/** * C hashtable implementation * * Copyright (C) 2018-2021 Wojtek Kosior * Redistribution terms are gathered in the `copyright' file. */ /* * https://git.koszko.org/C-hashtable * Note that this version is likely to be more up-to-date than the one linked. * * This is a separate chaining hashtable for general use. It's not * universal: it uses malloc() and free(), so it requires a standard * library to function and it's for single-threaded use only. It does, * however, have one advantage: it rehashes automatically, both when * it grows in size and when it shrinks, while retaining O(1) access * time. A normal hashtable with rehashing would have amortized O(1) * access time, but there would be single access with O(n) time * complexity for each rehashing. In this hashtable, rehashing is done * in parts. For example, a ht_add(), aside from adding an entry, * might also rehash 4 other entries from old table to the new one and * leave the rest unrehashed. * Of course, it is assumed that a good hash function is provided * by the programmer. If not, accesses may still degenerate to O(n). * Hence, this hashtable is not secure against DoS attacks. */ #ifndef HASHTABLE_H #define HASHTABLE_H #include <sys/types.h> /* for ssize_t */ /* These are possible return values of some ht_ functions (see below). */ #define HT_OK 0 #define HT_NO_MEM -1 #define HT_KEY_PRESENT -2 #define HT_KEY_ABSENT -3 typedef struct { /* All members are considered implementation details, except for "entries", * which can be read, but should not be modified by external code. */ size_t entries; /* * tab[] is where entries (chains of entries) are stored. * When rehashing, newtab[] is also used. */ struct ht_node **tab, **newtab; /* sizes of tab[] and newtab[], obviously */ size_t tab_size, new_size; size_t (*hashfunc)(const void* key); int (*cmpfunc)(const void* key1, const void *key2); /* * When no rehashing is taking place, rehashing_position is -1 (#define'd as * NOT_REHASHING in hashtable.c). At any other time, rehashing_position is the * lowest not yet rehashed position in the smaller table. */ ssize_t rehashing_position; } hashtable_t; /* * All int functions return 0 (#define'd as HT_OK) on success and in * case of failure they return error codes, as described below. */ /* May fail with HT_NO_MEM. */ int ht_init(hashtable_t *ht, size_t (*hash)(const void* key), int (*cmp)(const void* key1, const void *key2)); /* May fail with HT_NO_MEM and HT_KEY_PRESENT. */ int ht_add(hashtable_t *ht, const void *key, const void *val); /* * May fail with HT_NO_MEM. If key was not yet present in hashtable, *oldkey and * *oldval are not modified. Otherwise, just-replaced pair is stored in them. */ int ht_set(hashtable_t *ht, const void *key, const void *val, void **oldkey, void **oldval); /* * If present, the looked for pair is stored in *storedkey and *val. Otherwise, * they're not modified and HT_KEY_ABSENT is returned. storedkey and/or val can * be NULL. */ int ht_get(hashtable_t *ht, const void *key, void **storedkey, void **val); /* * Works like ht_get() but is thread-safe with regard to other calls to * ht_get_threadsafe() on the same hashtable. Note that the hash and compare * functions supplied to the hashtable also have to be thread-safe (that * requirement is of course met for those used by ht_string_init()). */ int ht_get_threadsafe(hashtable_t *ht, const void *key, void **storedkey, void **val); /* Works like the above but also removes the pair from ht if found. */ int ht_rem(hashtable_t *ht, const void *key, void **storedkey, void **val); /* * De-initializes the hashtable freeing all its structures. The programmer is * responsible for freeing keys and values if they were allocated from the heap * (see ht_map_destroy() below). */ void ht_destroy(hashtable_t *ht); /* Calls ht_finish_resizing(), then maps through ht. */ void ht_map(hashtable_t *ht, void *arg, void (*mapfunc)(const void *key, void *val, void *arg)); /* * It might be tempting to use ht_map() to free() all keys and values stored in * ht and then call ht_destroy(). If you think about it, ht_map() would leave * hashtable in a broken state - with keys being deallocated. Depending on the * implementation, ht_destroy() could cope with that, but we'd rather not * guarrantee anything, so here's another function just for that - mapping * through entries and destroying the hashtable immediately after, explicitly * allowing the mapping function to deallocate keys. */ void ht_map_destroy(hashtable_t *ht, void *arg, void (*mapfunc)(void *key, void *val, void *arg)); /* * If hashtable is in the process of being rehashed, this function * processes it to the end. Otherwise - it does nothing. */ void ht_finish_resizing(hashtable_t *ht); /* Included, since strings are commonly used as keys. */ size_t ht_string_hash(const char *key); /* * May fail with HT_NO_MEM. Initializes ht for use with string keys * (using ht_string_hash() and strcmp()). */ int ht_string_init(hashtable_t *ht); #endif /* HASHTABLE_H */