c_src/hash.h - couchdb-khash - Git at Google

 /*
  * Hash Table Data Type
  * Copyright (C) 1997 Kaz Kylheku <kaz@ashi.footprints.net>
  *
  * Free Software License:
  *
  * All rights are reserved by the author, with the following exceptions:
  * Permission is granted to freely reproduce and distribute this software,
  * possibly in exchange for a fee, provided that this copyright notice appears
  * intact. Permission is also granted to adapt this software to produce
  * derivative works, as long as the modified versions carry this copyright
  * notice and additional notices stating that the work has been modified.
  * This source code may be translated into executable form and incorporated
  * into proprietary software; there is no requirement for such software to
  * contain a copyright notice related to this source.
  *
  * $Id: hash.h,v 1.22.2.7 2000/11/13 01:36:45 kaz Exp $
  * $Name: kazlib_1_20 $
  */

 #ifndef HASH_H
 #define HASH_H

 #include <limits.h>
 #ifdef KAZLIB_SIDEEFFECT_DEBUG
 #include "sfx.h"
 #endif

 /*
  * Blurb for inclusion into C++ translation units
  */

 #ifdef __cplusplus
 extern "C" {
 #endif

 typedef unsigned long hashcount_t;
 #define HASHCOUNT_T_MAX ULONG_MAX

 typedef unsigned long hash_val_t;
 #define HASH_VAL_T_MAX ULONG_MAX

 extern int hash_val_t_bit;

 #ifndef HASH_VAL_T_BIT
 #define HASH_VAL_T_BIT ((int) hash_val_t_bit)
 #endif

 /*
  * Hash chain node structure.
  * Notes:
  * 1. This preprocessing directive is for debugging purposes.  The effect is
  *    that if the preprocessor symbol KAZLIB_OPAQUE_DEBUG is defined prior to the
  *    inclusion of this header,  then the structure shall be declared as having
  *    the single member   int __OPAQUE__.   This way, any attempts by the
  *    client code to violate the principles of information hiding (by accessing
  *    the structure directly) can be diagnosed at translation time. However,
  *    note the resulting compiled unit is not suitable for linking.
  * 2. This is a pointer to the next node in the chain. In the last node of a
  *    chain, this pointer is null.
  * 3. The key is a pointer to some user supplied data that contains a unique
  *    identifier for each hash node in a given table. The interpretation of
  *    the data is up to the user. When creating or initializing a hash table,
  *    the user must supply a pointer to a function for comparing two keys,
  *    and a pointer to a function for hashing a key into a numeric value.
  * 4. The value is a user-supplied pointer to void which may refer to
  *    any data object. It is not interpreted in any way by the hashing
  *    module.
  * 5. The hashed key is stored in each node so that we don't have to rehash
  *    each key when the table must grow or shrink.
  */

 typedef struct hnode_t {
     #if defined(HASH_IMPLEMENTATION) || !defined(KAZLIB_OPAQUE_DEBUG)	/* 1 */
     struct hnode_t *hash_next;		/* 2 */
     const void *hash_key;		/* 3 */
     void *hash_data;			/* 4 */
     hash_val_t hash_hkey;		/* 5 */
     #else
     int hash_dummy;
     #endif
 } hnode_t;

 /*
  * The comparison function pointer type. A comparison function takes two keys
  * and produces a value of -1 if the left key is less than the right key, a
  * value of 0 if the keys are equal, and a value of 1 if the left key is
  * greater than the right key.
  */

 typedef int (*hash_comp_t)(const void *, const void *);

 /*
  * The hashing function performs some computation on a key and produces an
  * integral value of type hash_val_t based on that key. For best results, the
  * function should have a good randomness properties in *all* significant bits
  * over the set of keys that are being inserted into a given hash table. In
  * particular, the most significant bits of hash_val_t are most significant to
  * the hash module. Only as the hash table expands are less significant bits
  * examined. Thus a function that has good distribution in its upper bits but
  * not lower is preferrable to one that has poor distribution in the upper bits
  * but not the lower ones.
  */

 typedef hash_val_t (*hash_fun_t)(const void *);

