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gerrit.opencord.org / voltha-openolt-adapter / efff76eab6179baf5979e46e5ad85b06dd0b943c / . / vendor / github.com / jhump / protoreflect / dynamic / dynamic_message.go
blob: de13b923cced3d3ed4823c88ca9acc7fdb04f32a [file] [log] [blame]
package dynamic
import (
"bytes"
"compress/gzip"
"errors"
"fmt"
"reflect"
"sort"
"strings"
"github.com/golang/protobuf/proto"
"github.com/golang/protobuf/protoc-gen-go/descriptor"
"github.com/jhump/protoreflect/codec"
"github.com/jhump/protoreflect/desc"
"github.com/jhump/protoreflect/internal"
)
// ErrUnknownTagNumber is an error that is returned when an operation refers
// to an unknown tag number.
var ErrUnknownTagNumber = errors.New("unknown tag number")
// UnknownTagNumberError is the same as ErrUnknownTagNumber.
// Deprecated: use ErrUnknownTagNumber
var UnknownTagNumberError = ErrUnknownTagNumber
// ErrUnknownFieldName is an error that is returned when an operation refers
// to an unknown field name.
var ErrUnknownFieldName = errors.New("unknown field name")
// UnknownFieldNameError is the same as ErrUnknownFieldName.
// Deprecated: use ErrUnknownFieldName
var UnknownFieldNameError = ErrUnknownFieldName
// ErrFieldIsNotMap is an error that is returned when map-related operations
// are attempted with fields that are not maps.
var ErrFieldIsNotMap = errors.New("field is not a map type")
// FieldIsNotMapError is the same as ErrFieldIsNotMap.
// Deprecated: use ErrFieldIsNotMap
var FieldIsNotMapError = ErrFieldIsNotMap
// ErrFieldIsNotRepeated is an error that is returned when repeated field
// operations are attempted with fields that are not repeated.
var ErrFieldIsNotRepeated = errors.New("field is not repeated")
// FieldIsNotRepeatedError is the same as ErrFieldIsNotRepeated.
// Deprecated: use ErrFieldIsNotRepeated
var FieldIsNotRepeatedError = ErrFieldIsNotRepeated
// ErrIndexOutOfRange is an error that is returned when an invalid index is
// provided when access a single element of a repeated field.
var ErrIndexOutOfRange = errors.New("index is out of range")
// IndexOutOfRangeError is the same as ErrIndexOutOfRange.
// Deprecated: use ErrIndexOutOfRange
var IndexOutOfRangeError = ErrIndexOutOfRange
// ErrNumericOverflow is an error returned by operations that encounter a
// numeric value that is too large, for example de-serializing a value into an
// int32 field when the value is larger that can fit into a 32-bit value.
var ErrNumericOverflow = errors.New("numeric value is out of range")
// NumericOverflowError is the same as ErrNumericOverflow.
// Deprecated: use ErrNumericOverflow
var NumericOverflowError = ErrNumericOverflow
var typeOfProtoMessage = reflect.TypeOf((*proto.Message)(nil)).Elem()
var typeOfDynamicMessage = reflect.TypeOf((*Message)(nil))
var typeOfBytes = reflect.TypeOf(([]byte)(nil))
// Message is a dynamic protobuf message. Instead of a generated struct,
// like most protobuf messages, this is a map of field number to values and
// a message descriptor, which is used to validate the field values and
// also to de-serialize messages (from the standard binary format, as well
// as from the text format and from JSON).
type Message struct {
md *desc.MessageDescriptor
er *ExtensionRegistry
mf *MessageFactory
extraFields map[int32]*desc.FieldDescriptor
values map[int32]interface{}
unknownFields map[int32][]UnknownField
}
// UnknownField represents a field that was parsed from the binary wire
// format for a message, but was not a recognized field number. Enough
// information is preserved so that re-serializing the message won't lose
// any of the unrecognized data.
type UnknownField struct {
// Encoding indicates how the unknown field was encoded on the wire. If it
// is proto.WireBytes or proto.WireGroupStart then Contents will be set to
// the raw bytes. If it is proto.WireTypeFixed32 then the data is in the least
// significant 32 bits of Value. Otherwise, the data is in all 64 bits of
// Value.
Encoding int8
Contents []byte
Value uint64
}
// NewMessage creates a new dynamic message for the type represented by the given
// message descriptor. During de-serialization, a default MessageFactory is used to
// instantiate any nested message fields and no extension fields will be parsed. To
// use a custom MessageFactory or ExtensionRegistry, use MessageFactory.NewMessage.
func NewMessage(md *desc.MessageDescriptor) *Message {
return NewMessageWithMessageFactory(md, nil)
}
// NewMessageWithExtensionRegistry creates a new dynamic message for the type
// represented by the given message descriptor. During de-serialization, the given
// ExtensionRegistry is used to parse extension fields and nested messages will be
// instantiated using dynamic.NewMessageFactoryWithExtensionRegistry(er).
func NewMessageWithExtensionRegistry(md *desc.MessageDescriptor, er *ExtensionRegistry) *Message {
mf := NewMessageFactoryWithExtensionRegistry(er)
return NewMessageWithMessageFactory(md, mf)
}
// NewMessageWithMessageFactory creates a new dynamic message for the type
// represented by the given message descriptor. During de-serialization, the given
// MessageFactory is used to instantiate nested messages.
func NewMessageWithMessageFactory(md *desc.MessageDescriptor, mf *MessageFactory) *Message {
var er *ExtensionRegistry
if mf != nil {
er = mf.er
}
return &Message{
md: md,
mf: mf,
er: er,
}
}
// AsDynamicMessage converts the given message to a dynamic message. If the
// given message is dynamic, it is returned. Otherwise, a dynamic message is
// created using NewMessage.
func AsDynamicMessage(msg proto.Message) (*Message, error) {
return AsDynamicMessageWithMessageFactory(msg, nil)
}
// AsDynamicMessageWithExtensionRegistry converts the given message to a dynamic
// message. If the given message is dynamic, it is returned. Otherwise, a
// dynamic message is created using NewMessageWithExtensionRegistry.
func AsDynamicMessageWithExtensionRegistry(msg proto.Message, er *ExtensionRegistry) (*Message, error) {
mf := NewMessageFactoryWithExtensionRegistry(er)
return AsDynamicMessageWithMessageFactory(msg, mf)
}
// AsDynamicMessageWithMessageFactory converts the given message to a dynamic
// message. If the given message is dynamic, it is returned. Otherwise, a
// dynamic message is created using NewMessageWithMessageFactory.
func AsDynamicMessageWithMessageFactory(msg proto.Message, mf *MessageFactory) (*Message, error) {
if dm, ok := msg.(*Message); ok {
return dm, nil
}
md, err := desc.LoadMessageDescriptorForMessage(msg)
if err != nil {
return nil, err
}
dm := NewMessageWithMessageFactory(md, mf)
err = dm.mergeFrom(msg)
if err != nil {
return nil, err
}
return dm, nil
}
// GetMessageDescriptor returns a descriptor for this message's type.
func (m *Message) GetMessageDescriptor() *desc.MessageDescriptor {
return m.md
}
// GetKnownFields returns a slice of descriptors for all known fields. The
// fields will not be in any defined order.
func (m *Message) GetKnownFields() []*desc.FieldDescriptor {
if len(m.extraFields) == 0 {
return m.md.GetFields()
}
flds := make([]*desc.FieldDescriptor, len(m.md.GetFields()), len(m.md.GetFields())+len(m.extraFields))
copy(flds, m.md.GetFields())
for _, fld := range m.extraFields {
if !fld.IsExtension() {
flds = append(flds, fld)
}
}
return flds
}
// GetKnownExtensions returns a slice of descriptors for all extensions known by
// the message's extension registry. The fields will not be in any defined order.
