hash_fn is int hash_fn(void *key, int modulus) It returns an integer between `0` and `modulus-1` such that if `compare_fn(key1,key2) == 0` then `hash_fn(key1) == hash_fn(key2)`.
There are five predefined hash and comparison functions in st. For keys as numbers: st_numhash(key, modulus) { return (unsigned int) key % modulus; } st_numcmp(x,y) { return (int) x - (int) y; } For keys as pointers: st_ptrhash(key, modulus) { return ((unsigned int) key/4) % modulus } st_ptrcmp(x,y) { return (int) x - (int) y; } For keys as strings: st_strhash(x,y) - a reasonable hashing function for strings strcmp(x,y) - the standard library function It is recommended to use these particular functions if they fit your needs, since st will recognize certain of them and run more quickly because of it. @sideeffect None @see st_init_table_with_params st_free_table */ st_table * st_init_table(st_compare_t compare, st_hash_t hash) { return st_init_table_with_params(compare, hash, ST_DEFAULT_INIT_TABLE_SIZE, ST_DEFAULT_MAX_DENSITY, ST_DEFAULT_GROW_FACTOR, ST_DEFAULT_REORDER_FLAG); } /* st_init_table */ /** @brief Create a table with given parameters. @details The full blown table initializer. compare and hash are the same as in st_init_table. density is the largest the average number of entries per hash bin there should be before the table is grown. grow_factor is the factor the table is grown by when it becomes too full. size is the initial number of bins to be allocated for the hash table. If reorder_flag is non-zero, then every time an entry is found, it is moved to the top of the chain.
st_init_table(compare, hash) is equivelent to st_init_table_with_params(compare, hash, ST_DEFAULT_INIT_TABLE_SIZE, ST_DEFAULT_MAX_DENSITY, ST_DEFAULT_GROW_FACTOR, ST_DEFAULT_REORDER_FLAG); @sideeffect None @see st_init_table st_free_table */ st_table * st_init_table_with_params( st_compare_t compare, st_hash_t hash, int size, int density, double grow_factor, int reorder_flag) { int i; st_table *newt; newt = ALLOC(st_table, 1); if (newt == NIL(st_table)) { return NIL(st_table); } newt->compare = compare; newt->hash = hash; newt->compare_arg = (st_compare_arg_t) 0; newt->hash_arg = (st_hash_arg_t) 0; newt->arg = NIL(void); newt->num_entries = 0; newt->max_density = density; newt->grow_factor = grow_factor; newt->reorder_flag = reorder_flag; if (size <= 0) { size = 1; } newt->num_bins = size; newt->bins = ALLOC(st_table_entry *, size); if (newt->bins == NIL(st_table_entry *)) { FREE(newt); return NIL(st_table); } for(i = 0; i < size; i++) { newt->bins[i] = 0; } return newt; } /* st_init_table_with_params */ /** @brief Creates and initializes a table. @details Like st_init_table_with_params, but the comparison and hash functions are passed an extra parameter `arg` that is registered in the table at initialization. @see st_init_table_with_params */ st_table * st_init_table_with_params_and_arg( st_compare_arg_t compare, st_hash_arg_t hash, void const * arg, int size, int density, double growth_factor, int reorder_flag) { st_table *table; table = st_init_table_with_params((st_compare_t) 0, (st_hash_t) 0, size, density, growth_factor, reorder_flag); if (table == NIL(st_table)) return NIL(st_table); table->compare_arg = compare; table->hash_arg = hash; table->arg = arg; return table; } /* st_init_table_with_params_and_arg */ /** @brief Creates and initializes a table. @details Like st_init_table, but the comparison and hash functions are passed an extra parameter `arg` that is registered in the table at initialization. @see st_init_table st_init_table_with_params_and_arg */ st_table * st_init_table_with_arg( st_compare_arg_t compare, st_hash_arg_t hash, void const * arg) { return st_init_table_with_params_and_arg(compare, hash, arg, ST_DEFAULT_INIT_TABLE_SIZE, ST_DEFAULT_MAX_DENSITY, ST_DEFAULT_GROW_FACTOR, ST_DEFAULT_REORDER_FLAG); } /* st_init_table_with_arg */ /** @brief