ack/lang/cem/cemcom/field.c

175 lines
4.2 KiB
C

/* $Header$ */
/* BITFIELD EXPRESSION EVALUATOR */
#include "nobitfield.h"
#ifndef NOBITFIELD
#include <em.h>
#include "debug.h"
#include "arith.h"
#include "type.h"
#include "idf.h"
#include "label.h"
#include "code.h"
#include "assert.h"
#include "expr.h"
#include "sizes.h"
#include "Lpars.h"
#include "field.h"
arith tmp_pointer_var(); /* eval.c */
char *symbol2str(); /* symbol2str.c */
/* Eval_field() evaluates expressions involving bit fields.
The various instructions are not yet optimised in the expression
tree and are therefore dealt with in this function.
The actions taken at any operation are described clearly by the
code for this actions.
Note: the bitfields are packed in target machine integers!
*/
eval_field(expr, code)
struct expr *expr;
int code;
{
int op = expr->OP_OPER;
struct expr *leftop = expr->OP_LEFT;
struct expr *rightop = expr->OP_RIGHT;
struct field *fd = leftop->ex_type->tp_field;
struct type *tp = leftop->ex_type->tp_up;
arith old_offset, tmpvar;
/* The type in which the bitfield arithmetic is done:
*/
struct type *atype = tp->tp_unsigned ? uword_type : word_type;
arith asize = atype->tp_size;
ASSERT(leftop->ex_type->tp_fund == FIELD);
ASSERT(asize == word_size); /* make sure that C_loc() is legal */
leftop->ex_type = atype; /* this is cheating but it works... */
/* Note that op is either an assignment operator or an increment/
decrement operator
*/
if (op == '=') {
/* F = E: f = ((E & mask)<<shift) | (~(mask<<shift) & f)
*/
EVAL(rightop, RVAL, TRUE, NO_LABEL, NO_LABEL);
conversion(tp, atype);
C_loc(fd->fd_mask);
C_and(asize);
if (code == TRUE)
C_dup(asize);
C_loc((arith)fd->fd_shift);
if (atype->tp_unsigned)
C_slu(asize);
else
C_sli(asize);
C_loc(~((fd->fd_mask << fd->fd_shift) | (~0 << (8 * asize))));
if (leftop->ex_depth == 0) { /* simple case */
load_val(leftop, RVAL);
C_and(asize);
C_ior(asize);
store_val(
&(leftop->ex_object.ex_value),
leftop->ex_type
);
}
else { /* complex case */
tmpvar = tmp_pointer_var(&old_offset);
EVAL(leftop, LVAL, TRUE, NO_LABEL, NO_LABEL);
C_dup(pointer_size);
C_lal(tmpvar);
C_sti(pointer_size);
C_loi(asize);
C_and(asize);
C_ior(asize);
C_lal(tmpvar);
C_loi(pointer_size);
C_sti(asize);
free_tmp_var(old_offset);
}
}
else { /* treat ++F as F += 1 and --F as F -= 1 */
/* F op= e: f = (((((f>>shift)&mask) op e)&mask)<<shift)|
(f&~(mask<<shift))
*/
if (leftop->ex_depth == 0) /* simple case */
load_val(leftop, RVAL);
else { /* complex case */
tmpvar = tmp_pointer_var(&old_offset);
EVAL(leftop, LVAL, TRUE, NO_LABEL, NO_LABEL);
C_dup(pointer_size);
C_lal(tmpvar);
C_sti(pointer_size);
C_loi(asize);
}
C_loc((arith)fd->fd_shift);
if (atype->tp_unsigned)
C_sru(asize);
else
C_sri(asize);
C_loc(fd->fd_mask);
C_and(asize);
if (code == TRUE && (op == POSTINCR || op == POSTDECR))
C_dup(asize);
EVAL(rightop, RVAL, TRUE, NO_LABEL, NO_LABEL);
conversion(tp, atype);
/* generate code for the operator */
if (op == PLUSPLUS || op == POSTINCR)
assop(atype, PLUSAB);
else
if (op == MINMIN || op == POSTDECR)
assop(atype, MINAB);
else
assop(atype, op);
C_loc(fd->fd_mask);
C_and(asize);
if (code == TRUE && op != POSTINCR && op != POSTDECR)
C_dup(asize);
C_loc((arith)fd->fd_shift);
if (atype->tp_unsigned)
C_slu(asize);
else
C_sli(asize);
C_loc(~((fd->fd_mask << fd->fd_shift) | (~0 << (8 * asize))));
if (leftop->ex_depth == 0) {
load_val(leftop, RVAL);
C_and(asize);
C_ior(asize);
store_val(
&(leftop->ex_object.ex_value),
leftop->ex_type
);
}
else {
C_lal(tmpvar);
C_loi(pointer_size);
C_loi(asize);
C_and(asize);
C_ior(asize);
C_lal(tmpvar);
C_loi(pointer_size);
C_sti(asize);
free_tmp_var(old_offset);
}
}
if (code == TRUE) {
/* Take care that the effective value stored in
the bit field (i.e. the value that is got on
retrieval) is on top of stack.
*/
if (atype->tp_unsigned == 0) { /* sign extension */
register arith shift = asize * 8 - fd->fd_width;
C_loc(shift);
C_sli(asize);
C_loc(shift);
C_sri(asize);
}
conversion(atype, tp);
}
}
#endif NOBITFIELD