User Manualjemalloc@jemalloc_version@JasonEvansAuthorJEMALLOC3jemallocjemallocgeneral purpose memory allocation functionsLIBRARYThis manual describes jemalloc @jemalloc_version@. More information
can be found at the jemalloc website.SYNOPSIS#include <jemalloc/jemalloc.h>Standard APIvoid *mallocsize_t sizevoid *callocsize_t numbersize_t sizeint posix_memalignvoid **ptrsize_t alignmentsize_t sizevoid *aligned_allocsize_t alignmentsize_t sizevoid *reallocvoid *ptrsize_t sizevoid freevoid *ptrNon-standard APIvoid *mallocxsize_t sizeint flagsvoid *rallocxvoid *ptrsize_t sizeint flagssize_t xallocxvoid *ptrsize_t sizesize_t extraint flagssize_t sallocxvoid *ptrint flagsvoid dallocxvoid *ptrint flagsvoid sdallocxvoid *ptrsize_t sizeint flagssize_t nallocxsize_t sizeint flagsint mallctlconst char *namevoid *oldpsize_t *oldlenpvoid *newpsize_t newlenint mallctlnametomibconst char *namesize_t *mibpsize_t *miblenpint mallctlbymibconst size_t *mibsize_t miblenvoid *oldpsize_t *oldlenpvoid *newpsize_t newlenvoid malloc_stats_printvoid (*write_cb)void *, const char *void *cbopaqueconst char *optssize_t malloc_usable_sizeconst void *ptrvoid (*malloc_message)void *cbopaqueconst char *sconst char *malloc_conf;DESCRIPTIONStandard APIThe malloc() function allocates
size bytes of uninitialized memory. The allocated
space is suitably aligned (after possible pointer coercion) for storage
of any type of object.The calloc() function allocates
space for number objects, each
size bytes in length. The result is identical to
calling malloc() with an argument of
number * size, with the
exception that the allocated memory is explicitly initialized to zero
bytes.The posix_memalign() function
allocates size bytes of memory such that the
allocation's base address is a multiple of
alignment, and returns the allocation in the value
pointed to by ptr. The requested
alignment must be a power of 2 at least as large as
sizeof(void *).The aligned_alloc() function
allocates size bytes of memory such that the
allocation's base address is a multiple of
alignment. The requested
alignment must be a power of 2. Behavior is
undefined if size is not an integral multiple of
alignment.The realloc() function changes the
size of the previously allocated memory referenced by
ptr to size bytes. The
contents of the memory are unchanged up to the lesser of the new and old
sizes. If the new size is larger, the contents of the newly allocated
portion of the memory are undefined. Upon success, the memory referenced
by ptr is freed and a pointer to the newly
allocated memory is returned. Note that
realloc() may move the memory allocation,
resulting in a different return value than ptr.
If ptr is NULL, the
realloc() function behaves identically to
malloc() for the specified size.The free() function causes the
allocated memory referenced by ptr to be made
available for future allocations. If ptr is
NULL, no action occurs.Non-standard APIThe mallocx(),
rallocx(),
xallocx(),
sallocx(),
dallocx(),
sdallocx(), and
nallocx() functions all have a
flags argument that can be used to specify
options. The functions only check the options that are contextually
relevant. Use bitwise or (|) operations to
specify one or more of the following:
MALLOCX_LG_ALIGN(la)
Align the memory allocation to start at an address
that is a multiple of (1 <<
la). This macro does not validate
that la is within the valid
range.MALLOCX_ALIGN(a)
Align the memory allocation to start at an address
that is a multiple of a, where
a is a power of two. This macro does not
validate that a is a power of 2.
MALLOCX_ZEROInitialize newly allocated memory to contain zero
bytes. In the growing reallocation case, the real size prior to
reallocation defines the boundary between untouched bytes and those
that are initialized to contain zero bytes. If this macro is
absent, newly allocated memory is uninitialized.MALLOCX_TCACHE(tc)
Use the thread-specific cache (tcache) specified by
the identifier tc, which must have been
acquired via the tcache.create
mallctl. This macro does not validate that
tc specifies a valid
identifier.MALLOCX_TCACHE_NONEDo not use a thread-specific cache (tcache). Unless
MALLOCX_TCACHE(tc) or
MALLOCX_TCACHE_NONE is specified, an
automatically managed tcache will be used under many circumstances.
This macro cannot be used in the same flags
argument as
MALLOCX_TCACHE(tc).MALLOCX_ARENA(a)
Use the arena specified by the index
a. This macro has no effect for regions that
were allocated via an arena other than the one specified. This
macro does not validate that a specifies an
arena index in the valid range.The mallocx() function allocates at
least size bytes of memory, and returns a pointer
to the base address of the allocation. Behavior is undefined if
size is 0.The rallocx() function resizes the
allocation at ptr to be at least
size bytes, and returns a pointer to the base
address of the resulting allocation, which may or may not have moved from
its original location. Behavior is undefined if
size is 0.The xallocx() function resizes the
allocation at ptr in place to be at least
size bytes, and returns the real size of the
allocation. If extra is non-zero, an attempt is
made to resize the allocation to be at least (size +
extra) bytes, though inability to allocate
the extra byte(s) will not by itself result in failure to resize.
