ind, past;
/* Dissociate run from bin. */
if (run == bin->runcur)
bin->runcur = NULL;
else if (bin->nregs != 1) {
size_t run_pageind = (((uintptr_t)run - (uintptr_t)chunk)) >>
PAGE_SHIFT;
arena_chunk_map_t *run_mapelm = &chunk->map[run_pageind];
/*
* This block's conditional is necessary because if the run
* only contains one region, then it never gets inserted into
* the non-full runs tree.
*/
arena_run_tree_remove(&bin->runs, run_mapelm);
}
malloc_mutex_unlock(&bin->lock);
/******************************/
npages = bin->run_size >> PAGE_SHIFT;
run_ind = (size_t)(((uintptr_t)run - (uintptr_t)chunk) >> PAGE_SHIFT);
past = (size_t)(((uintptr_t)run->next - (uintptr_t)1U -
(uintptr_t)chunk) >> PAGE_SHIFT) + 1;
malloc_mutex_lock(&arena->lock);
/*
* If the run was originally clean, and some pages were never touched,
* trim the clean pages before deallocating the dirty portion of the
* run.
*/
if ((chunk->map[run_ind].bits & CHUNK_MAP_DIRTY) == 0 && past - run_ind
< npages) {
/*
* Trim clean pages. Convert to large run beforehand. Set the
* last map element first, in case this is a one-page run.
*/
chunk->map[run_ind+npages-1].bits = CHUNK_MAP_LARGE |
(chunk->map[run_ind].bits & CHUNK_MAP_FLAGS_MASK);
chunk->map[run_ind].bits = bin->run_size | CHUNK_MAP_LARGE |
(chunk->map[run_ind].bits & CHUNK_MAP_FLAGS_MASK);
arena_run_trim_tail(arena, chunk, run, (npages << PAGE_SHIFT),
((npages - (past - run_ind)) << PAGE_SHIFT), false);
npages = past - run_ind;
}
#ifdef JEMALLOC_DEBUG
run->magic = 0;
#endif
arena_run_dalloc(arena, run, true);
malloc_mutex_unlock(&arena->lock);
/****************************/
malloc_mutex_lock(&bin->lock);
#ifdef JEMALLOC_STATS
bin->stats.curruns--;
#endif
}
void
arena_dalloc_bin(arena_t *arena, arena_chunk_t *chunk, void *ptr,
arena_chunk_map_t *mapelm)
{
size_t pageind;
arena_run_t *run;
arena_bin_t *bin;
#if (defined(JEMALLOC_FILL) || defined(JEMALLOC_STATS))
size_t size;
#endif
pageind = (((uintptr_t)ptr - (uintptr_t)chunk) >> PAGE_SHIFT);
run = (arena_run_t *)((uintptr_t)chunk + (uintptr_t)((pageind -
(mapelm->bits >> PAGE_SHIFT)) << PAGE_SHIFT));
assert(run->magic == ARENA_RUN_MAGIC);
bin = run->bin;
#if (defined(JEMALLOC_FILL) || defined(JEMALLOC_STATS))
size = bin->reg_size;
#endif
#ifdef JEMALLOC_FILL
if (opt_junk)
memset(ptr, 0x5a, size);
#endif
arena_run_reg_dalloc(run, ptr);
if (run->nfree == bin->nregs)
arena_dalloc_bin_run(arena, chunk, run, bin);
else if (run->nfree == 1 && run != bin->runcur) {
/*
* Make sure that bin->runcur always refers to the lowest
* non-full run, if one exists.
