// Inferno utils/5c/reg.c // http://code.google.com/p/inferno-os/source/browse/utils/5c/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 #include #include "gg.h" #include "opt.h" #define NREGVAR 32 #define REGBITS ((uint32)0xffffffff) void addsplits(void); static Reg* firstr; static int first = 1; 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; } static void setoutvar(void) { Type *t; Node *n; Addr a; Iter save; Bits bit; int z; t = structfirst(&save, getoutarg(curfn->type)); while(t != T) { n = nodarg(t, 1); a = zprog.from; naddr(n, &a, 0); bit = mkvar(R, &a); for(z=0; zprog; p->as = ANOP; p->scond = zprog.scond; p->from = zprog.from; p->to = zprog.to; p->reg = zprog.reg; } static void setaddrs(Bits bit) { int i, n; Var *v; Node *node; while(bany(&bit)) { // convert each bit to a variable i = bnum(bit); node = var[i].node; n = var[i].name; bit.b[i/32] &= ~(1L<<(i%32)); // disable all pieces of that variable for(i=0; inode == node && v->name == n) v->addr = 2; } } } static char* regname[] = { ".R0", ".R1", ".R2", ".R3", ".R4", ".R5", ".R6", ".R7", ".R8", ".R9", ".R10", ".R11", ".R12", ".R13", ".R14", ".R15", ".F0", ".F1", ".F2", ".F3", ".F4", ".F5", ".F6", ".F7", ".F8", ".F9", ".F10", ".F11", ".F12", ".F13", ".F14", ".F15", }; static Node* regnodes[NREGVAR]; void regopt(Prog *firstp) { Reg *r, *r1; Prog *p; Graph *g; int i, z; uint32 vreg; Bits bit; ProgInfo info; if(first) { fmtinstall('Q', Qconv); first = 0; } fixjmp(firstp); mergetemp(firstp); /* * control flow is more complicated in generated go code * than in generated c code. define pseudo-variables for * registers, so we have complete register usage information. */ nvar = NREGVAR; memset(var, 0, NREGVAR*sizeof var[0]); for(i=0; istart; for(r = firstr; r != R; r = (Reg*)r->f.link) { p = r->f.prog; proginfo(&info, p); // Avoid making variables for direct-called functions. if(p->as == ABL && p->to.type == D_EXTERN) continue; bit = mkvar(r, &p->from); if(info.flags & LeftRead) for(z=0; zuse1.b[z] |= bit.b[z]; if(info.flags & LeftAddr) setaddrs(bit); if(info.flags & RegRead) { if(p->from.type != D_FREG) r->use1.b[0] |= RtoB(p->reg); else r->use1.b[0] |= FtoB(p->reg); } if(info.flags & (RightAddr | RightRead | RightWrite)) { bit = mkvar(r, &p->to); if(info.flags & RightAddr) setaddrs(bit); if(info.flags & RightRead) for(z=0; zuse2.b[z] |= bit.b[z]; if(info.flags & RightWrite) for(z=0; zset.b[z] |= bit.b[z]; } } if(firstr == R) return; for(i=0; iaddr) { bit = blsh(i); for(z=0; zaddr, v->etype, v->width, v->node, v->offset); } if(debug['R'] && debug['v']) dumpit("pass1", &firstr->f, 1); /* * pass 2 * find looping structure */ flowrpo(g); if(debug['R'] && debug['v']) dumpit("pass2", &firstr->f, 1); /* * pass 3 * iterate propagating usage * back until flow graph is complete */ loop1: change = 0; for(r = firstr; r != R; r = (Reg*)r->f.link) r->f.active = 0; for(r = firstr; r != R; r = (Reg*)r->f.link) if(r->f.prog->as == ARET) prop(r, zbits, zbits); loop11: /* pick up unreachable code */ i = 0; for(r = firstr; r != R; r = r1) { r1 = (Reg*)r->f.link; if(r1 && r1->f.active && !r->f.active) { prop(r, zbits, zbits); i = 1; } } if(i) goto loop11; if(change) goto loop1; if(debug['R'] && debug['v']) dumpit("pass3", &firstr->f, 1); /* * pass 4 * iterate propagating register/variable synchrony * forward until graph is complete */ loop2: change = 0; for(r = firstr; r != R; r = (Reg*)r->f.link) r->f.active = 0; synch(firstr, zbits); if(change) goto loop2; addsplits(); if(debug['R'] && debug['v']) dumpit("pass4", &firstr->f, 1); if(debug['R'] > 1) { print("\nprop structure:\n"); for(r = firstr; r != R; r = (Reg*)r->f.link) { print("%d:%P", r->f.loop, r->f.prog); for(z=0; zset.b[z] | r->refahead.b[z] | r->calahead.b[z] | r->refbehind.b[z] | r->calbehind.b[z] | r->use1.b[z] | r->use2.b[z]; bit.b[z] &= ~addrs.b[z]; } if(bany(&bit)) { print("\t"); if(bany(&r->use1)) print(" u1=%Q", r->use1); if(bany(&r->use2)) print(" u2=%Q", r->use2); if(bany(&r->set)) print(" st=%Q", r->set); if(bany(&r->refahead)) print(" ra=%Q", r->refahead); if(bany(&r->calahead)) print(" ca=%Q", r->calahead); if(bany(&r->refbehind)) print(" rb=%Q", r->refbehind); if(bany(&r->calbehind)) print(" cb=%Q", r->calbehind); } print("\n"); } } /* * pass 4.5 * move register pseudo-variables into regu. */ for(r = firstr; r != R; r = (Reg*)r->f.link) { r->regu = (r->refbehind.b[0] | r->set.b[0]) & REGBITS; r->set.b[0] &= ~REGBITS; r->use1.b[0] &= ~REGBITS; r->use2.b[0] &= ~REGBITS; r->refbehind.b[0] &= ~REGBITS; r->refahead.b[0] &= ~REGBITS; r->calbehind.b[0] &= ~REGBITS; r->calahead.b[0] &= ~REGBITS; r->regdiff.b[0] &= ~REGBITS; r->act.b[0] &= ~REGBITS; } if(debug['R'] && debug['v']) dumpit("pass4.5", &firstr->f, 1); /* * 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) & !r->f.refset) { // should never happen - all variables are preset if(debug['w']) print("%L: used and not set: %Q\n", r->f.prog->lineno, bit); r->f.refset = 1; } } for(r = firstr; r != R; r = (Reg*)r->f.link) r->act = zbits; rgp = region; nregion = 0; for(r = firstr; r != R; r = (Reg*)r->f.link) { for(z=0; zset.b[z] & ~(r->refahead.b[z] | r->calahead.b[z] | addrs.b[z]); if(bany(&bit) && !r->f.refset) { if(debug['w']) print("%L: set and not used: %Q\n", r->f.prog->lineno, bit); r->f.refset = 1; excise(&r->f); } 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'] > 1) print("\n"); paint1(r, i); bit.b[i/32] &= ~(1L<<(i%32)); if(change <= 0) { if(debug['R']) print("%L $%d: %Q\n", r->f.prog->lineno, change, blsh(i)); continue; } rgp->cost = change; nregion++; if(nregion >= NRGN) { if(debug['R'] > 1) print("too many regions\n"); goto brk; } rgp++; } } brk: qsort(region, nregion, sizeof(region[0]), rcmp); if(debug['R'] && debug['v']) dumpit("pass5", &firstr->f, 1); /* * 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']) { if(rgp->regno >= NREG) print("%L $%d F%d: %Q\n", rgp->enter->f.prog->lineno, rgp->cost, rgp->regno-NREG, bit); else print("%L $%d R%d: %Q\n", rgp->enter->f.prog->lineno, rgp->cost, rgp->regno, bit); } if(rgp->regno != 0) paint3(rgp->enter, rgp->varno, vreg, rgp->regno); rgp++; } if(debug['R'] && debug['v']) dumpit("pass6", &firstr->f, 1); /* * pass 7 * peep-hole on basic block */ if(!debug['R'] || debug['P']) { peep(firstp); } if(debug['R'] && debug['v']) dumpit("pass7", &firstr->f, 1); /* * last pass * eliminate nops * free aux structures * adjust the stack pointer * MOVW.W R1,-12(R13) <<- start * MOVW R0,R1 * MOVW R1,8(R13) * MOVW $0,R1 * MOVW R1,4(R13) * BL ,runtime.newproc+0(SB) * MOVW &ft+-32(SP),R7 <<- adjust * MOVW &j+-40(SP),R6 <<- adjust * MOVW autotmp_0003+-24(SP),R5 <<- adjust * MOVW $12(R13),R13 <<- finish */ vreg = 0; for(p = firstp; p != P; p = p->link) { while(p->link != P && p->link->as == ANOP) p->link = p->link->link; if(p->to.type == D_BRANCH) while(p->to.u.branch != P && p->to.u.branch->as == ANOP) p->to.u.branch = p->to.u.branch->link; if(p->as == AMOVW && p->to.reg == 13) { if(p->scond & C_WBIT) { vreg = -p->to.offset; // in adjust region // print("%P adjusting %d\n", p, vreg); continue; } if(p->from.type == D_CONST && p->to.type == D_REG) { if(p->from.offset != vreg) print("in and out different\n"); // print("%P finish %d\n", p, vreg); vreg = 0; // done adjust region continue; } // print("%P %d %d from type\n", p, p->from.type, D_CONST); // print("%P %d %d to type\n\n", p, p->to.type, D_REG); } if(p->as == AMOVW && vreg != 0) { if(p->from.sym != S) if(p->from.name == D_AUTO || p->from.name == D_PARAM) { p->from.offset += vreg; // print("%P adjusting from %d %d\n", p, vreg, p->from.type); } if(p->to.sym != S) if(p->to.name == D_AUTO || p->to.name == D_PARAM) { p->to.offset += vreg; // print("%P adjusting to %d %d\n", p, vreg, p->from.type); } } } flowend(g); } void addsplits(void) { Reg *r, *r1; int z, i; Bits bit; for(r = firstr; r != R; r = (Reg*)r->f.link) { if(r->f.loop > 1) continue; if(r->f.prog->as == ABL) continue; for(r1 = (Reg*)r->f.p2; r1 != R; r1 = (Reg*)r1->f.p2link) { if(r1->f.loop <= 1) continue; for(z=0; zcalbehind.b[z] & (r->refahead.b[z] | r->use1.b[z] | r->use2.b[z]) & ~(r->calahead.b[z] & addrs.b[z]); while(bany(&bit)) { i = bnum(bit); bit.b[i/32] &= ~(1L << (i%32)); } } } } /* * add mov b,rn * just after r */ void addmove(Reg *r, int bn, int rn, int f) { Prog *p, *p1, *p2; Adr *a; Var *v; p1 = mal(sizeof(*p1)); *p1 = zprog; p = r->f.prog; // If there's a stack fixup coming (after BL newproc or BL deferproc), // delay the load until after the fixup. p2 = p->link; if(p2 && p2->as == AMOVW && p2->from.type == D_CONST && p2->from.reg == REGSP && p2->to.reg == REGSP && p2->to.type == D_REG) p = p2; p1->link = p->link; p->link = p1; p1->lineno = p->lineno; v = var + bn; a = &p1->to; a->name = v->name; a->node = v->node; a->sym = v->node->sym; a->offset = v->offset; a->etype = v->etype; a->type = D_OREG; if(a->etype == TARRAY || a->sym == S) a->type = D_CONST; if(v->addr) fatal("addmove: shouldn't be doing this %A\n", a); switch(v->etype) { default: print("What is this %E\n", v->etype); case TINT8: p1->as = AMOVBS; break; case TBOOL: case TUINT8: //print("movbu %E %d %S\n", v->etype, bn, v->sym); p1->as = AMOVBU; break; case TINT16: p1->as = AMOVHS; break; case TUINT16: p1->as = AMOVHU; break; case TINT32: case TUINT32: case TPTR32: p1->as = AMOVW; break; case TFLOAT32: p1->as = AMOVF; break; case TFLOAT64: p1->as = AMOVD; break; } p1->from.type = D_REG; p1->from.reg = rn; if(rn >= NREG) { p1->from.type = D_FREG; p1->from.reg = rn-NREG; } if(!f) { p1->from = *a; *a = zprog.from; a->type = D_REG; a->reg = rn; if(rn >= NREG) { a->type = D_FREG; a->reg = rn-NREG; } if(v->etype == TUINT8 || v->etype == TBOOL) p1->as = AMOVBU; if(v->etype == TUINT16) p1->as = AMOVHU; } if(debug['R']) print("%P\t.a%P\n", p, p1); } static int overlap(int32 o1, int w1, int32 o2, int w2) { int32 t1, t2; t1 = o1+w1; t2 = o2+w2; if(!