src/tcache.c - platform/external/jemalloc - Git at Google

 #define	JEMALLOC_TCACHE_C_
 #include "jemalloc/internal/jemalloc_internal.h"

 /******************************************************************************/
 /* Data. */

 malloc_tsd_data(, tcache, tcache_t *, NULL)
 malloc_tsd_data(, tcache_enabled, tcache_enabled_t, tcache_enabled_default)

 bool	opt_tcache = true;
 ssize_t	opt_lg_tcache_max = LG_TCACHE_MAXCLASS_DEFAULT;

 tcache_bin_info_t	*tcache_bin_info;
 static unsigned		stack_nelms; /* Total stack elms per tcache. */

 size_t			nhbins;
 size_t			tcache_maxclass;

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

 size_t	tcache_salloc(const void *ptr)
 {

 	return (arena_salloc(ptr, false));
 }

 void
 tcache_event_hard(tcache_t *tcache)
 {
 	size_t binind = tcache->next_gc_bin;
 	tcache_bin_t *tbin = &tcache->tbins[binind];
 	tcache_bin_info_t *tbin_info = &tcache_bin_info[binind];

 	if (tbin->low_water > 0) {
 		/*
 		 * Flush (ceiling) 3/4 of the objects below the low water mark.
 		 */
 		if (binind < NBINS) {
 			tcache_bin_flush_small(tbin, binind, tbin->ncached -
 			    tbin->low_water + (tbin->low_water >> 2), tcache);
 		} else {
 			tcache_bin_flush_large(tbin, binind, tbin->ncached -
 			    tbin->low_water + (tbin->low_water >> 2), tcache);
 		}
 		/*
 		 * Reduce fill count by 2X.  Limit lg_fill_div such that the
 		 * fill count is always at least 1.
 		 */
 		if ((tbin_info->ncached_max >> (tbin->lg_fill_div+1)) >= 1)
 			tbin->lg_fill_div++;
 	} else if (tbin->low_water < 0) {
 		/*
 		 * Increase fill count by 2X.  Make sure lg_fill_div stays
 		 * greater than 0.
 		 */
 		if (tbin->lg_fill_div > 1)
 			tbin->lg_fill_div--;
 	}
 	tbin->low_water = tbin->ncached;

 	tcache->next_gc_bin++;
 	if (tcache->next_gc_bin == nhbins)
 		tcache->next_gc_bin = 0;
 	tcache->ev_cnt = 0;
 }

 void *
 tcache_alloc_small_hard(tcache_t *tcache, tcache_bin_t *tbin, size_t binind)
 {
 	void *ret;

 	arena_tcache_fill_small(tcache->arena, tbin, binind,
 	    config_prof ? tcache->prof_accumbytes : 0);
 	if (config_prof)
 		tcache->prof_accumbytes = 0;
 	ret = tcache_alloc_easy(tbin);

 	return (ret);
 }

 void
 tcache_bin_flush_small(tcache_bin_t *tbin, size_t binind, unsigned rem,
     tcache_t *tcache)
 {
 	void *ptr;
 	unsigned i, nflush, ndeferred;
 	bool merged_stats = false;

 	assert(binind < NBINS);
 	assert(rem <= tbin->ncached);

 	for (nflush = tbin->ncached - rem; nflush > 0; nflush = ndeferred) {
 		/* Lock the arena bin associated with the first object. */
 		arena_chunk_t *chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(
 		    tbin->avail[0]);
 		arena_t *arena = chunk->arena;
 		arena_bin_t *bin = &arena->bins[binind];

 		if (config_prof && arena == tcache->arena) {
 			if (arena_prof_accum(arena, tcache->prof_accumbytes))
 				prof_idump();
 			tcache->prof_accumbytes = 0;
 		}

