// Inferno utils/8c/reg.c // http://code.google.com/p/inferno-os/source/browse/utils/8c/reg.c // // Copyright © 1994-1999 Lucent Technologies Inc. All rights reserved. // Portions Copyright © 1995-1997 C H Forsyth (forsyth@terzarima.net) // Portions Copyright © 1997-1999 Vita Nuova Limited // Portions Copyright © 2000-2007 Vita Nuova Holdings Limited (www.vitanuova.com) // Portions Copyright © 2004,2006 Bruce Ellis // Portions Copyright © 2005-2007 C H Forsyth (forsyth@terzarima.net) // Revisions Copyright © 2000-2007 Lucent Technologies Inc. and others // Portions Copyright © 2009 The Go Authors. All rights reserved. // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN // THE SOFTWARE. #include "gc.h" Reg* rega(void) { Reg *r; r = freer; if(r == R) { r = alloc(sizeof(*r)); } else freer = r->link; *r = zreg; return r; } int rcmp(const void *a1, const void *a2) { Rgn *p1, *p2; int c1, c2; p1 = (Rgn*)a1; p2 = (Rgn*)a2; c1 = p2->cost; c2 = p1->cost; if(c1 -= c2) return c1; return p2->varno - p1->varno; } void regopt(Prog *p) { Reg *r, *r1, *r2; Prog *p1; int i, z; int32 initpc, val, npc; uint32 vreg; Bits bit; struct { int32 m; int32 c; Reg* p; } log5[6], *lp; firstr = R; lastr = R; nvar = 0; regbits = RtoB(D_SP) | RtoB(D_AX); for(z=0; zm = val; lp->c = 0; lp->p = R; val /= 5L; lp++; } val = 0; for(; p != P; p = p->link) { switch(p->as) { case ADATA: case AGLOBL: case ANAME: case ASIGNAME: continue; } r = rega(); if(firstr == R) { firstr = r; lastr = r; } else { lastr->link = r; r->p1 = lastr; lastr->s1 = r; lastr = r; } r->prog = p; r->pc = val; val++; lp = log5; for(i=0; i<5; i++) { lp->c--; if(lp->c <= 0) { lp->c = lp->m; if(lp->p != R) lp->p->log5 = r; lp->p = r; (lp+1)->c = 0; break; } lp++; } r1 = r->p1; if(r1 != R) switch(r1->prog->as) { case ARET: case AJMP: case AIRETL: r->p1 = R; r1->s1 = R; } bit = mkvar(r, &p->from); if(bany(&bit)) switch(p->as) { /* * funny */ case ALEAL: for(z=0; zuse1.b[z] |= bit.b[z]; break; } bit = mkvar(r, &p->to); if(bany(&bit)) switch(p->as) { default: diag(Z, "reg: unknown op: %A", p->as); break; /* * right side read */ case ACMPB: case ACMPL: case ACMPW: for(z=0; zuse2.b[z] |= bit.b[z]; break; /* * right side write */ case ANOP: case AMOVL: case AMOVB: case AMOVW: case AMOVBLSX: case AMOVBLZX: case AMOVWLSX: case AMOVWLZX: for(z=0; zset.b[z] |= bit.b[z]; break; /* * right side read+write */ case AADDB: case AADDL: case AADDW: case AANDB: case AANDL: case AANDW: case ASUBB: case ASUBL: case ASUBW: case AORB: case AORL: case AORW: case AXORB: case AXORL: case AXORW: case ASALB: case ASALL: case ASALW: case ASARB: case ASARL: case ASARW: case AROLB: case AROLL: case AROLW: case ARORB: case ARORL: case ARORW: case ASHLB: case ASHLL: case ASHLW: case ASHRB: case ASHRL: case ASHRW: case AIMULL: case AIMULW: case ANEGL: case ANOTL: case AADCL: case ASBBL: for(z=0; zset.b[z] |= bit.b[z]; r->use2.b[z] |= bit.b[z]; } break; /* * funny */ case AFMOVDP: case AFMOVFP: case AFMOVLP: case AFMOVVP: case AFMOVWP: case ACALL: for(z=0; zas) { case AIMULL: case AIMULW: if(p->to.type != D_NONE) break; case AIDIVB: case AIDIVL: case AIDIVW: case AIMULB: case ADIVB: case ADIVL: case ADIVW: case AMULB: case AMULL: case AMULW: case ACWD: case ACDQ: r->regu |= RtoB(D_AX) | RtoB(D_DX); break; case AREP: case AREPN: case ALOOP: case ALOOPEQ: case ALOOPNE: r->regu |= RtoB(D_CX); break; case AMOVSB: case AMOVSL: case AMOVSW: case ACMPSB: case ACMPSL: case ACMPSW: r->regu |= RtoB(D_SI) | RtoB(D_DI); break; case ASTOSB: case ASTOSL: case ASTOSW: case ASCASB: case ASCASL: case ASCASW: r->regu |= RtoB(D_AX) | RtoB(D_DI); break; case AINSB: case AINSL: case AINSW: case AOUTSB: case AOUTSL: case AOUTSW: r->regu |= RtoB(D_DI) | RtoB(D_DX); break; case AFSTSW: case ASAHF: r->regu |= RtoB(D_AX); break; } } if(firstr == R) return; initpc = pc - val; npc = val; /* * pass 2 * turn branch references to pointers * build back pointers */ for(r = firstr; r != R; r = r->link) { p = r->prog; if(p->to.type == D_BRANCH) { val = p->to.offset - initpc; r1 = firstr; while(r1 != R) { r2 = r1->log5; if(r2 != R && val >= r2->pc) { r1 = r2; continue; } if(r1->pc == val) break; r1 = r1->link; } if(r1 == R) { nearln = p->lineno; diag(Z, "ref not found\n%P", p); continue; } if(r1 == r) { nearln = p->lineno; diag(Z, "ref to self\n%P", p); continue; } r->s2 = r1; r->p2link = r1->p2; r1->p2 = r; } } if(debug['R']) { p = firstr->prog; print("\n%L %D\n", p->lineno, &p->from); } /* * pass 2.5 * find looping structure */ for(r = firstr; r != R; r = r->link) r->active = 0; change = 0; loopit(firstr, npc); if(debug['R'] && debug['v']) { print("\nlooping structure:\n"); for(r = firstr; r != R; r = r->link) { print("%ld:%P", r->loop, r->prog); for(z=0; zuse1.b[z] | r->use2.b[z] | r->set.b[z]; if(bany(&bit)) { print("\t"); if(bany(&r->use1)) print(" u1=%B", r->use1); if(bany(&r->use2)) print(" u2=%B", r->use2); if(bany(&r->set)) print(" st=%B", r->set); } print("\n"); } } /* * pass 3 * iterate propagating usage * back until flow graph is complete */ loop1: change = 0; for(r = firstr; r != R; r = r->link) r->active = 0; for(r = firstr; r != R; r = r->link) if(r->prog->as == ARET) prop(r, zbits, zbits); loop11: /* pick up unreachable code */ i = 0; for(r = firstr; r != R; r = r1) { r1 = r->link; if(r1 && r1->active && !r->active) { prop(r, zbits, zbits); i = 1; } } if(i) goto loop11; if(change) goto loop1; /* * pass 4 * iterate propagating register/variable synchrony * forward until graph is complete */ loop2: change = 0; for(r = firstr; r != R; r = r->link) r->active = 0; synch(firstr, zbits); if(change) goto loop2; /* * pass 5 * isolate regions * calculate costs (paint1) */ r = firstr; if(r) { for(z=0; zrefahead.b[z] | r->calahead.b[z]) & ~(externs.b[z] | params.b[z] | addrs.b[z] | consts.b[z]); if(bany(&bit)) { nearln = r->prog->lineno; warn(Z, "used and not set: %B", bit); if(debug['R'] && !debug['w']) print("used and