// Copyright 2013 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. // This file implements Selections. package types import ( "bytes" "fmt" ) // SelectionKind describes the kind of a selector expression x.f // (excluding qualified identifiers). type SelectionKind int const ( FieldVal SelectionKind = iota // x.f is a struct field selector MethodVal // x.f is a method selector MethodExpr // x.f is a method expression ) // A Selection describes a selector expression x.f. // For the declarations: // // type T struct{ x int; E } // type E struct{} // func (e E) m() {} // var p *T // // the following relations exist: // // Selector Kind Recv Obj Type Index Indirect // // p.x FieldVal T x int {0} true // p.m MethodVal *T m func() {1, 0} true // T.m MethodExpr T m func(T) {1, 0} false // type Selection struct { kind SelectionKind recv Type // type of x obj Object // object denoted by x.f index []int // path from x to x.f indirect bool // set if there was any pointer indirection on the path } // Kind returns the selection kind. func (s *Selection) Kind() SelectionKind { return s.kind } // Recv returns the type of x in x.f. func (s *Selection) Recv() Type { return s.recv } // Obj returns the object denoted by x.f; a *Var for // a field selection, and a *Func in all other cases. func (s *Selection) Obj() Object { return s.obj } // Type returns the type of x.f, which may be different from the type of f. // See Selection for more information. func (s *Selection) Type() Type { switch s.kind { case MethodVal: // The type of x.f is a method with its receiver type set // to the type of x. sig := *s.obj.(*Func).typ.(*Signature) recv := *sig.recv recv.typ = s.recv sig.recv = &recv return &sig case MethodExpr: // The type of x.f is a function (without receiver) // and an additional first argument with the same type as x. // TODO(gri) Similar code is already in call.go - factor! // TODO(gri) Compute this eagerly to avoid allocations. sig := *s.obj.(*Func).typ.(*Signature) arg0 := *sig.recv sig.recv = nil arg0.typ = s.recv var params []*Var if sig.params != nil { params = sig.params.vars } sig.params = NewTuple(append([]*Var{&arg0}, params...)...) return &sig } // In all other cases, the type of x.f is the type of x. return s.obj.Type() } // Index describes the path from x to f in x.f. // The last index entry is the field or method index of the type declaring f; // either: // // 1) the list of declared methods of a named type; or // 2) the list of methods of an interface type; or // 3) the list of fields of a struct type. // // The earlier index entries are the indices of the embedded fields implicitly // traversed to get from (the type of) x to f, starting at embedding depth 0. func (s *Selection) Index() []int { return s.index } // Indirect reports whether any pointer indirection was required to get from // x to f in x.f. func (s *Selection) Indirect() bool { return s.indirect } func (s *Selection) String() string { return SelectionString(s, nil) } // SelectionString returns the string form of s. // The Qualifier controls the printing of // package-level objects, and may be nil. // // Examples: // "field (T) f int" // "method (T) f(X) Y" // "method expr (T) f(X) Y" // func SelectionString(s *Selection, qf Qualifier) string { var k string switch s.kind { case FieldVal: k = "field " case MethodVal: k = "method " case MethodExpr: k = "method expr " default: unreachable() } var buf bytes.Buffer buf.WriteString(k) buf.WriteByte('(') WriteType(&buf, s.Recv(), qf) fmt.Fprintf(&buf, ") %s", s.obj.Name()) if T := s.Type(); s.kind == FieldVal { buf.WriteByte(' ') WriteType(&buf, T, qf) } else { WriteSignature(&buf, T.(*Signature), qf) } return buf.String() }