src/chunk_dss.c - third_party/jemalloc - Git at Google

 #define	JEMALLOC_CHUNK_DSS_C_
 #include "jemalloc/internal/jemalloc_internal.h"
 /******************************************************************************/
 /* Data. */

 const char	*dss_prec_names[] = {
 	"disabled",
 	"primary",
 	"secondary",
 	"N/A"
 };

 /*
  * Current dss precedence default, used when creating new arenas.  NB: This is
  * stored as unsigned rather than dss_prec_t because in principle there's no
  * guarantee that sizeof(dss_prec_t) is the same as sizeof(unsigned), and we use
  * atomic operations to synchronize the setting.
  */
 static unsigned		dss_prec_default = (unsigned)DSS_PREC_DEFAULT;

 /* Base address of the DSS. */
 static void		*dss_base;
 /* Atomic boolean indicating whether the DSS is exhausted. */
 static unsigned		dss_exhausted;
 /* Atomic current upper limit on DSS addresses. */
 static void		*dss_max;

 /******************************************************************************/

 static void *
 chunk_dss_sbrk(intptr_t increment)
 {

 #ifdef JEMALLOC_DSS
 	return (sbrk(increment));
 #else
 	not_implemented();
 	return (NULL);
 #endif
 }

 dss_prec_t
 chunk_dss_prec_get(void)
 {
 	dss_prec_t ret;

 	if (!have_dss)
 		return (dss_prec_disabled);
 	ret = (dss_prec_t)atomic_read_u(&dss_prec_default);
 	return (ret);
 }

 bool
 chunk_dss_prec_set(dss_prec_t dss_prec)
 {

 	if (!have_dss)
 		return (dss_prec != dss_prec_disabled);
 	atomic_write_u(&dss_prec_default, (unsigned)dss_prec);
 	return (false);
 }

 static void *
 chunk_dss_max_update(void *new_addr)
 {
 	void *max_cur;
 	spin_t spinner;

 	/*
 	 * Get the current end of the DSS as max_cur and assure that dss_max is
 	 * up to date.
 	 */
 	spin_init(&spinner);
 	while (true) {
 		void *max_prev = atomic_read_p(&dss_max);

 		max_cur = chunk_dss_sbrk(0);
 		if ((uintptr_t)max_prev > (uintptr_t)max_cur) {
 			/*
 			 * Another thread optimistically updated dss_max.  Wait
 			 * for it to finish.
 			 */
 			spin_adaptive(&spinner);
 			continue;
 		}
 		if (!atomic_cas_p(&dss_max, max_prev, max_cur))
 			break;
 	}
 	/* Fixed new_addr can only be supported if it is at the edge of DSS. */
 	if (new_addr != NULL && max_cur != new_addr)
 		return (NULL);

 	return (max_cur);
 }

 void *
 chunk_alloc_dss(tsdn_t *tsdn, arena_t *arena, void *new_addr, size_t size,
     size_t alignment, bool *zero, bool *commit)
 {
 	cassert(have_dss);
 	assert(size > 0 && (size & chunksize_mask) == 0);
 	assert(alignment > 0 && (alignment & chunksize_mask) == 0);

 	/*
 	 * sbrk() uses a signed increment argument, so take care not to
 	 * interpret a huge allocation request as a negative increment.
 	 */
 	if ((intptr_t)size < 0)
 		return (NULL);

 	if (!atomic_read_u(&dss_exhausted)) {
 		/*
 		 * The loop is necessary to recover from races with other
 		 * threads that are using the DSS for something other than
 		 * malloc.
 		 */
 		while (true) {
 			void *ret, *cpad, *max_cur, *dss_next, *dss_prev;
 			size_t gap_size, cpad_size;
 			intptr_t incr;

 			max_cur = chunk_dss_max_update(new_addr);
 			if (max_cur == NULL)
 				goto label_oom;

 			/*
 			 * Calculate how much padding is necessary to
 			 * chunk-align the end of the DSS.
 			 */
 			gap_size = (chunksize - CHUNK_ADDR2OFFSET(dss_max)) &
 			    chunksize_mask;
 			/*
 			 * Compute how much chunk-aligned pad space (if any) is
 			 * necessary to satisfy alignment.  This space can be
 			 * recycled for later use.
 			 */
 			cpad = (void *)((uintptr_t)dss_max + gap_size);
 			ret = (void *)ALIGNMENT_CEILING((uintptr_t)dss_max,
 			    alignment);
 			cpad_size = (uintptr_t)ret - (uintptr_t)cpad;
 			dss_next = (void *)((uintptr_t)ret + size);
 			if ((uintptr_t)ret < (uintptr_t)dss_max ||
 			    (uintptr_t)dss_next < (uintptr_t)dss_max)
 				goto label_oom; /* Wrap-around. */
 			incr = gap_size + cpad_size + size;

