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[/] [eco32/] [trunk/] [lcc/] [src/] [gen.c] - Rev 4
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#include "c.h" static char rcsid[] = "$Id: gen.c,v 1.1 2002/08/28 23:12:43 drh Exp $"; #define readsreg(p) \ (generic((p)->op)==INDIR && (p)->kids[0]->op==VREG+P) #define setsrc(d) ((d) && (d)->x.regnode && \ (d)->x.regnode->set == src->x.regnode->set && \ (d)->x.regnode->mask&src->x.regnode->mask) #define relink(a, b) ((b)->x.prev = (a), (a)->x.next = (b)) static Symbol askfixedreg(Symbol); static Symbol askreg(Symbol, unsigned*); static void blkunroll(int, int, int, int, int, int, int[]); static void docall(Node); static void dumpcover(Node, int, int); static void dumpregs(char *, char *, char *); static void dumprule(int); static void dumptree(Node); static void genreload(Node, Symbol, int); static void genspill(Symbol, Node, Symbol); static Symbol getreg(Symbol, unsigned*, Node); static int getrule(Node, int); static void linearize(Node, Node); static int moveself(Node); static void prelabel(Node); static Node* prune(Node, Node*); static void putreg(Symbol); static void ralloc(Node); static void reduce(Node, int); static int reprune(Node*, int, int, Node); static int requate(Node); static Node reuse(Node, int); static void rewrite(Node); static Symbol spillee(Symbol, unsigned mask[], Node); static void spillr(Symbol, Node); static int uses(Node, Regnode); int offset; int maxoffset; int framesize; int argoffset; int maxargoffset; int dalign, salign; int bflag = 0; /* omit */ int dflag = 0; int swap; unsigned (*emitter)(Node, int) = emitasm; static char NeedsReg[] = { 0, /* unused */ 1, /* CNST */ 0, 0, /* ARG ASGN */ 1, /* INDIR */ 0, 0, 1, 1, /* - - CVF CVI */ 1, 0, 1, 1, /* CVP - CVU NEG */ 1, /* CALL */ 1, /* LOAD */ 0, /* RET */ 1, 1, 1, /* ADDRG ADDRF ADDRL */ 1, 1, 1, 1, 1, /* ADD SUB LSH MOD RSH */ 1, 1, 1, 1, /* BAND BCOM BOR BXOR */ 1, 1, /* DIV MUL */ 0, 0, 0, 0, 0, 0, /* EQ GE GT LE LT NE */ 0, 0 /* JUMP LABEL */ }; Node head; unsigned freemask[2]; unsigned usedmask[2]; unsigned tmask[2]; unsigned vmask[2]; Symbol mkreg(char *fmt, int n, int mask, int set) { Symbol p; NEW0(p, PERM); p->name = p->x.name = stringf(fmt, n); NEW0(p->x.regnode, PERM); p->x.regnode->number = n; p->x.regnode->mask = mask<<n; p->x.regnode->set = set; return p; } Symbol mkwildcard(Symbol *syms) { Symbol p; NEW0(p, PERM); p->name = p->x.name = "wildcard"; p->x.wildcard = syms; return p; } void mkauto(Symbol p) { assert(p->sclass == AUTO); offset = roundup(offset + p->type->size, p->type->align); p->x.offset = -offset; p->x.name = stringd(-offset); } void blockbeg(Env *e) { e->offset = offset; e->freemask[IREG] = freemask[IREG]; e->freemask[FREG] = freemask[FREG]; } void blockend(Env *e) { if (offset > maxoffset) maxoffset = offset; offset = e->offset; freemask[IREG] = e->freemask[IREG]; freemask[FREG] = e->freemask[FREG]; } int mkactual(int align, int size) { int n = roundup(argoffset, align); argoffset = n + size; return n; } static void docall(Node p) { p->syms[1] = p->syms[0]; p->syms[0] = intconst(argoffset); if (argoffset > maxargoffset) maxargoffset = argoffset; argoffset = 0; } void blkcopy(int dreg, int doff, int sreg, int soff, int size, int tmp[]) { assert(size >= 0); if (size == 0) return; else if (size <= 