// 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 xml
import (
"bytes";
"io";
"os";
"reflect";
"strings";
)
// BUG(rsc): Mapping between XML elements and data structures is inherently flawed:
// an XML element is an order-dependent collection of anonymous
// values, while a data structure is an order-independent collection
// of named values.
// See package json for a textual representation more suitable
// to data structures.
// Unmarshal parses an XML element from r and uses the
// reflect library to fill in an arbitrary struct, slice, or string
// pointed at by val. Well-formed data that does not fit
// into val is discarded.
//
// For example, given these definitions:
//
// type Email struct {
// Where string "attr";
// Addr string;
// }
//
// type Result struct {
// XMLName xml.Name "result";
// Name string;
// Phone string;
// Email []Email;
// }
//
// var result = Result{ "name", "phone", nil }
//
// unmarshalling the XML input
//
// <result>
// <email where="home">
// <addr>gre@example.com</addr>
// </email>
// <email where='work'>
// <addr>gre@work.com</addr>
// </email>
// <name>Grace R. Emlin</name>
// <address>123 Main Street</address>
// </result>
//
// via Unmarshal(r, &result) is equivalent to assigning
//
// r = Result{
// xml.Name{"", "result"},
// "Grace R. Emlin", // name
// "phone", // no phone given
// []Email{
// Email{ "home", "gre@example.com" },
// Email{ "work", "gre@work.com" }
// }
// }
//
// Note that the field r.Phone has not been modified and
// that the XML <address> element was discarded.
//
// Because Unmarshal uses the reflect package, it can only
// assign to upper case fields. Unmarshal uses a case-insensitive
// comparison to match XML element names to struct field names.
//
// Unmarshal maps an XML element to a struct using the following rules:
//
// * If the struct has a field named XMLName of type xml.Name,
// Unmarshal records the element name in that field.
//
// * If the XMLName field has an associated tag string of the form
// "tag" or "namespace-URL tag", the XML element must have
// the given tag (and, optionally, name space) or else Unmarshal
// returns an error.
//
// * If the XML element has an attribute whose name matches a
// struct field of type string with tag "attr", Unmarshal records
// the attribute value in that field.
//
// * If the XML element contains character data, that data is
// accumulated in the first struct field that has tag "chardata".
// The struct field may have type []byte or string.
// If there is no such field, the character data is discarded.
//
// * If the XML element contains a sub-element whose name
// matches a struct field whose tag is neither "attr" nor "chardata",
// Unmarshal maps the sub-element to that struct field.
// Otherwise, if the struct has a field named Any, unmarshal
// maps the sub-element to that struct field.
//
// Unmarshal maps an XML element to a string or []byte by saving the
// concatenation of that elements character data in the string or []byte.
//
// Unmarshal maps an XML element to a slice by extending the length
// of the slice and mapping the element to the newly created value.
//
// Unmarshal maps an XML element to a bool by setting the bool to true.
//
// Unmarshal maps an XML element to an xml.Name by recording the
// element name.
//
// Unmarshal maps an XML element to a pointer by setting the pointer
// to a freshly allocated value and then mapping the element to that value.
//
func Unmarshal(r io.Reader, val interface{}) os.Error {
v, ok := reflect.NewValue(val).(*reflect.PtrValue);
if !ok {
return os.NewError("non-pointer passed to Unmarshal")
}
p := NewParser(r);
elem := v.Elem();
err := p.unmarshal(elem, nil);
if err != nil {
return err
}
return nil;
}
// An UnmarshalError represents an error in the unmarshalling process.
type UnmarshalError string
func (e UnmarshalError) String() string { return string(e) }
// The Parser's Unmarshal method is like xml.Unmarshal
// except that it can be passed a pointer to the initial start element,
// useful when a client reads some raw XML tokens itself
// but also defers to Unmarshal for some elements.
// Passing a nil start element indicates that Unmarshal should
// read the token stream to find the start element.
func (p *Parser) Unmarshal(val interface{}, start *StartElement) os.Error {
v, ok := reflect.NewValue(val).(*reflect.PtrValue);
if !ok {
return os.NewError("non-pointer passed to Unmarshal")
}
return p.unmarshal(v.Elem(), start);
}
// Unmarshal a single XML element into val.
func (p *Parser) unmarshal(val reflect.Value, start *StartElement) os.Error {
// Find start element if we need it.
if start == nil {
for {
tok, err := p.Token();
if err != nil {
return err
}
if t, ok := tok.(StartElement); ok {
start = &t;
break;
}
}
}
if pv, ok := val.(*reflect.PtrValue); ok {
if pv.Get() == 0 {
zv := reflect.MakeZero(pv.Type().(*reflect.PtrType).Elem());
pv.PointTo(zv);
val = zv;
} else {
val = pv.Elem()
}
}
var (
data []byte;
saveData reflect.Value;
comment []byte;
saveComment reflect.Value;
sv *reflect.StructValue;
styp *reflect.StructType;
)
switch v := val.(type) {
case *reflect.BoolValue:
v.Set(true)
case *reflect.SliceValue:
typ := v.Type().(*reflect.SliceType);
if _, ok := typ.Elem().(*reflect.Uint8Type); ok {
// []byte
saveData = v;
break;
}
// Slice of element values.