not set: %B\n", bit); } } if(debug['R'] && debug['v']) print("\nprop structure:\n"); for(r = firstr; r != R; r = r->link) r->act = zbits; rgp = region; nregion = 0; for(r = firstr; r != R; r = r->link) { if(debug['R'] && debug['v']) { print("%P\t", r->prog); if(bany(&r->set)) print("s:%B ", r->set); if(bany(&r->refahead)) print("ra:%B ", r->refahead); if(bany(&r->calahead)) print("ca:%B ", r->calahead); print("\n"); } for(z=0; zset.b[z] & ~(r->refahead.b[z] | r->calahead.b[z] | addrs.b[z]); if(bany(&bit)) { nearln = r->prog->lineno; warn(Z, "set and not used: %B", bit); if(debug['R']) print("set and not used: %B\n", bit); excise(r); } for(z=0; zact.b[z] | addrs.b[z]); while(bany(&bit)) { i = bnum(bit); rgp->enter = r; rgp->varno = i; change = 0; if(debug['R'] && debug['v']) print("\n"); paint1(r, i); bit.b[i/32] &= ~(1L<<(i%32)); if(change <= 0) { if(debug['R']) print("%L$%d: %B\n", r->prog->lineno, change, blsh(i)); continue; } rgp->cost = change; nregion++; if(nregion >= NRGN) { warn(Z, "too many regions"); goto brk; } rgp++; } } brk: qsort(region, nregion, sizeof(region[0]), rcmp); /* * pass 6 * determine used registers (paint2) * replace code (paint3) */ rgp = region; for(i=0; ivarno); vreg = paint2(rgp->enter, rgp->varno); vreg = allreg(vreg, rgp); if(debug['R']) { print("%L$%d %R: %B\n", rgp->enter->prog->lineno, rgp->cost, rgp->regno, bit); } if(rgp->regno != 0) paint3(rgp->enter, rgp->varno, vreg, rgp->regno); rgp++; } /* * pass 7 * peep-hole on basic block */ if(!debug['R'] || debug['P']) peep(); /* * pass 8 * recalculate pc */ val = initpc; for(r = firstr; r != R; r = r1) { r->pc = val; p = r->prog; p1 = P; r1 = r->link; if(r1 != R) p1 = r1->prog; for(; p != p1; p = p->link) { switch(p->as) { default: val++; break; case ANOP: case ADATA: case AGLOBL: case ANAME: case ASIGNAME: break; } } } pc = val; /* * fix up branches */ if(debug['R']) if(bany(&addrs)) print("addrs: %B\n", addrs); r1 = 0; /* set */ for(r = firstr; r != R; r = r->link) { p = r->prog; if(p->to.type == D_BRANCH) p->to.offset = r->s2->pc; r1 = r; } /* * last pass * eliminate nops * free aux structures */ for(p = firstr->prog; p != P; p = p->link){ while(p->link && p->link->as == ANOP) p->link = p->link->link; } if(r1 != R) { r1->link = freer; freer = firstr; } } /* * add mov b,rn * just after r */ void addmove(Reg *r, int bn, int rn, int f) { Prog *p, *p1; Adr *a; Var *v; p1 = alloc(sizeof(*p1)); *p1 = zprog; p = r->prog; p1->link = p->link; p->link = p1; p1->lineno = p->lineno; v = var + bn; a = &p1->to; a->sym = v->sym; a->offset = v->offset; a->etype = v->etype; a->type = v->name; p1->as = AMOVL; if(v->etype == TCHAR || v->etype == TUCHAR) p1->as = AMOVB; if(v->etype == TSHORT || v->etype == TUSHORT) p1->as = AMOVW; p1->from.type = rn; if(!f) { p1->from = *a; *a = zprog.from; a->type = rn; if(v->etype == TUCHAR) p1->as = AMOVB; if(v->etype == TUSHORT) p1->as = AMOVW; } if(debug['R']) print("%P\t.a%P\n", p, p1); } uint32 