server-skynet-source-3rd-je.../include/jemalloc/internal/rtree.h

/*
 * This radix tree implementation is tailored to the singular purpose of
 * tracking which chunks are currently owned by jemalloc.  This functionality
 * is mandatory for OS X, where jemalloc must be able to respond to object
 * ownership queries.
 *
 *******************************************************************************
 */
#ifdef JEMALLOC_H_TYPES

typedef struct rtree_s rtree_t;

/*
 * Size of each radix tree node (must be a power of 2).  This impacts tree
 * depth.
 */
#if (LG_SIZEOF_PTR == 2)
#  define RTREE_NODESIZE (1U << 14)
#else
#  define RTREE_NODESIZE CACHELINE
#endif

#endif /* JEMALLOC_H_TYPES */
/******************************************************************************/
#ifdef JEMALLOC_H_STRUCTS

struct rtree_s {
	malloc_mutex_t	mutex;
	void		**root;
	unsigned	height;
	unsigned	level2bits[1]; /* Dynamically sized. */
};

#endif /* JEMALLOC_H_STRUCTS */
/******************************************************************************/
#ifdef JEMALLOC_H_EXTERNS

rtree_t	*rtree_new(unsigned bits);
void	rtree_prefork(rtree_t *rtree);
void	rtree_postfork_parent(rtree_t *rtree);
void	rtree_postfork_child(rtree_t *rtree);

#endif /* JEMALLOC_H_EXTERNS */
/******************************************************************************/
#ifdef JEMALLOC_H_INLINES

#ifndef JEMALLOC_ENABLE_INLINE
#ifndef JEMALLOC_DEBUG
void	*rtree_get_locked(rtree_t *rtree, uintptr_t key);
#endif
void	*rtree_get(rtree_t *rtree, uintptr_t key);
bool	rtree_set(rtree_t *rtree, uintptr_t key, void *val);
#endif

#if (defined(JEMALLOC_ENABLE_INLINE) || defined(JEMALLOC_RTREE_C_))
#define	RTREE_GET_GENERATE(f)						\
/* The least significant bits of the key are ignored. */		\
JEMALLOC_INLINE void *							\
f(rtree_t *rtree, uintptr_t key)					\
{									\
	void *ret;							\
	uintptr_t subkey;						\
	unsigned i, lshift, height, bits;				\
	void **node, **child;						\
									\
	RTREE_LOCK(&rtree->mutex);					\
	for (i = lshift = 0, height = rtree->height, node = rtree->root;\
	    i < height - 1;						\
	    i++, lshift += bits, node = child) {			\
		bits = rtree->level2bits[i];				\
		subkey = (key << lshift) >> ((ZU(1) << (LG_SIZEOF_PTR + \
		    3)) - bits);					\
		child = (void**)node[subkey];				\
		if (child == NULL) {					\
			RTREE_UNLOCK(&rtree->mutex);			\
			return (NULL);					\
		}							\
	}								\
									\
	/*								\
	 * node is a leaf, so it contains values rather than node	\
	 * pointers.							\
	 */								\
	bits = rtree->level2bits[i];					\
	subkey = (key << lshift) >> ((ZU(1) << (LG_SIZEOF_PTR+3)) -	\
	    bits);							\
	ret = node[subkey];						\
	RTREE_UNLOCK(&rtree->mutex);					\
									\
	RTREE_GET_VALIDATE						\
	return (ret);							\
}

#ifdef JEMALLOC_DEBUG
#  define RTREE_LOCK(l)		malloc_mutex_lock(l)
#  define RTREE_UNLOCK(l)	malloc_mutex_unlock(l)
#  define RTREE_GET_VALIDATE
RTREE_GET_GENERATE(rtree_get_locked)
#  undef RTREE_LOCK
#  undef RTREE_UNLOCK
#  undef RTREE_GET_VALIDATE
#endif

#define	RTREE_LOCK(l)
#define	RTREE_UNLOCK(l)
#ifdef JEMALLOC_DEBUG
   /*
    * Suppose that it were possible for a jemalloc-allocated chunk to be
    * munmap()ped, followed by a different allocator in another thread re-using
    * overlapping virtual memory, all without invalidating the cached rtree
    * value.  The result would be a false positive (the rtree would claim that
    * jemalloc owns memory that it had actually discarded).  This scenario
    * seems impossible, but the following assertion is a prudent sanity check.
    */
#  define RTREE_GET_VALIDATE						\
	assert(rtree_get_locked(rtree, key) == ret);
#else
#  define RTREE_GET_VALIDATE
#endif
RTREE_GET_GENERATE(rtree_get)
#undef RTREE_LOCK
#undef RTREE_UNLOCK
#undef RTREE_GET_VALIDATE

