blender-archive/source/blender/blenlib/intern/BLI_ghash.c

/*
 * ***** BEGIN GPL LICENSE BLOCK *****
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
 *
 * The Original Code is Copyright (C) 2001-2002 by NaN Holding BV.
 * All rights reserved.
 *
 * The Original Code is: all of this file.
 *
 * Contributor(s): none yet.
 *
 * ***** END GPL LICENSE BLOCK *****
 */

/** \file blender/blenlib/intern/BLI_ghash.c
 *  \ingroup bli
 *
 * A general (pointer -> pointer) hash table ADT
 *
 * \note edgehash.c is based on this, make sure they stay in sync.
 */

#include <string.h>
#include <stdlib.h>
#include <limits.h>

#include "MEM_guardedalloc.h"

#include "BLI_sys_types.h"  /* for intptr_t support */
#include "BLI_utildefines.h"
#include "BLI_mempool.h"
#include "BLI_ghash.h"
#include "BLI_strict_flags.h"


const unsigned int hashsizes[] = {
	5, 11, 17, 37, 67, 131, 257, 521, 1031, 2053, 4099, 8209, 
	16411, 32771, 65537, 131101, 262147, 524309, 1048583, 2097169, 
	4194319, 8388617, 16777259, 33554467, 67108879, 134217757, 
	268435459
};

/* internal flag to ensure sets values aren't used */
#ifndef NDEBUG
#  define GHASH_FLAG_IS_SET (1 << 8)
#  define IS_GHASH_ASSERT(gh) BLI_assert((gh->flag & GHASH_FLAG_IS_SET) == 0)
// #  define IS_GSET_ASSERT(gs) BLI_assert((gs->flag & GHASH_FLAG_IS_SET) != 0)
#else
#  define IS_GHASH_ASSERT(gh)
// #  define IS_GSET_ASSERT(eh)
#endif

/***/

typedef struct Entry {
	struct Entry *next;

	void *key, *val;
} Entry;

struct GHash {
	GHashHashFP hashfp;
	GHashCmpFP cmpfp;

	Entry **buckets;
	struct BLI_mempool *entrypool;
	unsigned int nbuckets;
	unsigned int nentries;
	unsigned int cursize, flag;
};


/* -------------------------------------------------------------------- */
/* GHash API */

/** \name Internal Utility API
 * \{ */

/**
 * Get the hash for a key.
 */
BLI_INLINE unsigned int ghash_keyhash(GHash *gh, const void *key)
{
	return gh->hashfp(key) % gh->nbuckets;
}

/**
 * Check if the number of items in the GHash is large enough to require more buckets.
 */
BLI_INLINE bool ghash_test_expand_buckets(const unsigned int nentries, const unsigned int nbuckets)
{
	return (nentries > nbuckets * 3);
}

/**
 * Expand buckets to the next size up.
 */
BLI_INLINE void ghash_resize_buckets(GHash *gh, const unsigned int nbuckets)
{
	Entry **buckets_old = gh->buckets;
	Entry **buckets_new;
	const unsigned int nbuckets_old = gh->nbuckets;
	unsigned int i;
	Entry *e;

	BLI_assert(gh->nbuckets != nbuckets);

	gh->nbuckets = nbuckets;
	buckets_new = (Entry **)MEM_callocN(gh->nbuckets * sizeof(*gh->buckets), "buckets");

	for (i = 0; i < nbuckets_old; i++) {
		Entry *e_next;
		for (e = buckets_old[i]; e; e = e_next) {
			const unsigned hash = ghash_keyhash(gh, e->key);
			e_next = e->next;
			e->next = buckets_new[hash];
			buckets_new[hash] = e;
		}
	}

	gh->buckets = buckets_new;
	MEM_freeN(buckets_old);
}

/**
 * Increase initial bucket size to match a reserved amount.
 */
BLI_INLINE void ghash_buckets_reserve(GHash *gh, const unsigned int nentries_reserve)
{
	while (ghash_test_expand_buckets(nentries_reserve, gh->nbuckets)) {
		gh->nbuckets = hashsizes[++gh->cursize];
	}
}

/**
 * Internal lookup function.
 * Takes a hash argument to avoid calling #ghash_keyhash multiple times.
 */
BLI_INLINE Entry *ghash_lookup_entry_ex(GHash *gh, const void *key,
                                        const unsigned int hash)
{
	Entry *e;

	for (e = gh->buckets[hash]; e; e = e->next) {
		if (UNLIKELY(gh->cmpfp(key, e->key) == 0)) {
			return e;
		}
	}
	return NULL;
}

