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|
#define JEMALLOC_C_
#include "jemalloc/internal/jemalloc_internal.h"
/******************************************************************************/
/* Data. */
malloc_tsd_data(, arenas, arena_t *, NULL)
malloc_tsd_data(, thread_allocated, thread_allocated_t,
THREAD_ALLOCATED_INITIALIZER)
/* Work around <http://llvm.org/bugs/show_bug.cgi?id=12623>: */
const char *__malloc_options_1_0 = NULL;
__sym_compat(_malloc_options, __malloc_options_1_0, FBSD_1.0);
/* Runtime configuration options. */
const char *je_malloc_conf;
bool opt_abort =
#ifdef JEMALLOC_DEBUG
true
#else
false
#endif
;
bool opt_junk =
#if (defined(JEMALLOC_DEBUG) && defined(JEMALLOC_FILL))
true
#else
false
#endif
;
size_t opt_quarantine = ZU(0);
bool opt_redzone = false;
bool opt_utrace = false;
bool opt_valgrind = false;
bool opt_xmalloc = false;
bool opt_zero = false;
size_t opt_narenas = 0;
unsigned ncpus;
malloc_mutex_t arenas_lock;
arena_t **arenas;
unsigned narenas_total;
unsigned narenas_auto;
/* Set to true once the allocator has been initialized. */
static bool malloc_initialized = false;
#ifdef JEMALLOC_THREADED_INIT
/* Used to let the initializing thread recursively allocate. */
# define NO_INITIALIZER ((unsigned long)0)
# define INITIALIZER pthread_self()
# define IS_INITIALIZER (malloc_initializer == pthread_self())
static pthread_t malloc_initializer = NO_INITIALIZER;
#else
# define NO_INITIALIZER false
# define INITIALIZER true
# define IS_INITIALIZER malloc_initializer
static bool malloc_initializer = NO_INITIALIZER;
#endif
/* Used to avoid initialization races. */
#ifdef _WIN32
static malloc_mutex_t init_lock;
JEMALLOC_ATTR(constructor)
static void WINAPI
_init_init_lock(void)
{
malloc_mutex_init(&init_lock);
}
#ifdef _MSC_VER
# pragma section(".CRT$XCU", read)
JEMALLOC_SECTION(".CRT$XCU") JEMALLOC_ATTR(used)
static const void (WINAPI *init_init_lock)(void) = _init_init_lock;
#endif
#else
static malloc_mutex_t init_lock = MALLOC_MUTEX_INITIALIZER;
#endif
typedef struct {
void *p; /* Input pointer (as in realloc(p, s)). */
size_t s; /* Request size. */
void *r; /* Result pointer. */
} malloc_utrace_t;
#ifdef JEMALLOC_UTRACE
# define UTRACE(a, b, c) do { \
if (opt_utrace) { \
int utrace_serrno = errno; \
malloc_utrace_t ut; \
ut.p = (a); \
ut.s = (b); \
ut.r = (c); \
utrace(&ut, sizeof(ut)); \
errno = utrace_serrno; \
} \
} while (0)
#else
# define UTRACE(a, b, c)
#endif
/******************************************************************************/
/* Function prototypes for non-inline static functions. */
static void stats_print_atexit(void);
static unsigned malloc_ncpus(void);
static bool malloc_conf_next(char const **opts_p, char const **k_p,
size_t *klen_p, char const **v_p, size_t *vlen_p);
static void malloc_conf_error(const char *msg, const char *k, size_t klen,
const char *v, size_t vlen);
static void malloc_conf_init(void);
static bool malloc_init_hard(void);
static int imemalign(void **memptr, size_t alignment, size_t size,
size_t min_alignment);
/******************************************************************************/
/*
* Begin miscellaneous support functions.
*/
/* Create a new arena and insert it into the arenas array at index ind. */
arena_t *
arenas_extend(unsigned ind)
{
arena_t *ret;
ret = (arena_t *)base_alloc(sizeof(arena_t));
if (ret != NULL && arena_new(ret, ind) == false) {
arenas[ind] = ret;
return (ret);
}
/* Only reached if there is an OOM error. */
/*
* OOM here is quite inconvenient to propagate, since dealing with it
* would require a check for failure in the fast path. Instead, punt
* by using arenas[0]. In practice, this is an extremely unlikely
* failure.
*/
malloc_write("<jemalloc>: Error initializing arena\n");
if (opt_abort)
abort();
return (arenas[0]);
}
/* Slow path, called only by choose_arena(). */
arena_t *
choose_arena_hard(void)
{
arena_t *ret;
if (narenas_auto > 1) {
unsigned i, choose, first_null;
choose = 0;
first_null = narenas_auto;
malloc_mutex_lock(&arenas_lock);
assert(arenas[0] != NULL);
for (i = 1; i < narenas_auto; i++) {
if (arenas[i] != NULL) {
/*
* Choose the first arena that has the lowest
* number of threads assigned to it.
*/
if (arenas[i]->nthreads <
arenas[choose]->nthreads)
choose = i;
} else if (first_null == narenas_auto) {
/*
* Record the index of the first uninitialized
* arena, in case all extant arenas are in use.
*
* NB: It is possible for there to be
* discontinuities in terms of initialized
* versus uninitialized arenas, due to the
* "thread.arena" mallctl.
*/
first_null = i;
}
}
if (arenas[choose]->nthreads == 0
|| first_null == narenas_auto) {
/*
* Use an unloaded arena, or the least loaded arena if
* all arenas are already initialized.
*/
ret = arenas[choose];
} else {
/* Initialize a new arena. */
ret = arenas_extend(first_null);
}
ret->nthreads++;
malloc_mutex_unlock(&arenas_lock);
} else {
ret = arenas[0];
malloc_mutex_lock(&arenas_lock);
ret->nthreads++;
malloc_mutex_unlock(&arenas_lock);
}
arenas_tsd_set(&ret);
return (ret);
}
static void
stats_print_atexit(void)
{
if (config_tcache && config_stats) {
unsigned narenas, i;
/*
* Merge stats from extant threads. This is racy, since
* individual threads do not lock when recording tcache stats
* events. As a consequence, the final stats may be slightly
* out of date by the time they are reported, if other threads
* continue to allocate.
*/
for (i = 0, narenas = narenas_total_get(); i < narenas; i++) {
arena_t *arena = arenas[i];
if (arena != NULL) {
tcache_t *tcache;
/*
* tcache_stats_merge() locks bins, so if any
* code is introduced that acquires both arena
* and bin locks in the opposite order,
* deadlocks may result.