Behavior is undefined if size is
0, or if (size + extra
> SIZE_T_MAX).The sallocx() function returns the
real size of the allocation at ptr.The dallocx() function causes the
memory referenced by ptr to be made available for
future allocations.The sdallocx() function is an
extension of dallocx() with a
size parameter to allow the caller to pass in the
allocation size as an optimization. The minimum valid input size is the
original requested size of the allocation, and the maximum valid input
size is the corresponding value returned by
nallocx() or
sallocx().The nallocx() function allocates no
memory, but it performs the same size computation as the
mallocx() function, and returns the real
size of the allocation that would result from the equivalent
mallocx() function call, or
0 if the inputs exceed the maximum supported size
class and/or alignment. Behavior is undefined if
size is 0.The mallctl() function provides a
general interface for introspecting the memory allocator, as well as
setting modifiable parameters and triggering actions. The
period-separated name argument specifies a
location in a tree-structured namespace; see the section for
documentation on the tree contents. To read a value, pass a pointer via
oldp to adequate space to contain the value, and a
pointer to its length via oldlenp; otherwise pass
NULL and NULL. Similarly, to
write a value, pass a pointer to the value via
newp, and its length via
newlen; otherwise pass NULL
and 0.The mallctlnametomib() function
provides a way to avoid repeated name lookups for applications that
repeatedly query the same portion of the namespace, by translating a name
to a Management Information Base (MIB) that can be passed
repeatedly to mallctlbymib(). Upon
successful return from mallctlnametomib(),
mibp contains an array of
*miblenp integers, where
*miblenp is the lesser of the number of components
in name and the input value of
*miblenp. Thus it is possible to pass a
*miblenp that is smaller than the number of
period-separated name components, which results in a partial MIB that can
be used as the basis for constructing a complete MIB. For name
components that are integers (e.g. the 2 in
arenas.bin.2.size),
the corresponding MIB component will always be that integer. Therefore,
it is legitimate to construct code like the following: The malloc_stats_print() function writes
summary statistics via the write_cb callback
function pointer and cbopaque data passed to
write_cb, or malloc_message()
if write_cb is NULL. The
statistics are presented in human-readable form unless J is
specified as a character within the opts string, in
which case the statistics are presented in JSON format. This function can be
called repeatedly. General information that never changes during
execution can be omitted by specifying g as a character
within the opts string. Note that
malloc_message() uses the
mallctl*() functions internally, so inconsistent
statistics can be reported if multiple threads use these functions
simultaneously. If is specified during
configuration, m and a can be specified to
omit merged arena and per arena statistics, respectively;
b, l, and h can be specified
to omit per size class statistics for bins, large objects, and huge
objects, respectively. Unrecognized characters are silently ignored.
Note that thread caching may prevent some statistics from being completely
up to date, since extra locking would be required to merge counters that
track thread cache operations.The malloc_usable_size() function
returns the usable size of the allocation pointed to by
ptr. The return value may be larger than the size
that was requested during allocation. The
malloc_usable_size() function is not a
mechanism for in-place realloc(); rather
it is provided solely as a tool for introspection purposes. Any
discrepancy between the requested allocation size and the size reported
by malloc_usable_size() should not be
depended on, since such behavior is entirely implementation-dependent.
TUNINGOnce, when the first call is made to one of the memory allocation
routines, the allocator initializes its internals based in part on various
options that can be specified at compile- or run-time.The string specified via , the
string pointed to by the global variable malloc_conf, the
name of the file referenced by the symbolic link named
/etc/malloc.conf, and the value of the
environment variable MALLOC_CONF, will be interpreted, in
that order, from left to right as options. Note that
malloc_conf may be read before
main() is entered, so the declaration of
malloc_conf should specify an initializer that contains
the final value to be read by jemalloc.
and malloc_conf are compile-time mechanisms, whereas
/etc/malloc.conf and
MALLOC_CONF can be safely set any time prior to program
invocation.An options string is a comma-separated list of option:value pairs.
There is one key corresponding to each opt.* mallctl (see the section for options
documentation). For example, abort:true,narenas:1 sets
the opt.abort and opt.narenas options. Some
options have boolean values (true/false), others have integer values (base
8, 10, or 16, depending on prefix), and yet others have raw string
values.IMPLEMENTATION NOTESTraditionally, allocators have used
sbrk2 to obtain memory, which is
suboptimal for several reasons, including race conditions, increased
fragmentation, and artificial limitations on maximum usable memory. If
sbrk2 is supported by the operating
system, this allocator uses both
mmap2 and
sbrk2, in that order of preference;
otherwise only mmap2 is used.This allocator uses multiple arenas in order to reduce lock
contention for threaded programs on multi-processor systems. This works
well with regard to threading scalability, but incurs some costs. There is
a small fixed per-arena overhead, and additionally, arenas manage memory
completely independently of each other, which means a small fixed increase
in overall memory fragmentation. These overheads are not generally an
issue, given the number of arenas normally used. Note that using
substantially more arenas than the default is not likely to improve
performance, mainly due to reduced cache performance. However, it may make
sense to reduce the number of arenas if an application does not make much
use of the allocation functions.In addition to multiple arenas, unless
is specified during configuration, this
allocator supports thread-specific caching for small and large objects, in
order to make it possible to completely avoid synchronization for most
allocation requests. Such caching allows very fast allocation in the
common case, but it increases memory usage and fragmentation, since a
bounded number of objects can remain allocated in each thread cache.Memory is conceptually broken into equal-sized chunks, where the chunk
size is a power of two that is greater than the page size. Chunks are
always aligned to multiples of the chunk size. This alignment makes it
possible to find metadata for user objects very quickly. User objects are
broken into three categories according to size: small, large, and huge.
Multiple small and large objects can reside within a single chunk, whereas
huge objects each have one or more chunks backing them. Each chunk that
contains small and/or large objects tracks its contents as runs of
contiguous pages (unused, backing a set of small objects, or backing one
large object). The combination of chunk alignment and chunk page maps makes
it possible to determine all metadata regarding small and large allocations
in constant time.Small objects are managed in groups by page runs. Each run maintains
a bitmap to track which regions are in use. Allocation requests that are no
more than half the quantum (8 or 16, depending on architecture) are rounded
up to the nearest power of two that is at least sizeof(double). All other object size
classes are multiples of the quantum, spaced such that there are four size
classes for each doubling in size, which limits internal fragmentation to
approximately 20% for all but the smallest size classes. Small size classes
are smaller than four times the page size, large size classes are smaller
than the chunk size (see the opt.lg_chunk option), and
huge size classes extend from the chunk size up to the largest size class
that does not exceed PTRDIFF_MAX.Allocations are packed tightly together, which can be an issue for
multi-threaded applications. If you need to assure that allocations do not
suffer from cacheline sharing, round your allocation requests up to the
nearest multiple of the cacheline size, or specify cacheline alignment when
allocating.The realloc(),
rallocx(), and
xallocx() functions may resize allocations
without moving them under limited circumstances. Unlike the
*allocx() API, the standard API does not
officially round up the usable size of an allocation to the nearest size
class, so technically it is necessary to call
realloc() to grow e.g. a 9-byte allocation to
16 bytes, or shrink a 16-byte allocation to 9 bytes. Growth and shrinkage
trivially succeeds in place as long as the pre-size and post-size both round
up to the same size class. No other API guarantees are made regarding
in-place resizing, but the current implementation also tries to resize large
and huge allocations in place, as long as the pre-size and post-size are
both large or both huge. In such cases shrinkage always succeeds for large
size classes, but for huge size classes the chunk allocator must support
splitting (see arena.<i>.chunk_hooks).
