tools/perf/util/hashmap.h - pub/scm/linux/kernel/git/hyperv/linux - Git at Google

 /* SPDX-License-Identifier: (LGPL-2.1 OR BSD-2-Clause) */

 /*
  * Generic non-thread safe hash map implementation.
  *
  * Copyright (c) 2019 Facebook
  */
 #ifndef __LIBBPF_HASHMAP_H
 #define __LIBBPF_HASHMAP_H

 #include <stdbool.h>
 #include <stddef.h>
 #include <limits.h>

 static inline size_t hash_bits(size_t h, int bits)
 {
 	/* shuffle bits and return requested number of upper bits */
 	if (bits == 0)
 		return 0;

 #if (__SIZEOF_SIZE_T__ == __SIZEOF_LONG_LONG__)
 	/* LP64 case */
 	return (h * 11400714819323198485llu) >> (__SIZEOF_LONG_LONG__ * 8 - bits);
 #elif (__SIZEOF_SIZE_T__ <= __SIZEOF_LONG__)
 	return (h * 2654435769lu) >> (__SIZEOF_LONG__ * 8 - bits);
 #else
 #	error "Unsupported size_t size"
 #endif
 }

 /* generic C-string hashing function */
 static inline size_t str_hash(const char *s)
 {
 	size_t h = 0;

 	while (*s) {
 		h = h * 31 + *s;
 		s++;
 	}
 	return h;
 }

 typedef size_t (*hashmap_hash_fn)(long key, void *ctx);
 typedef bool (*hashmap_equal_fn)(long key1, long key2, void *ctx);

 /*
  * Hashmap interface is polymorphic, keys and values could be either
  * long-sized integers or pointers, this is achieved as follows:
  * - interface functions that operate on keys and values are hidden
  *   behind auxiliary macros, e.g. hashmap_insert <-> hashmap__insert;
  * - these auxiliary macros cast the key and value parameters as
  *   long or long *, so the user does not have to specify the casts explicitly;
  * - for pointer parameters (e.g. old_key) the size of the pointed
  *   type is verified by hashmap_cast_ptr using _Static_assert;
  * - when iterating using hashmap__for_each_* forms
  *   hasmap_entry->key should be used for integer keys and
  *   hasmap_entry->pkey should be used for pointer keys,
  *   same goes for values.
  */
 struct hashmap_entry {
 	union {
 		long key;
 		const void *pkey;
 	};
 	union {
 		long value;
 		void *pvalue;
 	};
 	struct hashmap_entry *next;
 };

 struct hashmap {
 	hashmap_hash_fn hash_fn;
 	hashmap_equal_fn equal_fn;
 	void *ctx;

 	struct hashmap_entry **buckets;
 	size_t cap;
 	size_t cap_bits;
 	size_t sz;
 };

 void hashmap__init(struct hashmap *map, hashmap_hash_fn hash_fn,
 		   hashmap_equal_fn equal_fn, void *ctx);
 struct hashmap *hashmap__new(hashmap_hash_fn hash_fn,
 			     hashmap_equal_fn equal_fn,
 			     void *ctx);
 void hashmap__clear(struct hashmap *map);
 void hashmap__free(struct hashmap *map);

 size_t hashmap__size(const struct hashmap *map);
 size_t hashmap__capacity(const struct hashmap *map);

 /*
  * Hashmap insertion strategy:
  * - HASHMAP_ADD - only add key/value if key doesn't exist yet;
  * - HASHMAP_SET - add key/value pair if key doesn't exist yet; otherwise,
  *   update value;
  * - HASHMAP_UPDATE - update value, if key already exists; otherwise, do
  *   nothing and return -ENOENT;
  * - HASHMAP_APPEND - always add key/value pair, even if key already exists.
  *   This turns hashmap into a multimap by allowing multiple values to be
  *   associated with the same key. Most useful read API for such hashmap is
  *   hashmap__for_each_key_entry() iteration. If hashmap__find() is still
  *   used, it will return last inserted key/value entry (first in a bucket
  *   chain).
  */
 enum hashmap_insert_strategy {
 	HASHMAP_ADD,
 	HASHMAP_SET,
 	HASHMAP_UPDATE,
 	HASHMAP_APPEND,
 };

