// 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. package gc import ( "cmd/internal/obj" "fmt" "strings" ) func dflag() bool { if Debug['d'] == 0 { return false } if Debug['y'] != 0 { return true } if incannedimport != 0 { return false } return true } // declaration stack & operations func dcopy(a *Sym, b *Sym) { a.Pkg = b.Pkg a.Name = b.Name a.Def = b.Def a.Block = b.Block a.Lastlineno = b.Lastlineno } func push() *Sym { d := new(Sym) d.Lastlineno = lineno d.Link = dclstack dclstack = d return d } func pushdcl(s *Sym) *Sym { d := push() dcopy(d, s) if dflag() { fmt.Printf("\t%v push %v %p\n", linestr(lineno), s, s.Def) } return d } func popdcl() { d := dclstack for ; d != nil && d.Name != ""; d = d.Link { s := Pkglookup(d.Name, d.Pkg) lno := s.Lastlineno dcopy(s, d) d.Lastlineno = lno if dflag() { fmt.Printf("\t%v pop %v %p\n", linestr(lineno), s, s.Def) } } if d == nil { Fatalf("popdcl: no mark") } dclstack = d.Link // pop mark block = d.Block } func markdcl() { d := push() d.Name = "" // used as a mark in fifo d.Block = block blockgen++ block = blockgen } func dumpdcl(st string) { i := 0 for d := dclstack; d != nil; d = d.Link { i++ fmt.Printf(" %.2d %p", i, d) if d.Name == "" { fmt.Printf("\n") continue } fmt.Printf(" '%s'", d.Name) fmt.Printf(" %v\n", Pkglookup(d.Name, d.Pkg)) } } func testdclstack() { for d := dclstack; d != nil; d = d.Link { if d.Name == "" { if nerrors != 0 { errorexit() } Yyerror("mark left on the stack") } } } func redeclare(s *Sym, where string) { if s.Lastlineno == 0 { var tmp string if s.Origpkg != nil { tmp = s.Origpkg.Path } else { tmp = s.Pkg.Path } pkgstr := tmp Yyerror("%v redeclared %s\n"+"\tprevious declaration during import %q", s, where, pkgstr) } else { line1 := lineno line2 := s.Lastlineno // When an import and a declaration collide in separate files, // present the import as the "redeclared", because the declaration // is visible where the import is, but not vice versa. // See issue 4510. if s.Def == nil { line2 = line1 line1 = s.Lastlineno } yyerrorl(line1, "%v redeclared %s\n"+"\tprevious declaration at %v", s, where, linestr(line2)) } } var vargen int // declare individual names - var, typ, const var declare_typegen int func declare(n *Node, ctxt Class) { if ctxt == PDISCARD { return } if isblank(n) { return } if n.Name == nil { // named OLITERAL needs Name; most OLITERALs don't. n.Name = new(Name) } n.Lineno = lineno s := n.Sym // kludgy: typecheckok means we're past parsing. Eg genwrapper may declare out of package names later. if importpkg == nil && !typecheckok && s.Pkg != localpkg { Yyerror("cannot declare name %v", s) } if ctxt == PEXTERN && s.Name == "init" { Yyerror("cannot declare init - must be func") } gen := 0 if ctxt == PEXTERN { externdcl = append(externdcl, n) if dflag() { fmt.Printf("\t%v global decl %v %p\n", linestr(lineno), s, n) } } else { if Curfn == nil && ctxt == PAUTO { Fatalf("automatic outside function") } if Curfn != nil { Curfn.Func.Dcl = append(Curfn.Func.Dcl, n) } if n.Op == OTYPE { declare_typegen++ gen = declare_typegen } else if n.Op == ONAME && ctxt == PAUTO && !strings.Contains(s.Name, "·") { vargen++ gen = vargen } pushdcl(s) n.Name.Curfn = Curfn } if ctxt == PAUTO { n.Xoffset = 0 } if s.Block == block { // functype will print errors about duplicate function arguments. // Don't repeat the error here. if ctxt != PPARAM && ctxt != PPARAMOUT { redeclare(s, "in this block") } } s.Block = block s.Lastlineno = lineno s.Def = n n.Name.Vargen = int32(gen) n.Name.Funcdepth = Funcdepth n.Class = ctxt autoexport(n, ctxt) } func addvar(n *Node, t *Type, ctxt Class) { if n == nil || n.Sym == nil || (n.Op != ONAME && n.Op != ONONAME) || t == nil { Fatalf("addvar: n=%v t=%v