Free a table. @details Any internal storage associated with table is freed. It is the user's responsibility to free any storage associated with the pointers he placed in the table (by perhaps using st_foreach). @sideeffect None @see st_init_table st_init_table_with_params */ void st_free_table(st_table *table) { st_table_entry *ptr, *next; int i; for(i = 0; i < table->num_bins ; i++) { ptr = table->bins[i]; while (ptr != NIL(st_table_entry)) { next = ptr->next; FREE(ptr); ptr = next; } } FREE(table->bins); FREE(table); } /* st_free_table */ /** @brief Lookup up `key` in `table`. @details If an entry is found, 1 is returned and if `value` is not nil, the variable it points to is set to the associated value. If an entry is not found, 0 is returned and the variable pointed by value is unchanged. @sideeffect The location pointed by value is modified. @see st_lookup_int */ int st_lookup(st_table *table, void const *key, void **value) { int hash_val; st_table_entry *ptr, **last; hash_val = do_hash(key, table); FIND_ENTRY(table, hash_val, key, ptr, last); if (ptr == NIL(st_table_entry)) { return 0; } else { if (value != NIL(void *)) { *value = ptr->record; } return 1; } } /* st_lookup */ /** @brief Lookup up `key` in `table`. @details If an entry is found, 1 is returned and if `value` is not nil, the variable it points to is set to the associated integer value. If an entry is not found, 0 is return and the variable pointed by `value` is unchanged. @sideeffect The location pointed by value is modified. @see st_lookup */ int st_lookup_int(st_table *table, void const *key, int *value) { int hash_val; st_table_entry *ptr, **last; hash_val = do_hash(key, table); FIND_ENTRY(table, hash_val, key, ptr, last); if (ptr == NIL(st_table_entry)) { return 0; } else { if (value != NIL(int)) { *value = (int) (intptr_t) ptr->record; } return 1; } } /* st_lookup_int */ /** @brief Insert value in `table` under the key `key`. @return 1 if there was an entry already under the key; 0 if there was no entry under the key and insertion was successful; ST_OUT_OF_MEM otherwise. In either of the first two cases the new value is added. @sideeffect None */ int st_insert(st_table *table, void *key, void *value) { int hash_val; st_table_entry *newt; st_table_entry *ptr, **last; hash_val = do_hash(key, table); FIND_ENTRY(table, hash_val, key, ptr, last); if (ptr == NIL(st_table_entry)) { if (table->num_entries/table->num_bins >= table->max_density) { if (rehash(table) == ST_OUT_OF_MEM) { return ST_OUT_OF_MEM; } hash_val = do_hash(key, table); } newt = ALLOC(st_table_entry, 1); if (newt == NIL(st_table_entry)) { return ST_OUT_OF_MEM; } newt->key = key; newt->record = value; newt->next = table->bins[hash_val]; table->bins[hash_val] = newt; table->num_entries++; return 0; } else { ptr->record = value; return 1; } } /* st_insert */ /** @brief Place 'value' in 'table' under the key 'key'. @details This is done without checking if 'key' is in 'table' already. This should only be used if you are sure there is not already an entry for 'key', since it is undefined which entry you would later get from st_lookup or st_find_or_add. @return 1 if successful; ST_OUT_OF_MEM otherwise. @sideeffect None @see st_lookup st_find_or_add */ int st_add_direct(st_table *table, void *key, void *value) { int hash_val; st_table_entry *newt; if (table->num_entries / table->num_bins >= table->max_density) { if (rehash(table) == ST_OUT_OF_MEM) { return ST_OUT_OF_MEM; } } hash_val = do_hash(key, table); newt = ALLOC(st_table_entry, 1); if (newt == NIL(st_table_entry)) { return ST_OUT_OF_MEM; } newt->key = key; newt->record = value; newt->next = table->bins[hash_val]; table->bins[hash_val] = newt; table->num_entries++; return 1; } /* st_add_direct */ /** @brief Lookup `key` in `table`; if not found, create an entry. @details In either case set slot to point to the field in the entry where the