*/
malloc_mutex_lock(&arena->lock);
ql_foreach(tcache, &arena->tcache_ql, link) {
tcache_stats_merge(tcache, arena);
}
malloc_mutex_unlock(&arena->lock);
}
}
}
je_malloc_stats_print(NULL, NULL, NULL);
}
/*
* End miscellaneous support functions.
*/
/******************************************************************************/
/*
* Begin initialization functions.
*/
static unsigned
malloc_ncpus(void)
{
unsigned ret;
long result;
#ifdef _WIN32
SYSTEM_INFO si;
GetSystemInfo(&si);
result = si.dwNumberOfProcessors;
#else
result = sysconf(_SC_NPROCESSORS_ONLN);
#endif
if (result == -1) {
/* Error. */
ret = 1;
} else {
ret = (unsigned)result;
}
return (ret);
}
void
arenas_cleanup(void *arg)
{
arena_t *arena = *(arena_t **)arg;
malloc_mutex_lock(&arenas_lock);
arena->nthreads--;
malloc_mutex_unlock(&arenas_lock);
}
static JEMALLOC_ATTR(always_inline) bool
malloc_init(void)
{
if (malloc_initialized == false)
return (malloc_init_hard());
return (false);
}
static bool
malloc_conf_next(char const **opts_p, char const **k_p, size_t *klen_p,
char const **v_p, size_t *vlen_p)
{
bool accept;
const char *opts = *opts_p;
*k_p = opts;
for (accept = false; accept == false;) {
switch (*opts) {
case 'A': case 'B': case 'C': case 'D': case 'E': case 'F':
case 'G': case 'H': case 'I': case 'J': case 'K': case 'L':
case 'M': case 'N': case 'O': case 'P': case 'Q': case 'R':
case 'S': case 'T': case 'U': case 'V': case 'W': case 'X':
case 'Y': case 'Z':
case 'a': case 'b': case 'c': case 'd': case 'e': case 'f':
case 'g': case 'h': case 'i': case 'j': case 'k': case 'l':
case 'm': case 'n': case 'o': case 'p': case 'q': case 'r':
case 's': case 't': case 'u': case 'v': case 'w': case 'x':
case 'y': case 'z':
case '0': case '1': case '2': case '3': case '4': case '5':
case '6': case '7': case '8': case '9':
case '_':
opts++;
break;
case ':':
opts++;
*klen_p = (uintptr_t)opts - 1 - (uintptr_t)*k_p;
*v_p = opts;
accept = true;
break;
case '\0':
if (opts != *opts_p) {
malloc_write("<jemalloc>: Conf string ends "
"with key\n");
}
return (true);
default:
malloc_write("<jemalloc>: Malformed conf string\n");
return (true);
}
}
for (accept = false; accept == false;) {
switch (*opts) {
case ',':
opts++;
/*
* Look ahead one character here, because the next time
* this function is called, it will assume that end of
* input has been cleanly reached if no input remains,
* but we have optimistically already consumed the
* comma if one exists.
*/
if (*opts == '\0') {
malloc_write("<jemalloc>: Conf string ends "
"with comma\n");
}
*vlen_p = (uintptr_t)opts - 1 - (uintptr_t)*v_p;
accept = true;
break;
case '\0':
*vlen_p = (uintptr_t)opts - (uintptr_t)*v_p;
accept = true;
break;
default:
opts++;
break;
}
}
*opts_p = opts;
return (false);
}
static void
malloc_conf_error(const char *msg, const char *k, size_t klen, const char *v,
size_t vlen)
{
malloc_printf("<jemalloc>: %s: %.*s:%.*s\n", msg, (int)klen, k,
(int)vlen, v);
}
static void
malloc_conf_init(void)
{
unsigned i;
char buf[PATH_MAX + 1];
const char *opts, *k, *v;
size_t klen, vlen;
/*
* Automatically configure valgrind before processing options. The
* valgrind option remains in jemalloc 3.x for compatibility reasons.
*/
if (config_valgrind) {
opt_valgrind = (RUNNING_ON_VALGRIND != 0) ? true : false;
if (config_fill && opt_valgrind) {
opt_junk = false;
assert(opt_zero == false);
opt_quarantine = JEMALLOC_VALGRIND_QUARANTINE_DEFAULT;
opt_redzone = true;
}
if (config_tcache && opt_valgrind)
opt_tcache = false;
}
for (i = 0; i < 3; i++) {
/* Get runtime configuration. */
switch (i) {
case 0:
if (je_malloc_conf != NULL) {
/*
* Use options that were compiled into the
* program.
*/
opts = je_malloc_conf;
} else {
/* No configuration specified. */
buf[0] = '\0';
opts = buf;
}
break;
case 1: {
#ifndef _WIN32
int linklen;
const char *linkname =
# ifdef JEMALLOC_PREFIX
"/etc/"JEMALLOC_PREFIX"malloc.conf"
# else
"/etc/malloc.conf"
# endif
;
if ((linklen = readlink(linkname, buf,
sizeof(buf) - 1)) != -1) {
/*
* Use the contents of the "/etc/malloc.conf"
* symbolic link's name.
*/
buf[linklen] = '\0';
opts = buf;
} else
#endif
{
/* No configuration specified. */
buf[0] = '\0';
opts = buf;
}
break;
} case 2: {
const char *envname =
#ifdef JEMALLOC_PREFIX
JEMALLOC_CPREFIX"MALLOC_CONF"
#else
"MALLOC_CONF"
#endif
;
if (issetugid() == 0 && (opts = getenv(envname)) !=
NULL) {
/*
* Do nothing; opts is already initialized to
* the value of the MALLOC_CONF environment
* variable.