Growth only succeeds if the trailing memory is currently available, and
additionally for huge size classes the chunk allocator must support
merging.Assuming 2 MiB chunks, 4 KiB pages, and a 16-byte quantum on a
64-bit system, the size classes in each category are as shown in .
MALLCTL NAMESPACEThe following names are defined in the namespace accessible via the
mallctl*() functions. Value types are
specified in parentheses, their readable/writable statuses are encoded as
rw, r-, -w, or
--, and required build configuration flags follow, if
any. A name element encoded as <i> or
<j> indicates an integer component, where the
integer varies from 0 to some upper value that must be determined via
introspection. In the case of stats.arenas.<i>.*,
<i> equal to arenas.narenas can be
used to access the summation of statistics from all arenas. Take special
note of the epoch mallctl,
which controls refreshing of cached dynamic statistics.version
(const char *)
r-Return the jemalloc version string.epoch
(uint64_t)
rwIf a value is passed in, refresh the data from which
the mallctl*() functions report values,
and increment the epoch. Return the current epoch. This is useful for
detecting whether another thread caused a refresh.config.cache_oblivious
(bool)
r- was specified
during build configuration.config.debug
(bool)
r- was specified during
build configuration.config.fill
(bool)
r- was specified during
build configuration.config.lazy_lock
(bool)
r- was specified
during build configuration.config.malloc_conf
(const char *)
r-Embedded configure-time-specified run-time options
string, empty unless was specified
during build configuration.config.munmap
(bool)
r- was specified during
build configuration.config.prof
(bool)
r- was specified during
build configuration.config.prof_libgcc
(bool)
r- was not
specified during build configuration.config.prof_libunwind
(bool)
r- was specified
during build configuration.config.stats
(bool)
r- was specified during
build configuration.config.tcache
(bool)
r- was not specified
during build configuration.config.thp
(bool)
r- was not specified
during build configuration, and the system supports transparent huge
page manipulation.config.tls
(bool)
r- was not specified during
build configuration.config.utrace
(bool)
r- was specified during
build configuration.config.valgrind
(bool)
r- was specified during
build configuration.config.xmalloc
(bool)
r- was specified during
build configuration.opt.abort
(bool)
r-Abort-on-warning enabled/disabled. If true, most
warnings are fatal. The process will call
abort3 in these cases. This option is
disabled by default unless is
specified during configuration, in which case it is enabled by default.
opt.dss
(const char *)
r-dss (sbrk2) allocation precedence as
related to mmap2 allocation. The following
settings are supported if
sbrk2 is supported by the operating
system: disabled, primary, and
secondary; otherwise only disabled is
supported. The default is secondary if
sbrk2 is supported by the operating
system; disabled otherwise.
opt.lg_chunk
(size_t)
r-Virtual memory chunk size (log base 2). If a chunk
size outside the supported size range is specified, the size is
silently clipped to the minimum/maximum supported size. The default
chunk size is 2 MiB (2^21).
opt.narenas
(unsigned)
r-Maximum number of arenas to use for automatic
multiplexing of threads and arenas. The default is four times the
number of CPUs, or one if there is a single CPU.opt.purge
(const char *)
r-Purge mode is “ratio” (default) or
“decay”. See opt.lg_dirty_mult
for details of the ratio mode. See opt.decay_time for
details of the decay mode.opt.lg_dirty_mult
(ssize_t)
r-Per-arena minimum ratio (log base 2) of active to dirty
pages. Some dirty unused pages may be allowed to accumulate, within
the limit set by the ratio (or one chunk worth of dirty pages,
whichever is greater), before informing the kernel about some of those
pages via madvise2 or a similar system call. This
provides the kernel with sufficient information to recycle dirty pages
if physical memory becomes scarce and the pages remain unused. The
default minimum ratio is 8:1 (2^3:1); an option value of -1 will
disable dirty page purging. See arenas.lg_dirty_mult
and arena.<i>.lg_dirty_mult
for related dynamic control options.opt.decay_time
(ssize_t)
r-Approximate time in seconds from the creation of a set
of unused dirty pages until an equivalent set of unused dirty pages is
purged and/or reused. The pages are incrementally purged according to a
sigmoidal decay curve that starts and ends with zero purge rate. A
decay time of 0 causes all unused dirty pages to be purged immediately
upon creation. A decay time of -1 disables purging. The default decay
time is 10 seconds. See arenas.decay_time
and arena.<i>.decay_time
for related dynamic control options.
opt.stats_print
(bool)
r-Enable/disable statistics printing at exit. If
enabled, the malloc_stats_print()
function is called at program exit via an
atexit3 function. If
is specified during configuration, this
has the potential to cause deadlock for a multi-threaded process that
exits while one or more threads are executing in the memory allocation
functions. Furthermore, atexit() may
allocate memory during application initialization and then deadlock
internally when jemalloc in turn calls
atexit(), so this option is not
universally usable (though the application can register its own
atexit() function with equivalent
functionality). Therefore, this option should only be used with care;
it is primarily intended as a performance tuning aid during application
development. This option is disabled by default.opt.junk
(const char *)
r-
[]
Junk filling. If set to alloc, each byte
of uninitialized allocated memory will be initialized to
0xa5. If set to free, all deallocated
memory will be initialized to 0x5a. If set to
true, both allocated and deallocated memory will be
initialized, and if set to false, junk filling be
disabled entirely. This is intended for debugging and will impact
performance negatively. This option is false by default
unless is specified during
configuration, in which case it is true by default unless
running inside Valgrind.opt.quarantine
(size_t)
r-
[]
Per thread quarantine size in bytes. If non-zero, each
thread maintains a FIFO object quarantine that stores up to the
specified number of bytes of memory. The quarantined memory is not
freed until it is released from quarantine, though it is immediately
junk-filled if the opt.junk option is
enabled. This feature is of particular use in combination with Valgrind, which can detect attempts
to access quarantined objects. This is intended for debugging and will
impact performance negatively. The default quarantine size is 0 unless
running inside Valgrind, in which case the default is 16
MiB.opt.redzone
(bool)
r-
[]
Redzones enabled/disabled. If enabled, small
allocations have redzones before and after them. Furthermore, if the
opt.junk option is
enabled, the redzones are checked for corruption during deallocation.
