#include "flexdef.h"
int hashfunct PROTO((register char[], int));
struct hash_entry *ndtbl[NAME_TABLE_HASH_SIZE];
struct hash_entry *sctbl[START_COND_HASH_SIZE];
struct hash_entry *ccltab[CCL_HASH_SIZE];
struct hash_entry *findsym();
int addsym( sym, str_def, int_def, table, table_size )
register char sym[];
char *str_def;
int int_def;
hash_table table;
int table_size;
{
int hash_val = hashfunct( sym, table_size );
register struct hash_entry *sym_entry = table[hash_val];
register struct hash_entry *new_entry;
register struct hash_entry *successor;
while ( sym_entry )
{
if ( ! strcmp( sym, sym_entry->name ) )
{
return -1;
}
sym_entry = sym_entry->next;
}
new_entry = (struct hash_entry *)
flex_alloc( sizeof( struct hash_entry ) );
if ( new_entry == NULL )
flexfatal( _( "symbol table memory allocation failed" ) );
if ( (successor = table[hash_val]) != 0 )
{
new_entry->next = successor;
successor->prev = new_entry;
}
else
new_entry->next = NULL;
new_entry->prev = NULL;
new_entry->name = sym;
new_entry->str_val = str_def;
new_entry->int_val = int_def;
table[hash_val] = new_entry;
return 0;
}
void cclinstal( ccltxt, cclnum )
Char ccltxt[];
int cclnum;
{
Char *copy_unsigned_string();
(void) addsym( (char *) copy_unsigned_string( ccltxt ),
(char *) 0, cclnum,
ccltab, CCL_HASH_SIZE );
}
int ccllookup( ccltxt )
Char ccltxt[];
{
return findsym( (char *) ccltxt, ccltab, CCL_HASH_SIZE )->int_val;
}
struct hash_entry *findsym( sym, table, table_size )
register char sym[];
hash_table table;
int table_size;
{
static struct hash_entry empty_entry =
{
(struct hash_entry *) 0, (struct hash_entry *) 0,
(char *) 0, (char *) 0, 0,
} ;
register struct hash_entry *sym_entry =
table[hashfunct( sym, table_size )];
while ( sym_entry )
{
if ( ! strcmp( sym, sym_entry->name ) )
return sym_entry;
sym_entry = sym_entry->next;
}
return &empty_entry;
}
int hashfunct( str, hash_size )
register char str[];
int hash_size;
{
register int hashval;
register int locstr;
hashval = 0;
locstr = 0;
while ( str[locstr] )
{
hashval = (hashval << 1) + (unsigned char) str[locstr++];
hashval %= hash_size;
}
return hashval;
}
void ndinstal( name, definition )
char name[];
Char definition[];
{
char *copy_string();
Char *copy_unsigned_string();
if ( addsym( copy_string( name ),
(char *) copy_unsigned_string( definition ), 0,
ndtbl, NAME_TABLE_HASH_SIZE ) )
synerr( _( "name defined twice" ) );
}
Char *ndlookup( nd )
char nd[];
{
return (Char *) findsym( nd, ndtbl, NAME_TABLE_HASH_SIZE )->str_val;
}
void scextend()
{
current_max_scs += MAX_SCS_INCREMENT;
++num_reallocs;
scset = reallocate_integer_array( scset, current_max_scs );
scbol = reallocate_integer_array( scbol, current_max_scs );
scxclu = reallocate_integer_array( scxclu, current_max_scs );
sceof = reallocate_integer_array( sceof, current_max_scs );
scname = reallocate_char_ptr_array( scname, current_max_scs );
}
void scinstal( str, xcluflg )
char str[];
int xcluflg;
{
char *copy_string();
action_define( str, lastsc );
if ( ++lastsc >= current_max_scs )
scextend();
scname[lastsc] = copy_string( str );
if ( addsym( scname[lastsc], (char *) 0, lastsc,
sctbl, START_COND_HASH_SIZE ) )
format_pinpoint_message(
_( "start condition %s declared twice" ),
str );
scset[lastsc] = mkstate( SYM_EPSILON );
scbol[lastsc] = mkstate( SYM_EPSILON );
scxclu[lastsc] = xcluflg;
sceof[lastsc] = false;
}
int sclookup( str )
char str[];
{
return findsym( str, sctbl, START_COND_HASH_SIZE )->int_val;
}