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hashmap.c
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hashmap.c
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/*
* Copyright (c) 2016-2018 David Leeds <[email protected]>
*
* Hashmap is free software; you can redistribute it and/or modify
* it under the terms of the MIT license. See LICENSE for details.
*
* Updated 2018-02-16 by Tim Morgan to use GC_MALLOC and friends.
*/
#include <gc.h>
#include <stdlib.h>
#include <stdint.h>
#include <stdbool.h>
#include <string.h>
#include <ctype.h>
#include <errno.h>
#include "hashmap.h"
#ifndef HASHMAP_NOASSERT
#include <assert.h>
#define HASHMAP_ASSERT(expr) assert(expr)
#else
#define HASHMAP_ASSERT(expr)
#endif
/* Table sizes must be powers of 2 */
#define HASHMAP_SIZE_MIN (1 << 5) /* 32 */
#define HASHMAP_SIZE_DEFAULT (1 << 8) /* 256 */
#define HASHMAP_SIZE_MOD(map, val) ((val) & ((map)->table_size - 1))
/* Limit for probing is 1/2 of table_size */
#define HASHMAP_PROBE_LEN(map) ((map)->table_size >> 1)
/* Return the next linear probe index */
#define HASHMAP_PROBE_NEXT(map, index) HASHMAP_SIZE_MOD(map, (index) + 1)
/* Check if index b is less than or equal to index a */
#define HASHMAP_INDEX_LE(map, a, b) \
((a) == (b) || (((b) - (a)) & ((map)->table_size >> 1)) != 0)
struct hashmap_entry {
void *key;
void *data;
#ifdef HASHMAP_METRICS
size_t num_collisions;
#endif
};
/*
* Enforce a maximum 0.75 load factor.
*/
static inline size_t hashmap_table_min_size_calc(size_t num_entries)
{
return num_entries + (num_entries / 3);
}
/*
* Calculate the optimal table size, given the specified max number
* of elements.
*/
static size_t hashmap_table_size_calc(size_t num_entries)
{
size_t table_size;
size_t min_size;
table_size = hashmap_table_min_size_calc(num_entries);
/* Table size is always a power of 2 */
min_size = HASHMAP_SIZE_MIN;
while (min_size < table_size) {
min_size <<= 1;
}
return min_size;
}
/*
* Get a valid hash table index from a key.
*/
static inline size_t hashmap_calc_index(const struct hashmap *map,
const void *key)
{
return HASHMAP_SIZE_MOD(map, map->hash(key));
}
/*
* Return the next populated entry, starting with the specified one.
* Returns NULL if there are no more valid entries.
*/
static struct hashmap_entry *hashmap_entry_get_populated(
const struct hashmap *map, struct hashmap_entry *entry)
{
for (; entry < &map->table[map->table_size]; ++entry) {
if (entry->key) {
return entry;
}
}
return NULL;
}
/*
* Find the hashmap entry with the specified key, or an empty slot.
* Returns NULL if the entire table has been searched without finding a match.
*/
static struct hashmap_entry *hashmap_entry_find(const struct hashmap *map,
const void *key, bool find_empty)
{
size_t i;
size_t index;
size_t probe_len = HASHMAP_PROBE_LEN(map);
struct hashmap_entry *entry;
index = hashmap_calc_index(map, key);
/* Linear probing */
for (i = 0; i < probe_len; ++i) {
entry = &map->table[index];
if (!entry->key) {
if (find_empty) {
#ifdef HASHMAP_METRICS
entry->num_collisions = i;
#endif
return entry;
}
return NULL;
}
if (map->key_compare(key, entry->key) == 0) {
return entry;
}
index = HASHMAP_PROBE_NEXT(map, index);
}
return NULL;
}
/*
* Removes the specified entry and processes the proceeding entries to reduce
* the load factor and keep the chain continuous. This is a required
* step for hash maps using linear probing.
*/
static void hashmap_entry_remove(struct hashmap *map,
struct hashmap_entry *removed_entry)
{
size_t i;
#ifdef HASHMAP_METRICS
size_t removed_i = 0;
#endif
size_t index;
size_t entry_index;
size_t removed_index = (removed_entry - map->table);
struct hashmap_entry *entry;
/* Free the key */
if (map->key_free) {
map->key_free(removed_entry->key);
}
--map->num_entries;
/* Fill the free slot in the chain */
index = HASHMAP_PROBE_NEXT(map, removed_index);
for (i = 1; i < map->table_size; ++i) {
entry = &map->table[index];
if (!entry->key) {
/* Reached end of chain */
break;
}
entry_index = hashmap_calc_index(map, entry->key);
/* Shift in entries with an index <= to the removed slot */
if (HASHMAP_INDEX_LE(map, removed_index, entry_index)) {
#ifdef HASHMAP_METRICS
entry->num_collisions -= (i - removed_i);
removed_i = i;
#endif
memcpy(removed_entry, entry, sizeof(*removed_entry));
removed_index = index;
removed_entry = entry;
}
index = HASHMAP_PROBE_NEXT(map, index);
}
/* Clear the last removed entry */
memset(removed_entry, 0, sizeof(*removed_entry));
}
/*
* Reallocates the hash table to the new size and rehashes all entries.