However, the primary intended purpose of this feature is to be used in
combination with Valgrind,
which needs redzones in order to do effective buffer overflow/underflow
detection. This option is intended for debugging and will impact
performance negatively. This option is disabled by
default unless running inside Valgrind.opt.zero
(bool)
r-
[]
Zero filling enabled/disabled. If enabled, each byte
of uninitialized allocated memory will be initialized to 0. Note that
this initialization only happens once for each byte, so
realloc() and
rallocx() calls do not zero memory that
was previously allocated. This is intended for debugging and will
impact performance negatively. This option is disabled by default.
opt.utrace
(bool)
r-
[]
Allocation tracing based on
utrace2 enabled/disabled. This option
is disabled by default.opt.xmalloc
(bool)
r-
[]
Abort-on-out-of-memory enabled/disabled. If enabled,
rather than returning failure for any allocation function, display a
diagnostic message on STDERR_FILENO and cause the
program to drop core (using
abort3). If an application is
designed to depend on this behavior, set the option at compile time by
including the following in the source code:
This option is disabled by default.opt.tcache
(bool)
r-
[]
Thread-specific caching (tcache) enabled/disabled. When
there are multiple threads, each thread uses a tcache for objects up to
a certain size. Thread-specific caching allows many allocations to be
satisfied without performing any thread synchronization, at the cost of
increased memory use. See the opt.lg_tcache_max
option for related tuning information. This option is enabled by
default unless running inside Valgrind, in which case it is
forcefully disabled.opt.thp
(bool)
r-
[]
Transparent huge page (THP) integration
enabled/disabled. When enabled, THPs are explicitly disabled as a side
effect of unused dirty page purging for chunks that back small and/or
large allocations, because such chunks typically comprise active,
unused dirty, and untouched clean pages. This option is enabled by
default.opt.lg_tcache_max
(size_t)
r-
[]
Maximum size class (log base 2) to cache in the
thread-specific cache (tcache). At a minimum, all small size classes
are cached, and at a maximum all large size classes are cached. The
default maximum is 32 KiB (2^15).opt.prof
(bool)
r-
[]
Memory profiling enabled/disabled. If enabled, profile
memory allocation activity. See the opt.prof_active
option for on-the-fly activation/deactivation. See the opt.lg_prof_sample
option for probabilistic sampling control. See the opt.prof_accum
option for control of cumulative sample reporting. See the opt.lg_prof_interval
option for information on interval-triggered profile dumping, the opt.prof_gdump
option for information on high-water-triggered profile dumping, and the
opt.prof_final
option for final profile dumping. Profile output is compatible with
the jeprof command, which is based on the
pprof that is developed as part of the gperftools
package. See HEAP PROFILE
FORMAT for heap profile format documentation.opt.prof_prefix
(const char *)
r-
[]
Filename prefix for profile dumps. If the prefix is
set to the empty string, no automatic dumps will occur; this is
primarily useful for disabling the automatic final heap dump (which
also disables leak reporting, if enabled). The default prefix is
jeprof.opt.prof_active
(bool)
r-
[]
Profiling activated/deactivated. This is a secondary
control mechanism that makes it possible to start the application with
profiling enabled (see the opt.prof option) but
inactive, then toggle profiling at any time during program execution
with the prof.active mallctl.
This option is enabled by default.opt.prof_thread_active_init
(bool)
r-
[]
Initial setting for thread.prof.active
in newly created threads. The initial setting for newly created threads
can also be changed during execution via the prof.thread_active_init
mallctl. This option is enabled by default.opt.lg_prof_sample
(size_t)
r-
[]
Average interval (log base 2) between allocation
samples, as measured in bytes of allocation activity. Increasing the
sampling interval decreases profile fidelity, but also decreases the
computational overhead. The default sample interval is 512 KiB (2^19
B).opt.prof_accum
(bool)
r-
[]
Reporting of cumulative object/byte counts in profile
dumps enabled/disabled. If this option is enabled, every unique
backtrace must be stored for the duration of execution. Depending on
the application, this can impose a large memory overhead, and the
cumulative counts are not always of interest. This option is disabled
by default.opt.lg_prof_interval
(ssize_t)
r-
[]
Average interval (log base 2) between memory profile
dumps, as measured in bytes of allocation activity. The actual
interval between dumps may be sporadic because decentralized allocation
counters are used to avoid synchronization bottlenecks. Profiles are
dumped to files named according to the pattern
<prefix>.<pid>.<seq>.i<iseq>.heap,
where <prefix> is controlled by the
opt.prof_prefix
option. By default, interval-triggered profile dumping is disabled
(encoded as -1).
opt.prof_gdump
(bool)
r-
[]
Set the initial state of prof.gdump, which when
enabled triggers a memory profile dump every time the total virtual
memory exceeds the previous maximum. This option is disabled by
default.opt.prof_final
(bool)
r-
[]
Use an
atexit3 function to dump final memory
usage to a file named according to the pattern
<prefix>.<pid>.<seq>.f.heap,
where <prefix> is controlled by the opt.prof_prefix
option. Note that atexit() may allocate
memory during application initialization and then deadlock internally
when jemalloc in turn calls atexit(), so
this option is not universally usable (though the application can
register its own atexit() function with
equivalent functionality). This option is disabled by
default.opt.prof_leak
(bool)
r-
[]
Leak reporting enabled/disabled. If enabled, use an
atexit3 function to report memory leaks
detected by allocation sampling. See the
opt.prof option for
information on analyzing heap profile output. This option is disabled
by default.thread.arena
(unsigned)
rwGet or set the arena associated with the calling
thread. If the specified arena was not initialized beforehand (see the
arenas.initialized
mallctl), it will be automatically initialized as a side effect of
calling this interface.thread.allocated
(uint64_t)
r-
[]
Get the total number of bytes ever allocated by the
calling thread. This counter has the potential to wrap around; it is
up to the application to appropriately interpret the counter in such
cases.thread.allocatedp
(uint64_t *)
r-
[]
Get a pointer to the the value that is returned by the
thread.allocated
mallctl. This is useful for avoiding the overhead of repeated
mallctl*() calls.thread.deallocated
(uint64_t)
r-
[]
Get the total number of bytes ever deallocated by the
calling thread. This counter has the potential to wrap around; it is
up to the application to appropriately interpret the counter in such
cases.thread.deallocatedp
(uint64_t *)
r-
[]
Get a pointer to the the value that is returned by the
thread.deallocated
mallctl. This is useful for avoiding the overhead of repeated
mallctl*() calls.thread.tcache.enabled
(bool)
rw
[]
Enable/disable calling thread's tcache. The tcache is
implicitly flushed as a side effect of becoming
disabled (see thread.tcache.flush).
thread.tcache.flush
(void)
--
[]
Flush calling thread's thread-specific cache (tcache).
