/* * generate: * res = n; * simplifies and calls gmove. */ func cgen(n *gc.Node, res *gc.Node) { //print("cgen %N(%d) -> %N(%d)\n", n, n->addable, res, res->addable); if gc.Debug['g'] != 0 { gc.Dump("\ncgen-n", n) gc.Dump("cgen-res", res) } if n == nil || n.Type == nil { return } if res == nil || res.Type == nil { gc.Fatal("cgen: res nil") } for n.Op == gc.OCONVNOP { n = n.Left } switch n.Op { case gc.OSLICE, gc.OSLICEARR, gc.OSLICESTR, gc.OSLICE3, gc.OSLICE3ARR: if res.Op != gc.ONAME || res.Addable == 0 { var n1 gc.Node gc.Tempname(&n1, n.Type) gc.Cgen_slice(n, &n1) cgen(&n1, res) } else { gc.Cgen_slice(n, res) } return case gc.OEFACE: if res.Op != gc.ONAME || res.Addable == 0 { var n1 gc.Node gc.Tempname(&n1, n.Type) gc.Cgen_eface(n, &n1) cgen(&n1, res) } else { gc.Cgen_eface(n, res) } return } if n.Ullman >= gc.UINF { if n.Op == gc.OINDREG { gc.Fatal("cgen: this is going to misscompile") } if res.Ullman >= gc.UINF { var n1 gc.Node gc.Tempname(&n1, n.Type) cgen(n, &n1) cgen(&n1, res) return } } if gc.Isfat(n.Type) { if n.Type.Width < 0 { gc.Fatal("forgot to compute width for %v", gc.Tconv(n.Type, 0)) } sgen(n, res, n.Type.Width) return } if res.Addable == 0 { if n.Ullman > res.Ullman { var n1 gc.Node regalloc(&n1, n.Type, res) cgen(n, &n1) if n1.Ullman > res.Ullman { gc.Dump("n1", &n1) gc.Dump("res", res) gc.Fatal("loop in cgen") } cgen(&n1, res) regfree(&n1) return } var f int if res.Ullman >= gc.UINF { goto gen } if gc.Complexop(n, res) { gc.Complexgen(n, res) return } f = 1 // gen thru register switch n.Op { case gc.OLITERAL: if gc.Smallintconst(n) { f = 0 } case gc.OREGISTER: f = 0 } if !gc.Iscomplex[n.Type.Etype] { a := optoas(gc.OAS, res.Type) var addr obj.Addr if sudoaddable(a, res, &addr) { var p1 *obj.Prog if f != 0 { var n2 gc.Node regalloc(&n2, res.Type, nil) cgen(n, &n2) p1 = gins(a, &n2, nil) regfree(&n2) } else { p1 = gins(a, n, nil) } p1.To = addr if gc.Debug['g'] != 0 { fmt.Printf("%v [ignore previous line]\n", p1) } sudoclean() return } } gen: var n1 gc.Node igen(res, &n1, nil) cgen(n, &n1) regfree(&n1) 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 gc.OSPTR, gc.OLEN: if gc.Isslice(n.Left.Type) || gc.Istype(n.Left.Type, gc.TSTRING) { n.Addable = n.Left.Addable } case gc.OCAP: if gc.Isslice(n.Left.Type) { n.Addable = n.Left.Addable } case gc.OITAB: n.Addable = n.Left.Addable } if gc.Complexop(n, res) { gc.Complexgen(n, res) return } // if both are addressable, move if n.Addable != 0 { if n.Op == gc.OREGISTER || res.Op == gc.OREGISTER { gmove(n, res) } else { var n1 gc.Node regalloc(&n1, n.Type, nil) gmove(n, &n1) cgen(&n1, res) regfree(&n1) } return } nl := n.Left nr := n.Right if nl != nil && nl.Ullman >= gc.UINF { if nr != nil && nr.Ullman >= gc.UINF { var n1 gc.Node gc.Tempname(&n1, nl.Type) cgen(nl, &n1) n2 := *n n2.Left = &n1 cgen(&n2, res) return } } if !gc.Iscomplex[n.Type.Etype] { a := optoas(gc.OAS, n.Type) var addr obj.Addr if sudoaddable(a, n, &addr) { if res.Op == gc.OREGISTER { p1 := gins(a, nil, res) p1.From = addr } else { var n2 gc.Node regalloc(&n2, n.Type, nil) p1 := gins(a, nil, &n2) p1.From = addr gins(a, &n2, res) regfree(&n2) } sudoclean() return } } // TODO(minux): we shouldn't reverse FP comparisons, but then we need to synthesize // OGE, OLE, and ONE ourselves. // if(nl != N && isfloat[n->type->etype] && isfloat[nl->type->etype]) goto flt; var a int switch n.Op { default: gc.Dump("cgen", n) gc.Fatal("cgen: unknown op %v", gc.Nconv(n, obj.FmtShort|obj.FmtSign)) // these call bgen to get a bool value case gc.OOROR, gc.OANDAND, gc.OEQ, gc.ONE, gc.OLT, gc.OLE, gc.OGE, gc.OGT, gc.ONOT: p1 := gc.Gbranch(ppc64.ABR, nil, 0) p2 := gc.Pc gmove(gc.Nodbool(true), res) p3 := gc.Gbranch(ppc64.ABR, nil, 0) gc.Patch(p1, gc.Pc) bgen(n, true, 0, p2) gmove(gc.Nodbool(false), res) gc.Patch(p3, gc.Pc) return case gc.OPLUS: cgen(nl, res) return // unary case gc.OCOM: a := optoas(gc.OXOR, nl.Type) var n1 gc.Node regalloc(&n1, nl.Type, nil) cgen(nl, &n1) var n2 gc.Node gc.Nodconst(&n2, nl.Type, -1) gins(a, &n2, &n1) gmove(&n1, res) regfree(&n1) return case gc.OMINUS: if gc.Isfloat[nl.Type.Etype] { nr = gc.Nodintconst(-1) gc.Convlit(&nr, n.Type) a = optoas(gc.OMUL, nl.Type) goto sbop } a := optoas(int(n.Op), nl.Type) // unary var n1 gc.Node regalloc(&n1, nl.Type, res) cgen(nl, &n1) gins(a, nil, &n1) gmove(&n1, res) regfree(&n1) return // symmetric binary case gc.OAND, gc.OOR, gc.OXOR, gc.OADD, gc.OMUL: a = optoas(int(n.Op), nl.Type) goto sbop // asymmetric binary case gc.OSUB: a = optoas(int(n.Op), nl.Type) goto abop case gc.OHMUL: cgen_hmul(nl, nr, res) case gc.OCONV: if n.Type.Width > nl.Type.Width { // If loading from memory, do conversion during load, // so as to avoid use of 8-bit register in, say, int(*byteptr). switch nl.Op { case gc.ODOT, gc.ODOTPTR, gc.OINDEX, gc.OIND, gc.ONAME: var n1 gc.Node igen(nl, &n1, res) var n2 gc.Node regalloc(&n2, n.Type, res) gmove(&n1, &n2) gmove(&n2, res) regfree(&n2) regfree(&n1) return } } var n1 gc.Node regalloc(&n1, nl.Type, res) var n2 gc.Node regalloc(&n2, n.Type, &n1) cgen(nl, &n1) // if we do the conversion n1 -> n2 here // reusing the register, then gmove won't // have to allocate its own register. gmove(&n1, &n2) gmove(&n2, res) regfree(&n2) regfree(&n1) case gc.ODOT, gc.ODOTPTR, gc.OINDEX, gc.OIND, gc.ONAME: // PHEAP or PPARAMREF var var n1 gc.Node igen(n, &n1, res) gmove(&n1, res) regfree(&n1) // interface table is first word of interface value case gc.OITAB: var n1 gc.Node igen(nl, &n1, res) n1.Type = n.Type gmove(&n1, res) regfree(&n1) // pointer is the first word of string or slice. case gc.OSPTR: if gc.Isconst(nl, gc.CTSTR) { var n1 gc.Node regalloc(&n1, gc.Types[gc.Tptr], res) p1 := gins(ppc64.AMOVD, nil, &n1) gc.Datastring(nl.Val.U.Sval, &p1.From) gmove(&n1, res) regfree(&n1) break } var n1 gc.Node igen(nl, &n1, res) n1.Type = n.Type gmove(&n1, res) regfree(&n1) case gc.OLEN: if gc.Istype(nl.Type, gc.TMAP) || gc.Istype(nl.Type, gc.TCHAN) { // map