doregbits(int r) { uint32 b; b = 0; if(r >= D_INDIR) r -= D_INDIR; if(r >= D_AX && r <= D_DI) b |= RtoB(r); else if(r >= D_AL && r <= D_BL) b |= RtoB(r-D_AL+D_AX); else if(r >= D_AH && r <= D_BH) b |= RtoB(r-D_AH+D_AX); return b; } Bits mkvar(Reg *r, Adr *a) { Var *v; int i, t, n, et, z; int32 o; Bits bit; Sym *s; /* * mark registers used */ t = a->type; r->regu |= doregbits(t); r->regu |= doregbits(a->index); switch(t) { default: goto none; case D_ADDR: a->type = a->index; bit = mkvar(r, a); for(z=0; ztype = t; goto none; case D_EXTERN: case D_STATIC: case D_PARAM: case D_AUTO: n = t; break; } s = a->sym; if(s == S) goto none; if(s->name[0] == '.') goto none; et = a->etype; o = a->offset; v = var; for(i=0; isym) if(n == v->name) if(o == v->offset) goto out; v++; } if(nvar >= NVAR) { if(debug['w'] > 1 && s) warn(Z, "variable not optimized: %s", s->name); goto none; } i = nvar; nvar++; v = &var[i]; v->sym = s; v->offset = o; v->name = n; v->etype = et; if(debug['R']) print("bit=%2d et=%2d %D\n", i, et, a); out: bit = blsh(i); if(n == D_EXTERN || n == D_STATIC) for(z=0; zetype != et || !typechlpfd[et]) /* funny punning */ for(z=0; zp1) { for(z=0; zrefahead.b[z]; if(ref.b[z] != r1->refahead.b[z]) { r1->refahead.b[z] = ref.b[z]; change++; } cal.b[z] |= r1->calahead.b[z]; if(cal.b[z] != r1->calahead.b[z]) { r1->calahead.b[z] = cal.b[z]; change++; } } switch(r1->prog->as) { case ACALL: for(z=0; zset.b[z]) | r1->use1.b[z] | r1->use2.b[z]; cal.b[z] &= ~(r1->set.b[z] | r1->use1.b[z] | r1->use2.b[z]); r1->refbehind.b[z] = ref.b[z]; r1->calbehind.b[z] = cal.b[z]; } if(r1->active) break; r1->active = 1; } for(; r != r1; r = r->p1) for(r2 = r->p2; r2 != R; r2 = r2->p2link) prop(r2, r->refbehind, r->calbehind); } /* * find looping structure * * 1) find reverse postordering * 2) find approximate dominators, * the actual dominators if the flow graph is reducible * otherwise, dominators plus some other non-dominators. * See Matthew S. Hecht and Jeffrey D. Ullman, * "Analysis of a Simple Algorithm for Global Data Flow Problems", * Conf. Record of ACM Symp. on Principles of Prog. Langs, Boston, Massachusetts, * Oct. 1-3, 1973, pp. 207-217. * 3) find all nodes with a predecessor dominated by the current node. * such a node is a loop head. * recursively, all preds with a greater rpo number are in the loop */ int32 postorder(Reg *r, Reg **rpo2r, int32 n) { Reg *r1; r->rpo = 1; r1 = r->s1; if(r1 && !r1->rpo) n = postorder(r1, rpo2r, n); r1 = r->s2; if(r1 && !r1->rpo) n = postorder(r1, rpo2r, n); rpo2r[n] = r; n++; return n; } int32 rpolca(int32 *idom, int32 rpo1, int32 rpo2) { int32 t; if(rpo1 == -1) return rpo2; while(rpo1 != rpo2){ if(rpo1 > rpo2){ t = rpo2; rpo2 = rpo1; rpo1 = t; } while(rpo1 < rpo2){ t = idom[rpo2]; if(t >= rpo2) fatal(Z, "bad idom"); rpo2 = t; } } return rpo1; } int doms(int32 *idom, int32 r, int32 s) { while(s > r) s = idom[s]; return s == r; } int loophead(int32 *idom, Reg *r) { int32 src; src = r->rpo; if(r->p1 != R && doms(idom, src, r->p1->rpo)) return 1; for(r = r->p2; r != R; r = r->p2link) if(doms(idom, src, r->rpo)) return 1; return 0; } void loopmark(Reg **rpo2r, int32 head, Reg *r) { if(r->rpo < head || r->active == head) return; r->active = head; r->loop += LOOP; if(r->p1 != R) loopmark(rpo2r, head, r->p1); for(r = r->p2; r != R; r = r->p2link) loopmark(rpo2r, head, r); } void loopit(Reg *r, int32 nr) { Reg *r1; int32 i, d, me; if(nr > maxnr) { rpo2r = alloc(nr * sizeof(Reg*)); idom = alloc(nr * sizeof(int32)); maxnr = nr; } d = postorder(r, rpo2r, 0); if(d > nr) fatal(Z, "too many reg nodes"); nr = d; for(i = 0; i < nr / 2; i++){ r1 = rpo2r[i]; rpo2r[i] = rpo2r[nr - 1 - i]; rpo2r[nr - 1 - i] = r1; } for(i = 0; i < nr; i++) rpo2r[i]->rpo = i; idom[0] = 0; for(i = 0; i < nr; i++){ r1 = rpo2r[i]; me = r1->rpo; d = -1; if(r1->p1 != R && r1->p1->rpo < me) d = r1->p1->rpo; for(r1 = r1->p2; r1 != nil; r1 = r1->p2link) if(r1->rpo < me) d = rpolca(idom, d, r1->rpo); idom[i] = d; } for(i = 0; i < nr; i++){ r1 = rpo2r[i]; r1->loop++; if(r1->p2 != R && loophead(idom, r1)) loopmark(rpo2r, i, r1); } } void synch(Reg *r, Bits dif) { Reg *r1; int z; for(r1 = r; r1 != R; r1 = r1->s1) { for(z=0; zrefbehind.b[z] & r1->refahead.b[z])) | r1->set.b[z] | r1->regdiff.b[z]; if(dif.b[z] != r1->regdiff.b[z]) { r1->regdiff.b[z] = dif.b[z]; change++; } } if(r1->active) break; r1->active = 1; for(z=0; zcalbehind.b[z] & r1->calahead.b[z]); if(r1->s2 != R) synch(r1->s2, dif); } } uint32 allreg(uint32 b, Rgn *r) { Var *v; int i; v = var + r->varno; r->regno = 0; switch(v->etype) { default: diag(Z, "unknown etype %d/%d", bitno(b), v->etype); break; case TCHAR: case TUCHAR: case TSHORT: case TUSHORT: case TINT: case TUINT: case TLONG: case TULONG: case TIND: case TARRAY: i = BtoR(~b); if(i && r->cost > 0) { r->regno = i; return RtoB(i); } break; case TDOUBLE: case TFLOAT: break; } return 0; } void paint1(Reg *r, int bn) { Reg *r1; Prog *p; int z; uint32 bb; z = bn/32; bb = 1L<<(bn%32); if(r->act.b[z] & bb) return; for(;;) { if(!(r->refbehind.b[z] & bb)) break; r1 = r->p1; if(r1 == R) break; if(!(r1->refahead.b[z] & bb)) break; if(r1->act.b[z] & bb) break; r = r1; } if(LOAD(r) & ~(r->set.b[z]&~(r->use1.b[z]|r->use2.b[z])) & bb) { change -= CLOAD * r->loop; if(debug['R'] && debug['v']) print("%ld%P\tld %B $%d\n", r->loop, r->prog, blsh(bn), change); } for(;;) { r->act.b[z] |= bb; p = r->prog; if(r->use1.b[z] & bb) { change += CREF * r->loop; if(p->as == AFMOVL) if(BtoR(bb) != D_F0) change = -CINF; if(debug['R'] && debug['v']) print("%ld%P\tu1 %B $%d\n", r->loop, p, blsh(bn), change); } if((r->use2.b[z]|r->set.b[z]) & bb) { change += CREF * r->loop; if(p->as == AFMOVL) if(BtoR(bb) != D_F0) change = -CINF; if(debug['R'] && debug['v']) print("%ld%P\tu2 %B $%d\n", r->loop, p, blsh(bn), change); } if(STORE(r) & r->regdiff.b[z] & bb) { change -= CLOAD * r->loop; if(p->as == AFMOVL) if(BtoR(bb) != D_F0) change = -CINF; if(debug['R'] && debug['v']) print("%ld%P\tst %B $%d\n", r->loop, p, blsh(bn), change); } if(r->refbehind.b[z] & bb) for(r1 = r->p2; r1 != R; r1 = r1->p2link) if(r1->refahead.b[z] & bb) paint1(r1, bn); if(!