*/
} else {
/* No configuration specified. */
buf[0] = '\0';
opts = buf;
}
break;
} default:
/* NOTREACHED */
assert(false);
buf[0] = '\0';
opts = buf;
}
while (*opts != '\0' && malloc_conf_next(&opts, &k, &klen, &v,
&vlen) == false) {
#define CONF_HANDLE_BOOL(o, n) \
if (sizeof(n)-1 == klen && strncmp(n, k, \
klen) == 0) { \
if (strncmp("true", v, vlen) == 0 && \
vlen == sizeof("true")-1) \
o = true; \
else if (strncmp("false", v, vlen) == \
0 && vlen == sizeof("false")-1) \
o = false; \
else { \
malloc_conf_error( \
"Invalid conf value", \
k, klen, v, vlen); \
} \
continue; \
}
#define CONF_HANDLE_SIZE_T(o, n, min, max, clip) \
if (sizeof(n)-1 == klen && strncmp(n, k, \
klen) == 0) { \
uintmax_t um; \
char *end; \
\
set_errno(0); \
um = malloc_strtoumax(v, &end, 0); \
if (get_errno() != 0 || (uintptr_t)end -\
(uintptr_t)v != vlen) { \
malloc_conf_error( \
"Invalid conf value", \
k, klen, v, vlen); \
} else if (clip) { \
if (um < min) \
o = min; \
else if (um > max) \
o = max; \
else \
o = um; \
} else { \
if (um < min || um > max) { \
malloc_conf_error( \
"Out-of-range " \
"conf value", \
k, klen, v, vlen); \
} else \
o = um; \
} \
continue; \
}
#define CONF_HANDLE_SSIZE_T(o, n, min, max) \
if (sizeof(n)-1 == klen && strncmp(n, k, \
klen) == 0) { \
long l; \
char *end; \
\
set_errno(0); \
l = strtol(v, &end, 0); \
if (get_errno() != 0 || (uintptr_t)end -\
(uintptr_t)v != vlen) { \
malloc_conf_error( \
"Invalid conf value", \
k, klen, v, vlen); \
} else if (l < (ssize_t)min || l > \
(ssize_t)max) { \
malloc_conf_error( \
"Out-of-range conf value", \
k, klen, v, vlen); \
} else \
o = l; \
continue; \
}
#define CONF_HANDLE_CHAR_P(o, n, d) \
if (sizeof(n)-1 == klen && strncmp(n, k, \
klen) == 0) { \
size_t cpylen = (vlen <= \
sizeof(o)-1) ? vlen : \
sizeof(o)-1; \
strncpy(o, v, cpylen); \
o[cpylen] = '\0'; \
continue; \
}
CONF_HANDLE_BOOL(opt_abort, "abort")
/*
* Chunks always require at least one header page, plus
* one data page in the absence of redzones, or three
* pages in the presence of redzones. In order to
* simplify options processing, fix the limit based on
* config_fill.
*/
CONF_HANDLE_SIZE_T(opt_lg_chunk, "lg_chunk", LG_PAGE +
(config_fill ? 2 : 1), (sizeof(size_t) << 3) - 1,
true)
if (strncmp("dss", k, klen) == 0) {
int i;
bool match = false;
for (i = 0; i < dss_prec_limit; i++) {
if (strncmp(dss_prec_names[i], v, vlen)
== 0) {
if (chunk_dss_prec_set(i)) {
malloc_conf_error(
"Error setting dss",
k, klen, v, vlen);
} else {
opt_dss =
dss_prec_names[i];
match = true;
break;
}
}
}
if (match == false) {
malloc_conf_error("Invalid conf value",
k, klen, v, vlen);
}
continue;
}
CONF_HANDLE_SIZE_T(opt_narenas, "narenas", 1,
SIZE_T_MAX, false)
CONF_HANDLE_SSIZE_T(opt_lg_dirty_mult, "lg_dirty_mult",
-1, (sizeof(size_t) << 3) - 1)
CONF_HANDLE_BOOL(opt_stats_print, "stats_print")
if (config_fill) {
CONF_HANDLE_BOOL(opt_junk, "junk")
CONF_HANDLE_SIZE_T(opt_quarantine, "quarantine",
0, SIZE_T_MAX, false)
CONF_HANDLE_BOOL(opt_redzone, "redzone")
CONF_HANDLE_BOOL(opt_zero, "zero")
}
if (config_utrace) {
CONF_HANDLE_BOOL(opt_utrace, "utrace")
}
if (config_valgrind) {
CONF_HANDLE_BOOL(opt_valgrind, "valgrind")
}
if (config_xmalloc) {
CONF_HANDLE_BOOL(opt_xmalloc, "xmalloc")
}
if (config_tcache) {
CONF_HANDLE_BOOL(opt_tcache, "tcache")
CONF_HANDLE_SSIZE_T(opt_lg_tcache_max,
"lg_tcache_max", -1,
(sizeof(size_t) << 3) - 1)
}
if (config_prof) {
CONF_HANDLE_BOOL(opt_prof, "prof")
CONF_HANDLE_CHAR_P(opt_prof_prefix,
"prof_prefix", "jeprof")
CONF_HANDLE_BOOL(opt_prof_active, "prof_active")
CONF_HANDLE_SSIZE_T(opt_lg_prof_sample,
"lg_prof_sample", 0,
(sizeof(uint64_t) << 3) - 1)
CONF_HANDLE_BOOL(opt_prof_accum, "prof_accum")
CONF_HANDLE_SSIZE_T(opt_lg_prof_interval,
"lg_prof_interval", -1,
(sizeof(uint64_t) << 3) - 1)
CONF_HANDLE_BOOL(opt_prof_gdump, "prof_gdump")
CONF_HANDLE_BOOL(opt_prof_final, "prof_final")
CONF_HANDLE_BOOL(opt_prof_leak, "prof_leak")
}
malloc_conf_error("Invalid conf pair", k, klen, v,
vlen);
#undef CONF_HANDLE_BOOL
#undef CONF_HANDLE_SIZE_T
#undef CONF_HANDLE_SSIZE_T
#undef CONF_HANDLE_CHAR_P
}
}
}
static bool
malloc_init_hard(void)
{
arena_t *init_arenas[1];
malloc_mutex_lock(&init_lock);
if (malloc_initialized || IS_INITIALIZER) {
/*
* Another thread initialized the allocator before this one
* acquired init_lock, or this thread is the initializing
* thread, and it is recursively allocating.