 #define hashmap_cast_ptr(p) ({								\
 	_Static_assert((__builtin_constant_p((p)) ? (p) == NULL : 0) ||			\
 				sizeof(*(p)) == sizeof(long),				\
 		       #p " pointee should be a long-sized integer or a pointer");	\
 	(long *)(p);									\
 })

 /*
  * hashmap__insert() adds key/value entry w/ various semantics, depending on
  * provided strategy value. If a given key/value pair replaced already
  * existing key/value pair, both old key and old value will be returned
  * through old_key and old_value to allow calling code do proper memory
  * management.
  */
 int hashmap_insert(struct hashmap *map, long key, long value,
 		   enum hashmap_insert_strategy strategy,
 		   long *old_key, long *old_value);

 #define hashmap__insert(map, key, value, strategy, old_key, old_value) \
 	hashmap_insert((map), (long)(key), (long)(value), (strategy),  \
 		       hashmap_cast_ptr(old_key),		       \
 		       hashmap_cast_ptr(old_value))

 #define hashmap__add(map, key, value) \
 	hashmap__insert((map), (key), (value), HASHMAP_ADD, NULL, NULL)

 #define hashmap__set(map, key, value, old_key, old_value) \
 	hashmap__insert((map), (key), (value), HASHMAP_SET, (old_key), (old_value))

 #define hashmap__update(map, key, value, old_key, old_value) \
 	hashmap__insert((map), (key), (value), HASHMAP_UPDATE, (old_key), (old_value))

 #define hashmap__append(map, key, value) \
 	hashmap__insert((map), (key), (value), HASHMAP_APPEND, NULL, NULL)

 bool hashmap_delete(struct hashmap *map, long key, long *old_key, long *old_value);

 #define hashmap__delete(map, key, old_key, old_value)		       \
 	hashmap_delete((map), (long)(key),			       \
 		       hashmap_cast_ptr(old_key),		       \
 		       hashmap_cast_ptr(old_value))

 bool hashmap_find(const struct hashmap *map, long key, long *value);

 #define hashmap__find(map, key, value) \
 	hashmap_find((map), (long)(key), hashmap_cast_ptr(value))

 /*
  * hashmap__for_each_entry - iterate over all entries in hashmap
  * @map: hashmap to iterate
  * @cur: struct hashmap_entry * used as a loop cursor
  * @bkt: integer used as a bucket loop cursor
  */
 #define hashmap__for_each_entry(map, cur, bkt)				    \
 	for (bkt = 0; bkt < map->cap; bkt++)				    \
 		for (cur = map->buckets[bkt]; cur; cur = cur->next)

 /*
  * hashmap__for_each_entry_safe - iterate over all entries in hashmap, safe
  * against removals
  * @map: hashmap to iterate
  * @cur: struct hashmap_entry * used as a loop cursor
  * @tmp: struct hashmap_entry * used as a temporary next cursor storage
  * @bkt: integer used as a bucket loop cursor
  */
 #define hashmap__for_each_entry_safe(map, cur, tmp, bkt)		    \
 	for (bkt = 0; bkt < map->cap; bkt++)				    \
 		for (cur = map->buckets[bkt];				    \
 		     cur && ({tmp = cur->next; true; });		    \
 		     cur = tmp)

 /*
  * hashmap__for_each_key_entry - iterate over entries associated with given key
  * @map: hashmap to iterate
  * @cur: struct hashmap_entry * used as a loop cursor
  * @key: key to iterate entries for
  */
 #define hashmap__for_each_key_entry(map, cur, _key)			    \
 	for (cur = map->buckets						    \
 		     ? map->buckets[hash_bits(map->hash_fn((_key), map->ctx), map->cap_bits)] \
 		     : NULL;						    \
 	     cur;							    \
 	     cur = cur->next)						    \
 		if (map->equal_fn(cur->key, (_key), map->ctx))

 #define hashmap__for_each_key_entry_safe(map, cur, tmp, _key)		    \
 	for (cur = map->buckets						    \
 		     ? map->buckets[hash_bits(map->hash_fn((_key), map->ctx), map->cap_bits)] \
 		     : NULL;						    \
 	     cur && ({ tmp = cur->next; true; });			    \
 	     cur = tmp)							    \
 		if (map->equal_fn(cur->key, (_key), map->ctx))

