ref: fc4bfd57d261e5c99c5d4367adf5c72e8c7e6496
dir: /sys/src/cmd/7c/peep.c/
#include "gc.h" int xtramodes(Reg*, Adr*); Reg* findpre(Reg *r, Adr *v); Reg* findinc(Reg *r, Reg *r2, Adr *v); void peep(void) { Reg *r, *r1, *r2; Prog *p, *p1; int t; /* * complete R structure */ t = 0; for(r=firstr; r!=R; r=r1) { r1 = r->link; if(r1 == R) break; p = r->prog->link; while(p != r1->prog) switch(p->as) { default: r2 = rega(); r->link = r2; r2->link = r1; r2->prog = p; r2->p1 = r; r->s1 = r2; r2->s1 = r1; r1->p1 = r2; r = r2; t++; case ADATA: case AGLOBL: case ANAME: case ASIGNAME: p = p->link; } } loop1: t = 0; for(r=firstr; r!=R; r=r->link) { p = r->prog; if(p->as == ALSL || p->as == ALSR || p->as == AASR || p->as == ALSLW || p->as == ALSRW || p->as == AASRW) { /* * elide shift into D_SHIFT operand of subsequent instruction */ if(0 && shiftprop(r)) { excise(r); t++; } } if(p->as == ASXTW){ r1 = findpre(r, &p->from); if(r1 != R){ p1 = r1->prog; switch(p1->as){ case AMOVB: case AMOVBU: case AMOVH: case AMOVHU: case AMOVW: p->as = AMOVW; break; } } } if(p->as == AMOV || p->as == AMOVW || p->as == AFMOVS || p->as == AFMOVD) if(regtyp(&p->to)) { if(p->from.type == D_CONST) constprop(&p->from, &p->to, r->s1); else if(regtyp(&p->from)) if(p->from.type == p->to.type) { if(copyprop(r)) { excise(r); t++; } else if(subprop(r) && copyprop(r)) { excise(r); t++; } } if(regzer(&p->from)) if(p->to.type == D_REG) { p->from.type = D_REG; p->from.reg = REGZERO; if(copyprop(r)) { excise(r); t++; } else if(subprop(r) && copyprop(r)) { excise(r); t++; } } } } if(t) goto loop1; /* * look for MOVB x,R; MOVB R,R */ for(r=firstr; r!=R; r=r->link) { p = r->prog; switch(p->as) { default: continue; case AEOR: /* * EOR -1,x,y => MVN x,y */ if(p->from.type == D_CONST && p->from.offset == -1) { p->as = AMVN; p->from.type = D_REG; if(p->reg != NREG) p->from.reg = p->reg; else p->from.reg = p->to.reg; p->reg = NREG; } continue; case AEORW: /* * EOR -1,x,y => MVN x,y */ if(p->from.type == D_CONST && (p->from.offset&0xFFFFFFFF)==0xFFFFFFFF){ p->as = AMVNW; p->from.type = D_REG; if(p->reg != NREG) p->from.reg = p->reg; else p->from.reg = p->to.reg; p->reg = NREG; } continue; case AMOVH: case AMOVHU: case AMOVB: case AMOVBU: case AMOVW: case AMOVWU: if(p->to.type != D_REG) continue; break; } r1 = r->link; if(r1 == R) continue; p1 = r1->prog; if(p1->as != p->as) continue; if(p1->from.type != D_REG || p1->from.reg != p->to.reg) continue; if(p1->to.type != D_REG || p1->to.reg != p->to.reg) continue; excise(r1); } #ifdef NOTYET for(r=firstr; r!