*/
malloc_mutex_unlock(&init_lock);
return (false);
}
#ifdef JEMALLOC_THREADED_INIT
if (malloc_initializer != NO_INITIALIZER && IS_INITIALIZER == false) {
/* Busy-wait until the initializing thread completes. */
do {
malloc_mutex_unlock(&init_lock);
CPU_SPINWAIT;
malloc_mutex_lock(&init_lock);
} while (malloc_initialized == false);
malloc_mutex_unlock(&init_lock);
return (false);
}
#endif
malloc_initializer = INITIALIZER;
malloc_tsd_boot();
if (config_prof)
prof_boot0();
malloc_conf_init();
#if (!defined(JEMALLOC_MUTEX_INIT_CB) && !defined(JEMALLOC_ZONE) \
&& !defined(_WIN32))
/* Register fork handlers. */
if (pthread_atfork(jemalloc_prefork, jemalloc_postfork_parent,
jemalloc_postfork_child) != 0) {
malloc_write("<jemalloc>: Error in pthread_atfork()\n");
if (opt_abort)
abort();
}
#endif
if (opt_stats_print) {
/* Print statistics at exit. */
if (atexit(stats_print_atexit) != 0) {
malloc_write("<jemalloc>: Error in atexit()\n");
if (opt_abort)
abort();
}
}
if (base_boot()) {
malloc_mutex_unlock(&init_lock);
return (true);
}
if (chunk_boot()) {
malloc_mutex_unlock(&init_lock);
return (true);
}
if (ctl_boot()) {
malloc_mutex_unlock(&init_lock);
return (true);
}
if (config_prof)
prof_boot1();
arena_boot();
if (config_tcache && tcache_boot0()) {
malloc_mutex_unlock(&init_lock);
return (true);
}
if (huge_boot()) {
malloc_mutex_unlock(&init_lock);
return (true);
}
if (malloc_mutex_init(&arenas_lock))
return (true);
/*
* Create enough scaffolding to allow recursive allocation in
* malloc_ncpus().
*/
narenas_total = narenas_auto = 1;
arenas = init_arenas;
memset(arenas, 0, sizeof(arena_t *) * narenas_auto);
/*
* Initialize one arena here. The rest are lazily created in
* choose_arena_hard().
*/
arenas_extend(0);
if (arenas[0] == NULL) {
malloc_mutex_unlock(&init_lock);
return (true);
}
/* Initialize allocation counters before any allocations can occur. */
if (config_stats && thread_allocated_tsd_boot()) {
malloc_mutex_unlock(&init_lock);
return (true);
}
if (arenas_tsd_boot()) {
malloc_mutex_unlock(&init_lock);
return (true);
}
if (config_tcache && tcache_boot1()) {
malloc_mutex_unlock(&init_lock);
return (true);
}
if (config_fill && quarantine_boot()) {
malloc_mutex_unlock(&init_lock);
return (true);
}
if (config_prof && prof_boot2()) {
malloc_mutex_unlock(&init_lock);
return (true);
}
/* Get number of CPUs. */
malloc_mutex_unlock(&init_lock);
ncpus = malloc_ncpus();
malloc_mutex_lock(&init_lock);
if (mutex_boot()) {
malloc_mutex_unlock(&init_lock);
return (true);
}
if (opt_narenas == 0) {
/*
* For SMP systems, create more than one arena per CPU by
* default.
*/
if (ncpus > 1)
opt_narenas = ncpus << 2;
else
opt_narenas = 1;
}
narenas_auto = opt_narenas;
/*
* Make sure that the arenas array can be allocated. In practice, this
* limit is enough to allow the allocator to function, but the ctl
* machinery will fail to allocate memory at far lower limits.
*/
if (narenas_auto > chunksize / sizeof(arena_t *)) {
narenas_auto = chunksize / sizeof(arena_t *);
malloc_printf("<jemalloc>: Reducing narenas to limit (%d)\n",
narenas_auto);
}
narenas_total = narenas_auto;
/* Allocate and initialize arenas. */
arenas = (arena_t **)base_alloc(sizeof(arena_t *) * narenas_total);
if (arenas == NULL) {
malloc_mutex_unlock(&init_lock);
return (true);
}
/*
* Zero the array. In practice, this should always be pre-zeroed,
* since it was just mmap()ed, but let's be sure.
*/
memset(arenas, 0, sizeof(arena_t *) * narenas_total);
/* Copy the pointer to the one arena that was already initialized. */
arenas[0] = init_arenas[0];
malloc_initialized = true;
malloc_mutex_unlock(&init_lock);
return (false);
}
/*
* End initialization functions.
*/
/******************************************************************************/
/*
* Begin malloc(3)-compatible functions.
*/
void *
je_malloc(size_t size)
{
void *ret;
size_t usize JEMALLOC_CC_SILENCE_INIT(0);
prof_thr_cnt_t *cnt JEMALLOC_CC_SILENCE_INIT(NULL);
if (malloc_init()) {
ret = NULL;
goto label_oom;
}
if (size == 0)
size = 1;
if (config_prof && opt_prof) {
usize = s2u(size);
PROF_ALLOC_PREP(1, usize, cnt);
if (cnt == NULL) {
ret = NULL;
goto label_oom;
}
if (prof_promote && (uintptr_t)cnt != (uintptr_t)1U && usize <=
SMALL_MAXCLASS) {
ret = imalloc(SMALL_MAXCLASS+1);
if (ret != NULL)
arena_prof_promoted(ret, usize);
} else
ret = imalloc(size);
} else {
if (config_stats || (config_valgrind && opt_valgrind))
usize = s2u(size);
ret = imalloc(size);
}
label_oom:
if (ret == NULL) {
if (config_xmalloc && opt_xmalloc) {
malloc_write("<jemalloc>: Error in malloc(): "
"out of memory\n");
abort();
}
set_errno(ENOMEM);
}
if (config_prof && opt_prof && ret != NULL)
prof_malloc(ret, usize, cnt);
if (config_stats && ret != NULL) {
assert(usize == isalloc(ret, config_prof));
thread_allocated_tsd_get()->allocated += usize;
}
UTRACE(0, size, ret);
JEMALLOC_VALGRIND_MALLOC(ret != NULL, ret, usize, false);
return (ret);
}
JEMALLOC_ATTR(nonnull(1))
#ifdef JEMALLOC_PROF
/*
* Avoid any uncertainty as to how many backtrace frames to ignore in
* PROF_ALLOC_PREP().