/**
 * Internal lookup function. Only wraps #ghash_lookup_entry_ex
 */
BLI_INLINE Entry *ghash_lookup_entry(GHash *gh, const void *key)
{
	const unsigned int hash = ghash_keyhash(gh, key);
	return ghash_lookup_entry_ex(gh, key, hash);
}

static GHash *ghash_new(GHashHashFP hashfp, GHashCmpFP cmpfp, const char *info,
                        const unsigned int nentries_reserve,
                        const unsigned int entry_size)
{
	GHash *gh = MEM_mallocN(sizeof(*gh), info);

	gh->hashfp = hashfp;
	gh->cmpfp = cmpfp;

	gh->nbuckets = hashsizes[0];  /* gh->cursize */
	gh->nentries = 0;
	gh->cursize = 0;
	gh->flag = 0;

	/* if we have reserved the number of elements that this hash will contain */
	if (nentries_reserve) {
		ghash_buckets_reserve(gh, nentries_reserve);
	}

	gh->buckets = MEM_callocN(gh->nbuckets * sizeof(*gh->buckets), "buckets");
	gh->entrypool = BLI_mempool_create(entry_size, 64, 64, BLI_MEMPOOL_NOP);

	return gh;
}

/**
 * Internal insert function.
 * Takes a hash argument to avoid calling #ghash_keyhash multiple times.
 */
BLI_INLINE void ghash_insert_ex(GHash *gh, void *key, void *val,
                                unsigned int hash)
{
	Entry *e = (Entry *)BLI_mempool_alloc(gh->entrypool);
	BLI_assert((gh->flag & GHASH_FLAG_ALLOW_DUPES) || (BLI_ghash_haskey(gh, key) == 0));
	IS_GHASH_ASSERT(gh);

	e->next = gh->buckets[hash];
	e->key = key;
	e->val = val;
	gh->buckets[hash] = e;

	if (UNLIKELY(ghash_test_expand_buckets(++gh->nentries, gh->nbuckets))) {
		ghash_resize_buckets(gh, hashsizes[++gh->cursize]);
	}
}

/**
 * Insert function that doesn't set the value (use for GSet)
 */
BLI_INLINE void ghash_insert_ex_keyonly(GHash *gh, void *key,
                                        unsigned int hash)
{
	Entry *e = (Entry *)BLI_mempool_alloc(gh->entrypool);
	BLI_assert((gh->flag & GHASH_FLAG_ALLOW_DUPES) || (BLI_ghash_haskey(gh, key) == 0));
	e->next = gh->buckets[hash];
	e->key = key;
	/* intentionally leave value unset */
	gh->buckets[hash] = e;

	if (UNLIKELY(ghash_test_expand_buckets(++gh->nentries, gh->nbuckets))) {
		ghash_resize_buckets(gh, hashsizes[++gh->cursize]);
	}
}

BLI_INLINE void ghash_insert(GHash *gh, void *key, void *val)
{
	const unsigned int hash = ghash_keyhash(gh, key);
	ghash_insert_ex(gh, key, val, hash);
}

/**
 * Remove the entry and return it, caller must free from gh->entrypool.
 */
static Entry *ghash_remove_ex(GHash *gh, void *key, GHashKeyFreeFP keyfreefp, GHashValFreeFP valfreefp,
                              unsigned int hash)
{
	Entry *e;
	Entry *e_prev = NULL;

	for (e = gh->buckets[hash]; e; e = e->next) {
		if (UNLIKELY(gh->cmpfp(key, e->key) == 0)) {
			Entry *e_next = e->next;

			if (keyfreefp) keyfreefp(e->key);
			if (valfreefp) valfreefp(e->val);

			if (e_prev) e_prev->next = e_next;
			else   gh->buckets[hash] = e_next;

			gh->nentries--;
			return e;
		}
		e_prev = e;
	}

	return NULL;
}

/**
 * Run free callbacks for freeing entries.
 */
static void ghash_free_cb(GHash *gh, GHashKeyFreeFP keyfreefp, GHashValFreeFP valfreefp)
{
	unsigned int i;