 			/*
 			 * Optimistically update dss_max, and roll back below if
 			 * sbrk() fails.  No other thread will try to extend the
 			 * DSS while dss_max is greater than the current DSS
 			 * max reported by sbrk(0).
 			 */
 			if (atomic_cas_p(&dss_max, max_cur, dss_next))
 				continue;

 			/* Try to allocate. */
 			dss_prev = chunk_dss_sbrk(incr);
 			if (dss_prev == max_cur) {
 				/* Success. */
 				if (cpad_size != 0) {
 					chunk_hooks_t chunk_hooks =
 					    CHUNK_HOOKS_INITIALIZER;
 					chunk_dalloc_wrapper(tsdn, arena,
 					    &chunk_hooks, cpad, cpad_size,
 					    false, true);
 				}
 				if (*zero) {
 					JEMALLOC_VALGRIND_MAKE_MEM_UNDEFINED(
 					    ret, size);
 					memset(ret, 0, size);
 				}
 				if (!*commit)
 					*commit = pages_decommit(ret, size);
 				return (ret);
 			}

 			/*
 			 * Failure, whether due to OOM or a race with a raw
 			 * sbrk() call from outside the allocator.  Try to roll
 			 * back optimistic dss_max update; if rollback fails,
 			 * it's due to another caller of this function having
 			 * succeeded since this invocation started, in which
 			 * case rollback is not necessary.
 			 */
 			atomic_cas_p(&dss_max, dss_next, max_cur);
 			if (dss_prev == (void *)-1) {
 				/* OOM. */
 				atomic_write_u(&dss_exhausted, (unsigned)true);
 				goto label_oom;
 			}
 		}
 	}
 label_oom:
 	return (NULL);
 }

 static bool
 chunk_in_dss_helper(void *chunk, void *max)
 {

 	return ((uintptr_t)chunk >= (uintptr_t)dss_base && (uintptr_t)chunk <
 	    (uintptr_t)max);
 }

 bool
 chunk_in_dss(void *chunk)
 {

 	cassert(have_dss);

 	return (chunk_in_dss_helper(chunk, atomic_read_p(&dss_max)));
 }

 bool
 chunk_dss_mergeable(void *chunk_a, void *chunk_b)
 {
 	void *max;

 	cassert(have_dss);

 	max = atomic_read_p(&dss_max);
 	return (chunk_in_dss_helper(chunk_a, max) ==
 	    chunk_in_dss_helper(chunk_b, max));
 }

 void
 chunk_dss_boot(void)
 {

 	cassert(have_dss);

 	dss_base = chunk_dss_sbrk(0);
 	dss_exhausted = (unsigned)(dss_base == (void *)-1);
 	dss_max = dss_base;
 }

 /******************************************************************************/
	#define JEMALLOC_CHUNK_DSS_C_
	#include "jemalloc/internal/jemalloc_internal.h"
	/******************************************************************************/
	/* Data. */

	const char *dss_prec_names[] = {
	"disabled",
	"primary",
	"secondary",
	"N/A"
	};

	/*
	* Current dss precedence default, used when creating new arenas. NB: This is
	* stored as unsigned rather than dss_prec_t because in principle there's no
	* guarantee that sizeof(dss_prec_t) is the same as sizeof(unsigned), and we use
	* atomic operations to synchronize the setting.
	*/
	static unsigned dss_prec_default = (unsigned)DSS_PREC_DEFAULT;

	/* Base address of the DSS. */
	static void *dss_base;
	/* Atomic boolean indicating whether the DSS is exhausted. */
	static unsigned dss_exhausted;
	/* Atomic current upper limit on DSS addresses. */
	static void *dss_max;

	/******************************************************************************/

	static void *
	chunk_dss_sbrk(intptr_t increment)
	{

	#ifdef JEMALLOC_DSS
	return (sbrk(increment));
	#else
	not_implemented();
	return (NULL);
	#endif
	}

	dss_prec_t
	chunk_dss_prec_get(void)
	{
	dss_prec_t ret;

	if (!have_dss)
	return (dss_prec_disabled);
	ret = (dss_prec_t)atomic_read_u(&dss_prec_default);
	return (ret);
	}

	bool
	chunk_dss_prec_set(dss_prec_t dss_prec)
	{

	if (!have_dss)
	return (dss_prec != dss_prec_disabled);
	atomic_write_u(&dss_prec_default, (unsigned)dss_prec);
	return (false);
	}

	static void *
	chunk_dss_max_update(void *new_addr)
	{
	void *max_cur;
	spin_t spinner;