 #endif /* __LIBBPF_HASHMAP_H */
	/* SPDX-License-Identifier: (LGPL-2.1 OR BSD-2-Clause) */

	/*
	* Generic non-thread safe hash map implementation.
	*
	* Copyright (c) 2019 Facebook
	*/
	#ifndef __LIBBPF_HASHMAP_H
	#define __LIBBPF_HASHMAP_H

	#include <stdbool.h>
	#include <stddef.h>
	#include <limits.h>

	static inline size_t hash_bits(size_t h, int bits)
	{
	/* shuffle bits and return requested number of upper bits */
	if (bits == 0)
	return 0;

	#if (__SIZEOF_SIZE_T__ == __SIZEOF_LONG_LONG__)
	/* LP64 case */
	return (h * 11400714819323198485llu) >> (__SIZEOF_LONG_LONG__ * 8 - bits);
	#elif (__SIZEOF_SIZE_T__ <= __SIZEOF_LONG__)
	return (h * 2654435769lu) >> (__SIZEOF_LONG__ * 8 - bits);
	#else
	# error "Unsupported size_t size"
	#endif
	}

	/* generic C-string hashing function */
	static inline size_t str_hash(const char *s)
	{
	size_t h = 0;

	while (*s) {
	h = h * 31 + *s;
	s++;
	}
	return h;
	}

	typedef size_t (hashmap_hash_fn)(long key, void ctx);
	typedef bool (hashmap_equal_fn)(long key1, long key2, void ctx);

	/*
	* Hashmap interface is polymorphic, keys and values could be either
	* long-sized integers or pointers, this is achieved as follows:
	* - interface functions that operate on keys and values are hidden
	* behind auxiliary macros, e.g. hashmap_insert <-> hashmap__insert;
	* - these auxiliary macros cast the key and value parameters as
	* long or long *, so the user does not have to specify the casts explicitly;
	* - for pointer parameters (e.g. old_key) the size of the pointed
	* type is verified by hashmap_cast_ptr using _Static_assert;
	* - when iterating using hashmap__for_each_* forms
	* hasmap_entry->key should be used for integer keys and
	* hasmap_entry->pkey should be used for pointer keys,
	* same goes for values.
	*/
	struct hashmap_entry {
	union {
	long key;
	const void *pkey;
	};
	union {
	long value;
	void *pvalue;
	};
	struct hashmap_entry *next;
	};

	struct hashmap {
	hashmap_hash_fn hash_fn;
	hashmap_equal_fn equal_fn;
	void *ctx;

	struct hashmap_entry **buckets;
	size_t cap;
	size_t cap_bits;
	size_t sz;
	};

	void hashmap__init(struct hashmap *map, hashmap_hash_fn hash_fn,
	hashmap_equal_fn equal_fn, void *ctx);
	struct hashmap *hashmap__new(hashmap_hash_fn hash_fn,
	hashmap_equal_fn equal_fn,
	void *ctx);
	void hashmap__clear(struct hashmap *map);
	void hashmap__free(struct hashmap *map);

	size_t hashmap__size(const struct hashmap *map);
	size_t hashmap__capacity(const struct hashmap *map);

	/*
	* Hashmap insertion strategy:
	* - HASHMAP_ADD - only add key/value if key doesn't exist yet;
	* - HASHMAP_SET - add key/value pair if key doesn't exist yet; otherwise,
	* update value;
	* - HASHMAP_UPDATE - update value, if key already exists; otherwise, do
	* nothing and return -ENOENT;
	* - HASHMAP_APPEND - always add key/value pair, even if key already exists.
	* This turns hashmap into a multimap by allowing multiple values to be
	* associated with the same key. Most useful read API for such hashmap is
	* hashmap__for_each_key_entry() iteration. If hashmap__find() is still
	* used, it will return last inserted key/value entry (first in a bucket
	* chain).
	*/
	enum hashmap_insert_strategy {
	HASHMAP_ADD,
	HASHMAP_SET,
	HASHMAP_UPDATE,
	HASHMAP_APPEND,
	};