This interface releases all cached objects and internal data structures
associated with the calling thread's tcache. Ordinarily, this interface
need not be called, since automatic periodic incremental garbage
collection occurs, and the thread cache is automatically discarded when
a thread exits. However, garbage collection is triggered by allocation
activity, so it is possible for a thread that stops
allocating/deallocating to retain its cache indefinitely, in which case
the developer may find manual flushing useful.thread.prof.name
(const char *)
r- or
-w
[]
Get/set the descriptive name associated with the calling
thread in memory profile dumps. An internal copy of the name string is
created, so the input string need not be maintained after this interface
completes execution. The output string of this interface should be
copied for non-ephemeral uses, because multiple implementation details
can cause asynchronous string deallocation. Furthermore, each
invocation of this interface can only read or write; simultaneous
read/write is not supported due to string lifetime limitations. The
name string must be nil-terminated and comprised only of characters in
the sets recognized
by isgraph3 and
isblank3.thread.prof.active
(bool)
rw
[]
Control whether sampling is currently active for the
calling thread. This is an activation mechanism in addition to prof.active; both must
be active for the calling thread to sample. This flag is enabled by
default.tcache.create
(unsigned)
r-
[]
Create an explicit thread-specific cache (tcache) and
return an identifier that can be passed to the MALLOCX_TCACHE(tc)
macro to explicitly use the specified cache rather than the
automatically managed one that is used by default. Each explicit cache
can be used by only one thread at a time; the application must assure
that this constraint holds.
tcache.flush
(unsigned)
-w
[]
Flush the specified thread-specific cache (tcache). The
same considerations apply to this interface as to thread.tcache.flush,
except that the tcache will never be automatically discarded.
tcache.destroy
(unsigned)
-w
[]
Flush the specified thread-specific cache (tcache) and
make the identifier available for use during a future tcache creation.
arena.<i>.purge
(void)
--Purge all unused dirty pages for arena <i>, or for
all arenas if <i> equals arenas.narenas.
arena.<i>.decay
(void)
--Trigger decay-based purging of unused dirty pages for
arena <i>, or for all arenas if <i> equals arenas.narenas.
The proportion of unused dirty pages to be purged depends on the current
time; see opt.decay_time for
details.arena.<i>.reset
(void)
--Discard all of the arena's extant allocations. This
interface can only be used with arenas created via arenas.extend. None
of the arena's discarded/cached allocations may accessed afterward. As
part of this requirement, all thread caches which were used to
allocate/deallocate in conjunction with the arena must be flushed
beforehand. This interface cannot be used if running inside Valgrind,
nor if the quarantine size is
non-zero.arena.<i>.dss
(const char *)
rwSet the precedence of dss allocation as related to mmap
allocation for arena <i>, or for all arenas if <i> equals
arenas.narenas. See
opt.dss for supported
settings.arena.<i>.lg_dirty_mult
(ssize_t)
rwCurrent per-arena minimum ratio (log base 2) of active
to dirty pages for arena <i>. Each time this interface is set and
the ratio is increased, pages are synchronously purged as necessary to
impose the new ratio. See opt.lg_dirty_mult
for additional information.arena.<i>.decay_time
(ssize_t)
rwCurrent per-arena approximate time in seconds from the
creation of a set of unused dirty pages until an equivalent set of
unused dirty pages is purged and/or reused. Each time this interface is
set, all currently unused dirty pages are considered to have fully
decayed, which causes immediate purging of all unused dirty pages unless
the decay time is set to -1 (i.e. purging disabled). See opt.decay_time for
additional information.arena.<i>.chunk_hooks
(chunk_hooks_t)
rwGet or set the chunk management hook functions for arena
<i>. The functions must be capable of operating on all extant
chunks associated with arena <i>, usually by passing unknown
chunks to the replaced functions. In practice, it is feasible to
control allocation for arenas created via arenas.extend such
that all chunks originate from an application-supplied chunk allocator
(by setting custom chunk hook functions just after arena creation), but
the automatically created arenas may have already created chunks prior
to the application having an opportunity to take over chunk
allocation.The chunk_hooks_t structure comprises function
pointers which are described individually below. jemalloc uses these
functions to manage chunk lifetime, which starts off with allocation of
mapped committed memory, in the simplest case followed by deallocation.
However, there are performance and platform reasons to retain chunks for
later reuse. Cleanup attempts cascade from deallocation to decommit to
purging, which gives the chunk management functions opportunities to
reject the most permanent cleanup operations in favor of less permanent
(and often less costly) operations. The chunk splitting and merging
operations can also be opted out of, but this is mainly intended to
support platforms on which virtual memory mappings provided by the
operating system kernel do not automatically coalesce and split, e.g.
Windows.typedef void *(chunk_alloc_t)void *chunksize_t sizesize_t alignmentbool *zerobool *commitunsigned arena_indA chunk allocation function conforms to the
chunk_alloc_t type and upon success returns a pointer to
size bytes of mapped memory on behalf of arena
arena_ind such that the chunk's base address is a
multiple of alignment, as well as setting
*zero to indicate whether the chunk is zeroed and
*commit to indicate whether the chunk is
committed. Upon error the function returns NULL
and leaves *zero and
*commit unmodified. The
size parameter is always a multiple of the chunk
size. The alignment parameter is always a power
of two at least as large as the chunk size. Zeroing is mandatory if
*zero is true upon function entry. Committing is
mandatory if *commit is true upon function entry.