// Grow slice.
n := v.Len();
if n >= v.Cap() {
ncap := 2 * n;
if ncap < 4 {
ncap = 4
}
new := reflect.MakeSlice(typ, n, ncap);
reflect.ArrayCopy(new, v);
v.Set(new);
}
v.SetLen(n + 1);
// Recur to read element into slice.
if err := p.unmarshal(v.Elem(n), start); err != nil {
v.SetLen(n);
return err;
}
return nil;
case *reflect.StringValue:
saveData = v
case *reflect.StructValue:
if _, ok := v.Interface().(Name); ok {
v.Set(reflect.NewValue(start.Name).(*reflect.StructValue));
break;
}
sv = v;
typ := sv.Type().(*reflect.StructType);
styp = typ;
// Assign name.
if f, ok := typ.FieldByName("XMLName"); ok {
// Validate element name.
if f.Tag != "" {
tag := f.Tag;
ns := "";
i := strings.LastIndex(tag, " ");
if i >= 0 {
ns, tag = tag[0:i], tag[i+1:]
}
if tag != start.Name.Local {
return UnmarshalError("expected element type <" + tag + "> but have <" + start.Name.Local + ">")
}
if ns != "" && ns != start.Name.Space {
e := "expected element <" + tag + "> in name space " + ns + " but have ";
if start.Name.Space == "" {
e += "no name space"
} else {
e += start.Name.Space
}
return UnmarshalError(e);
}
}
// Save
v := sv.FieldByIndex(f.Index);
if _, ok := v.Interface().(Name); !ok {
return UnmarshalError(sv.Type().String() + " field XMLName does not have type xml.Name")
}
v.(*reflect.StructValue).Set(reflect.NewValue(start.Name).(*reflect.StructValue));
}
// Assign attributes.
// Also, determine whether we need to save character data or comments.
for i, n := 0, typ.NumField(); i < n; i++ {
f := typ.Field(i);
switch f.Tag {
case "attr":
strv, ok := sv.FieldByIndex(f.Index).(*reflect.StringValue);
if !ok {
return UnmarshalError(sv.Type().String() + " field " + f.Name + " has attr tag but is not type string")
}
// Look for attribute.
val := "";
k := strings.ToLower(f.Name);
for _, a := range start.Attr {
if strings.ToLower(a.Name.Local) == k {
val = a.Value;
break;
}
}
strv.Set(val);
case "comment":
if saveComment == nil {
saveComment = sv.FieldByIndex(f.Index)
}
case "chardata":
if saveData == nil {
saveData = sv.FieldByIndex(f.Index)
}
}
}
}
// Find end element.
// Process sub-elements along the way.
Loop:
for {
tok, err := p.Token();
if err != nil {
return err
}
switch t := tok.(type) {
case StartElement:
// Sub-element.
// Look up by tag name.
// If that fails, fall back to mop-up field named "Any".
if sv != nil {
k := strings.ToLower(t.Name.Local);
any := -1;
for i, n := 0, styp.NumField(); i < n; i++ {
f := styp.Field(i);
if strings.ToLower(f.Name) == k {
if err := p.unmarshal(sv.FieldByIndex(f.Index), &t); err != nil {
return err
}
continue Loop;
}
if any < 0 && f.Name == "Any" {
any = i
}
}
if any >= 0 {
if err := p.unmarshal(sv.FieldByIndex(styp.Field(any).Index), &t); err != nil {
return err
}
continue Loop;
}
}
// Not saving sub-element but still have to skip over it.
if err := p.Skip(); err != nil {
return err
}
case EndElement:
break Loop
case CharData:
if saveData != nil {
data = bytes.Add(data, t)
}
case Comment:
if saveComment != nil {
comment = bytes.Add(comment, t)
}
}
}
// Save accumulated character data and comments
switch t := saveData.(type) {
case *reflect.StringValue:
t.Set(string(data))
case *reflect.SliceValue:
t.Set(reflect.NewValue(data).(*reflect.SliceValue))
}
switch t := saveComment.(type) {
case *reflect.StringValue:
t.Set(string(comment))
case *reflect.SliceValue:
t.Set(reflect.NewValue(comment).(*reflect.SliceValue))
}
return nil;
}
// Have already read a start element.
// Read tokens until we find the end element.
// Token is taking care of making sure the
// end element matches the start element we saw.
func (p *Parser) Skip() os.Error {
for {
tok, err := p.Token();
if err != nil {
return err
}
switch t := tok.(type) {
case StartElement:
if err := p.Skip(); err != nil {
return err
}
case EndElement:
return nil
}
}
panic("unreachable");
}
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