// Copyright 2011 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 xml import ( "fmt" "reflect" "strings" "sync" ) // typeInfo holds details for the xml representation of a type. type typeInfo struct { xmlname *fieldInfo fields []fieldInfo } // fieldInfo holds details for the xml representation of a single field. type fieldInfo struct { idx []int name string xmlns string flags fieldFlags parents []string } type fieldFlags int const ( fElement fieldFlags = 1 << iota fAttr fCDATA fCharData fInnerXML fComment fAny fOmitEmpty fMode = fElement | fAttr | fCDATA | fCharData | fInnerXML | fComment | fAny xmlName = "XMLName" ) var tinfoMap sync.Map // map[reflect.Type]*typeInfo var nameType = reflect.TypeOf(Name{}) // getTypeInfo returns the typeInfo structure with details necessary // for marshaling and unmarshaling typ. func getTypeInfo(typ reflect.Type) (*typeInfo, error) { if ti, ok := tinfoMap.Load(typ); ok { return ti.(*typeInfo), nil } tinfo := &typeInfo{} if typ.Kind() == reflect.Struct && typ != nameType { n := typ.NumField() for i := 0; i < n; i++ { f := typ.Field(i) if (!f.IsExported() && !f.Anonymous) || f.Tag.Get("xml") == "-" { continue // Private field } // For embedded structs, embed its fields. if f.Anonymous { t := f.Type if t.Kind() == reflect.Pointer { t = t.Elem() } if t.Kind() == reflect.Struct { inner, err := getTypeInfo(t) if err != nil { return nil, err } if tinfo.xmlname == nil { tinfo.xmlname = inner.xmlname } for _, finfo := range inner.fields { finfo.idx = append([]int{i}, finfo.idx...) if err := addFieldInfo(typ, tinfo, &finfo); err != nil { return nil, err } } continue } } finfo, err := structFieldInfo(typ, &f) if err != nil { return nil, err } if f.Name == xmlName { tinfo.xmlname = finfo continue } // Add the field if it doesn't conflict with other fields. if err := addFieldInfo(typ, tinfo, finfo); err != nil { return nil, err } } } ti, _ := tinfoMap.LoadOrStore(typ, tinfo) return ti.(*typeInfo), nil } // structFieldInfo builds and returns a fieldInfo for f. func structFieldInfo(typ reflect.Type, f *reflect.StructField) (*fieldInfo, error) { finfo := &fieldInfo{idx: f.Index} // Split the tag from the xml namespace if necessary. tag := f.Tag.Get("xml") if ns, t, ok := strings.Cut(tag, " "); ok { finfo.xmlns, tag = ns, t } // Parse flags. tokens := strings.Split(tag, ",") if len(tokens) == 1 { finfo.flags = fElement } else { tag = tokens[0] for _, flag := range tokens[1:] { switch flag { case "attr": finfo.flags |= fAttr case "cdata": finfo.flags |= fCDATA case "chardata": finfo.flags |= fCharData case "innerxml": finfo.flags |= fInnerXML case "comment": finfo.flags |= fComment case "any": finfo.flags |= fAny case "omitempty": finfo.flags |= fOmitEmpty } } // Validate the flags used. valid := true switch mode := finfo.flags & fMode; mode { case 0: finfo.flags |= fElement case fAttr, fCDATA, fCharData, fInnerXML, fComment, fAny, fAny | fAttr: if f.Name == xmlName || tag != "" && mode != fAttr { valid = false } default: // This will also catch multiple modes in a single field. valid = false } if finfo.flags&fMode == fAny { finfo.flags |= fElement } if finfo.flags&fOmitEmpty != 0 && finfo.flags&(fElement|fAttr) == 0 { valid = false } if !valid { return nil, fmt.Errorf("xml: invalid tag in field %s of type %s: %q", f.Name, typ, f.Tag.Get("xml")) } } // Use of xmlns without a name is not allowed. if finfo.xmlns != "" && tag == "" { return nil, fmt.Errorf("xml: namespace without name in field %s of type %s: %q", f.Name, typ, f.Tag.Get("xml")) } if f.Name == xmlName { // The XMLName field records the XML element name. Don't // process it as usual because its name should default to // empty rather than to the field name. finfo.name = tag return finfo, nil } if tag == "" { // If the name part of the tag is completely empty, get // default from XMLName of underlying struct if feasible, // or field name otherwise. if xmlname := lookupXMLName(f.Type); xmlname != nil { finfo.xmlns, finfo.name = xmlname.xmlns, xmlname.name } else { finfo.name = f.Name } return finfo, nil } // Prepare field name and parents. parents := strings.Split(tag, ">") if parents[0] == "" { parents[0] = f.Name } if parents[len(parents)-1] == "" { return nil, fmt.Errorf("xml: trailing '>' in field %s of type %s", f.Name, typ) } finfo.name = parents[len(parents)-1] if len(parents) > 1 { if (finfo.flags & fElement) == 0 { return nil, fmt.Errorf("xml: %s chain not valid with %s flag", tag, strings.Join(tokens[1:], ",")) } finfo.parents = parents[:len(parents)-1] } // If the field type has an XMLName field, the names must match // so that the behavior of both marshaling and unmarshaling // is straightforward and unambiguous. if finfo.flags&fElement != 0 { ftyp := f.Type xmlname := lookupXMLName(ftyp) if xmlname != nil && xmlname.name != finfo.name { return nil, fmt.Errorf("xml: name %q in tag of %s.