/* $Header$ */
/*
* (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands.
* See the copyright notice in the ACK home directory, in the file "Copyright".
*/
/* S H A R E D F I L E
*
* A U X I L I A R Y R O U T I N E S
*
*/
#include "../share/types.h"
#include "../share/debug.h"
#include "../share/global.h"
#include "../share/alloc.h"
#include "../share/aux.h"
#include "../share/map.h"
#include "../share/lset.h"
#include "../../../h/em_mes.h"
#include "../../../h/em_pseu.h"
offset off_set(lnp)
line_p lnp;
{
switch(lnp->l_optype) {
case OPSHORT:
return (offset) SHORT(lnp);
case OPOFFSET:
return OFFSET(lnp);
default:
assert(FALSE);
}
/* NOTREACHED */
}
offset aoff(ap,n)
register arg_p ap;
{
while (n>0) {
if (ap != (arg_p) 0)
ap = ap->a_next;
n--;
}
if (ap == (arg_p) 0)
error("too few parameters");
if (ap->a_type != ARGOFF)
error("offset expected");
return(ap->a_a.a_offset);
}
offset tmplocal(p,size)
proc_p p;
offset size;
{
/* Allocate a new local variable in the stack frame of p */
p->p_localbytes += size;
return -(p->p_localbytes);
}
line_p int_line(off)
offset off;
{
/* Allocate a line struct of type OPSHORT or OPOFFSET,
* whichever one fits best.
*/
line_p lnp;
if ((short) off == off) {
/* fits in a short */
lnp = newline(OPSHORT);
SHORT(lnp) = (short) off;
} else {
lnp = newline(OPOFFSET);
OFFSET(lnp) = off;
}
return lnp;
}
line_p reg_mes(tmp,size,typ,score)
offset tmp;
short size;
int typ,score;
{
/* Generate a register message */
line_p l;
arg_p a;
#define NEXTARG(a,val) a->a_next = newarg(ARGOFF); a = a->a_next; \
a->a_a.a_offset = val
l = newline(OPLIST);
l->l_instr = ps_mes;
a = ARG(l) = newarg(ARGOFF);
a->a_a.a_offset = ms_reg;
NEXTARG(a,tmp);
NEXTARG(a,size);
NEXTARG(a,typ);
NEXTARG(a,score);
return l;
}
bool dom(b1,b2)
bblock_p b1,b2;
{
/* See if b1 dominates b2. Note that a block always
* dominates itself.
*/
register bblock_p b;
for (b = b2; b != (bblock_p) 0; b = b->b_idom) {
/* See if b1 is a (not necessarily proper) ancestor
* of b2 in the immediate dominator tree.
*/
if (b == b1) return TRUE;
}
return FALSE;
}
bblock_p common_dom(a,b)
bblock_p a,b;
{
/* find a basic block that dominates a as well as b;
* note that a basic block also dominates itself.
*/
assert (a != (bblock_p) 0);
assert (b != (bblock_p) 0);
if (dom(a,b)) {
return a;
} else {
if (dom(b,a)) {
return b;
} else {
return common_dom(a->b_idom,b->b_idom);
}
}
}
#define R time_space_ratio
short add_timespace(time,space)
short time,space;
{
/* Add together a time and space, using the time_space_ratio
* parameter that may be set by the user, indicating the need
* to optimize for time, space or something in between.
*/
return (R * time + (100 - R) * space) / 100;
}
rm_line(l,b)
line_p l;
bblock_p b;
{
if (b->b_start == l) {
b->b_start = l->l_next;
} else {
PREV(l)->l_next = l->l_next;
}
if (l->l_next != (line_p) 0) {
PREV(l->l_next) = PREV(l);
}
oldline(l);
}
appnd_line(l1,l2)
line_p l1,l2;
{
/* Put l1 after l2 */
PREV(l1) = l2;
l1->l_next = l2->l_next;
l2->l_next = l1;
if (l1->l_next != (line_p) 0) {
PREV(l1->l_next) = l1;
}
}
line_p last_instr(b)
bblock_p b;
{
/* Determine the last line of a list */
register line_p l = b->b_start;
if (l == (line_p) 0) return (line_p) 0;
while (l->l_next != (line_p) 0) l = l->l_next;
return l;
}
line_p find_mesreg(off)
offset off;
{
/* Find the register message for the local with the given offset */
Lindex li;
line_p l;
for (li = Lfirst(mesregs); li != (Lindex) 0; li = Lnext(li,mesregs)) {
l = (line_p) Lelem(li);
if (aoff(ARG(l),1) == off) return l;
}
return (line_p) 0;
}
bool is_regvar(off)
offset off;
{
return find_mesreg(off) != (line_p) 0;
}
offset regv_arg(off,n)
offset off;
int n;
{
/* fetch the n'th argument of the register message of the
* local variable at offset off;
*/
line_p x = find_mesreg(off);
assert (x != (line_p) 0);
return aoff(ARG(x),n);
}