ack/util/ego/ra/ra_pack.c

415 lines
9.3 KiB
C
Raw Normal View History

1987-03-10 11:49:39 +00:00
/* $Header$ */
1987-03-09 19:15:41 +00:00
/*
* (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands.
* See the copyright notice in the ACK home directory, in the file "Copyright".
*/
1984-11-26 14:35:32 +00:00
/* R E G I S T E R A L L O C A T I O N
*
* R A _ P A C K . C
*/
1991-03-05 12:44:05 +00:00
#include <em_reg.h>
1984-11-26 14:35:32 +00:00
#include "../share/types.h"
#include "../share/debug.h"
#include "../share/def.h"
#include "../share/global.h"
#include "../share/lset.h"
#include "../share/cset.h"
#include "../share/alloc.h"
#include "../share/aux.h"
#include "ra.h"
#include "ra_aux.h"
#include "ra_interv.h"
short regs_occupied[NRREGTYPES]; /* #occupied registers for reg_pointer,
* reg_any etc.
*/
#define reg_available(t) (regs_available[t] > regs_occupied[t])
STATIC initregcount()
1984-11-26 14:35:32 +00:00
{
int t;
for (t = 0; t < NRREGTYPES; t++) {
regs_occupied[t] = 0;
}
}
STATIC alloc_p make_dummy()
{
alloc_p x;
x = newalloc();
/* x->al_profits = 0; */
return x;
}
STATIC bool fits_in(a,b,cont_item)
alloc_p a,b;
bool *cont_item;
{
/* See if allocation a can be assigned the same register as b.
* Both allocations should be of the same register-type.
* Note that there may be several other allocations (mates) assigned to
* the same register as b. A new candidate (i.e. 'a') is only
* allowed to join them if it is not the rival of any resident
* allocation.
*/
*cont_item = FALSE;
if (a->al_regtype == b->al_regtype) {
while (b != (alloc_p) 0) {
if (Cis_elem(a->al_id,b->al_rivals)) break;
b = b->al_mates;
if (b != (alloc_p) 0 && a->al_item == b->al_item) {
1984-11-26 14:35:32 +00:00
*cont_item = TRUE;
}
}
}
return b == (alloc_p) 0;
}
STATIC alloc_p find_fitting_alloc(alloc,packed)
alloc_p alloc,packed;
{
/* Try to find and already packed allocation that is assigned
* a register that may also be used for alloc.
* We prefer allocations that have the same item as alloc.
*/
register alloc_p x;
alloc_p cand = (alloc_p) 0;
bool cont_item;
for (x = packed->al_next; x != (alloc_p) 0; x = x->al_next) {
if (fits_in(alloc,x,&cont_item)) {
cand = x;
if (cont_item) break;
}
}
return cand;
}
STATIC bool room_for(alloc,packed)
alloc_p alloc,packed;
{
/* See if there is any register available for alloc */
return reg_available(alloc->al_regtype) ||
(find_fitting_alloc(alloc,packed) != (alloc_p) 0);
}
STATIC alloc_p best_alloc(unpacked,packed,time_opt)
alloc_p unpacked,packed;
bool time_opt; /* now unused */
1984-11-26 14:35:32 +00:00
{
/* Find the next best candidate */
register alloc_p x,best;
best = unpacked; /* dummy */
for (x = unpacked->al_next; x != (alloc_p) 0; x = x->al_next) {
if (x->al_profits > best->al_profits &&
room_for(x,packed)) {
best = x;
1984-11-26 14:35:32 +00:00
}
}
return (best == unpacked ? (alloc_p) 0 : best);
}
STATIC alloc_p choose_location(alloc,packed,p)
alloc_p alloc,packed;
proc_p p;
{
/* Decide in which register to put alloc */
alloc_p fit;
offset dum;
fit = find_fitting_alloc(alloc,packed);
if (fit == (alloc_p) 0) {
/* Take a brand new register; allocate a dummy local for it */
alloc->al_regnr = regs_occupied[alloc->al_regtype]++;
dum = tmplocal(p,(offset) alloc->al_item->it_size);
1984-11-26 14:35:32 +00:00
alloc->al_dummy = dum;
} else {
alloc->al_regnr = fit->al_regnr;
alloc->al_dummy = fit->al_dummy;
}
return fit;
}
STATIC update_lists(alloc,unpacked,packed,fit)
alloc_p alloc,unpacked,packed,fit;
{
/* 'alloc' has been granted a register; move it from the 'unpacked'
* list to the 'packed' list. Also remove any allocation from 'unpacked'
* having:
* 1. the same item as 'alloc' and
* 2. a timespan that overlaps the timespan of alloc.
*/
register alloc_p x,q,next;
q = unpacked; /* dummy element at head of list */
for (x = unpacked->al_next; x != (alloc_p) 0; x = next) {
next = x->al_next;
if (x->al_item == alloc->al_item &&
not_disjoint(x->al_timespan, alloc->al_timespan)) {
/* this code kills two birds with one stone;
* x is either an overlapping allocation or
* alloc itself!
*/
q->al_next = x->al_next;
if (x == alloc) {
if (fit == (alloc_p) 0) {
x->al_next = packed->al_next;
packed->al_next = x;
} else {
x->al_mates = fit->al_mates;
fit->al_mates = x;
x->al_next = (alloc_p) 0;
}
}
} else {
q = x;
}
}
}
STATIC short cum_profits(alloc)
alloc_p alloc;
{
/* Add the profits of all allocations packed in the same
* register as alloc (i.e. alloc and all its 'mates').