*/
JEMALLOC_NOINLINE
#endif
static int
imemalign(void **memptr, size_t alignment, size_t size,
size_t min_alignment)
{
int ret;
size_t usize;
void *result;
prof_thr_cnt_t *cnt JEMALLOC_CC_SILENCE_INIT(NULL);
assert(min_alignment != 0);
if (malloc_init())
result = NULL;
else {
if (size == 0)
size = 1;
/* Make sure that alignment is a large enough power of 2. */
if (((alignment - 1) & alignment) != 0
|| (alignment < min_alignment)) {
if (config_xmalloc && opt_xmalloc) {
malloc_write("<jemalloc>: Error allocating "
"aligned memory: invalid alignment\n");
abort();
}
result = NULL;
ret = EINVAL;
goto label_return;
}
usize = sa2u(size, alignment);
if (usize == 0) {
result = NULL;
ret = ENOMEM;
goto label_return;
}
if (config_prof && opt_prof) {
PROF_ALLOC_PREP(2, usize, cnt);
if (cnt == NULL) {
result = NULL;
ret = EINVAL;
} else {
if (prof_promote && (uintptr_t)cnt !=
(uintptr_t)1U && usize <= SMALL_MAXCLASS) {
assert(sa2u(SMALL_MAXCLASS+1,
alignment) != 0);
result = ipalloc(sa2u(SMALL_MAXCLASS+1,
alignment), alignment, false);
if (result != NULL) {
arena_prof_promoted(result,
usize);
}
} else {
result = ipalloc(usize, alignment,
false);
}
}
} else
result = ipalloc(usize, alignment, false);
}
if (result == NULL) {
if (config_xmalloc && opt_xmalloc) {
malloc_write("<jemalloc>: Error allocating aligned "
"memory: out of memory\n");
abort();
}
ret = ENOMEM;
goto label_return;
}
*memptr = result;
ret = 0;
label_return:
if (config_stats && result != NULL) {
assert(usize == isalloc(result, config_prof));
thread_allocated_tsd_get()->allocated += usize;
}
if (config_prof && opt_prof && result != NULL)
prof_malloc(result, usize, cnt);
UTRACE(0, size, result);
return (ret);
}
int
je_posix_memalign(void **memptr, size_t alignment, size_t size)
{
int ret = imemalign(memptr, alignment, size, sizeof(void *));
JEMALLOC_VALGRIND_MALLOC(ret == 0, *memptr, isalloc(*memptr,
config_prof), false);
return (ret);
}
void *
je_aligned_alloc(size_t alignment, size_t size)
{
void *ret;
int err;
if ((err = imemalign(&ret, alignment, size, 1)) != 0) {
ret = NULL;
set_errno(err);
}
JEMALLOC_VALGRIND_MALLOC(err == 0, ret, isalloc(ret, config_prof),
false);
return (ret);
}
void *
je_calloc(size_t num, size_t size)
{
void *ret;
size_t num_size;
size_t usize JEMALLOC_CC_SILENCE_INIT(0);
prof_thr_cnt_t *cnt JEMALLOC_CC_SILENCE_INIT(NULL);
if (malloc_init()) {
num_size = 0;
ret = NULL;
goto label_return;
}
num_size = num * size;
if (num_size == 0) {
if (num == 0 || size == 0)
num_size = 1;
else {
ret = NULL;
goto label_return;
}
/*
* Try to avoid division here. We know that it isn't possible to
* overflow during multiplication if neither operand uses any of the
* most significant half of the bits in a size_t.
*/
} else if (((num | size) & (SIZE_T_MAX << (sizeof(size_t) << 2)))
&& (num_size / size != num)) {
/* size_t overflow. */
ret = NULL;
goto label_return;
}
if (config_prof && opt_prof) {
usize = s2u(num_size);
PROF_ALLOC_PREP(1, usize, cnt);
if (cnt == NULL) {
ret = NULL;
goto label_return;
}
if (prof_promote && (uintptr_t)cnt != (uintptr_t)1U && usize
<= SMALL_MAXCLASS) {
ret = icalloc(SMALL_MAXCLASS+1);
if (ret != NULL)
arena_prof_promoted(ret, usize);
} else
ret = icalloc(num_size);
} else {
if (config_stats || (config_valgrind && opt_valgrind))
usize = s2u(num_size);
ret = icalloc(num_size);
}
label_return:
if (ret == NULL) {
if (config_xmalloc && opt_xmalloc) {
malloc_write("<jemalloc>: Error in calloc(): out of "
"memory\n");
abort();
}
set_errno(ENOMEM);
}
if (config_prof && opt_prof && ret != NULL)
prof_malloc(ret, usize, cnt);
if (config_stats && ret != NULL) {
assert(usize == isalloc(ret, config_prof));
thread_allocated_tsd_get()->allocated += usize;
}
UTRACE(0, num_size, ret);
JEMALLOC_VALGRIND_MALLOC(ret != NULL, ret, usize, true);
return (ret);
}
void *
je_realloc(void *ptr, size_t size)
{
void *ret;
size_t usize JEMALLOC_CC_SILENCE_INIT(0);
size_t old_size = 0;
size_t old_rzsize JEMALLOC_CC_SILENCE_INIT(0);
prof_thr_cnt_t *cnt JEMALLOC_CC_SILENCE_INIT(NULL);
prof_ctx_t *old_ctx JEMALLOC_CC_SILENCE_INIT(NULL);
if (size == 0) {
if (ptr != NULL) {
/* realloc(ptr, 0) is equivalent to free(p). */
if (config_prof) {
old_size = isalloc(ptr, true);
if (config_valgrind && opt_valgrind)
old_rzsize = p2rz(ptr);
} else if (config_stats) {
old_size = isalloc(ptr, false);
if (config_valgrind && opt_valgrind)
old_rzsize = u2rz(old_size);
} else if (config_valgrind && opt_valgrind) {
old_size = isalloc(ptr, false);
old_rzsize = u2rz(old_size);
}
if (config_prof && opt_prof) {
old_ctx = prof_ctx_get(ptr);
cnt = NULL;
}
iqalloc(ptr);
ret = NULL;
goto label_return;
} else
size = 1;
}
if (ptr != NULL) {
assert(malloc_initialized || IS_INITIALIZER);
if (config_prof) {
old_size = isalloc(ptr, true);
if (config_valgrind && opt_valgrind)
old_rzsize = p2rz(ptr);
} else if (config_stats) {
old_size = isalloc(ptr, false);
if (config_valgrind && opt_valgrind)
old_rzsize = u2rz(old_size);
} else if (config_valgrind && opt_valgrind) {
old_size = isalloc(ptr, false);
old_rzsize = u2rz(old_size);
}
if (config_prof && opt_prof) {
usize = s2u(size);
old_ctx = prof_ctx_get(ptr);
PROF_ALLOC_PREP(1, usize, cnt);
if (cnt == NULL) {
old_ctx = NULL;
