/* Based on work Copyright 2002 Christopher Clark */
/* Copyright 2005-2012 Nick Mathewson */
/* Copyright 2009-2012 Niels Provos and Nick Mathewson */
/* See license at end. */
/* Based on ideas by Christopher Clark and interfaces from Niels Provos. */
#ifndef _EVENT_HT_H
#define _EVENT_HT_H
#define HT_HEAD(name, type) \
struct name { \
/* The hash table itself. */ \
struct type **hth_table; \
/* How long is the hash table? */ \
unsigned hth_table_length; \
/* How many elements does the table contain? */ \
unsigned hth_n_entries; \
/* How many elements will we allow in the table before resizing it? */ \
unsigned hth_load_limit; \
/* Position of hth_table_length in the primes table. */ \
int hth_prime_idx; \
}
#define HT_INITIALIZER() \
{ NULL, 0, 0, 0, -1 }
#ifdef HT_CACHE_HASH_VALUES
#define HT_ENTRY(type) \
struct { \
struct type *hte_next; \
unsigned hte_hash; \
}
#else
#define HT_ENTRY(type) \
struct { \
struct type *hte_next; \
}
#endif
#define HT_EMPTY(head) \
((head)->hth_n_entries == 0)
/* How many elements in 'head'? */
#define HT_SIZE(head) \
((head)->hth_n_entries)
#define HT_FIND(name, head, elm) name##_HT_FIND((head), (elm))
#define HT_INSERT(name, head, elm) name##_HT_INSERT((head), (elm))
#define HT_REPLACE(name, head, elm) name##_HT_REPLACE((head), (elm))
#define HT_REMOVE(name, head, elm) name##_HT_REMOVE((head), (elm))
#define HT_START(name, head) name##_HT_START(head)
#define HT_NEXT(name, head, elm) name##_HT_NEXT((head), (elm))
#define HT_NEXT_RMV(name, head, elm) name##_HT_NEXT_RMV((head), (elm))
#define HT_CLEAR(name, head) name##_HT_CLEAR(head)
#define HT_INIT(name, head) name##_HT_INIT(head)
/* Helper: */
static inline unsigned
ht_improve_hash(unsigned h)
{
/* Aim to protect against poor hash functions by adding logic here
* - logic taken from java 1.4 hashtable source */
h += ~(h << 9);
h ^= ((h >> 14) | (h << 18)); /* >>> */
h += (h << 4);
h ^= ((h >> 10) | (h << 22)); /* >>> */
return h;
}
#if 0
/** Basic string hash function, from Java standard String.hashCode(). */
static inline unsigned
ht_string_hash(const char *s)
{
unsigned h = 0;
int m = 1;
while (*s) {
h += ((signed char)*s++)*m;
m = (m<<5)-1; /* m *= 31 */
}
return h;
}
#endif
/** Basic string hash function, from Python's str.__hash__() */
static inline unsigned
ht_string_hash(const char *s)
{
unsigned h;
const unsigned char *cp = (const unsigned char *)s;
h = *cp << 7;
while (*cp) {
h = (1000003*h) ^ *cp++;
}
/* This conversion truncates the length of the string, but that's ok. */
h ^= (unsigned)(cp-(const unsigned char*)s);
return h;
}
#ifdef HT_CACHE_HASH_VALUES
#define _HT_SET_HASH(elm, field, hashfn) \
do { (elm)->field.hte_hash = hashfn(elm); } while (0)
#define _HT_SET_HASHVAL(elm, field, val) \
do { (elm)->field.hte_hash = (val); } while (0)
#define _HT_ELT_HASH(elm, field, hashfn) \
((elm)->field.hte_hash)
#else
#define _HT_SET_HASH(elm, field, hashfn) \
((void)0)
#define _HT_ELT_HASH(elm, field, hashfn) \
(hashfn(elm))
#define _HT_SET_HASHVAL(elm, field, val) \
((void)0)
#endif
/* Helper: alias for the bucket containing 'elm'. */
#define _HT_BUCKET(head, field, elm, hashfn) \
((head)->hth_table[_HT_ELT_HASH(elm,field,hashfn) % head->hth_table_length])
#define HT_FOREACH(x, name, head) \
for ((x) = HT_START(name, head); \
(x) != NULL; \
(x) = HT_NEXT(name, head, x))
