forked from Mirrors/freeswitch
65bfe506e2
git-svn-id: http://svn.freeswitch.org/svn/freeswitch/trunk@15542 d0543943-73ff-0310-b7d9-9358b9ac24b2
478 lines
15 KiB
C
478 lines
15 KiB
C
/* Licensed to the Apache Software Foundation (ASF) under one or more
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* contributor license agreements. See the NOTICE file distributed with
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* this work for additional information regarding copyright ownership.
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* The ASF licenses this file to You under the Apache License, Version 2.0
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* (the "License"); you may not use this file except in compliance with
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* the License. You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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#include "apr_private.h"
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#include "apr_general.h"
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#include "apr_pools.h"
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#include "apr_hash.h"
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#if APR_HAVE_STDLIB_H
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#include <stdlib.h>
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#endif
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#if APR_HAVE_STRING_H
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#include <string.h>
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#endif
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#if APR_POOL_DEBUG && APR_HAVE_STDIO_H
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#include <stdio.h>
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#endif
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/*
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* The internal form of a hash table.
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*
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* The table is an array indexed by the hash of the key; collisions
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* are resolved by hanging a linked list of hash entries off each
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* element of the array. Although this is a really simple design it
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* isn't too bad given that pools have a low allocation overhead.
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*/
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typedef struct apr_hash_entry_t apr_hash_entry_t;
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struct apr_hash_entry_t {
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apr_hash_entry_t *next;
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unsigned int hash;
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const void *key;
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apr_ssize_t klen;
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const void *val;
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};
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/*
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* Data structure for iterating through a hash table.
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*
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* We keep a pointer to the next hash entry here to allow the current
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* hash entry to be freed or otherwise mangled between calls to
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* apr_hash_next().
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*/
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struct apr_hash_index_t {
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apr_hash_t *ht;
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apr_hash_entry_t *this, *next;
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unsigned int index;
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};
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/*
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* The size of the array is always a power of two. We use the maximum
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* index rather than the size so that we can use bitwise-AND for
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* modular arithmetic.
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* The count of hash entries may be greater depending on the chosen
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* collision rate.
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*/
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struct apr_hash_t {
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apr_pool_t *pool;
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apr_hash_entry_t **array;
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apr_hash_index_t iterator; /* For apr_hash_first(NULL, ...) */
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unsigned int count, max;
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apr_hashfunc_t hash_func;
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apr_hash_entry_t *free; /* List of recycled entries */
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};
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#define INITIAL_MAX 15 /* tunable == 2^n - 1 */
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/*
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* Hash creation functions.
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*/
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static apr_hash_entry_t **alloc_array(apr_hash_t *ht, unsigned int max)
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{
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return apr_pcalloc(ht->pool, sizeof(*ht->array) * (max + 1));
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}
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APR_DECLARE(apr_hash_t *) apr_hash_make(apr_pool_t *pool)
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{
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apr_hash_t *ht;
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ht = apr_palloc(pool, sizeof(apr_hash_t));
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ht->pool = pool;
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ht->free = NULL;
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ht->count = 0;
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ht->max = INITIAL_MAX;
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ht->array = alloc_array(ht, ht->max);
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ht->hash_func = apr_hashfunc_default;
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return ht;
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}
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APR_DECLARE(apr_hash_t *) apr_hash_make_custom(apr_pool_t *pool,
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apr_hashfunc_t hash_func)
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{
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apr_hash_t *ht = apr_hash_make(pool);
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ht->hash_func = hash_func;
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return ht;
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}
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/*
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* Hash iteration functions.
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*/
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APR_DECLARE(apr_hash_index_t *) apr_hash_next(apr_hash_index_t *hi)
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{
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hi->this = hi->next;
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while (!hi->this) {
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if (hi->index > hi->ht->max)
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return NULL;
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hi->this = hi->ht->array[hi->index++];
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}
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hi->next = hi->this->next;
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return hi;
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}
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APR_DECLARE(apr_hash_index_t *) apr_hash_first(apr_pool_t *p, apr_hash_t *ht)
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{
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apr_hash_index_t *hi;
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if (p)
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hi = apr_palloc(p, sizeof(*hi));
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else
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hi = &ht->iterator;
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hi->ht = ht;
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hi->index = 0;
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hi->this = NULL;
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hi->next = NULL;
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return apr_hash_next(hi);
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}
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APR_DECLARE(void) apr_hash_this(apr_hash_index_t *hi,
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const void **key,
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apr_ssize_t *klen,
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void **val)
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{
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if (key) *key = hi->this->key;
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if (klen) *klen = hi->this->klen;
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if (val) *val = (void *)hi->this->val;
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}
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/*
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* Expanding a hash table
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*/
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static void expand_array(apr_hash_t *ht)
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{
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apr_hash_index_t *hi;
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apr_hash_entry_t **new_array;
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unsigned int new_max;
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new_max = ht->max * 2 + 1;
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new_array = alloc_array(ht, new_max);
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for (hi = apr_hash_first(NULL, ht); hi; hi = apr_hash_next(hi)) {
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unsigned int i = hi->this->hash & new_max;
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hi->this->next = new_array[i];
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new_array[i] = hi->this;
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}
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ht->array = new_array;
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ht->max = new_max;
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}
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APR_DECLARE_NONSTD(unsigned int) apr_hashfunc_default(const char *char_key,
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apr_ssize_t *klen)
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{
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unsigned int hash = 0;
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const unsigned char *key = (const unsigned char *)char_key;
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const unsigned char *p;
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apr_ssize_t i;
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/*
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* This is the popular `times 33' hash algorithm which is used by
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* perl and also appears in Berkeley DB. This is one of the best
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* known hash functions for strings because it is both computed
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* very fast and distributes very well.