ret = NULL;
goto label_oom;
}
if (prof_promote && (uintptr_t)cnt != (uintptr_t)1U &&
usize <= SMALL_MAXCLASS) {
ret = iralloc(ptr, SMALL_MAXCLASS+1, 0, 0,
false, false);
if (ret != NULL)
arena_prof_promoted(ret, usize);
else
old_ctx = NULL;
} else {
ret = iralloc(ptr, size, 0, 0, false, false);
if (ret == NULL)
old_ctx = NULL;
}
} else {
if (config_stats || (config_valgrind && opt_valgrind))
usize = s2u(size);
ret = iralloc(ptr, size, 0, 0, false, false);
}
label_oom:
if (ret == NULL) {
if (config_xmalloc && opt_xmalloc) {
malloc_write("<jemalloc>: Error in realloc(): "
"out of memory\n");
abort();
}
set_errno(ENOMEM);
}
} else {
/* realloc(NULL, size) is equivalent to malloc(size). */
if (config_prof && opt_prof)
old_ctx = NULL;
if (malloc_init()) {
if (config_prof && opt_prof)
cnt = NULL;
ret = NULL;
} else {
if (config_prof && opt_prof) {
usize = s2u(size);
PROF_ALLOC_PREP(1, usize, cnt);
if (cnt == NULL)
ret = NULL;
else {
if (prof_promote && (uintptr_t)cnt !=
(uintptr_t)1U && usize <=
SMALL_MAXCLASS) {
ret = imalloc(SMALL_MAXCLASS+1);
if (ret != NULL) {
arena_prof_promoted(ret,
usize);
}
} else
ret = imalloc(size);
}
} else {
if (config_stats || (config_valgrind &&
opt_valgrind))
usize = s2u(size);
ret = imalloc(size);
}
}
if (ret == NULL) {
if (config_xmalloc && opt_xmalloc) {
malloc_write("<jemalloc>: Error in realloc(): "
"out of memory\n");
abort();
}
set_errno(ENOMEM);
}
}
label_return:
if (config_prof && opt_prof)
prof_realloc(ret, usize, cnt, old_size, old_ctx);
if (config_stats && ret != NULL) {
thread_allocated_t *ta;
assert(usize == isalloc(ret, config_prof));
ta = thread_allocated_tsd_get();
ta->allocated += usize;
ta->deallocated += old_size;
}
UTRACE(ptr, size, ret);
JEMALLOC_VALGRIND_REALLOC(ret, usize, ptr, old_size, old_rzsize, false);
return (ret);
}
void
je_free(void *ptr)
{
UTRACE(ptr, 0, 0);
if (ptr != NULL) {
size_t usize;
size_t rzsize JEMALLOC_CC_SILENCE_INIT(0);
assert(malloc_initialized || IS_INITIALIZER);
if (config_prof && opt_prof) {
usize = isalloc(ptr, config_prof);
prof_free(ptr, usize);
} else if (config_stats || config_valgrind)
usize = isalloc(ptr, config_prof);
if (config_stats)
thread_allocated_tsd_get()->deallocated += usize;
if (config_valgrind && opt_valgrind)
rzsize = p2rz(ptr);
iqalloc(ptr);
JEMALLOC_VALGRIND_FREE(ptr, rzsize);
}
}
/*
* End malloc(3)-compatible functions.
*/
/******************************************************************************/
/*
* Begin non-standard override functions.
*/
#ifdef JEMALLOC_OVERRIDE_MEMALIGN
void *
je_memalign(size_t alignment, size_t size)
{
void *ret JEMALLOC_CC_SILENCE_INIT(NULL);
imemalign(&ret, alignment, size, 1);
JEMALLOC_VALGRIND_MALLOC(ret != NULL, ret, size, false);
return (ret);
}
#endif
#ifdef JEMALLOC_OVERRIDE_VALLOC
void *
je_valloc(size_t size)
{
void *ret JEMALLOC_CC_SILENCE_INIT(NULL);
imemalign(&ret, PAGE, size, 1);
JEMALLOC_VALGRIND_MALLOC(ret != NULL, ret, size, false);
return (ret);
}
#endif
/*
* is_malloc(je_malloc) is some macro magic to detect if jemalloc_defs.h has
* #define je_malloc malloc
*/
#define malloc_is_malloc 1
#define is_malloc_(a) malloc_is_ ## a
#define is_malloc(a) is_malloc_(a)
#if ((is_malloc(je_malloc) == 1) && defined(__GLIBC__) && !defined(__UCLIBC__))
/*
* glibc provides the RTLD_DEEPBIND flag for dlopen which can make it possible
* to inconsistently reference libc's malloc(3)-compatible functions
* (https://bugzilla.mozilla.org/show_bug.cgi?id=493541).
*
* These definitions interpose hooks in glibc. The functions are actually
* passed an extra argument for the caller return address, which will be
* ignored.
*/
JEMALLOC_EXPORT void (* __free_hook)(void *ptr) = je_free;
JEMALLOC_EXPORT void *(* __malloc_hook)(size_t size) = je_malloc;
JEMALLOC_EXPORT void *(* __realloc_hook)(void *ptr, size_t size) = je_realloc;
JEMALLOC_EXPORT void *(* __memalign_hook)(size_t alignment, size_t size) =
je_memalign;
#endif
/*
* End non-standard override functions.
*/
/******************************************************************************/
/*
* Begin non-standard functions.
*/
size_t
je_malloc_usable_size(JEMALLOC_USABLE_SIZE_CONST void *ptr)
{
size_t ret;
assert(malloc_initialized || IS_INITIALIZER);
if (config_ivsalloc)
ret = ivsalloc(ptr, config_prof);
else
ret = (ptr != NULL) ? isalloc(ptr, config_prof) : 0;
return (ret);
}
void
je_malloc_stats_print(void (*write_cb)(void *, const char *), void *cbopaque,
const char *opts)
{
stats_print(write_cb, cbopaque, opts);
}
int
je_mallctl(const char *name, void *oldp, size_t *oldlenp, void *newp,
size_t newlen)
{
if (malloc_init())
return (EAGAIN);
return (ctl_byname(name, oldp, oldlenp, newp, newlen));
}
int
je_mallctlnametomib(const char *name, size_t *mibp, size_t *miblenp)
{
if (malloc_init())
return (EAGAIN);
return (ctl_nametomib(name, mibp, miblenp));
}
int
je_mallctlbymib(const size_t *mib, size_t miblen, void *oldp, size_t *oldlenp,
void *newp, size_t newlen)
{
if (malloc_init())
return (EAGAIN);
return (ctl_bymib(mib, miblen, oldp, oldlenp, newp, newlen));
}
/*
* End non-standard functions.
*/
/******************************************************************************/
/*
* Begin experimental functions.
