func findClass(typ types.Type) (class Class) { named, ok := typ.(*types.Named) if !ok { return Uninterested } var struc *types.Struct if struc, ok = named.Underlying().(*types.Struct); !ok { return Uninterested } for i := 0; i < struc.NumFields(); i++ { f := struc.Field(i) switch { case !f.Anonymous(): continue case f.Name() == "Base": return ModelStruct case f.Name() == "List": return ListStruct } } return Uninterested }
func (c *funcContext) loadStruct(array, target string, s *types.Struct) string { view := c.newVariable("_view") code := fmt.Sprintf("%s = new DataView(%s.buffer, %s.byteOffset)", view, array, array) var fields []*types.Var var collectFields func(s *types.Struct, path string) collectFields = func(s *types.Struct, path string) { for i := 0; i < s.NumFields(); i++ { field := s.Field(i) if fs, isStruct := field.Type().Underlying().(*types.Struct); isStruct { collectFields(fs, path+"."+fieldName(s, i)) continue } fields = append(fields, types.NewVar(0, nil, path+"."+fieldName(s, i), field.Type())) } } collectFields(s, target) offsets := sizes32.Offsetsof(fields) for i, field := range fields { switch t := field.Type().Underlying().(type) { case *types.Basic: if isNumeric(t) { if is64Bit(t) { code += fmt.Sprintf(", %s = new %s(%s.getUint32(%d, true), %s.getUint32(%d, true))", field.Name(), c.typeName(field.Type()), view, offsets[i]+4, view, offsets[i]) break } code += fmt.Sprintf(", %s = %s.get%s(%d, true)", field.Name(), view, toJavaScriptType(t), offsets[i]) } case *types.Array: code += fmt.Sprintf(`, %s = new ($nativeArray(%s))(%s.buffer, $min(%s.byteOffset + %d, %s.buffer.byteLength))`, field.Name(), typeKind(t.Elem()), array, array, offsets[i], array) } } return code }
func fieldName(t *types.Struct, i int) string { name := t.Field(i).Name() if name == "_" || reservedKeywords[name] { return fmt.Sprintf("%s$%d", name, i) } return name }
// matchStructArgType reports whether all the elements of the struct match the expected // type. For instance, with "%d" all the elements must be printable with the "%d" format. func (f *File) matchStructArgType(t printfArgType, typ *types.Struct, arg ast.Expr, inProgress map[types.Type]bool) bool { for i := 0; i < typ.NumFields(); i++ { if !f.matchArgTypeInternal(t, typ.Field(i).Type(), arg, inProgress) { return false } } return true }
func exportedFields(T *types.Struct) []*types.Var { var fields []*types.Var for i := 0; i < T.NumFields(); i++ { f := T.Field(i) if !f.Exported() { continue } fields = append(fields, f) } return fields }
func optimalSize(str *types.Struct, sizes *gcSizes) int64 { nf := str.NumFields() fields := make([]*types.Var, nf) alignofs := make([]int64, nf) sizeofs := make([]int64, nf) for i := 0; i < nf; i++ { fields[i] = str.Field(i) ft := fields[i].Type() alignofs[i] = sizes.Alignof(ft) sizeofs[i] = sizes.Sizeof(ft) } sort.Sort(&byAlignAndSize{fields, alignofs, sizeofs}) return sizes.Sizeof(types.NewStruct(fields, nil)) }
func (p *exporter) fieldList(t *types.Struct) { if trace && t.NumFields() > 0 { p.tracef("fields {>\n") defer p.tracef("<\n} ") } p.int(t.NumFields()) for i := 0; i < t.NumFields(); i++ { if trace && i > 0 { p.tracef("\n") } p.field(t.Field(i)) p.string(t.Tag(i)) } }
func (c *converter) convertStruct(v *gotypes.Struct) *types.Struct { if v == nil { return nil } if v, ok := c.converted[v]; ok { return v.(*types.Struct) } fields := make([]*types.Var, 0, v.NumFields()) tags := make([]string, 0, v.NumFields()) for i := 0; i < v.NumFields(); i++ { fields = append(fields, c.convertVar(v.Field(i))) tags = append(tags, v.Tag(i)) } ret := types.NewStruct(fields, tags) c.converted[v] = ret return ret }
func (w *Walker) emitStructType(name string, typ *types.Struct) { typeStruct := fmt.Sprintf("type %s struct", name) w.emitf(typeStruct) defer w.pushScope(typeStruct)() for i := 0; i < typ.NumFields(); i++ { f := typ.Field(i) if !f.Exported() { continue } typ := f.Type() if f.Anonymous() { w.emitf("embedded %s", w.typeString(typ)) continue } w.emitf("%s %s", f.Name(), w.typeString(typ)) } }
// embeddedObjcTypes returns the possible empty list of Objc types embedded // in the given struct type. func embeddedObjcTypes(t *types.Struct) []string { typeSet := make(map[string]struct{}) var typs []string for i := 0; i < t.NumFields(); i++ { f := t.Field(i) if !f.Exported() { continue } if ft := f.Type(); isObjcType(ft) { name := ft.(*types.Named).Obj().Name() if _, exists := typeSet[name]; !exists { typeSet[name] = struct{}{} typs = append(typs, name) } } } return typs }
// embeddedJavaClasses returns the possible empty list of Java types embedded // in the given struct type. func embeddedJavaClasses(t *types.Struct) []string { clsSet := make(map[string]struct{}) var classes []string for i := 0; i < t.NumFields(); i++ { f := t.Field(i) if !f.Exported() { continue } if t := f.Type(); isJavaType(t) { cls := classNameFor(t) if _, exists := clsSet[cls]; !exists { clsSet[cls] = struct{}{} classes = append(classes, cls) } } } return classes }
func collectFields(fields map[string]string, struc *types.Struct) { // TODO: for i := 0; i < struc.NumFields(); i++ { f, tag := struc.Field(i), struc.Tag(i) switch { case f.Anonymous(): if named, ok := f.Type().(*types.Named); ok { if struc_, ok := named.Underlying().(*types.Struct); ok { collectFields(fields, struc_) } } case strings.Contains(tag, `pretty:""`): fields[f.Name()] = inflect.Underscore(f.Name()) } } }
func collectFields(struc *types.Struct) []string { result := []string{} for i := 0; i < struc.NumFields(); i++ { f, tag := struc.Field(i), struc.Tag(i) switch { case f.Anonymous(): if named, ok := f.Type().(*types.Named); ok { if struc_, ok := named.Underlying().(*types.Struct); ok { result = append(result, collectFields(struc_)...) } } case strings.Contains(tag, `pretty:""`): result = append(result, f.Name()) } } return result }
func findClass(typ types.Type) (class Class) { named, ok := typ.(*types.Named) if !ok { return Uninterested } name := named.Obj().Name() switch name { case "List", "Base": return Uninterested } for i := 0; i < named.NumMethods(); i++ { m := named.Method(i) if m.Name() == "Op" { return OperationStruct } } var struc *types.Struct if struc, ok = named.Underlying().(*types.Struct); !ok { return Uninterested } for i := 0; i < struc.NumFields(); i++ { f := struc.Field(i) switch { case !f.Anonymous(): continue case f.Name() == "Base": return ModelStruct case f.Name() == "List": return ListStruct } } return Uninterested }