/* $Id$ */ /* * (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands. * See the copyright notice in the ACK home directory, in the file "Copyright". */ /* R E G I S T E R A L L O C A T I O N * * R A _ I N T E R V A L . C */ #include #include #include "../share/types.h" #include "../share/debug.h" #include "../share/global.h" #include "../share/alloc.h" #include "../share/lset.h" #include "ra.h" #include "ra_interv.h" interv_p cons_interval(short t_start, short t_stop) { interv_p x; x = newinterval(); x->i_start = t_start; x->i_stop = t_stop; return x; } void add_interval(short t1, short t2, interv_p *list) { /* Add interval (t1,t2) to the list of intervals (which is * an in-out parameter!). The list is sorted in 'chronological' * order. We attempt to keep the list as small as possible, by * putting adjacent intervals in one interval. */ register interv_p x1, x2, *q; int adjacent = 0; interv_p x; q = list; x1 = (interv_p) 0; for (x2 = *list; x2 != (interv_p) 0; x2 = x2->i_next) { if (t2 < x2->i_start) break; x1 = x2; q = &x2->i_next; } /* Now interval (t1,t2) should be inserted somewhere in between * x1 and x2. */ if (x1 != (interv_p) 0 && t1 == x1->i_stop + 1) { /* join x1 and (t1,t2) */ x1->i_stop = t2; adjacent++; } if (x2 != (interv_p) 0 && t2 + 1 == x2->i_start) { /* join (t1,t2) and x2 */ x2->i_start = t1; adjacent++; } if (adjacent == 0) { /* no adjacents, allocate a new intervalfor (t1,t2) */ x = cons_interval(t1,t2); x->i_next = x2; *q = x; } else { if (adjacent == 2) { /* x1, (t1,t2) and x2 can be put in one interval */ x1->i_stop = x2->i_stop; x1->i_next = x2->i_next; oldinterval(x2); } } } interv_p loop_lifetime(lp) loop_p lp; { /* Determine the timespan of the loop, expressed as a list * of intervals. */ interv_p lt = 0; register bblock_p b; register Lindex bi; for (bi = Lfirst(lp->LP_BLOCKS); bi != (Lindex) 0; bi = Lnext(bi,lp->LP_BLOCKS)) { b = (bblock_p) Lelem(bi); add_interval(b->B_BEGIN,b->B_END,<); } return lt; } interv_p proc_lifetime(p) proc_p p; { /* Determine the lifetime of an entire procedure */ register bblock_p b; for (b = p->p_start; b->b_next != (bblock_p) 0; b = b->b_next) ; return cons_interval(0,b->B_END); } STATIC void set_min_max(iv1,iv2) interv_p *iv1,*iv2; { /* Auxiliary routine of intersect */ interv_p i1 = *iv1, i2 = *iv2; if (i1->i_start < i2->i_start) { *iv1 = i1; *iv2 = i2; } else { *iv1 = i2; *iv2 = i1; } } interv_p intersect(list1,list2) interv_p list1,list2; { /* Intersect two lifetimes, each denoted by a list of intervals. * We maintain two pointers, pmin and pmax, pointing to the * next interval of each list. At any time, pmin points to the * interval of which i_start is lowest; pmax points to the * other interval (i.e. the next interval of the other list). */ interv_p lt = 0; interv_p pmin,pmax; #define BUMP(p) p = p->i_next #define EMIT(t1,t2) add_interval(t1,t2,<) pmin = list1; pmax = list2; while (pmin != (interv_p) 0 && pmax != (interv_p) 0) { set_min_max(&pmin,&pmax); if (pmax->i_start > pmin->i_stop) { /* e.g. (5,7) and (9,13) */ BUMP(pmin); } else { if (pmax->i_stop < pmin->i_stop) { /* e.g. (5,12) and (7,10) */ EMIT(pmax->i_start,pmax->i_stop); BUMP(pmax); } else { /* e.g. (5,8) and (7,12) */ EMIT(pmax->i_start,pmin->i_stop); if (pmax->i_stop == pmin->i_stop) { /* e.g. (5,12) and (7,12) */ BUMP(pmax); } BUMP(pmin); } } } return lt; } bool not_disjoint(list1,list2) interv_p list1,list2; { /* See if list1 and list2 do overlap somewhere */ interv_p pmin,pmax; pmin = list1; pmax = list2; while (pmin != (interv_p) 0 && pmax != (interv_p) 0) { set_min_max(&pmin,&pmax); if (pmax->i_start > pmin->i_stop) { /* e.g. (5,7) and (9,13) */ BUMP(pmin); } else { return TRUE; /* not disjoint */ } } return FALSE; /* disjoint */ } bool contains(short t, interv_p timespan) { register interv_p iv; for (iv = timespan; iv != (interv_p) 0; iv = iv->i_next) { if (t <= iv->i_stop) return (t >= iv->i_start); } return FALSE; } interv_p copy_timespan(list) interv_p list; { /* copy the time span */ interv_p x,y,head,*p; head = (interv_p) 0; p = &head; for (x = list; x != (interv_p) 0; x = x->i_next) { y = cons_interval(x->i_start,x->i_stop); *p = y; p = &y->i_next; } return head; }