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*
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* The originator may be Dan Bernstein but the code in Berkeley DB
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* cites Chris Torek as the source. The best citation I have found
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* is "Chris Torek, Hash function for text in C, Usenet message
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* <27038@mimsy.umd.edu> in comp.lang.c , October, 1990." in Rich
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* Salz's USENIX 1992 paper about INN which can be found at
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* <http://citeseer.nj.nec.com/salz92internetnews.html>.
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*
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* The magic of number 33, i.e. why it works better than many other
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* constants, prime or not, has never been adequately explained by
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* anyone. So I try an explanation: if one experimentally tests all
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* multipliers between 1 and 256 (as I did while writing a low-level
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* data structure library some time ago) one detects that even
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* numbers are not useable at all. The remaining 128 odd numbers
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* (except for the number 1) work more or less all equally well.
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* They all distribute in an acceptable way and this way fill a hash
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* table with an average percent of approx. 86%.
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*
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* If one compares the chi^2 values of the variants (see
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* Bob Jenkins ``Hashing Frequently Asked Questions'' at
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* http://burtleburtle.net/bob/hash/hashfaq.html for a description
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* of chi^2), the number 33 not even has the best value. But the
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* number 33 and a few other equally good numbers like 17, 31, 63,
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* 127 and 129 have nevertheless a great advantage to the remaining
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* numbers in the large set of possible multipliers: their multiply
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* operation can be replaced by a faster operation based on just one
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* shift plus either a single addition or subtraction operation. And
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* because a hash function has to both distribute good _and_ has to
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* be very fast to compute, those few numbers should be preferred.
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*
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* -- Ralf S. Engelschall <rse@engelschall.com>
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*/
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if (*klen == APR_HASH_KEY_STRING) {
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for (p = key; *p; p++) {
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hash = hash * 33 + *p;
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}
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*klen = p - key;
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}
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else {
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for (p = key, i = *klen; i; i--, p++) {
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hash = hash * 33 + *p;
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}
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}
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return hash;
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}
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/*
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* This is where we keep the details of the hash function and control
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* the maximum collision rate.
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*
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* If val is non-NULL it creates and initializes a new hash entry if
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* there isn't already one there; it returns an updatable pointer so
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* that hash entries can be removed.
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*/
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static apr_hash_entry_t **find_entry(apr_hash_t *ht,
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const void *key,
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apr_ssize_t klen,
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const void *val)
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{
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apr_hash_entry_t **hep, *he;
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unsigned int hash;
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hash = ht->hash_func(key, &klen);
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/* scan linked list */
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for (hep = &ht->array[hash & ht->max], he = *hep;
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he; hep = &he->next, he = *hep) {
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if (he->hash == hash
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&& he->klen == klen
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&& memcmp(he->key, key, klen) == 0)
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break;
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}
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if (he || !val)
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return hep;
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/* add a new entry for non-NULL values */
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if ((he = ht->free) != NULL)
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ht->free = he->next;
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else
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he = apr_palloc(ht->pool, sizeof(*he));
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he->next = NULL;
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he->hash = hash;
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he->key = key;
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he->klen = klen;
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he->val = val;
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*hep = he;
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ht->count++;
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return hep;
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}
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APR_DECLARE(apr_hash_t *) apr_hash_copy(apr_pool_t *pool,
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const apr_hash_t *orig)
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{
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apr_hash_t *ht;
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apr_hash_entry_t *new_vals;
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unsigned int i, j;
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ht = apr_palloc(pool, sizeof(apr_hash_t) +
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sizeof(*ht->array) * (orig->max + 1) +
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sizeof(apr_hash_entry_t) * orig->count);
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ht->pool = pool;
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ht->free = NULL;
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ht->count = orig->count;
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ht->max = orig->max;
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ht->hash_func = orig->hash_func;
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ht->array = (apr_hash_entry_t **)((char *)ht + sizeof(apr_hash_t));
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new_vals = (apr_hash_entry_t *)((char *)(ht) + sizeof(apr_hash_t) +
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sizeof(*ht->array) * (orig->max + 1));
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j = 0;
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for (i = 0; i <= ht->max; i++) {
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apr_hash_entry_t **new_entry = &(ht->array[i]);
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apr_hash_entry_t *orig_entry = orig->array[i];
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while (orig_entry) {
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*new_entry = &new_vals[j++];
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(*new_entry)->hash = orig_entry->hash;
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(*new_entry)->key = orig_entry->key;
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(*new_entry)->klen = orig_entry->klen;
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(*new_entry)->val = orig_entry->val;
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new_entry = &((*new_entry)->next);
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orig_entry = orig_entry->next;
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}
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*new_entry = NULL;
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}
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return ht;
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}
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APR_DECLARE(void *) apr_hash_get(apr_hash_t *ht,
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const void *key,
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apr_ssize_t klen)
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{
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apr_hash_entry_t *he;
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he = *find_entry(ht, key, klen, NULL);