func (m *Message) GetKnownExtensions() []*desc.FieldDescriptor {
if !m.md.IsExtendable() {
return nil
}
exts := m.er.AllExtensionsForType(m.md.GetFullyQualifiedName())
for _, fld := range m.extraFields {
if fld.IsExtension() {
exts = append(exts, fld)
}
}
return exts
}
// GetUnknownFields returns a slice of tag numbers for all unknown fields that
// this message contains. The tags will not be in any defined order.
func (m *Message) GetUnknownFields() []int32 {
flds := make([]int32, 0, len(m.unknownFields))
for tag := range m.unknownFields {
flds = append(flds, tag)
}
return flds
}
// Descriptor returns the serialized form of the file descriptor in which the
// message was defined and a path to the message type therein. This mimics the
// method of the same name on message types generated by protoc.
func (m *Message) Descriptor() ([]byte, []int) {
// get encoded file descriptor
b, err := proto.Marshal(m.md.GetFile().AsProto())
if err != nil {
panic(fmt.Sprintf("failed to get encoded descriptor for %s: %v", m.md.GetFile().GetName(), err))
}
var zippedBytes bytes.Buffer
w := gzip.NewWriter(&zippedBytes)
if _, err := w.Write(b); err != nil {
panic(fmt.Sprintf("failed to get encoded descriptor for %s: %v", m.md.GetFile().GetName(), err))
}
if err := w.Close(); err != nil {
panic(fmt.Sprintf("failed to get an encoded descriptor for %s: %v", m.md.GetFile().GetName(), err))
}
// and path to message
path := []int{}
var d desc.Descriptor
name := m.md.GetFullyQualifiedName()
for d = m.md.GetParent(); d != nil; name, d = d.GetFullyQualifiedName(), d.GetParent() {
found := false
switch d := d.(type) {
case (*desc.FileDescriptor):
for i, md := range d.GetMessageTypes() {
if md.GetFullyQualifiedName() == name {
found = true
path = append(path, i)
}
}
case (*desc.MessageDescriptor):
for i, md := range d.GetNestedMessageTypes() {
if md.GetFullyQualifiedName() == name {
found = true
path = append(path, i)
}
}
}
if !found {
panic(fmt.Sprintf("failed to compute descriptor path for %s", m.md.GetFullyQualifiedName()))
}
}
// reverse the path
i := 0
j := len(path) - 1
for i < j {
path[i], path[j] = path[j], path[i]
i++
j--
}
return zippedBytes.Bytes(), path
}
// XXX_MessageName returns the fully qualified name of this message's type. This
// allows dynamic messages to be used with proto.MessageName.
func (m *Message) XXX_MessageName() string {
return m.md.GetFullyQualifiedName()
}
// FindFieldDescriptor returns a field descriptor for the given tag number. This
// searches known fields in the descriptor, known fields discovered during calls
// to GetField or SetField, and extension fields known by the message's extension
// registry. It returns nil if the tag is unknown.
func (m *Message) FindFieldDescriptor(tagNumber int32) *desc.FieldDescriptor {
fd := m.md.FindFieldByNumber(tagNumber)
if fd != nil {
return fd
}
fd = m.er.FindExtension(m.md.GetFullyQualifiedName(), tagNumber)
if fd != nil {
return fd
}
return m.extraFields[tagNumber]
}
// FindFieldDescriptorByName returns a field descriptor for the given field
// name. This searches known fields in the descriptor, known fields discovered
// during calls to GetField or SetField, and extension fields known by the
// message's extension registry. It returns nil if the name is unknown. If the
// given name refers to an extension, it should be fully qualified and may be
// optionally enclosed in parentheses or brackets.
func (m *Message) FindFieldDescriptorByName(name string) *desc.FieldDescriptor {
if name == "" {
return nil
}
fd := m.md.FindFieldByName(name)
if fd != nil {
return fd
}
mustBeExt := false
if name[0] == '(' {
if name[len(name)-1] != ')' {
// malformed name
return nil
}
mustBeExt = true
name = name[1 : len(name)-1]
} else if name[0] == '[' {
if name[len(name)-1] != ']' {
// malformed name
return nil
}
mustBeExt = true
name = name[1 : len(name)-1]
}
fd = m.er.FindExtensionByName(m.md.GetFullyQualifiedName(), name)
if fd != nil {
return fd
}
for _, fd := range m.extraFields {
if fd.IsExtension() && name == fd.GetFullyQualifiedName() {
return fd
} else if !mustBeExt && !fd.IsExtension() && name == fd.GetName() {
return fd
}
}
return nil
}
// FindFieldDescriptorByJSONName returns a field descriptor for the given JSON
// name. This searches known fields in the descriptor, known fields discovered
// during calls to GetField or SetField, and extension fields known by the
// message's extension registry. If no field matches the given JSON name, it
// will fall back to searching field names (e.g. FindFieldDescriptorByName). If
// this also yields no match, nil is returned.
func (m *Message) FindFieldDescriptorByJSONName(name string) *desc.FieldDescriptor {
if name == "" {
return nil
}
fd := m.md.FindFieldByJSONName(name)
if fd != nil {
return fd
}
mustBeExt := false
if name[0] == '(' {
if name[len(name)-1] != ')' {
// malformed name
return nil
}
mustBeExt = true
name = name[1 : len(name)-1]
} else if name[0] == '[' {
if name[len(name)-1] != ']' {
// malformed name
return nil
}
mustBeExt = true
name = name[1 : len(name)-1]
}
fd = m.er.FindExtensionByJSONName(m.md.GetFullyQualifiedName(), name)
if fd != nil {
return fd
}
for _, fd := range m.extraFields {
if fd.IsExtension() && name == fd.GetFullyQualifiedJSONName() {
return fd
} else if !mustBeExt && !fd.IsExtension() && name == fd.GetJSONName() {
return fd
}
}
// try non-JSON names
return m.FindFieldDescriptorByName(name)
}
func (m *Message) checkField(fd *desc.FieldDescriptor) error {
return checkField(fd, m.md)
}
func checkField(fd *desc.FieldDescriptor, md *desc.MessageDescriptor) error {
if fd.GetOwner().GetFullyQualifiedName() != md.GetFullyQualifiedName() {
return fmt.Errorf("given field, %s, is for wrong message type: %s; expecting %s", fd.GetName(), fd.GetOwner().GetFullyQualifiedName(), md.GetFullyQualifiedName())
}
if fd.IsExtension() && !md.IsExtension(fd.GetNumber()) {
return fmt.Errorf("given field, %s, is an extension but is not in message extension range: %v", fd.GetFullyQualifiedName(), md.GetExtensionRanges())
}
return nil
}
// GetField returns the value for the given field descriptor. It panics if an
// error is encountered. See TryGetField.
func (m *Message) GetField(fd *desc.FieldDescriptor) interface{} {
if v, err := m.TryGetField(fd); err != nil {
panic(err.Error())
} else {
return v
}
}
// TryGetField returns the value for the given field descriptor. An error is
// returned if the given field descriptor does not belong to the right message
// type.
//
// The Go type of the returned value, for scalar fields, is the same as protoc
// would generate for the field (in a non-dynamic message). The table below
// lists the scalar types and the corresponding Go types.
// +-------------------------+-----------+
// | Declared Type | Go Type |
// +-------------------------+-----------+
// | int32, sint32, sfixed32 | int32 |
// | int64, sint64, sfixed64 | int64 |
// | uint32, fixed32 | uint32 |
// | uint64, fixed64 | uint64 |
// | float | float32 |
// | double | double32 |
// | bool | bool |
// | string | string |
// | bytes | []byte |
// +-------------------------+-----------+
//
// Values for enum fields will always be int32 values. You can use the enum
// descriptor associated with the field to lookup value names with those values.
