#include "../libnetdata.h" #include "aral.h" #ifdef NETDATA_TRACE_ALLOCATIONS #define TRACE_ALLOCATIONS_FUNCTION_DEFINITION_PARAMS , const char *file, const char *function, size_t line #define TRACE_ALLOCATIONS_FUNCTION_CALL_PARAMS , file, function, line #else #define TRACE_ALLOCATIONS_FUNCTION_DEFINITION_PARAMS #define TRACE_ALLOCATIONS_FUNCTION_CALL_PARAMS #endif #define ARAL_FREE_PAGES_DELTA_TO_REARRANGE_LIST 5 // max file size #define ARAL_MAX_PAGE_SIZE_MMAP (1*1024*1024*1024) // max malloc size // optimal at current versions of libc is up to 256k // ideal to have the same overhead as libc is 4k #define ARAL_MAX_PAGE_SIZE_MALLOC (65*1024) typedef struct aral_free { size_t size; struct aral_free *next; } ARAL_FREE; typedef struct aral_page { size_t size; // the allocation size of the page const char *filename; uint8_t *data; uint32_t free_elements_to_move_first; uint32_t max_elements; // the number of elements that can fit on this page struct { uint32_t used_elements; // the number of used elements on this page uint32_t free_elements; // the number of free elements on this page struct aral_page *prev; // the prev page on the list struct aral_page *next; // the next page on the list } aral_lock; struct { SPINLOCK spinlock; ARAL_FREE *list; } free; } ARAL_PAGE; typedef enum { ARAL_LOCKLESS = (1 << 0), ARAL_DEFRAGMENT = (1 << 1), ARAL_ALLOCATED_STATS = (1 << 2), } ARAL_OPTIONS; struct aral { struct { char name[ARAL_MAX_NAME + 1]; ARAL_OPTIONS options; size_t element_size; // calculated to take into account ARAL overheads size_t max_allocation_size; // calculated in bytes size_t max_page_elements; // calculated size_t page_ptr_offset; // calculated size_t natural_page_size; // calculated size_t initial_page_elements; size_t requested_element_size; size_t requested_max_page_size; struct { bool enabled; const char *filename; char **cache_dir; } mmap; } config; struct { SPINLOCK spinlock; size_t file_number; // for mmap struct aral_page *pages; // linked list of pages size_t user_malloc_operations; size_t user_free_operations; size_t defragment_operations; size_t defragment_linked_list_traversals; } aral_lock; struct { SPINLOCK spinlock; size_t allocating_elements; // currently allocating elements size_t allocation_size; // current / next allocation size } adders; struct { size_t allocators; // the number of threads currently trying to allocate memory } atomic; struct aral_statistics *stats; }; size_t aral_structures_from_stats(struct aral_statistics *stats) { return __atomic_load_n(&stats->structures.allocated_bytes, __ATOMIC_RELAXED); } size_t aral_overhead_from_stats(struct aral_statistics *stats) { return __atomic_load_n(&stats->malloc.allocated_bytes, __ATOMIC_RELAXED) - __atomic_load_n(&stats->malloc.used_bytes, __ATOMIC_RELAXED); } size_t aral_overhead(ARAL *ar) { return aral_overhead_from_stats(ar->stats); } size_t aral_structures(ARAL *ar) { return aral_structures_from_stats(ar->stats); } struct aral_statistics *aral_statistics(ARAL *ar) { return ar->stats; } #define ARAL_NATURAL_ALIGNMENT (sizeof(uintptr_t) * 2) static inline size_t natural_alignment(size_t size, size_t alignment) { if(unlikely(size % alignment)) size = size + alignment - (size % alignment); return size; } static size_t aral_align_alloc_size(ARAL *ar, uint64_t size) { if(size % ar->config.natural_page_size) size += ar->config.natural_page_size - (size % ar->config.natural_page_size) ; if(size % ar->config.element_size) size -= size % ar->config.element_size; return size; } static inline void aral_lock(ARAL *ar) { if(likely(!(ar->config.options & ARAL_LOCKLESS))) netdata_spinlock_lock(&ar->aral_lock.spinlock); } static inline void aral_unlock(ARAL *ar) { if(likely(!(ar->config.options & ARAL_LOCKLESS))) netdata_spinlock_unlock(&ar->aral_lock.spinlock); } static inline void aral_page_free_lock(ARAL *ar, ARAL_PAGE *page) { if(likely(!(ar->config.options & ARAL_LOCKLESS))) netdata_spinlock_lock(&page->free.spinlock); } static inline void aral_page_free_unlock(ARAL *ar, ARAL_PAGE *page) { if(likely(!(ar->config.options & ARAL_LOCKLESS))) netdata_spinlock_unlock(&page->free.spinlock); } static inline bool aral_adders_trylock(ARAL *ar) { if(likely(!