* new_size MUST be a power of 2.
* Returns 0 on success and -errno on allocation or hash function failure.
*/
static int hashmap_rehash(struct hashmap *map, size_t new_size)
{
size_t old_size;
struct hashmap_entry *old_table;
struct hashmap_entry *new_table;
struct hashmap_entry *entry;
struct hashmap_entry *new_entry;
HASHMAP_ASSERT(new_size >= HASHMAP_SIZE_MIN);
HASHMAP_ASSERT((new_size & (new_size - 1)) == 0);
new_table = (struct hashmap_entry *)GC_MALLOC(new_size * sizeof(struct hashmap_entry));
if (!new_table) {
return -ENOMEM;
}
/* Backup old elements in case of rehash failure */
old_size = map->table_size;
old_table = map->table;
map->table_size = new_size;
map->table = new_table;
/* Rehash */
for (entry = old_table; entry < &old_table[old_size]; ++entry) {
if (!entry->data) {
/* Only copy entries with data */
continue;
}
new_entry = hashmap_entry_find(map, entry->key, true);
if (!new_entry) {
/*
* The load factor is too high with the new table
* size, or a poor hash function was used.
*/
goto revert;
}
/* Shallow copy (intentionally omits num_collisions) */
new_entry->key = entry->key;
new_entry->data = entry->data;
}
GC_FREE(old_table);
return 0;
revert:
map->table_size = old_size;
map->table = old_table;
GC_FREE(new_table);
return -EINVAL;
}
/*
* Iterate through all entries and free all keys.
*/
static void hashmap_free_keys(struct hashmap *map)
{
struct hashmap_iter *iter;
if (!map->key_free) {
return;
}
for (iter = hashmap_iter(map); iter;
iter = hashmap_iter_next(map, iter)) {
map->key_free((void *)hashmap_iter_get_key(iter));
}
}
/*
* Initialize an empty hashmap.
*
* hash_func should return an even distribution of numbers between 0
* and SIZE_MAX varying on the key provided. If set to NULL, the default
* case-sensitive string hash function is used: hashmap_hash_string
*
* key_compare_func should return 0 if the keys match, and non-zero otherwise.
* If set to NULL, the default case-sensitive string comparator function is
* used: hashmap_compare_string
*
* initial_size is optional, and may be set to the max number of entries
* expected to be put in the hash table. This is used as a hint to
* pre-allocate the hash table to the minimum size needed to avoid
* gratuitous rehashes. If initial_size is 0, a default size will be used.
*
* Returns 0 on success and -errno on failure.
*/
int hashmap_init(struct hashmap *map, size_t (*hash_func)(const void *),
int (*key_compare_func)(const void *, const void *),
size_t initial_size)
{
HASHMAP_ASSERT(map != NULL);
if (!initial_size) {
initial_size = HASHMAP_SIZE_DEFAULT;
} else {
/* Convert init size to valid table size */
initial_size = hashmap_table_size_calc(initial_size);
}
map->table_size_init = initial_size;
map->table_size = initial_size;
map->num_entries = 0;
map->table = (struct hashmap_entry *)GC_MALLOC(initial_size * sizeof(struct hashmap_entry));
if (!map->table) {
return -ENOMEM;
}
map->hash = hash_func ?
hash_func : hashmap_hash_string;
map->key_compare = key_compare_func ?
key_compare_func : hashmap_compare_string;
map->key_alloc = NULL;
map->key_free = NULL;
return 0;
}
/*
* Free the hashmap and all associated memory.
*/
void hashmap_destroy(struct hashmap *map)
{
if (!map) {
return;
}
hashmap_free_keys(map);
GC_FREE(map->table);
memset(map, 0, sizeof(*map));
}
/*
* Enable internal memory management of hash keys.
*/
void hashmap_set_key_alloc_funcs(struct hashmap *map,
void *(*key_alloc_func)(const void *),
void (*key_free_func)(void *))
{
HASHMAP_ASSERT(map != NULL);
map->key_alloc = key_alloc_func;
map->key_free = key_free_func;
}
/*
* Add an entry to the hashmap. If an entry with a matching key already
* exists and has a data pointer associated with it, the existing data
* pointer is returned, instead of assigning the new value. Compare
* the return value with the data passed in to determine if a new entry was
* created. Returns NULL if memory allocation failed.