// Values for message type fields may be an instance of the generated type *or*
// may be another *dynamic.Message that represents the type.
//
// If the given field is a map field, the returned type will be
// map[interface{}]interface{}. The actual concrete types of keys and values is
// as described above. If the given field is a (non-map) repeated field, the
// returned type is always []interface{}; the type of the actual elements is as
// described above.
//
// If this message has no value for the given field, its default value is
// returned. If the message is defined in a file with "proto3" syntax, the
// default is always the zero value for the field. The default value for map and
// repeated fields is a nil map or slice (respectively). For field's whose types
// is a message, the default value is an empty message for "proto2" syntax or a
// nil message for "proto3" syntax. Note that the in the latter case, a non-nil
// interface with a nil pointer is returned, not a nil interface. Also note that
// whether the returned value is an empty message or nil depends on if *this*
// message was defined as "proto3" syntax, not the message type referred to by
// the field's type.
//
// If the given field descriptor is not known (e.g. not present in the message
// descriptor) but corresponds to an unknown field, the unknown value will be
// parsed and become known. The parsed value will be returned, or an error will
// be returned if the unknown value cannot be parsed according to the field
// descriptor's type information.
func (m *Message) TryGetField(fd *desc.FieldDescriptor) (interface{}, error) {
if err := m.checkField(fd); err != nil {
return nil, err
}
return m.getField(fd)
}
// GetFieldByName returns the value for the field with the given name. It panics
// if an error is encountered. See TryGetFieldByName.
func (m *Message) GetFieldByName(name string) interface{} {
if v, err := m.TryGetFieldByName(name); err != nil {
panic(err.Error())
} else {
return v
}
}
// TryGetFieldByName returns the value for the field with the given name. An
// error is returned if the given name is unknown. If the given name refers to
// an extension field, it should be fully qualified and optionally enclosed in
// parenthesis or brackets.
//
// If this message has no value for the given field, its default value is
// returned. (See TryGetField for more info on types and default field values.)
func (m *Message) TryGetFieldByName(name string) (interface{}, error) {
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return nil, UnknownFieldNameError
}
return m.getField(fd)
}
// GetFieldByNumber returns the value for the field with the given tag number.
// It panics if an error is encountered. See TryGetFieldByNumber.
func (m *Message) GetFieldByNumber(tagNumber int) interface{} {
if v, err := m.TryGetFieldByNumber(tagNumber); err != nil {
panic(err.Error())
} else {
return v
}
}
// TryGetFieldByNumber returns the value for the field with the given tag
// number. An error is returned if the given tag is unknown.
//
// If this message has no value for the given field, its default value is
// returned. (See TryGetField for more info on types and default field values.)
func (m *Message) TryGetFieldByNumber(tagNumber int) (interface{}, error) {
fd := m.FindFieldDescriptor(int32(tagNumber))
if fd == nil {
return nil, UnknownTagNumberError
}
return m.getField(fd)
}
func (m *Message) getField(fd *desc.FieldDescriptor) (interface{}, error) {
return m.doGetField(fd, false)
}
func (m *Message) doGetField(fd *desc.FieldDescriptor, nilIfAbsent bool) (interface{}, error) {
res := m.values[fd.GetNumber()]
if res == nil {
var err error
if res, err = m.parseUnknownField(fd); err != nil {
return nil, err
}
if res == nil {
if nilIfAbsent {
return nil, nil
} else {
def := fd.GetDefaultValue()
if def != nil {
return def, nil
}
// GetDefaultValue only returns nil for message types
md := fd.GetMessageType()
if m.md.IsProto3() {
return nilMessage(md), nil
} else {
// for proto2, return default instance of message
return m.mf.NewMessage(md), nil
}
}
}
}
rt := reflect.TypeOf(res)
if rt.Kind() == reflect.Map {
// make defensive copies to prevent caller from storing illegal keys and values
m := res.(map[interface{}]interface{})
res := map[interface{}]interface{}{}
for k, v := range m {
res[k] = v
}
return res, nil
} else if rt.Kind() == reflect.Slice && rt != typeOfBytes {
// make defensive copies to prevent caller from storing illegal elements
sl := res.([]interface{})
res := make([]interface{}, len(sl))
copy(res, sl)
return res, nil
}
return res, nil
}
func nilMessage(md *desc.MessageDescriptor) interface{} {
// try to return a proper nil pointer
msgType := proto.MessageType(md.GetFullyQualifiedName())
if msgType != nil && msgType.Implements(typeOfProtoMessage) {
return reflect.Zero(msgType).Interface().(proto.Message)
}
// fallback to nil dynamic message pointer
return (*Message)(nil)
}
// HasField returns true if this message has a value for the given field. If the
// given field is not valid (e.g. belongs to a different message type), false is
// returned. If this message is defined in a file with "proto3" syntax, this
// will return false even if a field was explicitly assigned its zero value (the
// zero values for a field are intentionally indistinguishable from absent).
func (m *Message) HasField(fd *desc.FieldDescriptor) bool {
if err := m.checkField(fd); err != nil {
return false
}
return m.HasFieldNumber(int(fd.GetNumber()))
}
// HasFieldName returns true if this message has a value for a field with the
// given name. If the given name is unknown, this returns false.
func (m *Message) HasFieldName(name string) bool {
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return false
}
return m.HasFieldNumber(int(fd.GetNumber()))
}
// HasFieldNumber returns true if this message has a value for a field with the
// given tag number. If the given tag is unknown, this returns false.
func (m *Message) HasFieldNumber(tagNumber int) bool {
if _, ok := m.values[int32(tagNumber)]; ok {
return true
}
_, ok := m.unknownFields[int32(tagNumber)]
return ok
}
// SetField sets the value for the given field descriptor to the given value. It
// panics if an error is encountered. See TrySetField.
func (m *Message) SetField(fd *desc.FieldDescriptor, val interface{}) {
if err := m.TrySetField(fd, val); err != nil {
panic(err.Error())
}
}
// TrySetField sets the value for the given field descriptor to the given value.
// An error is returned if the given field descriptor does not belong to the
// right message type or if the given value is not a correct/compatible type for
// the given field.
//
// The Go type expected for a field is the same as TryGetField would return for
// the field. So message values can be supplied as either the correct generated
// message type or as a *dynamic.Message.
//
// Since it is cumbersome to work with dynamic messages, some concessions are
// made to simplify usage regarding types:
//
// 1. If a numeric type is provided that can be converted *without loss or
// overflow*, it is accepted. This allows for setting int64 fields using int
// or int32 values. Similarly for uint64 with uint and uint32 values and for
// float64 fields with float32 values.
// 2. The value can be a named type, as long as its underlying type is correct.
// 3. Map and repeated fields can be set using any kind of concrete map or
// slice type, as long as the values within are all of the correct type. So
// a field defined as a 'map<string, int32>` can be set using a
// map[string]int32, a map[string]interface{}, or even a
// map[interface{}]interface{}.
// 4. Finally, dynamic code that chooses to not treat maps as a special-case
// find that they can set map fields using a slice where each element is a
// message that matches the implicit map-entry field message type.
//
// If the given field descriptor is not known (e.g. not present in the message
// descriptor) it will become known. Subsequent operations using tag numbers or
// names will be able to resolve the newly-known type. If the message has a
// value for the unknown value, it is cleared, replaced by the given known
// value.
func (m *Message) TrySetField(fd *desc.FieldDescriptor, val interface{}) error {
if err := m.checkField(fd); err != nil {
return err
}
return m.setField(fd, val)
}
// SetFieldByName sets the value for the field with the given name to the given
// value. It panics if an error is encountered. See TrySetFieldByName.
func (m *Message) SetFieldByName(name string, val interface{}) {
if err := m.TrySetFieldByName(name, val); err != nil {
panic(err.Error())
}
}
// TrySetFieldByName sets the value for the field with the given name to the
// given value. An error is returned if the given name is unknown or if the
// given value has an incorrect type. If the given name refers to an extension
// field, it should be fully qualified and optionally enclosed in parenthesis or
// brackets.
