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427 lines
9.5 KiB
C
427 lines
9.5 KiB
C
/**
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r_assoc.c
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This is an associative array implementation, using an open-chained
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hash bucket technique.
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Note that this implementation permits each data entry to have
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separate copy constructors and destructors. This currently wastes
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space, but could be implemented while saving space by using
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the high order bit of the length value or somesuch.
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The major problem with this code is it's not resizable, though it
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could be made so.
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Copyright (C) 1999-2000 RTFM, Inc.
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All Rights Reserved
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This package is a SSLv3/TLS protocol analyzer written by Eric Rescorla
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<ekr@rtfm.com> and licensed by RTFM, Inc.
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Redistribution and use in source and binary forms, with or without
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modification, are permitted provided that the following conditions
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are met:
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1. Redistributions of source code must retain the above copyright
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notice, this list of conditions and the following disclaimer.
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2. Redistributions in binary form must reproduce the above copyright
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notice, this list of conditions and the following disclaimer in the
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documentation and/or other materials provided with the distribution.
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3. All advertising materials mentioning features or use of this software
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must display the following acknowledgement:
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This product includes software developed by Eric Rescorla for
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RTFM, Inc.
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4. Neither the name of RTFM, Inc. nor the name of Eric Rescorla may be
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used to endorse or promote products derived from this
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software without specific prior written permission.
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THIS SOFTWARE IS PROVIDED BY ERIC RESCORLA AND RTFM, INC. ``AS IS'' AND
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ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
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FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY SUCH DAMAGE.
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$Id: r_assoc.c,v 1.4 2001/12/24 06:06:26 ekr Exp $
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ekr@rtfm.com Sun Jan 17 17:57:15 1999
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*/
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#include <r_common.h>
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#include "r_assoc.h"
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typedef struct r_assoc_el_ {
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char *key;
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int key_len;
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void *data;
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struct r_assoc_el_ *prev;
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struct r_assoc_el_ *next;
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int (*copy) PROTO_LIST((void **new,void *old));
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int (*destroy) PROTO_LIST((void *ptr));
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} r_assoc_el;
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struct r_assoc_ {
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int size;
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int bits;
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r_assoc_el **chains;
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};
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#define DEFAULT_TABLE_BITS 5
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static int destroy_assoc_chain PROTO_LIST((r_assoc_el *chain));
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static int r_assoc_fetch_bucket PROTO_LIST((r_assoc *assoc,
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char *key,int len,r_assoc_el **bucketp));
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UINT4 hash_compute PROTO_LIST((char *key,int len,int size));
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static int copy_assoc_chain PROTO_LIST((r_assoc_el **newp,
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r_assoc_el *old));
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int r_assoc_create(assocp)
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r_assoc **assocp;
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{
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r_assoc *assoc=0;
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int _status;
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if(!(assoc=(r_assoc *)calloc(sizeof(r_assoc),1)))
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ABORT(R_NO_MEMORY);
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assoc->size=(1<<DEFAULT_TABLE_BITS);
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assoc->bits=DEFAULT_TABLE_BITS;
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if(!(assoc->chains=(r_assoc_el **)calloc(sizeof(r_assoc_el *),
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assoc->size)))
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ABORT(R_NO_MEMORY);
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*assocp=assoc;
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_status=0;
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abort:
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if(_status){
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r_assoc_destroy(&assoc);
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}
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return(_status);
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}
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int r_assoc_destroy(assocp)
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r_assoc **assocp;
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{
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r_assoc *assoc;
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int i;
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if(!assocp || !*assocp)
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return(0);
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assoc=*assocp;
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for(i=0;i<assoc->size;i++)
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destroy_assoc_chain(assoc->chains[i]);
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free(assoc->chains);
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free(assoc);
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return(0);
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}
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static int destroy_assoc_chain(chain)
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r_assoc_el *chain;
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{
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r_assoc_el *nxt;
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while(chain){
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nxt=chain->next;
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if(chain->destroy)
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chain->destroy(chain->data);
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free(chain->key);
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free(chain);
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chain=nxt;
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}
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return(0);
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}
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static int copy_assoc_chain(newp,old)
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r_assoc_el **newp;
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r_assoc_el *old;
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{
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r_assoc_el *new=0,*ptr,*tmp;
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int r,_status;
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if(!old) {
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*newp=0;
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return(0);
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}
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for(;old;old=old->next){
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if(!(tmp=(r_assoc_el *)calloc(sizeof(r_assoc_el),1)))
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ABORT(R_NO_MEMORY);
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if(!new){
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new=tmp;
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ptr=new;
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}
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else{
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ptr->next=tmp;
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tmp->prev=ptr;
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ptr=tmp;
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}
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ptr->destroy=old->destroy;
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ptr->copy=old->copy;
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if(old->copy){
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if((r=old->copy(&ptr->data,old->data)))
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ABORT(r);
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}
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else
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ptr->data=old->data;
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if(!(ptr->key=(char *)malloc(old->key_len)))
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ABORT(R_NO_MEMORY);
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memcpy(ptr->key,old->key,ptr->key_len=old->key_len);
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}
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*newp=new;
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_status=0;
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abort:
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if(_status){
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destroy_assoc_chain(new);
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}
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return(_status);
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}
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static int r_assoc_fetch_bucket(assoc,key,len,bucketp)
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r_assoc *assoc;
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char *key;
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int len;
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r_assoc_el **bucketp;
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{
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UINT4 hash_value;
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r_assoc_el *bucket;
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hash_value=hash_compute(key,len,assoc->bits);
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for(bucket=assoc->chains[hash_value];bucket;bucket=bucket->next){
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if(bucket->key_len == len && !memcmp(bucket->key,key,len)){
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*bucketp=bucket;
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return(0);