 		malloc_mutex_lock(&bin->lock);
 		if (config_stats && arena == tcache->arena) {
 			assert(merged_stats == false);
 			merged_stats = true;
 			bin->stats.nflushes++;
 			bin->stats.nrequests += tbin->tstats.nrequests;
 			tbin->tstats.nrequests = 0;
 		}
 		ndeferred = 0;
 		for (i = 0; i < nflush; i++) {
 			ptr = tbin->avail[i];
 			assert(ptr != NULL);
 			chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ptr);
 			if (chunk->arena == arena) {
 				size_t pageind = ((uintptr_t)ptr -
 				    (uintptr_t)chunk) >> LG_PAGE;
 				arena_chunk_map_t *mapelm =
 				    arena_mapp_get(chunk, pageind);
 				if (config_fill && opt_junk) {
 					arena_alloc_junk_small(ptr,
 					    &arena_bin_info[binind], true);
 				}
 				arena_dalloc_bin_locked(arena, chunk, ptr,
 				    mapelm);
 			} else {
 				/*
 				 * This object was allocated via a different
 				 * arena bin than the one that is currently
 				 * locked.  Stash the object, so that it can be
 				 * handled in a future pass.
 				 */
 				tbin->avail[ndeferred] = ptr;
 				ndeferred++;
 			}
 		}
 		malloc_mutex_unlock(&bin->lock);
 	}
 	if (config_stats && merged_stats == false) {
 		/*
 		 * The flush loop didn't happen to flush to this thread's
 		 * arena, so the stats didn't get merged.  Manually do so now.
 		 */
 		arena_bin_t *bin = &tcache->arena->bins[binind];
 		malloc_mutex_lock(&bin->lock);
 		bin->stats.nflushes++;
 		bin->stats.nrequests += tbin->tstats.nrequests;
 		tbin->tstats.nrequests = 0;
 		malloc_mutex_unlock(&bin->lock);
 	}

 	memmove(tbin->avail, &tbin->avail[tbin->ncached - rem],
 	    rem * sizeof(void *));
 	tbin->ncached = rem;
 	if ((int)tbin->ncached < tbin->low_water)
 		tbin->low_water = tbin->ncached;
 }

 void
 tcache_bin_flush_large(tcache_bin_t *tbin, size_t binind, unsigned rem,
     tcache_t *tcache)
 {
 	void *ptr;
 	unsigned i, nflush, ndeferred;
 	bool merged_stats = false;

 	assert(binind < nhbins);
 	assert(rem <= tbin->ncached);

 	for (nflush = tbin->ncached - rem; nflush > 0; nflush = ndeferred) {
 		/* Lock the arena associated with the first object. */
 		arena_chunk_t *chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(
 		    tbin->avail[0]);
 		arena_t *arena = chunk->arena;
 		UNUSED bool idump;

 		if (config_prof)
 			idump = false;
 		malloc_mutex_lock(&arena->lock);
 		if ((config_prof || config_stats) && arena == tcache->arena) {
 			if (config_prof) {
 				idump = arena_prof_accum_locked(arena,
 				    tcache->prof_accumbytes);
 				tcache->prof_accumbytes = 0;
 			}
 			if (config_stats) {
 				merged_stats = true;
 				arena->stats.nrequests_large +=
 				    tbin->tstats.nrequests;
 				arena->stats.lstats[binind - NBINS].nrequests +=
 				    tbin->tstats.nrequests;
 				tbin->tstats.nrequests = 0;
 			}
 		}
 		ndeferred = 0;
 		for (i = 0; i < nflush; i++) {
 			ptr = tbin->avail[i];
 			assert(ptr != NULL);
 			chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ptr);
 			if (chunk->arena == arena)
 				arena_dalloc_large_locked(arena, chunk, ptr);
 			else {
 				/*
 				 * This object was allocated via a different
 				 * arena than the one that is currently locked.
 				 * Stash the object, so that it can be handled
 				 * in a future pass.
 				 */
 				tbin->avail[ndeferred] = ptr;
 				ndeferred++;
 			}
 		}
 		malloc_mutex_unlock(&arena->lock);
 		if (config_prof && idump)
 			prof_idump();
 	}
 	if (config_stats && merged_stats == false) {
 		/*
 		 * The flush loop didn't happen to flush to this thread's
 		 * arena, so the stats didn't get merged.  Manually do so now.
 		 */
 		arena_t *arena = tcache->arena;
 		malloc_mutex_lock(&arena->lock);
 		arena->stats.nrequests_large += tbin->tstats.nrequests;
 		arena->stats.lstats[binind - NBINS].nrequests +=
 		    tbin->tstats.nrequests;
 		tbin->tstats.nrequests = 0;
 		malloc_mutex_unlock(&arena->lock);
 	}

 	memmove(tbin->avail, &tbin->avail[tbin->ncached - rem],
 	    rem * sizeof(void *));
 	tbin->ncached = rem;
 	if ((int)tbin->ncached < tbin->low_water)
 		tbin->low_water = tbin->ncached;
 }

 void
 tcache_arena_associate(tcache_t *tcache, arena_t *arena)
 {

 	if (config_stats) {
 		/* Link into list of extant tcaches. */
 		malloc_mutex_lock(&arena->lock);
 		ql_elm_new(tcache, link);
 		ql_tail_insert(&arena->tcache_ql, tcache, link);
 		malloc_mutex_unlock(&arena->lock);
 	}
 	tcache->arena = arena;
 }

