#include #include #define DEFAULT_HT_INIT_SIZE 16 #define SLOT_OF_HASH(k, nslots) (((size_t)(k)*21179)%(size_t)(nslots)) typedef struct hashtbl_item { void* key; void* val; struct hashtbl_item *next; } hashtbl_item_t; // When nitems > size * 3/4, size is multiplied by two // When nitems < size * 1/4, size is divided by two struct hashtbl { key_eq_fun_t ef; hash_fun_t hf; kv_iter_fun_t releasef; size_t size, nitems; hashtbl_item_t **items; }; hashtbl_t *create_hashtbl(key_eq_fun_t ef, hash_fun_t hf, kv_iter_fun_t on_release) { hashtbl_t *ht = (hashtbl_t*)malloc(sizeof(hashtbl_t)); if (ht == 0) return 0; ht->ef = ef; ht->hf = hf; ht->releasef = on_release; ht->size = DEFAULT_HT_INIT_SIZE; ht->nitems = 0; ht->items = (hashtbl_item_t**)malloc(ht->size * sizeof(hashtbl_item_t*)); if (ht->items == 0) { free(ht); return 0; } for (size_t i = 0; i < ht->size; i++) ht->items[i] = 0; return ht; } void delete_hashtbl(hashtbl_t *ht) { // Free items for (size_t i = 0; i < ht->size; i++) { while (ht->items[i] != 0) { hashtbl_item_t *x = ht->items[i]; ht->items[i] = x->next; if (ht->releasef) ht->releasef(x->key, x->val); free(x); } } // Free table free(ht->items); free(ht); } static void hashtbl_check_size(hashtbl_t *ht) { size_t nsize = 0; if (4 * ht->nitems < ht->size) nsize = ht->size / 2; if (4 * ht->nitems > 3 * ht->size) nsize = ht->size * 2; if (nsize != 0) { hashtbl_item_t **nitems = (hashtbl_item_t**)malloc(nsize * sizeof(hashtbl_item_t*)); if (nitems == 0) return; // if we can't realloc, too bad, we just lose space for (size_t i = 0; i < nsize; i++) nitems[i] = 0; // rehash for (size_t i = 0; i < ht->size; i++) { while (ht->items[i] != 0) { hashtbl_item_t *x = ht->items[i]; ht->items[i] = x->next; size_t slot = SLOT_OF_HASH(ht->hf(x->key), nsize); x->next = nitems[slot]; nitems[slot] = x; } } free(ht->items); ht->size = nsize; ht->items = nitems; } } bool hashtbl_add(hashtbl_t *ht, void* key, void* v) { size_t slot = SLOT_OF_HASH(ht->hf(key), ht->size); hashtbl_item_t *i = (hashtbl_item_t*)malloc(sizeof(hashtbl_item_t)); if (i == 0) return false; // OOM // make sure item is not already present hashtbl_remove(ht, key); i->key = key; i->val = v; i->next = ht->items[slot]; ht->items[slot] = i; ht->nitems++; hashtbl_check_size(ht); return true; } void hashtbl_remove(hashtbl_t* ht, const void* key) { size_t slot = SLOT_OF_HASH(ht->hf(key), ht->size); if (ht->items[slot] == 0) return; hashtbl_item_t *x = 0; if (ht->ef(ht->items[slot]->key, key)) { x = ht->items[slot]; ht->items[slot] = x->next; } else { for (hashtbl_item_t *i = ht->items[slot]; i->next != 0; i = i->next) { if (ht->ef(i->next->key, key)) { x = i->next; i->next = x->next; break; } } } if (x != 0) { ht->nitems--; if (ht->releasef) ht->releasef(x->key, x->val); free(x); } hashtbl_check_size(ht); } void* hashtbl_find(hashtbl_t* ht, const void* key) { size_t slot = SLOT_OF_HASH(ht->hf(key), ht->size); for (hashtbl_item_t *i = ht->items[slot]; i != 0; i = i->next) { if (ht->ef(i->key, key)) return i->val; } return 0; } void hashtbl_iter(hashtbl_t *ht, kv_iter_fun_t f) { for (size_t s = 0; s < ht->size; s++) { for (hashtbl_item_t *i = ht->items[s]; i != 0; i = i->next) { f(i->key, i->val); } } } size_t hashtbl_count(hashtbl_t* ht) { return ht->nitems; } bool hashtbl_change(hashtbl_t* ht, void* key, void* newval) { size_t slot = SLOT_OF_HASH(ht->hf(key), ht->size); for (hashtbl_item_t *i = ht->items[slot]; i != 0; i = i->next) { if (ht->ef(i->key, key)) { i->val = newval; return true; } } return false; } /* vim: set ts=4 sw=4 tw=0 noet :*/