(t1 > o2 && t2 > o1)) return 0; return 1; } Bits mkvar(Reg *r, Adr *a) { Var *v; int i, t, n, et, z, w, flag; int32 o; Bits bit; Node *node; // mark registers used t = a->type; flag = 0; switch(t) { default: print("type %d %d %D\n", t, a->name, a); goto none; case D_NONE: case D_FCONST: case D_BRANCH: break; case D_REGREG: case D_REGREG2: bit = zbits; if(a->offset != NREG) bit.b[0] |= RtoB(a->offset); if(a->reg != NREG) bit.b[0] |= RtoB(a->reg); return bit; case D_CONST: case D_REG: case D_SHIFT: if(a->reg != NREG) { bit = zbits; bit.b[0] = RtoB(a->reg); return bit; } break; case D_OREG: if(a->reg != NREG) { if(a == &r->f.prog->from) r->use1.b[0] |= RtoB(a->reg); else r->use2.b[0] |= RtoB(a->reg); if(r->f.prog->scond & (C_PBIT|C_WBIT)) r->set.b[0] |= RtoB(a->reg); } break; case D_FREG: if(a->reg != NREG) { bit = zbits; bit.b[0] = FtoB(a->reg); return bit; } break; } switch(a->name) { default: goto none; case D_EXTERN: case D_STATIC: case D_AUTO: case D_PARAM: n = a->name; break; } node = a->node; if(node == N || node->op != ONAME || node->orig == N) goto none; node = node->orig; if(node->orig != node) fatal("%D: bad node", a); if(node->sym == S || node->sym->name[0] == '.') goto none; et = a->etype; o = a->offset; w = a->width; if(w < 0) fatal("bad width %d for %D", w, a); for(i=0; inode == node && v->name == n) { if(v->offset == o) if(v->etype == et) if(v->width == w) if(!flag) return blsh(i); // if they overlap, disable both if(overlap(v->offset, v->width, o, w)) { v->addr = 1; flag = 1; } } } switch(et) { case 0: case TFUNC: goto none; } if(nvar >= NVAR) { if(debug['w'] > 1 && node) fatal("variable not optimized: %D", a); goto none; } i = nvar; nvar++; //print("var %d %E %D %S\n", i, et, a, s); v = var+i; v->offset = o; v->name = n; v->etype = et; v->width = w; v->addr = flag; // funny punning v->node = node; if(debug['R']) print("bit=%2d et=%2E w=%d+%d %#N %D flag=%d\n", i, et, o, w, node, a, v->addr); bit = blsh(i); if(n == D_EXTERN || n == D_STATIC) for(z=0; zf.p1) { 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->f.prog->as) { case ABL: if(noreturn(r1->f.prog)) break; 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->f.active) break; r1->f.active = 1; } for(; r != r1; r = (Reg*)r->f.p1) for(r2 = (Reg*)r->f.p2; r2 != R; r2 = (Reg*)r2->f.p2link) prop(r2, r->refbehind, r->calbehind); } void synch(Reg *r, Bits dif) { Reg *r1; int z; for(r1 = r; r1 != R; r1 = (Reg*)r1->f.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->f.active) break; r1->f.active = 1; for(z=0; zcalbehind.b[z] & r1->calahead.b[z]); if(r1->f.s2 != nil) synch((Reg*)r1->f.s2, dif); } } uint32 allreg(uint32 b, Rgn *r) { Var *v; int i; v = var + r->varno; r->regno = 0; switch(v->etype) { default: fatal("unknown etype %d/%E", bitno(b), v->etype); break; case TINT8: case TUINT8: case TINT16: case TUINT16: case TINT32: case TUINT32: case TINT: case TUINT: case TUINTPTR: case TBOOL: case TPTR32: i = BtoR(~b); if(i && r->cost >= 0) { r->regno = i; return RtoB(i); } break; case TFLOAT32: case TFLOAT64: i = BtoF(~b); if(i && r->cost >= 0) { r->regno = i+NREG; return FtoB(i); } break; case TINT64: case TUINT64: case TPTR64: case TINTER: case TSTRUCT: case TARRAY: 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 = (Reg*)r->f.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->f.loop; if(debug['R'] > 1) print("%d%P\td %Q $%d\n", r->f.loop, r->f.prog, blsh(bn), change); } for(;;) { r->act.b[z] |= bb; p = r->f.prog; if(r->use1.b[z] & bb) { change += CREF * r->f.loop; if(debug['R'] > 1) print("%d%P\tu1 %Q $%d\n", r->f.loop, p, blsh(bn), change); } if((r->use2.b[z]|r->set.b[z]) & bb) { change += CREF * r->f.loop; if(debug['R'] > 1) print("%d%P\tu2 %Q $%d\n", r->f.loop, p, blsh(bn), change); } if(STORE(r) & r->regdiff.b[z] & bb) { change -= CLOAD * r->f.loop; if(debug['R'] > 1) print("%d%P\tst %Q $%d\n", r->f.loop, p, blsh(bn), change); } if(r->refbehind.b[z] & bb) for(r1 = (Reg*)r->f.p2; r1 != R; r1 = (Reg*)r1->f.p2link) if(r1->refahead.b[z] & bb) paint1(r1, bn); if(!