 void
 tcache_arena_dissociate(tcache_t *tcache)
 {

 	if (config_stats) {
 		/* Unlink from list of extant tcaches. */
 		malloc_mutex_lock(&tcache->arena->lock);
 		ql_remove(&tcache->arena->tcache_ql, tcache, link);
 		tcache_stats_merge(tcache, tcache->arena);
 		malloc_mutex_unlock(&tcache->arena->lock);
 	}
 }

 tcache_t *
 tcache_get_hard(tcache_t *tcache, bool create)
 {

 	if (tcache == NULL) {
 		if (create == false) {
 			/*
 			 * Creating a tcache here would cause
 			 * allocation as a side effect of free().
 			 * Ordinarily that would be okay since
 			 * tcache_create() failure is a soft failure
 			 * that doesn't propagate.  However, if TLS
 			 * data are freed via free() as in glibc,
 			 * subtle corruption could result from setting
 			 * a TLS variable after its backing memory is
 			 * freed.
 			 */
 			return (NULL);
 		}
 		if (tcache_enabled_get() == false) {
 			tcache_enabled_set(false); /* Memoize. */
 			return (NULL);
 		}
 		return (tcache_create(choose_arena(NULL)));
 	}
 	if (tcache == TCACHE_STATE_PURGATORY) {
 		/*
 		 * Make a note that an allocator function was called
 		 * after tcache_thread_cleanup() was called.
 		 */
 		tcache = TCACHE_STATE_REINCARNATED;
 		tcache_tsd_set(&tcache);
 		return (NULL);
 	}
 	if (tcache == TCACHE_STATE_REINCARNATED)
 		return (NULL);
 	not_reached();
 	return (NULL);
 }

 tcache_t *
 tcache_create(arena_t *arena)
 {
 	tcache_t *tcache;
 	size_t size, stack_offset;
 	unsigned i;

 	size = offsetof(tcache_t, tbins) + (sizeof(tcache_bin_t) * nhbins);
 	/* Naturally align the pointer stacks. */
 	size = PTR_CEILING(size);
 	stack_offset = size;
 	size += stack_nelms * sizeof(void *);
 	/*
 	 * Round up to the nearest multiple of the cacheline size, in order to
 	 * avoid the possibility of false cacheline sharing.
 	 *
 	 * That this works relies on the same logic as in ipalloc(), but we
 	 * cannot directly call ipalloc() here due to tcache bootstrapping
 	 * issues.
 	 */
 	size = (size + CACHELINE_MASK) & (-CACHELINE);

 	if (size <= SMALL_MAXCLASS)
 		tcache = (tcache_t *)arena_malloc_small(arena, size, true);
 	else if (size <= tcache_maxclass)
 		tcache = (tcache_t *)arena_malloc_large(arena, size, true);
 	else
 		tcache = (tcache_t *)icalloct(size, false, arena);

 	if (tcache == NULL)
 		return (NULL);

 	tcache_arena_associate(tcache, arena);

 	assert((TCACHE_NSLOTS_SMALL_MAX & 1U) == 0);
 	for (i = 0; i < nhbins; i++) {
 		tcache->tbins[i].lg_fill_div = 1;
 		tcache->tbins[i].avail = (void **)((uintptr_t)tcache +
 		    (uintptr_t)stack_offset);
 		stack_offset += tcache_bin_info[i].ncached_max * sizeof(void *);
 	}

 	tcache_tsd_set(&tcache);

 	return (tcache);
 }

 void
 tcache_destroy(tcache_t *tcache)
 {
 	unsigned i;
 	size_t tcache_size;

 	tcache_arena_dissociate(tcache);

 	for (i = 0; i < NBINS; i++) {
 		tcache_bin_t *tbin = &tcache->tbins[i];
 		tcache_bin_flush_small(tbin, i, 0, tcache);

 		if (config_stats && tbin->tstats.nrequests != 0) {
 			arena_t *arena = tcache->arena;
 			arena_bin_t *bin = &arena->bins[i];
 			malloc_mutex_lock(&bin->lock);
 			bin->stats.nrequests += tbin->tstats.nrequests;
 			malloc_mutex_unlock(&bin->lock);
 		}
 	}

 	for (; i < nhbins; i++) {
 		tcache_bin_t *tbin = &tcache->tbins[i];
 		tcache_bin_flush_large(tbin, i, 0, tcache);

 		if (config_stats && tbin->tstats.nrequests != 0) {
 			arena_t *arena = tcache->arena;
 			malloc_mutex_lock(&arena->lock);
 			arena->stats.nrequests_large += tbin->tstats.nrequests;
 			arena->stats.lstats[i - NBINS].nrequests +=
 			    tbin->tstats.nrequests;
 			malloc_mutex_unlock(&arena->lock);
 		}
 	}