	BLI_assert(keyfreefp || valfreefp);

	for (i = 0; i < gh->nbuckets; i++) {
		Entry *e;

		for (e = gh->buckets[i]; e; ) {
			Entry *e_next = e->next;

			if (keyfreefp) keyfreefp(e->key);
			if (valfreefp) valfreefp(e->val);

			e = e_next;
		}
	}
}
/** \} */


/** \name Public API
 * \{ */

/**
 * Creates a new, empty GHash.
 *
 * \param hashfp  Hash callback.
 * \param cmpfp  Comparison callback.
 * \param info  Identifier string for the GHash.
 * \param nentries_reserve  Optionally reserve the number of members that the hash will hold.
 * Use this to avoid resizing buckets if the size is known or can be closely approximated.
 * \return  An empty GHash.
 */
GHash *BLI_ghash_new_ex(GHashHashFP hashfp, GHashCmpFP cmpfp, const char *info,
                        const unsigned int nentries_reserve)
{
	return ghash_new(hashfp, cmpfp, info,
	                 nentries_reserve,
	                 (unsigned int)sizeof(Entry));
}

/**
 * Wraps #BLI_ghash_new_ex with zero entries reserved.
 */
GHash *BLI_ghash_new(GHashHashFP hashfp, GHashCmpFP cmpfp, const char *info)
{
	return BLI_ghash_new_ex(hashfp, cmpfp, info, 0);
}

/**
 * \return size of the GHash.
 */
int BLI_ghash_size(GHash *gh)
{
	return (int)gh->nentries;
}

/**
 * Insert a key/value pair into the \a gh.
 *
 * \note Duplicates are not checked,
 * the caller is expected to ensure elements are unique unless
 * GHASH_FLAG_ALLOW_DUPES flag is set.
 */
void BLI_ghash_insert(GHash *gh, void *key, void *val)
{
	ghash_insert(gh, key, val);
}

/**
 * Inserts a new value to a key that may already be in ghash.
 *
 * Avoids #BLI_ghash_remove, #BLI_ghash_insert calls (double lookups)
 *
 * \returns true if a new key has been added.
 */
bool BLI_ghash_reinsert(GHash *gh, void *key, void *val, GHashKeyFreeFP keyfreefp, GHashValFreeFP valfreefp)
{
	const unsigned int hash = ghash_keyhash(gh, key);
	Entry *e = ghash_lookup_entry_ex(gh, key, hash);
	if (e) {
		if (keyfreefp) keyfreefp(e->key);
		if (valfreefp) valfreefp(e->val);
		e->key = key;
		e->val = val;
		return false;
	}
	else {
		ghash_insert_ex(gh, key, val, hash);
		return true;
	}
}

/**
 * Lookup the value of \a key in \a gh.
 *
 * \param key  The key to lookup.
 * \returns the value for \a key or NULL.
 *
 * \note When NULL is a valid value, use #BLI_ghash_lookup_p to differentiate a missing key
 * from a key with a NULL value. (Avoids calling #BLI_ghash_haskey before #BLI_ghash_lookup)
 */
void *BLI_ghash_lookup(GHash *gh, const void *key)
{
	Entry *e = ghash_lookup_entry(gh, key);
	IS_GHASH_ASSERT(gh);
	return e ? e->val : NULL;
}

/**
 * A version of #BLI_ghash_lookup which accepts a fallback argument.
 */
void *BLI_ghash_lookup_default(GHash *gh, const void *key, void *val_default)
{
	Entry *e = ghash_lookup_entry(gh, key);
	IS_GHASH_ASSERT(gh);
	return e ? e->val : val_default;
}

/**
 * Lookup a pointer to the value of \a key in \a gh.
 *
 * \param key  The key to lookup.
 * \returns the pointer to value for \a key or NULL.
 *
 * \note This has 2 main benifits over #BLI_ghash_lookup.
 * - A NULL return always means that \a key isn't in \a gh.
 * - The value can be modified in-place without further function calls (faster).
 */
void **BLI_ghash_lookup_p(GHash *gh, const void *key)
{
	Entry *e = ghash_lookup_entry(gh, key);
	IS_GHASH_ASSERT(gh);
	return e ? &e->val : NULL;
}