 /*
  * allocator functions
  */

 typedef hnode_t *(*hnode_alloc_t)(void *);
 typedef void (*hnode_free_t)(hnode_t *, void *);

 /*
  * This is the hash table control structure. It keeps track of information
  * about a hash table, as well as the hash table itself.
  * Notes:
  * 1.  Pointer to the hash table proper. The table is an array of pointers to
  *     hash nodes (of type hnode_t). If the table is empty, every element of
  *     this table is a null pointer. A non-null entry points to the first
  *     element of a chain of nodes.
  * 2.  This member keeps track of the size of the hash table---that is, the
  *     number of chain pointers.
  * 3.  The count member maintains the number of elements that are presently
  *     in the hash table.
  * 4.  The maximum count is the greatest number of nodes that can populate this
  *     table. If the table contains this many nodes, no more can be inserted,
  *     and the hash_isfull() function returns true.
  * 5.  The high mark is a population threshold, measured as a number of nodes,
  *     which, if exceeded, will trigger a table expansion. Only dynamic hash
  *     tables are subject to this expansion.
  * 6.  The low mark is a minimum population threshold, measured as a number of
  *     nodes. If the table population drops below this value, a table shrinkage
  *     will occur. Only dynamic tables are subject to this reduction.  No table
  *     will shrink beneath a certain absolute minimum number of nodes.
  * 7.  This is the a pointer to the hash table's comparison function. The
  *     function is set once at initialization or creation time.
  * 8.  Pointer to the table's hashing function, set once at creation or
  *     initialization time.
  * 9.  The current hash table mask. If the size of the hash table is 2^N,
  *     this value has its low N bits set to 1, and the others clear. It is used
  *     to select bits from the result of the hashing function to compute an
  *     index into the table.
  * 10. A flag which indicates whether the table is to be dynamically resized. It
  *     is set to 1 in dynamically allocated tables, 0 in tables that are
  *     statically allocated.
  */

 typedef struct hash_t {
     #if defined(HASH_IMPLEMENTATION) || !defined(KAZLIB_OPAQUE_DEBUG)
     struct hnode_t **hash_table;		/* 1 */
     hashcount_t hash_nchains;			/* 2 */
     hashcount_t hash_nodecount;			/* 3 */
     hashcount_t hash_maxcount;			/* 4 */
     hashcount_t hash_highmark;			/* 5 */
     hashcount_t hash_lowmark;			/* 6 */
     hash_comp_t hash_compare;			/* 7 */
     hash_fun_t hash_function;			/* 8 */
     hnode_alloc_t hash_allocnode;
     hnode_free_t hash_freenode;
     void *hash_context;
     hash_val_t hash_mask;			/* 9 */
     int hash_dynamic;				/* 10 */
     #else
     int hash_dummy;
     #endif
 } hash_t;

 /*
  * Hash scanner structure, used for traversals of the data structure.
  * Notes:
  * 1. Pointer to the hash table that is being traversed.
  * 2. Reference to the current chain in the table being traversed (the chain
  *    that contains the next node that shall be retrieved).
  * 3. Pointer to the node that will be retrieved by the subsequent call to
  *    hash_scan_next().
  */

 typedef struct hscan_t {
     #if defined(HASH_IMPLEMENTATION) || !defined(KAZLIB_OPAQUE_DEBUG)
     hash_t *hash_table;		/* 1 */
     hash_val_t hash_chain;	/* 2 */
     hnode_t *hash_next;		/* 3 */
     #else
     int hash_dummy;
     #endif
 } hscan_t;

 extern hash_t *kl_hash_create(hashcount_t, hash_comp_t, hash_fun_t);
 extern void kl_hash_set_allocator(hash_t *, hnode_alloc_t, hnode_free_t, void *);
 extern void kl_hash_destroy(hash_t *);
 extern void kl_hash_free_nodes(hash_t *);
 extern void kl_hash_free(hash_t *);
 extern hash_t *kl_hash_init(hash_t *, hashcount_t, hash_comp_t,
 	hash_fun_t, hnode_t **, hashcount_t);
 extern void kl_hash_insert(hash_t *, hnode_t *, const void *);
 extern hnode_t *kl_hash_lookup(hash_t *, const void *);
 extern hnode_t *kl_hash_delete(hash_t *, hnode_t *);
 extern int kl_hash_alloc_insert(hash_t *, const void *, void *);
 extern void kl_hash_delete_free(hash_t *, hnode_t *);