 	if (config_prof && tcache->prof_accumbytes > 0 &&
 	    arena_prof_accum(tcache->arena, tcache->prof_accumbytes))
 		prof_idump();

 	tcache_size = arena_salloc(tcache, false);
 	if (tcache_size <= SMALL_MAXCLASS) {
 		arena_chunk_t *chunk = CHUNK_ADDR2BASE(tcache);
 		arena_t *arena = chunk->arena;
 		size_t pageind = ((uintptr_t)tcache - (uintptr_t)chunk) >>
 		    LG_PAGE;
 		arena_chunk_map_t *mapelm = arena_mapp_get(chunk, pageind);

 		arena_dalloc_bin(arena, chunk, tcache, pageind, mapelm);
 	} else if (tcache_size <= tcache_maxclass) {
 		arena_chunk_t *chunk = CHUNK_ADDR2BASE(tcache);
 		arena_t *arena = chunk->arena;

 		arena_dalloc_large(arena, chunk, tcache);
 	} else
 		idalloct(tcache, false);
 }

 void
 tcache_thread_cleanup(void *arg)
 {
 	tcache_t *tcache = *(tcache_t **)arg;

 	if (tcache == TCACHE_STATE_DISABLED) {
 		/* Do nothing. */
 	} else if (tcache == TCACHE_STATE_REINCARNATED) {
 		/*
 		 * Another destructor called an allocator function after this
 		 * destructor was called.  Reset tcache to
 		 * TCACHE_STATE_PURGATORY in order to receive another callback.
 		 */
 		tcache = TCACHE_STATE_PURGATORY;
 		tcache_tsd_set(&tcache);
 	} else if (tcache == TCACHE_STATE_PURGATORY) {
 		/*
 		 * The previous time this destructor was called, we set the key
 		 * to TCACHE_STATE_PURGATORY so that other destructors wouldn't
 		 * cause re-creation of the tcache.  This time, do nothing, so
 		 * that the destructor will not be called again.
 		 */
 	} else if (tcache != NULL) {
 		assert(tcache != TCACHE_STATE_PURGATORY);
 		tcache_destroy(tcache);
 		tcache = TCACHE_STATE_PURGATORY;
 		tcache_tsd_set(&tcache);
 	}
 }

 /* Caller must own arena->lock. */
 void
 tcache_stats_merge(tcache_t *tcache, arena_t *arena)
 {
 	unsigned i;

 	cassert(config_stats);

 	/* Merge and reset tcache stats. */
 	for (i = 0; i < NBINS; i++) {
 		arena_bin_t *bin = &arena->bins[i];
 		tcache_bin_t *tbin = &tcache->tbins[i];
 		malloc_mutex_lock(&bin->lock);
 		bin->stats.nrequests += tbin->tstats.nrequests;
 		malloc_mutex_unlock(&bin->lock);
 		tbin->tstats.nrequests = 0;
 	}

 	for (; i < nhbins; i++) {
 		malloc_large_stats_t *lstats = &arena->stats.lstats[i - NBINS];
 		tcache_bin_t *tbin = &tcache->tbins[i];
 		arena->stats.nrequests_large += tbin->tstats.nrequests;
 		lstats->nrequests += tbin->tstats.nrequests;
 		tbin->tstats.nrequests = 0;
 	}
 }

 bool
 tcache_boot0(void)
 {
 	unsigned i;

 	/*
 	 * If necessary, clamp opt_lg_tcache_max, now that arena_maxclass is
 	 * known.
 	 */
 	if (opt_lg_tcache_max < 0 || (1U << opt_lg_tcache_max) < SMALL_MAXCLASS)
 		tcache_maxclass = SMALL_MAXCLASS;
 	else if ((1U << opt_lg_tcache_max) > arena_maxclass)
 		tcache_maxclass = arena_maxclass;
 	else
 		tcache_maxclass = (1U << opt_lg_tcache_max);

 	nhbins = NBINS + (tcache_maxclass >> LG_PAGE);