/**
 * Remove \a key from \a gh, or return false if the key wasn't found.
 *
 * \param key  The key to remove.
 * \param keyfreefp  Optional callback to free the key.
 * \param valfreefp  Optional callback to free the value.
 * \return true if \a key was removed from \a gh.
 */
bool BLI_ghash_remove(GHash *gh, void *key, GHashKeyFreeFP keyfreefp, GHashValFreeFP valfreefp)
{
	const unsigned int hash = ghash_keyhash(gh, key);
	Entry *e = ghash_remove_ex(gh, key, keyfreefp, valfreefp, hash);
	if (e) {
		BLI_mempool_free(gh->entrypool, e);
		return true;
	}
	else {
		return false;
	}
}

/* same as above but return the value,
 * no free value argument since it will be returned */
/**
 * Remove \a key from \a gh, returning the value or NULL if the key wasn't found.
 *
 * \param key  The key to remove.
 * \param keyfreefp  Optional callback to free the key.
 * \return the value of \a key int \a gh or NULL.
 */
void *BLI_ghash_popkey(GHash *gh, void *key, GHashKeyFreeFP keyfreefp)
{
	const unsigned int hash = ghash_keyhash(gh, key);
	Entry *e = ghash_remove_ex(gh, key, keyfreefp, NULL, hash);
	IS_GHASH_ASSERT(gh);
	if (e) {
		void *val = e->val;
		BLI_mempool_free(gh->entrypool, e);
		return val;
	}
	else {
		return NULL;
	}
}

/**
 * \return true if the \a key is in \a gh.
 */
bool BLI_ghash_haskey(GHash *gh, const void *key)
{
	return (ghash_lookup_entry(gh, key) != NULL);
}

/**
 * Reset \a gh clearing all entries.
 *
 * \param keyfreefp  Optional callback to free the key.
 * \param valfreefp  Optional callback to free the value.
 * \param nentries_reserve  Optionally reserve the number of members that the hash will hold.
 */
void BLI_ghash_clear_ex(GHash *gh, GHashKeyFreeFP keyfreefp, GHashValFreeFP valfreefp,
                        const unsigned int nentries_reserve)
{
	if (keyfreefp || valfreefp)
		ghash_free_cb(gh, keyfreefp, valfreefp);

	gh->nbuckets = hashsizes[0];  /* gh->cursize */
	gh->nentries = 0;
	gh->cursize = 0;

	if (nentries_reserve) {
		ghash_buckets_reserve(gh, nentries_reserve);
	}

	MEM_freeN(gh->buckets);
	gh->buckets = MEM_callocN(gh->nbuckets * sizeof(*gh->buckets), "buckets");

	BLI_mempool_clear_ex(gh->entrypool, nentries_reserve ? (int)nentries_reserve : -1);
}

/**
 * Wraps #BLI_ghash_clear_ex with zero entries reserved.
 */
void BLI_ghash_clear(GHash *gh, GHashKeyFreeFP keyfreefp, GHashValFreeFP valfreefp)
{
	BLI_ghash_clear_ex(gh, keyfreefp, valfreefp, 0);
}

/**
 * Frees the GHash and its members.
 *
 * \param gh  The GHash to free.
 * \param keyfreefp  Optional callback to free the key.
 * \param valfreefp  Optional callback to free the value.
 */
void BLI_ghash_free(GHash *gh, GHashKeyFreeFP keyfreefp, GHashValFreeFP valfreefp)
{
	BLI_assert((int)gh->nentries == BLI_mempool_count(gh->entrypool));
	if (keyfreefp || valfreefp)
		ghash_free_cb(gh, keyfreefp, valfreefp);

	MEM_freeN(gh->buckets);
	BLI_mempool_destroy(gh->entrypool);
	MEM_freeN(gh);
}

/**
 * Sets a GHash flag.
 */
void BLI_ghash_flag_set(GHash *gh, unsigned int flag)
{
	gh->flag |= flag;
}

/**
 * Clear a GHash flag.
 */
void BLI_ghash_flag_clear(GHash *gh, unsigned int flag)
{
	gh->flag &= ~flag;
}

/** \} */


/* -------------------------------------------------------------------- */
/* GHash Iterator API */

/** \name Iterator API
 * \{ */

/**
 * Create a new GHashIterator. The hash table must not be mutated
 * while the iterator is in use, and the iterator will step exactly
 * BLI_ghash_size(gh) times before becoming done.
 *
 * \param gh The GHash to iterate over.
 * \return Pointer to a new DynStr.
 */
GHashIterator *BLI_ghashIterator_new(GHash *gh)
{
	GHashIterator *ghi = MEM_mallocN(sizeof(*ghi), "ghash iterator");
	BLI_ghashIterator_init(ghi, gh);
	return ghi;
}