2) blkunroll(size, dreg, doff, sreg, soff, size, tmp); else if (size == 3) { blkunroll(2, dreg, doff, sreg, soff, 2, tmp); blkunroll(1, dreg, doff+2, sreg, soff+2, 1, tmp); } else if (size <= 16) { blkunroll(4, dreg, doff, sreg, soff, size&~3, tmp); blkcopy(dreg, doff+(size&~3), sreg, soff+(size&~3), size&3, tmp); } else (*IR->x.blkloop)(dreg, doff, sreg, soff, size, tmp); } static void blkunroll(int k, int dreg, int doff, int sreg, int soff, int size, int tmp[]) { int i; assert(IR->x.max_unaligned_load); if (k > IR->x.max_unaligned_load && (k > salign || k > dalign)) k = IR->x.max_unaligned_load; for (i = 0; i+k < size; i += 2*k) { (*IR->x.blkfetch)(k, soff+i, sreg, tmp[0]); (*IR->x.blkfetch)(k, soff+i+k, sreg, tmp[1]); (*IR->x.blkstore)(k, doff+i, dreg, tmp[0]); (*IR->x.blkstore)(k, doff+i+k, dreg, tmp[1]); } if (i < size) { (*IR->x.blkfetch)(k, i+soff, sreg, tmp[0]); (*IR->x.blkstore)(k, i+doff, dreg, tmp[0]); } } void parseflags(int argc, char *argv[]) { int i; for (i = 0; i < argc; i++) if (strcmp(argv[i], "-d") == 0) dflag = 1; else if (strcmp(argv[i], "-b") == 0) /* omit */ bflag = 1; /* omit */ } static int getrule(Node p, int nt) { int rulenum; assert(p); rulenum = (*IR->x._rule)(p->x.state, nt); if (!rulenum) { fprint(stderr, "(%x->op=%s at %w is corrupt.)\n", p, opname(p->op), &src); assert(0); } return rulenum; } static void reduce(Node p, int nt) { int rulenum, i; short *nts; Node kids[10]; p = reuse(p, nt); rulenum = getrule(p, nt); nts = IR->x._nts[rulenum]; (*IR->x._kids)(p, rulenum, kids); for (i = 0; nts[i]; i++) reduce(kids[i], nts[i]); if (IR->x._isinstruction[rulenum]) { assert(p->x.inst == 0 || p->x.inst == nt); p->x.inst = nt; if (p->syms[RX] && p->syms[RX]->temporary) { debug(fprint(stderr, "(using %s)\n", p->syms[RX]->name)); p->syms[RX]->x.usecount++; } } } static Node reuse(Node p, int nt) { struct _state { short cost[1]; }; Symbol r = p->syms[RX]; if (generic(p->op) == INDIR && p->kids[0]->op == VREG+P && r->u.t.cse && p->x.mayrecalc && ((struct _state*)r->u.t.cse->x.state)->cost[nt] == 0) return r->u.t.cse; else return p; } int mayrecalc(Node p) { int op; assert(p && p->syms[RX]); if (p->syms[RX]->u.t.cse == NULL) return 0; op = generic(p->syms[RX]->u.t.cse->op); if (op == CNST || op == ADDRF || op == ADDRG || op == ADDRL) { p->x.mayrecalc = 1; return 1; } else return 0; } static Node *prune(Node p, Node pp[]) { if (p == NULL) return pp; p->x.kids[0] = p->x.kids[1] = p->x.kids[2] = NULL; if (p->x.inst == 0) return prune(p->kids[1], prune(p->kids[0], pp)); else if (p->syms[RX] && p->syms[RX]->temporary && p->syms[RX]->x.usecount < 2) { p->x.inst = 0; debug(fprint(stderr, "(clobbering %s)\n", p->syms[RX]->name)); return prune(p->kids[1], prune(p->kids[0], pp)); } else { prune(p->kids[1], prune(p->kids[0], &p->x.kids[0])); *pp = p; return pp + 1; } } #define ck(i) return (i) ? 0 : LBURG_MAX int range(Node p, int lo, int hi) { Symbol s = p->syms[0]; switch (specific(p->op)) { case ADDRF+P: case ADDRL+P: ck(s->x.offset >= lo && s->x.offset <= hi); case CNST+I: ck(s->u.c.v.i >= lo && s->u.c.v.i <= hi); case CNST+U: ck(s->u.c.v.u >= lo && s->u.c.v.u <= hi); case CNST+P: ck(s->u.c.v.p == 0 && lo <= 0 && hi >= 0); } return LBURG_MAX; } static void dumptree(Node p) { if (p->op == VREG+P && p->syms[0]) { fprint(stderr, "VREGP(%s)", p->syms[0]->name); return; } else if (generic(p->op) == LOAD) { fprint(stderr, "LOAD("); dumptree(p->kids[0]); fprint(stderr, ")"); return; } fprint(stderr, "%s(", opname(p->op)); switch (generic(p->op)) { case CNST: case LABEL: case ADDRG: case ADDRF: case ADDRL: if (p->syms[0]) fprint(stderr, "%s", p->syms[0]->name); break; case RET: if (p->kids[0]) dumptree(p->kids[0]); break; case CVF: case CVI: case CVP: case CVU: case JUMP: case ARG: case BCOM: case NEG: case INDIR: dumptree(p->kids[0]); break; case CALL: if (optype(p->op) != B) { dumptree(p->kids[0]); break; } /* else fall thru */ case EQ: case NE: case GT: case GE: case LE: case LT: case ASGN: case BOR: case BAND: case BXOR: case RSH: case LSH: case ADD: case SUB: case DIV: case MUL: case MOD: dumptree(p->kids[0]); fprint(stderr, ", "); dumptree(p->kids[1]); break; default: assert(0); } fprint(stderr, ")"); } static void dumpcover(Node p, int nt, int in) { int rulenum, i; short *nts; Node kids[10]; p = reuse(p, nt); rulenum = getrule(p, nt); nts = IR->x._nts[rulenum]; fprint(stderr, "dumpcover(%x) = ", p); for (i = 0; i < in; i++) fprint(stderr, " "); dumprule(rulenum); (*IR->x._kids)(p, rulenum, kids); for (i = 0; nts[i]; i++) dumpcover(kids[i], nts[i], in+1); } static void dumprule(int rulenum) { assert(rulenum); fprint(stderr, "%s / %s", IR->x._string[rulenum], IR->x._templates[rulenum]); if (!IR->x._isinstruction[rulenum]) fprint(stderr, "\n"); } unsigned emitasm(Node p, int nt) { int rulenum; short *nts; char *fmt; Node kids[10]; p = reuse(p, nt); rulenum = getrule(p, nt); nts = IR->x._nts[rulenum]; fmt = IR->x._templates[rulenum]; assert(fmt); if (IR->x._isinstruction[rulenum] && p->x.emitted) print("%s", p->syms[RX]->x.name); else if (*fmt == '#') (*IR->x.emit2)(p); else { if (*fmt == '?') { fmt++; assert(p->kids[0]); if (p->syms[RX] == p->x.kids[0]->syms[RX]) while (*fmt++ != '\n') ; } for ((*IR->x._kids)(p, rulenum, kids); *fmt; fmt++) if (*fmt != '%') (void)putchar(*fmt); else if (*++fmt == 'F') print("%d", framesize); else if (*fmt >= '0' && *fmt <= '9') emitasm(kids[*fmt - '0'], nts[*fmt - '0']); else if (*fmt >= 'a' && *fmt < 'a' + NELEMS(p->syms)) fputs(p->syms[*fmt - 'a']->x.name, stdout); else (void)putchar(*fmt); } return 0; } void emit(Node p) { for (; p; p = p->x.next) { assert(p->x.registered); if (p->x.equatable && requate(p) || moveself(p)) ; else (*emitter)(p, p->x.inst); p->x.emitted = 1; } } static int moveself(Node p) { return p->x.copy && p->syms[RX]->x.name == p->x.kids[0]->syms[RX]->x.name; } int move(Node p) { p->x.copy = 1; return 1; } static int requate(Node q) { Symbol src = q->x.kids[0]->syms[RX]; Symbol tmp = q->syms[RX]; Node p; int n = 0; debug(fprint(stderr, "(requate(%x): tmp=%s src=%s)\n", q, tmp->x.name, src->x.name)); for (p = q->x.next; p; p = p->x.next) if (p->x.copy && p->syms[RX] == src && p->x.kids[0]->syms[RX] == tmp) debug(fprint(stderr, "(requate arm 0 at %x)\n", p)), p->syms[RX] = tmp; else if (setsrc(p->syms[RX]) && !moveself(p) && !readsreg(p)) return 0; else if (p->x.spills) return 0; else if (generic(p->op) == CALL && p->x.next) return 0; else if (p->op == LABEL+V && p->x.next) return 0; else if (p->syms[RX] == tmp && readsreg(p)) debug(fprint(stderr, "(requate arm 5 at %x)\n", p)), n++; else if (p->syms[RX] == tmp) break; debug(fprint(stderr, "(requate arm 7 at %x)\n", p)); assert(n > 0); for (p = q->x.next; p; p = p->x.next) if (p->syms[RX] == tmp && readsreg(p)) { p->syms[RX] = src; if (--n <= 0) break; } return 1; } static void prelabel(Node p) { if (p == NULL) return; prelabel(p->kids[0]); prelabel(p->kids[1]); if (NeedsReg[opindex(p->op)]) setreg(p, (*IR->x.rmap)(opkind(p->op))); switch (generic(p->op)) { case ADDRF: case ADDRL: if (p->syms[0]->sclass == REGISTER) p->op = VREG+P; break; case INDIR: if (p->kids[0]->op == VREG+P) setreg(p, p->kids[0]->syms[0]); break; case ASGN: if (p->kids[0]->op == VREG+P) rtarget(p, 1, p->kids[0]->syms[0]); break; case CVI: case CVU: case CVP: if (optype(p->op) != F && opsize(p->op) <= p->syms[0]->u.c.v.i) p->op = LOAD + opkind(p->op); break; } (IR->x.target)(p); } void setreg(Node p, Symbol r) { p->syms[RX] = r; } void rtarget(Node p, int n, Symbol r) { Node q = p->kids[n]; assert(q); assert(r); assert(r->sclass == REGISTER || !r->x.wildcard); assert(q->syms[RX]); if (r != q->syms[RX] && !q->syms[RX]->x.wildcard) { q = newnode(LOAD + opkind(q->op), q, NULL, q->syms[0]); if (r->u.t.cse == p->kids[n]) r->u.t.cse = q; p->kids[n] = p->x.kids[n] = q; q->x.kids[0] = q->kids[0]; } setreg(q, r); debug(fprint(stderr, "(targeting %x->x.kids[%d]=%x to %s)\n", p, n, p->kids[n], r->x.name)); } static void rewrite(Node p) { assert(p->x.inst == 0); prelabel(p); debug(dumptree(p)); debug(fprint(stderr, "\n")); (*IR->x._label)(p); debug(dumpcover(p, 1, 0)); reduce(p, 1); } Node gen(Node forest) { int i; struct node sentinel; Node dummy, p; head = forest; for (p = forest; p; p = p->link) { assert(p->count == 0); if (generic(p->op) == CALL) docall(p); else if ( generic(p->op) == ASGN && generic(p->kids[1]->op) == CALL) docall(p->kids[1]); else if (generic(p->op) == ARG) (*IR->x.doarg)(p); rewrite(p); p->x.listed = 1; } for (p = forest; p; p = p->link) prune(p, &dummy); relink(&sentinel, &sentinel); for (p = forest; p; p = p->link) linearize(p, &sentinel); forest = sentinel.x.next; assert(forest); sentinel.x.next->x.prev = NULL; sentinel.x.prev->x.next = NULL; for (p = forest; p; p = p->x.next) for (i = 0; i < NELEMS(p->x.kids) && p->x.kids[i]; i++) { assert(p->x.kids[i]->syms[RX]); if (p->x.kids[i]->syms[RX]->temporary) { p->x.kids[i]->x.prevuse = p->x.kids[i]->syms[RX]->x.lastuse; p->x.kids[i]->syms[RX]->x.lastuse = p->x.kids[i]; } } for (p = forest; p; p = p->x.next) { ralloc(p); if (p->x.listed && NeedsReg[opindex(p->op)] && (*IR->x.rmap)(opkind(p->op))) { assert(generic(p->op) == CALL || generic(p->op) == LOAD); putreg(p->syms[RX]); } } return forest; } int notarget(Node p) { return p->syms[RX]->x.wildcard ? 0 : LBURG_MAX; } static void putreg(Symbol r) { assert(r && r->x.regnode); freemask[r->x.regnode->set] |= r->x.regnode->mask; debug(dumpregs("(freeing %s)\n", r->x.name, NULL)); } static Symbol askfixedreg(Symbol s) { Regnode r = s->x.regnode; int n = r->set; if (r->mask&~freemask[n]) return NULL; else { freemask[n] &= ~r->mask; usedmask[n] |= r->mask; return s; } } static Symbol askreg(Symbol rs, unsigned rmask[]) { int i; if (rs->x.wildcard == NULL) return askfixedreg(rs); for (i = 31; i >= 0; i--) { Symbol r = rs->x.wildcard[i]; if (r != NULL && !