JEMALLOC_INLINE bool
rtree_set(rtree_t *rtree, uintptr_t key, void *val)
{
	uintptr_t subkey;
	unsigned i, lshift, height, bits;
	void **node, **child;

	malloc_mutex_lock(&rtree->mutex);
	for (i = lshift = 0, height = rtree->height, node = rtree->root;
	    i < height - 1;
	    i++, lshift += bits, node = child) {
		bits = rtree->level2bits[i];
		subkey = (key << lshift) >> ((ZU(1) << (LG_SIZEOF_PTR+3)) -
		    bits);
		child = (void**)node[subkey];
		if (child == NULL) {
			child = (void**)base_alloc(sizeof(void *) <<
			    rtree->level2bits[i+1]);
			if (child == NULL) {
				malloc_mutex_unlock(&rtree->mutex);
				return (true);
			}
			memset(child, 0, sizeof(void *) <<
			    rtree->level2bits[i+1]);
			node[subkey] = child;
		}
	}

	/* node is a leaf, so it contains values rather than node pointers. */
	bits = rtree->level2bits[i];
	subkey = (key << lshift) >> ((ZU(1) << (LG_SIZEOF_PTR+3)) - bits);
	node[subkey] = val;
	malloc_mutex_unlock(&rtree->mutex);

	return (false);
}
#endif

#endif /* JEMALLOC_H_INLINES */
/******************************************************************************/
Port to Mac OS X. Add Mac OS X support, based in large part on the OS X support in Mozilla's version of jemalloc. 2010-09-06 01:35:13 +08:00			`/*`
			`* This radix tree implementation is tailored to the singular purpose of`
			`* tracking which chunks are currently owned by jemalloc. This functionality`
			`* is mandatory for OS X, where jemalloc must be able to respond to object`
			`* ownership queries.`
			`*`
			`*******************************************************************************`
			`*/`
			`#ifdef JEMALLOC_H_TYPES`

			`typedef struct rtree_s rtree_t;`

			`/*`
			`* Size of each radix tree node (must be a power of 2). This impacts tree`
			`* depth.`
			`*/`
			`#if (LG_SIZEOF_PTR == 2)`
			`# define RTREE_NODESIZE (1U << 14)`
			`#else`
			`# define RTREE_NODESIZE CACHELINE`
			`#endif`

			`#endif /* JEMALLOC_H_TYPES */`
			`/******************************************************************************/`
			`#ifdef JEMALLOC_H_STRUCTS`

			`struct rtree_s {`
			`malloc_mutex_t mutex;`
			`void **root;`
			`unsigned height;`
			`unsigned level2bits[1]; /* Dynamically sized. */`
			`};`

			`#endif /* JEMALLOC_H_STRUCTS */`
			`/******************************************************************************/`
			`#ifdef JEMALLOC_H_EXTERNS`

			`rtree_t *rtree_new(unsigned bits);`
Fix fork(2)-related deadlocks. Add a library constructor for jemalloc that initializes the allocator. This fixes a race that could occur if threads were created by the main thread prior to any memory allocation, followed by fork(2), and then memory allocation in the child process. Fix the prefork/postfork functions to acquire/release the ctl, prof, and rtree mutexes. This fixes various fork() child process deadlocks, but one possible deadlock remains (intentionally) unaddressed: prof backtracing can acquire runtime library mutexes, so deadlock is still possible if heap profiling is enabled during fork(). This deadlock is known to be a real issue in at least the case of libgcc-based backtracing. Reported by tfengjun. 2012-10-10 05:46:22 +08:00			`void rtree_prefork(rtree_t *rtree);`
			`void rtree_postfork_parent(rtree_t *rtree);`
			`void rtree_postfork_child(rtree_t *rtree);`
Port to Mac OS X. Add Mac OS X support, based in large part on the OS X support in Mozilla's version of jemalloc. 2010-09-06 01:35:13 +08:00
			`#endif /* JEMALLOC_H_EXTERNS */`
			`/******************************************************************************/`
			`#ifdef JEMALLOC_H_INLINES`

			`#ifndef JEMALLOC_ENABLE_INLINE`
			`#ifndef JEMALLOC_DEBUG`
			`void rtree_get_locked(rtree_t rtree, uintptr_t key);`
			`#endif`
			`void rtree_get(rtree_t rtree, uintptr_t key);`
			`bool rtree_set(rtree_t rtree, uintptr_t key, void val);`
			`#endif`