nil", n, t) } n.Op = ONAME declare(n, ctxt) n.Type = t } // declare variables from grammar // new_name_list (type | [type] = expr_list) func variter(vl *NodeList, t *Node, el *NodeList) *NodeList { var init *NodeList doexpr := el != nil if count(el) == 1 && count(vl) > 1 { e := el.N as2 := Nod(OAS2, nil, nil) setNodeSeq(&as2.List, vl) setNodeSeqNode(&as2.Rlist, e) var v *Node for ; vl != nil; vl = vl.Next { v = vl.N v.Op = ONAME declare(v, dclcontext) v.Name.Param.Ntype = t v.Name.Defn = as2 if Funcdepth > 0 { init = list(init, Nod(ODCL, v, nil)) } } return list(init, as2) } var v *Node var e *Node for ; vl != nil; vl = vl.Next { if doexpr { if el == nil { Yyerror("missing expression in var declaration") break } e = el.N el = el.Next } else { e = nil } v = vl.N v.Op = ONAME declare(v, dclcontext) v.Name.Param.Ntype = t if e != nil || Funcdepth > 0 || isblank(v) { if Funcdepth > 0 { init = list(init, Nod(ODCL, v, nil)) } e = Nod(OAS, v, e) init = list(init, e) if e.Right != nil { v.Name.Defn = e } } } if el != nil { Yyerror("extra expression in var declaration") } return init } // declare constants from grammar // new_name_list [[type] = expr_list] func constiter(vl *NodeList, t *Node, cl *NodeList) *NodeList { lno := int32(0) // default is to leave line number alone in listtreecopy if cl == nil { if t != nil { Yyerror("const declaration cannot have type without expression") } cl = lastconst t = lasttype lno = vl.N.Lineno } else { lastconst = cl lasttype = t } clcopy := listtreecopy(cl, lno) var v *Node var c *Node var vv *NodeList for ; vl != nil; vl = vl.Next { if len(clcopy) == 0 { Yyerror("missing value in const declaration") break } c = clcopy[0] clcopy = clcopy[1:] v = vl.N v.Op = OLITERAL declare(v, dclcontext) v.Name.Param.Ntype = t v.Name.Defn = c vv = list(vv, Nod(ODCLCONST, v, nil)) } if len(clcopy) != 0 { Yyerror("extra expression in const declaration") } iota_ += 1 return vv } // this generates a new name node, // typically for labels or other one-off names. func newname(s *Sym) *Node { if s == nil { Fatalf("newname nil") } n := Nod(ONAME, nil, nil) n.Sym = s n.Type = nil n.Addable = true n.Ullman = 1 n.Xoffset = 0 return n } // newfuncname generates a new name node for a function or method. // TODO(rsc): Use an ODCLFUNC node instead. See comment in CL 7360. func newfuncname(s *Sym) *Node { n := newname(s) n.Func = new(Func) n.Func.FCurfn = Curfn return n } // this generates a new name node for a name // being declared. func dclname(s *Sym) *Node { n := newname(s) n.Op = ONONAME // caller will correct it return n } func typenod(t *Type) *Node { // if we copied another type with *t = *u // then t->nod might be out of date, so // check t->nod->type too if t.Nod == nil || t.Nod.Type != t { t.Nod = Nod(OTYPE, nil, nil) t.Nod.Type = t t.Nod.Sym = t.Sym } return t.Nod } // this will return an old name // that has already been pushed on the // declaration list. a diagnostic is // generated if no name has been defined. func oldname(s *Sym) *Node { n := s.Def if n == nil { // maybe a top-level name will come along // to give this a definition later. // walkdef will check s->def again once // all the input source has been processed. n = newname(s) n.Op = ONONAME n.Name.Iota = iota_ // save current iota value in const declarations return n } if Curfn != nil && n.Op == ONAME && n.Name.Funcdepth > 0 && n.Name.Funcdepth != Funcdepth { // inner func is referring to var in outer func. // // TODO(rsc): If there is an outer variable x and we // are parsing x := 5 inside the closure, until we get to // the := it looks like a reference to the outer x so we'll // make x a closure variable unnecessarily. if n.Name.Param.Closure == nil || n.Name.Param.Closure.Name.Funcdepth != Funcdepth { // create new closure var. c := Nod(ONAME, nil, nil) c.Sym = s c.Class = PPARAMREF c.Isddd = n.Isddd c.Name.Defn = n c.Addable = false c.Ullman = 2 c.Name.Funcdepth = Funcdepth c.Name.Param.Outer = n.Name.Param.Closure n.Name.Param.Closure = c c.Name.Param.Closure = n c.Xoffset = 0 Curfn.Func.Cvars.Append(c) } // return ref to closure var, not original return n.Name.Param.Closure } return n } // := declarations func colasname(n *Node) bool { switch n.Op { case ONAME, ONONAME, OPACK, OTYPE, OLITERAL: return n.Sym != nil } return false } func colasdefn(left nodesOrNodeList, defn *Node) { for it := nodeSeqIterate(left); !it.Done(); it.Next() { if it.N().Sym != nil { it.N().Sym.Flags |= SymUniq } } nnew := 0 nerr := 0 var n *Node for it := nodeSeqIterate(left); !it.Done(); it.Next() { n = it.N() if isblank(n) { continue } if !colasname(n) { yyerrorl(defn.Lineno, "non-name %v on left side of :=", n) nerr++ continue } if n.Sym.Flags&SymUniq == 0 { yyerrorl(defn.Lineno, "%v repeated on left side of :=", n.Sym) n.Diag++ nerr++ continue } n.Sym.Flags &^= SymUniq if n.Sym.Block == block { continue } nnew++ n = newname(n.Sym) declare(n, dclcontext) n.Name.Defn = defn appendNodeSeqNode(&defn.Ninit, Nod(ODCL, n, nil)) *it.P() = n } if nnew == 0 && nerr == 0 { yyerrorl(defn.Lineno, "no new variables on left side of :=") } } func colas(left *NodeList, right *NodeList, lno int32) *Node { as := Nod(OAS2, nil, nil) setNodeSeq(&as.List, left) setNodeSeq(&as.Rlist, right) as.Colas = true as.Lineno = lno colasdefn(as.List, as) // make the tree prettier; not necessary if nodeSeqLen(as.List) == 1 && nodeSeqLen(as.Rlist) == 1 { as.Left = nodeSeqFirst(as.List) as.Right = nodeSeqFirst(as.Rlist) setNodeSeq(&as.List, nil) setNodeSeq(&as.Rlist, nil) as.Op = OAS } return as } // declare the arguments in an // interface field declaration. func ifacedcl(n *Node) { if n.Op != ODCLFIELD || n.Right == nil { Fatalf("ifacedcl") } if isblank(n.Left) { Yyerror("methods must have a unique non-blank name") } n.Func = new(Func) n.Func.FCurfn = Curfn dclcontext = PPARAM markdcl() Funcdepth++ n.Func.Outer = Curfn Curfn = n funcargs(n.Right) // funcbody is normally called after the parser has // seen the body of a function but since an interface // field declaration does not have a body, we must // call it now to pop the current declaration context. dclcontext = PAUTO funcbody(n) } // declare the function proper // and declare the arguments. // called in extern-declaration context // returns in auto-declaration context. func funchdr(n *Node) { // change the declaration context from extern to auto if Funcdepth == 0 && dclcontext != PEXTERN { Fatalf("funchdr: dclcontext") } if importpkg == nil && n.Func.Nname != nil { makefuncsym(n.Func.Nname.Sym) } dclcontext = PAUTO markdcl() Funcdepth++ n.Func.Outer = Curfn Curfn = n if n.Func.Nname != nil { funcargs(n.Func.Nname.Name.Param.Ntype) } else if n.Func.Ntype != nil { funcargs(n.Func.Ntype) } else { funcargs2(n.Type) } } func funcargs(nt *Node) { if nt.Op != OTFUNC { Fatalf("funcargs %v", Oconv(nt.Op, 0)) } // re-start the variable generation number // we want to use small numbers for the return variables, // so let them have the chunk starting at 1. vargen = nodeSeqLen(nt.Rlist) // declare the receiver and in arguments. // no n->defn because type checking of func header // will not fill in the types until later if nt.Left != nil { n := nt.Left if n.Op != ODCLFIELD { Fatalf("funcargs receiver %v", Oconv(n.Op, 0)) } if n.Left != nil { n.Left.Op = ONAME n.Left.Name.Param.Ntype = n.Right declare(n.Left, PPARAM) if dclcontext == PAUTO { vargen++ n.Left.Name.Vargen = int32(vargen) } } } var n *Node for it := nodeSeqIterate(nt.List); !it.Done(); it.Next() { n = it.N() if n.Op != ODCLFIELD { Fatalf("funcargs in %v", Oconv(n.Op, 0)) } if n.Left != nil { n.Left.Op = ONAME n.Left.Name.Param.Ntype = n.Right declare(n.Left, PPARAM) if dclcontext == PAUTO { vargen++ n.Left.Name.Vargen = int32(vargen) } } } // declare the out arguments. gen := nodeSeqLen(nt.List) var i int = 0 var nn *Node for it := nodeSeqIterate(nt.Rlist); !it.Done(); it.Next() { n = it.N() if n.Op != ODCLFIELD { Fatalf("funcargs out %v", Oconv(n.Op, 0)) } if n.Left == nil { // Name so that escape analysis can track it. ~r stands for 'result'. n.Left = newname(Lookupf("~r%d", gen)) gen++ } // TODO: n->left->missing = 1; n.Left.Op = ONAME if isblank(n.Left) { // Give it a name so we can assign to it during return. ~b stands for 'blank'. // The name must be different from ~r above because if you have // func f() (_ int) // func g() int // f is allowed to use a plain 'return' with no arguments, while g is not. // So the two cases must be distinguished. // We do not record a pointer to the original node (n->orig). // Having multiple names causes too much confusion in later passes. nn = Nod(OXXX, nil, nil) *nn = *n.Left nn.Orig = nn nn.Sym = Lookupf("~b%d", gen) gen++ n.Left = nn } n.Left.Name.Param.Ntype = n.Right declare(n.Left, PPARAMOUT) if dclcontext == PAUTO { i++ n.Left.Name.Vargen = int32(i) } } } // Same as funcargs, except run over an already constructed TFUNC. // This happens during import, where the hidden_fndcl rule has // used functype directly to parse the function's type. func funcargs2(t *Type) { if t.Etype != TFUNC { Fatalf("funcargs2 %v", t) } if t.Thistuple != 0 { var n *Node for ft := getthisx(t).Type; ft != nil; ft = ft.Down { if ft.Nname == nil || ft.Nname.Sym == nil { continue } n = ft.Nname // no need for newname(ft->nname->sym) n.Type = ft.Type declare(n, PPARAM) } } if t.Intuple != 0 { var n *Node for ft := getinargx(t).Type; ft != nil; ft = ft.Down { if ft.Nname == nil || ft.Nname.Sym == nil { continue } n = ft.Nname n.Type = ft.Type declare(n, PPARAM) } } if t.Outtuple != 0 { var n *Node for ft := getoutargx(t).Type; ft != nil; ft = ft.Down { if ft.Nname == nil || ft.Nname.Sym == nil { continue } n = ft.Nname n.Type = ft.Type declare(n, PPARAMOUT) } } } // finish the body. // called in auto-declaration context. // returns in extern-declaration context. func funcbody(n *Node) { // change the declaration context from auto to extern if dclcontext != PAUTO { Fatalf("funcbody: dclcontext") } popdcl() Funcdepth-- Curfn = n.Func.Outer n.Func.Outer = nil if Funcdepth == 0 { dclcontext = PEXTERN } } // new type being defined with name s. func typedcl0(s *Sym) *Node { n := newname(s) n.Op = OTYPE declare(n, dclcontext) return n } // node n, which was returned by typedcl0 // is being declared to have uncompiled type t. // return the ODCLTYPE node to use. func typedcl1(n *Node, t *Node, local bool) *Node { n.Name.Param.Ntype = t n.Local = local return Nod(ODCLTYPE, n, nil) } // structs, functions, and methods. // they don't belong here, but where do they belong? func checkembeddedtype(t *Type) { if t == nil { return } if t.Sym == nil && Isptr[t.Etype] { t = t.Type if t.Etype == TINTER { Yyerror("embedded type cannot be a pointer to interface") } } if Isptr[t.Etype] { Yyerror("embedded type cannot be a pointer") } else if t.Etype == TFORW && t.Embedlineno == 0 { t.Embedlineno = lineno } } func structfield(n *Node) *Type { lno := lineno lineno = n.Lineno if n.Op != ODCLFIELD { Fatalf("structfield: oops %v\n", n) } f := typ(TFIELD) f.Isddd = n.Isddd if n.Right != nil { typecheck(&n.Right, Etype) n.Type = n.Right.Type if n.Left != nil { n.Left.Type = n.Type } if n.Embedded != 0 { checkembeddedtype(n.Type) } } n.Right = nil f.Type = n.Type if f.Type == nil { f.Broke = true } switch n.Val().Ctype() { case CTSTR: f.Note = new(string) *f.Note = n.Val().U.