//
// (See TrySetField for more info on types.)
func (m *Message) TrySetFieldByName(name string, val interface{}) error {
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return UnknownFieldNameError
}
return m.setField(fd, val)
}
// SetFieldByNumber sets the value for the field with the given tag number to
// the given value. It panics if an error is encountered. See
// TrySetFieldByNumber.
func (m *Message) SetFieldByNumber(tagNumber int, val interface{}) {
if err := m.TrySetFieldByNumber(tagNumber, val); err != nil {
panic(err.Error())
}
}
// TrySetFieldByNumber sets the value for the field with the given tag number to
// the given value. An error is returned if the given tag is unknown or if the
// given value has an incorrect type.
//
// (See TrySetField for more info on types.)
func (m *Message) TrySetFieldByNumber(tagNumber int, val interface{}) error {
fd := m.FindFieldDescriptor(int32(tagNumber))
if fd == nil {
return UnknownTagNumberError
}
return m.setField(fd, val)
}
func (m *Message) setField(fd *desc.FieldDescriptor, val interface{}) error {
var err error
if val, err = validFieldValue(fd, val); err != nil {
return err
}
m.internalSetField(fd, val)
return nil
}
func (m *Message) internalSetField(fd *desc.FieldDescriptor, val interface{}) {
if fd.IsRepeated() {
// Unset fields and zero-length fields are indistinguishable, in both
// proto2 and proto3 syntax
if reflect.ValueOf(val).Len() == 0 {
if m.values != nil {
delete(m.values, fd.GetNumber())
}
return
}
} else if m.md.IsProto3() && fd.GetOneOf() == nil {
// proto3 considers fields that are set to their zero value as unset
// (we already handled repeated fields above)
var equal bool
if b, ok := val.([]byte); ok {
// can't compare slices, so we have to special-case []byte values
equal = ok && bytes.Equal(b, fd.GetDefaultValue().([]byte))
} else {
defVal := fd.GetDefaultValue()
equal = defVal == val
if !equal && defVal == nil {
// above just checks if value is the nil interface,
// but we should also test if the given value is a
// nil pointer
rv := reflect.ValueOf(val)
if rv.Kind() == reflect.Ptr && rv.IsNil() {
equal = true
}
}
}
if equal {
if m.values != nil {
delete(m.values, fd.GetNumber())
}
return
}
}
if m.values == nil {
m.values = map[int32]interface{}{}
}
m.values[fd.GetNumber()] = val
// if this field is part of a one-of, make sure all other one-of choices are cleared
od := fd.GetOneOf()
if od != nil {
for _, other := range od.GetChoices() {
if other.GetNumber() != fd.GetNumber() {
delete(m.values, other.GetNumber())
}
}
}
// also clear any unknown fields
if m.unknownFields != nil {
delete(m.unknownFields, fd.GetNumber())
}
// and add this field if it was previously unknown
if existing := m.FindFieldDescriptor(fd.GetNumber()); existing == nil {
m.addField(fd)
}
}
func (m *Message) addField(fd *desc.FieldDescriptor) {
if m.extraFields == nil {
m.extraFields = map[int32]*desc.FieldDescriptor{}
}
m.extraFields[fd.GetNumber()] = fd
}
// ClearField removes any value for the given field. It panics if an error is
// encountered. See TryClearField.
func (m *Message) ClearField(fd *desc.FieldDescriptor) {
if err := m.TryClearField(fd); err != nil {
panic(err.Error())
}
}
// TryClearField removes any value for the given field. An error is returned if
// the given field descriptor does not belong to the right message type.
func (m *Message) TryClearField(fd *desc.FieldDescriptor) error {
if err := m.checkField(fd); err != nil {
return err
}
m.clearField(fd)
return nil
}
// ClearFieldByName removes any value for the field with the given name. It
// panics if an error is encountered. See TryClearFieldByName.
func (m *Message) ClearFieldByName(name string) {
if err := m.TryClearFieldByName(name); err != nil {
panic(err.Error())
}
}
// TryClearFieldByName removes any value for the field with the given name. An
// error is returned if the given name is unknown. If the given name refers to
// an extension field, it should be fully qualified and optionally enclosed in
// parenthesis or brackets.
func (m *Message) TryClearFieldByName(name string) error {
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return UnknownFieldNameError
}
m.clearField(fd)
return nil
}
// ClearFieldByNumber removes any value for the field with the given tag number.
// It panics if an error is encountered. See TryClearFieldByNumber.
func (m *Message) ClearFieldByNumber(tagNumber int) {
if err := m.TryClearFieldByNumber(tagNumber); err != nil {
panic(err.Error())
}
}
// TryClearFieldByNumber removes any value for the field with the given tag
// number. An error is returned if the given tag is unknown.
func (m *Message) TryClearFieldByNumber(tagNumber int) error {
fd := m.FindFieldDescriptor(int32(tagNumber))
if fd == nil {
return UnknownTagNumberError
}
m.clearField(fd)
return nil
}
func (m *Message) clearField(fd *desc.FieldDescriptor) {
// clear value
if m.values != nil {
delete(m.values, fd.GetNumber())
}
// also clear any unknown fields
if m.unknownFields != nil {
delete(m.unknownFields, fd.GetNumber())
}
// and add this field if it was previously unknown
if existing := m.FindFieldDescriptor(fd.GetNumber()); existing == nil {
m.addField(fd)
}
}
// GetOneOfField returns which of the given one-of's fields is set and the
// corresponding value. It panics if an error is encountered. See
// TryGetOneOfField.
func (m *Message) GetOneOfField(od *desc.OneOfDescriptor) (*desc.FieldDescriptor, interface{}) {
if fd, val, err := m.TryGetOneOfField(od); err != nil {
panic(err.Error())
} else {
return fd, val
}
}
// TryGetOneOfField returns which of the given one-of's fields is set and the
// corresponding value. An error is returned if the given one-of belongs to the
// wrong message type. If the given one-of has no field set, this method will
// return nil, nil.
//
// The type of the value, if one is set, is the same as would be returned by
// TryGetField using the returned field descriptor.
//
// Like with TryGetField, if the given one-of contains any fields that are not
// known (e.g. not present in this message's descriptor), they will become known
// and any unknown value will be parsed (and become a known value on success).
func (m *Message) TryGetOneOfField(od *desc.OneOfDescriptor) (*desc.FieldDescriptor, interface{}, error) {
if od.GetOwner().GetFullyQualifiedName() != m.md.GetFullyQualifiedName() {
return nil, nil, fmt.Errorf("given one-of, %s, is for wrong message type: %s; expecting %s", od.GetName(), od.GetOwner().GetFullyQualifiedName(), m.md.GetFullyQualifiedName())
}
for _, fd := range od.GetChoices() {
val, err := m.doGetField(fd, true)
if err != nil {
return nil, nil, err
}
if val != nil {
return fd, val, nil
}
}
return nil, nil, nil
}
// ClearOneOfField removes any value for any of the given one-of's fields. It
// panics if an error is encountered. See TryClearOneOfField.
func (m *Message) ClearOneOfField(od *desc.OneOfDescriptor) {
if err := m.TryClearOneOfField(od); err != nil {
panic(err.Error())
}
}
// TryClearOneOfField removes any value for any of the given one-of's fields. An
// error is returned if the given one-of descriptor does not belong to the right
// message type.
func (m *Message) TryClearOneOfField(od *desc.OneOfDescriptor) error {
if od.GetOwner().GetFullyQualifiedName() != m.md.GetFullyQualifiedName() {
return fmt.Errorf("given one-of, %s, is for wrong message type: %s; expecting %s", od.GetName(), od.GetOwner().GetFullyQualifiedName(), m.md.GetFullyQualifiedName())
}
for _, fd := range od.GetChoices() {
m.clearField(fd)
}
return nil
}
// GetMapField returns the value for the given map field descriptor and given
// key. It panics if an error is encountered. See TryGetMapField.
func (m *Message) GetMapField(fd *desc.FieldDescriptor, key interface{}) interface{} {
if v, err := m.TryGetMapField(fd, key); err != nil {
panic(err.Error())
} else {
return v
}
}
// TryGetMapField returns the value for the given map field descriptor and given
// key. An error is returned if the given field descriptor does not belong to
// the right message type or if it is not a map field.