(ar->config.options & ARAL_LOCKLESS))) return netdata_spinlock_trylock(&ar->adders.spinlock); return true; } static inline void aral_adders_lock(ARAL *ar) { if(likely(!(ar->config.options & ARAL_LOCKLESS))) netdata_spinlock_lock(&ar->adders.spinlock); } static inline void aral_adders_unlock(ARAL *ar) { if(likely(!(ar->config.options & ARAL_LOCKLESS))) netdata_spinlock_unlock(&ar->adders.spinlock); } static void aral_delete_leftover_files(const char *name, const char *path, const char *required_prefix) { DIR *dir = opendir(path); if(!dir) return; char full_path[FILENAME_MAX + 1]; size_t len = strlen(required_prefix); struct dirent *de = NULL; while((de = readdir(dir))) { if(de->d_type == DT_DIR) continue; if(strncmp(de->d_name, required_prefix, len) != 0) continue; snprintfz(full_path, FILENAME_MAX, "%s/%s", path, de->d_name); info("ARAL: '%s' removing left-over file '%s'", name, full_path); if(unlikely(unlink(full_path) == -1)) error("ARAL: '%s' cannot delete file '%s'", name, full_path); } closedir(dir); } // ---------------------------------------------------------------------------- // check a free slot #ifdef NETDATA_INTERNAL_CHECKS static inline void aral_free_validate_internal_check(ARAL *ar, ARAL_FREE *fr) { if(unlikely(fr->size < ar->config.element_size)) fatal("ARAL: '%s' free item of size %zu, less than the expected element size %zu", ar->config.name, fr->size, ar->config.element_size); if(unlikely(fr->size % ar->config.element_size)) fatal("ARAL: '%s' free item of size %zu is not multiple to element size %zu", ar->config.name, fr->size, ar->config.element_size); } #else #define aral_free_validate_internal_check(ar, fr) debug_dummy() #endif // ---------------------------------------------------------------------------- // find the page a pointer belongs to #ifdef NETDATA_INTERNAL_CHECKS static inline ARAL_PAGE *find_page_with_allocation_internal_check(ARAL *ar, void *ptr) { aral_lock(ar); uintptr_t seeking = (uintptr_t)ptr; ARAL_PAGE *page; for(page = ar->aral_lock.pages; page ; page = page->aral_lock.next) { if(unlikely(seeking >= (uintptr_t)page->data && seeking < (uintptr_t)page->data + page->size)) break; } aral_unlock(ar); return page; } #endif // ---------------------------------------------------------------------------- // find a page with a free slot (there shouldn't be any) #ifdef NETDATA_ARAL_INTERNAL_CHECKS static inline ARAL_PAGE *find_page_with_free_slots_internal_check___with_aral_lock(ARAL *ar) { ARAL_PAGE *page; for(page = ar->aral_lock.pages; page ; page = page->next) { if(page->aral_lock.free_elements) break; internal_fatal(page->size - page->aral_lock.used_elements * ar->config.element_size >= ar->config.element_size, "ARAL: '%s' a page is marked full, but it is not!", ar->config.name); internal_fatal(page->size < page->aral_lock.used_elements * ar->config.element_size, "ARAL: '%s' a page has been overflown!", ar->config.name); } return page; } #endif size_t aral_next_allocation_size___adders_lock_needed(ARAL *ar) { size_t size = ar->adders.allocation_size; if(size > ar->config.max_allocation_size) size = ar->config.max_allocation_size; else ar->adders.allocation_size = aral_align_alloc_size(ar, (uint64_t)ar->adders.allocation_size * 2); return size; } static ARAL_PAGE *aral_create_page___no_lock_needed(ARAL *ar, size_t size TRACE_ALLOCATIONS_FUNCTION_DEFINITION_PARAMS) { ARAL_PAGE *page = callocz(1, sizeof(ARAL_PAGE)); netdata_spinlock_init(&page->free.spinlock); page->size = size; page->max_elements = page->size / ar->config.element_size; page->aral_lock.free_elements = page->max_elements; page->free_elements_to_move_first = page->max_elements / 4; if(unlikely(page->free_elements_to_move_first < 1)) page->free_elements_to_move_first = 1; __atomic_add_fetch(&ar->stats->structures.allocations, 1, __ATOMIC_RELAXED); __atomic_add_fetch(&ar->stats->structures.allocated_bytes, sizeof(ARAL_PAGE), __ATOMIC_RELAXED); if(unlikely(ar->config.mmap.enabled)) { ar->aral_lock.file_number++; char filename[FILENAME_MAX + 1]; snprintfz(filename, FILENAME_MAX, "%s/array_alloc.mmap/%s.