func declTypeName(pkg *types.Package, name string) *types.TypeName { scope := pkg.Scope() if obj := scope.Lookup(name); obj != nil { return obj.(*types.TypeName) } obj := types.NewTypeName(token.NoPos, pkg, name, nil) // a named type may be referred to before the underlying type // is known - set it up types.NewNamed(obj, nil, nil) scope.Insert(obj) return obj }
// pkgString returns a string representation of a package's exported interface. func pkgString(pkg *types.Package) string { var buf bytes.Buffer fmt.Fprintf(&buf, "package %s\n", pkg.Name()) scope := pkg.Scope() for _, name := range scope.Names() { if exported(name) { obj := scope.Lookup(name) buf.WriteString(obj.String()) switch obj := obj.(type) { case *types.Const: // For now only print constant values if they are not float // or complex. This permits comparing go/types results with // gc-generated gcimported package interfaces. info := obj.Type().Underlying().(*types.Basic).Info() if info&types.IsFloat == 0 && info&types.IsComplex == 0 { fmt.Fprintf(&buf, " = %s", obj.Val()) } case *types.TypeName: // Print associated methods. // Basic types (e.g., unsafe.Pointer) have *types.Basic // type rather than *types.Named; so we need to check. if typ, _ := obj.Type().(*types.Named); typ != nil { if n := typ.NumMethods(); n > 0 { // Sort methods by name so that we get the // same order independent of whether the // methods got imported or coming directly // for the source. // TODO(gri) This should probably be done // in go/types. list := make([]*types.Func, n) for i := 0; i < n; i++ { list[i] = typ.Method(i) } sort.Sort(byName(list)) buf.WriteString("\nmethods (\n") for _, m := range list { fmt.Fprintf(&buf, "\t%s\n", m) } buf.WriteString(")") } } } buf.WriteByte('\n') } } return buf.String() }
func (p *importer) obj(pkg *types.Package) { var obj types.Object switch tag := p.int(); tag { case constTag: obj = types.NewConst(token.NoPos, pkg, p.string(), p.typ(), p.value()) case typeTag: // type object is added to scope via respective named type _ = p.typ().(*types.Named) return case varTag: obj = types.NewVar(token.NoPos, pkg, p.string(), p.typ()) case funcTag: obj = types.NewFunc(token.NoPos, pkg, p.string(), p.typ().(*types.Signature)) default: panic(fmt.Sprintf("unexpected object tag %d", tag)) } if alt := pkg.Scope().Insert(obj); alt != nil { panic(fmt.Sprintf("%s already declared", alt.Name())) } }
func (p *exporter) pkg(pkg *types.Package) { if trace { p.tracef("package { ") defer p.tracef("} ") } if pkg == nil { panic("unexpected nil pkg") } // if the package was seen before, write its index (>= 0) if i, ok := p.pkgIndex[pkg]; ok { p.int(i) return } p.pkgIndex[pkg] = len(p.pkgIndex) // otherwise, write the package tag (< 0) and package data p.int(packageTag) p.string(pkg.Name()) p.string(pkg.Path()) }
// ExportData serializes the interface (exported package objects) // of package pkg and returns the corresponding data. The export // format is described elsewhere (TODO). func ExportData(pkg *types.Package) []byte { p := exporter{ data: append([]byte(magic), format()), pkgIndex: make(map[*types.Package]int), typIndex: make(map[types.Type]int), } // populate typIndex with predeclared types for _, t := range predeclared { p.typIndex[t] = len(p.typIndex) } if trace { p.tracef("export %s\n", pkg.Name()) defer p.tracef("\n") } p.string(version) p.pkg(pkg) // collect exported objects from package scope var list []types.Object scope := pkg.Scope() for _, name := range scope.Names() { if exported(name) { list = append(list, scope.Lookup(name)) } } // write objects p.int(len(list)) for _, obj := range list { p.obj(obj) } return p.data }
// FunctionType = ParamList ResultList . func (p *parser) parseFunctionType(pkg *types.Package) *types.Signature { params, isVariadic := p.parseParamList(pkg) results := p.parseResultList(pkg) return types.NewSignature(pkg.Scope(), nil, params, results, isVariadic) }
func (in *interp) augmentPackageScope(pkg *types.Package) { for _, obj := range in.scope { pkg.Scope().Insert(obj) } }
func testExportImport(t *testing.T, pkg0 *types.Package, path string) (size, gcsize int) { data := ExportData(pkg0) size = len(data) imports := make(map[string]*types.Package) n, pkg1, err := ImportData(imports, data) if err != nil { t.Errorf("package %s: import failed: %s", pkg0.Name(), err) return } if n != size { t.Errorf("package %s: not all input data consumed", pkg0.Name()) return } s0 := pkgString(pkg0) s1 := pkgString(pkg1) if s1 != s0 { t.Errorf("package %s: \nimport got:\n%s\nwant:\n%s\n", pkg0.Name(), s1, s0) } // If we have a standard library, compare also against the gcimported package. if path == "" { return // not std library } gcdata, err := gcExportData(path) if err != nil { if pkg0.Name() == "main" { return // no export data present for main package } t.Errorf("package %s: couldn't get export data: %s", pkg0.Name(), err) } gcsize = len(gcdata) imports = make(map[string]*types.Package) pkg2, err := gcImportData(imports, gcdata, path) if err != nil { t.Errorf("package %s: gcimport failed: %s", pkg0.Name(), err) return } s2 := pkgString(pkg2) if s2 != s0 { t.Errorf("package %s: \ngcimport got:\n%s\nwant:\n%s\n", pkg0.Name(), s2, s0) } return }