gecko-dev/memory/jemalloc/jemalloc.h

178 строки
6.3 KiB
C

#ifndef MOZ_MEMORY_WINDOWS
# include <stdbool.h>
#else
# include <windows.h>
# ifndef bool
# define bool BOOL
# endif
#endif
extern const char *_malloc_options;
/*
* jemalloc_stats() is not a stable interface. When using jemalloc_stats_t, be
* sure that the compiled results of jemalloc.c are in sync with this header
* file.
*/
typedef struct {
/*
* Run-time configuration settings.
*/
bool opt_abort; /* abort(3) on error? */
bool opt_junk; /* Fill allocated/free memory with 0xa5/0x5a? */
bool opt_utrace; /* Trace all allocation events? */
bool opt_sysv; /* SysV semantics? */
bool opt_xmalloc; /* abort(3) on OOM? */
bool opt_zero; /* Fill allocated memory with 0x0? */
size_t narenas; /* Number of arenas. */
size_t balance_threshold; /* Arena contention rebalance threshold. */
size_t quantum; /* Allocation quantum. */
size_t small_max; /* Max quantum-spaced allocation size. */
size_t large_max; /* Max sub-chunksize allocation size. */
size_t chunksize; /* Size of each virtual memory mapping. */
size_t dirty_max; /* Max dirty pages per arena. */
size_t reserve_min; /* reserve_low callback threshold. */
size_t reserve_max; /* Maximum reserve size before unmapping. */
/*
* Current memory usage statistics.
*/
size_t mapped; /* Bytes mapped (not necessarily committed). */
size_t committed; /* Bytes committed (readable/writable). */
size_t allocated; /* Bytes allocted (in use by application). */
size_t dirty; /* Bytes dirty (committed unused pages). */
size_t reserve_cur; /* Current memory reserve. */
} jemalloc_stats_t;
#ifndef MOZ_MEMORY_DARWIN
void *malloc(size_t size);
void *valloc(size_t size);
void *calloc(size_t num, size_t size);
void *realloc(void *ptr, size_t size);
void free(void *ptr);
#endif
int posix_memalign(void **memptr, size_t alignment, size_t size);
void *memalign(size_t alignment, size_t size);
size_t malloc_usable_size(const void *ptr);
void jemalloc_stats(jemalloc_stats_t *stats);
/* The x*() functions never return NULL. */
void *xmalloc(size_t size);
void *xcalloc(size_t num, size_t size);
void *xrealloc(void *ptr, size_t size);
void *xmemalign(size_t alignment, size_t size);
/*
* The allocator maintains a memory reserve that is used to satisfy allocation
* requests when no additional memory can be acquired from the operating
* system. Under normal operating conditions, the reserve size is at least
* reserve_min bytes. If the reserve is depleted or insufficient to satisfy an
* allocation request, then condition notifications are sent to one or more of
* the registered callback functions:
*
* RESERVE_CND_LOW: The reserve had to be used to satisfy an allocation
* request, which dropped the reserve size below the
* minimum. The callee should try to free memory in order
* to restore the reserve.
*
* RESERVE_CND_CRIT: The reserve was not large enough to satisfy a pending
* allocation request. Some callee must free adequate
* memory in order to prevent application failure (unless
* the condition spontaneously desists due to concurrent
* deallocation).
*
* RESERVE_CND_FAIL: An allocation request could not be satisfied, despite all
* attempts. The allocator is about to terminate the
* application.
*
* The order in which the callback functions are called is only loosely
* specified: in the absence of interposing callback
* registrations/unregistrations, enabled callbacks will be called in an
* arbitrary round-robin order.
*
* Condition notifications are sent to callbacks only while conditions exist.
* For example, just before the allocator sends a RESERVE_CND_LOW condition
* notification to a callback, the reserve is in fact depleted. However, due
* to allocator concurrency, the reserve may have been restored by the time the
* callback function executes. Furthermore, if the reserve is restored at some
* point during the delivery of condition notifications to callbacks, no
* further deliveries will occur, since the condition no longer exists.
*
* Callback functions can freely call back into the allocator (i.e. the
* allocator releases all internal resources before calling each callback
* function), though allocation is discouraged, since recursive callbacks are
* likely to result, which places extra burden on the application to avoid
* deadlock.
*
* Callback functions must be thread-safe, since it is possible that multiple
* threads will call into the same callback function concurrently.
*/
/* Memory reserve condition types. */
typedef enum {
RESERVE_CND_LOW,
RESERVE_CND_CRIT,
RESERVE_CND_FAIL
} reserve_cnd_t;
/*
* Reserve condition notification callback function type definition.
*
* Inputs:
* ctx: Opaque application data, as passed to reserve_cb_register().
* cnd: Condition type being delivered.
* size: Allocation request size for the allocation that caused the condition.
*/
typedef void reserve_cb_t(void *ctx, reserve_cnd_t cnd, size_t size);
/*
* Register a callback function.
*
* Inputs:
* cb: Callback function pointer.
* ctx: Opaque application data, passed to cb().
*
* Output:
* ret: If true, failure due to OOM; success otherwise.
*/
bool reserve_cb_register(reserve_cb_t *cb, void *ctx);
/*
* Unregister a callback function.
*
* Inputs:
* cb: Callback function pointer.
* ctx: Opaque application data, same as that passed to reserve_cb_register().
*
* Output:
* ret: False upon success, true if the {cb,ctx} registration could not be
* found.
*/
bool reserve_cb_unregister(reserve_cb_t *cb, void *ctx);
/*
* Get the current reserve size.
*
* ret: Current reserve size.
*/
size_t reserve_cur_get(void);
/*
* Get the minimum acceptable reserve size. If the reserve drops below this
* value, the RESERVE_CND_LOW condition notification is sent to the callbacks.
*
* ret: Minimum acceptable reserve size.
*/
size_t reserve_min_get(void);
/*
* Set the minimum acceptable reserve size.
*
* min: Reserve threshold. This value may be internally rounded up.
* ret: False if the reserve was successfully resized; true otherwise. Note
* that failure to resize the reserve also results in a RESERVE_CND_LOW
* condition.
*/
bool reserve_min_set(size_t min);