%zu", *ar->config.mmap.cache_dir, ar->config.mmap.filename, ar->aral_lock.file_number); page->filename = strdupz(filename); page->data = netdata_mmap(page->filename, page->size, MAP_SHARED, 0, false, NULL); if (unlikely(!page->data)) fatal("ARAL: '%s' cannot allocate aral buffer of size %zu on filename '%s'", ar->config.name, page->size, page->filename); __atomic_add_fetch(&ar->stats->mmap.allocations, 1, __ATOMIC_RELAXED); __atomic_add_fetch(&ar->stats->mmap.allocated_bytes, page->size, __ATOMIC_RELAXED); } else { #ifdef NETDATA_TRACE_ALLOCATIONS page->data = mallocz_int(page->size TRACE_ALLOCATIONS_FUNCTION_CALL_PARAMS); #else page->data = mallocz(page->size); #endif __atomic_add_fetch(&ar->stats->malloc.allocations, 1, __ATOMIC_RELAXED); __atomic_add_fetch(&ar->stats->malloc.allocated_bytes, page->size, __ATOMIC_RELAXED); } // link the free space to its page ARAL_FREE *fr = (ARAL_FREE *)page->data; fr->size = page->size; fr->next = NULL; page->free.list = fr; aral_free_validate_internal_check(ar, fr); return page; } void aral_del_page___no_lock_needed(ARAL *ar, ARAL_PAGE *page TRACE_ALLOCATIONS_FUNCTION_DEFINITION_PARAMS) { // free it if (ar->config.mmap.enabled) { netdata_munmap(page->data, page->size); if (unlikely(unlink(page->filename) == 1)) error("Cannot delete file '%s'", page->filename); freez((void *)page->filename); __atomic_sub_fetch(&ar->stats->mmap.allocations, 1, __ATOMIC_RELAXED); __atomic_sub_fetch(&ar->stats->mmap.allocated_bytes, page->size, __ATOMIC_RELAXED); } else { #ifdef NETDATA_TRACE_ALLOCATIONS freez_int(page->data TRACE_ALLOCATIONS_FUNCTION_CALL_PARAMS); #else freez(page->data); #endif __atomic_sub_fetch(&ar->stats->malloc.allocations, 1, __ATOMIC_RELAXED); __atomic_sub_fetch(&ar->stats->malloc.allocated_bytes, page->size, __ATOMIC_RELAXED); } freez(page); __atomic_sub_fetch(&ar->stats->structures.allocations, 1, __ATOMIC_RELAXED); __atomic_sub_fetch(&ar->stats->structures.allocated_bytes, sizeof(ARAL_PAGE), __ATOMIC_RELAXED); } static inline void aral_insert_not_linked_page_with_free_items_to_proper_position___aral_lock_needed(ARAL *ar, ARAL_PAGE *page) { ARAL_PAGE *first = ar->aral_lock.pages; if (page->aral_lock.free_elements <= page->free_elements_to_move_first || !first || !first->aral_lock.free_elements || page->aral_lock.free_elements <= first->aral_lock.free_elements + ARAL_FREE_PAGES_DELTA_TO_REARRANGE_LIST) { // first position DOUBLE_LINKED_LIST_PREPEND_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); } else { ARAL_PAGE *second = first->aral_lock.next; if (!second || !second->aral_lock.free_elements || page->aral_lock.free_elements <= second->aral_lock.free_elements) // second position DOUBLE_LINKED_LIST_INSERT_ITEM_AFTER_UNSAFE(ar->aral_lock.pages, first, page, aral_lock.prev, aral_lock.next); else // third position DOUBLE_LINKED_LIST_INSERT_ITEM_AFTER_UNSAFE(ar->aral_lock.pages, second, page, aral_lock.prev, aral_lock.next); } } static inline ARAL_PAGE *aral_acquire_a_free_slot(ARAL *ar TRACE_ALLOCATIONS_FUNCTION_DEFINITION_PARAMS) { __atomic_add_fetch(&ar->atomic.allocators, 1, __ATOMIC_RELAXED); aral_lock(ar); ARAL_PAGE *page = ar->aral_lock.pages; while(!page || !page->aral_lock.free_elements) { #ifdef NETDATA_ARAL_INTERNAL_CHECKS internal_fatal(find_page_with_free_slots_internal_check___with_aral_lock(ar), "ARAL: '%s' found page with free slot!", ar->config.name); #endif aral_unlock(ar); if(aral_adders_trylock(ar)) { if(ar->adders.allocating_elements < __atomic_load_n(&ar->atomic.allocators, __ATOMIC_RELAXED)) { size_t size = aral_next_allocation_size___adders_lock_needed(ar); ar->adders.allocating_elements += size / ar->config.element_size; aral_adders_unlock(ar); page = aral_create_page___no_lock_needed(ar, size TRACE_ALLOCATIONS_FUNCTION_CALL_PARAMS); aral_lock(ar); aral_insert_not_linked_page_with_free_items_to_proper_position___aral_lock_needed(ar, page); aral_adders_lock(ar); ar->adders.allocating_elements -= size / ar->config.element_size; aral_adders_unlock(ar); // we have a page that is all empty // and only aral_lock() is held, so // break the loop break; } aral_adders_unlock(ar); } aral_lock(ar); page = ar->aral_lock.pages; } __atomic_sub_fetch(&ar->atomic.allocators, 1, __ATOMIC_RELAXED); // we have a page // and aral locked { ARAL_PAGE *first = ar->aral_lock.pages; ARAL_PAGE *second = first->aral_lock.next; if (!second || !second->aral_lock.free_elements || first->aral_lock.free_elements <= second->aral_lock.free_elements + ARAL_FREE_PAGES_DELTA_TO_REARRANGE_LIST) page = first; else { DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(ar->aral_lock.pages, second, aral_lock.prev, aral_lock.next); DOUBLE_LINKED_LIST_PREPEND_ITEM_UNSAFE(ar->aral_lock.pages, second, aral_lock.prev, aral_lock.next); page = second; } } internal_fatal(!page || !page->aral_lock.free_elements, "ARAL: '%s' selected page does not have a free slot in it", ar->config.name); internal_fatal(page->max_elements != page->aral_lock.used_elements + page->aral_lock.free_elements, "ARAL: '%s' page element counters do not match, " "page says it can handle %zu elements, " "but there are %zu used and %zu free items, " "total %zu items", ar->config.name, (size_t)page->max_elements, (size_t)page->aral_lock.used_elements, (size_t)page->aral_lock.free_elements, (size_t)page->aral_lock.used_elements + (size_t)page->aral_lock.free_elements ); ar->aral_lock.user_malloc_operations++; // acquire a slot for the caller page->aral_lock.used_elements++; if(--page->aral_lock.free_elements == 0) { // we are done with this page // move the full page last // so that pages with free items remain first in the list DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); DOUBLE_LINKED_LIST_APPEND_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); } aral_unlock(ar); return page; } void *aral_mallocz_internal(ARAL *ar TRACE_ALLOCATIONS_FUNCTION_DEFINITION_PARAMS) { #ifdef FSANITIZE_ADDRESS return mallocz(ar->config.requested_element_size); #endif ARAL_PAGE *page = aral_acquire_a_free_slot(ar TRACE_ALLOCATIONS_FUNCTION_CALL_PARAMS); aral_page_free_lock(ar, page); internal_fatal(!page->free.list, "ARAL: '%s' free item to use, cannot be NULL.", ar->config.name); internal_fatal(page->free.list->size < ar->config.element_size, "ARAL: '%s' free item size %zu, cannot be smaller than %zu", ar->config.name, page->free.list->size, ar->config.element_size); ARAL_FREE *found_fr = page->free.list; // check if the remaining size (after we use this slot) is not enough for another element if(unlikely(found_fr->size - ar->config.element_size < ar->config.element_size)) { // we can use the entire free space entry page->free.list = found_fr->next; } else { // we can split the free space entry uint8_t *data = (uint8_t *)found_fr; ARAL_FREE *fr = (ARAL_FREE *)&data[ar->config.element_size]; fr->size = found_fr->size - ar->config.element_size; // link the free slot first in the page fr->next = found_fr->next; page->free.list = fr; aral_free_validate_internal_check(ar, fr); } aral_page_free_unlock(ar, page); // put the page pointer after the element uint8_t *data = (uint8_t *)found_fr; ARAL_PAGE **page_ptr = (ARAL_PAGE **)&data[ar->config.page_ptr_offset]; *page_ptr = page; if(unlikely(ar->config.mmap.enabled)) __atomic_add_fetch(&ar->stats->mmap.used_bytes, ar->config.element_size, __ATOMIC_RELAXED); else __atomic_add_fetch(&ar->stats->malloc.used_bytes, ar->config.element_size, __ATOMIC_RELAXED); return (void *)found_fr; } static inline ARAL_PAGE *aral_ptr_to_page___must_NOT_have_aral_lock(ARAL *ar, void *ptr) { // given a data pointer we returned before, // find the ARAL_PAGE it belongs to uint8_t *data = (uint8_t *)ptr; ARAL_PAGE **page_ptr = (ARAL_PAGE **)&data[ar->config.page_ptr_offset]; ARAL_PAGE *page = *page_ptr; #ifdef NETDATA_INTERNAL_CHECKS // make it NULL so that we will fail on double free // do not enable this on production, because the MMAP file // will need to be saved again! *page_ptr = NULL; #endif #ifdef NETDATA_ARAL_INTERNAL_CHECKS { // find the page ptr belongs ARAL_PAGE *page2 = find_page_with_allocation_internal_check(ar, ptr); internal_fatal(page != page2, "ARAL: '%s' page pointers do not match!", ar->name); internal_fatal(!page2, "ARAL: '%s' free of pointer %p is not in ARAL