/* * Copyright (c) 2017-2020 Bailey Thompson * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ /* * The Containers library is hosted at: github.com/bkthomps/Containers * The author is: Bailey Thompson * This local version is: v1.1.2 */ #ifndef CONTAINERS_UNORDERED_MAP_H #define CONTAINERS_UNORDERED_MAP_H #include /** * The unordered_map data structure, which is a collection of key-value pairs, * hashed by keys, keys are unique */ typedef struct internal_unordered_map *unordered_map; /* Starting */ unordered_map unordered_map_init(size_t key_size, size_t value_size, unsigned long (*hash)(const void *const key), int (*comparator)(const void *const one, const void *const two)); /* Utility */ int unordered_map_rehash(unordered_map me); int unordered_map_size(unordered_map me); int unordered_map_is_empty(unordered_map me); /* Accessing */ int unordered_map_put(unordered_map me, void *key, void *value); int unordered_map_get(void *value, unordered_map me, void *key); int unordered_map_contains(unordered_map me, void *key); int unordered_map_remove(unordered_map me, void *key); /* Ending */ int unordered_map_clear(unordered_map me); unordered_map unordered_map_destroy(unordered_map me); #endif /* CONTAINERS_UNORDERED_MAP_H */ #ifndef CONTAINERS_MAP_H #define CONTAINERS_MAP_H #include /** * The map data structure, which is a collection of key-value pairs, sorted by * keys, keys are unique. */ typedef struct internal_map *map; /* Starting */ map map_init(size_t key_size, size_t value_size, int (*comparator)(const void *const one, const void *const two)); /* Capacity */ int map_size(map me); int map_is_empty(map me); /* Accessing */ int map_put(map me, void *key, void *value); int map_get(void *value, map me, void *key); int map_contains(map me, void *key); int map_remove(map me, void *key); /* Ending */ void map_clear(map me); map map_destroy(map me); #endif /* CONTAINERS_MAP_H */ #ifndef CONTAINERS_UNORDERED_MULTISET_H #define CONTAINERS_UNORDERED_MULTISET_H #include /** * The unordered_multiset data structure, which is a collection of keys, hashed * by keys. */ typedef struct internal_unordered_multiset *unordered_multiset; /* Starting */ unordered_multiset unordered_multiset_init(size_t key_size, unsigned long (*hash)(const void *const key), int (*comparator)(const void *const one, const void *const two)); /* Utility */ int unordered_multiset_rehash(unordered_multiset me); int unordered_multiset_size(unordered_multiset me); int unordered_multiset_is_empty(unordered_multiset me); /* Accessing */ int unordered_multiset_put(unordered_multiset me, void *key); int unordered_multiset_count(unordered_multiset me, void *key); int unordered_multiset_contains(unordered_multiset me, void *key); int unordered_multiset_remove(unordered_multiset me, void *key); int unordered_multiset_remove_all(unordered_multiset me, void *key); /* Ending */ int unordered_multiset_clear(unordered_multiset me); unordered_multiset unordered_multiset_destroy(unordered_multiset me); #endif /* CONTAINERS_UNORDERED_MULTISET_H */ #ifndef CONTAINERS_MULTIMAP_H #define CONTAINERS_MULTIMAP_H #include /** * The multimap data structure, which is a collection of key-value pairs, sorted * by keys. */ typedef struct internal_multimap *multimap; /* Starting */ multimap multimap_init(size_t key_size, size_t value_size, int (*key_comparator)(const void *const one, const void *const two), int (*value_comparator)(const void *const one, const void *const two)); /* Capacity */ int multimap_size(multimap me); int multimap_is_empty(multimap me); /* Accessing */ int multimap_put(multimap me, void *key, void *value); void multimap_get_start(multimap me, void *key); int multimap_get_next(void *value, multimap me); int multimap_count(multimap me, void *key); int multimap_contains(multimap me, void *key); int multimap_remove(multimap me, void *key, void *value); int multimap_remove_all(multimap me, void *key); /* Ending */ void multimap_clear(multimap me); multimap multimap_destroy(multimap me); #endif /* CONTAINERS_MULTIMAP_H */ #ifndef CONTAINERS_PRIORITY_QUEUE_H #define CONTAINERS_PRIORITY_QUEUE_H #include /** * The priority_queue data structure, which adapts a container to provide a * priority queue. Adapts the vector container. */ typedef struct internal_priority_queue *priority_queue; /* Starting */ priority_queue priority_queue_init(size_t data_size, int (*comparator)(const void *const one, const void *const two)); /* Utility */ int priority_queue_size(priority_queue me); int priority_queue_is_empty(priority_queue me); /* Adding */ int priority_queue_push(priority_queue me, void *data); /* Removing */ int priority_queue_pop(void *data, priority_queue me); /* Getting */ int priority_queue_front(void *data, priority_queue me); /* Ending */ int priority_queue_clear(priority_queue me); priority_queue priority_queue_destroy(priority_queue me); #endif /* CONTAINERS_PRIORITY_QUEUE_H */ #ifndef CONTAINERS_LIST_H #define CONTAINERS_LIST_H #include /** * The list data