(r->refahead.b[z] & bb)) break; r1 = r->s2; if(r1 != R) if(r1->refbehind.b[z] & bb) paint1(r1, bn); r = r->s1; if(r == R) break; if(r->act.b[z] & bb) break; if(!(r->refbehind.b[z] & bb)) break; } } uint32 regset(Reg *r, uint32 bb) { uint32 b, set; Adr v; int c; set = 0; v = zprog.from; while(b = bb & ~(bb-1)) { v.type = BtoR(b); c = copyu(r->prog, &v, A); if(c == 3) set |= b; bb &= ~b; } return set; } uint32 reguse(Reg *r, uint32 bb) { uint32 b, set; Adr v; int c; set = 0; v = zprog.from; while(b = bb & ~(bb-1)) { v.type = BtoR(b); c = copyu(r->prog, &v, A); if(c == 1 || c == 2 || c == 4) set |= b; bb &= ~b; } return set; } uint32 paint2(Reg *r, int bn) { Reg *r1; int z; uint32 bb, vreg, x; z = bn/32; bb = 1L << (bn%32); vreg = regbits; if(!(r->act.b[z] & bb)) return vreg; for(;;) { if(!(r->refbehind.b[z] & bb)) break; r1 = r->p1; if(r1 == R) break; if(!(r1->refahead.b[z] & bb)) break; if(!(r1->act.b[z] & bb)) break; r = r1; } for(;;) { r->act.b[z] &= ~bb; vreg |= r->regu; if(r->refbehind.b[z] & bb) for(r1 = r->p2; r1 != R; r1 = r1->p2link) if(r1->refahead.b[z] & bb) vreg |= paint2(r1, bn); if(!(r->refahead.b[z] & bb)) break; r1 = r->s2; if(r1 != R) if(r1->refbehind.b[z] & bb) vreg |= paint2(r1, bn); r = r->s1; if(r == R) break; if(!(r->act.b[z] & bb)) break; if(!(r->refbehind.b[z] & bb)) break; } bb = vreg; for(; r; r=r->s1) { x = r->regu & ~bb; if(x) { vreg |= reguse(r, x); bb |= regset(r, x); } } return vreg; } void paint3(Reg *r, int bn, int32 rb, int rn) { Reg *r1; Prog *p; int z; uint32 bb; z = bn/32; bb = 1L << (bn%32); if(r->act.b[z] & bb) return; for(;;) { if(!(r->refbehind.b[z] & bb)) break; r1 = r->p1; if(r1 == R) break; if(!(r1->refahead.b[z] & bb)) break; if(r1->act.b[z] & bb) break; r = r1; } if(LOAD(r) & ~(r->set.b[z] & ~(r->use1.b[z]|r->use2.b[z])) & bb) addmove(r, bn, rn, 0); for(;;) { r->act.b[z] |= bb; p = r->prog; if(r->use1.b[z] & bb) { if(debug['R']) print("%P", p); addreg(&p->from, rn); if(debug['R']) print("\t.c%P\n", p); } if((r->use2.b[z]|r->set.b[z]) & bb) { if(debug['R']) print("%P", p); addreg(&p->to, rn); if(debug['R']) print("\t.c%P\n", p); } if(STORE(r) & r->regdiff.b[z] & bb) addmove(r, bn, rn, 1); r->regu |= rb; if(r->refbehind.b[z] & bb) for(r1 = r->p2; r1 != R; r1 = r1->p2link) if(r1->refahead.b[z] & bb) paint3(r1, bn, rb, rn); if(!(r->refahead.b[z] & bb)) break; r1 = r->s2; if(r1 != R) if(r1->refbehind.b[z] & bb) paint3(r1, bn, rb, rn); r = r->s1; if(r == R) break; if(r->act.b[z] & bb) break; if(!(r->refbehind.b[z] & bb)) break; } } void addreg(Adr *a, int rn) { a->sym = 0; a->offset = 0; a->type = rn; } int32 RtoB(int r) { if(r < D_AX || r > D_DI) return 0; return 1L << (r-D_AX); } int BtoR(int32 b) { b &= 0xffL; if(b == 0) return 0; return bitno(b) + D_AX; }