// Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // TODO(rsc): // assume CLD? #include "gg.h" void mgen(Node *n, Node *n1, Node *rg) { n1->op = OEMPTY; if(n->addable) { *n1 = *n; if(n1->op == OREGISTER || n1->op == OINDREG) reg[n->val.u.reg]++; return; } if(n->type->width > widthptr) tempname(n1, n->type); else regalloc(n1, n->type, rg); cgen(n, n1); } void mfree(Node *n) { if(n->op == OREGISTER) regfree(n); } /* * generate: * res = n; * simplifies and calls gmove. * * TODO: * sudoaddable */ void cgen(Node *n, Node *res) { Node *nl, *nr, *r, n1, n2, nt, f0, f1; Prog *p1, *p2, *p3; int a; if(debug['g']) { dump("\ncgen-n", n); dump("cgen-res", res); } if(n == N || n->type == T) fatal("cgen: n nil"); if(res == N || res->type == T) fatal("cgen: res nil"); // inline slices if(cgen_inline(n, res)) return; while(n->op == OCONVNOP) n = n->left; // function calls on both sides? introduce temporary if(n->ullman >= UINF && res->ullman >= UINF) { tempname(&n1, n->type); cgen(n, &n1); cgen(&n1, res); return; } // structs etc get handled specially if(isfat(n->type)) { sgen(n, res, n->type->width); return; } // update addressability for string, slice // can't do in walk because n->left->addable // changes if n->left is an escaping local variable. switch(n->op) { case OLEN: if(isslice(n->left->type) || istype(n->left->type, TSTRING)) n->addable = n->left->addable; break; case OCAP: if(isslice(n->left->type)) n->addable = n->left->addable; break; } // if both are addressable, move if(n->addable && res->addable) { gmove(n, res); return; } // if both are not addressable, use a temporary. if(!n->addable && !res->addable) { // could use regalloc here sometimes, // but have to check for ullman >= UINF. tempname(&n1, n->type); cgen(n, &n1); cgen(&n1, res); return; } // if result is not addressable directly but n is, // compute its address and then store via the address. if(!res->addable) { igen(res, &n1, N); cgen(n, &n1); regfree(&n1); return; } // otherwise, the result is addressable but n is not. // let's do some computation. // use ullman to pick operand to eval first. nl = n->left; nr = n->right; if(nl != N && nl->ullman >= UINF) if(nr != N && nr->ullman >= UINF) { // both are hard tempname(&n1, nl->type); cgen(nl, &n1); n2 = *n; n2.left = &n1; cgen(&n2, res); return; } // 64-bit ops are hard on 32-bit machine. if(is64(n->type) || is64(res->type) || n->left != N && is64(n->left->type)) { switch(n->op) { // math goes to cgen64. case OMINUS: case OCOM: case OADD: case OSUB: case OMUL: case OLSH: case ORSH: case OAND: case OOR: case OXOR: cgen64(n, res); return; } } if(nl != N && isfloat[n->type->etype] && isfloat[nl->type->etype]) goto flt; switch(n->op) { default: dump("cgen", n); fatal("cgen %O", n->op); break; // these call bgen to get a bool value case OOROR: case OANDAND: case OEQ: case ONE: case OLT: case OLE: case OGE: case OGT: case ONOT: p1 = gbranch(AJMP, T); p2 = pc; gmove(nodbool(1), res); p3 = gbranch(AJMP, T); patch(p1, pc); bgen(n, 1, p2); gmove(nodbool(0), res); patch(p3, pc); return; case OPLUS: cgen(nl, res); return; case OMINUS: case OCOM: a = optoas(n->op, nl->type); goto uop; // symmetric binary case OAND: case OOR: case OXOR: case OADD: case OMUL: a = optoas(n->op, nl->type); if(a == AIMULB) { cgen_bmul(n->op, nl, nr, res); break; } goto sbop; // asymmetric binary case OSUB: a = optoas(n->op, nl->type); goto abop; case OCONV: if(eqtype(n->type, nl->type) || noconv(n->type, nl->type)) { cgen(nl, res); break; } mgen(nl, &n1, res); gmove(&n1, res); mfree(&n1); break; case ODOT: case ODOTPTR: case OINDEX: case OIND: case ONAME: // PHEAP or PPARAMREF var igen(n, &n1, res); gmove(&n1, res); regfree(&n1); break; case OLEN: if(istype(nl->type, TMAP) || istype(nl->type, TCHAN)) { // map has len in the first 32-bit word. // a zero pointer means zero length tempname(&n1, types[tptr]); cgen(nl, &n1); regalloc(&n2, types[tptr], N); gmove(&n1, &n2); n1 = n2; nodconst(&n2, types[tptr], 0); gins(optoas(OCMP, types[tptr]), &n1, &n2); p1 = gbranch(optoas(OEQ, types[tptr]), T); n2 = n1; n2.op = OINDREG; n2.type = types[TINT32]; gmove(&n2, &n1); patch(p1, pc); gmove(&n1, res); regfree(&n1); break; } if(istype(nl->type, TSTRING) || isslice(nl->type)) { // both slice and string have len one pointer into the struct. igen(nl, &n1, res); n1.op = OREGISTER; // was OINDREG regalloc(&n2, types[TUINT32], &n1); n1.op = OINDREG; n1.type = types[TUINT32]; n1.xoffset = Array_nel; gmove(&n1, &n2); gmove(&n2, res); regfree(&n1); regfree(&n2); break; } fatal("cgen: OLEN: unknown type %lT", nl->type); break; case OCAP: if(istype(nl->type, TCHAN)) { // chan has cap in the second 32-bit word. // a zero pointer means zero length regalloc(&n1, types[tptr], res); cgen(nl, &n1); nodconst(&n2, types[tptr], 0); gins(optoas(OCMP, types[tptr]), &n1, &n2); p1 = gbranch(optoas(OEQ, types[tptr]), T); n2 = n1; n2.op = OINDREG; n2.xoffset = 4; n2.type = types[TINT32]; gmove(&n2, &n1); patch(p1, pc); gmove(&n1, res); regfree(&n1); break; } if(isslice(nl->type)) { igen(nl, &n1, res); n1.op = OINDREG; n1.type = types[TUINT32]; n1.xoffset = Array_cap; gmove(&n1, res); regfree(&n1); break; } fatal("cgen: OCAP: unknown type %lT", nl->type); break; case OADDR: agen(nl, res); break; case OCALLMETH: cgen_callmeth(n, 0); cgen_callret(n, res); break; case OCALLINTER: cgen_callinter(n, res, 0); cgen_callret(n, res); break; case OCALLFUNC: cgen_call(n, 0); cgen_callret(n, res); break; case OMOD: case ODIV: cgen_div(n->op, nl, nr, res); break; case OLSH: case ORSH: cgen_shift(n->op, nl, nr, res); break; } return; sbop: // symmetric binary if(nl->ullman < nr->ullman) { r = nl; nl = nr; nr = r; } abop: // asymmetric binary if(nl->ullman >= nr->ullman) { tempname(&nt, nl->type); cgen(nl, &nt); mgen(nr, &n2, N); regalloc(&n1, nl->type, res); gmove(&nt, &n1); gins(a, &n2, &n1); gmove(&n1, res); regfree(&n1); mfree(&n2); } else { regalloc(&n2, nr->type, res); cgen(nr, &n2); regalloc(&n1, nl->type, N); cgen(nl, &n1); gins(a, &n2, &n1); regfree(&n2); gmove(&n1, res); regfree(&n1); } return; uop: // unary tempname(&n1, nl->type); cgen(nl, &n1); gins(a, N, &n1); gmove(&n1, res); return; flt: // floating-point. 