and chan have len in the first int-sized word. // a zero pointer means zero length var n1 gc.Node regalloc(&n1, gc.Types[gc.Tptr], res) cgen(nl, &n1) var n2 gc.Node gc.Nodconst(&n2, gc.Types[gc.Tptr], 0) gins(optoas(gc.OCMP, gc.Types[gc.Tptr]), &n1, &n2) p1 := gc.Gbranch(optoas(gc.OEQ, gc.Types[gc.Tptr]), nil, 0) n2 = n1 n2.Op = gc.OINDREG n2.Type = gc.Types[gc.Simtype[gc.TINT]] gmove(&n2, &n1) gc.Patch(p1, gc.Pc) gmove(&n1, res) regfree(&n1) break } if gc.Istype(nl.Type, gc.TSTRING) || gc.Isslice(nl.Type) { // both slice and string have len one pointer into the struct. // a zero pointer means zero length var n1 gc.Node igen(nl, &n1, res) n1.Type = gc.Types[gc.Simtype[gc.TUINT]] n1.Xoffset += int64(gc.Array_nel) gmove(&n1, res) regfree(&n1) break } gc.Fatal("cgen: OLEN: unknown type %v", gc.Tconv(nl.Type, obj.FmtLong)) case gc.OCAP: if gc.Istype(nl.Type, gc.TCHAN) { // chan has cap in the second int-sized word. // a zero pointer means zero length var n1 gc.Node regalloc(&n1, gc.Types[gc.Tptr], res) cgen(nl, &n1) var n2 gc.Node gc.Nodconst(&n2, gc.Types[gc.Tptr], 0) gins(optoas(gc.OCMP, gc.Types[gc.Tptr]), &n1, &n2) p1 := gc.Gbranch(optoas(gc.OEQ, gc.Types[gc.Tptr]), nil, 0) n2 = n1 n2.Op = gc.OINDREG n2.Xoffset = int64(gc.Widthint) n2.Type = gc.Types[gc.Simtype[gc.TINT]] gmove(&n2, &n1) gc.Patch(p1, gc.Pc) gmove(&n1, res) regfree(&n1) break } if gc.Isslice(nl.Type) { var n1 gc.Node igen(nl, &n1, res) n1.Type = gc.Types[gc.Simtype[gc.TUINT]] n1.Xoffset += int64(gc.Array_cap) gmove(&n1, res) regfree(&n1) break } gc.Fatal("cgen: OCAP: unknown type %v", gc.Tconv(nl.Type, obj.FmtLong)) case gc.OADDR: if n.Bounded { // let race detector avoid nil checks gc.Disable_checknil++ } agen(nl, res) if n.Bounded { gc.Disable_checknil-- } case gc.OCALLMETH: gc.Cgen_callmeth(n, 0) cgen_callret(n, res) case gc.OCALLINTER: cgen_callinter(n, res, 0) cgen_callret(n, res) case gc.OCALLFUNC: cgen_call(n, 0) cgen_callret(n, res) case gc.OMOD, gc.ODIV: if gc.Isfloat[n.Type.Etype] { a = optoas(int(n.Op), nl.Type) goto abop } if nl.Ullman >= nr.Ullman { var n1 gc.Node regalloc(&n1, nl.Type, res) cgen(nl, &n1) cgen_div(int(n.Op), &n1, nr, res) regfree(&n1) } else { var n2 gc.Node if !gc.Smallintconst(nr) { regalloc(&n2, nr.Type, res) cgen(nr, &n2) } else { n2 = *nr } cgen_div(int(n.Op), nl, &n2, res) if n2.Op != gc.OLITERAL { regfree(&n2) } } case gc.OLSH, gc.ORSH, gc.OLROT: cgen_shift(int(n.Op), n.Bounded, nl, nr, res) } return /* * put simplest on right - we'll generate into left * and then adjust it using the computation of right. * constants and variables have the same ullman * count, so look for constants specially. * * an integer constant we can use as an immediate * is simpler than a variable - we can use the immediate * in the adjustment instruction directly - so it goes * on the right. * * other constants, like big integers or floating point * constants, require a mov into a register, so those * might as well go on the left, so we can reuse that * register for the computation. */ sbop: // symmetric binary if nl.Ullman < nr.Ullman || (nl.Ullman == nr.Ullman && (gc.Smallintconst(nl) || (nr.Op == gc.OLITERAL && !gc.Smallintconst(nr)))) { r := nl nl = nr nr = r } abop: // asymmetric binary var n1 gc.Node var n2 gc.Node if nl.Ullman >= nr.Ullman { regalloc(&n1, nl.Type, res) cgen(nl, &n1) /* * This generates smaller code - it avoids a MOV - but it's * easily 10% slower due to not being able to * optimize/manipulate the move. * To see, run: go test -bench . crypto/md5 * with and without. * if(sudoaddable(a, nr, &addr)) { p1 = gins(a, N, &n1); p1->from = addr; gmove(&n1, res); sudoclean(); regfree(&n1); goto ret; } * */ // TODO(minux): enable using constants directly in certain instructions. //if(smallintconst(nr)) // n2 = *nr; //else { regalloc(&n2, nr.Type, nil) cgen(nr, &n2) } else //} { //if(smallintconst(nr)) // n2 = *nr; //else { regalloc(&n2, nr.Type, res) cgen(nr, &n2) //} regalloc(&n1, nl.Type, nil) cgen(nl, &n1) } gins(a, &n2, &n1) // Normalize result for types smaller than word. if n.Type.Width < int64(gc.Widthreg) { switch n.Op { case gc.OADD, gc.OSUB, gc.OMUL, gc.OLSH: gins(optoas(gc.OAS, n.Type), &n1, &n1) } } gmove(&n1, res) regfree(&n1) if n2.Op != gc.OLITERAL { regfree(&n2) } return }
func cgen_floatsse(n *gc.Node, res *gc.Node) { var a int nl := n.Left nr := n.Right switch n.Op { default: gc.Dump("cgen_floatsse", n) gc.Fatal("cgen_floatsse %v", gc.Oconv(int(n.Op), 0)) return case gc.OMINUS, gc.OCOM: nr = gc.Nodintconst(-1) gc.Convlit(&nr, n.Type) a = foptoas(gc.OMUL, nl.Type, 0) goto sbop // symmetric binary case gc.OADD, gc.OMUL: a = foptoas(int(n.Op), nl.Type, 0) goto sbop // asymmetric binary case gc.OSUB, gc.OMOD, gc.ODIV: a = foptoas(int(n.Op), nl.Type, 0) goto abop } sbop: // symmetric binary if nl.Ullman < nr.Ullman || nl.Op == gc.OLITERAL { r := nl nl = nr nr = r } abop: // asymmetric binary if nl.Ullman >= nr.Ullman { var nt gc.Node gc.Tempname(&nt, nl.Type) gc.Cgen(nl, &nt) var n2 gc.Node gc.Mgen(nr, &n2, nil) var n1 gc.Node gc.Regalloc(&n1, nl.Type, res) gmove(&nt, &n1) gins(a, &n2, &n1) gmove(&n1, res) gc.Regfree(&n1) gc.Mfree(&n2) } else { var n2 gc.Node gc.Regalloc(&n2, nr.Type, res) gc.Cgen(nr, &n2) var n1 gc.Node gc.Regalloc(&n1, nl.Type, nil) gc.Cgen(nl, &n1) gins(a, &n2, &n1) gc.Regfree(&n2) gmove(&n1, res) gc.Regfree(&n1) } return }
/* * generate: * res = n; * simplifies and calls gmove. */ func cgen(n *gc.Node, res *gc.Node) { if gc.Debug['g'] != 0 { gc.Dump("\ncgen-n", n) gc.Dump("cgen-res", res) } if n == nil || n.Type == nil { return } if res == nil || res.Type == nil { gc.Fatal("cgen: res nil") } switch n.Op { case gc.OSLICE, gc.OSLICEARR, gc.OSLICESTR, gc.OSLICE3, gc.OSLICE3ARR: if res.Op != gc.ONAME || res.Addable == 0 { var n1 gc.Node gc.Tempname(&n1, n.Type) gc.Cgen_slice(n, &n1) cgen(&n1, res) } else { gc.Cgen_slice(n, res) } return case gc.OEFACE: if res.Op != gc.ONAME || res.Addable == 0 { var n1 gc.Node gc.Tempname(&n1, n.Type) gc.Cgen_eface(n, &n1) cgen(&n1, res) } else { gc.Cgen_eface(n, res) } return } for n.Op == gc.OCONVNOP { n = n.Left } if n.Ullman >= gc.UINF { if n.Op == gc.OINDREG { gc.Fatal("cgen: this is going to misscompile") } if res.Ullman >= gc.UINF { var n1 gc.Node gc.Tempname(&n1, n.Type) cgen(n, &n1) cgen(&n1, res) return } } if gc.Isfat(n.Type) { if n.Type.Width < 0 { gc.Fatal("forgot to compute width for %v", gc.Tconv(n.Type, 0)) } 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 gc.OSPTR, gc.OLEN: if gc.Isslice(n.Left.Type) || gc.Istype(n.Left.Type, gc.TSTRING) { n.Addable = n.Left.Addable } case gc.OCAP: if gc.Isslice(n.Left.Type) { n.Addable = n.Left.Addable } case gc.OITAB: n.Addable = n.Left.Addable } // if both are addressable, move if n.Addable != 0 && res.Addable != 0 { if gc.Is64(n.Type) || gc.Is64(res.Type) || n.Op == gc.OREGISTER || res.Op == gc.OREGISTER || gc.Iscomplex[n.Type.Etype] || gc.Iscomplex[res.Type.Etype] { gmove(n, res) } else { var n1 gc.Node regalloc(&n1, n.Type, nil) gmove(n, &n1) cgen(&n1, res) regfree(&n1) } return } // if both are not addressable, use a temporary. if n.Addable == 0 && res.Addable == 0 { // could use regalloc here sometimes, // but have to check for ullman >= UINF. var n1 gc.Node gc.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 == 0 { var n1 gc.Node igen(res, &n1, nil) cgen(n, &n1) regfree(&n1) return } if gc.Complexop(n, res) { gc.Complexgen(n, res) return } // if n is sudoaddable generate addr and move if !gc.Is64(n.Type) && !gc.Is64(res.Type) && !gc.Iscomplex[n.Type.Etype] && !gc.Iscomplex[res.Type.Etype] { a := optoas(gc.OAS, n.Type) var w int var addr obj.Addr if sudoaddable(a, n, &addr, &w) { if res.Op != gc.OREGISTER { var n2 gc.Node regalloc(&n2, res.Type, nil) p1 := gins(a, nil, &n2) p1.From = addr if gc.Debug['g'] != 0 { fmt.Printf("%v [ignore previous line]\n", p1) } gmove(&n2, res) regfree(&n2) } else { p1 := gins(a, nil, res) p1.From = addr if gc.Debug['g'] != 0 { fmt.Printf("%v [ignore previous line]\n", p1) } } sudoclean() return } } // otherwise, the result is addressable but n is not. // let's do some computation. nl := n.Left nr := n.Right if nl != nil && nl.Ullman >= gc.UINF { if nr != nil && nr.Ullman >= gc.UINF { var n1 gc.Node gc.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 gc.Is64(n.Type) || gc.Is64(res.Type) || n.Left != nil && gc.Is64(n.Left.Type) { switch n.Op { // math goes to cgen64. case gc.OMINUS, gc.OCOM, gc.OADD, gc.OSUB, gc.OMUL, gc.OLROT, gc.OLSH, gc.ORSH, gc.OAND, gc.OOR, gc.OXOR: cgen64(n, res) return } } var a int var f0 gc.Node var n1 gc.Node var n2 gc.Node if nl != nil && gc.Isfloat[n.Type.Etype] && gc.Isfloat[nl.Type.Etype] { // floating-point. regalloc(&f0, nl.Type, res) if nr != nil { goto flt2 } if n.Op == gc.OMINUS { nr = gc.Nodintconst(-1) gc.Convlit(&nr, n.Type) n.Op = gc.OMUL goto flt2 } // unary cgen(nl, &f0) if n.Op != gc.OCONV && n.Op != gc.OPLUS { gins(optoas(int(n.Op), n.Type), &f0, &f0) } gmove(&f0, res) regfree(&f0) return } switch n.Op { default: gc.Dump("cgen", n) gc.Fatal("cgen: unknown op %v", gc.Nconv(n, obj.FmtShort|obj.FmtSign)) case gc.OREAL, gc.OIMAG, gc.OCOMPLEX: gc.Fatal("unexpected complex") // these call bgen to get a bool value case gc.OOROR, gc.OANDAND, gc.OEQ, gc.ONE, gc.OLT, gc.OLE, gc.OGE, gc.OGT, gc.ONOT: p1 := gc.Gbranch(arm.AB, nil, 0) p2 := gc.Pc gmove(gc.Nodbool(true), res) p3 := gc.Gbranch(arm.AB, nil, 0) gc.Patch(p1, gc.Pc) bgen(n, true, 0, p2) gmove(gc.Nodbool(false), res) gc.Patch(p3, gc.Pc) return case gc.OPLUS: cgen(nl, res) return // unary case gc.OCOM: a := optoas(gc.OXOR, nl.Type) regalloc(&n1, nl.Type, nil) cgen(nl, &n1) gc.Nodconst(&n2, nl.Type, -1) gins(a, &n2, &n1) goto norm case gc.OMINUS: regalloc(&n1, nl.Type, nil) cgen(nl, &n1) gc.Nodconst(&n2, nl.Type, 0) gins(optoas(gc.OMINUS, nl.Type), &n2, &n1) goto norm // symmetric binary case gc.OAND, gc.OOR, gc.OXOR, gc.OADD, gc.OMUL: a = optoas(int(n.Op), nl.Type) // symmetric binary if nl.Ullman < nr.Ullman { r := nl nl = nr nr = r } goto abop // asymmetric binary case gc.OSUB: a = optoas(int(n.Op), nl.Type) goto abop case gc.OHMUL: cgen_hmul(nl, nr, res) case gc.OLROT, gc.OLSH, gc.ORSH: cgen_shift(int(n.Op), n.Bounded, nl, nr, res) case gc.OCONV: if gc.Eqtype(n.Type, nl.Type) || gc.Noconv(n.Type, nl.Type) { cgen(nl, res) break } var n1 gc.Node if nl.Addable != 0 && !gc.Is64(nl.Type) { regalloc(&n1, nl.Type, res) gmove(nl, &n1) } else { if n.Type.Width > int64(gc.Widthptr) || gc.Is64(nl.Type) || gc.Isfloat[nl.Type.Etype] { gc.Tempname(&n1, nl.Type) } else { regalloc(&n1, nl.Type, res) } cgen(nl, &n1) } var n2 gc.Node if n.Type.Width > int64(gc.Widthptr) || gc.Is64(n.Type) || gc.Isfloat[n.Type.Etype] { gc.Tempname(&n2, n.Type) } else { regalloc(&n2, n.Type, nil) } gmove(&n1, &n2) gmove(&n2, res) if n1.Op == gc.OREGISTER { regfree(&n1) } if n2.Op == gc.OREGISTER { regfree(&n2) } case gc.ODOT, gc.ODOTPTR, gc.OINDEX, gc.OIND, gc.ONAME: // PHEAP or PPARAMREF var var n1 gc.Node igen(n, &n1, res) gmove(&n1, res) regfree(&n1) // interface table is first word of interface value case gc.OITAB: var n1 gc.Node igen(nl, &n1, res) n1.Type = n.Type gmove(&n1, res) regfree(&n1) // pointer is the first word of string or slice. case gc.OSPTR: if gc.Isconst(nl, gc.CTSTR) { var n1 gc.Node regalloc(&n1, gc.Types[gc.Tptr], res) p1 := gins(arm.AMOVW, nil, &n1) gc.Datastring(nl.Val.U.Sval, &p1.From) gmove(&n1, res) regfree(&n1) break } var n1 gc.Node igen(nl, &n1, res) n1.Type = n.Type gmove(&n1, res) regfree(&n1) case gc.OLEN: if gc.Istype(nl.Type, gc.TMAP) || gc.Istype(nl.Type, gc.TCHAN) { // map has len in the first 32-bit word. // a zero pointer means zero length var n1 gc.Node regalloc(&n1, gc.Types[gc.Tptr], res) cgen(nl, &n1) var n2 gc.Node gc.Nodconst(&n2, gc.Types[gc.Tptr], 0) gcmp(optoas(gc.OCMP, gc.Types[gc.Tptr]), &n1, &n2) p1 := gc.Gbranch(optoas(gc.OEQ, gc.Types[gc.Tptr]), nil, -1) n2 = n1 n2.Op = gc.OINDREG n2.Type = gc.Types[gc.TINT32] gmove(&n2, &n1) gc.Patch(p1, gc.Pc) gmove(&n1, res) regfree(&n1) break } if gc.Istype(nl.Type, gc.TSTRING) || gc.Isslice(nl.Type) { // both slice and string have len one pointer into the struct. var n1 gc.Node igen(nl, &n1, res) n1.Type = gc.Types[gc.TUINT32] n1.Xoffset += int64(gc.Array_nel) gmove(&n1, res) regfree(&n1) break } gc.Fatal("cgen: OLEN: unknown type %v", gc.Tconv(nl.Type, obj.FmtLong)) case gc.OCAP: if gc.Istype(nl.Type, gc.TCHAN) { // chan has cap in the second 32-bit word. // a zero pointer means zero length var n1 gc.Node regalloc(&n1, gc.Types[gc.Tptr], res) cgen(nl, &n1) var n2 gc.Node gc.Nodconst(&n2, gc.Types[gc.Tptr], 0) gcmp(optoas(gc.OCMP, gc.Types[gc.Tptr]), &n1, &n2) p1 := gc.Gbranch(optoas(gc.OEQ, gc.Types[gc.Tptr]), nil, -1) n2 = n1 n2.Op = gc.OINDREG n2.Xoffset = 4 n2.Type = gc.Types[gc.TINT32] gmove(&n2, &n1) gc.Patch(p1, gc.Pc) gmove(&n1, res) regfree(&n1) break } if gc.Isslice(nl.Type) { var n1 gc.Node igen(nl, &n1, res) n1.Type = gc.Types[gc.TUINT32] n1.Xoffset += int64(gc.Array_cap) gmove(&n1, res) regfree(&n1) break } gc.Fatal("cgen: OCAP: unknown type %v", gc.Tconv(nl.Type, obj.FmtLong)) case gc.OADDR: agen(nl, res) // Release res so that it is available for cgen_call. // Pick it up again after the call. case gc.OCALLMETH, gc.OCALLFUNC: rg := -1 if n.Ullman >= gc.UINF { if res != nil && (res.Op == gc.OREGISTER || res.Op == gc.OINDREG) { rg = int(res.Val.U.Reg) reg[rg]-- } } if n.Op == gc.OCALLMETH { gc.Cgen_callmeth(n, 0) } else { cgen_call(n, 0) } if rg >= 0 { reg[rg]++ } cgen_callret(n, res) case gc.OCALLINTER: cgen_callinter(n, res, 0) cgen_callret(n, res) case gc.OMOD, gc.ODIV: a = optoas(int(n.Op), nl.Type) goto abop } return // TODO(kaib): use fewer registers here. abop: // asymmetric binary if nl.Ullman >= nr.Ullman { regalloc(&n1, nl.Type, res) cgen(nl, &n1) switch n.Op { case gc.OADD, gc.OSUB, gc.OAND, gc.OOR, gc.OXOR: if gc.Smallintconst(nr) { n2 = *nr break } fallthrough default: regalloc(&n2, nr.Type, nil) cgen(nr, &n2) } } else { switch n.Op { case gc.OADD, gc.OSUB, gc.OAND, gc.OOR, gc.OXOR: if gc.Smallintconst(nr) { n2 = *nr break } fallthrough default: regalloc(&n2, nr.Type, res) cgen(nr, &n2) } regalloc(&n1, nl.Type, nil) cgen(nl, &n1) } gins(a, &n2, &n1) // Normalize result for types smaller than word. norm: if n.Type.Width < int64(gc.Widthptr) { switch n.Op { case gc.OADD, gc.OSUB, gc.OMUL, gc.OCOM, gc.OMINUS: gins(optoas(gc.OAS, n.Type), &n1, &n1) } } gmove(&n1, res) regfree(&n1) if n2.Op != gc.OLITERAL { regfree(&n2) } return flt2: // binary var f1 gc.Node if nl.Ullman >= nr.Ullman { cgen(nl, &f0) regalloc(&f1, n.Type, nil) gmove(&f0, &f1) cgen(nr, &f0) gins(optoas(int(n.Op), n.Type), &f0, &f1) } else { cgen(nr, &f0) regalloc(&f1, n.Type, nil) cgen(nl, &f1) gins(optoas(int(n.Op), n.Type), &f0, &f1) } gmove(&f1, res) regfree(&f0) regfree(&f1) return }