(r->refahead.b[z] & bb)) break; r1 = (Reg*)r->f.s2; if(r1 != R) if(r1->refbehind.b[z] & bb) paint1(r1, bn); r = (Reg*)r->f.s1; if(r == R) break; if(r->act.b[z] & bb) break; if(!(r->refbehind.b[z] & bb)) break; } } uint32 paint2(Reg *r, int bn) { Reg *r1; int z; uint32 bb, vreg; 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 = (Reg*)r->f.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 = (Reg*)r->f.p2; r1 != R; r1 = (Reg*)r1->f.p2link) if(r1->refahead.b[z] & bb) vreg |= paint2(r1, bn); if(!(r->refahead.b[z] & bb)) break; r1 = (Reg*)r->f.s2; if(r1 != R) if(r1->refbehind.b[z] & bb) vreg |= paint2(r1, bn); r = (Reg*)r->f.s1; if(r == R) break; if(!(r->act.b[z] & bb)) break; if(!(r->refbehind.b[z] & bb)) break; } 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 = (Reg*)r->f.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->f.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 = (Reg*)r->f.p2; r1 != R; r1 = (Reg*)r1->f.p2link) if(r1->refahead.b[z] & bb) paint3(r1, bn, rb, rn); if(!(r->refahead.b[z] & bb)) break; r1 = (Reg*)r->f.s2; if(r1 != R) if(r1->refbehind.b[z] & bb) paint3(r1, bn, rb, rn); r = (Reg*)r->f.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->name = D_NONE; a->type = D_REG; a->reg = rn; if(rn >= NREG) { a->type = D_FREG; a->reg = rn-NREG; } } /* * bit reg * 0 R0 * 1 R1 * ... ... * 10 R10 * 12 R12 */ int32 RtoB(int r) { if(r >= REGTMP-2 && r != 12) // excluded R9 and R10 for m and g, but not R12 return 0; return 1L << r; } int BtoR(int32 b) { b &= 0x11fcL; // excluded R9 and R10 for m and g, but not R12 if(b == 0) return 0; return bitno(b); } /* * bit reg * 18 F2 * 19 F3 * ... ... * 31 F15 */ int32 FtoB(int f) { if(f < 2 || f > NFREG-1) return 0; return 1L << (f + 16); } int BtoF(int32 b) { b &= 0xfffc0000L; if(b == 0) return 0; return bitno(b) - 16; } void dumpone(Flow *f, int isreg) { int z; Bits bit; Reg *r; print("%d:%P", f->loop, f->prog); if(isreg) { r = (Reg*)f; for(z=0; zset.b[z] | r->use1.b[z] | r->use2.b[z] | r->refbehind.b[z] | r->refahead.b[z] | r->calbehind.b[z] | r->calahead.b[z] | r->regdiff.b[z] | r->act.b[z] | 0; if(bany(&bit)) { print("\t"); if(bany(&r->set)) print(" s:%Q", r->set); if(bany(&r->use1)) print(" u1:%Q", r->use1); if(bany(&r->use2)) print(" u2:%Q", r->use2); if(bany(&r->refbehind)) print(" rb:%Q ", r->refbehind); if(bany(&r->refahead)) print(" ra:%Q ", r->refahead); if(bany(&r->calbehind)) print(" cb:%Q ", r->calbehind); if(bany(&r->calahead)) print(" ca:%Q ", r->calahead); if(bany(&r->regdiff)) print(" d:%Q ", r->regdiff); if(bany(&r->act)) print(" a:%Q ", r->act); } } print("\n"); } void dumpit(char *str, Flow *r0, int isreg) { Flow *r, *r1; print("\n%s\n", str); for(r = r0; r != nil; r = r->link) { dumpone(r, isreg); r1 = r->p2; if(r1 != nil) { print(" pred:"); for(; r1 != nil; r1 = r1->p2link) print(" %.4ud", r1->prog->loc); print("\n"); } // r1 = r->s1; // if(r1 != nil) { // print(" succ:"); // for(; r1 != R; r1 = r1->s1) // print(" %.4ud", r1->prog->loc); // print("\n"); // } } }