/******************************************************************************/ #ifdef JEMALLOC_H_TYPES typedef struct tcache_bin_info_s tcache_bin_info_t; typedef struct tcache_bin_s tcache_bin_t; typedef struct tcache_s tcache_t; /* * tcache pointers close to NULL are used to encode state information that is * used for two purposes: preventing thread caching on a per thread basis and * cleaning up during thread shutdown. */ #define TCACHE_STATE_DISABLED ((tcache_t *)(uintptr_t)1) #define TCACHE_STATE_REINCARNATED ((tcache_t *)(uintptr_t)2) #define TCACHE_STATE_PURGATORY ((tcache_t *)(uintptr_t)3) #define TCACHE_STATE_MAX TCACHE_STATE_PURGATORY /* * Absolute maximum number of cache slots for each small bin in the thread * cache. This is an additional constraint beyond that imposed as: twice the * number of regions per run for this size class. * * This constant must be an even number. */ #define TCACHE_NSLOTS_SMALL_MAX 200 /* Number of cache slots for large size classes. */ #define TCACHE_NSLOTS_LARGE 20 /* (1U << opt_lg_tcache_max) is used to compute tcache_maxclass. */ #define LG_TCACHE_MAXCLASS_DEFAULT 15 /* * TCACHE_GC_SWEEP is the approximate number of allocation events between * full GC sweeps. Integer rounding may cause the actual number to be * slightly higher, since GC is performed incrementally. */ #define TCACHE_GC_SWEEP 8192 /* Number of tcache allocation/deallocation events between incremental GCs. */ #define TCACHE_GC_INCR \ ((TCACHE_GC_SWEEP / NBINS) + ((TCACHE_GC_SWEEP / NBINS == 0) ? 0 : 1)) #endif /* JEMALLOC_H_TYPES */ /******************************************************************************/ #ifdef JEMALLOC_H_STRUCTS typedef enum { tcache_enabled_false = 0, /* Enable cast to/from bool. */ tcache_enabled_true = 1, tcache_enabled_default = 2 } tcache_enabled_t; /* * Read-only information associated with each element of tcache_t's tbins array * is stored separately, mainly to reduce memory usage. */ struct tcache_bin_info_s { unsigned ncached_max; /* Upper limit on ncached. */ }; struct tcache_bin_s { tcache_bin_stats_t tstats; int low_water; /* Min # cached since last GC. */ unsigned lg_fill_div; /* Fill (ncached_max >> lg_fill_div). */ unsigned ncached; /* # of cached objects. */ void **avail; /* Stack of available objects. */ }; struct tcache_s { ql_elm(tcache_t) link; /* Used for aggregating stats. */ uint64_t prof_accumbytes;/* Cleared after arena_prof_accum() */ arena_t *arena; /* This thread's arena. */ unsigned ev_cnt; /* Event count since incremental GC. */ unsigned next_gc_bin; /* Next bin to GC. */ tcache_bin_t tbins[1]; /* Dynamically sized. */ /* * The pointer stacks associated with tbins follow as a contiguous * array. During tcache initialization, the avail pointer in each * element of tbins is initialized to point to the proper offset within * this array. */ }; #endif /* JEMALLOC_H_STRUCTS */ /******************************************************************************/ #ifdef JEMALLOC_H_EXTERNS extern bool opt_tcache; extern ssize_t opt_lg_tcache_max; extern tcache_bin_info_t *tcache_bin_info; /* * Number of tcache bins. There are NBINS small-object bins, plus 0 or more * large-object bins. */ extern size_t nhbins; /* Maximum cached size class. */ extern size_t