*/
alloc_p m;
short sum = 0;
for (m = alloc; m != (alloc_p) 0; m = m->al_mates) {
sum += m->al_profits;
}
return sum;
}
STATIC alloc_p best_cumprofits(list,x_out,prev_out)
alloc_p list, *x_out, *prev_out;
{
/* Find the allocation with the best cummulative profits */
register alloc_p x,prev,best_prev;
short best = 0, cum;
prev = list;
for (x = list->al_next; x != (alloc_p) 0; x = x->al_next) {
cum = cum_profits(x);
if (cum > best) {
best = cum;
best_prev = prev;
}
prev = x;
}
if (best == 0) {
*x_out = (alloc_p) 0;
} else {
*x_out = best_prev->al_next;
*prev_out = best_prev;
}
}
STATIC account_regsave(packed,unpacked)
alloc_p packed,unpacked;
{
/* After all packing has been done, we check for every allocated
* register whether it is really advantageous to use this
* register. It may be possible that the cost of saving
* and restoring the register are higher than the profits of all
* allocations packed in the register. If so, we simply remove
* all these allocations.
* The cost of saving/restoring one extra register may depend on
* the number of registers already saved.
*/
alloc_p x,prev,checked;
short time,space;
short tot_cost = 0,diff;
initregcount();
1984-11-26 14:35:32 +00:00
checked = make_dummy();
while (TRUE) {
best_cumprofits(packed,&x,&prev);
if (x == (alloc_p) 0) break;
regs_occupied[x->al_regtype]++;
regsave_cost(regs_occupied,&time,&space);
diff = add_timespace(time,space) - tot_cost;
if (diff < cum_profits(x)) {
/* x is o.k. */
prev->al_next = x->al_next;
x->al_next = checked->al_next;
checked->al_next = x;
tot_cost += diff;
} else {
break;
}
}
/* Now every allocation in 'packed' does not pay off, so
* it is moved to unpacked, indicating it will not be assigned
* a register.
*/
for (x = unpacked; x->al_next != (alloc_p) 0; x = x->al_next);
x->al_next = packed->al_next;
packed->al_next = checked->al_next;
oldalloc(checked);
}
STATIC bool in_single_reg(item,packed)
item_p item;
alloc_p packed;
{
/* See if item is allocated in only one register (i.e. not in
* several different registers during several parts of its lifetime.
*/
register alloc_p x,m;
bool seen = FALSE;
for (x = packed->al_next; x != (alloc_p) 0; x = x->al_next) {
for ( m = x; m != (alloc_p) 0; m = m->al_mates) {
if (m->al_item == item) {
if (seen) return FALSE;
seen = TRUE;
break;
}
}
}
return TRUE;
}
STATIC alloc_p find_prev(alloc,list)
alloc_p alloc,list;
{
register alloc_p x;
assert ( alloc != (alloc_p) 0);
for (x = list; x->al_next != alloc ; x = x->al_next)
assert(x != (alloc_p) 0);
return x;
}
/* If an item is always put in the same register during different loops,
* we try to put it in that register during the whole procedure.
* The profits of the whole-procedure allocation are updated to prevent
* account_regsave from rejecting it.
*/
1984-11-26 14:35:32 +00:00
STATIC repl_allocs(new,old,packed)
alloc_p new,old,packed;
{
alloc_p x,next,prev,*p;
short prof = 0;
1984-11-26 14:35:32 +00:00
new->al_regnr = old->al_regnr;
new->al_dummy = old->al_dummy;
prev = find_prev(old,packed);
new->al_next = old->al_next;
old->al_next = (alloc_p) 0;
prev->al_next = new;
new->al_mates = old;
p = &new->al_mates;
for (x = old; x != (alloc_p) 0; x = next) {
next = x->al_mates;
if (x->al_item == new->al_item) {
prof += x->al_profits;
1984-11-26 14:35:32 +00:00
*p = next;
oldalloc(x);
} else {
p = &x->al_mates;
}
}
new->al_profits = prof;
1984-11-26 14:35:32 +00:00
}
STATIC assemble_allocs(packed)
alloc_p packed;
{
register alloc_p x,m,next;
alloc_p e;
bool voidb;
for (x = packed->al_next; x != (alloc_p) 0; x = next) {
next = x->al_next;
for ( m = x; m != (alloc_p) 0; m = m->al_mates) {
if (in_single_reg(m->al_item,packed) &&
(e = m->al_wholeproc) != (alloc_p) 0 &&
e->al_profits > 0 &&
fits_in(e,x,&voidb)) {
repl_allocs(e,x,packed);
break;
}
}
}
}
pack(alloclist,time_opt,packed_out,not_packed_out,p)
alloc_p alloclist, *packed_out,*not_packed_out;
bool time_opt;
proc_p p;
{
/* This is the packing system. It decides which allations
* to grant a register.
* We use two lists: packed (for allocations that are assigned a
* register) and unpacked (allocations not yet assigned a register).
* The packed list is in fact '2-dimensional': the al_next field is
* used to link allations that are assigned different registers;
* the al_mates field links allocations that are assigned to
* the same registers (i.e. these allocations fit together).
*/
register alloc_p x;
alloc_p packed,unpacked,fit;
initregcount();
1984-11-26 14:35:32 +00:00
packed = make_dummy();
unpacked = make_dummy();
unpacked->al_next = alloclist;
while ((x = best_alloc(unpacked,packed,time_opt)) != (alloc_p) 0) {
fit = choose_location(x,packed,p);
update_lists(x,unpacked,packed,fit);
}
assemble_allocs(packed);
account_regsave(packed,unpacked);
/* remove allocations that don't pay off against register
* save/restore costs.
*/
*packed_out = packed->al_next;
*not_packed_out = unpacked->al_next;
oldalloc(packed);
oldalloc(unpacked);
}