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}
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}
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return(R_NOT_FOUND);
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}
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int r_assoc_fetch(assoc,key,len,datap)
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r_assoc *assoc;
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char *key;
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int len;
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void **datap;
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{
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r_assoc_el *bucket;
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int r;
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if((r=r_assoc_fetch_bucket(assoc,key,len,&bucket))){
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if(r!=R_NOT_FOUND)
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ERETURN(r);
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return(r);
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}
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*datap=bucket->data;
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return(0);
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}
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int r_assoc_insert(assoc,key,len,data,copy,destroy,how)
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r_assoc *assoc;
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char *key;
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int len;
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void *data;
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int (*copy) PROTO_LIST((void **new,void *old));
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int (*destroy) PROTO_LIST((void *ptr));
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int how;
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{
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r_assoc_el *bucket,*new_bucket=0;
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int r,_status;
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if((r=r_assoc_fetch_bucket(assoc,key,len,&bucket))){
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/*Note that we compute the hash value twice*/
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UINT4 hash_value;
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if(r!=R_NOT_FOUND)
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ABORT(r);
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hash_value=hash_compute(key,len,assoc->bits);
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if(!(new_bucket=(r_assoc_el *)calloc(sizeof(r_assoc_el),1)))
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ABORT(R_NO_MEMORY);
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if(!(new_bucket->key=(char *)malloc(len)))
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ABORT(R_NO_MEMORY);
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memcpy(new_bucket->key,key,len);
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new_bucket->key_len=len;
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/*Insert at the list head. Is FIFO a good algorithm?*/
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if(assoc->chains[hash_value])
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assoc->chains[hash_value]->prev=new_bucket;
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new_bucket->next=assoc->chains[hash_value];
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assoc->chains[hash_value]=new_bucket;
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bucket=new_bucket;
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}
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else{
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if(!(how&R_ASSOC_REPLACE))
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ABORT(R_ALREADY);
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if(bucket->destroy)
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bucket->destroy(bucket->data);
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}
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bucket->data=data;
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bucket->copy=copy;
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bucket->destroy=destroy;
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_status=0;
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abort:
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if(_status && new_bucket){
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free(new_bucket->key);
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free(new_bucket);
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}
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return(_status);
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}
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int r_assoc_copy(newp,old)
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r_assoc **newp;
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r_assoc *old;
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{
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int r,_status,i;
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r_assoc *new;
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if(!(new=(r_assoc *)calloc(sizeof(r_assoc),1)))
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ABORT(R_NO_MEMORY);
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new->size=old->size;
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new->bits=old->bits;
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if(!(new->chains=(r_assoc_el **)calloc(sizeof(r_assoc_el),old->size)))
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ABORT(R_NO_MEMORY);
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for(i=0;i<new->size;i++){
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if((r=copy_assoc_chain(new->chains+i,old->chains[i])))
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ABORT(R_NO_MEMORY);
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}
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*newp=new;
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_status=0;
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abort:
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if(_status){
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r_assoc_destroy(&new);
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}
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return(_status);
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}
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int r_assoc_init_iter(assoc,iter)
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r_assoc *assoc;
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r_assoc_iterator *iter;
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{
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int i;
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iter->assoc=assoc;
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iter->prev_chain=-1;
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iter->prev=0;
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iter->next_chain=assoc->size;
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iter->next=0;
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for(i=0;i<assoc->size;i++){
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if(assoc->chains[i]!=0){
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iter->next_chain=i;
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iter->next=assoc->chains[i];
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break;
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}
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}
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return(0);
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}
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int r_assoc_iter(iter,key,keyl,val)
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r_assoc_iterator *iter;
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void **key;
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int *keyl;
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void **val;
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{
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int i;
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r_assoc_el *ret;
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if(!iter->next)
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return(R_EOD);
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ret=iter->next;
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*key=ret->key;
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*keyl=ret->key_len;
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*val=ret->data;
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/* Now increment */
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iter->prev_chain=iter->next_chain;
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iter->prev=iter->next;
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/* More on this chain */
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if(iter->next->next){
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iter->next=iter->next->next;
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}
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else{
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iter->next=0;
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/* FInd the next occupied chain*/
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for(i=iter->next_chain;i<iter->assoc->size;i++){
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if(iter->assoc->chains[i]){
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iter->next_chain=i;
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iter->next=iter->assoc->chains[i];
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break;
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}
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}
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}
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return(0);
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}
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/* Delete the last returned value*/
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int r_assoc_iter_delete(iter)
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r_assoc_iterator *iter;
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{
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/* First unhook it from the list*/
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if(!iter->prev->prev){
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/* First element*/
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iter->assoc->chains[iter->prev_chain]=iter->prev->next;
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}
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else{
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iter->prev->prev->next=iter->prev->next;
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}
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if(iter->prev->next){
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iter->prev->next->prev=iter->prev->prev;
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}
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iter->prev->destroy(iter->prev->data);
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free(iter->prev->data);
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free(iter->prev);
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return(0);
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}
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/*This is a hack from AMS. Supposedly, it's pretty good for strings, even
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though it doesn't take into account all the data*/
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UINT4 hash_compute(key,len,bits)
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char *key;
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int len;
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int bits;
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{
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UINT4 h=0;
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h=key[0] +(key[len-1] * len);
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h &= (1<<bits) - 1;
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return(h);
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}
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