(string) default: Yyerror("field annotation must be string") fallthrough case CTxxx: f.Note = nil } if n.Left != nil && n.Left.Op == ONAME { f.Nname = n.Left f.Embedded = n.Embedded f.Sym = f.Nname.Sym } lineno = lno return f } var uniqgen uint32 func checkdupfields(t *Type, what string) { lno := lineno for ; t != nil; t = t.Down { if t.Sym != nil && t.Nname != nil && !isblank(t.Nname) { if t.Sym.Uniqgen == uniqgen { lineno = t.Nname.Lineno Yyerror("duplicate %s %s", what, t.Sym.Name) } else { t.Sym.Uniqgen = uniqgen } } } lineno = lno } // convert a parsed id/type list into // a type for struct/interface/arglist func tostruct(l nodesOrNodeList) *Type { t := typ(TSTRUCT) tostruct0(t, l) return t } func tostruct0(t *Type, l nodesOrNodeList) { if t == nil || t.Etype != TSTRUCT { Fatalf("struct expected") } for tp, it := &t.Type, nodeSeqIterate(l); !it.Done(); it.Next() { f := structfield(it.N()) *tp = f tp = &f.Down } for f := t.Type; f != nil && !t.Broke; f = f.Down { if f.Broke { t.Broke = true } } uniqgen++ checkdupfields(t.Type, "field") if !t.Broke { checkwidth(t) } } func tofunargs(l nodesOrNodeList) *Type { var f *Type t := typ(TSTRUCT) t.Funarg = true for tp, it := &t.Type, nodeSeqIterate(l); !it.Done(); it.Next() { f = structfield(it.N()) f.Funarg = true // esc.go needs to find f given a PPARAM to add the tag. if it.N().Left != nil && it.N().Left.Class == PPARAM { it.N().Left.Name.Param.Field = f } *tp = f tp = &f.Down } for f := t.Type; f != nil && !t.Broke; f = f.Down { if f.Broke { t.Broke = true } } return t } func interfacefield(n *Node) *Type { lno := lineno lineno = n.Lineno if n.Op != ODCLFIELD { Fatalf("interfacefield: oops %v\n", n) } if n.Val().Ctype() != CTxxx { Yyerror("interface method cannot have annotation") } f := typ(TFIELD) f.Isddd = n.Isddd if n.Right != nil { if n.Left != nil { // queue resolution of method type for later. // right now all we need is the name list. // avoids cycles for recursive interface types. n.Type = typ(TINTERMETH) n.Type.Nname = n.Right n.Left.Type = n.Type queuemethod(n) if n.Left.Op == ONAME { f.Nname = n.Left f.Embedded = n.Embedded f.Sym = f.Nname.Sym } } else { typecheck(&n.Right, Etype) n.Type = n.Right.Type if n.Embedded != 0 { checkembeddedtype(n.Type) } if n.Type != nil { switch n.Type.Etype { case TINTER: break case TFORW: Yyerror("interface type loop involving %v", n.Type) f.Broke = true default: Yyerror("interface contains embedded non-interface %v", n.Type) f.Broke = true } } } } n.Right = nil f.Type = n.Type if f.Type == nil { f.Broke = true } lineno = lno return f } func tointerface(l nodesOrNodeList) *Type { t := typ(TINTER) tointerface0(t, l) return t } func tointerface0(t *Type, l nodesOrNodeList) *Type { if t == nil || t.Etype != TINTER { Fatalf("interface expected") } tp := &t.Type for it := nodeSeqIterate(l); !it.Done(); it.Next() { f := interfacefield(it.N()) if it.N().Left == nil && f.Type.Etype == TINTER { // embedded interface, inline methods for t1 := f.Type.Type; t1 != nil; t1 = t1.Down { f = typ(TFIELD) f.Type = t1.Type f.Broke = t1.Broke f.Sym = t1.Sym if f.Sym != nil { f.Nname = newname(f.Sym) } *tp = f tp = &f.Down } } else { *tp = f tp = &f.Down } } for f := t.Type; f != nil && !t.Broke; f = f.Down { if f.Broke { t.Broke = true } } uniqgen++ checkdupfields(t.Type, "method") t = sortinter(t) checkwidth(t) return t } func embedded(s *Sym, pkg *Pkg) *Node { const ( CenterDot = 0xB7 ) // Names sometimes have disambiguation junk // appended after a center dot. Discard it when // making the name for the embedded struct