 	/* Initialize tcache_bin_info. */
 	tcache_bin_info = (tcache_bin_info_t *)base_alloc(nhbins *
 	    sizeof(tcache_bin_info_t));
 	if (tcache_bin_info == NULL)
 		return (true);
 	stack_nelms = 0;
 	for (i = 0; i < NBINS; i++) {
 		if ((arena_bin_info[i].nregs << 1) <= TCACHE_NSLOTS_SMALL_MAX) {
 			tcache_bin_info[i].ncached_max =
 			    (arena_bin_info[i].nregs << 1);
 		} else {
 			tcache_bin_info[i].ncached_max =
 			    TCACHE_NSLOTS_SMALL_MAX;
 		}
 		stack_nelms += tcache_bin_info[i].ncached_max;
 	}
 	for (; i < nhbins; i++) {
 		tcache_bin_info[i].ncached_max = TCACHE_NSLOTS_LARGE;
 		stack_nelms += tcache_bin_info[i].ncached_max;
 	}

 	return (false);
 }

 bool
 tcache_boot1(void)
 {

 	if (tcache_tsd_boot() || tcache_enabled_tsd_boot())
 		return (true);

 	return (false);
 }
	#define JEMALLOC_TCACHE_C_
	#include "jemalloc/internal/jemalloc_internal.h"

	/******************************************************************************/
	/* Data. */

	malloc_tsd_data(, tcache, tcache_t *, NULL)
	malloc_tsd_data(, tcache_enabled, tcache_enabled_t, tcache_enabled_default)

	bool opt_tcache = true;
	ssize_t opt_lg_tcache_max = LG_TCACHE_MAXCLASS_DEFAULT;

	tcache_bin_info_t *tcache_bin_info;
	static unsigned stack_nelms; /* Total stack elms per tcache. */

	size_t nhbins;
	size_t tcache_maxclass;

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

	size_t tcache_salloc(const void *ptr)
	{

	return (arena_salloc(ptr, false));
	}

	void
	tcache_event_hard(tcache_t *tcache)
	{
	size_t binind = tcache->next_gc_bin;
	tcache_bin_t *tbin = &tcache->tbins[binind];
	tcache_bin_info_t *tbin_info = &tcache_bin_info[binind];

	if (tbin->low_water > 0) {
	/*
	* Flush (ceiling) 3/4 of the objects below the low water mark.
	*/
	if (binind < NBINS) {
	tcache_bin_flush_small(tbin, binind, tbin->ncached -
	tbin->low_water + (tbin->low_water >> 2), tcache);
	} else {
	tcache_bin_flush_large(tbin, binind, tbin->ncached -
	tbin->low_water + (tbin->low_water >> 2), tcache);
	}
	/*
	* Reduce fill count by 2X. Limit lg_fill_div such that the
	* fill count is always at least 1.
	*/
	if ((tbin_info->ncached_max >> (tbin->lg_fill_div+1)) >= 1)
	tbin->lg_fill_div++;
	} else if (tbin->low_water < 0) {
	/*
	* Increase fill count by 2X. Make sure lg_fill_div stays
	* greater than 0.
	*/
	if (tbin->lg_fill_div > 1)
	tbin->lg_fill_div--;
	}
	tbin->low_water = tbin->ncached;

	tcache->next_gc_bin++;
	if (tcache->next_gc_bin == nhbins)
	tcache->next_gc_bin = 0;
	tcache->ev_cnt = 0;
	}

	void *
	tcache_alloc_small_hard(tcache_t tcache, tcache_bin_t tbin, size_t binind)
	{
	void *ret;

	arena_tcache_fill_small(tcache->arena, tbin, binind,
	config_prof ? tcache->prof_accumbytes : 0);
	if (config_prof)
	tcache->prof_accumbytes = 0;
	ret = tcache_alloc_easy(tbin);

	return (ret);
	}

	void
	tcache_bin_flush_small(tcache_bin_t *tbin, size_t binind, unsigned rem,
	tcache_t *tcache)
	{
	void *ptr;
	unsigned i, nflush, ndeferred;
	bool merged_stats = false;

	assert(binind < NBINS);
	assert(rem <= tbin->ncached);

	for (nflush = tbin->ncached - rem; nflush > 0; nflush = ndeferred) {
	/* Lock the arena bin associated with the first object. */
	arena_chunk_t chunk = (arena_chunk_t )CHUNK_ADDR2BASE(
	tbin->avail[0]);
	arena_t *arena = chunk->arena;
	arena_bin_t *bin = &arena->bins[binind];

	if (config_prof && arena == tcache->arena) {
	if (arena_prof_accum(arena, tcache->prof_accumbytes))
	prof_idump();
	tcache->prof_accumbytes = 0;
	}