value is stored. The value associated with `key` may then be changed by accessing directly through slot. As an example: void **slot; void *key; void *value = item_ptr // ptr to a malloc'd structure if (st_find_or_add(table, key, &slot) == 1) { FREE(*slot); // free the old value of the record } *slot = value; // attach the new value to the record This replaces the equivelent code: if (st_lookup(table, key, &ovalue) == 1) { FREE(ovalue); } st_insert(table, key, value); @return 1 if an entry already existed, 0 if it did not exist and creation was successful; ST_OUT_OF_MEM otherwise. @sideeffect The location pointed by slot is modified. @see st_find */ int st_find_or_add(st_table *table, void *key, void ***slot) { int hash_val; st_table_entry *newt, *ptr, **last; hash_val = do_hash(key, table); FIND_ENTRY(table, hash_val, key, ptr, last); if (ptr == NIL(st_table_entry)) { if (table->num_entries / table->num_bins >= table->max_density) { if (rehash(table) == ST_OUT_OF_MEM) { return ST_OUT_OF_MEM; } hash_val = do_hash(key, table); } newt = ALLOC(st_table_entry, 1); if (newt == NIL(st_table_entry)) { return ST_OUT_OF_MEM; } newt->key = key; newt->record = NIL(void); newt->next = table->bins[hash_val]; table->bins[hash_val] = newt; table->num_entries++; if (slot != NIL(void **)) *slot = &newt->record; return 0; } else { if (slot != NIL(void **)) *slot = &ptr->record; return 1; } } /* st_find_or_add */ /** @brief Lookup `key` in `table`. @details Like st_find_or_add, but does not create an entry if one is not found. @sideeffect The location pointed by slot is modified. @see st_find_or_add */ int st_find(st_table *table, void const *key, void ***slot) { int hash_val; st_table_entry *ptr, **last; hash_val = do_hash(key, table); FIND_ENTRY(table, hash_val, key, ptr, last); if (ptr == NIL(st_table_entry)) { return 0; } else { if (slot != NIL(void **)) { *slot = &ptr->record; } return 1; } } /* st_find */ /** @brief Returns a copy of old_table and all its members. @details (st_table *) 0 is returned if there was insufficient memory to do the copy. @sideeffect None */ st_table * st_copy (st_table const *old_table) { st_table *new_table; st_table_entry *ptr, *newptr, *next, *newt; int i, j, num_bins = old_table->num_bins; new_table = ALLOC(st_table, 1); if (new_table == NIL(st_table)) { return NIL(st_table); } *new_table = *old_table; new_table->bins = ALLOC(st_table_entry *, num_bins); if (new_table->bins == NIL(st_table_entry *)) { FREE(new_table); return NIL(st_table); } for(i = 0; i < num_bins ; i++) { new_table->bins[i] = NIL(st_table_entry); ptr = old_table->bins[i]; while (ptr != NIL(st_table_entry)) { newt = ALLOC(st_table_entry, 1); if (newt == NIL(st_table_entry)) { for (j = 0; j <= i; j++) { newptr = new_table->bins[j]; while (newptr != NIL(st_table_entry)) { next = newptr->next; FREE(newptr); newptr = next; } } FREE(new_table->bins); FREE(new_table); return NIL(st_table); } *newt = *ptr; newt->next = new_table->bins[i]; new_table->bins[i] = newt; ptr = ptr->next; } } return new_table; } /* st_copy */ /** @brief Deletes the entry with the key pointed to by `keyp`. @details If the entry is found, 1 is returned, the variable pointed by `keyp` is set to the actual key and the variable pointed by `value` is set to the corresponding entry. (This allows the freeing of the associated storage.) If the entry is not found, then 0 is returned and nothing is changed. @sideeffect The locations pointed by keyp and value are modified. @see st_delete_int */ int st_delete(st_table *table, void **keyp, void **value) { int hash_val; void *key = *keyp; st_table_entry *ptr, **last; hash_val = do_hash(key, table); FIND_ENTRY(table, hash_val, key, ptr ,last); if (ptr == NIL(st_table_entry)) { return 0; } *last = ptr->next; if (value != NIL(void *)) *value = ptr->record; *keyp = ptr->key; FREE(ptr); table->num_entries--; return 1; } /* st_delete */ /** @brief Deletes the entry with the key pointed to by `keyp`. @details `value` must be a pointer to an integer. If the entry is found, 1 is returned, the variable pointed by `keyp` is set to the actual key and the variable pointed by `value` is set to the corresponding entry. (This allows the freeing of the associated storage.) If the entry is not found, then 0 is returned and nothing is changed. @sideeffect The locations pointed by keyp and value are modified. @see st_delete */ int st_delete_int(st_table *table, void **keyp, int *value) { int hash_val; void *key = *keyp; st_table_entry *ptr, **last; hash_val = do_hash(key, table); FIND_ENTRY(table, hash_val, key, ptr ,last); if (ptr == NIL(st_table_entry)) { return 0; } *last = ptr->next; if (value != NIL(int)) *value = (int) (intptr_t) ptr->record; *keyp = ptr->key; FREE(ptr); table->num_entries--; return 1; } /* st_delete_int */ /** @brief Returns the number of entries in the table `table`. @sideeffect None */ int st_count(st_table const *table) { return table->num_entries; } /** @brief Iterates over the elements of a table. @details For each (key, value) record in `table`, st_foreach calls func with the arguments (*func)(key, value, arg) If func returns ST_CONTINUE, st_foreach continues processing entries. If func returns ST_STOP, st_foreach stops processing and returns immediately. If func returns ST_DELETE, then the entry is deleted from the symbol table and st_foreach continues. In the case of ST_DELETE, it is func's responsibility to free the key and value, if necessary. The order in which the records are visited will be seemingly random. @return 1 if all items in the table were generated and 0 if the generation sequence was aborted using ST_STOP. @sideeffect None @see st_foreach_item st_foreach_item_int */ int st_foreach(st_table *table, st_foreach_t func, void *arg) { st_table_entry *ptr, **last; enum st_retval retval; int i; for(i = 0; i < table->num_bins; i++) { last = &table->bins[i]; ptr = *last; while (ptr != NIL(st_table_entry)) { retval = (*func)(ptr->key, ptr->record, arg); switch (retval) { case ST_CONTINUE: last = &ptr->next; ptr = *last; break; case ST_STOP: return 0; case ST_DELETE: *last = ptr->next; table->num_entries--; /* cstevens@ic */ FREE(ptr); ptr = *last; } } } return 1; } /* st_foreach */ /** @brief String hash function. @sideeffect None @see st_init_table */ int st_strhash(void const *string, int modulus) { int val = 0; int c; char const * s = (char const *) string; while ((c = *s++) != '\0') { val = val*997 + c; } return ((val < 0) ? -val : val)%modulus; } /* st_strhash */ /** @brief Integral number hash function. @sideeffect None @see st_init_table st_numcmp */ int st_numhash(void const *x, int size) { return ST_NUMHASH(x, size); } /* st_numhash */ /** @brief Pointer hash function. @sideeffect None @see st_init_table st_ptrcmp */ int st_ptrhash(void const *x, int size) { return ST_PTRHASH(x, size); } /* st_ptrhash */ /** @brief Integral number comparison function. @sideeffect None @see st_init_table st_numhash */ int st_numcmp(void const *x, void const *y) { return ST_NUMCMP(x, y); } /* st_numcmp */ /** @brief Pointer comparison function. @sideeffect None @see st_init_table st_ptrhash */ int st_ptrcmp(void const *x, void const *y) { return ST_NUMCMP(x, y); } /* st_ptrcmp */ /** @brief Initializes a generator. @details Returns a generator handle which when used with st_gen() will progressively return each (key, value) record in `table`. @sideeffect None @see st_free_gen */ st_generator * st_init_gen(st_table const *table) { st_generator *gen; gen = ALLOC(st_generator, 1); if (gen == NIL(st_generator)) { return NIL(st_generator); } gen->table = table; gen->entry = NIL(st_table_entry); gen->index = 0; return gen; } /* st_init_gen */ /** @brief Returns the next (key, value) pair in the generation sequence. @details@parblock Given a generator