*/
#ifdef JEMALLOC_EXPERIMENTAL
static JEMALLOC_ATTR(always_inline) void *
iallocm(size_t usize, size_t alignment, bool zero, bool try_tcache,
arena_t *arena)
{
assert(usize == ((alignment == 0) ? s2u(usize) : sa2u(usize,
alignment)));
if (alignment != 0)
return (ipallocx(usize, alignment, zero, try_tcache, arena));
else if (zero)
return (icallocx(usize, try_tcache, arena));
else
return (imallocx(usize, try_tcache, arena));
}
int
je_allocm(void **ptr, size_t *rsize, size_t size, int flags)
{
void *p;
size_t usize;
size_t alignment = (ZU(1) << (flags & ALLOCM_LG_ALIGN_MASK)
& (SIZE_T_MAX-1));
bool zero = flags & ALLOCM_ZERO;
unsigned arena_ind = ((unsigned)(flags >> 8)) - 1;
arena_t *arena;
bool try_tcache;
assert(ptr != NULL);
assert(size != 0);
if (malloc_init())
goto label_oom;
if (arena_ind != UINT_MAX) {
arena = arenas[arena_ind];
try_tcache = false;
} else {
arena = NULL;
try_tcache = true;
}
usize = (alignment == 0) ? s2u(size) : sa2u(size, alignment);
if (usize == 0)
goto label_oom;
if (config_prof && opt_prof) {
prof_thr_cnt_t *cnt;
PROF_ALLOC_PREP(1, usize, cnt);
if (cnt == NULL)
goto label_oom;
if (prof_promote && (uintptr_t)cnt != (uintptr_t)1U && usize <=
SMALL_MAXCLASS) {
size_t usize_promoted = (alignment == 0) ?
s2u(SMALL_MAXCLASS+1) : sa2u(SMALL_MAXCLASS+1,
alignment);
assert(usize_promoted != 0);
p = iallocm(usize_promoted, alignment, zero,
try_tcache, arena);
if (p == NULL)
goto label_oom;
arena_prof_promoted(p, usize);
} else {
p = iallocm(usize, alignment, zero, try_tcache, arena);
if (p == NULL)
goto label_oom;
}
prof_malloc(p, usize, cnt);
} else {
p = iallocm(usize, alignment, zero, try_tcache, arena);
if (p == NULL)
goto label_oom;
}
if (rsize != NULL)
*rsize = usize;
*ptr = p;
if (config_stats) {
assert(usize == isalloc(p, config_prof));
thread_allocated_tsd_get()->allocated += usize;
}
UTRACE(0, size, p);
JEMALLOC_VALGRIND_MALLOC(true, p, usize, zero);
return (ALLOCM_SUCCESS);
label_oom:
if (config_xmalloc && opt_xmalloc) {
malloc_write("<jemalloc>: Error in allocm(): "
"out of memory\n");
abort();
}
*ptr = NULL;
UTRACE(0, size, 0);
return (ALLOCM_ERR_OOM);
}
int
je_rallocm(void **ptr, size_t *rsize, size_t size, size_t extra, int flags)
{
void *p, *q;
size_t usize;
size_t old_size;
size_t old_rzsize JEMALLOC_CC_SILENCE_INIT(0);
size_t alignment = (ZU(1) << (flags & ALLOCM_LG_ALIGN_MASK)
& (SIZE_T_MAX-1));
bool zero = flags & ALLOCM_ZERO;
bool no_move = flags & ALLOCM_NO_MOVE;
unsigned arena_ind = ((unsigned)(flags >> 8)) - 1;
bool try_tcache_alloc, try_tcache_dalloc;
arena_t *arena;
assert(ptr != NULL);
assert(*ptr != NULL);
assert(size != 0);
assert(SIZE_T_MAX - size >= extra);
assert(malloc_initialized || IS_INITIALIZER);
if (arena_ind != UINT_MAX) {
arena_chunk_t *chunk;
try_tcache_alloc = true;
chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(*ptr);
try_tcache_dalloc = (chunk == *ptr || chunk->arena !=
arenas[arena_ind]);
arena = arenas[arena_ind];
} else {
try_tcache_alloc = true;
try_tcache_dalloc = true;
arena = NULL;
}
p = *ptr;
if (config_prof && opt_prof) {
prof_thr_cnt_t *cnt;
/*
* usize isn't knowable before iralloc() returns when extra is
* non-zero. Therefore, compute its maximum possible value and
* use that in PROF_ALLOC_PREP() to decide whether to capture a
* backtrace. prof_realloc() will use the actual usize to
* decide whether to sample.
*/
size_t max_usize = (alignment == 0) ? s2u(size+extra) :
sa2u(size+extra, alignment);
prof_ctx_t *old_ctx = prof_ctx_get(p);
old_size = isalloc(p, true);
if (config_valgrind && opt_valgrind)
old_rzsize = p2rz(p);
PROF_ALLOC_PREP(1, max_usize, cnt);
if (cnt == NULL)
goto label_oom;
/*
* Use minimum usize to determine whether promotion may happen.