If chunk is not NULL, the
returned pointer must be chunk on success or
NULL on error. Committed memory may be committed
in absolute terms as on a system that does not overcommit, or in
implicit terms as on a system that overcommits and satisfies physical
memory needs on demand via soft page faults. Note that replacing the
default chunk allocation function makes the arena's arena.<i>.dss
setting irrelevant.typedef bool (chunk_dalloc_t)void *chunksize_t sizebool committedunsigned arena_ind
A chunk deallocation function conforms to the
chunk_dalloc_t type and deallocates a
chunk of given size with
committed/decommited memory as indicated, on
behalf of arena arena_ind, returning false upon
success. If the function returns true, this indicates opt-out from
deallocation; the virtual memory mapping associated with the chunk
remains mapped, in the same commit state, and available for future use,
in which case it will be automatically retained for later reuse.typedef bool (chunk_commit_t)void *chunksize_t sizesize_t offsetsize_t lengthunsigned arena_indA chunk commit function conforms to the
chunk_commit_t type and commits zeroed physical memory to
back pages within a chunk of given
size at offset bytes,
extending for length on behalf of arena
arena_ind, returning false upon success.
Committed memory may be committed in absolute terms as on a system that
does not overcommit, or in implicit terms as on a system that
overcommits and satisfies physical memory needs on demand via soft page
faults. If the function returns true, this indicates insufficient
physical memory to satisfy the request.typedef bool (chunk_decommit_t)void *chunksize_t sizesize_t offsetsize_t lengthunsigned arena_indA chunk decommit function conforms to the
chunk_decommit_t type and decommits any physical memory
that is backing pages within a chunk of given
size at offset bytes,
extending for length on behalf of arena
arena_ind, returning false upon success, in which
case the pages will be committed via the chunk commit function before
being reused. If the function returns true, this indicates opt-out from
decommit; the memory remains committed and available for future use, in
which case it will be automatically retained for later reuse.typedef bool (chunk_purge_t)void *chunksize_tsizesize_t offsetsize_t lengthunsigned arena_indA chunk purge function conforms to the chunk_purge_t
type and optionally discards physical pages within the virtual memory
mapping associated with chunk of given
size at offset bytes,
extending for length on behalf of arena
arena_ind, returning false if pages within the
purged virtual memory range will be zero-filled the next time they are
accessed.typedef bool (chunk_split_t)void *chunksize_t sizesize_t size_asize_t size_bbool committedunsigned arena_indA chunk split function conforms to the chunk_split_t
type and optionally splits chunk of given
size into two adjacent chunks, the first of
size_a bytes, and the second of
size_b bytes, operating on
committed/decommitted memory as indicated, on
behalf of arena arena_ind, returning false upon
success. If the function returns true, this indicates that the chunk
remains unsplit and therefore should continue to be operated on as a
whole.typedef bool (chunk_merge_t)void *chunk_asize_t size_avoid *chunk_bsize_t size_bbool committedunsigned arena_indA chunk merge function conforms to the chunk_merge_t
type and optionally merges adjacent chunks,
chunk_a of given size_a
and chunk_b of given
size_b into one contiguous chunk, operating on
committed/decommitted memory as indicated, on
behalf of arena arena_ind, returning false upon
success. If the function returns true, this indicates that the chunks
remain distinct mappings and therefore should continue to be operated on
independently.arenas.narenas
(unsigned)
r-Current limit on number of arenas.arenas.initialized
(bool *)
r-An array of arenas.narenas
booleans. Each boolean indicates whether the corresponding arena is
initialized.arenas.lg_dirty_mult
(ssize_t)
rwCurrent default per-arena minimum ratio (log base 2) of
active to dirty pages, used to initialize arena.<i>.lg_dirty_mult
during arena creation. See opt.lg_dirty_mult
for additional information.arenas.decay_time
(ssize_t)
rwCurrent default per-arena approximate time in seconds
from the creation of a set of unused dirty pages until an equivalent set
of unused dirty pages is purged and/or reused, used to initialize arena.<i>.decay_time
during arena creation. See opt.decay_time for
additional information.arenas.quantum
(size_t)
r-Quantum size.arenas.page
(size_t)
r-Page size.arenas.tcache_max
(size_t)
r-
[]
Maximum thread-cached size class.arenas.nbins
(unsigned)
r-Number of bin size classes.arenas.nhbins
(unsigned)
r-
[]
Total number of thread cache bin size
classes.arenas.bin.<i>.size
(size_t)
r-Maximum size supported by size class.arenas.bin.<i>.nregs
(uint32_t)
r-Number of regions per page run.arenas.bin.<i>.run_size
(size_t)
r-Number of bytes per page run.arenas.nlruns
(unsigned)
r-Total number of large size classes.arenas.lrun.<i>.size
(size_t)
r-Maximum size supported by this large size
class.arenas.nhchunks
(unsigned)
r-Total number of huge size classes.arenas.hchunk.<i>.size
(size_t)
r-Maximum size supported by this huge size
class.arenas.extend
(unsigned)
r-Extend the array of arenas by appending a new arena,
and returning the new arena index.prof.thread_active_init
(bool)
rw
[]
Control the initial setting for thread.prof.active
in newly created threads. See the opt.prof_thread_active_init
option for additional information.prof.active
(bool)
rw
[]
Control whether sampling is currently active. See the
opt.prof_active
option for additional information, as well as the interrelated thread.prof.active
mallctl.prof.dump
(const char *)
-w
[]
Dump a memory profile to the specified file, or if NULL
is specified, to a file according to the pattern
<prefix>.<pid>.<seq>.m<mseq>.heap,
where <prefix> is controlled by the
opt.prof_prefix
option.prof.gdump
(bool)
rw
[]
When enabled, trigger a memory profile dump every time
the total virtual memory exceeds the previous maximum. Profiles are
dumped to files named according to the pattern
<prefix>.<pid>.<seq>.u<useq>.heap,
where <prefix> is controlled by the opt.prof_prefix
option.prof.reset
(size_t)
-w
[]
Reset all memory profile statistics, and optionally
update the sample rate (see opt.lg_prof_sample
and prof.lg_sample).
prof.lg_sample
(size_t)
r-
[]
Get the current sample rate (see opt.lg_prof_sample).
prof.interval
(uint64_t)
r-
[]
Average number of bytes allocated between
interval-based profile dumps. See the
opt.lg_prof_interval
option for additional information.stats.cactive
(size_t *)
r-
[]
Pointer to a counter that contains an approximate count
of the current number of bytes in active pages. The estimate may be
high, but never low, because each arena rounds up when computing its
contribution to the counter. Note that the epoch mallctl has no bearing
on this counter. Furthermore, counter consistency is maintained via
atomic operations, so it is necessary to use an atomic operation in
order to guarantee a consistent read when dereferencing the pointer.
stats.allocated
(size_t)
r-
[]
Total number of bytes allocated by the
application.stats.active
(size_t)
r-
[]
Total number of bytes in active pages allocated by the
application. This is a multiple of the page size, and greater than or
equal to stats.allocated.