387 (not SSE2) to interoperate with 6c nodreg(&f0, nl->type, D_F0); nodreg(&f1, n->type, D_F0+1); if(nr != N) goto flt2; if(n->op == OMINUS) { nr = nodintconst(-1); convlit(&nr, n->type); n->op = OMUL; goto flt2; } // unary cgen(nl, &f0); if(n->op != OCONV && n->op != OPLUS) gins(foptoas(n->op, n->type, 0), &f0, &f0); gmove(&f0, res); return; flt2: // binary if(nl->ullman >= nr->ullman) { cgen(nl, &f0); if(nr->addable) gins(foptoas(n->op, n->type, 0), nr, &f0); else { cgen(nr, &f0); gins(foptoas(n->op, n->type, Fpop), &f0, &f1); } } else { cgen(nr, &f0); if(nl->addable) gins(foptoas(n->op, n->type, Frev), nl, &f0); else { cgen(nl, &f0); gins(foptoas(n->op, n->type, Frev|Fpop), &f0, &f1); } } gmove(&f0, res); return; } /* * address gen * res = &n; */ void agen(Node *n, Node *res) { Node *nl, *nr; Node n1, n2, n3, n4, tmp; Type *t; uint32 w; uint64 v; Prog *p1; if(debug['g']) { dump("\nagen-res", res); dump("agen-r", n); } if(n == N || n->type == T || res == N || res->type == T) fatal("agen"); while(n->op == OCONVNOP) n = n->left; // addressable var is easy if(n->addable) { if(n->op == OREGISTER) fatal("agen OREGISTER"); regalloc(&n1, types[tptr], res); gins(ALEAL, n, &n1); gmove(&n1, res); regfree(&n1); return; } // let's compute nl = n->left; nr = n->right; switch(n->op) { default: fatal("agen %O", n->op); case OCALLMETH: cgen_callmeth(n, 0); cgen_aret(n, res); break; case OCALLINTER: cgen_callinter(n, res, 0); cgen_aret(n, res); break; case OCALLFUNC: cgen_call(n, 0); cgen_aret(n, res); break; case OINDEX: // TODO(rsc): uint64 indices w = n->type->width; if(nr->addable) { agenr(nl, &n3, res); if(!isconst(nr, CTINT)) { tempname(&tmp, types[TINT32]); cgen(nr, &tmp); regalloc(&n1, tmp.type, N); gmove(&tmp, &n1); } } else if(nl->addable) { if(!isconst(nr, CTINT)) { tempname(&tmp, types[TINT32]); cgen(nr, &tmp); regalloc(&n1, tmp.type, N); gmove(&tmp, &n1); } regalloc(&n3, types[tptr], res); agen(nl, &n3); } else { tempname(&tmp, types[TINT32]); cgen(nr, &tmp); nr = &tmp; agenr(nl, &n3, res); regalloc(&n1, tmp.type, N); gins(optoas(OAS, tmp.type), &tmp, &n1); } // &a is in &n3 (allocated in res) // i is in &n1 (if not constant) // w is width // explicit check for nil if array is large enough // that we might derive too big a pointer. if(!isslice(nl->type) && nl->type->width >= unmappedzero) { regalloc(&n4, types[tptr], &n3); gmove(&n3, &n4); n4.op = OINDREG; n4.type = types[TUINT8]; n4.xoffset = 0; gins(ATESTB, nodintconst(0), &n4); regfree(&n4); } if(w == 0) fatal("index is zero width"); // constant index if(isconst(nr, CTINT)) { v = mpgetfix(nr->val.u.xval); if(isslice(nl->type)) { if(!debug['B'] && !n->etype) { n1 = n3; n1.op = OINDREG; n1.type = types[tptr]; n1.xoffset = Array_nel; nodconst(&n2, types[TUINT32], v); gins(optoas(OCMP, types[TUINT32]), &n1, &n2); p1 = gbranch(optoas(OGT, types[TUINT32]), T); ginscall(throwindex, 0); patch(p1, pc); } n1 = n3; n1.op = OINDREG; n1.type = types[tptr]; n1.xoffset = Array_array; gmove(&n1, &n3); } else if(!debug['B'] && !n->etype) { if(v < 0) yyerror("out of bounds on array"); else if(v >= nl->type->bound) yyerror("out of bounds on array"); } nodconst(&n2, types[tptr], v*w); gins(optoas(OADD, types[tptr]), &n2, &n3); gmove(&n3, res); regfree(&n3); break; } // type of the index t = types[TUINT32]; if(issigned[n1.type->etype]) t = types[TINT32]; regalloc(&n2, t, &n1); // i