ack/util/grind/value.c

183 lines
3.8 KiB
C
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/* $Header$ */
#include <alloc.h>
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#include <assert.h>
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#include "position.h"
#include "scope.h"
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#include "idf.h"
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#include "symbol.h"
#include "type.h"
#include "message.h"
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#include "langdep.h"
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#include "expr.h"
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int stack_offset; /* for up and down commands */
extern long pointer_size;
extern t_addr *get_EM_regs();
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extern char *memcpy();
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/* Get the address of the object indicated by sym.
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Return 0 on failure,
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address on success.
*psize will contain size of object.
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*/
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t_addr
get_addr(sym, psize)
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register p_symbol sym;
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long *psize;
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{
p_type tp = sym->sy_type;
long size = tp->ty_size;
t_addr *EM_regs;
int i;
p_scope sc, symsc;
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*psize = size;
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switch(sym->sy_class) {
case VAR:
/* exists if child exists; nm_value contains addres */
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return (t_addr) sym->sy_name.nm_value;
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case VARPAR:
case LOCVAR:
/* first find the stack frame in which it resides */
symsc = base_scope(sym->sy_scope);
/* now symsc contains the scope where the storage for sym is
allocated. Now find it on the stack of child.
*/
i = stack_offset;
for (;;) {
sc = 0;
if (! (EM_regs = get_EM_regs(i++))) {
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return 0;
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}
if (! EM_regs[AB_OFF]) {
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error("%s not available", sym->sy_idf->id_text);
return 0;
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}
sc = base_scope(get_scope_from_addr(EM_regs[PC_OFF]));
if (! sc || sc->sc_start > EM_regs[PC_OFF]) {
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error("%s not available", sym->sy_idf->id_text);
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sc = 0;
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return 0;
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}
if (sc == symsc) break; /* found it */
}
if (sym->sy_class == LOCVAR) {
/* Either local variable or value parameter */
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return EM_regs[sym->sy_name.nm_value < 0 ? LB_OFF : AB_OFF] +
(t_addr) sym->sy_name.nm_value;
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}
/* If we get here, we have a var parameter. Get the parameters
of the current procedure invocation.
*/
{
p_type proctype = sc->sc_definedby->sy_type;
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t_addr a;
char *AB;
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size = proctype->ty_nbparams;
if (has_static_link(sc)) size += pointer_size;
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AB = malloc((unsigned) size);
if (! AB) {
error("could not allocate enough memory");
break;
}
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if (! get_bytes(size, EM_regs[AB_OFF], AB)) {
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break;
}
if ((size = tp->ty_size) == 0) {
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size = compute_size(tp, AB);
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*psize = size;
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}
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a = (t_addr) get_int(AB+sym->sy_name.nm_value, pointer_size, T_UNSIGNED);
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free(AB);
return a;
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}
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default:
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error("%s is not a variable", sym->sy_idf->id_text);
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break;
}
return 0;
}
/* Get the value of the symbol indicated by sym.
Return 0 on failure,
1 on success.
On success, 'buf' contains the value, and 'size' contains the size.
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For 'buf', storage is allocated by malloc; this storage must
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be freed by caller (I don't like this any more than you do, but caller
does not know sizes).
*/
int
get_value(sym, buf, psize)
register p_symbol sym;
char **buf;
long *psize;
{
p_type tp = sym->sy_type;
int retval = 0;
t_addr a;
long size = tp->ty_size;
*buf = 0;
switch(sym->sy_class) {
case CONST:
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*buf = malloc((unsigned) size);
if (! *buf) {
error("could not allocate enough memory");
break;
}
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switch(tp->ty_class) {
case T_REAL:
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put_real(*buf, size, sym->sy_const.co_rval);
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break;
case T_INTEGER:
case T_SUBRANGE:
case T_UNSIGNED:
case T_ENUM:
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put_int(*buf, size, sym->sy_const.co_ival);
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break;
case T_SET:
memcpy(*buf, sym->sy_const.co_setval, (int) size);
break;
case T_STRING:
memcpy(*buf, sym->sy_const.co_sval, (int) size);
break;
default:
fatal("strange constant");
}
retval = 1;
break;
case VAR:
case VARPAR:
case LOCVAR:
a = get_addr(sym, psize);
if (a) {
size = *psize;
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*buf = malloc((unsigned) size);
if (! *buf) {
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error("could not allocate enough memory");
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break;
}
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if (get_bytes(size, a, *buf)) {
retval = 1;
}
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}
break;
}
if (retval == 0) {
if (*buf) free(*buf);
*buf = 0;
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*psize = 0;
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}
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else *psize = size;
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return retval;
}