(r->x.regnode->mask&~rmask[r->x.regnode->set]) && askfixedreg(r)) return r; } return NULL; } static Symbol getreg(Symbol s, unsigned mask[], Node p) { Symbol r = askreg(s, mask); if (r == NULL) { r = spillee(s, mask, p); assert(r && r->x.regnode); spill(r->x.regnode->mask, r->x.regnode->set, p); r = askreg(s, mask); } assert(r && r->x.regnode); r->x.regnode->vbl = NULL; return r; } int askregvar(Symbol p, Symbol regs) { Symbol r; assert(p); if (p->sclass != REGISTER) return 0; else if (!isscalar(p->type)) { p->sclass = AUTO; return 0; } else if (p->temporary) { p->x.name = "?"; return 1; } else if ((r = askreg(regs, vmask)) != NULL) { p->x.regnode = r->x.regnode; p->x.regnode->vbl = p; p->x.name = r->x.name; debug(dumpregs("(allocating %s to symbol %s)\n", p->x.name, p->name)); return 1; } else { p->sclass = AUTO; return 0; } } static void linearize(Node p, Node next) { int i; for (i = 0; i < NELEMS(p->x.kids) && p->x.kids[i]; i++) linearize(p->x.kids[i], next); relink(next->x.prev, p); relink(p, next); debug(fprint(stderr, "(listing %x)\n", p)); } static void ralloc(Node p) { int i; unsigned mask[2]; mask[0] = tmask[0]; mask[1] = tmask[1]; assert(p); debug(fprint(stderr, "(rallocing %x)\n", p)); for (i = 0; i < NELEMS(p->x.kids) && p->x.kids[i]; i++) { Node kid = p->x.kids[i]; Symbol r = kid->syms[RX]; assert(r && kid->x.registered); if (r->sclass != REGISTER && r->x.lastuse == kid) putreg(r); } if (!p->x.registered && NeedsReg[opindex(p->op)] && (*IR->x.rmap)(opkind(p->op))) { Symbol sym = p->syms[RX], set = sym; assert(sym); if (sym->temporary) set = (*IR->x.rmap)(opkind(p->op)); assert(set); if (set->sclass != REGISTER) { Symbol r; if (*IR->x._templates[getrule(p, p->x.inst)] == '?') for (i = 1; i < NELEMS(p->x.kids) && p->x.kids[i]; i++) { Symbol r = p->x.kids[i]->syms[RX]; assert(p->x.kids[i]->x.registered); assert(r && r->x.regnode); assert(sym->x.wildcard || sym != r); mask[r->x.regnode->set] &= ~r->x.regnode->mask; } r = getreg(set, mask, p); if (sym->temporary) { Node q; r->x.lastuse = sym->x.lastuse; for (q = sym->x.lastuse; q; q = q->x.prevuse) { q->syms[RX] = r; q->x.registered = 1; if (sym->u.t.cse && q->x.copy) q->x.equatable = 1; } } else { p->syms[RX] = r; r->x.lastuse = p; } debug(dumpregs("(allocating %s to node %x)\n", r->x.name, (char *) p)); } } p->x.registered = 1; (*IR->x.clobber)(p); } static Symbol spillee(Symbol set, unsigned mask[], Node here) { Symbol bestreg = NULL; int bestdist = -1, i; assert(set); if (!set->x.wildcard) bestreg = set; else { for (i = 31; i >= 0; i--) { Symbol ri = set->x.wildcard[i]; if ( ri != NULL && ri->x.lastuse && (ri->x.regnode->mask&tmask[ri->x.regnode->set]&mask[ri->x.regnode->set]) ) { Regnode rn = ri->x.regnode; Node q = here; int dist = 0; for (; q && !uses(q, rn); q = q->x.next) dist++; if (q && dist > bestdist) { bestdist = dist; bestreg = ri; } } } } assert(bestreg); /* Must be able to spill something. Reconfigure the register allocator to ensure that we can allocate a register for all nodes without spilling the node's necessary input regs. */ assert(bestreg->x.regnode->vbl == NULL); /* Can't spill register variables because the reload site might be in other blocks. Reconfigure the register allocator to ensure that this register is never allocated to a variable. */ return bestreg; } static int uses(Node p, Regnode rn) { int i; for (i = 0; i < NELEMS(p->x.kids); i++) if ( p->x.kids[i] && p->x.kids[i]->x.registered && rn->set == p->x.kids[i]->syms[RX]->x.regnode->set && (rn->mask&p->x.kids[i]->syms[RX]->x.regnode->mask) ) return 