	malloc_mutex_lock(&bin->lock);
	if (config_stats && arena == tcache->arena) {
	assert(merged_stats == false);
	merged_stats = true;
	bin->stats.nflushes++;
	bin->stats.nrequests += tbin->tstats.nrequests;
	tbin->tstats.nrequests = 0;
	}
	ndeferred = 0;
	for (i = 0; i < nflush; i++) {
	ptr = tbin->avail[i];
	assert(ptr != NULL);
	chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ptr);
	if (chunk->arena == arena) {
	size_t pageind = ((uintptr_t)ptr -
	(uintptr_t)chunk) >> LG_PAGE;
	arena_chunk_map_t *mapelm =
	arena_mapp_get(chunk, pageind);
	if (config_fill && opt_junk) {
	arena_alloc_junk_small(ptr,
	&arena_bin_info[binind], true);
	}
	arena_dalloc_bin_locked(arena, chunk, ptr,
	mapelm);
	} else {
	/*
	* This object was allocated via a different
	* arena bin than the one that is currently
	* locked. Stash the object, so that it can be
	* handled in a future pass.
	*/
	tbin->avail[ndeferred] = ptr;
	ndeferred++;
	}
	}
	malloc_mutex_unlock(&bin->lock);
	}
	if (config_stats && merged_stats == false) {
	/*
	* The flush loop didn't happen to flush to this thread's
	* arena, so the stats didn't get merged. Manually do so now.
	*/
	arena_bin_t *bin = &tcache->arena->bins[binind];
	malloc_mutex_lock(&bin->lock);
	bin->stats.nflushes++;
	bin->stats.nrequests += tbin->tstats.nrequests;
	tbin->tstats.nrequests = 0;
	malloc_mutex_unlock(&bin->lock);
	}

	memmove(tbin->avail, &tbin->avail[tbin->ncached - rem],
	rem * sizeof(void *));
	tbin->ncached = rem;
	if ((int)tbin->ncached < tbin->low_water)
	tbin->low_water = tbin->ncached;
	}

	void
	tcache_bin_flush_large(tcache_bin_t *tbin, size_t binind, unsigned rem,
	tcache_t *tcache)
	{
	void *ptr;
	unsigned i, nflush, ndeferred;
	bool merged_stats = false;

	assert(binind < nhbins);
	assert(rem <= tbin->ncached);

	for (nflush = tbin->ncached - rem; nflush > 0; nflush = ndeferred) {
	/* Lock the arena associated with the first object. */
	arena_chunk_t chunk = (arena_chunk_t )CHUNK_ADDR2BASE(
	tbin->avail[0]);
	arena_t *arena = chunk->arena;
	UNUSED bool idump;

	if (config_prof)
	idump = false;
	malloc_mutex_lock(&arena->lock);
	if ((config_prof \|\| config_stats) && arena == tcache->arena) {
	if (config_prof) {
	idump = arena_prof_accum_locked(arena,
	tcache->prof_accumbytes);
	tcache->prof_accumbytes = 0;
	}
	if (config_stats) {
	merged_stats = true;
	arena->stats.nrequests_large +=
	tbin->tstats.nrequests;
	arena->stats.lstats[binind - NBINS].nrequests +=
	tbin->tstats.nrequests;
	tbin->tstats.nrequests = 0;
	}
	}
	ndeferred = 0;
	for (i = 0; i < nflush; i++) {
	ptr = tbin->avail[i];
	assert(ptr != NULL);
	chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ptr);
	if (chunk->arena == arena)
	arena_dalloc_large_locked(arena, chunk, ptr);
	else {
	/*
	* This object was allocated via a different
	* arena than the one that is currently locked.
	* Stash the object, so that it can be handled
	* in a future pass.
	*/
	tbin->avail[ndeferred] = ptr;
	ndeferred++;
	}
	}
	malloc_mutex_unlock(&arena->lock);
	if (config_prof && idump)
	prof_idump();
	}
	if (config_stats && merged_stats == false) {
	/*
	* The flush loop didn't happen to flush to this thread's
	* arena, so the stats didn't get merged. Manually do so now.
	*/
	arena_t *arena = tcache->arena;
	malloc_mutex_lock(&arena->lock);
	arena->stats.nrequests_large += tbin->tstats.nrequests;
	arena->stats.lstats[binind - NBINS].nrequests +=
	tbin->tstats.nrequests;
	tbin->tstats.nrequests = 0;
	malloc_mutex_unlock(&arena->lock);
	}

	memmove(tbin->avail, &tbin->avail[tbin->ncached - rem],
	rem * sizeof(void *));
	tbin->ncached = rem;
	if ((int)tbin->ncached < tbin->low_water)
	tbin->low_water = tbin->ncached;
	}

	void
	tcache_arena_associate(tcache_t tcache, arena_t arena)
	{

	if (config_stats) {
	/* Link into list of extant tcaches. */
	malloc_mutex_lock(&arena->lock);
	ql_elm_new(tcache, link);
	ql_tail_insert(&arena->tcache_ql, tcache, link);
	malloc_mutex_unlock(&arena->lock);
	}
	tcache->arena = arena;
	}