address space.", ar->name, ptr); } #endif internal_fatal(!page, "ARAL: '%s' possible corruption or double free of pointer %p", ar->config.name, ptr); return page; } static void aral_defrag_sorted_page_position___aral_lock_needed(ARAL *ar, ARAL_PAGE *page) { ARAL_PAGE *tmp; int action = 0; (void)action; size_t move_later = 0, move_earlier = 0; for(tmp = page->aral_lock.next ; tmp && tmp->aral_lock.free_elements && tmp->aral_lock.free_elements < page->aral_lock.free_elements ; tmp = tmp->aral_lock.next) move_later++; if(!tmp && page->aral_lock.next) { DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); DOUBLE_LINKED_LIST_APPEND_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); action = 1; } else if(tmp != page->aral_lock.next) { DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); DOUBLE_LINKED_LIST_INSERT_ITEM_BEFORE_UNSAFE(ar->aral_lock.pages, tmp, page, aral_lock.prev, aral_lock.next); action = 2; } else { for(tmp = (page == ar->aral_lock.pages) ? NULL : page->aral_lock.prev ; tmp && (!tmp->aral_lock.free_elements || tmp->aral_lock.free_elements > page->aral_lock.free_elements); tmp = (tmp == ar->aral_lock.pages) ? NULL : tmp->aral_lock.prev) move_earlier++; if(!tmp) { DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); DOUBLE_LINKED_LIST_PREPEND_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); action = 3; } else if(tmp != page->aral_lock.prev){ DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); DOUBLE_LINKED_LIST_INSERT_ITEM_AFTER_UNSAFE(ar->aral_lock.pages, tmp, page, aral_lock.prev, aral_lock.next); action = 4; } } ar->aral_lock.defragment_operations++; ar->aral_lock.defragment_linked_list_traversals += move_earlier + move_later; internal_fatal(page->aral_lock.next && page->aral_lock.next->aral_lock.free_elements && page->aral_lock.next->aral_lock.free_elements < page->aral_lock.free_elements, "ARAL: '%s' item should be later in the list", ar->config.name); internal_fatal(page != ar->aral_lock.pages && (!page->aral_lock.prev->aral_lock.free_elements || page->aral_lock.prev->aral_lock.free_elements > page->aral_lock.free_elements), "ARAL: '%s' item should be earlier in the list", ar->config.name); } static inline void aral_move_page_with_free_list___aral_lock_needed(ARAL *ar, ARAL_PAGE *page) { if(unlikely(page == ar->aral_lock.pages)) // we are the first already return; if(likely(!(ar->config.options & ARAL_DEFRAGMENT))) { DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); aral_insert_not_linked_page_with_free_items_to_proper_position___aral_lock_needed(ar, page); } else aral_defrag_sorted_page_position___aral_lock_needed(ar, page); } void aral_freez_internal(ARAL *ar, void *ptr TRACE_ALLOCATIONS_FUNCTION_DEFINITION_PARAMS) { #ifdef FSANITIZE_ADDRESS freez(ptr); return; #endif if(unlikely(!ptr)) return; // get the page pointer ARAL_PAGE *page = aral_ptr_to_page___must_NOT_have_aral_lock(ar, ptr); if(unlikely(ar->config.mmap.enabled)) __atomic_sub_fetch(&ar->stats->mmap.used_bytes, ar->config.element_size, __ATOMIC_RELAXED); else __atomic_sub_fetch(&ar->stats->malloc.used_bytes, ar->config.element_size, __ATOMIC_RELAXED); // make this element available ARAL_FREE *fr = (ARAL_FREE *)ptr; fr->size = ar->config.element_size; aral_page_free_lock(ar, page); fr->next = page->free.list; page->free.list = fr; aral_page_free_unlock(ar, page); aral_lock(ar); internal_fatal(!page->aral_lock.used_elements, "ARAL: '%s' pointer %p is inside a page without any active allocations.", ar->config.name, ptr); internal_fatal(page->max_elements != page->aral_lock.used_elements + page->aral_lock.free_elements, "ARAL: '%s' page element counters do not match, " "page says it can handle %zu elements, " "but there are %zu used and %zu free items, " "total %zu items", ar->config.name, (size_t)page->max_elements, (size_t)page->aral_lock.used_elements, (size_t)page->aral_lock.free_elements, (size_t)page->aral_lock.used_elements + (size_t)page->aral_lock.free_elements ); page->aral_lock.used_elements--; page->aral_lock.free_elements++; ar->aral_lock.user_free_operations++; // if the page is empty, release it if(unlikely(!page->aral_lock.used_elements)) { bool