=R; r=r->link) { p = r->prog; switch(p->as) { case AMOVW: case AMOVB: case AMOVBU: if(p->from.type == D_OREG && p->from.offset == 0) xtramodes(r, &p->from); else if(p->to.type == D_OREG && p->to.offset == 0) xtramodes(r, &p->to); else continue; break; case ACMP: /* * elide CMP $0,x if calculation of x can set condition codes */ if(p->from.type != D_CONST || p->from.offset != 0) continue; r2 = r->s1; if(r2 == R) continue; t = r2->prog->as; switch(t) { default: continue; case ABEQ: case ABNE: case ABMI: case ABPL: break; case ABGE: t = ABPL; break; case ABLT: t = ABMI; break; case ABHI: t = ABNE; break; case ABLS: t = ABEQ; break; } r1 = r; do r1 = uniqp(r1); while (r1 != R && r1->prog->as == ANOP); if(r1 == R) continue; p1 = r1->prog; if(p1->to.type != D_REG) continue; if(p1->to.reg != p->reg) if(!(p1->as == AMOVW && p1->from.type == D_REG && p1->from.reg == p->reg)) continue; switch(p1->as) { default: continue; case AMOVW: if(p1->from.type != D_REG) continue; case AAND: case AEOR: case AORR: case ABIC: case AMVN: case ASUB: case AADD: case AADC: case ASBC: break; } p1->scond |= C_SBIT; r2->prog->as = t; excise(r); continue; } } #endif #ifdef XXX predicate(); #endif } void excise(Reg *r) { Prog *p; p = r->prog; p->as = ANOP; p->scond = zprog.scond; p->from = zprog.from; p->to = zprog.to; p->reg = zprog.reg; /**/ } Reg* uniqp(Reg *r) { Reg *r1; r1 = r->p1; if(r1 == R) { r1 = r->p2; if(r1 == R || r1->p2link != R) return R; } else if(r->p2 != R) return R; return r1; } Reg* uniqs(Reg *r) { Reg *r1; r1 = r->s1; if(r1 == R) { r1 = r->s2; if(r1 == R) return R; } else if(r->s2 != R) return R; return r1; } /* * convert references to $0 to references to ZR (REGZERO) */ int regzer(Adr *a) { return 0; switch(a->type){ case D_CONST: return a->sym == S && a->offset == 0; case D_REG: return a->reg == REGZERO; } return 0; } int regtyp(Adr *a) { if(a->type == D_REG){ if(a->reg == REGZERO) return 0; return 1; } if(a->type == D_FREG) return 1; return 0; } /* * the idea is to substitute * one register for another * from one MOV to another * MOV a, R0 * ADD b, R0 / no use of R1 * MOV R0, R1 * would be converted to * MOV a, R1 * ADD b, R1 * MOV R1, R0 * hopefully, then the former or latter MOV * will be eliminated by copy propagation. */ int subprop(Reg *r0) { Prog *p; Adr *v1, *v2; Reg *r; int t; p = r0->prog; v1 = &p->from; if(!regtyp(v1)) return 0; v2 = &p->to; if(!regtyp(v2)) return 0; for(r=uniqp(r0); r!=R; r=uniqp(r)) { if(uniqs(r) == R) break; p = r->prog; switch(p->as) { case ABL: return 0; case ACMP: case ACMN: case AADC: case AADCS: case AADD: case AADDS: case ASUB: case ASUBS: case ALSL: case ALSR: case AASR: case AORR: case AAND: case AANDS: case AEOR: case AMUL: case ASDIV: case AUDIV: case AREM: case AUREM: case ACMPW: case ACMNW: case AADCW: case AADCSW: case AADDSW: case AADDW: case ASUBSW: case ASUBW: case ALSLW: case ALSRW: case AASRW: case AORRW: case AANDW: case AANDSW: case AEORW: case AMULW: case ASDIVW: case AUDIVW: case AREMW: case AUREMW: case AFCMPS: case AFCMPD: case AFADDD: case AFADDS: case AFSUBD: case AFSUBS: case AFMULD: case AFMULS: case AFDIVD: case AFDIVS: if(p->to.type == v1->type) if(p->to.reg == v1->reg) { if(p->reg == NREG) p->reg = p->to.reg; goto gotit; } break; case ANEG: case ANEGS: case ANEGSW: case ANEGW: case ANGC: case ANGCS: case ANGCSW: case ANGCW: case AMVN: case AMVNW: case AFNEGD: case AFNEGS: case AFABSS: case AFABSD: case AFSQRTS: case AFSQRTD: case AFMOVS: case AFMOVD: case AMOVW: case AMOV: case ASXTW: if(p->to.type == v1->type) if(p->to.reg == v1->reg) goto gotit; break; } if(copyau(&p->from, v2) || copyau1(p, v2) || copyau(&p->to, v2)) break; if(copysub(&p->from, v1, v2, 0) || copysub1(p, v1, v2, 0) || copysub(&p->to, v1, v2, 0)) break; } return 0; gotit: copysub(&p->to, v1, v2, 1); if(debug['P']) { print("gotit: %D->%D\n%P", v1, v2, r->prog); if(p->from.type == v2->type) print(" excise"); print("\n"); } for(r=uniqs(r); r!=r0; r=uniqs(r)) { p = r->prog; copysub(&p->from, v1, v2, 1); copysub1(p, v1, v2, 1); copysub(&p->to, v1, v2, 1); if(debug['P']) print("%P\n", r->prog); } t = v1->reg; v1->reg = v2->reg; v2->reg = t; if(debug['P']) print("%P last\n", r->prog); return 1; } /* * The idea is to remove redundant copies. * v1->v2 F=0 * (use v2 s/v2/v1/)* * set v1 F=1 * use v2 return fail * ----------------- * v1->v2 F=0 * (use v2 s/v2/v1/)* * set v1 F=1 * set v2 return success */ int copyprop(Reg *r0) { Prog *p; Adr *v1, *v2; Reg *r; p = r0->prog; v1 = &p->from; v2 = &p->to; if(copyas(v1, v2)) return 1; for(r=firstr; r!=R; r=r->link) r->active = 0; return copy1(v1, v2, r0->s1, 0); } int copy1(Adr *v1, Adr *v2, Reg *r, int f) { int t; Prog *p; if(r->active) { if(debug['P']) print("act set; return 1\n"); return 1; } r->active = 1; if(debug['P']) print("copy %D->%D f=%d\n", v1, v2, f); for(; r != R; r = r->s1) { p = r->prog; if(debug['P']) print("%P", p); if(!f && uniqp(r) == R) { f = 1; if(debug['P']) print("; merge; f=%d", f); } t = copyu(p, v2, A); switch(t) { case 2: /* rar, cant split */ if(debug['P']) print("; %Drar; return 0\n", v2); return 0; case 3: /* set */ if(debug['P']) print("; %Dset; return 1\n", v2); return 1; case 1: /* used, substitute */ case 4: /* use and set */ if(f) { if(!debug['P']) return 0; if(t == 4) print("; %Dused+set and f=%d; return 0\n", v2, f); else print("; %Dused and f=%d; return 0\n", v2, f); return 0; } if(copyu(p, v2, v1)) { if(debug['P']) print("; sub fail; return 0\n"); return 0; } if(debug['P']) print("; sub%D/%D", v2, v1); if(t == 4) { if(debug['P']) print("; %Dused+set; return 1\n", v2); return 1; } break; } if(!f) { t = copyu(p, v1, A); if(!f && (t == 2 || t == 3 || t == 4)) { f = 1; if(debug['P']) print("; %Dset and !f; f=%d", v1, f); } } if(debug['P']) print("\n"); if(r->s2) if(!copy1(v1, v2, r->s2, f)) return 0; } return 1; } /* * The idea is to remove redundant constants. * $c1->v1 * ($c1->v2 s/$c1/v1)* * set v1 return * The v1->v2 should be eliminated by copy propagation. */ void constprop(Adr *c1, Adr *v1, Reg *r) { Prog *p; if(debug['C']) print("constprop %D->%D\n", c1, v1); for(; r != R; r = r->s1) { p = r->prog; if(debug['C']) print("%P", p); if(uniqp(r) == R) { if(debug['C']) print("; merge; return\n"); return; } if(p->as == AMOVW && copyas(&p->from, c1)) { if(debug['C']) print("; sub%D/%D", &p->from, v1); p->from = *v1; } else if(copyu(p, v1, A) > 1) { if(debug['C']) print("; %Dset; return\n", v1); return; } if(debug['C']) print("\n"); if(r->s2) constprop(c1, v1, r->s2); } } /* * ALSL x,y,w * .. (not use w, not set x y w) * AXXX w,a,b (a != w) * .. (not use w) * (set w) * ----------- changed to * .. * AXXX (x<<y),a,b * .. */ #define FAIL(msg) { if(debug['H']) print("\t%s; FAILURE\n", msg); return 0; } int shiftprop(Reg *r) { Reg *r1; Prog *p, *p1, *p2; int n, o; Adr a; p = r->prog; if(p->to.type != D_REG) FAIL("BOTCH: result not reg"); n = p->to.reg; a = zprog.from; if(p->reg != NREG && p->reg != p->to.reg) { a.type = D_REG; a.reg = p->reg; } if(debug['H']) print("shiftprop\n%P", p); r1 = r; for(;;) { /* find first use of shift result; abort if shift operands or result are changed */ r1 = uniqs(r1); if(r1 == R) FAIL("branch"); if(uniqp(r1) == R) FAIL("merge"); p1 = r1->prog; if(debug['H']) print("\n%P", p1); switch(copyu(p1, &p->to, A)) { case 0: /* not used or set */ if((p->from.type == D_REG && copyu(p1, &p->from, A) > 1) || (a.type == D_REG && copyu(p1, &a, A) > 1)) FAIL("args modified"); continue; case 3: /* set, not used */ FAIL("BOTCH: noref"); } break; } /* check whether substitution can be done */ switch(p1->as) { case ABIC: case ACMP: case ACMN: if(p1->reg == n) FAIL("can't swap"); if(p1->reg == NREG && p1->to.reg == n) FAIL("shift result used twice"); case AMVN: if(p1->from.type == D_SHIFT) FAIL("shift result used in shift"); if(p1->from.type != D_REG || p1->from.reg != n) FAIL("BOTCH: where is it used?"); break; } /* check whether shift result is used subsequently */ p2 = p1; if(p1->to.reg != n) for (;;) { r1 = uniqs(r1); if(r1 == R) FAIL("inconclusive"); p1 = r1->prog; if(debug['H']) print("\n%P", p1); switch(copyu(p1, &p->to, A)) { case 0: /* not used or set */ continue; case 3: /* set, not used */ break; default:/* used */ FAIL("reused"); } break; } /* make the substitution */ p2->from.type = D_SHIFT; p2->from.reg = NREG; o = p->reg; if(o == NREG) o = p->to.reg; switch(p->from.type){ case D_CONST: o |= (p->from.offset&0x3f)<<7; break; case D_REG: o |= (1<<4) | (p->from.reg<<8); break; } switch(p->as){ case ALSL: o |= 0<<5; break; case ALSR: o |= 1<<5; break; case AASR: o |= 2<<5; break; } p2->from.offset = o; if(debug['H']) print("\t=>%P\tSUCCEED\n", p2); return 1; } Reg* findpre(Reg *r, Adr *v) { Reg *r1; for(r1=uniqp(r); r1!=R; r=r1,r1=uniqp(r)) { if(uniqs(r1) != r) return R; switch(copyu(r1->prog, v, A)) { case 1: /* used */ case 2: /* read-alter-rewrite */ return R; case 3: /* set */ case 4: /* set and used */ return r1; } } return R; } Reg* findinc(Reg *r, Reg *r2, Adr *v) { Reg *r1; Prog *p; for(r1=uniqs(r); r1!=R && r1!