//
// If the map field does not contain the requested key, this method returns
// nil, nil. The Go type of the value returned mirrors the type that protoc
// would generate for the field. (See TryGetField for more details on types).
//
// If the given field descriptor is not known (e.g. not present in the message
// descriptor) but corresponds to an unknown field, the unknown value will be
// parsed and become known. The parsed value will be searched for the requested
// key and any value returned. An error will be returned if the unknown value
// cannot be parsed according to the field descriptor's type information.
func (m *Message) TryGetMapField(fd *desc.FieldDescriptor, key interface{}) (interface{}, error) {
if err := m.checkField(fd); err != nil {
return nil, err
}
return m.getMapField(fd, key)
}
// GetMapFieldByName returns the value for the map field with the given name and
// given key. It panics if an error is encountered. See TryGetMapFieldByName.
func (m *Message) GetMapFieldByName(name string, key interface{}) interface{} {
if v, err := m.TryGetMapFieldByName(name, key); err != nil {
panic(err.Error())
} else {
return v
}
}
// TryGetMapFieldByName returns the value for the map field with the given name
// and given key. An error is returned if the given name is unknown or if it
// names a field that is not a map field.
//
// If this message has no value for the given field or the value has no value
// for the requested key, then this method returns nil, nil.
//
// (See TryGetField for more info on types.)
func (m *Message) TryGetMapFieldByName(name string, key interface{}) (interface{}, error) {
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return nil, UnknownFieldNameError
}
return m.getMapField(fd, key)
}
// GetMapFieldByNumber returns the value for the map field with the given tag
// number and given key. It panics if an error is encountered. See
// TryGetMapFieldByNumber.
func (m *Message) GetMapFieldByNumber(tagNumber int, key interface{}) interface{} {
if v, err := m.TryGetMapFieldByNumber(tagNumber, key); err != nil {
panic(err.Error())
} else {
return v
}
}
// TryGetMapFieldByNumber returns the value for the map field with the given tag
// number and given key. An error is returned if the given tag is unknown or if
// it indicates a field that is not a map field.
//
// If this message has no value for the given field or the value has no value
// for the requested key, then this method returns nil, nil.
//
// (See TryGetField for more info on types.)
func (m *Message) TryGetMapFieldByNumber(tagNumber int, key interface{}) (interface{}, error) {
fd := m.FindFieldDescriptor(int32(tagNumber))
if fd == nil {
return nil, UnknownTagNumberError
}
return m.getMapField(fd, key)
}
func (m *Message) getMapField(fd *desc.FieldDescriptor, key interface{}) (interface{}, error) {
if !fd.IsMap() {
return nil, FieldIsNotMapError
}
kfd := fd.GetMessageType().GetFields()[0]
ki, err := validElementFieldValue(kfd, key, false)
if err != nil {
return nil, err
}
mp := m.values[fd.GetNumber()]
if mp == nil {
if mp, err = m.parseUnknownField(fd); err != nil {
return nil, err
} else if mp == nil {
return nil, nil
}
}
return mp.(map[interface{}]interface{})[ki], nil
}
// ForEachMapFieldEntry executes the given function for each entry in the map
// value for the given field descriptor. It stops iteration if the function
// returns false. It panics if an error is encountered. See
// TryForEachMapFieldEntry.
func (m *Message) ForEachMapFieldEntry(fd *desc.FieldDescriptor, fn func(key, val interface{}) bool) {
if err := m.TryForEachMapFieldEntry(fd, fn); err != nil {
panic(err.Error())
}
}
// TryForEachMapFieldEntry executes the given function for each entry in the map
// value for the given field descriptor. An error is returned if the given field
// descriptor does not belong to the right message type or if it is not a map
// field.
//
// Iteration ends either when all entries have been examined or when the given
// function returns false. So the function is expected to return true for normal
// iteration and false to break out. If this message has no value for the given
// field, it returns without invoking the given function.
//
// The Go type of the key and value supplied to the function mirrors the type
// that protoc would generate for the field. (See TryGetField for more details
// on types).
//
// If the given field descriptor is not known (e.g. not present in the message
// descriptor) but corresponds to an unknown field, the unknown value will be
// parsed and become known. The parsed value will be searched for the requested
// key and any value returned. An error will be returned if the unknown value
// cannot be parsed according to the field descriptor's type information.
func (m *Message) TryForEachMapFieldEntry(fd *desc.FieldDescriptor, fn func(key, val interface{}) bool) error {
if err := m.checkField(fd); err != nil {
return err
}
return m.forEachMapFieldEntry(fd, fn)
}
// ForEachMapFieldEntryByName executes the given function for each entry in the
// map value for the field with the given name. It stops iteration if the
// function returns false. It panics if an error is encountered. See
// TryForEachMapFieldEntryByName.
func (m *Message) ForEachMapFieldEntryByName(name string, fn func(key, val interface{}) bool) {
if err := m.TryForEachMapFieldEntryByName(name, fn); err != nil {
panic(err.Error())
}
}
// TryForEachMapFieldEntryByName executes the given function for each entry in
// the map value for the field with the given name. It stops iteration if the
// function returns false. An error is returned if the given name is unknown or
// if it names a field that is not a map field.
//
// If this message has no value for the given field, it returns without ever
// invoking the given function.
//
// (See TryGetField for more info on types supplied to the function.)
func (m *Message) TryForEachMapFieldEntryByName(name string, fn func(key, val interface{}) bool) error {
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return UnknownFieldNameError
}
return m.forEachMapFieldEntry(fd, fn)
}
// ForEachMapFieldEntryByNumber executes the given function for each entry in
// the map value for the field with the given tag number. It stops iteration if
// the function returns false. It panics if an error is encountered. See
// TryForEachMapFieldEntryByNumber.
func (m *Message) ForEachMapFieldEntryByNumber(tagNumber int, fn func(key, val interface{}) bool) {
if err := m.TryForEachMapFieldEntryByNumber(tagNumber, fn); err != nil {
panic(err.Error())
}
}
// TryForEachMapFieldEntryByNumber executes the given function for each entry in
// the map value for the field with the given tag number. It stops iteration if
// the function returns false. An error is returned if the given tag is unknown
// or if it indicates a field that is not a map field.
//
// If this message has no value for the given field, it returns without ever
// invoking the given function.