This does not include
stats.arenas.<i>.pdirty, nor pages
entirely devoted to allocator metadata.stats.metadata
(size_t)
r-
[]
Total number of bytes dedicated to metadata, which
comprise base allocations used for bootstrap-sensitive internal
allocator data structures, arena chunk headers (see stats.arenas.<i>.metadata.mapped),
and internal allocations (see stats.arenas.<i>.metadata.allocated).stats.resident
(size_t)
r-
[]
Maximum number of bytes in physically resident data
pages mapped by the allocator, comprising all pages dedicated to
allocator metadata, pages backing active allocations, and unused dirty
pages. This is a maximum rather than precise because pages may not
actually be physically resident if they correspond to demand-zeroed
virtual memory that has not yet been touched. This is a multiple of the
page size, and is larger than stats.active.stats.mapped
(size_t)
r-
[]
Total number of bytes in active chunks mapped by the
allocator. This is a multiple of the chunk size, and is larger than
stats.active.
This does not include inactive chunks, even those that contain unused
dirty pages, which means that there is no strict ordering between this
and stats.resident.stats.retained
(size_t)
r-
[]
Total number of bytes in virtual memory mappings that
were retained rather than being returned to the operating system via
e.g. munmap2. Retained virtual memory is
typically untouched, decommitted, or purged, so it has no strongly
associated physical memory (see chunk hooks for details). Retained
memory is excluded from mapped memory statistics, e.g. stats.mapped.
stats.arenas.<i>.dss
(const char *)
r-dss (sbrk2) allocation precedence as
related to mmap2 allocation. See opt.dss for details.
stats.arenas.<i>.lg_dirty_mult
(ssize_t)
r-Minimum ratio (log base 2) of active to dirty pages.
See opt.lg_dirty_mult
for details.stats.arenas.<i>.decay_time
(ssize_t)
r-Approximate time in seconds from the creation of a set
of unused dirty pages until an equivalent set of unused dirty pages is
purged and/or reused. See opt.decay_time
for details.stats.arenas.<i>.nthreads
(unsigned)
r-Number of threads currently assigned to
arena.stats.arenas.<i>.pactive
(size_t)
r-Number of pages in active runs.stats.arenas.<i>.pdirty
(size_t)
r-Number of pages within unused runs that are potentially
dirty, and for which madvise...MADV_DONTNEED or
similar has not been called.stats.arenas.<i>.mapped
(size_t)
r-
[]
Number of mapped bytes.stats.arenas.<i>.retained
(size_t)
r-
[]
Number of retained bytes. See stats.retained for
details.stats.arenas.<i>.metadata.mapped
(size_t)
r-
[]
Number of mapped bytes in arena chunk headers, which
track the states of the non-metadata pages.stats.arenas.<i>.metadata.allocated
(size_t)
r-
[]
Number of bytes dedicated to internal allocations.
Internal allocations differ from application-originated allocations in
that they are for internal use, and that they are omitted from heap
profiles. This statistic is reported separately from stats.metadata and
stats.arenas.<i>.metadata.mapped
because it overlaps with e.g. the stats.allocated and
stats.active
statistics, whereas the other metadata statistics do
not.stats.arenas.<i>.npurge
(uint64_t)
r-
[]
Number of dirty page purge sweeps performed.
stats.arenas.<i>.nmadvise
(uint64_t)
r-
[]
Number of madvise...MADV_DONTNEED or
similar calls made to purge dirty pages.stats.arenas.<i>.purged
(uint64_t)
r-
[]
Number of pages purged.stats.arenas.<i>.small.allocated
(size_t)
r-
[]
Number of bytes currently allocated by small objects.
stats.arenas.<i>.small.nmalloc
(uint64_t)
r-
[]
Cumulative number of allocation requests served by
small bins.stats.arenas.<i>.small.ndalloc
(uint64_t)
r-
[]
Cumulative number of small objects returned to bins.
stats.arenas.<i>.small.nrequests
(uint64_t)
r-
[]
Cumulative number of small allocation requests.
stats.arenas.<i>.large.allocated
(size_t)
r-
[]
Number of bytes currently allocated by large objects.
stats.arenas.<i>.large.nmalloc
(uint64_t)
r-
[]
Cumulative number of large allocation requests served
directly by the arena.stats.arenas.<i>.large.ndalloc
(uint64_t)
r-
[]
Cumulative number of large deallocation requests served
directly by the arena.stats.arenas.<i>.large.nrequests
(uint64_t)
r-
[]
Cumulative number of large allocation requests.
stats.arenas.<i>.huge.allocated
(size_t)
r-
[]
Number of bytes currently allocated by huge objects.
stats.arenas.<i>.huge.nmalloc
(uint64_t)
r-
[]
Cumulative number of huge allocation requests served
directly by the arena.stats.arenas.<i>.huge.ndalloc
(uint64_t)
r-
[]
Cumulative number of huge deallocation requests served
directly by the arena.stats.arenas.<i>.huge.nrequests
(uint64_t)
r-
[]
Cumulative number of huge allocation requests.
stats.arenas.<i>.bins.<j>.nmalloc
(uint64_t)
r-
[]
Cumulative number of allocations served by bin.
stats.arenas.<i>.bins.<j>.ndalloc
(uint64_t)
r-
[]
Cumulative number of allocations returned to bin.
stats.arenas.<i>.bins.<j>.nrequests
(uint64_t)
r-
[]
Cumulative number of allocation
requests.stats.arenas.<i>.bins.<j>.curregs
(size_t)
r-
[]
Current number of regions for this size
class.stats.arenas.<i>.bins.<j>.nfills
(uint64_t)
r-
[ ]
Cumulative number of tcache fills.stats.arenas.<i>.bins.<j>.nflushes
(uint64_t)
r-
[ ]
Cumulative number of tcache flushes.stats.arenas.<i>.bins.<j>.nruns
(uint64_t)
r-
[]
Cumulative number of runs created.stats.arenas.<i>.bins.<j>.nreruns
(uint64_t)
r-
[]
Cumulative number of times the current run from which
to allocate changed.stats.arenas.<i>.bins.<j>.curruns
(size_t)
r-
[]
Current number of runs.stats.arenas.<i>.lruns.<j>.nmalloc
(uint64_t)
r-
[]
Cumulative number of allocation requests for this size
class served directly by the arena.stats.arenas.<i>.lruns.<j>.ndalloc
(uint64_t)
r-
[]
Cumulative number of deallocation requests for this
size class served directly by the arena.stats.arenas.<i>.lruns.<j>.nrequests
(uint64_t)
r-
[]
Cumulative number of allocation requests for this size
class.stats.arenas.<i>.lruns.<j>.curruns
(size_t)
r-
[]
Current number of runs for this size class.
