#define JEMALLOC_HUGE_C_ #include "jemalloc/internal/jemalloc_internal.h" /******************************************************************************/ /* Data. */ #ifdef JEMALLOC_STATS uint64_t huge_nmalloc; uint64_t huge_ndalloc; size_t huge_allocated; #endif malloc_mutex_t huge_mtx; /******************************************************************************/ /* Tree of chunks that are stand-alone huge allocations. */ static extent_tree_t huge; void * huge_malloc(size_t size, bool zero) { void *ret; size_t csize; extent_node_t *node; /* Allocate one or more contiguous chunks for this request. */ csize = CHUNK_CEILING(size); if (csize == 0) { /* size is large enough to cause size_t wrap-around. */ return (NULL); } /* Allocate an extent node with which to track the chunk. */ node = base_node_alloc(); if (node == NULL) return (NULL); ret = chunk_alloc(csize, false, &zero); if (ret == NULL) { base_node_dealloc(node); return (NULL); } /* Insert node into huge. */ node->addr = ret; node->size = csize; malloc_mutex_lock(&huge_mtx); extent_tree_ad_insert(&huge, node); #ifdef JEMALLOC_STATS huge_nmalloc++; huge_allocated += csize; #endif malloc_mutex_unlock(&huge_mtx); #ifdef JEMALLOC_FILL if (zero == false) { if (opt_junk) memset(ret, 0xa5, csize); else if (opt_zero) memset(ret, 0, csize); } #endif return (ret); } /* Only handles large allocations that require more than chunk alignment. */ void * huge_palloc(size_t alignment, size_t size) { void *ret; size_t alloc_size, chunk_size, offset; extent_node_t *node; bool zero; /* * This allocation requires alignment that is even larger than chunk * alignment. This means that huge_malloc() isn't good enough. * * Allocate almost twice as many chunks as are demanded by the size or * alignment, in order to assure the alignment can be achieved, then * unmap leading and trailing chunks. */ assert(alignment >= chunksize); chunk_size = CHUNK_CEILING(size); if (size >= alignment) alloc_size = chunk_size + alignment - chunksize; else alloc_size = (alignment << 1) - chunksize; /* Allocate an extent node with which to track the chunk. */ node = base_node_alloc(); if (node == NULL) return (NULL); zero = false; ret = chunk_alloc(alloc_size, false, &zero); if (ret == NULL) { base_node_dealloc(node); return (NULL); } offset = (uintptr_t)ret & (alignment - 1); assert((offset & chunksize_mask) == 0); assert(offset < alloc_size); if (offset == 0) { /* Trim trailing space. */ chunk_dealloc((void *)((uintptr_t)ret + chunk_size), alloc_size - chunk_size); } else { size_t trailsize; /* Trim leading space. */ chunk_dealloc(ret, alignment - offset); ret = (void *)((uintptr_t)ret + (alignment - offset)); trailsize = alloc_size - (alignment - offset) - chunk_size; if (trailsize != 0) { /* Trim trailing space. */ assert(trailsize < alloc_size); chunk_dealloc((void *)((uintptr_t)ret + chunk_size), trailsize); } } /* Insert node into huge. */ node->addr = ret; node->size = chunk_size; malloc_mutex_lock(&huge_mtx); extent_tree_ad_insert(&huge, node); #ifdef JEMALLOC_STATS huge_nmalloc++; huge_allocated += chunk_size; #endif malloc_mutex_unlock(&huge_mtx); #ifdef JEMALLOC_FILL if (opt_junk) memset(ret, 0xa5, chunk_size); else if (opt_zero) memset(ret, 0, chunk_size); #endif return (ret); } void * huge_ralloc(void *ptr, size_t size, size_t oldsize) { void *ret; size_t copysize; /* Avoid moving the allocation if the size class would not change. */ if (oldsize > arena_maxclass && CHUNK_CEILING(size) == CHUNK_CEILING(oldsize)) { #ifdef JEMALLOC_FILL if (opt_junk && size < oldsize) { memset((void *)((uintptr_t)ptr + size), 0x5a, oldsize - size); } else if (opt_zero && size > oldsize) { memset((void *)((uintptr_t)ptr + oldsize), 0, size - oldsize); } #endif return (ptr); } /* * If we get here, then size and oldsize are different enough that we * need to use a different size class. In that case, fall back to * allocating new space and copying. */ ret = huge_malloc(size, false); if (ret == NULL) return (NULL); copysize = (size < oldsize) ? size : oldsize; memcpy(ret, ptr, copysize); idalloc(ptr); return (ret); } void huge_dalloc(void *ptr) { extent_node_t *node, key; malloc_mutex_lock(&huge_mtx); /* Extract from tree of huge allocations. */ key.addr = ptr; node = extent_tree_ad_search(&huge, &key); assert(node != NULL); assert(node->addr == ptr); extent_tree_ad_remove(&huge, node); #ifdef JEMALLOC_STATS huge_ndalloc++; huge_allocated -= node->size; #endif malloc_mutex_unlock(&huge_mtx); /* Unmap chunk. */ #ifdef JEMALLOC_FILL #if (defined(JEMALLOC_SWAP) || defined(JEMALLOC_DSS)) if (opt_junk) memset(node->addr, 0x5a, node->size); #endif #endif chunk_dealloc(node->addr, node->size); base_node_dealloc(node); } size_t huge_salloc(const void *ptr) { size_t ret; extent_node_t *node, key; malloc_mutex_lock(&huge_mtx); /* Extract from tree of huge allocations. */ key.addr = __DECONST(void *, ptr); node = extent_tree_ad_search(&huge, &key); assert(node != NULL); ret = node->size; malloc_mutex_unlock(&huge_mtx); return (ret); } #ifdef JEMALLOC_PROF prof_ctx_t * huge_prof_ctx_get(const void *ptr) { prof_ctx_t *ret; extent_node_t *node, key; malloc_mutex_lock(&huge_mtx); /* Extract from tree of huge allocations. */ key.addr = __DECONST(void *, ptr); node = extent_tree_ad_search(&huge, &key); assert(node != NULL); ret = node->prof_ctx; malloc_mutex_unlock(&huge_mtx); return (ret); } void huge_prof_ctx_set(const void *ptr, prof_ctx_t *ctx) { extent_node_t *node, key; malloc_mutex_lock(&huge_mtx); /* Extract from tree of huge allocations. */ key.addr = __DECONST(void *, ptr); node = extent_tree_ad_search(&huge, &key); assert(node != NULL); node->prof_ctx = ctx; malloc_mutex_unlock(&huge_mtx); } #endif bool huge_boot(void) { /* Initialize chunks data. */ if (malloc_mutex_init(&huge_mtx)) return (true); extent_tree_ad_new(&huge); #ifdef JEMALLOC_STATS huge_nmalloc = 0; huge_ndalloc = 0; huge_allocated = 0; #endif return (false); }