*/
void *hashmap_put(struct hashmap *map, const void *key, void *data)
{
struct hashmap_entry *entry;
HASHMAP_ASSERT(map != NULL);
HASHMAP_ASSERT(key != NULL);
/* Rehash with 2x capacity if load factor is approaching 0.75 */
if (map->table_size <= hashmap_table_min_size_calc(map->num_entries)) {
hashmap_rehash(map, map->table_size << 1);
}
entry = hashmap_entry_find(map, key, true);
if (!entry) {
/*
* Cannot find an empty slot. Either out of memory, or using
* a poor hash function. Attempt to rehash once to reduce
* chain length.
*/
if (hashmap_rehash(map, map->table_size << 1) < 0) {
return NULL;
}
entry = hashmap_entry_find(map, key, true);
if (!entry) {
return NULL;
}
}
if (!entry->key) {
/* Allocate copy of key to simplify memory management */
if (map->key_alloc) {
entry->key = map->key_alloc(key);
if (!entry->key) {
return NULL;
}
} else {
entry->key = (void *)key;
}
++map->num_entries;
} else if (entry->data) {
/* Do not overwrite existing data */
return entry->data;
}
entry->data = data;
return data;
}
/*
* Return the data pointer, or NULL if no entry exists.
*/
void *hashmap_get(const struct hashmap *map, const void *key)
{
struct hashmap_entry *entry;
HASHMAP_ASSERT(map != NULL);
HASHMAP_ASSERT(key != NULL);
entry = hashmap_entry_find(map, key, false);
if (!entry) {
return NULL;
}
return entry->data;
}
/*
* Remove an entry with the specified key from the map.
* Returns the data pointer, or NULL, if no entry was found.
*/
void *hashmap_remove(struct hashmap *map, const void *key)
{
struct hashmap_entry *entry;
void *data;
HASHMAP_ASSERT(map != NULL);
HASHMAP_ASSERT(key != NULL);
entry = hashmap_entry_find(map, key, false);
if (!entry) {
return NULL;
}
data = entry->data;
/* Clear the entry and make the chain contiguous */
hashmap_entry_remove(map, entry);
return data;
}
/*
* Remove all entries.
*/
void hashmap_clear(struct hashmap *map)
{
HASHMAP_ASSERT(map != NULL);
hashmap_free_keys(map);
map->num_entries = 0;
memset(map->table, 0, sizeof(struct hashmap_entry) * map->table_size);
}
/*
* Remove all entries and reset the hash table to its initial size.
*/
void hashmap_reset(struct hashmap *map)
{
struct hashmap_entry *new_table;
HASHMAP_ASSERT(map != NULL);
hashmap_clear(map);
if (map->table_size == map->table_size_init) {
return;
}
new_table = (struct hashmap_entry *)GC_REALLOC(map->table,
sizeof(struct hashmap_entry) * map->table_size_init);
if (!new_table) {
return;
}
map->table = new_table;
map->table_size = map->table_size_init;
}
/*
* Return the number of entries in the hash map.
*/
size_t hashmap_size(const struct hashmap *map)
{
HASHMAP_ASSERT(map != NULL);
return map->num_entries;
}
/*
* Get a new hashmap iterator. The iterator is an opaque
* pointer that may be used with hashmap_iter_*() functions.
* Hashmap iterators are INVALID after a put or remove operation is performed.
* hashmap_iter_remove() allows safe removal during iteration.
*/
struct hashmap_iter *hashmap_iter(const struct hashmap *map)
{
HASHMAP_ASSERT(map != NULL);
if (!map->num_entries) {
return NULL;
}
return (struct hashmap_iter *)hashmap_entry_get_populated(map,
map->table);
}
/*
* Return an iterator to the next hashmap entry. Returns NULL if there are
* no more entries.
*/
struct hashmap_iter *hashmap_iter_next(const struct hashmap *map,
const struct hashmap_iter *iter)
{
struct hashmap_entry *entry = (struct hashmap_entry *)iter;
HASHMAP_ASSERT(map != NULL);
if (!iter) {
return NULL;
}
return (struct hashmap_iter *)hashmap_entry_get_populated(map,
entry + 1);
}
/*
* Remove the hashmap entry pointed to by this iterator and return an
* iterator to the next entry. Returns NULL if there are no more entries.
*/
struct hashmap_iter *hashmap_iter_remove(struct hashmap *map,
const struct hashmap_iter *iter)
{
struct hashmap_entry *entry = (struct hashmap_entry *)iter;
HASHMAP_ASSERT(map != NULL);
if (!iter) {
return NULL;
}
if (!entry->key) {
/* Iterator is invalid, so just return the next valid entry */
return hashmap_iter_next(map, iter);
}
hashmap_entry_remove(map, entry);
return (struct hashmap_iter *)hashmap_entry_get_populated(map, entry);
}
/*
* Return the key of the entry pointed to by the iterator.