field. name := s.Name if i := strings.Index(s.Name, string(CenterDot)); i >= 0 { name = s.Name[:i] } var n *Node if exportname(name) { n = newname(Lookup(name)) } else if s.Pkg == builtinpkg { // The name of embedded builtins belongs to pkg. n = newname(Pkglookup(name, pkg)) } else { n = newname(Pkglookup(name, s.Pkg)) } n = Nod(ODCLFIELD, n, oldname(s)) n.Embedded = 1 return n } // check that the list of declarations is either all anonymous or all named func findtype(l *NodeList) *Node { for ; l != nil; l = l.Next { if l.N.Op == OKEY { return l.N.Right } } return nil } func checkarglist(all *NodeList, input int) *NodeList { named := 0 for l := all; l != nil; l = l.Next { if l.N.Op == OKEY { named = 1 break } } if named != 0 { var n *Node var l *NodeList for l = all; l != nil; l = l.Next { n = l.N if n.Op != OKEY && n.Sym == nil { Yyerror("mixed named and unnamed function parameters") break } } if l == nil && n != nil && n.Op != OKEY { Yyerror("final function parameter must have type") } } var nextt *Node var t *Node var n *Node for l := all; l != nil; l = l.Next { // can cache result from findtype to avoid // quadratic behavior here, but unlikely to matter. n = l.N if named != 0 { if n.Op == OKEY { t = n.Right n = n.Left nextt = nil } else { if nextt == nil { nextt = findtype(l) } t = nextt } } else { t = n n = nil } // during import l->n->op is OKEY, but l->n->left->sym == S // means it was a '?', not that it was // a lone type This doesn't matter for the exported // declarations, which are parsed by rules that don't // use checkargs, but can happen for func literals in // the inline bodies. // TODO(rsc) this can go when typefmt case TFIELD in exportmode fmt.go prints _ instead of ? if importpkg != nil && n.Sym == nil { n = nil } if n != nil && n.Sym == nil { t = n n = nil } if n != nil { n = newname(n.Sym) } n = Nod(ODCLFIELD, n, t) if n.Right != nil && n.Right.Op == ODDD { if input == 0 { Yyerror("cannot use ... in output argument list") } else if l.Next != nil { Yyerror("can only use ... as final argument in list") } n.Right.Op = OTARRAY n.Right.Right = n.Right.Left n.Right.Left = nil n.Isddd = true if n.Left != nil { n.Left.Isddd = true } } l.N = n } return all } func fakethis() *Node { n := Nod(ODCLFIELD, nil, typenod(Ptrto(typ(TSTRUCT)))) return n } // Is this field a method on an interface? // Those methods have an anonymous *struct{} as the receiver. // (See fakethis above.) func isifacemethod(f *Type) bool { rcvr := getthisx(f).Type if rcvr.Sym != nil { return false } t := rcvr.Type if !Isptr[t.Etype] { return false } t = t.Type if t.Sym != nil || t.Etype != TSTRUCT || t.Type != nil { return false } return true } // turn a parsed function declaration into a type func functype(this *Node, in nodesOrNodeList, out nodesOrNodeList) *Type { t := typ(TFUNC) functype0(t, this, in, out) return t } func functype0(t *Type, this *Node, in nodesOrNodeList, out nodesOrNodeList) { if t == nil || t.Etype != TFUNC { Fatalf("function type expected") } var rcvr *NodeList if this != nil { rcvr = list1(this) } t.Type = tofunargs(rcvr) t.Type.Down = tofunargs(out) t.Type.Down.Down = tofunargs(in) uniqgen++ checkdupfields(t.Type.Type, "argument") checkdupfields(t.Type.Down.Type, "argument") checkdupfields(t.Type.Down.Down.Type, "argument") if t.Type.Broke || t.Type.Down.Broke || t.Type.Down.Down.Broke { t.Broke = true } if this != nil { t.Thistuple = 1 } t.Outtuple = nodeSeqLen(out) t.Intuple = nodeSeqLen(in) t.Outnamed = false if t.Outtuple > 0 && nodeSeqFirst(out).Left != nil && nodeSeqFirst(out).Left.Orig != nil { s := nodeSeqFirst(out).Left.Orig.Sym if s != nil && (s.Name[0] != '~' || s.Name[1] != 'r') { // ~r%d is the name invented for an unnamed result