gmove(&n1, &n2); regfree(&n1); if(!debug['B'] && !n->etype) { // check bounds if(isslice(nl->type)) { n1 = n3; n1.op = OINDREG; n1.type = types[tptr]; n1.xoffset = Array_nel; } else nodconst(&n1, types[TUINT32], nl->type->bound); gins(optoas(OCMP, types[TUINT32]), &n2, &n1); p1 = gbranch(optoas(OLT, types[TUINT32]), T); ginscall(throwindex, 0); patch(p1, pc); } if(isslice(nl->type)) { n1 = n3; n1.op = OINDREG; n1.type = types[tptr]; n1.xoffset = Array_array; gmove(&n1, &n3); } if(w == 1 || w == 2 || w == 4 || w == 8) { p1 = gins(ALEAL, &n2, &n3); p1->from.scale = w; p1->from.index = p1->from.type; p1->from.type = p1->to.type + D_INDIR; } else { nodconst(&n1, t, w); gins(optoas(OMUL, t), &n1, &n2); gins(optoas(OADD, types[tptr]), &n2, &n3); gmove(&n3, res); } gmove(&n3, res); regfree(&n2); regfree(&n3); break; case ONAME: // should only get here with names in this func. if(n->funcdepth > 0 && n->funcdepth != funcdepth) { dump("bad agen", n); fatal("agen: bad ONAME funcdepth %d != %d", n->funcdepth, funcdepth); } // should only get here for heap vars or paramref if(!(n->class & PHEAP) && n->class != PPARAMREF) { dump("bad agen", n); fatal("agen: bad ONAME class %#x", n->class); } cgen(n->heapaddr, res); if(n->xoffset != 0) { nodconst(&n1, types[tptr], n->xoffset); gins(optoas(OADD, types[tptr]), &n1, res); } break; case OIND: cgen(nl, res); break; case ODOT: t = nl->type; agen(nl, res); if(n->xoffset != 0) { nodconst(&n1, types[tptr], n->xoffset); gins(optoas(OADD, types[tptr]), &n1, res); } break; case ODOTPTR: t = nl->type; if(!isptr[t->etype]) fatal("agen: not ptr %N", n); cgen(nl, res); if(n->xoffset != 0) { // explicit check for nil if struct is large enough // that we might derive too big a pointer. if(nl->type->type->width >= unmappedzero) { regalloc(&n1, types[tptr], res); gmove(res, &n1); n1.op = OINDREG; n1.type = types[TUINT8]; n1.xoffset = 0; gins(ATESTB, nodintconst(0), &n1); regfree(&n1); } nodconst(&n1, types[tptr], n->xoffset); gins(optoas(OADD, types[tptr]), &n1, res); } break; } } /* * generate: * newreg = &n; * res = newreg * * on exit, a has been changed to be *newreg. * caller must regfree(a). */ void igen(Node *n, Node *a, Node *res) { Node n1; tempname(&n1, types[tptr]); agen(n, &n1); regalloc(a, types[tptr], res); gmove(&n1, a); a->op = OINDREG; a->type = n->type; } /* * generate: * newreg = &n; * * caller must regfree(a). */ void agenr(Node *n, Node *a, Node *res) { Node n1; tempname(&n1, types[tptr]); agen(n, &n1); regalloc(a, types[tptr], res); gmove(&n1, a); } /* * branch gen * if(n == true) goto to; */ void bgen(Node *n, int true, Prog *to) { int et, a; Node *nl, *nr, *r; Node n1, n2, tmp, t1, t2, ax; Prog *p1, *p2; if(debug['g']) { dump("\nbgen", n); } if(n == N) n = nodbool(1); nl = n->left; nr = n->right; if(n->type == T) { convlit(&n, types[TBOOL]); if(n->type == T) return; } et = n->type->etype; if(et != TBOOL) { yyerror("cgen: bad type %T for %O", n->type, n->op); patch(gins(AEND, N, N), to); return; } nl = N; nr = N; switch(n->op) { default: def: regalloc(&n1, n->type, N); cgen(n, &n1); nodconst(&n2, n->type, 0); gins(optoas(OCMP, n->type), &n1, &n2); a = AJNE; if(!true) a = AJEQ; patch(gbranch(a, n->type), to); regfree(&n1); return; case OLITERAL: // need to ask if it is bool? if(!true == !n->val.u.bval) patch(gbranch(AJMP, T), to); return; case ONAME: if(!n->addable) goto def; nodconst(&n1, n->type, 0); gins(optoas(OCMP, n->type), n, &n1); a = AJNE; if(!true) a = AJEQ; patch(gbranch(a, n->type), to); return; case OANDAND: if(!true) goto caseor; caseand: p1 = gbranch(AJMP, T); p2 = gbranch(AJMP, T); patch(p1, pc); bgen(n->left, !true, p2); bgen(n->right, !true, p2); p1 = gbranch(AJMP, T); patch(p1, to); patch(p2, pc); return; case OOROR: if(!true) goto caseand; caseor: bgen(n->left, true, to); bgen(n->right, true, to); return; case OEQ: case ONE: case OLT: case OGT: case OLE: case OGE: nr = n->right; if(nr == N || nr->type == T) return; case ONOT: // unary nl = n->left; if(nl == N || nl->type == T) return; } switch(n->op) { case ONOT: bgen(nl, !true, to); break; case OEQ: case ONE: case OLT: case OGT: case OLE: case OGE: a = n->op; if(!true) { if(isfloat[nl->type->etype]) { // brcom is not valid on floats when NaN is involved. p1 = gbranch(AJMP, T); p2 = gbranch(AJMP, T); patch(p1, pc); bgen(n, 1, p2); patch(gbranch(AJMP, T), to); patch(p2, pc); break; } a = brcom(a); } // make simplest on right if(nl->op == OLITERAL || nl->ullman < nr->ullman) { a = brrev(a); r = nl; nl = nr; nr = r; } if(isslice(nl->type)) { // only valid to cmp darray to literal nil if((a != OEQ && a != ONE) || nr->op != OLITERAL) { yyerror("illegal array comparison"); break; } a = optoas(a, types[tptr]); regalloc(&n1, types[tptr], N); agen(nl, &n1); n2 = n1; n2.op = OINDREG; n2.xoffset = Array_array; nodconst(&tmp, types[tptr], 0); gins(optoas(OCMP, types[tptr]), &n2, &tmp); patch(gbranch(a, types[tptr]), to); regfree(&n1); break; } if(isinter(nl->type)) { // front end shold only leave cmp to literal nil if((a != OEQ && a != ONE) || nr->op != OLITERAL) { yyerror("illegal interface comparison"); break; } a = optoas(a, types[tptr]); regalloc(&n1, types[tptr], N); agen(nl, &n1); n2 = n1; n2.op = OINDREG; n2.xoffset = 0; nodconst(&tmp, types[tptr], 0); gins(optoas(OCMP, types[tptr]), &n2, &tmp); patch(gbranch(a, types[tptr]), to); regfree(&n1); break; } if(isfloat[nr->type->etype]) { a = brrev(a); // because the args are stacked if(a == OGE || a == OGT) { // only < and <= work right with NaN; reverse if needed r = nr; nr = nl; nl = r; a = brrev(a); } nodreg(&tmp, nr->type, D_F0); nodreg(&n2, nr->type, D_F0 + 1); nodreg(&ax, types[TUINT16], D_AX); et = simsimtype(nr->type); if(et == TFLOAT64) { // easy - do in FPU cgen(nr, &tmp); cgen(nl, &tmp); gins(AFUCOMPP, &tmp, &n2); } else { // TODO(rsc): The moves back and forth to memory // here are for truncating the value to 32 bits. // This handles 32-bit comparison but presumably // all the other ops have the same problem. // We need to figure out what the right general // solution is, besides telling people to use float64. tempname(&t1, types[TFLOAT32]); tempname(&t2, types[TFLOAT32]); cgen(nr, &t1); cgen(nl, &t2); gmove(&t2, &tmp); gins(AFCOMFP, &t1, &tmp); } gins(AFSTSW, N, &ax); gins(ASAHF, N, N); if(a == OEQ) { // neither NE nor P p1 = gbranch(AJNE, T); p2 = gbranch(AJPS, T); patch(gbranch(AJMP, T), to); patch(p1, pc); patch(p2, pc); } else if(a == ONE) { // either NE or P patch(gbranch(AJNE, T), to); patch(gbranch(AJPS, T), to); } else patch(gbranch(optoas(a, nr->type), T), to); break; } if(is64(nr->type)) { if(!nl->addable) { tempname(&n1, nl->type); cgen(nl, &n1); nl = &n1; } if(!nr->addable) { tempname(&n2, nr->type); cgen(nr, &n2); nr = &n2; } cmp64(nl, nr, a, to); break; } a = optoas(a, nr->type); if(nr->ullman >= UINF) { tempname(&n1, nl->type); tempname(&tmp, nr->type); cgen(nr, &tmp); cgen(nl, &n1); regalloc(&n2, nr->type, N); cgen(&tmp, &n2); goto cmp; } tempname(&n1, nl->type); cgen(nl, &n1); if(smallintconst(nr)) { gins(optoas(OCMP, nr->type), &n1, nr); patch(gbranch(a, nr->type), to); break; } tempname(&tmp, nr->type); cgen(nr, &tmp); regalloc(&n2, nr->type, N); gmove(&tmp, &n2); cmp: gins(optoas(OCMP, nr->type), &n1, &n2); patch(gbranch(a, nr->type), to); regfree(&n2); break; } } /* * n is on stack, either local variable * or return value from function call. * return n's offset from SP. */ int32 stkof(Node *n) { Type *t; Iter flist; switch(n->op) { case OINDREG: return n->xoffset; case OCALLMETH: case OCALLINTER: case OCALLFUNC: t = n->left->type; if(isptr[t->etype]) t = t->type; t = structfirst(&flist, getoutarg(t)); if(t != T) return t->width; break; } // botch - probably failing to recognize address // arithmetic on the above. eg INDEX and DOT return -1000; } /* * struct gen * memmove(&res, &n, w); */ void sgen(Node *n, Node *res, int32 w) { Node dst, src, tdst, tsrc; int32 c, q, odst, osrc; if(debug['g']) { print("\nsgen w=%d\n", w); dump("r", n); dump("res", res); } if(w == 0) return; if(n->ullman >= UINF && res->ullman >= UINF) { fatal("sgen UINF"); } if(w < 0) fatal("sgen copy %d", w); // offset on the stack osrc = stkof(n); odst = stkof(res); nodreg(&dst, types[tptr], D_DI); nodreg(&src, types[tptr], D_SI); tempname(&tsrc, types[tptr]); tempname(&tdst, types[tptr]); if(!n->addable) agen(n, &tsrc); if(!res->addable) agen(res, &tdst); if(n->addable) agen(n, &src); else gmove(&tsrc, &src); if(res->addable) agen(res, &dst); else gmove(&tdst, &dst); c = w % 4; // bytes q = w / 4; // doublewords // if we are copying forward on the stack and // the src and dst overlap, then reverse direction if(osrc < odst && odst < osrc+w) { // reverse direction gins(ASTD, N, N); // set direction flag if(c > 0) { gconreg(AADDL, w-1, D_SI); gconreg(AADDL, w-1, D_DI); gconreg(AMOVL, c, D_CX); gins(AREP, N, N); // repeat gins(AMOVSB, N, N); // MOVB *(SI)-,*(DI)- } if(q > 0) { if(c > 0) { gconreg(AADDL, -3, D_SI); gconreg(AADDL, -3, D_DI); } else { gconreg(AADDL, w-4, D_SI); gconreg(AADDL, w-4, D_DI); } gconreg(AMOVL, q, D_CX); gins(AREP, N, N); // repeat gins(AMOVSL, N, N); // MOVL *(SI)-,*(DI)- } // we leave with the flag clear gins(ACLD, N, N); } else { gins(ACLD, N, N); // paranoia. TODO(rsc): remove? // normal direction if(q >= 4) { gconreg(AMOVL, q, D_CX); gins(AREP, N, N); // repeat gins(AMOVSL, N, N); // MOVL *(SI)+,*(DI)+ } else while(q > 0) { gins(AMOVSL, N, N); // MOVL *(SI)+,*(DI)+ q--; } while(c > 0) { gins(AMOVSB, N, N); // MOVB *(SI)+,*(DI)+ c--; } } }