	#define hashmap_cast_ptr(p) ({ \
	_Static_assert((__builtin_constant_p((p)) ? (p) == NULL : 0) \|\| \
	sizeof(*(p)) == sizeof(long), \
	#p " pointee should be a long-sized integer or a pointer"); \
	(long *)(p); \
	})

	/*
	* hashmap__insert() adds key/value entry w/ various semantics, depending on
	* provided strategy value. If a given key/value pair replaced already
	* existing key/value pair, both old key and old value will be returned
	* through old_key and old_value to allow calling code do proper memory
	* management.
	*/
	int hashmap_insert(struct hashmap *map, long key, long value,
	enum hashmap_insert_strategy strategy,
	long old_key, long old_value);

	#define hashmap__insert(map, key, value, strategy, old_key, old_value) \
	hashmap_insert((map), (long)(key), (long)(value), (strategy), \
	hashmap_cast_ptr(old_key), \
	hashmap_cast_ptr(old_value))

	#define hashmap__add(map, key, value) \
	hashmap__insert((map), (key), (value), HASHMAP_ADD, NULL, NULL)

	#define hashmap__set(map, key, value, old_key, old_value) \
	hashmap__insert((map), (key), (value), HASHMAP_SET, (old_key), (old_value))

	#define hashmap__update(map, key, value, old_key, old_value) \
	hashmap__insert((map), (key), (value), HASHMAP_UPDATE, (old_key), (old_value))

	#define hashmap__append(map, key, value) \
	hashmap__insert((map), (key), (value), HASHMAP_APPEND, NULL, NULL)

	bool hashmap_delete(struct hashmap map, long key, long old_key, long *old_value);

	#define hashmap__delete(map, key, old_key, old_value) \
	hashmap_delete((map), (long)(key), \
	hashmap_cast_ptr(old_key), \
	hashmap_cast_ptr(old_value))

	bool hashmap_find(const struct hashmap map, long key, long value);

	#define hashmap__find(map, key, value) \
	hashmap_find((map), (long)(key), hashmap_cast_ptr(value))

	/*
	* hashmap__for_each_entry - iterate over all entries in hashmap
	* @map: hashmap to iterate
	* @cur: struct hashmap_entry * used as a loop cursor
	* @bkt: integer used as a bucket loop cursor
	*/
	#define hashmap__for_each_entry(map, cur, bkt) \
	for (bkt = 0; bkt < map->cap; bkt++) \
	for (cur = map->buckets[bkt]; cur; cur = cur->next)

	/*
	* hashmap__for_each_entry_safe - iterate over all entries in hashmap, safe
	* against removals
	* @map: hashmap to iterate
	* @cur: struct hashmap_entry * used as a loop cursor
	* @tmp: struct hashmap_entry * used as a temporary next cursor storage
	* @bkt: integer used as a bucket loop cursor
	*/
	#define hashmap__for_each_entry_safe(map, cur, tmp, bkt) \
	for (bkt = 0; bkt < map->cap; bkt++) \
	for (cur = map->buckets[bkt]; \
	cur && ({tmp = cur->next; true; }); \
	cur = tmp)

	/*
	* hashmap__for_each_key_entry - iterate over entries associated with given key
	* @map: hashmap to iterate
	* @cur: struct hashmap_entry * used as a loop cursor
	* @key: key to iterate entries for
	*/
	#define hashmap__for_each_key_entry(map, cur, _key) \
	for (cur = map->buckets \
	? map->buckets[hash_bits(map->hash_fn((_key), map->ctx), map->cap_bits)] \
	: NULL; \
	cur; \
	cur = cur->next) \
	if (map->equal_fn(cur->key, (_key), map->ctx))

	#define hashmap__for_each_key_entry_safe(map, cur, tmp, _key) \
	for (cur = map->buckets \
	? map->buckets[hash_bits(map->hash_fn((_key), map->ctx), map->cap_bits)] \
	: NULL; \
	cur && ({ tmp = cur->next; true; }); \
	cur = tmp) \
	if (map->equal_fn(cur->key, (_key), map->ctx))

	#endif /* __LIBBPF_HASHMAP_H */