//
// (See TryGetField for more info on types supplied to the function.)
func (m *Message) TryForEachMapFieldEntryByNumber(tagNumber int, fn func(key, val interface{}) bool) error {
fd := m.FindFieldDescriptor(int32(tagNumber))
if fd == nil {
return UnknownTagNumberError
}
return m.forEachMapFieldEntry(fd, fn)
}
func (m *Message) forEachMapFieldEntry(fd *desc.FieldDescriptor, fn func(key, val interface{}) bool) error {
if !fd.IsMap() {
return FieldIsNotMapError
}
mp := m.values[fd.GetNumber()]
if mp == nil {
if mp, err := m.parseUnknownField(fd); err != nil {
return err
} else if mp == nil {
return nil
}
}
for k, v := range mp.(map[interface{}]interface{}) {
if !fn(k, v) {
break
}
}
return nil
}
// PutMapField sets the value for the given map field descriptor and given key
// to the given value. It panics if an error is encountered. See TryPutMapField.
func (m *Message) PutMapField(fd *desc.FieldDescriptor, key interface{}, val interface{}) {
if err := m.TryPutMapField(fd, key, val); err != nil {
panic(err.Error())
}
}
// TryPutMapField sets the value for the given map field descriptor and given
// key to the given value. An error is returned if the given field descriptor
// does not belong to the right message type, if the given field is not a map
// field, or if the given value is not a correct/compatible type for the given
// field.
//
// The Go type expected for a field is the same as required by TrySetField for
// a field with the same type as the map's value type.
//
// If the given field descriptor is not known (e.g. not present in the message
// descriptor) it will become known. Subsequent operations using tag numbers or
// names will be able to resolve the newly-known type. If the message has a
// value for the unknown value, it is cleared, replaced by the given known
// value.
func (m *Message) TryPutMapField(fd *desc.FieldDescriptor, key interface{}, val interface{}) error {
if err := m.checkField(fd); err != nil {
return err
}
return m.putMapField(fd, key, val)
}
// PutMapFieldByName sets the value for the map field with the given name and
// given key to the given value. It panics if an error is encountered. See
// TryPutMapFieldByName.
func (m *Message) PutMapFieldByName(name string, key interface{}, val interface{}) {
if err := m.TryPutMapFieldByName(name, key, val); err != nil {
panic(err.Error())
}
}
// TryPutMapFieldByName sets the value for the map field with the given name and
// the given key to the given value. An error is returned if the given name is
// unknown, if it names a field that is not a map, or if the given value has an
// incorrect type.
//
// (See TrySetField for more info on types.)
func (m *Message) TryPutMapFieldByName(name string, key interface{}, val interface{}) error {
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return UnknownFieldNameError
}
return m.putMapField(fd, key, val)
}
// PutMapFieldByNumber sets the value for the map field with the given tag
// number and given key to the given value. It panics if an error is
// encountered. See TryPutMapFieldByNumber.
func (m *Message) PutMapFieldByNumber(tagNumber int, key interface{}, val interface{}) {
if err := m.TryPutMapFieldByNumber(tagNumber, key, val); err != nil {
panic(err.Error())
}
}
// TryPutMapFieldByNumber sets the value for the map field with the given tag
// number and the given key to the given value. An error is returned if the
// given tag is unknown, if it indicates a field that is not a map, or if the
// given value has an incorrect type.
//
// (See TrySetField for more info on types.)
func (m *Message) TryPutMapFieldByNumber(tagNumber int, key interface{}, val interface{}) error {
fd := m.FindFieldDescriptor(int32(tagNumber))
if fd == nil {
return UnknownTagNumberError
}
return m.putMapField(fd, key, val)
}
func (m *Message) putMapField(fd *desc.FieldDescriptor, key interface{}, val interface{}) error {
if !fd.IsMap() {
return FieldIsNotMapError
}
kfd := fd.GetMessageType().GetFields()[0]
ki, err := validElementFieldValue(kfd, key, false)
if err != nil {
return err
}
vfd := fd.GetMessageType().GetFields()[1]
vi, err := validElementFieldValue(vfd, val, true)
if err != nil {
return err
}
mp := m.values[fd.GetNumber()]
if mp == nil {
if mp, err = m.parseUnknownField(fd); err != nil {
return err
} else if mp == nil {
m.internalSetField(fd, map[interface{}]interface{}{ki: vi})
return nil
}
}
mp.(map[interface{}]interface{})[ki] = vi
return nil
}
// RemoveMapField changes the value for the given field descriptor by removing
// any value associated with the given key. It panics if an error is
// encountered. See TryRemoveMapField.
func (m *Message) RemoveMapField(fd *desc.FieldDescriptor, key interface{}) {
if err := m.TryRemoveMapField(fd, key); err != nil {
panic(err.Error())
}
}
// TryRemoveMapField changes the value for the given field descriptor by
// removing any value associated with the given key. An error is returned if the
// given field descriptor does not belong to the right message type or if the
// given field is not a map field.
//
// If the given field descriptor is not known (e.g. not present in the message
// descriptor) it will become known. Subsequent operations using tag numbers or
// names will be able to resolve the newly-known type. If the message has a
// value for the unknown value, it is parsed and any value for the given key
// removed.
func (m *Message) TryRemoveMapField(fd *desc.FieldDescriptor, key interface{}) error {
if err := m.checkField(fd); err != nil {
return err
}
return m.removeMapField(fd, key)
}
// RemoveMapFieldByName changes the value for the field with the given name by
// removing any value associated with the given key. It panics if an error is
// encountered. See TryRemoveMapFieldByName.
func (m *Message) RemoveMapFieldByName(name string, key interface{}) {
if err := m.TryRemoveMapFieldByName(name, key); err != nil {
panic(err.Error())
}
}
// TryRemoveMapFieldByName changes the value for the field with the given name
// by removing any value associated with the given key. An error is returned if
// the given name is unknown or if it names a field that is not a map.
func (m *Message) TryRemoveMapFieldByName(name string, key interface{}) error {
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return UnknownFieldNameError
}
return m.removeMapField(fd, key)
}
// RemoveMapFieldByNumber changes the value for the field with the given tag
// number by removing any value associated with the given key. It panics if an
// error is encountered. See TryRemoveMapFieldByNumber.
func (m *Message) RemoveMapFieldByNumber(tagNumber int, key interface{}) {
if err := m.TryRemoveMapFieldByNumber(tagNumber, key); err != nil {
panic(err.Error())
}
}
// TryRemoveMapFieldByNumber changes the value for the field with the given tag
// number by removing any value associated with the given key. An error is
// returned if the given tag is unknown or if it indicates a field that is not
// a map.
func (m *Message) TryRemoveMapFieldByNumber(tagNumber int, key interface{}) error {
fd := m.FindFieldDescriptor(int32(tagNumber))
if fd == nil {
return UnknownTagNumberError
}
return m.removeMapField(fd, key)
}
func (m *Message) removeMapField(fd *desc.FieldDescriptor, key interface{}) error {
if !fd.IsMap() {
return FieldIsNotMapError
}
kfd := fd.GetMessageType().GetFields()[0]
ki, err := validElementFieldValue(kfd, key, false)
if err != nil {
return err
}
mp := m.values[fd.GetNumber()]
if mp == nil {
if mp, err = m.parseUnknownField(fd); err != nil {
return err
} else if mp == nil {
return nil
}
}
res := mp.(map[interface{}]interface{})
delete(res, ki)
if len(res) == 0 {
delete(m.values, fd.GetNumber())
}
return nil
}
// FieldLength returns the number of elements in this message for the given
// field descriptor. It panics if an error is encountered. See TryFieldLength.
func (m *Message) FieldLength(fd *desc.FieldDescriptor) int {
l, err := m.TryFieldLength(fd)
if err != nil {
panic(err.Error())
}
return l
}
// TryFieldLength returns the number of elements in this message for the given
// field descriptor. An error is returned if the given field descriptor does not
// belong to the right message type or if it is neither a map field nor a
// repeated field.