/**
 * Init an already allocated GHashIterator. The hash table must not
 * be mutated while the iterator is in use, and the iterator will
 * step exactly BLI_ghash_size(gh) times before becoming done.
 *
 * \param ghi The GHashIterator to initialize.
 * \param gh The GHash to iterate over.
 */
void BLI_ghashIterator_init(GHashIterator *ghi, GHash *gh)
{
	ghi->gh = gh;
	ghi->curEntry = NULL;
	ghi->curBucket = UINT_MAX;  /* wraps to zero */
	if (gh->nentries) {
		while (!ghi->curEntry) {
			ghi->curBucket++;
			if (UNLIKELY(ghi->curBucket == ghi->gh->nbuckets))
				break;
			ghi->curEntry = ghi->gh->buckets[ghi->curBucket];
		}
	}
}

/**
 * Steps the iterator to the next index.
 *
 * \param ghi The iterator.
 */
void BLI_ghashIterator_step(GHashIterator *ghi)
{
	if (ghi->curEntry) {
		ghi->curEntry = ghi->curEntry->next;
		while (!ghi->curEntry) {
			ghi->curBucket++;
			if (ghi->curBucket == ghi->gh->nbuckets)
				break;
			ghi->curEntry = ghi->gh->buckets[ghi->curBucket];
		}
	}
}

/**
 * Free a GHashIterator.
 *
 * \param ghi The iterator to free.
 */
void BLI_ghashIterator_free(GHashIterator *ghi)
{
	MEM_freeN(ghi);
}

/* inline functions now */
#if 0
/**
 * Retrieve the key from an iterator.
 *
 * \param ghi The iterator.
 * \return The key at the current index, or NULL if the
 * iterator is done.
 */
void *BLI_ghashIterator_getKey(GHashIterator *ghi)
{
	return ghi->curEntry->key;
}

/**
 * Retrieve the value from an iterator.
 *
 * \param ghi The iterator.
 * \return The value at the current index, or NULL if the
 * iterator is done.
 */
void *BLI_ghashIterator_getValue(GHashIterator *ghi)
{
	return ghi->curEntry->val;
}

/**
 * Retrieve the value from an iterator.
 *
 * \param ghi The iterator.
 * \return The value at the current index, or NULL if the
 * iterator is done.
 */
void **BLI_ghashIterator_getValue_p(GHashIterator *ghi)
{
	return &ghi->curEntry->val;
}

/**
 * Determine if an iterator is done (has reached the end of
 * the hash table).
 *
 * \param ghi The iterator.
 * \return True if done, False otherwise.
 */
bool BLI_ghashIterator_done(GHashIterator *ghi)
{
	return ghi->curEntry == NULL;
}
#endif

/** \} */


/** \name Generic Key Hash & Comparison Functions
 * \{ */

/***/

#if 0
/* works but slower */
unsigned int BLI_ghashutil_ptrhash(const void *key)
{
	return (unsigned int)(intptr_t)key;
}
#else
/* based python3.3's pointer hashing function */
unsigned int BLI_ghashutil_ptrhash(const void *key)
{
	size_t y = (size_t)key;
	/* bottom 3 or 4 bits are likely to be 0; rotate y by 4 to avoid
	 * excessive hash collisions for dicts and sets */
	y = (y >> 4) | (y << (8 * sizeof(void *) - 4));
	return (unsigned int)y;
}
#endif
int BLI_ghashutil_ptrcmp(const void *a, const void *b)
{
	if (a == b)
		return 0;
	else
		return (a < b) ? -1 : 1;
}

unsigned int BLI_ghashutil_uinthash_v4(const unsigned int key[4])
{
	unsigned int hash;
	hash  = key[0];
	hash *= 37;
	hash += key[1];
	hash *= 37;
	hash += key[2];
	hash *= 37;
	hash += key[3];
	return hash;
}

unsigned int BLI_ghashutil_uinthash(unsigned int key)
{
	key += ~(key << 16);
	key ^=  (key >>  5);
	key +=  (key <<  3);
	key ^=  (key >> 13);
	key += ~(key <<  9);
	key ^=  (key >> 17);

	return key;
}

unsigned int BLI_ghashutil_inthash_p(const void *ptr)
{
	uintptr_t key = (uintptr_t)ptr;

	key += ~(key << 16);
	key ^=  (key >>  5);
	key +=  (key <<  3);
	key ^=  (key >> 13);
	key += ~(key <<  9);
	key ^=  (key >> 17);

	return (unsigned int)(key & 0xffffffff);
}

int BLI_ghashutil_intcmp(const void *a, const void *b)
{
	if (a == b)
		return 0;
	else
		return (a < b) ? -1 : 1;
}