t.Outnamed = true } } } var methodsym_toppkg *Pkg func methodsym(nsym *Sym, t0 *Type, iface int) *Sym { var s *Sym var p string var suffix string var spkg *Pkg t := t0 if t == nil { goto bad } s = t.Sym if s == nil && Isptr[t.Etype] { t = t.Type if t == nil { goto bad } s = t.Sym } spkg = nil if s != nil { spkg = s.Pkg } // if t0 == *t and t0 has a sym, // we want to see *t, not t0, in the method name. if t != t0 && t0.Sym != nil { t0 = Ptrto(t) } suffix = "" if iface != 0 { dowidth(t0) if t0.Width < Types[Tptr].Width { suffix = "·i" } } if (spkg == nil || nsym.Pkg != spkg) && !exportname(nsym.Name) { if t0.Sym == nil && Isptr[t0.Etype] { p = fmt.Sprintf("(%v).%s.%s%s", Tconv(t0, obj.FmtLeft|obj.FmtShort), nsym.Pkg.Prefix, nsym.Name, suffix) } else { p = fmt.Sprintf("%v.%s.%s%s", Tconv(t0, obj.FmtLeft|obj.FmtShort), nsym.Pkg.Prefix, nsym.Name, suffix) } } else { if t0.Sym == nil && Isptr[t0.Etype] { p = fmt.Sprintf("(%v).%s%s", Tconv(t0, obj.FmtLeft|obj.FmtShort), nsym.Name, suffix) } else { p = fmt.Sprintf("%v.%s%s", Tconv(t0, obj.FmtLeft|obj.FmtShort), nsym.Name, suffix) } } if spkg == nil { if methodsym_toppkg == nil { methodsym_toppkg = mkpkg("go") } spkg = methodsym_toppkg } s = Pkglookup(p, spkg) return s bad: Yyerror("illegal receiver type: %v", t0) return nil } func methodname(n *Node, t *Type) *Node { s := methodsym(n.Sym, t, 0) if s == nil { return n } return newname(s) } func methodname1(n *Node, t *Node) *Node { star := "" if t.Op == OIND { star = "*" t = t.Left } if t.Sym == nil || isblank(n) { return newfuncname(n.Sym) } var p string if star != "" { p = fmt.Sprintf("(%s%v).%v", star, t.Sym, n.Sym) } else { p = fmt.Sprintf("%v.%v", t.Sym, n.Sym) } if exportname(t.Sym.Name) { n = newfuncname(Lookup(p)) } else { n = newfuncname(Pkglookup(p, t.Sym.Pkg)) } return n } // add a method, declared as a function, // n is fieldname, pa is base type, t is function type func addmethod(sf *Sym, t *Type, local bool, nointerface bool) { // get field sym if sf == nil { Fatalf("no method symbol") } // get parent type sym pa := getthisx(t).Type // ptr to this structure if pa == nil { Yyerror("missing receiver") return } pa = pa.Type f := methtype(pa, 1) if f == nil { t = pa if t == nil { // rely on typecheck having complained before return } if t != nil { if Isptr[t.Etype] { if t.Sym != nil { Yyerror("invalid receiver type %v (%v is a pointer type)", pa, t) return } t = t.Type } if t.Broke { // rely on typecheck having complained before return } if t.Sym == nil { Yyerror("invalid receiver type %v (%v is an unnamed type)", pa, t) return } if Isptr[t.Etype] { Yyerror("invalid receiver type %v (%v is a pointer type)", pa, t) return } if t.Etype == TINTER { Yyerror("invalid receiver type %v (%v is an interface type)", pa, t) return } } // Should have picked off all the reasons above, // but just in case, fall back to generic error. Yyerror("invalid receiver type %v (%v / %v)", pa, Tconv(pa, obj.FmtLong), Tconv(t, obj.FmtLong)) return } pa = f if local && !pa.Local { Yyerror("cannot define new methods on non-local type %v", pa) return } if isblanksym(sf) { return } if pa.Etype == TSTRUCT { for f := pa.Type; f != nil; f = f.Down { if f.Sym == sf { Yyerror("type %v has both field and method named %v", pa, sf) return } } } n := Nod(ODCLFIELD, newname(sf), nil) n.Type = t var d *Type // last found for f := pa.Method; f != nil; f = f.Down { d = f if f.Etype != TFIELD { Fatalf("addmethod: not TFIELD: %v", Tconv(f, obj.FmtLong)) } if sf.Name != f.Sym.Name { continue } if !Eqtype(t, f.Type) { Yyerror("method redeclared: %v.