*/
if (bin->runcur == NULL)
bin->runcur = run;
else if ((uintptr_t)run < (uintptr_t)bin->runcur) {
/* Switch runcur. */
if (bin->runcur->nfree > 0) {
arena_chunk_t *runcur_chunk =
CHUNK_ADDR2BASE(bin->runcur);
size_t runcur_pageind =
(((uintptr_t)bin->runcur -
(uintptr_t)runcur_chunk)) >> PAGE_SHIFT;
arena_chunk_map_t *runcur_mapelm =
&runcur_chunk->map[runcur_pageind];
/* Insert runcur. */
arena_run_tree_insert(&bin->runs,
runcur_mapelm);
}
bin->runcur = run;
} else {
size_t run_pageind = (((uintptr_t)run -
(uintptr_t)chunk)) >> PAGE_SHIFT;
arena_chunk_map_t *run_mapelm =
&chunk->map[run_pageind];
assert(arena_run_tree_search(&bin->runs, run_mapelm) ==
NULL);
arena_run_tree_insert(&bin->runs, run_mapelm);
}
}
#ifdef JEMALLOC_STATS
bin->stats.allocated -= size;
bin->stats.ndalloc++;
#endif
}
#ifdef JEMALLOC_STATS
void
arena_stats_merge(arena_t *arena, size_t *nactive, size_t *ndirty,
arena_stats_t *astats, malloc_bin_stats_t *bstats,
malloc_large_stats_t *lstats)
{
unsigned i;
malloc_mutex_lock(&arena->lock);
*nactive += arena->nactive;
*ndirty += arena->ndirty;
astats->mapped += arena->stats.mapped;
astats->npurge += arena->stats.npurge;
astats->nmadvise += arena->stats.nmadvise;
astats->purged += arena->stats.purged;
astats->allocated_large += arena->stats.allocated_large;
astats->nmalloc_large += arena->stats.nmalloc_large;
astats->ndalloc_large += arena->stats.ndalloc_large;
astats->nrequests_large += arena->stats.nrequests_large;
for (i = 0; i < nlclasses; i++) {
lstats[i].nmalloc += arena->stats.lstats[i].nmalloc;
lstats[i].ndalloc += arena->stats.lstats[i].ndalloc;
lstats[i].nrequests += arena->stats.lstats[i].nrequests;
lstats[i].highruns += arena->stats.lstats[i].highruns;
lstats[i].curruns += arena->stats.lstats[i].curruns;
}
malloc_mutex_unlock(&arena->lock);
for (i = 0; i < nbins; i++) {
arena_bin_t *bin = &arena->bins[i];
malloc_mutex_lock(&bin->lock);
bstats[i].allocated += bin->stats.allocated;
bstats[i].nmalloc += bin->stats.nmalloc;
bstats[i].ndalloc += bin->stats.ndalloc;
bstats[i].nrequests += bin->stats.nrequests;
#ifdef JEMALLOC_TCACHE
bstats[i].nfills += bin->stats.nfills;
bstats[i].nflushes += bin->stats.nflushes;
#endif
bstats[i].nruns += bin->stats.nruns;
bstats[i].reruns += bin->stats.reruns;
bstats[i].highruns += bin->stats.highruns;
bstats[i].curruns += bin->stats.curruns;
malloc_mutex_unlock(&bin->lock);
}
}
#endif
void
arena_dalloc_large(arena_t *arena, arena_chunk_t *chunk, void *ptr)
{
2010-01-31 19:57:29 +08:00
/* Large allocation. */
#ifdef JEMALLOC_FILL
# ifndef JEMALLOC_STATS
if (opt_junk)
# endif
#endif
{
#if (defined(JEMALLOC_FILL) || defined(JEMALLOC_STATS))
size_t pageind = ((uintptr_t)ptr - (uintptr_t)chunk) >>
PAGE_SHIFT;
size_t size = chunk->map[pageind].bits & ~PAGE_MASK;
#endif
#ifdef JEMALLOC_FILL
# ifdef JEMALLOC_STATS
if (opt_junk)
# endif
memset(ptr, 0x5a, size);
#endif
#ifdef JEMALLOC_STATS
arena->stats.ndalloc_large++;
arena->stats.allocated_large -= size;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].ndalloc++;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns--;
#endif
}
arena_run_dalloc(arena, (arena_run_t *)ptr, true);
}
static void
arena_ralloc_large_shrink(arena_t *arena, arena_chunk_t *chunk, void *ptr,
size_t oldsize, size_t size)
{
assert(size < oldsize);
/*
* Shrink the run, and make trailing pages available for other
* allocations.