/**
 * This function implements the widely used "djb" hash apparently posted
 * by Daniel Bernstein to comp.lang.c some time ago.  The 32 bit
 * unsigned hash value starts at 5381 and for each byte 'c' in the
 * string, is updated: ``hash = hash * 33 + c``.  This
 * function uses the signed value of each byte.
 *
 * note: this is the same hash method that glib 2.34.0 uses.
 */
unsigned int BLI_ghashutil_strhash_n(const char *key, size_t n)
{
	const signed char *p;
	unsigned int h = 5381;

	for (p = (const signed char *)key; n-- && *p != '\0'; p++) {
		h = (h << 5) + h + (unsigned int)*p;
	}

	return h;
}
unsigned int BLI_ghashutil_strhash_p(const void *ptr)
{
	const signed char *p;
	unsigned int h = 5381;

	for (p = ptr; *p != '\0'; p++) {
		h = (h << 5) + h + (unsigned int)*p;
	}

	return h;
}
int BLI_ghashutil_strcmp(const void *a, const void *b)
{
	return strcmp(a, b);
}

GHashPair *BLI_ghashutil_pairalloc(const void *first, const void *second)
{
	GHashPair *pair = MEM_mallocN(sizeof(GHashPair), "GHashPair");
	pair->first = first;
	pair->second = second;
	return pair;
}

unsigned int BLI_ghashutil_pairhash(const void *ptr)
{
	const GHashPair *pair = ptr;
	unsigned int hash = BLI_ghashutil_ptrhash(pair->first);
	return hash ^ BLI_ghashutil_ptrhash(pair->second);
}

int BLI_ghashutil_paircmp(const void *a, const void *b)
{
	const GHashPair *A = a;
	const GHashPair *B = b;

	int cmp = BLI_ghashutil_ptrcmp(A->first, B->first);
	if (cmp == 0)
		return BLI_ghashutil_ptrcmp(A->second, B->second);
	return cmp;
}

void BLI_ghashutil_pairfree(void *ptr)
{
	MEM_freeN(ptr);
}

/** \} */


/** \name Convenience GHash Creation Functions
 * \{ */

GHash *BLI_ghash_ptr_new_ex(const char *info,
                            const unsigned int nentries_reserve)
{
	return BLI_ghash_new_ex(BLI_ghashutil_ptrhash, BLI_ghashutil_ptrcmp, info,
	                        nentries_reserve);
}
GHash *BLI_ghash_ptr_new(const char *info)
{
	return BLI_ghash_ptr_new_ex(info, 0);
}

GHash *BLI_ghash_str_new_ex(const char *info,
                            const unsigned int nentries_reserve)
{
	return BLI_ghash_new_ex(BLI_ghashutil_strhash_p, BLI_ghashutil_strcmp, info,
	                        nentries_reserve);
}
GHash *BLI_ghash_str_new(const char *info)
{
	return BLI_ghash_str_new_ex(info, 0);
}

GHash *BLI_ghash_int_new_ex(const char *info,
                            const unsigned int nentries_reserve)
{
	return BLI_ghash_new_ex(BLI_ghashutil_inthash_p, BLI_ghashutil_intcmp, info,
	                        nentries_reserve);
}
GHash *BLI_ghash_int_new(const char *info)
{
	return BLI_ghash_int_new_ex(info, 0);
}

GHash *BLI_ghash_pair_new_ex(const char *info,
                             const unsigned int nentries_reserve)
{
	return BLI_ghash_new_ex(BLI_ghashutil_pairhash, BLI_ghashutil_paircmp, info,
	                        nentries_reserve);
}
GHash *BLI_ghash_pair_new(const char *info)
{
	return BLI_ghash_pair_new_ex(info, 0);
}

/** \} */


/* -------------------------------------------------------------------- */
/* GSet API */