%s conflicts with name %q in %s.XMLName", finfo.name, typ, f.Name, xmlname.name, ftyp) } } return finfo, nil } // lookupXMLName returns the fieldInfo for typ's XMLName field // in case it exists and has a valid xml field tag, otherwise // it returns nil. func lookupXMLName(typ reflect.Type) (xmlname *fieldInfo) { for typ.Kind() == reflect.Pointer { typ = typ.Elem() } if typ.Kind() != reflect.Struct { return nil } for i, n := 0, typ.NumField(); i < n; i++ { f := typ.Field(i) if f.Name != xmlName { continue } finfo, err := structFieldInfo(typ, &f) if err == nil && finfo.name != "" { return finfo } // Also consider errors as a non-existent field tag // and let getTypeInfo itself report the error. break } return nil } func min(a, b int) int { if a <= b { return a } return b } // addFieldInfo adds finfo to tinfo.fields if there are no // conflicts, or if conflicts arise from previous fields that were // obtained from deeper embedded structures than finfo. In the latter // case, the conflicting entries are dropped. // A conflict occurs when the path (parent + name) to a field is // itself a prefix of another path, or when two paths match exactly. // It is okay for field paths to share a common, shorter prefix. func addFieldInfo(typ reflect.Type, tinfo *typeInfo, newf *fieldInfo) error { var conflicts []int Loop: // First, figure all conflicts. Most working code will have none. for i := range tinfo.fields { oldf := &tinfo.fields[i] if oldf.flags&fMode != newf.flags&fMode { continue } if oldf.xmlns != "" && newf.xmlns != "" && oldf.xmlns != newf.xmlns { continue } minl := min(len(newf.parents), len(oldf.parents)) for p := 0; p < minl; p++ { if oldf.parents[p] != newf.parents[p] { continue Loop } } if len(oldf.parents) > len(newf.parents) { if oldf.parents[len(newf.parents)] == newf.name { conflicts = append(conflicts, i) } } else if len(oldf.parents) < len(newf.parents) { if newf.parents[len(oldf.parents)] == oldf.name { conflicts = append(conflicts, i) } } else { if newf.name == oldf.name { conflicts = append(conflicts, i) } } } // Without conflicts, add the new field and return. if conflicts == nil { tinfo.fields = append(tinfo.fields, *newf) return nil } // If any conflict is shallower, ignore the new field. // This matches the Go field resolution on embedding. for _, i := range conflicts { if len(tinfo.fields[i].idx) < len(newf.idx) { return nil } } // Otherwise, if any of them is at the same depth level, it's an error. for _, i := range conflicts { oldf := &tinfo.fields[i] if len(oldf.idx) == len(newf.idx) { f1 := typ.FieldByIndex(oldf.idx) f2 := typ.FieldByIndex(newf.idx) return &TagPathError{typ, f1.Name, f1.Tag.Get("xml"), f2.Name, f2.Tag.Get("xml")} } } // Otherwise, the new field is shallower, and thus takes precedence, // so drop the conflicting fields from tinfo and append the new one. for c := len(conflicts) - 1; c >= 0; c-- { i := conflicts[c] copy(tinfo.fields[i:], tinfo.fields[i+1:]) tinfo.fields = tinfo.fields[:len(tinfo.fields)-1] } tinfo.fields = append(tinfo.fields, *newf) return nil } // A TagPathError represents an error in the unmarshaling process // caused by the use of field tags with conflicting paths. type TagPathError struct { Struct reflect.Type Field1, Tag1 string Field2, Tag2 string } func (e *TagPathError) Error() string { return fmt.Sprintf("%s field %q with tag %q conflicts with field %q with tag %q", e.Struct, e.Field1, e.Tag1, e.Field2, e.Tag2) } const ( initNilPointers = true dontInitNilPointers = false ) // value returns v's field value corresponding to finfo. // It's equivalent to v.FieldByIndex(finfo.idx), but when passed // initNilPointers, it initializes and dereferences pointers as necessary. // When passed dontInitNilPointers and a nil pointer is reached, the function // returns a zero reflect.Value. func (finfo *fieldInfo) value(v reflect.Value, shouldInitNilPointers bool) reflect.Value { for i, x := range finfo.idx { if i > 0 { t := v.Type() if t.Kind() == reflect.Pointer && t.Elem().Kind() == reflect.Struct { if v.IsNil() { if !shouldInitNilPointers { return reflect.Value{} } v.Set(reflect.New(v.Type().Elem())) } v = v.Elem() } } v = v.Field(x) } return v }