*/
if (prof_promote && (uintptr_t)cnt != (uintptr_t)1U
&& ((alignment == 0) ? s2u(size) : sa2u(size, alignment))
<= SMALL_MAXCLASS) {
q = irallocx(p, SMALL_MAXCLASS+1, (SMALL_MAXCLASS+1 >=
size+extra) ? 0 : size+extra - (SMALL_MAXCLASS+1),
alignment, zero, no_move, try_tcache_alloc,
try_tcache_dalloc, arena);
if (q == NULL)
goto label_err;
if (max_usize < PAGE) {
usize = max_usize;
arena_prof_promoted(q, usize);
} else
usize = isalloc(q, config_prof);
} else {
q = irallocx(p, size, extra, alignment, zero, no_move,
try_tcache_alloc, try_tcache_dalloc, arena);
if (q == NULL)
goto label_err;
usize = isalloc(q, config_prof);
}
prof_realloc(q, usize, cnt, old_size, old_ctx);
if (rsize != NULL)
*rsize = usize;
} else {
if (config_stats) {
old_size = isalloc(p, false);
if (config_valgrind && opt_valgrind)
old_rzsize = u2rz(old_size);
} else if (config_valgrind && opt_valgrind) {
old_size = isalloc(p, false);
old_rzsize = u2rz(old_size);
}
q = irallocx(p, size, extra, alignment, zero, no_move,
try_tcache_alloc, try_tcache_dalloc, arena);
if (q == NULL)
goto label_err;
if (config_stats)
usize = isalloc(q, config_prof);
if (rsize != NULL) {
if (config_stats == false)
usize = isalloc(q, config_prof);
*rsize = usize;
}
}
*ptr = q;
if (config_stats) {
thread_allocated_t *ta;
ta = thread_allocated_tsd_get();
ta->allocated += usize;
ta->deallocated += old_size;
}
UTRACE(p, size, q);
JEMALLOC_VALGRIND_REALLOC(q, usize, p, old_size, old_rzsize, zero);
return (ALLOCM_SUCCESS);
label_err:
if (no_move) {
UTRACE(p, size, q);
return (ALLOCM_ERR_NOT_MOVED);
}
label_oom:
if (config_xmalloc && opt_xmalloc) {
malloc_write("<jemalloc>: Error in rallocm(): "
"out of memory\n");
abort();
}
UTRACE(p, size, 0);
return (ALLOCM_ERR_OOM);
}
int
je_sallocm(const void *ptr, size_t *rsize, int flags)
{
size_t sz;
assert(malloc_initialized || IS_INITIALIZER);
if (config_ivsalloc)
sz = ivsalloc(ptr, config_prof);
else {
assert(ptr != NULL);
sz = isalloc(ptr, config_prof);
}
assert(rsize != NULL);
*rsize = sz;
return (ALLOCM_SUCCESS);
}
int
je_dallocm(void *ptr, int flags)
{
size_t usize;
size_t rzsize JEMALLOC_CC_SILENCE_INIT(0);
unsigned arena_ind = ((unsigned)(flags >> 8)) - 1;
bool try_tcache;
assert(ptr != NULL);
assert(malloc_initialized || IS_INITIALIZER);
if (arena_ind != UINT_MAX) {
arena_chunk_t *chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ptr);
try_tcache = (chunk == ptr || chunk->arena !=
arenas[arena_ind]);
} else
try_tcache = true;
UTRACE(ptr, 0, 0);
if (config_stats || config_valgrind)
usize = isalloc(ptr, config_prof);
if (config_prof && opt_prof) {
if (config_stats == false && config_valgrind == false)
usize = isalloc(ptr, config_prof);
prof_free(ptr, usize);
}
if (config_stats)
thread_allocated_tsd_get()->deallocated += usize;
if (config_valgrind && opt_valgrind)
rzsize = p2rz(ptr);
iqallocx(ptr, try_tcache);
JEMALLOC_VALGRIND_FREE(ptr, rzsize);
return (ALLOCM_SUCCESS);
}
int
je_nallocm(size_t *rsize, size_t size, int flags)
{
size_t usize;
size_t alignment = (ZU(1) << (flags & ALLOCM_LG_ALIGN_MASK)
& (SIZE_T_MAX-1));
assert(size != 0);
if (malloc_init())
return (ALLOCM_ERR_OOM);
usize = (alignment == 0) ? s2u(size) : sa2u(size, alignment);
if (usize == 0)
return (ALLOCM_ERR_OOM);
if (rsize != NULL)
*rsize = usize;
return (ALLOCM_SUCCESS);
}
#endif
/*
* End experimental functions.
*/
/******************************************************************************/
/*
* The following functions are used by threading libraries for protection of
* malloc during fork().
*/
/*
* If an application creates a thread before doing any allocation in the main
* thread, then calls fork(2) in the main thread followed by memory allocation
* in the child process, a race can occur that results in deadlock within the
* child: the main thread may have forked while the created thread had
* partially initialized the allocator. Ordinarily jemalloc prevents
* fork/malloc races via the following functions it registers during
* initialization using pthread_atfork(), but of course that does no good if
* the allocator isn't fully initialized at fork time. The following library
* constructor is a partial solution to this problem. It may still possible to
* trigger the deadlock described above, but doing so would involve forking via
* a library constructor that runs before jemalloc's runs.
*/
JEMALLOC_ATTR(constructor)
static void
jemalloc_constructor(void)
{
malloc_init();
}
#ifndef JEMALLOC_MUTEX_INIT_CB
void
jemalloc_prefork(void)
#else
JEMALLOC_EXPORT void
_malloc_prefork(void)
#endif
{
unsigned i;
#ifdef JEMALLOC_MUTEX_INIT_CB
if (malloc_initialized == false)
return;
#endif
assert(malloc_initialized);
/* Acquire all mutexes in a safe order. */
ctl_prefork();
malloc_mutex_prefork(&arenas_lock);
for (i = 0; i < narenas_total; i++) {
if (arenas[i] != NULL)
arena_prefork(arenas[i]);
}
prof_prefork();
chunk_prefork();
base_prefork();
huge_prefork();
}
#ifndef JEMALLOC_MUTEX_INIT_CB
void
jemalloc_postfork_parent(void)
#else
JEMALLOC_EXPORT void
_malloc_postfork(void)
#endif
{
unsigned i;
#ifdef JEMALLOC_MUTEX_INIT_CB
if (malloc_initialized == false)
return;
#endif
assert(malloc_initialized);
/* Release all mutexes, now that fork() has completed. */
huge_postfork_parent();
base_postfork_parent();
chunk_postfork_parent();
prof_postfork_parent();
for (i = 0; i < narenas_total; i++) {
if (arenas[i] != NULL)
arena_postfork_parent(arenas[i]);
}
malloc_mutex_postfork_parent(&arenas_lock);
ctl_postfork_parent();
}
void
jemalloc_postfork_child(void)
{
unsigned i;
assert(malloc_initialized);
/* Release all mutexes, now that fork() has completed. */
huge_postfork_child();
base_postfork_child();
chunk_postfork_child();
prof_postfork_child();
for (i = 0; i < narenas_total; i++) {
if (arenas[i] != NULL)
arena_postfork_child(arenas[i]);
}
malloc_mutex_postfork_child(&arenas_lock);
ctl_postfork_child();
}
/******************************************************************************/
/*
* The following functions are used for TLS allocation/deallocation in static
* binaries on FreeBSD. The primary difference between these and i[mcd]alloc()
* is that these avoid accessing TLS variables.
*/
static void *
a0alloc(size_t size, bool zero)
{
if (malloc_init())
return (NULL);
if (size == 0)
size = 1;
if (size <= arena_maxclass)
return (arena_malloc(arenas[0], size, zero, false));
else
return (huge_malloc(size, zero));
}
void *
a0malloc(size_t size)
{
return (a0alloc(size, false));
}
void *
a0calloc(size_t num, size_t size)
{
return (a0alloc(num * size, true));
}
void
a0free(void *ptr)
{
arena_chunk_t *chunk;
if (ptr == NULL)
return;
chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ptr);
if (chunk != ptr)
arena_dalloc(chunk->arena, chunk, ptr, false);
else
huge_dalloc(ptr, true);
}
/******************************************************************************/
|