/* Use ghash API to give 'set' functionality */

/* TODO: typical set functions
 * isdisjoint/issubset/issuperset/union/intersection/difference etc */

/** \name GSet Functions
 * \{ */
GSet *BLI_gset_new_ex(GSetHashFP hashfp, GSetCmpFP cmpfp, const char *info,
                      const unsigned int nentries_reserve)
{
	GSet *gs = (GSet *)ghash_new(hashfp, cmpfp, info,
	                             nentries_reserve,
	                             sizeof(Entry) - sizeof(void *));
#ifndef NDEBUG
	((GHash *)gs)->flag |= GHASH_FLAG_IS_SET;
#endif
	return gs;
}

GSet *BLI_gset_new(GSetHashFP hashfp, GSetCmpFP cmpfp, const char *info)
{
	return BLI_gset_new_ex(hashfp, cmpfp, info, 0);
}

int BLI_gset_size(GSet *gs)
{
	return (int)((GHash *)gs)->nentries;
}

/**
 * Adds the key to the set (no checks for unique keys!).
 * Matching #BLI_ghash_insert
 */
void BLI_gset_insert(GSet *gs, void *key)
{
	const unsigned int hash = ghash_keyhash((GHash *)gs, key);
	ghash_insert_ex_keyonly((GHash *)gs, key, hash);
}

/**
 * A version of BLI_gset_insert which checks first if the key is in the set.
 * \returns true if a new key has been added.
 *
 * \note GHash has no equivalent to this because typically the value would be different.
 */
bool BLI_gset_add(GSet *gs, void *key)
{
	const unsigned int hash = ghash_keyhash((GHash *)gs, key);
	Entry *e = ghash_lookup_entry_ex((GHash *)gs, key, hash);
	if (e) {
		return false;
	}
	else {
		ghash_insert_ex_keyonly((GHash *)gs, key, hash);
		return true;
	}
}

/**
 * Adds the key to the set (duplicates are managed).
 * Matching #BLI_ghash_reinsert
 *
 * \returns true if a new key has been added.
 */
bool BLI_gset_reinsert(GSet *gs, void *key, GSetKeyFreeFP keyfreefp)
{
	const unsigned int hash = ghash_keyhash((GHash *)gs, key);
	Entry *e = ghash_lookup_entry_ex((GHash *)gs, key, hash);
	if (e) {
		if (keyfreefp) keyfreefp(e->key);
		e->key = key;
		return false;
	}
	else {
		ghash_insert_ex_keyonly((GHash *)gs, key, hash);
		return true;
	}
}

bool BLI_gset_remove(GSet *gs, void *key, GSetKeyFreeFP keyfreefp)
{
	return BLI_ghash_remove((GHash *)gs, key, keyfreefp, NULL);
}


bool BLI_gset_haskey(GSet *gs, const void *key)
{
	return (ghash_lookup_entry((GHash *)gs, key) != NULL);
}

void BLI_gset_clear_ex(GSet *gs, GSetKeyFreeFP keyfreefp,
                       const unsigned int nentries_reserve)
{
	BLI_ghash_clear_ex((GHash *)gs, keyfreefp, NULL,
	                   nentries_reserve);
}

void BLI_gset_clear(GSet *gs, GSetKeyFreeFP keyfreefp)
{
	BLI_ghash_clear((GHash *)gs, keyfreefp, NULL);
}

void BLI_gset_free(GSet *gs, GSetKeyFreeFP keyfreefp)
{
	BLI_ghash_free((GHash *)gs, keyfreefp, NULL);
}
/** \} */


/** \name Convenience GSet Creation Functions
 * \{ */

GSet *BLI_gset_ptr_new_ex(const char *info,
                          const unsigned int nentries_reserve)
{
	return BLI_gset_new_ex(BLI_ghashutil_ptrhash, BLI_ghashutil_ptrcmp, info,
	                       nentries_reserve);
}
GSet *BLI_gset_ptr_new(const char *info)
{
	return BLI_gset_ptr_new_ex(info, 0);
}

GSet *BLI_gset_pair_new_ex(const char *info,
                             const unsigned int nentries_reserve)
{
	return BLI_gset_new_ex(BLI_ghashutil_pairhash, BLI_ghashutil_paircmp, info,
	                        nentries_reserve);
}
GSet *BLI_gset_pair_new(const char *info)
{
	return BLI_gset_pair_new_ex(info, 0);
}

/** \} */