	/*
	* Get the current end of the DSS as max_cur and assure that dss_max is
	* up to date.
	*/
	spin_init(&spinner);
	while (true) {
	void *max_prev = atomic_read_p(&dss_max);

	max_cur = chunk_dss_sbrk(0);
	if ((uintptr_t)max_prev > (uintptr_t)max_cur) {
	/*
	* Another thread optimistically updated dss_max. Wait
	* for it to finish.
	*/
	spin_adaptive(&spinner);
	continue;
	}
	if (!atomic_cas_p(&dss_max, max_prev, max_cur))
	break;
	}
	/* Fixed new_addr can only be supported if it is at the edge of DSS. */
	if (new_addr != NULL && max_cur != new_addr)
	return (NULL);

	return (max_cur);
	}

	void *
	chunk_alloc_dss(tsdn_t tsdn, arena_t arena, void *new_addr, size_t size,
	size_t alignment, bool zero, bool commit)
	{
	cassert(have_dss);
	assert(size > 0 && (size & chunksize_mask) == 0);
	assert(alignment > 0 && (alignment & chunksize_mask) == 0);

	/*
	* sbrk() uses a signed increment argument, so take care not to
	* interpret a huge allocation request as a negative increment.
	*/
	if ((intptr_t)size < 0)
	return (NULL);

	if (!atomic_read_u(&dss_exhausted)) {
	/*
	* The loop is necessary to recover from races with other
	* threads that are using the DSS for something other than
	* malloc.
	*/
	while (true) {
	void ret, cpad, max_cur, dss_next, *dss_prev;
	size_t gap_size, cpad_size;
	intptr_t incr;

	max_cur = chunk_dss_max_update(new_addr);
	if (max_cur == NULL)
	goto label_oom;

	/*
	* Calculate how much padding is necessary to
	* chunk-align the end of the DSS.
	*/
	gap_size = (chunksize - CHUNK_ADDR2OFFSET(dss_max)) &
	chunksize_mask;
	/*
	* Compute how much chunk-aligned pad space (if any) is
	* necessary to satisfy alignment. This space can be
	* recycled for later use.
	*/
	cpad = (void *)((uintptr_t)dss_max + gap_size);
	ret = (void *)ALIGNMENT_CEILING((uintptr_t)dss_max,
	alignment);
	cpad_size = (uintptr_t)ret - (uintptr_t)cpad;
	dss_next = (void *)((uintptr_t)ret + size);
	if ((uintptr_t)ret < (uintptr_t)dss_max \|\|
	(uintptr_t)dss_next < (uintptr_t)dss_max)
	goto label_oom; /* Wrap-around. */
	incr = gap_size + cpad_size + size;

	/*
	* Optimistically update dss_max, and roll back below if
	* sbrk() fails. No other thread will try to extend the
	* DSS while dss_max is greater than the current DSS
	* max reported by sbrk(0).
	*/
	if (atomic_cas_p(&dss_max, max_cur, dss_next))
	continue;

	/* Try to allocate. */
	dss_prev = chunk_dss_sbrk(incr);
	if (dss_prev == max_cur) {
	/* Success. */
	if (cpad_size != 0) {
	chunk_hooks_t chunk_hooks =
	CHUNK_HOOKS_INITIALIZER;
	chunk_dalloc_wrapper(tsdn, arena,
	&chunk_hooks, cpad, cpad_size,
	false, true);
	}
	if (*zero) {
	JEMALLOC_VALGRIND_MAKE_MEM_UNDEFINED(
	ret, size);
	memset(ret, 0, size);
	}
	if (!*commit)
	*commit = pages_decommit(ret, size);
	return (ret);
	}

	/*
	* Failure, whether due to OOM or a race with a raw
	* sbrk() call from outside the allocator. Try to roll
	* back optimistic dss_max update; if rollback fails,
	* it's due to another caller of this function having
	* succeeded since this invocation started, in which
	* case rollback is not necessary.
	*/
	atomic_cas_p(&dss_max, dss_next, max_cur);
	if (dss_prev == (void *)-1) {
	/* OOM. */
	atomic_write_u(&dss_exhausted, (unsigned)true);
	goto label_oom;
	}
	}
	}
	label_oom:
	return (NULL);
	}

	static bool
	chunk_in_dss_helper(void chunk, void max)
	{

	return ((uintptr_t)chunk >= (uintptr_t)dss_base && (uintptr_t)chunk <
	(uintptr_t)max);
	}

	bool
	chunk_in_dss(void *chunk)
	{

	cassert(have_dss);

	return (chunk_in_dss_helper(chunk, atomic_read_p(&dss_max)));
	}

	bool
	chunk_dss_mergeable(void chunk_a, void chunk_b)
	{
	void *max;

	cassert(have_dss);

	max = atomic_read_p(&dss_max);
	return (chunk_in_dss_helper(chunk_a, max) ==
	chunk_in_dss_helper(chunk_b, max));
	}

	void
	chunk_dss_boot(void)
	{

	cassert(have_dss);

	dss_base = chunk_dss_sbrk(0);
	dss_exhausted = (unsigned)(dss_base == (void *)-1);
	dss_max = dss_base;
	}

	/******************************************************************************/