#define HT_PROTOTYPE(name, type, field, hashfn, eqfn) \
int name##_HT_GROW(struct name *ht, unsigned min_capacity); \
void name##_HT_CLEAR(struct name *ht); \
int _##name##_HT_REP_IS_BAD(const struct name *ht); \
static inline void \
name##_HT_INIT(struct name *head) { \
head->hth_table_length = 0; \
head->hth_table = NULL; \
head->hth_n_entries = 0; \
head->hth_load_limit = 0; \
head->hth_prime_idx = -1; \
} \
/* Helper: returns a pointer to the right location in the table \
* 'head' to find or insert the element 'elm'. */ \
static inline struct type ** \
_##name##_HT_FIND_P(struct name *head, struct type *elm) \
{ \
struct type **p; \
if (!head->hth_table) \
return NULL; \
p = &_HT_BUCKET(head, field, elm, hashfn); \
while (*p) { \
if (eqfn(*p, elm)) \
return p; \
p = &(*p)->field.hte_next; \
} \
return p; \
} \
/* Return a pointer to the element in the table 'head' matching 'elm', \
* or NULL if no such element exists */ \
static inline struct type * \
name##_HT_FIND(const struct name *head, struct type *elm) \
{ \
struct type **p; \
struct name *h = (struct name *) head; \
_HT_SET_HASH(elm, field, hashfn); \
p = _##name##_HT_FIND_P(h, elm); \
return p ? *p : NULL; \
} \
/* Insert the element 'elm' into the table 'head'. Do not call this \
* function if the table might already contain a matching element. */ \
static inline void \
name##_HT_INSERT(struct name *head, struct type *elm) \
{ \
struct type **p; \
if (!head->hth_table || head->hth_n_entries >= head->hth_load_limit) \
name##_HT_GROW(head, head->hth_n_entries+1); \
++head->hth_n_entries; \
_HT_SET_HASH(elm, field, hashfn); \
p = &_HT_BUCKET(head, field, elm, hashfn); \
elm->field.hte_next = *p; \
*p = elm; \
} \
/* Insert the element 'elm' into the table 'head'. If there already \
* a matching element in the table, replace that element and return \
* it. */ \
static inline struct type * \
name##_HT_REPLACE(struct name *head, struct type *elm) \
{ \
struct type **p, *r; \
if (!head->hth_table || head->hth_n_entries >= head->hth_load_limit) \
name##_HT_GROW(head, head->hth_n_entries+1); \
_HT_SET_HASH(elm, field, hashfn); \
p = _##name##_HT_FIND_P(head, elm); \
r = *p; \
*p = elm; \
if (r && (r!=elm)) { \
elm->field.hte_next = r->field.hte_next; \
r->field.hte_next = NULL; \
return r; \
} else { \
++head->hth_n_entries; \
return NULL; \
} \
} \
/* Remove any element matching 'elm' from the table 'head'. If such \
* an element is found, return it; otherwise return NULL. */ \
static inline struct type * \
name##_HT_REMOVE(struct name *head, struct type *elm) \
{ \
struct type **p, *r; \
_HT_SET_HASH(elm, field, hashfn); \
p = _##name##_HT_FIND_P(head,elm); \
if (!p || !*p) \
return NULL; \
r = *p; \
*p = r->field.hte_next; \
r->field.hte_next = NULL; \
--head->hth_n_entries; \
return r; \
} \
/* Invoke the function 'fn' on every element of the table 'head', \
* using 'data' as its second argument. If the function returns \
* nonzero, remove the most recently examined element before invoking \
* the function again. */ \
static inline void \
name##_HT_FOREACH_FN(struct name *head, \
int (*fn)(struct type *, void *), \
void *data) \
{ \
unsigned idx; \
struct type **p, **nextp, *next; \
if (!head->hth_table) \
return; \
for (idx=0; idx < head->hth_table_length; ++idx) { \