*/
malloc_mutex_lock(&arena->lock);
arena_run_trim_tail(arena, chunk, (arena_run_t *)ptr, oldsize, size,
true);
#ifdef JEMALLOC_STATS
arena->stats.ndalloc_large++;
arena->stats.allocated_large -= oldsize;
arena->stats.lstats[(oldsize >> PAGE_SHIFT) - 1].ndalloc++;
arena->stats.lstats[(oldsize >> PAGE_SHIFT) - 1].curruns--;
arena->stats.nmalloc_large++;
arena->stats.nrequests_large++;
arena->stats.allocated_large += size;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].nmalloc++;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].nrequests++;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns++;
if (arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns >
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].highruns) {
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].highruns =
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns;
}
#endif
malloc_mutex_unlock(&arena->lock);
}
static bool
arena_ralloc_large_grow(arena_t *arena, arena_chunk_t *chunk, void *ptr,
size_t oldsize, size_t size, size_t extra, bool zero)
{
size_t pageind = ((uintptr_t)ptr - (uintptr_t)chunk) >> PAGE_SHIFT;
size_t npages = oldsize >> PAGE_SHIFT;
size_t followsize;
assert(oldsize == (chunk->map[pageind].bits & ~PAGE_MASK));
/* Try to extend the run. */
assert(size + extra > oldsize);
malloc_mutex_lock(&arena->lock);
if (pageind + npages < chunk_npages && (chunk->map[pageind+npages].bits
& CHUNK_MAP_ALLOCATED) == 0 && (followsize =
chunk->map[pageind+npages].bits & ~PAGE_MASK) >= size - oldsize) {
/*
* The next run is available and sufficiently large. Split the
* following run, then merge the first part with the existing
* allocation.
*/
size_t splitsize = (oldsize + followsize <= size + extra)
? followsize : size + extra - oldsize;
arena_run_split(arena, (arena_run_t *)((uintptr_t)chunk +
((pageind+npages) << PAGE_SHIFT)), splitsize, true, zero);
chunk->map[pageind].bits = size | CHUNK_MAP_LARGE |
CHUNK_MAP_ALLOCATED;
chunk->map[pageind+npages].bits = CHUNK_MAP_LARGE |
CHUNK_MAP_ALLOCATED;
#ifdef JEMALLOC_STATS
arena->stats.ndalloc_large++;
arena->stats.allocated_large -= oldsize;
arena->stats.lstats[(oldsize >> PAGE_SHIFT) - 1].ndalloc++;
arena->stats.lstats[(oldsize >> PAGE_SHIFT) - 1].curruns--;
arena->stats.nmalloc_large++;
arena->stats.nrequests_large++;
arena->stats.allocated_large += size;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].nmalloc++;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].nrequests++;
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns++;
if (arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns >
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].highruns) {
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].highruns =
arena->stats.lstats[(size >> PAGE_SHIFT) - 1].curruns;
}
#endif
malloc_mutex_unlock(&arena->lock);
return (false);
}
malloc_mutex_unlock(&arena->lock);
return (true);
}
/*
* Try to resize a large allocation, in order to avoid copying. This will
* always fail if growing an object, and the following run is already in use.
*/
static bool
arena_ralloc_large(void *ptr, size_t oldsize, size_t size, size_t extra,
bool zero)
{
size_t psize;
psize = PAGE_CEILING(size + extra);
if (psize == oldsize) {
/* Same size class. */
#ifdef JEMALLOC_FILL
if (opt_junk && size < oldsize) {
memset((void *)((uintptr_t)ptr + size), 0x5a, oldsize -
size);
}
#endif
return (false);
} else {
arena_chunk_t *chunk;
arena_t *arena;
chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ptr);
arena = chunk->arena;
assert(arena->magic == ARENA_MAGIC);
if (psize < oldsize) {
#ifdef JEMALLOC_FILL
/* Fill before shrinking in order avoid a race. */
if (opt_junk) {
memset((void *)((uintptr_t)ptr + size), 0x5a,
oldsize - size);
}
#endif
arena_ralloc_large_shrink(arena, chunk, ptr, oldsize,
psize);
return (false);
} else {
bool ret = arena_ralloc_large_grow(arena, chunk, ptr,
oldsize, PAGE_CEILING(size),
psize - PAGE_CEILING(size), zero);
#ifdef JEMALLOC_FILL
if (ret == false && zero == false && opt_zero) {
memset((void *)((uintptr_t)ptr + oldsize), 0,
size - oldsize);
}
#endif
return (ret);
}
}
}
void *
arena_ralloc_no_move(void *ptr, size_t oldsize, size_t size, size_t extra,
bool zero)
{
/*
* Avoid moving the allocation if the size class can be left the same.