	void
	tcache_arena_dissociate(tcache_t *tcache)
	{

	if (config_stats) {
	/* Unlink from list of extant tcaches. */
	malloc_mutex_lock(&tcache->arena->lock);
	ql_remove(&tcache->arena->tcache_ql, tcache, link);
	tcache_stats_merge(tcache, tcache->arena);
	malloc_mutex_unlock(&tcache->arena->lock);
	}
	}

	tcache_t *
	tcache_get_hard(tcache_t *tcache, bool create)
	{

	if (tcache == NULL) {
	if (create == false) {
	/*
	* Creating a tcache here would cause
	* allocation as a side effect of free().
	* Ordinarily that would be okay since
	* tcache_create() failure is a soft failure
	* that doesn't propagate. However, if TLS
	* data are freed via free() as in glibc,
	* subtle corruption could result from setting
	* a TLS variable after its backing memory is
	* freed.
	*/
	return (NULL);
	}
	if (tcache_enabled_get() == false) {
	tcache_enabled_set(false); /* Memoize. */
	return (NULL);
	}
	return (tcache_create(choose_arena(NULL)));
	}
	if (tcache == TCACHE_STATE_PURGATORY) {
	/*
	* Make a note that an allocator function was called
	* after tcache_thread_cleanup() was called.
	*/
	tcache = TCACHE_STATE_REINCARNATED;
	tcache_tsd_set(&tcache);
	return (NULL);
	}
	if (tcache == TCACHE_STATE_REINCARNATED)
	return (NULL);
	not_reached();
	return (NULL);
	}

	tcache_t *
	tcache_create(arena_t *arena)
	{
	tcache_t *tcache;
	size_t size, stack_offset;
	unsigned i;

	size = offsetof(tcache_t, tbins) + (sizeof(tcache_bin_t) * nhbins);
	/* Naturally align the pointer stacks. */
	size = PTR_CEILING(size);
	stack_offset = size;
	size += stack_nelms * sizeof(void *);
	/*
	* Round up to the nearest multiple of the cacheline size, in order to
	* avoid the possibility of false cacheline sharing.
	*
	* That this works relies on the same logic as in ipalloc(), but we
	* cannot directly call ipalloc() here due to tcache bootstrapping
	* issues.
	*/
	size = (size + CACHELINE_MASK) & (-CACHELINE);

	if (size <= SMALL_MAXCLASS)
	tcache = (tcache_t *)arena_malloc_small(arena, size, true);
	else if (size <= tcache_maxclass)
	tcache = (tcache_t *)arena_malloc_large(arena, size, true);
	else
	tcache = (tcache_t *)icalloct(size, false, arena);

	if (tcache == NULL)
	return (NULL);

	tcache_arena_associate(tcache, arena);

	assert((TCACHE_NSLOTS_SMALL_MAX & 1U) == 0);
	for (i = 0; i < nhbins; i++) {
	tcache->tbins[i].lg_fill_div = 1;
	tcache->tbins[i].avail = (void **)((uintptr_t)tcache +
	(uintptr_t)stack_offset);
	stack_offset += tcache_bin_info[i].ncached_max * sizeof(void *);
	}

	tcache_tsd_set(&tcache);

	return (tcache);
	}

	void
	tcache_destroy(tcache_t *tcache)
	{
	unsigned i;
	size_t tcache_size;

	tcache_arena_dissociate(tcache);

	for (i = 0; i < NBINS; i++) {
	tcache_bin_t *tbin = &tcache->tbins[i];
	tcache_bin_flush_small(tbin, i, 0, tcache);

	if (config_stats && tbin->tstats.nrequests != 0) {
	arena_t *arena = tcache->arena;
	arena_bin_t *bin = &arena->bins[i];
	malloc_mutex_lock(&bin->lock);
	bin->stats.nrequests += tbin->tstats.nrequests;
	malloc_mutex_unlock(&bin->lock);
	}
	}

	for (; i < nhbins; i++) {
	tcache_bin_t *tbin = &tcache->tbins[i];
	tcache_bin_flush_large(tbin, i, 0, tcache);

	if (config_stats && tbin->tstats.nrequests != 0) {
	arena_t *arena = tcache->arena;
	malloc_mutex_lock(&arena->lock);
	arena->stats.nrequests_large += tbin->tstats.nrequests;
	arena->stats.lstats[i - NBINS].nrequests +=
	tbin->tstats.nrequests;
	malloc_mutex_unlock(&arena->lock);
	}
	}

	if (config_prof && tcache->prof_accumbytes > 0 &&
	arena_prof_accum(tcache->arena, tcache->prof_accumbytes))
	prof_idump();