 extern void kl_hnode_put(hnode_t *, void *);
 extern void *kl_hnode_get(hnode_t *);
 extern const void *kl_hnode_getkey(hnode_t *);
 extern hashcount_t kl_hash_count(hash_t *);
 extern hashcount_t kl_hash_size(hash_t *);

 extern int kl_hash_isfull(hash_t *);
 extern int kl_hash_isempty(hash_t *);

 extern void kl_hash_scan_begin(hscan_t *, hash_t *);
 extern hnode_t *kl_hash_scan_next(hscan_t *);
 extern hnode_t *kl_hash_scan_delete(hash_t *, hnode_t *);
 extern void kl_hash_scan_delfree(hash_t *, hnode_t *);

 extern int kl_hash_verify(hash_t *);

 extern hnode_t *kl_hnode_create(void *);
 extern hnode_t *kl_hnode_init(hnode_t *, void *);
 extern void kl_hnode_destroy(hnode_t *);

 #if defined(HASH_IMPLEMENTATION) || !defined(KAZLIB_OPAQUE_DEBUG)
 #ifdef KAZLIB_SIDEEFFECT_DEBUG
 #define kl_hash_isfull(H) (SFX_CHECK(H)->hash_nodecount == (H)->hash_maxcount)
 #else
 #define kl_hash_isfull(H) ((H)->hash_nodecount == (H)->hash_maxcount)
 #endif
 #define kl_hash_isempty(H) ((H)->hash_nodecount == 0)
 #define kl_hash_count(H) ((H)->hash_nodecount)
 #define kl_hash_size(H) ((H)->hash_nchains)
 #define kl_hnode_get(N) ((N)->hash_data)
 #define kl_hnode_getkey(N) ((N)->hash_key)
 #define kl_hnode_put(N, V) ((N)->hash_data = (V))
 #endif

 #ifdef __cplusplus
 }
 #endif

 #endif
	/*
	* Hash Table Data Type
	* Copyright (C) 1997 Kaz Kylheku <kaz@ashi.footprints.net>
	*
	* Free Software License:
	*
	* All rights are reserved by the author, with the following exceptions:
	* Permission is granted to freely reproduce and distribute this software,
	* possibly in exchange for a fee, provided that this copyright notice appears
	* intact. Permission is also granted to adapt this software to produce
	* derivative works, as long as the modified versions carry this copyright
	* notice and additional notices stating that the work has been modified.
	* This source code may be translated into executable form and incorporated
	* into proprietary software; there is no requirement for such software to
	* contain a copyright notice related to this source.
	*
	* $Id: hash.h,v 1.22.2.7 2000/11/13 01:36:45 kaz Exp $
	* $Name: kazlib_1_20 $
	*/

	#ifndef HASH_H
	#define HASH_H

	#include <limits.h>
	#ifdef KAZLIB_SIDEEFFECT_DEBUG
	#include "sfx.h"
	#endif

	/*
	* Blurb for inclusion into C++ translation units
	*/

	#ifdef __cplusplus
	extern "C" {
	#endif

	typedef unsigned long hashcount_t;
	#define HASHCOUNT_T_MAX ULONG_MAX

	typedef unsigned long hash_val_t;
	#define HASH_VAL_T_MAX ULONG_MAX

	extern int hash_val_t_bit;