*/
if (oldsize <= arena_maxclass) {
if (oldsize <= small_maxclass) {
assert(choose_arena()->bins[small_size2bin[
oldsize]].reg_size == oldsize);
if ((size + extra <= small_maxclass &&
small_size2bin[size + extra] ==
small_size2bin[oldsize]) || (size <= oldsize &&
size + extra >= oldsize)) {
#ifdef JEMALLOC_FILL
if (opt_junk && size < oldsize) {
memset((void *)((uintptr_t)ptr + size),
0x5a, oldsize - size);
}
#endif
return (ptr);
}
} else {
assert(size <= arena_maxclass);
if (size + extra > small_maxclass) {
if (arena_ralloc_large(ptr, oldsize, size,
extra, zero) == false)
return (ptr);
}
}
}
/* Reallocation would require a move. */
return (NULL);
}
void *
arena_ralloc(void *ptr, size_t oldsize, size_t size, size_t extra,
size_t alignment, bool zero)
{
void *ret;
size_t copysize;
/* Try to avoid moving the allocation. */
ret = arena_ralloc_no_move(ptr, oldsize, size, extra, zero);
if (ret != NULL)
return (ret);
/*
* size and oldsize are different enough that we need to move the
* object. In that case, fall back to allocating new space and
* copying.
*/
if (alignment != 0)
ret = ipalloc(size + extra, alignment, zero);
else
ret = arena_malloc(size + extra, zero);
if (ret == NULL) {
if (extra == 0)
return (NULL);
/* Try again, this time without extra. */
if (alignment != 0)
ret = ipalloc(size, alignment, zero);
else
ret = arena_malloc(size, zero);
if (ret == NULL)
return (NULL);
}
/* Junk/zero-filling were already done by ipalloc()/arena_malloc(). */
/*
* Copy at most size bytes (not size+extra), since the caller has no
* expectation that the extra bytes will be reliably preserved.
*/
copysize = (size < oldsize) ? size : oldsize;
memcpy(ret, ptr, copysize);
idalloc(ptr);
return (ret);
}
bool
arena_new(arena_t *arena, unsigned ind)
{
unsigned i;
arena_bin_t *bin;
size_t prev_run_size;
arena->ind = ind;
if (malloc_mutex_init(&arena->lock))
return (true);
#ifdef JEMALLOC_STATS
memset(&arena->stats, 0, sizeof(arena_stats_t));
arena->stats.lstats = (malloc_large_stats_t *)base_alloc(nlclasses *
sizeof(malloc_large_stats_t));
if (arena->stats.lstats == NULL)
return (true);
memset(arena->stats.lstats, 0, nlclasses *
sizeof(malloc_large_stats_t));
# ifdef JEMALLOC_TCACHE
ql_new(&arena->tcache_ql);
# endif
#endif
#ifdef JEMALLOC_PROF
arena->prof_accumbytes = 0;
#endif
/* Initialize chunks. */
ql_new(&arena->chunks_dirty);
arena->spare = NULL;
arena->nactive = 0;
arena->ndirty = 0;
arena->npurgatory = 0;
arena_avail_tree_new(&arena->runs_avail_clean);
arena_avail_tree_new(&arena->runs_avail_dirty);
/* Initialize bins. */
prev_run_size = PAGE_SIZE;
i = 0;
#ifdef JEMALLOC_TINY
/* (2^n)-spaced tiny bins. */
for (; i < ntbins; i++) {
bin = &arena->bins[i];
if (malloc_mutex_init(&bin->lock))
return (true);
bin->runcur = NULL;
arena_run_tree_new(&bin->runs);
bin->reg_size = (1U << (LG_TINY_MIN + i));
prev_run_size = arena_bin_run_size_calc(bin, prev_run_size);
#ifdef JEMALLOC_STATS
memset(&bin->stats, 0, sizeof(malloc_bin_stats_t));
#endif
}
#endif
/* Quantum-spaced bins. */
for (; i < ntbins + nqbins; i++) {
bin = &arena->bins[i];