is_this_page_the_last_one = ar->aral_lock.pages == page && !page->aral_lock.next; if(!is_this_page_the_last_one) DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); aral_unlock(ar); if(!is_this_page_the_last_one) aral_del_page___no_lock_needed(ar, page TRACE_ALLOCATIONS_FUNCTION_CALL_PARAMS); } else { aral_move_page_with_free_list___aral_lock_needed(ar, page); aral_unlock(ar); } } void aral_destroy_internal(ARAL *ar TRACE_ALLOCATIONS_FUNCTION_DEFINITION_PARAMS) { aral_lock(ar); ARAL_PAGE *page; while((page = ar->aral_lock.pages)) { DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(ar->aral_lock.pages, page, aral_lock.prev, aral_lock.next); aral_del_page___no_lock_needed(ar, page TRACE_ALLOCATIONS_FUNCTION_CALL_PARAMS); } aral_unlock(ar); if(ar->config.options & ARAL_ALLOCATED_STATS) freez(ar->stats); freez(ar); } size_t aral_element_size(ARAL *ar) { return ar->config.requested_element_size; } ARAL *aral_create(const char *name, size_t element_size, size_t initial_page_elements, size_t max_page_size, struct aral_statistics *stats, const char *filename, char **cache_dir, bool mmap, bool lockless) { ARAL *ar = callocz(1, sizeof(ARAL)); ar->config.options = (lockless) ? ARAL_LOCKLESS : 0; ar->config.requested_element_size = element_size; ar->config.initial_page_elements = initial_page_elements; ar->config.requested_max_page_size = max_page_size; ar->config.mmap.filename = filename; ar->config.mmap.cache_dir = cache_dir; ar->config.mmap.enabled = mmap; strncpyz(ar->config.name, name, ARAL_MAX_NAME); netdata_spinlock_init(&ar->aral_lock.spinlock); if(stats) { ar->stats = stats; ar->config.options &= ~ARAL_ALLOCATED_STATS; } else { ar->stats = callocz(1, sizeof(struct aral_statistics)); ar->config.options |= ARAL_ALLOCATED_STATS; } long int page_size = sysconf(_SC_PAGE_SIZE); if (unlikely(page_size == -1)) ar->config.natural_page_size = 4096; else ar->config.natural_page_size = page_size; // we need to add a page pointer after the element // so, first align the element size to the pointer size ar->config.element_size = natural_alignment(ar->config.requested_element_size, sizeof(uintptr_t)); // then add the size of a pointer to it ar->config.element_size += sizeof(uintptr_t); // make sure it is at least what we need for an ARAL_FREE slot if (ar->config.element_size < sizeof(ARAL_FREE)) ar->config.element_size = sizeof(ARAL_FREE); // and finally align it to the natural alignment ar->config.element_size = natural_alignment(ar->config.element_size, ARAL_NATURAL_ALIGNMENT); ar->config.max_page_elements = ar->config.requested_max_page_size / ar->config.element_size; // we write the page pointer just after each element ar->config.page_ptr_offset = ar->config.element_size - sizeof(uintptr_t); if(ar->config.requested_element_size + sizeof(uintptr_t) > ar->config.element_size) fatal("ARAL: '%s' failed to calculate properly page_ptr_offset: " "element size %zu, sizeof(uintptr_t) %zu, natural alignment %zu, " "final element size %zu, page_ptr_offset %zu", ar->config.name, ar->config.requested_element_size, sizeof(uintptr_t), ARAL_NATURAL_ALIGNMENT, ar->config.element_size, ar->config.page_ptr_offset); //info("ARAL: element size %zu, sizeof(uintptr_t) %zu, natural alignment %zu, final element size %zu, page_ptr_offset %zu", // ar->element_size, sizeof(uintptr_t), ARAL_NATURAL_ALIGNMENT, ar->internal.element_size, ar->internal.page_ptr_offset); if (ar->config.initial_page_elements < 2) ar->config.initial_page_elements = 2; if(ar->config.mmap.enabled && (!ar->config.mmap.cache_dir || !