func (m *Message) TryFieldLength(fd *desc.FieldDescriptor) (int, error) {
if err := m.checkField(fd); err != nil {
return 0, err
}
return m.fieldLength(fd)
}
// FieldLengthByName returns the number of elements in this message for the
// field with the given name. It panics if an error is encountered. See
// TryFieldLengthByName.
func (m *Message) FieldLengthByName(name string) int {
l, err := m.TryFieldLengthByName(name)
if err != nil {
panic(err.Error())
}
return l
}
// TryFieldLengthByName returns the number of elements in this message for the
// field with the given name. An error is returned if the given name is unknown
// or if the named field is neither a map field nor a repeated field.
func (m *Message) TryFieldLengthByName(name string) (int, error) {
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return 0, UnknownFieldNameError
}
return m.fieldLength(fd)
}
// FieldLengthByNumber returns the number of elements in this message for the
// field with the given tag number. It panics if an error is encountered. See
// TryFieldLengthByNumber.
func (m *Message) FieldLengthByNumber(tagNumber int32) int {
l, err := m.TryFieldLengthByNumber(tagNumber)
if err != nil {
panic(err.Error())
}
return l
}
// TryFieldLengthByNumber returns the number of elements in this message for the
// field with the given tag number. An error is returned if the given tag is
// unknown or if the named field is neither a map field nor a repeated field.
func (m *Message) TryFieldLengthByNumber(tagNumber int32) (int, error) {
fd := m.FindFieldDescriptor(int32(tagNumber))
if fd == nil {
return 0, UnknownTagNumberError
}
return m.fieldLength(fd)
}
func (m *Message) fieldLength(fd *desc.FieldDescriptor) (int, error) {
if !fd.IsRepeated() {
return 0, FieldIsNotRepeatedError
}
val := m.values[fd.GetNumber()]
if val == nil {
var err error
if val, err = m.parseUnknownField(fd); err != nil {
return 0, err
} else if val == nil {
return 0, nil
}
}
if sl, ok := val.([]interface{}); ok {
return len(sl), nil
} else if mp, ok := val.(map[interface{}]interface{}); ok {
return len(mp), nil
}
return 0, nil
}
// GetRepeatedField returns the value for the given repeated field descriptor at
// the given index. It panics if an error is encountered. See
// TryGetRepeatedField.
func (m *Message) GetRepeatedField(fd *desc.FieldDescriptor, index int) interface{} {
if v, err := m.TryGetRepeatedField(fd, index); err != nil {
panic(err.Error())
} else {
return v
}
}
// TryGetRepeatedField returns the value for the given repeated field descriptor
// at the given index. An error is returned if the given field descriptor does
// not belong to the right message type, if it is not a repeated field, or if
// the given index is out of range (less than zero or greater than or equal to
// the length of the repeated field). Also, even though map fields technically
// are repeated fields, if the given field is a map field an error will result:
// map representation does not lend itself to random access by index.
//
// The Go type of the value returned mirrors the type that protoc would generate
// for the field's element type. (See TryGetField for more details on types).
//
// If the given field descriptor is not known (e.g. not present in the message
// descriptor) but corresponds to an unknown field, the unknown value will be
// parsed and become known. The value at the given index in the parsed value
// will be returned. An error will be returned if the unknown value cannot be
// parsed according to the field descriptor's type information.
func (m *Message) TryGetRepeatedField(fd *desc.FieldDescriptor, index int) (interface{}, error) {
if index < 0 {
return nil, IndexOutOfRangeError
}
if err := m.checkField(fd); err != nil {
return nil, err
}
return m.getRepeatedField(fd, index)
}
// GetRepeatedFieldByName returns the value for the repeated field with the
// given name at the given index. It panics if an error is encountered. See
// TryGetRepeatedFieldByName.
func (m *Message) GetRepeatedFieldByName(name string, index int) interface{} {
if v, err := m.TryGetRepeatedFieldByName(name, index); err != nil {
panic(err.Error())
} else {
return v
}
}
// TryGetRepeatedFieldByName returns the value for the repeated field with the
// given name at the given index. An error is returned if the given name is
// unknown, if it names a field that is not a repeated field (or is a map
// field), or if the given index is out of range (less than zero or greater
// than or equal to the length of the repeated field).
//
// (See TryGetField for more info on types.)
func (m *Message) TryGetRepeatedFieldByName(name string, index int) (interface{}, error) {
if index < 0 {
return nil, IndexOutOfRangeError
}
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return nil, UnknownFieldNameError
}
return m.getRepeatedField(fd, index)
}
// GetRepeatedFieldByNumber returns the value for the repeated field with the
// given tag number at the given index. It panics if an error is encountered.
// See TryGetRepeatedFieldByNumber.
func (m *Message) GetRepeatedFieldByNumber(tagNumber int, index int) interface{} {
if v, err := m.TryGetRepeatedFieldByNumber(tagNumber, index); err != nil {
panic(err.Error())
} else {
return v
}
}
// TryGetRepeatedFieldByNumber returns the value for the repeated field with the
// given tag number at the given index. An error is returned if the given tag is
// unknown, if it indicates a field that is not a repeated field (or is a map
// field), or if the given index is out of range (less than zero or greater than
// or equal to the length of the repeated field).
//
// (See TryGetField for more info on types.)
func (m *Message) TryGetRepeatedFieldByNumber(tagNumber int, index int) (interface{}, error) {
if index < 0 {
return nil, IndexOutOfRangeError
}
fd := m.FindFieldDescriptor(int32(tagNumber))
if fd == nil {
return nil, UnknownTagNumberError
}
return m.getRepeatedField(fd, index)
}
func (m *Message) getRepeatedField(fd *desc.FieldDescriptor, index int) (interface{}, error) {
if fd.IsMap() || !fd.IsRepeated() {
return nil, FieldIsNotRepeatedError
}
sl := m.values[fd.GetNumber()]
if sl == nil {
var err error
if sl, err = m.parseUnknownField(fd); err != nil {
return nil, err
} else if sl == nil {
return nil, IndexOutOfRangeError
}
}
res := sl.([]interface{})
if index >= len(res) {
return nil, IndexOutOfRangeError
}
return res[index], nil
}
// AddRepeatedField appends the given value to the given repeated field. It
// panics if an error is encountered. See TryAddRepeatedField.
func (m *Message) AddRepeatedField(fd *desc.FieldDescriptor, val interface{}) {
if err := m.TryAddRepeatedField(fd, val); err != nil {
panic(err.Error())
}
}
// TryAddRepeatedField appends the given value to the given repeated field. An
// error is returned if the given field descriptor does not belong to the right
// message type, if the given field is not repeated, or if the given value is
// not a correct/compatible type for the given field. If the given field is a
// map field, the call will succeed if the given value is an instance of the
// map's entry message type.
//
// The Go type expected for a field is the same as required by TrySetField for
// a non-repeated field of the same type.
//
// If the given field descriptor is not known (e.g. not present in the message
// descriptor) it will become known. Subsequent operations using tag numbers or
// names will be able to resolve the newly-known type. If the message has a
// value for the unknown value, it is parsed and the given value is appended to
// it.
func (m *Message) TryAddRepeatedField(fd *desc.FieldDescriptor, val interface{}) error {
if err := m.checkField(fd); err != nil {
return err
}
return m.addRepeatedField(fd, val)
}
// AddRepeatedFieldByName appends the given value to the repeated field with the
// given name. It panics if an error is encountered. See
// TryAddRepeatedFieldByName.
func (m *Message) AddRepeatedFieldByName(name string, val interface{}) {
if err := m.TryAddRepeatedFieldByName(name, val); err != nil {
panic(err.Error())
}
}
// TryAddRepeatedFieldByName appends the given value to the repeated field with
// the given name. An error is returned if the given name is unknown, if it
// names a field that is not repeated, or if the given value has an incorrect
// type.