if (malloc_mutex_init(&bin->lock))
return (true);
bin->runcur = NULL;
arena_run_tree_new(&bin->runs);
bin->reg_size = (i - ntbins + 1) << LG_QUANTUM;
prev_run_size = arena_bin_run_size_calc(bin, prev_run_size);
#ifdef JEMALLOC_STATS
memset(&bin->stats, 0, sizeof(malloc_bin_stats_t));
#endif
}
/* Cacheline-spaced bins. */
for (; i < ntbins + nqbins + ncbins; i++) {
bin = &arena->bins[i];
if (malloc_mutex_init(&bin->lock))
return (true);
bin->runcur = NULL;
arena_run_tree_new(&bin->runs);
bin->reg_size = cspace_min + ((i - (ntbins + nqbins)) <<
LG_CACHELINE);
prev_run_size = arena_bin_run_size_calc(bin, prev_run_size);
#ifdef JEMALLOC_STATS
memset(&bin->stats, 0, sizeof(malloc_bin_stats_t));
#endif
}
/* Subpage-spaced bins. */
for (; i < nbins; i++) {
bin = &arena->bins[i];
if (malloc_mutex_init(&bin->lock))
return (true);
bin->runcur = NULL;
arena_run_tree_new(&bin->runs);
bin->reg_size = sspace_min + ((i - (ntbins + nqbins + ncbins))
<< LG_SUBPAGE);
prev_run_size = arena_bin_run_size_calc(bin, prev_run_size);
#ifdef JEMALLOC_STATS
memset(&bin->stats, 0, sizeof(malloc_bin_stats_t));
#endif
}
#ifdef JEMALLOC_DEBUG
arena->magic = ARENA_MAGIC;
#endif
return (false);
}
#ifdef JEMALLOC_DEBUG
static void
small_size2bin_validate(void)
{
size_t i, size, binind;
assert(small_size2bin[0] == 0xffU);
i = 1;
# ifdef JEMALLOC_TINY
/* Tiny. */
for (; i < (1U << LG_TINY_MIN); i++) {
size = pow2_ceil(1U << LG_TINY_MIN);
binind = ffs((int)(size >> (LG_TINY_MIN + 1)));
assert(small_size2bin[i] == binind);
}
for (; i < qspace_min; i++) {
size = pow2_ceil(i);
binind = ffs((int)(size >> (LG_TINY_MIN + 1)));
assert(small_size2bin[i] == binind);
}
# endif
/* Quantum-spaced. */
for (; i <= qspace_max; i++) {
size = QUANTUM_CEILING(i);
binind = ntbins + (size >> LG_QUANTUM) - 1;
assert(small_size2bin[i] == binind);
}
/* Cacheline-spaced. */
for (; i <= cspace_max; i++) {
size = CACHELINE_CEILING(i);
binind = ntbins + nqbins + ((size - cspace_min) >>
LG_CACHELINE);
assert(small_size2bin[i] == binind);
}
/* Sub-page. */
for (; i <= sspace_max; i++) {
size = SUBPAGE_CEILING(i);
binind = ntbins + nqbins + ncbins + ((size - sspace_min)
>> LG_SUBPAGE);
assert(small_size2bin[i] == binind);
}
}
#endif
static bool
small_size2bin_init(void)
{
if (opt_lg_qspace_max != LG_QSPACE_MAX_DEFAULT
|| opt_lg_cspace_max != LG_CSPACE_MAX_DEFAULT
|| sizeof(const_small_size2bin) != small_maxclass + 1)
return (small_size2bin_init_hard());
small_size2bin = const_small_size2bin;
#ifdef JEMALLOC_DEBUG
assert(sizeof(const_small_size2bin) == small_maxclass + 1);
small_size2bin_validate();
#endif
return (false);
}
static bool
small_size2bin_init_hard(void)
{
size_t i, size, binind;
uint8_t *custom_small_size2bin;
assert(opt_lg_qspace_max != LG_QSPACE_MAX_DEFAULT
|| opt_lg_cspace_max != LG_CSPACE_MAX_DEFAULT
|| sizeof(const_small_size2bin) != small_maxclass + 1);
custom_small_size2bin = (uint8_t *)base_alloc(small_maxclass + 1);
if (custom_small_size2bin == NULL)
return (true);
custom_small_size2bin[0] = 0xffU;
i = 1;
#ifdef JEMALLOC_TINY
/* Tiny. */
for (; i < (1U << LG_TINY_MIN); i++) {