%v\n\t%v\n\t%v", pa, sf, f.Type, t) } return } f = structfield(n) f.Nointerface = nointerface // during import unexported method names should be in the type's package if importpkg != nil && f.Sym != nil && !exportname(f.Sym.Name) && f.Sym.Pkg != structpkg { Fatalf("imported method name %v in wrong package %s\n", Sconv(f.Sym, obj.FmtSign), structpkg.Name) } if d == nil { pa.Method = f } else { d.Down = f } return } func funccompile(n *Node) { Stksize = BADWIDTH Maxarg = 0 if n.Type == nil { if nerrors == 0 { Fatalf("funccompile missing type") } return } // assign parameter offsets checkwidth(n.Type) if Curfn != nil { Fatalf("funccompile %v inside %v", n.Func.Nname.Sym, Curfn.Func.Nname.Sym) } Stksize = 0 dclcontext = PAUTO Funcdepth = n.Func.Depth + 1 compile(n) Curfn = nil Pc = nil continpc = nil breakpc = nil Funcdepth = 0 dclcontext = PEXTERN flushdata() obj.Flushplist(Ctxt) // convert from Prog list to machine code } func funcsym(s *Sym) *Sym { if s.Fsym != nil { return s.Fsym } s1 := Pkglookup(s.Name+"·f", s.Pkg) s.Fsym = s1 return s1 } func makefuncsym(s *Sym) { if isblanksym(s) { return } if compiling_runtime != 0 && s.Name == "getg" { // runtime.getg() is not a real function and so does // not get a funcsym. return } s1 := funcsym(s) s1.Def = newfuncname(s1) s1.Def.Func.Shortname = newname(s) funcsyms = append(funcsyms, s1.Def) } type nowritebarrierrecChecker struct { curfn *Node stable bool // best maps from the ODCLFUNC of each visited function that // recursively invokes a write barrier to the called function // on the shortest path to a write barrier. best map[*Node]nowritebarrierrecCall } type nowritebarrierrecCall struct { target *Node depth int lineno int32 } func checknowritebarrierrec() { c := nowritebarrierrecChecker{ best: make(map[*Node]nowritebarrierrecCall), } visitBottomUp(xtop, func(list []*Node, recursive bool) { // Functions with write barriers have depth 0. for _, n := range list { if n.Func.WBLineno != 0 { c.best[n] = nowritebarrierrecCall{target: nil, depth: 0, lineno: n.Func.WBLineno} } } // Propagate write barrier depth up from callees. In // the recursive case, we have to update this at most // len(list) times and can stop when we an iteration // that doesn't change anything. for _ = range list { c.stable = false for _, n := range list { if n.Func.WBLineno == 0 { c.curfn = n c.visitcodelist(n.Nbody) } } if c.stable { break } } // Check nowritebarrierrec functions. for _, n := range list { if n.Func.Pragma&Nowritebarrierrec == 0 { continue } call, hasWB := c.best[n] if !hasWB { continue } // Build the error message in reverse. err := "" for call.target != nil { err = fmt.Sprintf("\n\t%v: called by %v%s", linestr(call.lineno), n.Func.Nname, err) n = call.target call = c.best[n] } err = fmt.Sprintf("write barrier prohibited by caller; %v%s", n.Func.Nname, err) yyerrorl(n.Func.WBLineno, err) } }) } func (c *nowritebarrierrecChecker) visitcodelist(l nodesOrNodeList) { for it := nodeSeqIterate(l); !it.Done(); it.Next() { c.visitcode(it.N()) } } func (c *nowritebarrierrecChecker) visitcode(n *Node) { if n == nil { return } if n.Op == OCALLFUNC || n.Op == OCALLMETH { c.visitcall(n) } c.visitcodelist(n.Ninit) c.visitcode(n.Left) c.visitcode(n.Right) c.visitcodelist(n.List) c.visitcodelist(n.Nbody) c.visitcodelist(n.Rlist) } func (c *nowritebarrierrecChecker) visitcall(n *Node) { fn := n.Left if n.Op == OCALLMETH { fn = n.Left.Right.Sym.Def } if fn == nil || fn.Op != ONAME || fn.Class != PFUNC || fn.Name.Defn == nil { return } if (compiling_runtime != 0 || fn.Sym.Pkg == Runtimepkg) && fn.Sym.Name == "allocm" { return } defn := fn.Name.Defn fnbest, ok := c.best[defn] if !ok { return } best, ok := c.best[c.curfn] if ok && fnbest.depth+1 >= best.depth { return } c.best[c.curfn] = nowritebarrierrecCall{target: defn, depth: fnbest.depth + 1, lineno: n.Lineno} c.stable = false }