*/
const void *hashmap_iter_get_key(const struct hashmap_iter *iter)
{
if (!iter) {
return NULL;
}
return (const void *)((struct hashmap_entry *)iter)->key;
}
/*
* Return the data of the entry pointed to by the iterator.
*/
void *hashmap_iter_get_data(const struct hashmap_iter *iter)
{
if (!iter) {
return NULL;
}
return ((struct hashmap_entry *)iter)->data;
}
/*
* Set the data pointer of the entry pointed to by the iterator.
*/
void hashmap_iter_set_data(const struct hashmap_iter *iter, void *data)
{
if (!iter) {
return;
}
((struct hashmap_entry *)iter)->data = data;
}
/*
* Invoke func for each entry in the hashmap. Unlike the hashmap_iter_*()
* interface, this function supports calls to hashmap_remove() during iteration.
* However, it is an error to put or remove an entry other than the current one,
* and doing so will immediately halt iteration and return an error.
* Iteration is stopped if func returns non-zero. Returns func's return
* value if it is < 0, otherwise, 0.
*/
int hashmap_foreach(const struct hashmap *map,
int (*func)(const void *, void *, void *), void *arg)
{
struct hashmap_entry *entry;
size_t num_entries;
const void *key;
int rc;
HASHMAP_ASSERT(map != NULL);
HASHMAP_ASSERT(func != NULL);
entry = map->table;
for (entry = map->table; entry < &map->table[map->table_size];
++entry) {
if (!entry->key) {
continue;
}
num_entries = map->num_entries;
key = entry->key;
rc = func(entry->key, entry->data, arg);
if (rc < 0) {
return rc;
}
if (rc > 0) {
return 0;
}
/* Run this entry again if func() deleted it */
if (entry->key != key) {
--entry;
} else if (num_entries != map->num_entries) {
/* Stop immediately if func put/removed another entry */
return -1;
}
}
return 0;
}
/*
* Default hash function for string keys.
* This is an implementation of the well-documented Jenkins one-at-a-time
* hash function.
*/
size_t hashmap_hash_string(const void *key)
{
const char *key_str = (const char *)key;
size_t hash = 0;
for (; *key_str; ++key_str) {
hash += *key_str;
hash += (hash << 10);
hash ^= (hash >> 6);
}
hash += (hash << 3);
hash ^= (hash >> 11);
hash += (hash << 15);
return hash;
}
/*
* Default key comparator function for string keys.
*/
int hashmap_compare_string(const void *a, const void *b)
{
return strcmp((const char *)a, (const char *)b);
}
/*
* Default key allocation function for string keys. Use free() for the
* key_free_func.
*/
void *hashmap_alloc_key_string(const void *key)
{
return (void *)strdup((const char *)key);
}
/*
* Case insensitive hash function for string keys.
*/
size_t hashmap_hash_string_i(const void *key)
{
const char *key_str = (const char *)key;
size_t hash = 0;
for (; *key_str; ++key_str) {
hash += tolower(*key_str);
hash += (hash << 10);
hash ^= (hash >> 6);
}
hash += (hash << 3);
hash ^= (hash >> 11);
hash += (hash << 15);
return hash;
}
/*
* Case insensitive key comparator function for string keys.
*/
int hashmap_compare_string_i(const void *a, const void *b)
{
return strcasecmp((const char *)a, (const char *)b);
}
#ifdef HASHMAP_METRICS
/*
* Return the load factor.
*/
double hashmap_load_factor(const struct hashmap *map)
{
HASHMAP_ASSERT(map != NULL);
if (!map->table_size) {
return 0;
}
return (double)map->num_entries / map->table_size;
}
/*
* Return the average number of collisions per entry.
*/
double hashmap_collisions_mean(const struct hashmap *map)
{
struct hashmap_entry *entry;
size_t total_collisions = 0;
HASHMAP_ASSERT(map != NULL);
if (!map->num_entries) {
return 0;
}
for (entry = map->table; entry < &map->table[map->table_size];
++entry) {
if (!entry->key) {
continue;
}
total_collisions += entry->num_collisions;
}
return (double)total_collisions / map->num_entries;
}
/*
* Return the variance between entry collisions. The higher the variance,
* the more likely the hash function is poor and is resulting in clustering.
*/
double hashmap_collisions_variance(const struct hashmap *map)
{
struct hashmap_entry *entry;
double mean_collisions;
double variance;
double total_variance = 0;
HASHMAP_ASSERT(map != NULL);
if (!map->num_entries) {
return 0;
}
mean_collisions = hashmap_collisions_mean(map);
for (entry = map->table; entry < &map->table[map->table_size];
++entry) {
if (!entry->key) {
continue;
}
variance = (double)entry->num_collisions - mean_collisions;
total_variance += variance * variance;
}
return total_variance / map->num_entries;
}
#endif