*ar->config.mmap.cache_dir)) { error("ARAL: '%s' mmap cache directory is not configured properly, disabling mmap.", ar->config.name); ar->config.mmap.enabled = false; internal_fatal(true, "ARAL: '%s' mmap cache directory is not configured properly", ar->config.name); } uint64_t max_alloc_size; if(!ar->config.max_page_elements) max_alloc_size = ar->config.mmap.enabled ? ARAL_MAX_PAGE_SIZE_MMAP : ARAL_MAX_PAGE_SIZE_MALLOC; else max_alloc_size = ar->config.max_page_elements * ar->config.element_size; ar->config.max_allocation_size = aral_align_alloc_size(ar, max_alloc_size); ar->adders.allocation_size = aral_align_alloc_size(ar, (uint64_t)ar->config.element_size * ar->config.initial_page_elements); ar->aral_lock.pages = NULL; ar->aral_lock.file_number = 0; if(ar->config.mmap.enabled) { char directory_name[FILENAME_MAX + 1]; snprintfz(directory_name, FILENAME_MAX, "%s/array_alloc.mmap", *ar->config.mmap.cache_dir); int r = mkdir(directory_name, 0775); if (r != 0 && errno != EEXIST) fatal("Cannot create directory '%s'", directory_name); char file[FILENAME_MAX + 1]; snprintfz(file, FILENAME_MAX, "%s.", ar->config.mmap.filename); aral_delete_leftover_files(ar->config.name, directory_name, file); } internal_error(true, "ARAL: '%s' " "element size %zu (requested %zu bytes), " "min elements per page %zu (requested %zu), " "max elements per page %zu, " "max page size %zu bytes (requested %zu) " , ar->config.name , ar->config.element_size, ar->config.requested_element_size , ar->adders.allocation_size / ar->config.element_size, ar->config.initial_page_elements , ar->config.max_allocation_size / ar->config.element_size , ar->config.max_allocation_size, ar->config.requested_max_page_size ); __atomic_add_fetch(&ar->stats->structures.allocations, 1, __ATOMIC_RELAXED); __atomic_add_fetch(&ar->stats->structures.allocated_bytes, sizeof(ARAL), __ATOMIC_RELAXED); return ar; } // ---------------------------------------------------------------------------- // global aral caching #define ARAL_BY_SIZE_MAX_SIZE 1024 struct aral_by_size { ARAL *ar; int32_t refcount; }; struct { struct aral_statistics shared_statistics; SPINLOCK spinlock; struct aral_by_size array[ARAL_BY_SIZE_MAX_SIZE + 1]; } aral_by_size_globals = {}; struct aral_statistics *aral_by_size_statistics(void) { return &aral_by_size_globals.shared_statistics; } size_t aral_by_size_structures(void) { return aral_structures_from_stats(&aral_by_size_globals.shared_statistics); } size_t aral_by_size_overhead(void) { return aral_overhead_from_stats(&aral_by_size_globals.shared_statistics); } ARAL *aral_by_size_acquire(size_t size) { netdata_spinlock_lock(&aral_by_size_globals.spinlock); ARAL *ar = NULL; if(size <= ARAL_BY_SIZE_MAX_SIZE && aral_by_size_globals.array[size].ar) { ar = aral_by_size_globals.array[size].ar; aral_by_size_globals.array[size].refcount++; internal_fatal(aral_element_size(ar) != size, "DICTIONARY: aral has size %zu but we want %zu", aral_element_size(ar), size); } if(!ar) { char buf[30 + 1]; snprintf(buf, 30, "size-%zu", size); ar = aral_create(buf, size, 0, 65536 * ((size / 150) + 1), &aral_by_size_globals.shared_statistics, NULL, NULL, false, false); if(size <= ARAL_BY_SIZE_MAX_SIZE) { aral_by_size_globals.array[size].ar = ar; aral_by_size_globals.array[size].refcount = 1; } } netdata_spinlock_unlock(&aral_by_size_globals.spinlock); return ar; } void aral_by_size_release(ARAL *ar) { size_t size = aral_element_size(ar); if(size <= ARAL_BY_SIZE_MAX_SIZE) { netdata_spinlock_lock(&aral_by_size_globals.spinlock); internal_fatal(aral_by_size_globals.array[size].ar != ar, "ARAL BY SIZE: aral pointers do not match"); if(aral_by_size_globals.array[size].refcount <= 0) fatal("ARAL BY SIZE: double release detected"); aral_by_size_globals.array[size].refcount--; // if(!aral_by_size_globals.array[size].refcount) { // aral_destroy(aral_by_size_globals.array[size].ar); // aral_by_size_globals.array[size].ar = NULL; // } netdata_spinlock_unlock(&aral_by_size_globals.spinlock); } else aral_destroy(ar); } // ---------------------------------------------------------------------------- // unittest struct aral_unittest_config { bool single_threaded; bool stop; ARAL *ar; size_t elements; size_t threads; int errors; }; static void *aral_test_thread(void *ptr) { struct aral_unittest_config *auc = ptr; ARAL *ar = auc->ar; size_t elements = auc->elements; void **pointers = callocz(elements, sizeof(void *)); do { for (size_t i = 0; i < elements; i++) { pointers[i] = aral_mallocz(ar); } for (size_t div = 5; div >= 2; div--) { for (size_t i = 0; i < elements / div; i++) { aral_freez(ar, pointers[i]); pointers[i] = NULL; } for (size_t i = 0; i < elements / div; i++) { pointers[i] = aral_mallocz(ar); } } for (size_t step = 50; step >= 10; step -= 10) { for (size_t i = 0; i < elements; i += step) { aral_freez(ar, pointers[i]); pointers[i] = NULL; } for (size_t i = 0; i < elements; i += step) { pointers[i] = aral_mallocz(ar); } } for (size_t i = 0; i < elements; i++) { aral_freez(ar, pointers[i]); pointers[i] = NULL; } if (auc->single_threaded && ar->aral_lock.pages && ar->aral_lock.pages->aral_lock.used_elements) { fprintf(stderr, "\n\nARAL leftovers detected (1)\n\n"); __atomic_add_fetch(&auc->errors, 1, __ATOMIC_RELAXED); } if(!auc->single_threaded && __atomic_load_n(&auc->stop, __ATOMIC_RELAXED)) break; for (size_t i = 0; i < elements; i++) { pointers[i] = aral_mallocz(ar); } size_t increment = elements / ar->config.max_page_elements; for (size_t all = increment; all <= elements / 2; all += increment) { size_t to_free = (all % ar->config.max_page_elements) + 1; size_t step = elements / to_free; if(!step) step = 1; // fprintf(stderr, "all %zu, to free %zu, step %zu\n", all, to_free, step); size_t free_list[to_free]; for (size_t i = 0; i < to_free; i++) { size_t pos = step * i; aral_freez(ar, pointers[pos]); pointers[pos] = NULL; free_list[i] = pos; } for (size_t i = 0; i < to_free; i++) { size_t pos = free_list[i]; pointers[pos] = aral_mallocz(ar); } } for (size_t i = 0; i < elements; i++) { aral_freez(ar, pointers[i]); pointers[i] = NULL; } if (auc->single_threaded && ar->aral_lock.pages && ar->aral_lock.pages->aral_lock.used_elements) { fprintf(stderr, "\n\nARAL leftovers detected (2)\n\n"); __atomic_add_fetch(&auc->errors, 1, __ATOMIC_RELAXED); } } while(!auc->single_threaded && !__atomic_load_n(&auc->stop, __ATOMIC_RELAXED)); freez(pointers); return ptr; } int aral_stress_test(size_t threads, size_t elements, size_t seconds) { fprintf(stderr, "Running stress test of %zu threads, with %zu elements each, for %zu seconds...\n", threads, elements, seconds); struct aral_unittest_config auc = { .single_threaded = false, .threads = threads, .ar = aral_create("aral-stress-test", 20, 0, 8192, NULL, "aral-stress-test", NULL, false, false), .elements = elements, .errors = 0, }; usec_t started_ut = now_monotonic_usec(); netdata_thread_t thread_ptrs[threads]; for(size_t i = 0; i < threads ; i++) { char tag[NETDATA_THREAD_NAME_MAX + 1]; snprintfz(tag, NETDATA_THREAD_NAME_MAX, "TH[%zu]", i); netdata_thread_create(&thread_ptrs[i], tag, NETDATA_THREAD_OPTION_JOINABLE | NETDATA_THREAD_OPTION_DONT_LOG, aral_test_thread, &auc); } size_t malloc_done = 0; size_t free_done = 0; size_t countdown = seconds; while(countdown-- > 0) { sleep_usec(1 * USEC_PER_SEC); aral_lock(auc.ar); size_t m = auc.ar->aral_lock.user_malloc_operations; size_t f = auc.ar->aral_lock.user_free_operations; aral_unlock(auc.ar); fprintf(stderr, "ARAL executes %0.2f M malloc and %0.2f M free operations/s\n", (double)(m - malloc_done) / 1000000.0, (double)(f - free_done) / 1000000.0); malloc_done = m; free_done = f; } __atomic_store_n(&auc.stop, true, __ATOMIC_RELAXED); // fprintf(stderr, "Cancelling the threads...\n"); // for(size_t i = 0; i < threads ; i++) { // netdata_thread_cancel(thread_ptrs[i]); // } fprintf(stderr, "Waiting the threads to finish...\n"); for(size_t i = 0; i < threads ; i++) { netdata_thread_join(thread_ptrs[i], NULL); } usec_t ended_ut = now_monotonic_usec(); if (auc.ar->aral_lock.pages && auc.ar->aral_lock.pages->aral_lock.used_elements) { fprintf(stderr, "\n\nARAL leftovers detected (3)\n\n"); __atomic_add_fetch(&auc.errors, 1, __ATOMIC_RELAXED); } info("ARAL: did %zu malloc, %zu free, " "using %zu threads, in %llu usecs", auc.ar->aral_lock.user_malloc_operations, auc.ar->aral_lock.user_free_operations, threads, ended_ut - started_ut); aral_destroy(auc.ar); return auc.errors; } int aral_unittest(size_t elements) { char *cache_dir = "/tmp/"; struct aral_unittest_config auc = { .single_threaded = true, .threads = 1, .ar = aral_create("aral-test", 20, 0, 8192, NULL, "aral-test", &cache_dir, false, false), .elements = elements, .errors = 0, }; aral_test_thread(&auc); aral_destroy(auc.ar); int errors = aral_stress_test(2, elements, 5); return auc.errors + errors; }