returned by st_init_gen(), this routine returns the next (key, value) pair in the generation sequence. The pointer `value_p` can be zero which means no value will be returned. When there are no more items in the generation sequence, the routine returns 0. While using a generation sequence, deleting any (key, value) pair other than the one just generated may cause a fatal error when st_gen() is called later in the sequence and is therefore not recommended. @endparblock @sideeffect The locations pointed by key_p and value_p are modified. @see st_gen_int */ int st_gen(st_generator *gen, void **key_p, void **value_p) { int i; if (gen->entry == NIL(st_table_entry)) { /* try to find next entry */ for(i = gen->index; i < gen->table->num_bins; i++) { if (gen->table->bins[i] != NIL(st_table_entry)) { gen->index = i+1; gen->entry = gen->table->bins[i]; break; } } if (gen->entry == NIL(st_table_entry)) { return 0; /* that's all folks ! */ } } *key_p = gen->entry->key; if (value_p != NIL(void *)) { *value_p = gen->entry->record; } gen->entry = gen->entry->next; return 1; } /* st_gen */ /** @brief Returns the next (key, value) pair in the generation sequence. @details Given a generator returned by st_init_gen(), this routine returns the next (key, value) pair in the generation sequence. `value_p` must be a pointer to an integer. The pointer `value_p` can be zero which means no value will be returned. When there are no more items in the generation sequence, the routine returns 0. @sideeffect The locations pointed by key_p and value_p are modified. @see st_gen */ int st_gen_int(st_generator *gen, void **key_p, int *value_p) { int i; if (gen->entry == NIL(st_table_entry)) { /* try to find next entry */ for(i = gen->index; i < gen->table->num_bins; i++) { if (gen->table->bins[i] != NIL(st_table_entry)) { gen->index = i+1; gen->entry = gen->table->bins[i]; break; } } if (gen->entry == NIL(st_table_entry)) { return 0; /* that's all folks ! */ } } *key_p = gen->entry->key; if (value_p != NIL(int)) { *value_p = (int) (intptr_t) gen->entry->record; } gen->entry = gen->entry->next; return 1; } /* st_gen_int */ /** @brief Reclaims the resources associated with `gen`. @details After generating all items in a generation sequence, this routine must be called to reclaim the resources associated with `gen`. @sideeffect None @see st_init_gen */ void st_free_gen(st_generator *gen) { FREE(gen); } /* st_free_gen */ /*---------------------------------------------------------------------------*/ /* Definition of internal functions */ /*---------------------------------------------------------------------------*/ /*---------------------------------------------------------------------------*/ /* Definition of static functions */ /*---------------------------------------------------------------------------*/ /** @brief Rehashes a symbol table. @sideeffect None @see st_insert */ static int rehash(st_table *table) { st_table_entry *ptr, *next, **old_bins; int i, old_num_bins, hash_val, old_num_entries; /* save old values */ old_bins = table->bins; old_num_bins = table->num_bins; old_num_entries = table->num_entries; /* rehash */ table->num_bins = (int) (table->grow_factor * old_num_bins); if (table->num_bins % 2 == 0) { table->num_bins += 1; } table->num_entries = 0; table->bins = ALLOC(st_table_entry *, table->num_bins); if (table->bins == NIL(st_table_entry *)) { table->bins = old_bins; table->num_bins = old_num_bins; table->num_entries = old_num_entries; return ST_OUT_OF_MEM; } /* initialize */ for (i = 0; i < table->num_bins; i++) { table->bins[i] = 0; } /* copy data over */ for (i = 0; i < old_num_bins; i++) { ptr = old_bins[i]; while (ptr != NIL(st_table_entry)) { next = ptr->next; hash_val = do_hash(ptr->key, table); ptr->next = table->bins[hash_val]; table->bins[hash_val] = ptr; table->num_entries++; ptr = next; } } FREE(old_bins); return 1; } /* rehash */