	tcache_size = arena_salloc(tcache, false);
	if (tcache_size <= SMALL_MAXCLASS) {
	arena_chunk_t *chunk = CHUNK_ADDR2BASE(tcache);
	arena_t *arena = chunk->arena;
	size_t pageind = ((uintptr_t)tcache - (uintptr_t)chunk) >>
	LG_PAGE;
	arena_chunk_map_t *mapelm = arena_mapp_get(chunk, pageind);

	arena_dalloc_bin(arena, chunk, tcache, pageind, mapelm);
	} else if (tcache_size <= tcache_maxclass) {
	arena_chunk_t *chunk = CHUNK_ADDR2BASE(tcache);
	arena_t *arena = chunk->arena;

	arena_dalloc_large(arena, chunk, tcache);
	} else
	idalloct(tcache, false);
	}

	void
	tcache_thread_cleanup(void *arg)
	{
	tcache_t tcache = (tcache_t **)arg;

	if (tcache == TCACHE_STATE_DISABLED) {
	/* Do nothing. */
	} else if (tcache == TCACHE_STATE_REINCARNATED) {
	/*
	* Another destructor called an allocator function after this
	* destructor was called. Reset tcache to
	* TCACHE_STATE_PURGATORY in order to receive another callback.
	*/
	tcache = TCACHE_STATE_PURGATORY;
	tcache_tsd_set(&tcache);
	} else if (tcache == TCACHE_STATE_PURGATORY) {
	/*
	* The previous time this destructor was called, we set the key
	* to TCACHE_STATE_PURGATORY so that other destructors wouldn't
	* cause re-creation of the tcache. This time, do nothing, so
	* that the destructor will not be called again.
	*/
	} else if (tcache != NULL) {
	assert(tcache != TCACHE_STATE_PURGATORY);
	tcache_destroy(tcache);
	tcache = TCACHE_STATE_PURGATORY;
	tcache_tsd_set(&tcache);
	}
	}

	/* Caller must own arena->lock. */
	void
	tcache_stats_merge(tcache_t tcache, arena_t arena)
	{
	unsigned i;

	cassert(config_stats);

	/* Merge and reset tcache stats. */
	for (i = 0; i < NBINS; i++) {
	arena_bin_t *bin = &arena->bins[i];
	tcache_bin_t *tbin = &tcache->tbins[i];
	malloc_mutex_lock(&bin->lock);
	bin->stats.nrequests += tbin->tstats.nrequests;
	malloc_mutex_unlock(&bin->lock);
	tbin->tstats.nrequests = 0;
	}

	for (; i < nhbins; i++) {
	malloc_large_stats_t *lstats = &arena->stats.lstats[i - NBINS];
	tcache_bin_t *tbin = &tcache->tbins[i];
	arena->stats.nrequests_large += tbin->tstats.nrequests;
	lstats->nrequests += tbin->tstats.nrequests;
	tbin->tstats.nrequests = 0;
	}
	}

	bool
	tcache_boot0(void)
	{
	unsigned i;

	/*
	* If necessary, clamp opt_lg_tcache_max, now that arena_maxclass is
	* known.
	*/
	if (opt_lg_tcache_max < 0 \|\| (1U << opt_lg_tcache_max) < SMALL_MAXCLASS)
	tcache_maxclass = SMALL_MAXCLASS;
	else if ((1U << opt_lg_tcache_max) > arena_maxclass)
	tcache_maxclass = arena_maxclass;
	else
	tcache_maxclass = (1U << opt_lg_tcache_max);

	nhbins = NBINS + (tcache_maxclass >> LG_PAGE);

	/* Initialize tcache_bin_info. */
	tcache_bin_info = (tcache_bin_info_t )base_alloc(nhbins
	sizeof(tcache_bin_info_t));
	if (tcache_bin_info == NULL)
	return (true);
	stack_nelms = 0;
	for (i = 0; i < NBINS; i++) {
	if ((arena_bin_info[i].nregs << 1) <= TCACHE_NSLOTS_SMALL_MAX) {
	tcache_bin_info[i].ncached_max =
	(arena_bin_info[i].nregs << 1);
	} else {
	tcache_bin_info[i].ncached_max =
	TCACHE_NSLOTS_SMALL_MAX;
	}
	stack_nelms += tcache_bin_info[i].ncached_max;
	}
	for (; i < nhbins; i++) {
	tcache_bin_info[i].ncached_max = TCACHE_NSLOTS_LARGE;
	stack_nelms += tcache_bin_info[i].ncached_max;
	}

	return (false);
	}

	bool
	tcache_boot1(void)
	{

	if (tcache_tsd_boot() \|\| tcache_enabled_tsd_boot())
	return (true);

	return (false);
	}