	#ifndef HASH_VAL_T_BIT
	#define HASH_VAL_T_BIT ((int) hash_val_t_bit)
	#endif

	/*
	* Hash chain node structure.
	* Notes:
	* 1. This preprocessing directive is for debugging purposes. The effect is
	* that if the preprocessor symbol KAZLIB_OPAQUE_DEBUG is defined prior to the
	* inclusion of this header, then the structure shall be declared as having
	* the single member int __OPAQUE__. This way, any attempts by the
	* client code to violate the principles of information hiding (by accessing
	* the structure directly) can be diagnosed at translation time. However,
	* note the resulting compiled unit is not suitable for linking.
	* 2. This is a pointer to the next node in the chain. In the last node of a
	* chain, this pointer is null.
	* 3. The key is a pointer to some user supplied data that contains a unique
	* identifier for each hash node in a given table. The interpretation of
	* the data is up to the user. When creating or initializing a hash table,
	* the user must supply a pointer to a function for comparing two keys,
	* and a pointer to a function for hashing a key into a numeric value.
	* 4. The value is a user-supplied pointer to void which may refer to
	* any data object. It is not interpreted in any way by the hashing
	* module.
	* 5. The hashed key is stored in each node so that we don't have to rehash
	* each key when the table must grow or shrink.
	*/

	typedef struct hnode_t {
	#if defined(HASH_IMPLEMENTATION) \|\| !defined(KAZLIB_OPAQUE_DEBUG) /* 1 */
	struct hnode_t hash_next; / 2 */
	const void hash_key; / 3 */
	void hash_data; / 4 */
	hash_val_t hash_hkey; /* 5 */
	#else
	int hash_dummy;
	#endif
	} hnode_t;

	/*
	* The comparison function pointer type. A comparison function takes two keys
	* and produces a value of -1 if the left key is less than the right key, a
	* value of 0 if the keys are equal, and a value of 1 if the left key is
	* greater than the right key.
	*/

	typedef int (hash_comp_t)(const void , const void *);

	/*
	* The hashing function performs some computation on a key and produces an
	* integral value of type hash_val_t based on that key. For best results, the
	* function should have a good randomness properties in all significant bits
	* over the set of keys that are being inserted into a given hash table. In
	* particular, the most significant bits of hash_val_t are most significant to
	* the hash module. Only as the hash table expands are less significant bits
	* examined. Thus a function that has good distribution in its upper bits but
	* not lower is preferrable to one that has poor distribution in the upper bits
	* but not the lower ones.
	*/

	typedef hash_val_t (hash_fun_t)(const void );

	/*
	* allocator functions
	*/

	typedef hnode_t (hnode_alloc_t)(void *);
	typedef void (hnode_free_t)(hnode_t , void *);

	/*
	* This is the hash table control structure. It keeps track of information
	* about a hash table, as well as the hash table itself.
	* Notes:
	* 1. Pointer to the hash table proper. The table is an array of pointers to
	* hash nodes (of type hnode_t). If the table is empty, every element of
	* this table is a null pointer. A non-null entry points to the first
	* element of a chain of nodes.
	* 2. This member keeps track of the size of the hash table---that is, the
	* number of chain pointers.
	* 3. The count member maintains the number of elements that are presently
	* in the hash table.
	* 4. The maximum count is the greatest number of nodes that can populate this
	* table. If the table contains this many nodes, no more can be inserted,
	* and the hash_isfull() function returns true.
	* 5. The high mark is a population threshold, measured as a number of nodes,
	* which, if exceeded, will trigger a table expansion. Only dynamic hash
	* tables are subject to this expansion.
	* 6. The low mark is a minimum population threshold, measured as a number of
	* nodes. If the table population drops below this value, a table shrinkage
	* will occur. Only dynamic tables are subject to this reduction. No table
	* will shrink beneath a certain absolute minimum number of nodes.
	* 7. This is the a pointer to the hash table's comparison function. The
	* function is set once at initialization or creation time.
	* 8. Pointer to the table's hashing function, set once at creation or
	* initialization time.
	* 9. The current hash table mask. If the size of the hash table is 2^N,
	* this value has its low N bits set to 1, and the others clear. It is used
	* to select bits from the result of the hashing function to compute an
	* index into the table.
	* 10. A flag which indicates whether the table is to be dynamically resized. It
	* is set to 1 in dynamically allocated tables, 0 in tables that are
	* statically allocated.
	*/