Add the "stats.cactive" mallctl. Add the "stats.cactive" mallctl, which can be used to efficiently and repeatedly query approximately how much active memory the application is utilizing. 2011-03-19 08:56:14 +08:00			`#if (defined(JEMALLOC_ENABLE_INLINE) \|\| defined(JEMALLOC_RTREE_C_))`
Port to Mac OS X. Add Mac OS X support, based in large part on the OS X support in Mozilla's version of jemalloc. 2010-09-06 01:35:13 +08:00			`#define RTREE_GET_GENERATE(f) \`
			`/* The least significant bits of the key are ignored. */ \`
			`JEMALLOC_INLINE void * \`
			`f(rtree_t *rtree, uintptr_t key) \`
			`{ \`
			`void *ret; \`
			`uintptr_t subkey; \`
			`unsigned i, lshift, height, bits; \`
			`void node, child; \`
			`\`
			`RTREE_LOCK(&rtree->mutex); \`
			`for (i = lshift = 0, height = rtree->height, node = rtree->root;\`
			`i < height - 1; \`
			`i++, lshift += bits, node = child) { \`
			`bits = rtree->level2bits[i]; \`
			`subkey = (key << lshift) >> ((ZU(1) << (LG_SIZEOF_PTR + \`
			`3)) - bits); \`
			`child = (void**)node[subkey]; \`
			`if (child == NULL) { \`
			`RTREE_UNLOCK(&rtree->mutex); \`
			`return (NULL); \`
			`} \`
			`} \`
			`\`
			`/* \`
			`* node is a leaf, so it contains values rather than node \`
			`* pointers. \`
			`*/ \`
			`bits = rtree->level2bits[i]; \`
			`subkey = (key << lshift) >> ((ZU(1) << (LG_SIZEOF_PTR+3)) - \`
			`bits); \`
			`ret = node[subkey]; \`
			`RTREE_UNLOCK(&rtree->mutex); \`
			`\`
			`RTREE_GET_VALIDATE \`
			`return (ret); \`
			`}`

			`#ifdef JEMALLOC_DEBUG`
			`# define RTREE_LOCK(l) malloc_mutex_lock(l)`
			`# define RTREE_UNLOCK(l) malloc_mutex_unlock(l)`
			`# define RTREE_GET_VALIDATE`
			`RTREE_GET_GENERATE(rtree_get_locked)`
			`# undef RTREE_LOCK`
			`# undef RTREE_UNLOCK`
			`# undef RTREE_GET_VALIDATE`
			`#endif`

			`#define RTREE_LOCK(l)`
			`#define RTREE_UNLOCK(l)`
			`#ifdef JEMALLOC_DEBUG`
			`/*`
			`* Suppose that it were possible for a jemalloc-allocated chunk to be`
			`* munmap()ped, followed by a different allocator in another thread re-using`
			`* overlapping virtual memory, all without invalidating the cached rtree`
			`* value. The result would be a false positive (the rtree would claim that`
			`* jemalloc owns memory that it had actually discarded). This scenario`
			`* seems impossible, but the following assertion is a prudent sanity check.`
			`*/`
			`# define RTREE_GET_VALIDATE \`
			`assert(rtree_get_locked(rtree, key) == ret);`
			`#else`
			`# define RTREE_GET_VALIDATE`
			`#endif`
			`RTREE_GET_GENERATE(rtree_get)`
			`#undef RTREE_LOCK`
			`#undef RTREE_UNLOCK`
			`#undef RTREE_GET_VALIDATE`

			`JEMALLOC_INLINE bool`
			`rtree_set(rtree_t rtree, uintptr_t key, void val)`
			`{`
			`uintptr_t subkey;`
			`unsigned i, lshift, height, bits;`
			`void node, child;`

			`malloc_mutex_lock(&rtree->mutex);`
			`for (i = lshift = 0, height = rtree->height, node = rtree->root;`
			`i < height - 1;`
			`i++, lshift += bits, node = child) {`
			`bits = rtree->level2bits[i];`
			`subkey = (key << lshift) >> ((ZU(1) << (LG_SIZEOF_PTR+3)) -`
			`bits);`
			`child = (void**)node[subkey];`
			`if (child == NULL) {`
			`child = (void*)base_alloc(sizeof(void ) <<`
			`rtree->level2bits[i+1]);`
			`if (child == NULL) {`
			`malloc_mutex_unlock(&rtree->mutex);`
			`return (true);`
			`}`
			`memset(child, 0, sizeof(void *) <<`
			`rtree->level2bits[i+1]);`
			`node[subkey] = child;`
			`}`
			`}`

			`/* node is a leaf, so it contains values rather than node pointers. */`
			`bits = rtree->level2bits[i];`
			`subkey = (key << lshift) >> ((ZU(1) << (LG_SIZEOF_PTR+3)) - bits);`
			`node[subkey] = val;`
			`malloc_mutex_unlock(&rtree->mutex);`

			`return (false);`
			`}`
			`#endif`

			`#endif /* JEMALLOC_H_INLINES */`
			`/******************************************************************************/`