size = pow2_ceil(1U << LG_TINY_MIN);
binind = ffs((int)(size >> (LG_TINY_MIN + 1)));
custom_small_size2bin[i] = binind;
}
for (; i < qspace_min; i++) {
size = pow2_ceil(i);
binind = ffs((int)(size >> (LG_TINY_MIN + 1)));
custom_small_size2bin[i] = binind;
}
#endif
/* Quantum-spaced. */
for (; i <= qspace_max; i++) {
size = QUANTUM_CEILING(i);
binind = ntbins + (size >> LG_QUANTUM) - 1;
custom_small_size2bin[i] = binind;
}
/* Cacheline-spaced. */
for (; i <= cspace_max; i++) {
size = CACHELINE_CEILING(i);
binind = ntbins + nqbins + ((size - cspace_min) >>
LG_CACHELINE);
custom_small_size2bin[i] = binind;
}
/* Sub-page. */
for (; i <= sspace_max; i++) {
size = SUBPAGE_CEILING(i);
binind = ntbins + nqbins + ncbins + ((size - sspace_min) >>
LG_SUBPAGE);
custom_small_size2bin[i] = binind;
}
small_size2bin = custom_small_size2bin;
#ifdef JEMALLOC_DEBUG
small_size2bin_validate();
#endif
return (false);
}
bool
arena_boot(void)
{
size_t header_size;
/* Set variables according to the value of opt_lg_[qc]space_max. */
qspace_max = (1U << opt_lg_qspace_max);
cspace_min = CACHELINE_CEILING(qspace_max);
if (cspace_min == qspace_max)
cspace_min += CACHELINE;
cspace_max = (1U << opt_lg_cspace_max);
sspace_min = SUBPAGE_CEILING(cspace_max);
if (sspace_min == cspace_max)
sspace_min += SUBPAGE;
assert(sspace_min < PAGE_SIZE);
sspace_max = PAGE_SIZE - SUBPAGE;
#ifdef JEMALLOC_TINY
assert(LG_QUANTUM >= LG_TINY_MIN);
#endif
assert(ntbins <= LG_QUANTUM);
nqbins = qspace_max >> LG_QUANTUM;
ncbins = ((cspace_max - cspace_min) >> LG_CACHELINE) + 1;
nsbins = ((sspace_max - sspace_min) >> LG_SUBPAGE) + 1;
nbins = ntbins + nqbins + ncbins + nsbins;
/*
* The small_size2bin lookup table uses uint8_t to encode each bin
* index, so we cannot support more than 256 small size classes. This
* limit is difficult to exceed (not even possible with 16B quantum and
* 4KiB pages), and such configurations are impractical, but
* nonetheless we need to protect against this case in order to avoid
* undefined behavior.
*
* Further constrain nbins to 255 if prof_promote is true, since all
* small size classes, plus a "not small" size class must be stored in
* 8 bits of arena_chunk_map_t's bits field.
*/
#ifdef JEMALLOC_PROF
if (opt_prof && prof_promote) {
if (nbins > 255) {
char line_buf[UMAX2S_BUFSIZE];
malloc_write("<jemalloc>: Too many small size classes (");
malloc_write(umax2s(nbins, 10, line_buf));
malloc_write(" > max 255)\n");
abort();
}
} else
#endif
if (nbins > 256) {
char line_buf[UMAX2S_BUFSIZE];
malloc_write("<jemalloc>: Too many small size classes (");
malloc_write(umax2s(nbins, 10, line_buf));
malloc_write(" > max 256)\n");
abort();
}
if (small_size2bin_init())
return (true);
/*
* Compute the header size such that it is large enough to contain the
* page map.
*/
header_size = sizeof(arena_chunk_t) +
(sizeof(arena_chunk_map_t) * (chunk_npages - 1));
arena_chunk_header_npages = (header_size >> PAGE_SHIFT) +
((header_size & PAGE_MASK) != 0);
arena_maxclass = chunksize - (arena_chunk_header_npages << PAGE_SHIFT);
return (false);
}