	typedef struct hash_t {
	#if defined(HASH_IMPLEMENTATION) \|\| !defined(KAZLIB_OPAQUE_DEBUG)
	struct hnode_t *hash_table; / 1 */
	hashcount_t hash_nchains; /* 2 */
	hashcount_t hash_nodecount; /* 3 */
	hashcount_t hash_maxcount; /* 4 */
	hashcount_t hash_highmark; /* 5 */
	hashcount_t hash_lowmark; /* 6 */
	hash_comp_t hash_compare; /* 7 */
	hash_fun_t hash_function; /* 8 */
	hnode_alloc_t hash_allocnode;
	hnode_free_t hash_freenode;
	void *hash_context;
	hash_val_t hash_mask; /* 9 */
	int hash_dynamic; /* 10 */
	#else
	int hash_dummy;
	#endif
	} hash_t;

	/*
	* Hash scanner structure, used for traversals of the data structure.
	* Notes:
	* 1. Pointer to the hash table that is being traversed.
	* 2. Reference to the current chain in the table being traversed (the chain
	* that contains the next node that shall be retrieved).
	* 3. Pointer to the node that will be retrieved by the subsequent call to
	* hash_scan_next().
	*/

	typedef struct hscan_t {
	#if defined(HASH_IMPLEMENTATION) \|\| !defined(KAZLIB_OPAQUE_DEBUG)
	hash_t hash_table; / 1 */
	hash_val_t hash_chain; /* 2 */
	hnode_t hash_next; / 3 */
	#else
	int hash_dummy;
	#endif
	} hscan_t;

	extern hash_t *kl_hash_create(hashcount_t, hash_comp_t, hash_fun_t);
	extern void kl_hash_set_allocator(hash_t , hnode_alloc_t, hnode_free_t, void );
	extern void kl_hash_destroy(hash_t *);
	extern void kl_hash_free_nodes(hash_t *);
	extern void kl_hash_free(hash_t *);
	extern hash_t kl_hash_init(hash_t , hashcount_t, hash_comp_t,
	hash_fun_t, hnode_t **, hashcount_t);
	extern void kl_hash_insert(hash_t , hnode_t , const void *);
	extern hnode_t kl_hash_lookup(hash_t , const void *);
	extern hnode_t kl_hash_delete(hash_t , hnode_t *);
	extern int kl_hash_alloc_insert(hash_t , const void , void *);
	extern void kl_hash_delete_free(hash_t , hnode_t );

	extern void kl_hnode_put(hnode_t , void );
	extern void kl_hnode_get(hnode_t );
	extern const void kl_hnode_getkey(hnode_t );
	extern hashcount_t kl_hash_count(hash_t *);
	extern hashcount_t kl_hash_size(hash_t *);

	extern int kl_hash_isfull(hash_t *);
	extern int kl_hash_isempty(hash_t *);

	extern void kl_hash_scan_begin(hscan_t , hash_t );
	extern hnode_t kl_hash_scan_next(hscan_t );
	extern hnode_t kl_hash_scan_delete(hash_t , hnode_t *);
	extern void kl_hash_scan_delfree(hash_t , hnode_t );

	extern int kl_hash_verify(hash_t *);

	extern hnode_t kl_hnode_create(void );
	extern hnode_t kl_hnode_init(hnode_t , void *);
	extern void kl_hnode_destroy(hnode_t *);

	#if defined(HASH_IMPLEMENTATION) \|\| !defined(KAZLIB_OPAQUE_DEBUG)
	#ifdef KAZLIB_SIDEEFFECT_DEBUG
	#define kl_hash_isfull(H) (SFX_CHECK(H)->hash_nodecount == (H)->hash_maxcount)
	#else
	#define kl_hash_isfull(H) ((H)->hash_nodecount == (H)->hash_maxcount)
	#endif
	#define kl_hash_isempty(H) ((H)->hash_nodecount == 0)
	#define kl_hash_count(H) ((H)->hash_nodecount)
	#define kl_hash_size(H) ((H)->hash_nchains)
	#define kl_hnode_get(N) ((N)->hash_data)
	#define kl_hnode_getkey(N) ((N)->hash_key)
	#define kl_hnode_put(N, V) ((N)->hash_data = (V))
	#endif

	#ifdef __cplusplus
	}
	#endif

	#endif