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if (he)
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return (void *)he->val;
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else
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return NULL;
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}
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APR_DECLARE(void) apr_hash_set(apr_hash_t *ht,
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const void *key,
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apr_ssize_t klen,
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const void *val)
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{
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apr_hash_entry_t **hep;
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hep = find_entry(ht, key, klen, val);
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if (*hep) {
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if (!val) {
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/* delete entry */
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apr_hash_entry_t *old = *hep;
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*hep = (*hep)->next;
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old->next = ht->free;
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ht->free = old;
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--ht->count;
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}
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else {
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/* replace entry */
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(*hep)->val = val;
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/* check that the collision rate isn't too high */
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if (ht->count > ht->max) {
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expand_array(ht);
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}
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}
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}
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/* else key not present and val==NULL */
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}
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APR_DECLARE(unsigned int) apr_hash_count(apr_hash_t *ht)
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{
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return ht->count;
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}
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APR_DECLARE(void) apr_hash_clear(apr_hash_t *ht)
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{
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apr_hash_index_t *hi;
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for (hi = apr_hash_first(NULL, ht); hi; hi = apr_hash_next(hi))
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apr_hash_set(ht, hi->this->key, hi->this->klen, NULL);
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}
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APR_DECLARE(apr_hash_t*) apr_hash_overlay(apr_pool_t *p,
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const apr_hash_t *overlay,
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const apr_hash_t *base)
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{
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return apr_hash_merge(p, overlay, base, NULL, NULL);
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}
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APR_DECLARE(apr_hash_t *) apr_hash_merge(apr_pool_t *p,
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const apr_hash_t *overlay,
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const apr_hash_t *base,
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void * (*merger)(apr_pool_t *p,
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const void *key,
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apr_ssize_t klen,
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const void *h1_val,
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const void *h2_val,
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const void *data),
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const void *data)
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{
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apr_hash_t *res;
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apr_hash_entry_t *new_vals = NULL;
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apr_hash_entry_t *iter;
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apr_hash_entry_t *ent;
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unsigned int i,j,k;
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#if APR_POOL_DEBUG
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/* we don't copy keys and values, so it's necessary that
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* overlay->a.pool and base->a.pool have a life span at least
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* as long as p
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*/
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if (!apr_pool_is_ancestor(overlay->pool, p)) {
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fprintf(stderr,
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"apr_hash_merge: overlay's pool is not an ancestor of p\n");
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abort();
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}
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if (!apr_pool_is_ancestor(base->pool, p)) {
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fprintf(stderr,
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"apr_hash_merge: base's pool is not an ancestor of p\n");
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abort();
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}
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#endif
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res = apr_palloc(p, sizeof(apr_hash_t));
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res->pool = p;
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res->free = NULL;
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res->hash_func = base->hash_func;
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res->count = base->count;
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res->max = (overlay->max > base->max) ? overlay->max : base->max;
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if (base->count + overlay->count > res->max) {
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res->max = res->max * 2 + 1;
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}
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res->array = alloc_array(res, res->max);
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if (base->count + overlay->count) {
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new_vals = apr_palloc(p, sizeof(apr_hash_entry_t) *
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(base->count + overlay->count));
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}
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j = 0;
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for (k = 0; k <= base->max; k++) {
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for (iter = base->array[k]; iter; iter = iter->next) {
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i = iter->hash & res->max;
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new_vals[j].klen = iter->klen;
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new_vals[j].key = iter->key;
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new_vals[j].val = iter->val;
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new_vals[j].hash = iter->hash;
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new_vals[j].next = res->array[i];
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res->array[i] = &new_vals[j];
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j++;
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}
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}
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for (k = 0; k <= overlay->max; k++) {
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for (iter = overlay->array[k]; iter; iter = iter->next) {
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i = iter->hash & res->max;
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for (ent = res->array[i]; ent; ent = ent->next) {
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if ((ent->klen == iter->klen) &&
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(memcmp(ent->key, iter->key, iter->klen) == 0)) {
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if (merger) {
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ent->val = (*merger)(p, iter->key, iter->klen,
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iter->val, ent->val, data);
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}
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else {
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ent->val = iter->val;
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}
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break;
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}
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}
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if (!ent) {
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new_vals[j].klen = iter->klen;
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new_vals[j].key = iter->key;
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new_vals[j].val = iter->val;
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new_vals[j].hash = iter->hash;
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new_vals[j].next = res->array[i];
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res->array[i] = &new_vals[j];
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res->count++;
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j++;
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}
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}
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}
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return res;
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}
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APR_POOL_IMPLEMENT_ACCESSOR(hash)
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