structure, which is a doubly-linked list. */ typedef struct internal_list *list; /* Starting */ list list_init(size_t data_size); /* Utility */ size_t list_size(list me); int list_is_empty(list me); void list_copy_to_array(void *arr, list me); /* Adding */ int list_add_first(list me, void *data); int list_add_at(list me, size_t index, void *data); int list_add_last(list me, void *data); /* Removing */ int list_remove_first(list me); int list_remove_at(list me, size_t index); int list_remove_last(list me); /* Setting */ int list_set_first(list me, void *data); int list_set_at(list me, size_t index, void *data); int list_set_last(list me, void *data); /* Getting */ int list_get_first(void *data, list me); int list_get_at(void *data, list me, size_t index); int list_get_last(void *data, list me); /* Ending */ void list_clear(list me); list list_destroy(list me); #endif /* CONTAINERS_LIST_H */ #ifndef CONTAINERS_UNORDERED_MULTIMAP_H #define CONTAINERS_UNORDERED_MULTIMAP_H #include /** * The unordered_multimap data structure, which is a collection of key-value * pairs, hashed by keys. */ typedef struct internal_unordered_multimap *unordered_multimap; /* Starting */ unordered_multimap unordered_multimap_init(size_t key_size, size_t value_size, unsigned long (*hash)(const void *const key), int (*key_comparator)(const void *const one, const void *const two), int (*value_comparator)(const void *const one, const void *const two)); /* Utility */ int unordered_multimap_rehash(unordered_multimap me); int unordered_multimap_size(unordered_multimap me); int unordered_multimap_is_empty(unordered_multimap me); /* Accessing */ int unordered_multimap_put(unordered_multimap me, void *key, void *value); void unordered_multimap_get_start(unordered_multimap me, void *key); int unordered_multimap_get_next(void *value, unordered_multimap me); int unordered_multimap_count(unordered_multimap me, void *key); int unordered_multimap_contains(unordered_multimap me, void *key); int unordered_multimap_remove(unordered_multimap me, void *key, void *value); int unordered_multimap_remove_all(unordered_multimap me, void *key); /* Ending */ int unordered_multimap_clear(unordered_multimap me); unordered_multimap unordered_multimap_destroy(unordered_multimap me); #endif /* CONTAINERS_UNORDERED_MULTIMAP_H */ #ifndef CONTAINERS_ARRAY_H #define CONTAINERS_ARRAY_H #include /** * The array data structure, which is a static contiguous array. */ typedef char *array; /* Starting */ array array_init(size_t element_count, size_t data_size); /* Utility */ size_t array_size(array me); void array_copy_to_array(void *arr, array me); void *array_get_data(array me); /* Accessing */ int array_set(array me, size_t index, void *data); int array_get(void *data, array me, size_t index); /* Ending */ array array_destroy(array me); #endif /* CONTAINERS_ARRAY_H */ #ifndef CONTAINERS_FORWARD_LIST_H #define CONTAINERS_FORWARD_LIST_H #include /** * The forward_list data structure, which is a singly-linked list. */ typedef struct internal_forward_list *forward_list; /* Starting */ forward_list forward_list_init(size_t data_size); /* Utility */ size_t forward_list_size(forward_list me); int forward_list_is_empty(forward_list me); void forward_list_copy_to_array(void *arr, forward_list me); /* Adding */ int forward_list_add_first(forward_list me, void *data); int forward_list_add_at(forward_list me, size_t index, void *data); int forward_list_add_last(forward_list me, void *data); /* Removing */ int forward_list_remove_first(forward_list me); int forward_list_remove_at(forward_list me, size_t index); int forward_list_remove_last(forward_list me); /* Setting */ int forward_list_set_first(forward_list me, void *data); int forward_list_set_at(forward_list me, size_t index, void *data); int forward_list_set_last(forward_list me, void *data); /* Getting */ int forward_list_get_first(void *data, forward_list me); int forward_list_get_at(void *data, forward_list me, size_t index); int forward_list_get_last(void *data, forward_list me); /* Ending */ void forward_list_clear(forward_list me); forward_list forward_list_destroy(forward_list me); #endif /* CONTAINERS_FORWARD_LIST_H */ #ifndef CONTAINERS_MULTISET_H #define CONTAINERS_MULTISET_H #include /** * The multiset data structure, which is a collection of key-value pairs, sorted * by keys, keys are unique */ typedef struct internal_multiset *multiset; /* Starting */ multiset multiset_init(size_t key_size, int (*comparator)(const void *const one, const void *const two)); /* Capacity */ int multiset_size(multiset me); int multiset_is_empty(multiset me); /* Accessing */ int multiset_put(multiset me, void *key); int multiset_count(multiset me, void *key); int multiset_contains(multiset me, void *key); int multiset_remove(multiset me, void *key); int multiset_remove_all(multiset me, void *key); /* Ending */ void multiset_clear(multiset me); multiset multiset_destroy(multiset me); #endif /* CONTAINERS_MULTISET_H */ #ifndef CONTAINERS_DEQUE_H #define CONTAINERS_DEQUE_H #include /** * The deque data structure, which is a doubly-ended queue. */ typedef struct internal_deque *deque; /* Starting */ deque deque_init(size_t data_size); /* Utility */ size_t deque_size(deque me); int deque_is_empty(deque me); int deque_trim(deque me); void deque_copy_to_array(void *arr, deque me); /* Adding */ int deque_push_front(deque me, void *data); int deque_push_back(deque me, void *data); /* Removing */ int deque_pop_front(void *data, deque me); int deque_pop_back(void *data, deque me); /* Setting */ int deque_set_first(deque me, void *data); int deque_set_at(deque me, size_t index, void *data); int deque_set_last(deque me, void *data); /* Getting */ int deque_get_first(void *data, deque me); int deque_get_at(void *data, deque me, size_t index); int deque_get_last(void *data, deque me); /* Ending */ int deque_clear(deque me); deque deque_destroy(deque me); #endif /* CONTAINERS_DEQUE_H */ #ifndef CONTAINERS_STACK_H #define CONTAINERS_STACK_H #include /** * The stack data structure, which adapts a container to provide a stack * (last-in first-out). Adapts the deque container. */ typedef struct internal_deque *stack; /* Starting */ stack stack_init(size_t data_size); /* Utility */ size_t stack_size(stack me); int stack_is_empty(stack me); int stack_trim(stack me); void stack_copy_to_array(void *arr, stack me); /* Adding */ int stack_push(stack me, void *data); /* Removing */ int stack_pop(void *data, stack me); /* Getting */ int stack_top(void *data, stack me); /* Ending */ int stack_clear(stack me); stack stack_destroy(stack me); #endif /* CONTAINERS_STACK_H */ #ifndef CONTAINERS_UNORDERED_SET_H #define CONTAINERS_UNORDERED_SET_H #include /** * The unordered_set data structure, which is a collection of unique keys, * hashed by keys. */ typedef struct internal_unordered_set *unordered_set; /* Starting */ unordered_set unordered_set_init(size_t key_size, unsigned long (*hash)(const void *const key), int (*comparator)(const void *const one, const void *const two)); /* Utility */ int unordered_set_rehash(unordered_set me); int unordered_set_size(unordered_set me); int unordered_set_is_empty(unordered_set me); /* Accessing */ int unordered_set_put(unordered_set me, void *key); int unordered_set_contains(unordered_set me, void *key); int unordered_set_remove(unordered_set me, void *key); /* Ending */ int unordered_set_clear(unordered_set me); unordered_set unordered_set_destroy(unordered_set me); #endif /* CONTAINERS_UNORDERED_SET_H */ #ifndef CONTAINERS_VECTOR_H #define CONTAINERS_VECTOR_H #include /** * The vector data structure, which is a dynamic contiguous array. */ typedef struct internal_vector *vector; /* Starting */ vector vector_init(size_t data_size); /* Utility */ int vector_size(vector me); int vector_capacity(vector me); int vector_is_empty(vector me); int vector_reserve(vector me, int size); int vector_trim(vector me); void vector_copy_to_array(void *arr, vector me); void *vector_get_data(vector me); /* Adding */ int vector_add_first(vector me, void *data); int vector_add_at(vector me, int index, void *data); int vector_add_last(vector me, void *data); /* Removing */ int vector_remove_first(vector me); int vector_remove_at(vector me, int index); int vector_remove_last(vector me); /* Setting */ int vector_set_first(vector me, void *data); int vector_set_at(vector me, int index, void *data); int vector_set_last(vector me, void *data); /* Getting */ int vector_get_first(void *data, vector me); int vector_get_at(void *data, vector me, int index); int vector_get_last(void *data, vector me); /* Ending */ int vector_clear(vector me); vector vector_destroy(vector me); #endif /* CONTAINERS_VECTOR_H */ #ifndef CONTAINERS_QUEUE_H #define CONTAINERS_QUEUE_H #include /** * The queue data structure, which adapts a container to provide a queue * (first-in first-out). Adapts the deque container. */ typedef struct internal_deque *queue; /* Starting */ queue queue_init(size_t data_size); /* Utility */ size_t queue_size(queue me); int queue_is_empty(queue me); int queue_trim(queue me); void queue_copy_to_array(void *arr, queue me); /* Adding */ int queue_push(queue me, void *data); /* Removing */ int queue_pop(void *data, queue me); /* Getting */ int queue_front(void *data, queue me); int queue_back(void *data, queue me); /* Ending */ int queue_clear(queue me); queue queue_destroy(queue me); #endif /* CONTAINERS_QUEUE_H */ #ifndef CONTAINERS_SET_H #define CONTAINERS_SET_H #include /** * The set data structure, which is a collection of unique keys, sorted by keys. */ typedef struct internal_set *set; /* Starting */ set set_init(size_t key_size, int (*comparator)(const void *const one, const void *const two)); /* Capacity */ int set_size(set me); int set_is_empty(set me); /* Accessing */ int set_put(set me, void *key); int set_contains(set me, void *key); int set_remove(set me, void *key); /* Ending */ void set_clear(set me); set set_destroy(set me); #endif /* CONTAINERS_SET_H */