p = &head->hth_table[idx]; \
while (*p) { \
nextp = &(*p)->field.hte_next; \
next = *nextp; \
if (fn(*p, data)) { \
--head->hth_n_entries; \
*p = next; \
} else { \
p = nextp; \
} \
} \
} \
} \
/* Return a pointer to the first element in the table 'head', under \
* an arbitrary order. This order is stable under remove operations, \
* but not under others. If the table is empty, return NULL. */ \
static inline struct type ** \
name##_HT_START(struct name *head) \
{ \
unsigned b = 0; \
while (b < head->hth_table_length) { \
if (head->hth_table[b]) \
return &head->hth_table[b]; \
++b; \
} \
return NULL; \
} \
/* Return the next element in 'head' after 'elm', under the arbitrary \
* order used by HT_START. If there are no more elements, return \
* NULL. If 'elm' is to be removed from the table, you must call \
* this function for the next value before you remove it. \
*/ \
static inline struct type ** \
name##_HT_NEXT(struct name *head, struct type **elm) \
{ \
if ((*elm)->field.hte_next) { \
return &(*elm)->field.hte_next; \
} else { \
unsigned b = (_HT_ELT_HASH(*elm, field, hashfn) % head->hth_table_length)+1; \
while (b < head->hth_table_length) { \
if (head->hth_table[b]) \
return &head->hth_table[b]; \
++b; \
} \
return NULL; \
} \
} \
static inline struct type ** \
name##_HT_NEXT_RMV(struct name *head, struct type **elm) \
{ \
unsigned h = _HT_ELT_HASH(*elm, field, hashfn); \
*elm = (*elm)->field.hte_next; \
--head->hth_n_entries; \
if (*elm) { \
return elm; \
} else { \
unsigned b = (h % head->hth_table_length)+1; \
while (b < head->hth_table_length) { \
if (head->hth_table[b]) \
return &head->hth_table[b]; \
++b; \
} \
return NULL; \
} \
}
#define HT_GENERATE(name, type, field, hashfn, eqfn, load, mallocfn, \
reallocfn, freefn) \
static unsigned name##_PRIMES[] = { \
53, 97, 193, 389, \
769, 1543, 3079, 6151, \
12289, 24593, 49157, 98317, \
196613, 393241, 786433, 1572869, \
3145739, 6291469, 12582917, 25165843, \
50331653, 100663319, 201326611, 402653189, \
805306457, 1610612741 \
}; \
static unsigned name##_N_PRIMES = \
(unsigned)(sizeof(name##_PRIMES)/sizeof(name##_PRIMES[0])); \
/* Expand the internal table of 'head' until it is large enough to \
* hold 'size' elements. Return 0 on success, -1 on allocation \
* failure. */ \
int \
name##_HT_GROW(struct name *head, unsigned size) \
{ \
unsigned new_len, new_load_limit; \
int prime_idx; \
struct type **new_table; \
if (head->hth_prime_idx == (int)name##_N_PRIMES - 1) \
return 0; \
if (head->hth_load_limit > size) \
return 0; \
prime_idx = head->hth_prime_idx; \
do { \
new_len = name##_PRIMES[++prime_idx]; \
new_load_limit = (unsigned)(load*new_len); \
} while (new_load_limit <= size && \
prime_idx < (int)name##_N_PRIMES); \
if ((new_table = mallocfn(new_len*sizeof(struct type*)))) { \
unsigned b; \
memset(new_table, 0, new_len*sizeof(struct type*)); \
for (b = 0; b < head->hth_table_length; ++b) { \
struct type *elm, *next; \
unsigned b2; \
elm = head->hth_table[b]; \
while (elm) { \
next = elm->field.hte_next; \
b2 = _HT_ELT_HASH(elm, field, hashfn) % new_len; \
elm->field.hte_next = new_table[b2]; \
new_table[b2] = elm; \
elm = next; \
} \
} \
if (head->hth_table) \
freefn(head->hth_table); \
head->hth_table = new_table; \
} else { \
unsigned b, b2; \
new_table = reallocfn(head->hth_table, new_len*sizeof(struct type*)); \