tcache_maxclass; size_t tcache_salloc(const void *ptr); void tcache_event_hard(tcache_t *tcache); void *tcache_alloc_small_hard(tcache_t *tcache, tcache_bin_t *tbin, size_t binind); void tcache_bin_flush_small(tcache_bin_t *tbin, size_t binind, unsigned rem, tcache_t *tcache); void tcache_bin_flush_large(tcache_bin_t *tbin, size_t binind, unsigned rem, tcache_t *tcache); void tcache_arena_associate(tcache_t *tcache, arena_t *arena); void tcache_arena_dissociate(tcache_t *tcache); tcache_t *tcache_get_hard(tsd_t *tsd); tcache_t *tcache_create(arena_t *arena); void tcache_cleanup(tsd_t *tsd); void tcache_enabled_cleanup(tsd_t *tsd); void tcache_stats_merge(tcache_t *tcache, arena_t *arena); bool tcache_boot(void); #endif /* JEMALLOC_H_EXTERNS */ /******************************************************************************/ #ifdef JEMALLOC_H_INLINES #ifndef JEMALLOC_ENABLE_INLINE void tcache_event(tcache_t *tcache); void tcache_flush(void); bool tcache_enabled_get(void); tcache_t *tcache_get(tsd_t *tsd, bool create); void tcache_enabled_set(bool enabled); void *tcache_alloc_easy(tcache_bin_t *tbin); void *tcache_alloc_small(tcache_t *tcache, size_t size, bool zero); void *tcache_alloc_large(tcache_t *tcache, size_t size, bool zero); void tcache_dalloc_small(tcache_t *tcache, void *ptr, size_t binind); void tcache_dalloc_large(tcache_t *tcache, void *ptr, size_t size); #endif #if (defined(JEMALLOC_ENABLE_INLINE) || defined(JEMALLOC_TCACHE_C_)) JEMALLOC_INLINE void tcache_flush(void) { tsd_t *tsd; cassert(config_tcache); tsd = tsd_fetch(); tcache_cleanup(tsd); } JEMALLOC_INLINE bool tcache_enabled_get(void) { tsd_t *tsd; tcache_enabled_t tcache_enabled; cassert(config_tcache); tsd = tsd_fetch(); tcache_enabled = tsd_tcache_enabled_get(tsd); if (tcache_enabled == tcache_enabled_default) { tcache_enabled = (tcache_enabled_t)opt_tcache; tsd_tcache_enabled_set(tsd, tcache_enabled); } return ((bool)tcache_enabled); } JEMALLOC_INLINE void tcache_enabled_set(bool enabled) { tsd_t *tsd; tcache_enabled_t tcache_enabled; cassert(config_tcache); tsd = tsd_fetch(); tcache_enabled = (tcache_enabled_t)enabled; tsd_tcache_enabled_set(tsd, tcache_enabled); if (!enabled) tcache_cleanup(tsd); } JEMALLOC_ALWAYS_INLINE tcache_t * tcache_get(tsd_t *tsd, bool create) { tcache_t *tcache; if (!config_tcache) return (NULL); if (config_lazy_lock && !isthreaded) return (NULL); tcache = tsd_tcache_get(tsd); if (!create) return (tcache); if (unlikely(tcache == NULL) && tsd_nominal(tsd)) { tcache = tcache_get_hard(tsd); tsd_tcache_set(tsd, tcache); } return (tcache); } JEMALLOC_ALWAYS_INLINE void tcache_event(tcache_t *tcache) { if (TCACHE_GC_INCR == 0) return; tcache->ev_cnt++; assert(tcache->ev_cnt <= TCACHE_GC_INCR); if (unlikely(tcache->ev_cnt == TCACHE_GC_INCR)) tcache_event_hard(tcache); } JEMALLOC_ALWAYS_INLINE void * tcache_alloc_easy(tcache_bin_t *tbin) { void *ret; if (unlikely(tbin->ncached == 0)) { tbin->low_water = -1; return (NULL); } tbin->ncached--; if (unlikely((int)tbin->ncached < tbin->low_water)) tbin->low_water = tbin->ncached; ret = tbin->avail[tbin->ncached]; return (ret); } JEMALLOC_ALWAYS_INLINE void * tcache_alloc_small(tcache_t *tcache, size_t size, bool zero) { void *ret; size_t binind; tcache_bin_t *tbin; binind = small_size2bin(size); assert(binind < NBINS); tbin = &tcache->tbins[binind]; size = small_bin2size(binind); ret = tcache_alloc_easy(tbin); if (unlikely(ret == NULL)) { ret = tcache_alloc_small_hard(tcache, tbin, binind); if (ret == NULL) return (NULL); } assert(tcache_salloc(ret) == size); if (likely(!zero)) { if (config_fill) { if (unlikely(opt_junk)) { arena_alloc_junk_small(ret, &arena_bin_info[binind], false); } else if (unlikely(opt_zero)) memset(ret, 0, size); } } else { if (config_fill && unlikely(opt_junk)) { arena_alloc_junk_small(ret, &arena_bin_info[binind], true); } memset(ret, 0, size); } if (config_stats) tbin->tstats.nrequests++; if (config_prof) tcache->prof_accumbytes += size; tcache_event(tcache); return (ret); } JEMALLOC_ALWAYS_INLINE void * tcache_alloc_large(tcache_t *tcache, size_t size, bool zero) { void *ret; size_t binind; tcache_bin_t *tbin; size = PAGE_CEILING(size); assert(size <= tcache_maxclass); binind = NBINS + (size >> LG_PAGE) - 1; assert(binind < nhbins); tbin = &tcache->tbins[binind]; ret = tcache_alloc_easy(tbin); if (unlikely(ret == NULL)) { /* * Only allocate one large object at a time, because it's quite * expensive to create one and not use it. */ ret = arena_malloc_large(tcache->arena, size, zero); if (ret == NULL) return (NULL); } else { if (config_prof && size == PAGE) { arena_chunk_t *chunk = (arena_chunk_t *)CHUNK_ADDR2BASE(ret); size_t pageind = (((uintptr_t)ret - (uintptr_t)chunk) >> LG_PAGE); arena_mapbits_large_binind_set(chunk, pageind, BININD_INVALID); } if (likely(!zero)) { if (config_fill) { if (unlikely(opt_junk)) memset(ret, 0xa5, size); else if (unlikely(opt_zero)) memset(ret, 0, size); } } else memset(ret, 0, size); if (config_stats) tbin->tstats.nrequests++; if (config_prof) tcache->prof_accumbytes += size; } tcache_event(tcache); return (ret); } JEMALLOC_ALWAYS_INLINE void tcache_dalloc_small(tcache_t *tcache, void *ptr, size_t binind) { tcache_bin_t *tbin; tcache_bin_info_t *tbin_info; assert(tcache_salloc(ptr) <= SMALL_MAXCLASS); if (config_fill && unlikely(opt_junk)) arena_dalloc_junk_small(ptr, &arena_bin_info[binind]); tbin = &tcache->tbins[binind]; tbin_info = &tcache_bin_info[binind]; if (unlikely(tbin->ncached == tbin_info->ncached_max)) { tcache_bin_flush_small(tbin, binind, (tbin_info->ncached_max >> 1), tcache); } assert(tbin->ncached < tbin_info->ncached_max); tbin->avail[tbin->ncached] = ptr; tbin->ncached++; tcache_event(tcache); } JEMALLOC_ALWAYS_INLINE void tcache_dalloc_large(tcache_t *tcache, void *ptr, size_t size) { size_t binind; tcache_bin_t *tbin; tcache_bin_info_t *tbin_info; assert((size & PAGE_MASK) == 0); assert(tcache_salloc(ptr) > SMALL_MAXCLASS); assert(tcache_salloc(ptr) <= tcache_maxclass); binind = NBINS + (size >> LG_PAGE) - 1; if (config_fill && unlikely(opt_junk)) memset(ptr, 0x5a, size); tbin = &tcache->tbins[binind]; tbin_info = &tcache_bin_info[binind]; if (unlikely(tbin->ncached == tbin_info->ncached_max)) { tcache_bin_flush_large(tbin, binind, (tbin_info->ncached_max >> 1), tcache); } assert(tbin->ncached < tbin_info->ncached_max); tbin->avail[tbin->ncached] = ptr; tbin->ncached++; tcache_event(tcache); } #endif #endif /* JEMALLOC_H_INLINES */ /******************************************************************************/