/*-*- Mode: C; c-basic-offset: 8; indent-tabs-mode: nil -*-*/ /*** This file is part of systemd. Copyright 2010 Lennart Poettering systemd is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. systemd is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with systemd; If not, see . ***/ #include #include #include #include #include "util.h" #include "hashmap.h" #include "macro.h" #define NBUCKETS 127 struct hashmap_entry { const void *key; void *value; struct hashmap_entry *bucket_next, *bucket_previous; struct hashmap_entry *iterate_next, *iterate_previous; }; struct Hashmap { hash_func_t hash_func; compare_func_t compare_func; struct hashmap_entry *iterate_list_head, *iterate_list_tail; unsigned n_entries; bool from_pool; }; #define BY_HASH(h) ((struct hashmap_entry**) ((uint8_t*) (h) + ALIGN(sizeof(Hashmap)))) struct pool { struct pool *next; unsigned n_tiles; unsigned n_used; }; static struct pool *first_hashmap_pool = NULL; static void *first_hashmap_tile = NULL; static struct pool *first_entry_pool = NULL; static void *first_entry_tile = NULL; static void* allocate_tile(struct pool **first_pool, void **first_tile, size_t tile_size) { unsigned i; if (*first_tile) { void *r; r = *first_tile; *first_tile = * (void**) (*first_tile); return r; } if (_unlikely_(!*first_pool) || _unlikely_((*first_pool)->n_used >= (*first_pool)->n_tiles)) { unsigned n; size_t size; struct pool *p; n = *first_pool ? (*first_pool)->n_tiles : 0; n = MAX(512U, n * 2); size = PAGE_ALIGN(ALIGN(sizeof(struct pool)) + n*tile_size); n = (size - ALIGN(sizeof(struct pool))) / tile_size; p = malloc(size); if (!p) return NULL; p->next = *first_pool; p->n_tiles = n; p->n_used = 0; *first_pool = p; } i = (*first_pool)->n_used++; return ((uint8_t*) (*first_pool)) + ALIGN(sizeof(struct pool)) + i*tile_size; } static void deallocate_tile(void **first_tile, void *p) { * (void**) p = *first_tile; *first_tile = p; } #ifdef VALGRIND static void drop_pool(struct pool *p) { while (p) { struct pool *n; n = p->next; free(p); p = n; } } #endif unsigned string_hash_func(const void *p) { unsigned hash = 5381; const signed char *c; /* DJB's hash function */ for (c = p; *c; c++) hash = (hash << 5) + hash + (unsigned) *c; return hash; } int string_compare_func(const void *a, const void *b) { return strcmp(a, b); } unsigned trivial_hash_func(const void *p) { return PTR_TO_UINT(p); } int trivial_compare_func(const void *a, const void *b) { return a < b ? -1 : (a > b ? 1 : 0); } Hashmap *hashmap_new(hash_func_t hash_func, compare_func_t compare_func) { bool b; Hashmap *h; size_t size; b = is_main_thread(); size = ALIGN(sizeof(Hashmap)) + NBUCKETS * sizeof(struct hashmap_entry*); if (b) { h = allocate_tile(&first_hashmap_pool, &first_hashmap_tile, size); if (!h) return NULL; memset(h, 0, size); } else { h = malloc0(size); if (!h) return NULL; } h->hash_func = hash_func ? hash_func : trivial_hash_func; h->compare_func = compare_func ? compare_func : trivial_compare_func; h->n_entries = 0; h->iterate_list_head = h->iterate_list_tail = NULL; h->from_pool = b; return h; } static void link_entry(Hashmap *h, struct hashmap_entry *e, unsigned hash) { assert(h); assert(e); /* Insert into hash table */ e->bucket_next = BY_HASH(h)[hash]; e->bucket_previous = NULL; if (BY_HASH(h)[hash]) BY_HASH(h)[hash]->bucket_previous = e; BY_HASH(h)[hash] = e; /* Insert into iteration list */ e->iterate_previous = h->iterate_list_tail; e->iterate_next = NULL; if (h->iterate_list_tail) { assert(h->iterate_list_head); h->iterate_list_tail->iterate_next = e; } else { assert(!h->iterate_list_head); h->iterate_list_head = e; } h->iterate_list_tail = e; h->n_entries++; assert(h->n_entries >= 1); } static void unlink_entry(Hashmap *h, struct hashmap_entry *e, unsigned hash) { assert(h); assert(e); /* Remove from iteration list */ if (e->iterate_next) e->iterate_next->iterate_previous = e->iterate_previous; else h->iterate_list_tail = e->iterate_previous; if (e->iterate_previous) e->iterate_previous->iterate_next = e->iterate_next; else h->iterate_list_head = e->iterate_next; /* Remove from hash table bucket list */ if (e->bucket_next) e->bucket_next->bucket_previous = e->bucket_previous; if (e->bucket_previous) e->bucket_previous->bucket_next = e->bucket_next; else BY_HASH(h)[hash] = e->bucket_next; assert(h->n_entries >= 1); h->n_entries--; } static void remove_entry(Hashmap *h, struct hashmap_entry *e) { unsigned hash; assert(h); assert(e); hash = h->hash_func(e->key) % NBUCKETS; unlink_entry(h, e, hash); if (h->from_pool) deallocate_tile(&first_entry_tile, e); else free(e); } void hashmap_free(Hashmap*h) { /* Free the hashmap, but nothing in it */ if (!h) return; hashmap_clear(h); if (h->from_pool) deallocate_tile(&first_hashmap_tile, h); else free(h); } void hashmap_free_free(Hashmap *h) { /* Free the hashmap and all data objects in it, but not the * keys */ if (!h) return; hashmap_clear_free(h); hashmap_free(h); } void hashmap_clear(Hashmap *h) { if (!h) return; while (h->iterate_list_head) remove_entry(h, h->iterate_list_head); } void hashmap_clear_free(Hashmap *h) { void *p; if (!h) return; while ((p = hashmap_steal_first(h))) free(p); } static struct hashmap_entry *hash_scan(Hashmap *h, unsigned hash, const void *key) { struct hashmap_entry *e; assert(h); assert(hash < NBUCKETS); for (e = BY_HASH(h)[hash]; e; e = e->bucket_next) if (h->compare_func(e->key, key) == 0) return e; return NULL; } int hashmap_put(Hashmap *h, const void *key, void *value) { struct hashmap_entry *e; unsigned hash; assert(h); hash = h->hash_func(key) % NBUCKETS; e = hash_scan(h, hash, key); if (e) { if (e->value == value) return 0; return -EEXIST; } if (h->from_pool) e = allocate_tile(&first_entry_pool, &first_entry_tile, sizeof(struct hashmap_entry)); else e = new(struct hashmap_entry, 1); if (!e) return -ENOMEM; e->key = key; e->value = value; link_entry(h, e, hash); return 1; } void* hashmap_get(Hashmap *h, const void *key) { unsigned hash; struct hashmap_entry *e; if (!h) return NULL; hash = h->hash_func(key) % NBUCKETS; e = hash_scan(h, hash, key); if (!e) return NULL; return e->value; } bool hashmap_contains(Hashmap *h, const void *key) { unsigned hash; if (!h) return false; hash = h->hash_func(key) % NBUCKETS; if (!hash_scan(h, hash, key)) return false; return true; } void* hashmap_remove(Hashmap *h, const void *key) { struct hashmap_entry *e; unsigned hash; void *data; if (!h) return NULL; hash = h->hash_func(key) % NBUCKETS; if (!(e = hash_scan(h, hash, key))) return NULL; data = e->value; remove_entry(h, e); return data; } void *hashmap_iterate(Hashmap *h, Iterator *i, const void **key) { struct hashmap_entry *e; assert(i); if (!h) goto at_end; if (*i == ITERATOR_LAST) goto at_end; if (*i == ITERATOR_FIRST && !h->iterate_list_head) goto at_end; e = *i == ITERATOR_FIRST ? h->iterate_list_head : (struct hashmap_entry*) *i; if (e->iterate_next) *i = (Iterator) e->iterate_next; else *i = ITERATOR_LAST; if (key) *key = e->key; return e->value; at_end: *i = ITERATOR_LAST; if (key) *key = NULL; return NULL; } void *hashmap_iterate_backwards(Hashmap *h, Iterator *i, const void **key) { struct hashmap_entry *e; assert(i); if (!h) goto at_beginning; if (*i == ITERATOR_FIRST) goto at_beginning; if (*i == ITERATOR_LAST && !h->iterate_list_tail) goto at_beginning; e = *i == ITERATOR_LAST ? h->iterate_list_tail : (struct hashmap_entry*) *i; if (e->iterate_previous) *i = (Iterator) e->iterate_previous; else *i = ITERATOR_FIRST; if (key) *key = e->key; return e->value; at_beginning: *i = ITERATOR_FIRST; if (key) *key = NULL; return NULL; } void* hashmap_steal_first(Hashmap *h) { void *data; if (!h) return NULL; if (!h->iterate_list_head) return NULL; data = h->iterate_list_head->value; remove_entry(h, h->iterate_list_head); return data; } unsigned hashmap_size(Hashmap *h) { if (!h) return 0; return h->n_entries; } int hashmap_merge(Hashmap *h, Hashmap *other) { struct hashmap_entry *e; assert(h); if (!other) return 0; for (e = other->iterate_list_head; e; e = e->iterate_next) { int r; if ((r = hashmap_put(h, e->key, e->value)) < 0) if (r != -EEXIST) return r; } return 0; } void hashmap_move(Hashmap *h, Hashmap *other) { struct hashmap_entry *e, *n; assert(h); /* The same as hashmap_merge(), but every new item from other * is moved to h. This function is guaranteed to succeed. */ if (!other) return; for (e = other->iterate_list_head; e; e = n) { unsigned h_hash, other_hash; n = e->iterate_next; h_hash = h->hash_func(e->key) % NBUCKETS; if (hash_scan(h, h_hash, e->key)) continue; other_hash = other->hash_func(e->key) % NBUCKETS; unlink_entry(other, e, other_hash); link_entry(h, e, h_hash); } } char **hashmap_get_strv(Hashmap *h) { char **sv; Iterator it; char *item; int n; sv = new(char*, h->n_entries+1); if (!sv) return NULL; n = 0; HASHMAP_FOREACH(item, h, it) sv[n++] = item; sv[n] = NULL; return sv; }