1; return 0; } static void spillr(Symbol r, Node here) { int i; Symbol tmp; Node p = r->x.lastuse; assert(p); while (p->x.prevuse) assert(r == p->syms[RX]), p = p->x.prevuse; assert(p->x.registered && !readsreg(p)); tmp = newtemp(AUTO, optype(p->op), opsize(p->op)); genspill(r, p, tmp); for (p = here->x.next; p; p = p->x.next) for (i = 0; i < NELEMS(p->x.kids) && p->x.kids[i]; i++) { Node k = p->x.kids[i]; if (k->x.registered && k->syms[RX] == r) genreload(p, tmp, i); } putreg(r); } static void genspill(Symbol r, Node last, Symbol tmp) { Node p, q; Symbol s; unsigned ty; debug(fprint(stderr, "(spilling %s to local %s)\n", r->x.name, tmp->x.name)); debug(fprint(stderr, "(genspill: ")); debug(dumptree(last)); debug(fprint(stderr, ")\n")); ty = opkind(last->op); NEW0(s, FUNC); s->sclass = REGISTER; s->name = s->x.name = r->x.name; s->x.regnode = r->x.regnode; q = newnode(ADDRL+P + sizeop(IR->ptrmetric.size), NULL, NULL, s); q = newnode(INDIR + ty, q, NULL, NULL); p = newnode(ADDRL+P + sizeop(IR->ptrmetric.size), NULL, NULL, tmp); p = newnode(ASGN + ty, p, q, NULL); p->x.spills = 1; rewrite(p); prune(p, &q); q = last->x.next; linearize(p, q); for (p = last->x.next; p != q; p = p->x.next) { ralloc(p); assert(!p->x.listed || !NeedsReg[opindex(p->op)] || !(*IR->x.rmap)(opkind(p->op))); } } static void genreload(Node p, Symbol tmp, int i) { Node q; int ty; debug(fprint(stderr, "(replacing %x with a reload from %s)\n", p->x.kids[i], tmp->x.name)); debug(fprint(stderr, "(genreload: ")); debug(dumptree(p->x.kids[i])); debug(fprint(stderr, ")\n")); ty = opkind(p->x.kids[i]->op); q = newnode(ADDRL+P + sizeop(IR->ptrmetric.size), NULL, NULL, tmp); p->x.kids[i] = newnode(INDIR + ty, q, NULL, NULL); rewrite(p->x.kids[i]); prune(p->x.kids[i], &q); reprune(&p->kids[1], reprune(&p->kids[0], 0, i, p), i, p); prune(p, &q); linearize(p->x.kids[i], p); } static int reprune(Node *pp, int k, int n, Node p) { struct node x, *q = *pp; if (q == NULL || k > n) return k; else if (q->x.inst == 0) return reprune(&q->kids[1], reprune(&q->kids[0], k, n, p), n, p); if (k == n) { debug(fprint(stderr, "(reprune changes %x from %x to %x)\n", pp, *pp, p->x.kids[n])); *pp = p->x.kids[n]; x = *p; (IR->x.target)(&x); } return k + 1; } void spill(unsigned mask, int n, Node here) { int i; Node p; here->x.spills = 1; usedmask[n] |= mask; if (mask&~freemask[n]) { assert( /* It makes no sense for a node to clobber() its target. */ here->x.registered == 0 || /* call isn't coming through clobber() */ here->syms[RX] == NULL || here->syms[RX]->x.regnode == NULL || here->syms[RX]->x.regnode->set != n || (here->syms[RX]->x.regnode->mask&mask) == 0 ); for (p = here; p; p = p->x.next) for (i = 0; i < NELEMS(p->x.kids) && p->x.kids[i]; i++) { Symbol r = p->x.kids[i]->syms[RX]; assert(r); if (p->x.kids[i]->x.registered && r->x.regnode->set == n && r->x.regnode->mask&mask) spillr(r, here); } } } static void dumpregs(char *msg, char *a, char *b) { fprint(stderr, msg, a, b); fprint(stderr, "(free[0]=%x)\n", freemask[0]); fprint(stderr, "(free[1]=%x)\n", freemask[1]); } int getregnum(Node p) { assert(p && p->syms[RX] && p->syms[RX]->x.regnode); return p->syms[RX]->x.regnode->number; } unsigned regloc(Symbol p) { assert(p && p->sclass == REGISTER && p->sclass == REGISTER && p->x.regnode); return p->x.regnode->set<<8 | p->x.regnode->number; }