if (!new_table) return -1; \
memset(new_table + head->hth_table_length, 0, \
(new_len - head->hth_table_length)*sizeof(struct type*)); \
for (b=0; b < head->hth_table_length; ++b) { \
struct type *e, **pE; \
for (pE = &new_table[b], e = *pE; e != NULL; e = *pE) { \
b2 = _HT_ELT_HASH(e, field, hashfn) % new_len; \
if (b2 == b) { \
pE = &e->field.hte_next; \
} else { \
*pE = e->field.hte_next; \
e->field.hte_next = new_table[b2]; \
new_table[b2] = e; \
} \
} \
} \
head->hth_table = new_table; \
} \
head->hth_table_length = new_len; \
head->hth_prime_idx = prime_idx; \
head->hth_load_limit = new_load_limit; \
return 0; \
} \
/* Free all storage held by 'head'. Does not free 'head' itself, or \
* individual elements. */ \
void \
name##_HT_CLEAR(struct name *head) \
{ \
if (head->hth_table) \
freefn(head->hth_table); \
head->hth_table_length = 0; \
name##_HT_INIT(head); \
} \
/* Debugging helper: return false iff the representation of 'head' is \
* internally consistent. */ \
int \
_##name##_HT_REP_IS_BAD(const struct name *head) \
{ \
unsigned n, i; \
struct type *elm; \
if (!head->hth_table_length) { \
if (!head->hth_table && !head->hth_n_entries && \
!head->hth_load_limit && head->hth_prime_idx == -1) \
return 0; \
else \
return 1; \
} \
if (!head->hth_table || head->hth_prime_idx < 0 || \
!head->hth_load_limit) \
return 2; \
if (head->hth_n_entries > head->hth_load_limit) \
return 3; \
if (head->hth_table_length != name##_PRIMES[head->hth_prime_idx]) \
return 4; \
if (head->hth_load_limit != (unsigned)(load*head->hth_table_length)) \
return 5; \
for (n = i = 0; i < head->hth_table_length; ++i) { \
for (elm = head->hth_table[i]; elm; elm = elm->field.hte_next) { \
if (_HT_ELT_HASH(elm, field, hashfn) != hashfn(elm)) \
return 1000 + i; \
if ((_HT_ELT_HASH(elm, field, hashfn) % head->hth_table_length) != i) \
return 10000 + i; \
++n; \
} \
} \
if (n != head->hth_n_entries) \
return 6; \
return 0; \
}
/** Implements an over-optimized "find and insert if absent" block;
* not meant for direct usage by typical code, or usage outside the critical
* path.*/
#define _HT_FIND_OR_INSERT(name, field, hashfn, head, eltype, elm, var, y, n) \
{ \
struct name *_##var##_head = head; \
struct eltype **var; \
if (!_##var##_head->hth_table || \
_##var##_head->hth_n_entries >= _##var##_head->hth_load_limit) \
name##_HT_GROW(_##var##_head, _##var##_head->hth_n_entries+1); \
_HT_SET_HASH((elm), field, hashfn); \
var = _##name##_HT_FIND_P(_##var##_head, (elm)); \
if (*var) { \
y; \
} else { \
n; \
} \
}
#define _HT_FOI_INSERT(field, head, elm, newent, var) \
{ \
_HT_SET_HASHVAL(newent, field, (elm)->field.hte_hash); \
newent->field.hte_next = NULL; \
*var = newent; \
++((head)->hth_n_entries); \
}
/*
* Copyright 2005, Nick Mathewson. Implementation logic is adapted from code
* by Cristopher Clark, retrofit to allow drop-in memory management, and to
* use the same interface as Niels Provos's tree.h. This is probably still
* a derived work, so the original license below still applies.
*
* Copyright (c) 2002, Christopher Clark
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* * Neither the name of the original author; nor the names of any contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
* OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#endif