#include "hashmap.h" #include #include #include #include #include #include #include #define HASH_OFFSET_BASIS 0xcbf29ce484222325 #define HASH_PRIME 0x100000001b3 /* clang-format off */ static B_BTREE_DEFINE_SIMPLE_GET( struct b_hashmap_bucket, uint64_t, bk_node, bk_hash, get_bucket) static B_BTREE_DEFINE_SIMPLE_INSERT( struct b_hashmap_bucket, bk_node, bk_hash, put_bucket) static uint64_t hash_data(const void *p, size_t size) { /* clang-format on */ const unsigned char *s = p; uint64_t hash = HASH_OFFSET_BASIS; for (size_t i = 0; s[i]; i++) { hash *= HASH_PRIME; hash ^= s[i]; } return hash; } static uint64_t hash_key(const struct b_hashmap_key *key) { if (key->key_flags & B_HASHMAP_KEY_F_INTVALUE) { return hash_data(&key->key_data, sizeof key->key_data); } else { return hash_data(key->key_data, key->key_size); } } static bool compare_key( const struct b_hashmap_key *a, const struct b_hashmap_key *b) { const void *a_data = NULL, *b_data = NULL; size_t a_len = 0, b_len = 0; if (a->key_flags & B_HASHMAP_KEY_F_INTVALUE) { a_data = &a->key_data; a_len = sizeof a->key_data; } else { a_data = a->key_data; a_len = a->key_size; } if (b->key_flags & B_HASHMAP_KEY_F_INTVALUE) { b_data = &b->key_data; b_len = sizeof b->key_data; } else { b_data = b->key_data; b_len = b->key_size; } if (a_len != b_len) { return false; } size_t cmp_len = a_len; return memcmp(a_data, b_data, cmp_len) == 0; } static void hashmap_release(struct b_object *obj); static struct b_object_type hashmap_type = { .t_name = "corelib::hashmap", .t_flags = B_OBJECT_FUNDAMENTAL, .t_id = B_OBJECT_TYPE_HASHMAP, .t_instance_size = sizeof(struct b_hashmap), .t_release = hashmap_release, }; struct b_hashmap *b_hashmap_create( b_hashmap_key_destructor key_dtor, b_hashmap_value_destructor value_dtor) { struct b_hashmap *hashmap = (struct b_hashmap *)b_object_type_instantiate(&hashmap_type); if (!hashmap) { return NULL; } return hashmap; } struct b_hashmap *b_hashmap_create_with_items(const b_hashmap_item *items) { struct b_hashmap *hashmap = b_hashmap_create(NULL, NULL); if (!hashmap) { return NULL; } for (size_t i = 0; items[i].key.key_data && items[i].key.key_size; i++) { b_hashmap_put(hashmap, &items[i].key, &items[i].value); } return hashmap; } static struct b_hashmap_bucket *create_bucket(void) { /* clang-format on */ struct b_hashmap_bucket *bucket = malloc(sizeof *bucket); if (!bucket) { return NULL; } memset(bucket, 0x0, sizeof *bucket); return bucket; } static struct b_hashmap_bucket_item *create_bucket_item(void) { struct b_hashmap_bucket_item *item = malloc(sizeof *item); if (!item) { return NULL; } memset(item, 0x0, sizeof *item); return item; } b_status b_hashmap_put( struct b_hashmap *hashmap, const b_hashmap_key *key, const b_hashmap_value *value) { uint64_t hash = hash_key(key); struct b_hashmap_bucket *bucket = get_bucket(&hashmap->h_buckets, hash); if (!bucket) { bucket = create_bucket(); if (!bucket) { return B_ERR_NO_MEMORY; } bucket->bk_hash = hash; put_bucket(&hashmap->h_buckets, bucket); } b_queue_iterator it; b_queue_foreach (&it, &bucket->bk_items) { struct b_hashmap_bucket_item *item = b_unbox( struct b_hashmap_bucket_item, it.entry, bi_entry); if (compare_key(&item->bi_key, key)) { memcpy(&item->bi_value, value, sizeof *value); return B_SUCCESS; } } struct b_hashmap_bucket_item *item = create_bucket_item(); if (!item) { return B_ERR_NO_MEMORY; } memcpy(&item->bi_key, key, sizeof *key); memcpy(&item->bi_value, value, sizeof *value); b_queue_push_back(&bucket->bk_items, &item->bi_entry); return B_SUCCESS; } const struct b_hashmap_value *b_hashmap_get( const struct b_hashmap *hashmap, const struct b_hashmap_key *key) { uint64_t hash = hash_key(key); struct b_hashmap_bucket *bucket = get_bucket(&hashmap->h_buckets, hash); if (!bucket) { return NULL; } b_queue_iterator it; b_queue_foreach (&it, &bucket->bk_items) { struct b_hashmap_bucket_item *item = b_unbox( struct b_hashmap_bucket_item, it.entry, bi_entry); if (compare_key(&item->bi_key, key)) { return &item->bi_value; } } return NULL; } bool b_hashmap_has_key(const struct b_hashmap *hashmap, const b_hashmap_key *key) { uint64_t hash = hash_key(key); struct b_hashmap_bucket *bucket = get_bucket(&hashmap->h_buckets, hash); if (!bucket) { return false; } b_queue_iterator it; b_queue_foreach (&it, &bucket->bk_items) { struct b_hashmap_bucket_item *item = b_unbox( struct b_hashmap_bucket_item, it.entry, bi_entry); if (compare_key(&item->bi_key, key)) { return true; } } return false; } size_t b_hashmap_get_size(const struct b_hashmap *hashmap) { size_t count = 0; b_btree_iterator it1; b_queue_iterator it2; b_btree_foreach (&it1, &hashmap->h_buckets) { struct b_hashmap_bucket *bucket = b_unbox(struct b_hashmap_bucket, it1.node, bk_node); b_queue_foreach (&it2, &bucket->bk_items) { count++; } } return count; } bool b_hashmap_is_empty(const b_hashmap *hashmap) { b_btree_node *first_node = b_btree_first(&hashmap->h_buckets); struct b_hashmap_bucket *first_bucket = b_unbox(struct b_hashmap_bucket, first_node, bk_node); if (!first_bucket) { return true; } b_queue_entry *first_entry = b_queue_first(&first_bucket->bk_items); struct b_hashmap_bucket_item *first_item = b_unbox(struct b_hashmap_bucket_item, first_entry, bi_entry); if (!first_item) { return true; } return false; } static b_status delete_item( struct b_hashmap *hashmap, struct b_hashmap_bucket *bucket, struct b_hashmap_bucket_item *item) { b_queue_delete(&bucket->bk_items, &item->bi_entry); if (hashmap->h_key_dtor) { hashmap->h_key_dtor((void *)item->bi_key.key_data); } if (hashmap->h_value_dtor) { hashmap->h_value_dtor((void *)item->bi_value.value_data); } free(item); if (b_queue_empty(&bucket->bk_items)) { b_btree_delete(&hashmap->h_buckets, &bucket->bk_node); free(bucket); } return B_SUCCESS; } static bool hashmap_iterator_next(struct b_iterator *it) { return b_hashmap_iterator_next((struct b_hashmap_iterator *)it); } static b_status hashmap_iterator_erase(struct b_iterator *it) { return b_hashmap_iterator_erase((struct b_hashmap_iterator *)it); } static bool hashmap_iterator_is_valid(const struct b_iterator *it) { return b_hashmap_iterator_is_valid((struct b_hashmap_iterator *)it); } static struct b_iterator_ops it_ops = { .it_next = hashmap_iterator_next, .it_erase = hashmap_iterator_erase, .it_close = NULL, .it_is_valid = hashmap_iterator_is_valid, }; int b_hashmap_iterator_begin( struct b_hashmap *hashmap, struct b_hashmap_iterator *it) { it->_h = hashmap; it->_base.it_ops = &it_ops; it->i = 0; if (b_hashmap_is_empty(hashmap)) { it->key = NULL; it->value = NULL; return -1; } struct b_btree_node *first_node = b_btree_first(&hashmap->h_buckets); struct b_hashmap_bucket *first_bucket = b_unbox(struct b_hashmap_bucket, first_node, bk_node); if (!first_bucket) { it->key = NULL; it->value = NULL; return -1; } struct b_queue_entry *first_entry = b_queue_first(&first_bucket->bk_items); struct b_hashmap_bucket_item *first_item = b_unbox(struct b_hashmap_bucket_item, first_entry, bi_entry); if (!first_item) { it->key = NULL; it->value = NULL; return -1; } it->key = &first_item->bi_key; it->value = &first_item->bi_value; it->_cbn = first_node; it->_cqe = first_entry; return 0; } static bool get_next_node( struct b_btree_node *cur_node, struct b_queue_entry *cur_entry, struct b_btree_node **out_next_node, struct b_queue_entry **out_next_entry) { struct b_hashmap_bucket *cur_bucket = b_unbox(struct b_hashmap_bucket, cur_node, bk_node); if (!cur_bucket) { return false; } struct b_hashmap_bucket_item *cur_item = b_unbox(struct b_hashmap_bucket_item, cur_entry, bi_entry); if (!cur_item) { return false; } struct b_btree_node *next_node = cur_node; struct b_queue_entry *next_entry = b_queue_next(cur_entry); if (!next_entry) { next_node = b_btree_next(cur_node); if (!next_node) { return false; } struct b_hashmap_bucket *next_bucket = b_unbox(struct b_hashmap_bucket, next_node, bk_node); if (!next_bucket) { return false; } next_entry = b_queue_first(&next_bucket->bk_items); if (!next_entry) { return false; } } struct b_hashmap_bucket_item *next_item = b_unbox(struct b_hashmap_bucket_item, next_entry, bi_entry); if (!next_item) { return false; } *out_next_node = next_node; *out_next_entry = next_entry; return true; } bool b_hashmap_iterator_next(struct b_hashmap_iterator *it) { struct b_btree_node *next_node; struct b_queue_entry *next_entry; if (!get_next_node(it->_cbn, it->_cqe, &next_node, &next_entry)) { it->key = NULL; it->value = NULL; return false; } struct b_hashmap_bucket_item *next_item = b_unbox(struct b_hashmap_bucket_item, next_entry, bi_entry); if (!next_item) { it->key = NULL; it->value = NULL; return false; } it->i++; it->key = &next_item->bi_key; it->value = &next_item->bi_value; it->_cbn = next_node; it->_cqe = next_entry; return true; } b_status b_hashmap_iterator_erase(struct b_hashmap_iterator *it) { if ((it->key || it->value) && !(it->_cbn && it->_cqe)) { return B_ERR_BAD_STATE; } if (!it->key || !it->_cqe) { return B_ERR_OUT_OF_BOUNDS; } struct b_btree_node *next_node; struct b_queue_entry *next_entry; if (!get_next_node(it->_cbn, it->_cqe, &next_node, &next_entry)) { it->key = NULL; it->value = NULL; return false; } struct b_hashmap_bucket *cur_bucket = b_unbox(struct b_hashmap_bucket, it->_cbn, bk_node); struct b_hashmap_bucket_item *cur_item = b_unbox(struct b_hashmap_bucket_item, it->_cqe, bi_entry); struct b_hashmap_bucket_item *next_item = b_unbox(struct b_hashmap_bucket_item, next_entry, bi_entry); b_status status = delete_item(it->_h, cur_bucket, cur_item); if (B_ERR(status)) { return status; } if (next_item) { it->key = &next_item->bi_key; it->value = &next_item->bi_value; it->_cbn = next_node; it->_cqe = next_entry; } else { it->key = NULL; it->value = NULL; it->_cbn = NULL; it->_cqe = NULL; } return B_SUCCESS; } bool b_hashmap_iterator_is_valid(const struct b_hashmap_iterator *it) { return it->key != NULL; } static void hashmap_release(struct b_object *obj) { struct b_hashmap *map = B_HASHMAP(obj); b_hashmap_iterator it; b_hashmap_iterator_begin(map, &it); while (b_hashmap_iterator_is_valid(&it)) { b_hashmap_iterator_erase(&it); } } b_object_type_id b_hashmap_type_id(void) { return (b_object_type_id)&hashmap_type; }