stats.arenas.<i>.hchunks.<j>.nmalloc
(uint64_t)
r-
[]
Cumulative number of allocation requests for this size
class served directly by the arena.stats.arenas.<i>.hchunks.<j>.ndalloc
(uint64_t)
r-
[]
Cumulative number of deallocation requests for this
size class served directly by the arena.stats.arenas.<i>.hchunks.<j>.nrequests
(uint64_t)
r-
[]
Cumulative number of allocation requests for this size
class.stats.arenas.<i>.hchunks.<j>.curhchunks
(size_t)
r-
[]
Current number of huge allocations for this size class.
HEAP PROFILE FORMATAlthough the heap profiling functionality was originally designed to
be compatible with the
pprof command that is developed as part of the gperftools
package, the addition of per thread heap profiling functionality
required a different heap profile format. The jeprof
command is derived from pprof, with enhancements to
support the heap profile format described here.In the following hypothetical heap profile, [...]
indicates elision for the sake of compactness. The following matches the above heap profile, but most
tokens are replaced with <description> to indicate
descriptions of the corresponding fields. /: : [: ]
[...]
: : [: ]
[...]
: : [: ]
[...]
@ [...] [...]
: : [: ]
: : [: ]
: : [: ]
[...]
MAPPED_LIBRARIES:
/maps>]]>DEBUGGING MALLOC PROBLEMSWhen debugging, it is a good idea to configure/build jemalloc with
the and
options, and recompile the program with suitable options and symbols for
debugger support. When so configured, jemalloc incorporates a wide variety
of run-time assertions that catch application errors such as double-free,
write-after-free, etc.Programs often accidentally depend on uninitialized
memory actually being filled with zero bytes. Junk filling
(see the opt.junk
option) tends to expose such bugs in the form of obviously incorrect
results and/or coredumps. Conversely, zero
filling (see the opt.zero option) eliminates
the symptoms of such bugs. Between these two options, it is usually
possible to quickly detect, diagnose, and eliminate such bugs.This implementation does not provide much detail about the problems
it detects, because the performance impact for storing such information
would be prohibitive. However, jemalloc does integrate with the most
excellent Valgrind tool if the
configuration option is enabled.DIAGNOSTIC MESSAGESIf any of the memory allocation/deallocation functions detect an
error or warning condition, a message will be printed to file descriptor
STDERR_FILENO. Errors will result in the process
dumping core. If the opt.abort option is set, most
warnings are treated as errors.The malloc_message variable allows the programmer
to override the function which emits the text strings forming the errors
and warnings if for some reason the STDERR_FILENO file
descriptor is not suitable for this.
malloc_message() takes the
cbopaque pointer argument that is
NULL unless overridden by the arguments in a call to
malloc_stats_print(), followed by a string
pointer. Please note that doing anything which tries to allocate memory in
this function is likely to result in a crash or deadlock.All messages are prefixed by
<jemalloc>: .RETURN VALUESStandard APIThe malloc() and
calloc() functions return a pointer to the
allocated memory if successful; otherwise a NULL
pointer is returned and errno is set to
ENOMEM.The posix_memalign() function
returns the value 0 if successful; otherwise it returns an error value.
The posix_memalign() function will fail
if:
EINVALThe alignment parameter is
not a power of 2 at least as large as
sizeof(void *).
ENOMEMMemory allocation error.The aligned_alloc() function returns
a pointer to the allocated memory if successful; otherwise a
NULL pointer is returned and
errno is set. The
aligned_alloc() function will fail if:
EINVALThe alignment parameter is
not a power of 2.
ENOMEMMemory allocation error.The realloc() function returns a
pointer, possibly identical to ptr, to the
allocated memory if successful; otherwise a NULL
pointer is returned, and errno is set to
ENOMEM if the error was the result of an
allocation failure. The realloc()
function always leaves the original buffer intact when an error occurs.
The free() function returns no
value.Non-standard APIThe mallocx() and
rallocx() functions return a pointer to
the allocated memory if successful; otherwise a NULL
pointer is returned to indicate insufficient contiguous memory was
available to service the allocation request. The xallocx() function returns the
real size of the resulting resized allocation pointed to by
ptr, which is a value less than
size if the allocation could not be adequately
grown in place. The sallocx() function returns the
real size of the allocation pointed to by ptr.
The nallocx() returns the real size
that would result from a successful equivalent
mallocx() function call, or zero if
insufficient memory is available to perform the size computation. The mallctl(),
mallctlnametomib(), and
mallctlbymib() functions return 0 on
success; otherwise they return an error value. The functions will fail
if:
EINVALnewp is not
NULL, and newlen is too
large or too small. Alternatively, *oldlenp
is too large or too small; in this case as much data as possible
are read despite the error.ENOENTname or
mib specifies an unknown/invalid
value.EPERMAttempt to read or write void value, or attempt to
write read-only value.EAGAINA memory allocation failure
occurred.EFAULTAn interface with side effects failed in some way
not directly related to mallctl*()
read/write processing.The malloc_usable_size() function
returns the usable size of the allocation pointed to by
ptr. ENVIRONMENTThe following environment variable affects the execution of the
allocation functions:
MALLOC_CONFIf the environment variable
MALLOC_CONF is set, the characters it contains
will be interpreted as options.EXAMPLESTo dump core whenever a problem occurs:
ln -s 'abort:true' /etc/malloc.confTo specify in the source a chunk size that is 16 MiB:
SEE ALSOmadvise2,
mmap2,
sbrk2,
utrace2,
alloca3,
atexit3,
getpagesize3STANDARDSThe malloc(),
calloc(),
realloc(), and
free() functions conform to ISO/IEC
9899:1990 (ISO C90).The posix_memalign() function conforms
to IEEE Std 1003.1-2001 (POSIX.1).