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/*
* Copyright 1993, 1995 Christopher Seiwald.
*
* This file is part of Jam - see jam.c for Copyright information.
*/
/*
* hash.c - simple in-memory hashing routines
*
* External routines:
*
* hashinit() - initialize a hash table, returning a handle
* hashitem() - find a record in the table, and optionally enter a new one
* hashdone() - free a hash table, given its handle
*
* Internal routines:
*
* hashrehash() - resize and rebuild hp->tab, the hash table
*
* 4/29/93 - ensure ITEM's are aligned
* 11/04/02 (seiwald) - const-ing for string literals
* 01/31/02 (seiwald) - keyval now unsigned (cray-ziness)
*/
# include "jsh.h"
# include "hash.h"
/* Header attached to all data items entered into a hash table. */
struct hashhdr {
struct item *next;
unsigned int keyval; /* for quick comparisons */
} ;
/* This structure overlays the one handed to hashenter(). */
/* It's actual size is given to hashinit(). */
struct hashdata {
char *key;
/* rest of user data */
} ;
typedef struct item {
struct hashhdr hdr;
struct hashdata data;
} ITEM ;
# define MAX_LISTS 32
struct hash
{
/*
* the hash table, just an array of item pointers
*/
struct {
int nel;
ITEM **base;
} tab;
int bloat; /* tab.nel / items.nel */
int inel; /* initial number of elements */
/*
* the array of records, maintained by these routines
* essentially a microallocator
*/
struct {
int more; /* how many more ITEMs fit in lists[ list ] */
char *next; /* where to put more ITEMs in lists[ list ] */
int datalen; /* length of records in this hash table */
int size; /* sizeof( ITEM ) + aligned datalen */
int nel; /* total ITEMs held by all lists[] */
int list; /* index into lists[] */
struct {
int nel; /* total ITEMs held by this list */
char *base; /* base of ITEMs array */
} lists[ MAX_LISTS ];
} items;
const char *name; /* just for hashstats() */
} ;
static void hashrehash( struct hash *hp );
static void hashstat( struct hash *hp );
#if 0
/*
* hashitem() - find a record in the table, and optionally enter a new one
*/
int
hashitem(
register struct hash *hp,
HASHDATA **data,
int enter )
{
ITEM **base;
register ITEM *i;
unsigned char *b = (unsigned char *)(*data)->key;
unsigned int keyval;
if( enter && !hp->items.more )
hashrehash( hp );
if( !enter && !hp->items.nel )
return 0;
keyval = *b;
while( *b )
keyval = keyval * 2147059363 + *b++;
base = hp->tab.base + ( keyval % hp->tab.nel );
for( i = *base; i; i = i->hdr.next )
if( keyval == i->hdr.keyval &&
!strcmp( i->data.key, (*data)->key ) )
{
*data = &i->data;
return !0;
}
if( enter )
{
i = (ITEM *)hp->items.next;
hp->items.next += hp->items.size;
hp->items.more--;
memcpy( (char *)&i->data, (char *)*data, hp->items.datalen );
i->hdr.keyval = keyval;
i->hdr.next = *base;
*base = i;
*data = &i->data;
}
return 0;
}
#endif
void*
hashget(
register struct hash *hp,
const char* key)
{
ITEM **base;
register ITEM *i;
unsigned char *b = (unsigned char *)key;
unsigned int keyval;
if( !hp->items.nel )
return 0;
keyval = *b;
while( *b )
keyval = keyval * 2147059363 + *b++;
base = hp->tab.base + ( keyval % hp->tab.nel );
for( i = *base; i; i = i->hdr.next )
if( keyval == i->hdr.keyval &&
!strcmp( i->data.key, key ) )
{
return &i->data;
}
return 0;
}
void*
hashput(
register struct hash *hp,
const char* key,
int *pcreate )
{
ITEM **base;
register ITEM *i;
unsigned char *b = (unsigned char *)key;
unsigned int keyval;
if( !hp->items.more )
hashrehash( hp );
keyval = *b;
while( *b )
keyval = keyval * 2147059363 + *b++;
base = hp->tab.base + ( keyval % hp->tab.nel );
for( i = *base; i; i = i->hdr.next )
if( keyval == i->hdr.keyval &&
!strcmp( i->data.key, key ) )
{
*pcreate = 0;
return &i->data;
}
i = (ITEM *)hp->items.next;
hp->items.next += hp->items.size;
hp->items.more--;
memset( (char *)&i->data, 0, hp->items.datalen );
i->hdr.keyval = keyval;
i->hdr.next = *base;
*base = i;
*pcreate = 1;
return &i->data;
}
/*
* hashrehash() - resize and rebuild hp->tab, the hash table
*/
static void hashrehash( register struct hash *hp )
{
int i = ++hp->items.list;
hp->items.more = i ? 2 * hp->items.nel : hp->inel;
hp->items.next = (char *)malloc( hp->items.more * hp->items.size );
hp->items.lists[i].nel = hp->items.more;
hp->items.lists[i].base = hp->items.next;
hp->items.nel += hp->items.more;
if( hp->tab.base )
free( (char *)hp->tab.base );
hp->tab.nel = hp->items.nel * hp->bloat;
hp->tab.base = (ITEM **)malloc( hp->tab.nel * sizeof(ITEM **) );
memset( (char *)hp->tab.base, '\0', hp->tab.nel * sizeof( ITEM * ) );
for( i = 0; i < hp->items.list; i++ )
{
int nel = hp->items.lists[i].nel;
char *next = hp->items.lists[i].base;
for( ; nel--; next += hp->items.size )
{
register ITEM *i = (ITEM *)next;
ITEM **ip = hp->tab.base + i->hdr.keyval % hp->tab.nel;
i->hdr.next = *ip;
*ip = i;
}
}
}
/* --- */
# define ALIGNED(x) ( ( x + sizeof( ITEM ) - 1 ) & ~( sizeof( ITEM ) - 1 ) )
/*
* hashinit() - initialize a hash table, returning a handle
*/
struct hash *
hashinit(
int datalen,
const char *name )
{
struct hash *hp = (struct hash *)malloc( sizeof( *hp ) );
hp->bloat = 3;
hp->tab.nel = 0;
hp->tab.base = (ITEM **)0;
hp->items.more = 0;
hp->items.datalen = datalen;
hp->items.size = sizeof( struct hashhdr ) + ALIGNED( datalen );
hp->items.list = -1;
hp->items.nel = 0;
hp->inel = 11;
hp->name = name;
return hp;
}
/*
* hashdone() - free a hash table, given its handle
*/
void
hashdone( struct hash *hp )
{
int i;
if( !hp )
return;
if( DEBUG_MEM )
hashstat( hp );
if( hp->tab.base )
free( (char *)hp->tab.base );
for( i = 0; i <= hp->items.list; i++ )
free( hp->items.lists[i].base );
free( (char *)hp );
}
/* ---- */
static void
hashstat( struct hash *hp )
{
ITEM **tab = hp->tab.base;
int nel = hp->tab.nel;
int count = 0;
int sets = 0;
int run = ( tab[ nel - 1 ] != (ITEM *)0 );
int i, here;
for( i = nel; i > 0; i-- )
{
if( (here = ( *tab++ != (ITEM *)0 )) )
count++;
if( here && !run )
sets++;
run = here;
}
printf( "%s table: %d+%d+%d (%dK+%dK) items+table+hash, %f density\n",
hp->name,
count,
hp->items.nel,
hp->tab.nel,
hp->items.nel * hp->items.size / 1024,
hp->tab.nel * sizeof( ITEM ** ) / 1024,
(float)count / (float)sets );
}
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