=r2; r=r1,r1=uniqs(r)) { if(uniqp(r1) != r) return R; switch(copyu(r1->prog, v, A)) { case 0: /* not touched */ continue; case 4: /* set and used */ p = r1->prog; if(p->as == AADD) if(p->from.type == D_CONST) if(p->from.offset > -256 && p->from.offset < 256) return r1; default: return R; } } return R; } int nochange(Reg *r, Reg *r2, Prog *p) { Adr a[3]; int i, n; if(r == r2) return 1; n = 0; if(p->reg != NREG && p->reg != p->to.reg) { a[n].type = D_REG; a[n++].reg = p->reg; } switch(p->from.type) { case D_SHIFT: a[n].type = D_REG; a[n++].reg = p->from.offset&0xf; case D_REG: a[n].type = D_REG; a[n++].reg = p->from.reg; } if(n == 0) return 1; for(; r!=R && r!=r2; r=uniqs(r)) { p = r->prog; for(i=0; i<n; i++) if(copyu(p, &a[i], A) > 1) return 0; } return 1; } int findu1(Reg *r, Adr *v) { for(; r != R; r = r->s1) { if(r->active) return 0; r->active = 1; switch(copyu(r->prog, v, A)) { case 1: /* used */ case 2: /* read-alter-rewrite */ case 4: /* set and used */ return 1; case 3: /* set */ return 0; } if(r->s2) if (findu1(r->s2, v)) return 1; } return 0; } int finduse(Reg *r, Adr *v) { Reg *r1; for(r1=firstr; r1!=R; r1=r1->link) r1->active = 0; return findu1(r, v); } #ifdef NOTYET int xtramodes(Reg *r, Adr *a) { Reg *r1, *r2, *r3; Prog *p, *p1; Adr v; p = r->prog; if(debug['h'] && p->as == AMOVB && p->from.type == D_OREG) /* byte load */ return 0; v = *a; v.type = D_REG; r1 = findpre(r, &v); if(r1 != R) { p1 = r1->prog; if(p1->to.type == D_REG && p1->to.reg == v.reg) switch(p1->as) { case AADD: if(p1->from.type == D_REG || (p1->from.type == D_SHIFT && (p1->from.offset&(1<<4)) == 0 && (p->as != AMOVB || (a == &p->from && (p1->from.offset&~0xf) == 0))) || (p1->from.type == D_CONST && p1->from.offset > -4096 && p1->from.offset < 4096)) if(nochange(uniqs(r1), r, p1)) { if(a != &p->from || v.reg != p->to.reg) if (finduse(r->s1, &v)) { if(p1->reg == NREG || p1->reg == v.reg) /* pre-indexing */ p->scond |= C_WBIT; else return 0; } switch (p1->from.type) { case D_REG: /* register offset */ a->type = D_SHIFT; a->offset = p1->from.reg; break; case D_SHIFT: /* scaled register offset */ a->type = D_SHIFT; case D_CONST: /* immediate offset */ a->offset = p1->from.offset; break; } if(p1->reg != NREG) a->reg = p1->reg; excise(r1); return 1; } break; case AMOVW: if(p1->from.type == D_REG) if((r2 = findinc(r1, r, &p1->from)) != R) { for(r3=uniqs(r2); r3->prog->as==ANOP; r3=uniqs(r3)) ; if(r3 == r) { /* post-indexing */ p1 = r2->prog; a->reg = p1->to.reg; a->offset = p1->from.offset; p->scond |= C_PBIT; if(!finduse(r, &r1->prog->to)) excise(r1); excise(r2); return 1; } } break; } } if(a != &p->from || a->reg != p->to.reg) if((r1 = findinc(r, R, &v)) != R) { /* post-indexing */ p1 = r1->prog; a->offset = p1->from.offset; p->scond |= C_PBIT; excise(r1); return 1; } return 0; } #endif /* * return * 1 if v only used (and substitute), * 2 if read-alter-rewrite * 3 if set * 4 if set and used * 0 otherwise (not touched) */ int copyu(Prog *p, Adr *v, Adr *s) { switch(p->as) { default: if(debug['P']) print(" (unk)"); return 2; case ANOP: /* read, write */ case AFMOVS: case AFMOVD: case AMOVH: case AMOVHU: case AMOVB: case AMOVBU: case AMOVW: case AMOVWU: case ASXTW: case AMOV: case AMVN: case AMVNW: case ANEG: case ANEGS: case ANEGW: case ANEGSW: case ANGC: case ANGCS: case ANGCW: case ANGCSW: case AFCVTSD: case AFCVTDS: case AFCVTZSD: case AFCVTZSDW: case AFCVTZSS: case AFCVTZSSW: case AFCVTZUD: case AFCVTZUDW: case AFCVTZUS: case AFCVTZUSW: case ASCVTFD: case ASCVTFS: case ASCVTFWD: case ASCVTFWS: case AUCVTFD: case AUCVTFS: case AUCVTFWD: case AUCVTFWS: case AFNEGD: case AFNEGS: case AFABSD: case AFABSS: case AFSQRTD: case AFSQRTS: case ACASE: #ifdef YYY if(p->scond&(C_WBIT|C_PBIT)) if(v->type == D_REG) { if(p->from.type == D_OREG || p->from.type == D_SHIFT) { if(p->from.reg == v->reg) return 2; } else { if(p->to.reg == v->reg) return 2; } } #endif if(s != A) { if(copysub(&p->from, v, s, 1)) return 1; if(!copyas(&p->to, v)) if(copysub(&p->to, v, s, 1)) return 1; return 0; } if(copyas(&p->to, v)) { if(copyau(&p->from, v)) return 4; return 3; } if(copyau(&p->from, v)) return 1; if(copyau(&p->to, v)) return 1; return 0; case AADD: /* read, read, write */ case AADDW: case AADDS: case AADDSW: case ASUB: case ASUBW: case ASUBS: case ASUBSW: if(0 && p->from.type == D_CONST){ if(s != A && regzer(s)) return 4; /* add/sub $c,r,r -> r31 is sp not zr, don't touch */ } case ALSL: case ALSLW: case ALSR: case ALSRW: case AASR: case AASRW: case AORR: case AORRW: case AAND: case AANDW: case AEOR: case AEORW: case AMUL: case AMULW: case AUMULL: case AREM: case AREMW: case ASDIV: case ASDIVW: case AUDIV: case AUDIVW: case AUREM: case AUREMW: case AFADDS: case AFADDD: case AFSUBS: case AFSUBD: case AFMULS: case AFMULD: case AFDIVS: case AFDIVD: if(s != A) { if(copysub(&p->from, v, s, 1)) return 1; if(copysub1(p, v, s, 1)) return 1; if(!copyas(&p->to, v)) if(copysub(&p->to, v, s, 1)) return 1; return 0; } if(copyas(&p->to, v)) { if(p->reg == NREG) p->reg = p->to.reg; if(copyau(&p->from, v)) return 4; if(copyau1(p, v)) return 4; return 3; } if(copyau(&p->from, v)) return 1; if(copyau1(p, v)) return 1; if(copyau(&p->to, v)) return 1; return 0; case ABEQ: /* read, read */ case ABNE: case ABCS: case ABHS: case ABCC: case ABLO: case ABMI: case ABPL: case ABVS: case ABVC: case ABHI: case ABLS: case ABGE: case ABLT: case ABGT: case ABLE: case AFCMPS: case AFCMPD: case ACMP: case ACMPW: case ACMN: case ACMNW: if(s != A) { if(copysub(&p->from, v, s, 1)) return 1; return copysub1(p, v, s, 1); } if(copyau(&p->from, v)) return 1; if(copyau1(p, v)) return 1; return 0; case AB: /* funny */ if(s != A) { if(copysub(&p->to, v, s, 1)) return 1; return 0; } if(copyau(&p->to, v)) return 1; return 0; case ARET: case ARETURN: /* funny */ if(v->type == D_REG) if(v->reg == REGRET) return 2; if(v->type == D_FREG) if(v->reg == FREGRET) return 2; case ABL: /* funny */ if(v->type == D_REG) { if(v->reg <= REGEXT && v->reg > exregoffset) return 2; if(v->reg == REGARG) return 2; } if(v->type == D_FREG) if(v->reg <= FREGEXT && v->reg > exfregoffset) return 2; if(s != A) { if(copysub(&p->to, v, s, 1)) return 1; return 0; } if(copyau(&p->to, v)) return 4; return 3; case ATEXT: /* funny */ if(v->type == D_REG) if(v->reg == REGARG) return 3; return 0; } } int a2type(Prog *p) { switch(p->as) { case ACMP: case ACMPW: case ACMN: case ACMNW: case AADD: case AADDW: case AADDS: case AADDSW: case ASUB: case ASUBS: case ASUBSW: case ASUBW: case ALSL: case ALSLW: case ALSR: case ALSRW: case AASR: case AASRW: case AORR: case AORRW: case AAND: case AANDW: case AANDS: case AANDSW: case AEOR: case AEORW: case AMUL: case AMULW: case AUMULL: case AREM: case AREMW: case ASDIV: case ASDIVW: case AUDIV: case AUDIVW: case AUREM: case AUREMW: return D_REG; case AFCMPS: case AFCMPD: case AFADDS: case AFADDD: case AFSUBS: case AFSUBD: case AFMULS: case AFMULD: case AFDIVS: case AFDIVD: return D_FREG; } return D_NONE; } /* * direct reference, * could be set/use depending on * semantics */ int copyas(Adr *a, Adr *v) { if(regtyp(v)) { if(a->type == v->type) if(a->reg == v->reg) return 1; } else if(v->type == D_CONST) { /* for constprop */ if(a->type == v->type) if(a->name == v->name) if(a->sym == v->sym) if(a->reg == v->reg) if(a->offset == v->offset) return 1; } return 0; } /* * either direct or indirect */ int copyau(Adr *a, Adr *v) { if(copyas(a, v)) return 1; if(v->type == D_REG) { if(a->type == D_OREG) { if(v->reg == a->reg) return 1; } else if(a->type == D_SHIFT) { if(((a->offset>>16)&0x1F) == v->reg) return 1; } else if(a->type == D_EXTREG) { if(a->reg == v->reg || ((a->offset>>16)&0x1F) == v->reg) return 1; } } return 0; } int copyau1(Prog *p, Adr *v) { if(regtyp(v)) { if(a2type(p) == v->type) if(p->reg == v->reg) { if(a2type(p) != v->type) print("botch a2type %P\n", p); return 1; } } return 0; } /* * substitute s for v in a * return failure to substitute */ int copysub(Adr *a, Adr *v, Adr *s, int f) { if(f) if(copyau(a, v)) { if(a->type == D_SHIFT) { if(((a->offset>>16)&0x1F) == v->reg) a->offset = (a->offset&~(0x1F<<16))|(s->reg<<16); } else a->reg = s->reg; } return 0; } int copysub1(Prog *p1, Adr *v, Adr *s, int f) { if(f) if(copyau1(p1, v)) p1->reg = s->reg; return 0; } struct { int opcode; int notopcode; int scond; int notscond; } predinfo[] = { { ABEQ, ABNE, 0x0, 0x1, }, { ABNE, ABEQ, 0x1, 0x0, }, { ABCS, ABCC, 0x2, 0x3, }, { ABHS, ABLO, 0x2, 0x3, }, { ABCC, ABCS, 0x3, 0x2, }, { ABLO, ABHS, 0x3, 0x2, }, { ABMI, ABPL, 0x4, 0x5, }, { ABPL, ABMI, 0x5, 0x4, }, { ABVS, ABVC, 0x6, 0x7, }, { ABVC, ABVS, 0x7, 0x6, }, { ABHI, ABLS, 0x8, 0x9, }, { ABLS, ABHI, 0x9, 0x8, }, { ABGE, ABLT, 0xA, 0xB, }, { ABLT, ABGE, 0xB, 0xA, }, { ABGT, ABLE, 0xC, 0xD, }, { ABLE, ABGT, 0xD, 0xC, }, }; typedef struct { Reg *start; Reg *last; Reg *end; int len; } Joininfo; enum { Join, Split, End, Branch, Setcond, Toolong }; enum { Falsecond, Truecond, Delbranch, Keepbranch }; int isbranch(Prog *p) { return (ABEQ <= p->as) && (p->as <= ABLE); } int predicable(Prog *p) { if (isbranch(p) || p->as == ANOP || p->as == AXXX || p->as == ADATA || p->as == AGLOBL || p->as == AGOK || p->as == AHISTORY || p->as == ANAME || p->as == ASIGNAME || p->as == ATEXT || p->as == AWORD || p->as == ADYNT || p->as == AINIT || p->as == ABCASE || p->as == ACASE) return 0; return 1; } /* * Depends on an analysis of the encodings performed by 5l. * These seem to be all of the opcodes that lead to the "S" bit * being set in the instruction encodings. * * C_SBIT may also have been set explicitly in p->scond. */ int modifiescpsr(Prog *p) { // return (p->scond&C_SBIT) return 1 || p->as == ATST || p->as == ACMN || p->as == ACMP || p->as == AUMULL || p->as == AUDIV || p->as == AMUL || p->as == ASDIV || p->as == AREM || p->as == AUREM || p->as == ABL; } /* * Find the maximal chain of instructions starting with r which could * be executed conditionally */ int joinsplit(Reg *r, Joininfo *j) { j->start = r; j->last = r; j->len = 0; do { if (r->p2 && (r->p1 || r->p2->p2link)) { j->end = r; return Join; } if (r->s1 && r->s2) { j->end = r; return Split; } j->last = r; if (r->prog->as != ANOP) j->len++; if (!r->s1 && !r->s2) { j->end = r->link; return End; } if (r->s2) { j->end = r->s2; return Branch; } if (modifiescpsr(r->prog)) { j->end = r->s1; return Setcond; } r = r->s1; } while (j->len < 4); j->end = r; return Toolong; } Reg * successor(Reg *r) { if (r->s1) return r->s1; else return r->s2; } #ifdef XXX void applypred(Reg *rstart, Joininfo *j, int cond, int branch) { int pred; Reg *r; if(j->len == 0) return; if (cond == Truecond) pred = predinfo[rstart->prog->as - ABEQ].scond; else pred = predinfo[rstart->prog->as - ABEQ].notscond; for (r = j->start; ; r = successor(r)) { if (r->prog->as == AB) { if (r != j->last || branch == Delbranch) excise(r); else { if (cond == Truecond) r->prog->as = predinfo[rstart->prog->as - ABEQ].opcode; else r->prog->as = predinfo[rstart->prog->as - ABEQ].notopcode; } } else if (predicable(r->prog)) r->prog->scond = (r->prog->scond&~C_SCOND)|pred; if (r->s1 != r->link) { r->s1 = r->link; r->link->p1 = r; } if (r == j->last) break; } } void predicate(void) { Reg *r; int t1, t2; Joininfo j1, j2; for(r=firstr; r!=R; r=r->link) { if (isbranch(r->prog)) { t1 = joinsplit(r->s1, &j1); t2 = joinsplit(r->s2, &j2); if(j1.last->link != j2.start) continue; if(j1.end == j2.end) if((t1 == Branch && (t2 == Join || t2 == Setcond)) || (t2 == Join && (t1 == Join || t1 == Setcond))) { applypred(r, &j1, Falsecond, Delbranch); applypred(r, &j2, Truecond, Delbranch); excise(r); continue; } if(t1 == End || t1 == Branch) { applypred(r, &j1, Falsecond, Keepbranch); excise(r); continue; } } } } #endif