//
// (See TrySetField for more info on types.)
func (m *Message) TryAddRepeatedFieldByName(name string, val interface{}) error {
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return UnknownFieldNameError
}
return m.addRepeatedField(fd, val)
}
// AddRepeatedFieldByNumber appends the given value to the repeated field with
// the given tag number. It panics if an error is encountered. See
// TryAddRepeatedFieldByNumber.
func (m *Message) AddRepeatedFieldByNumber(tagNumber int, val interface{}) {
if err := m.TryAddRepeatedFieldByNumber(tagNumber, val); err != nil {
panic(err.Error())
}
}
// TryAddRepeatedFieldByNumber appends the given value to the repeated field
// with the given tag number. An error is returned if the given tag is unknown,
// if it indicates a field that is not repeated, or if the given value has an
// incorrect type.
//
// (See TrySetField for more info on types.)
func (m *Message) TryAddRepeatedFieldByNumber(tagNumber int, val interface{}) error {
fd := m.FindFieldDescriptor(int32(tagNumber))
if fd == nil {
return UnknownTagNumberError
}
return m.addRepeatedField(fd, val)
}
func (m *Message) addRepeatedField(fd *desc.FieldDescriptor, val interface{}) error {
if !fd.IsRepeated() {
return FieldIsNotRepeatedError
}
val, err := validElementFieldValue(fd, val, false)
if err != nil {
return err
}
if fd.IsMap() {
// We're lenient. Just as we allow setting a map field to a slice of entry messages, we also allow
// adding entries one at a time (as if the field were a normal repeated field).
msg := val.(proto.Message)
dm, err := asDynamicMessage(msg, fd.GetMessageType(), m.mf)
if err != nil {
return err
}
k, err := dm.TryGetFieldByNumber(1)
if err != nil {
return err
}
v, err := dm.TryGetFieldByNumber(2)
if err != nil {
return err
}
return m.putMapField(fd, k, v)
}
sl := m.values[fd.GetNumber()]
if sl == nil {
if sl, err = m.parseUnknownField(fd); err != nil {
return err
} else if sl == nil {
sl = []interface{}{}
}
}
res := sl.([]interface{})
res = append(res, val)
m.internalSetField(fd, res)
return nil
}
// SetRepeatedField sets the value for the given repeated field descriptor and
// given index to the given value. It panics if an error is encountered. See
// SetRepeatedField.
func (m *Message) SetRepeatedField(fd *desc.FieldDescriptor, index int, val interface{}) {
if err := m.TrySetRepeatedField(fd, index, val); err != nil {
panic(err.Error())
}
}
// TrySetRepeatedField sets the value for the given repeated field descriptor
// and given index to the given value. An error is returned if the given field
// descriptor does not belong to the right message type, if the given field is
// not repeated, or if the given value is not a correct/compatible type for the
// given field. Also, even though map fields technically are repeated fields, if
// the given field is a map field an error will result: map representation does
// not lend itself to random access by index.
//
// The Go type expected for a field is the same as required by TrySetField for
// a non-repeated field of the same type.
//
// If the given field descriptor is not known (e.g. not present in the message
// descriptor) it will become known. Subsequent operations using tag numbers or
// names will be able to resolve the newly-known type. If the message has a
// value for the unknown value, it is parsed and the element at the given index
// is replaced with the given value.
func (m *Message) TrySetRepeatedField(fd *desc.FieldDescriptor, index int, val interface{}) error {
if index < 0 {
return IndexOutOfRangeError
}
if err := m.checkField(fd); err != nil {
return err
}
return m.setRepeatedField(fd, index, val)
}
// SetRepeatedFieldByName sets the value for the repeated field with the given
// name and given index to the given value. It panics if an error is
// encountered. See TrySetRepeatedFieldByName.
func (m *Message) SetRepeatedFieldByName(name string, index int, val interface{}) {
if err := m.TrySetRepeatedFieldByName(name, index, val); err != nil {
panic(err.Error())
}
}
// TrySetRepeatedFieldByName sets the value for the repeated field with the
// given name and the given index to the given value. An error is returned if
// the given name is unknown, if it names a field that is not repeated (or is a
// map field), or if the given value has an incorrect type.
//
// (See TrySetField for more info on types.)
func (m *Message) TrySetRepeatedFieldByName(name string, index int, val interface{}) error {
if index < 0 {
return IndexOutOfRangeError
}
fd := m.FindFieldDescriptorByName(name)
if fd == nil {
return UnknownFieldNameError
}
return m.setRepeatedField(fd, index, val)
}
// SetRepeatedFieldByNumber sets the value for the repeated field with the given
// tag number and given index to the given value. It panics if an error is
// encountered. See TrySetRepeatedFieldByNumber.
func (m *Message) SetRepeatedFieldByNumber(tagNumber int, index int, val interface{}) {
if err := m.TrySetRepeatedFieldByNumber(tagNumber, index, val); err != nil {
panic(err.Error())
}
}
// TrySetRepeatedFieldByNumber sets the value for the repeated field with the
// given tag number and the given index to the given value. An error is returned
// if the given tag is unknown, if it indicates a field that is not repeated (or
// is a map field), or if the given value has an incorrect type.
//
// (See TrySetField for more info on types.)
func (m *Message) TrySetRepeatedFieldByNumber(tagNumber int, index int, val interface{}) error {
if index < 0 {
return IndexOutOfRangeError
}
fd := m.FindFieldDescriptor(int32(tagNumber))
if fd == nil {
return UnknownTagNumberError
}
return m.setRepeatedField(fd, index, val)
}
func (m *Message) setRepeatedField(fd *desc.FieldDescriptor, index int, val interface{}) error {
if fd.IsMap() || !fd.IsRepeated() {
return FieldIsNotRepeatedError
}
val, err := validElementFieldValue(fd, val, false)
if err != nil {
return err
}
sl := m.values[fd.GetNumber()]
if sl == nil {
if sl, err = m.parseUnknownField(fd); err != nil {
return err
} else if sl == nil {
return IndexOutOfRangeError
}
}
res := sl.([]interface{})
if index >= len(res) {
return IndexOutOfRangeError
}
res[index] = val
return nil
}
// GetUnknownField gets the value(s) for the given unknown tag number. If this
// message has no unknown fields with the given tag, nil is returned.
func (m *Message) GetUnknownField(tagNumber int32) []UnknownField {
if u, ok := m.unknownFields[tagNumber]; ok {
return u
} else {
return nil
}
}
func (m *Message) parseUnknownField(fd *desc.FieldDescriptor) (interface{}, error) {
unks, ok := m.unknownFields[fd.GetNumber()]
if !ok {
return nil, nil
}
var v interface{}
var sl []interface{}
var mp map[interface{}]interface{}
if fd.IsMap() {
mp = map[interface{}]interface{}{}
}
var err error
for _, unk := range unks {
var val interface{}
if unk.Encoding == proto.WireBytes || unk.Encoding == proto.WireStartGroup {
val, err = codec.DecodeLengthDelimitedField(fd, unk.Contents, m.mf)
} else {
val, err = codec.DecodeScalarField(fd, unk.Value)
}
if err != nil {
return nil, err
}
if fd.IsMap() {
newEntry := val.(*Message)
kk, err := newEntry.TryGetFieldByNumber(1)
if err != nil {
return nil, err
}
vv, err := newEntry.TryGetFieldByNumber(2)
if err != nil {
return nil, err
}
mp[kk] = vv
v = mp
} else if fd.IsRepeated() {
t := reflect.TypeOf(val)
if t.Kind() == reflect.Slice && t != typeOfBytes {
// append slices if we unmarshalled a packed repeated field
newVals := val.([]interface{})
sl = append(sl, newVals...)
} else {
sl = append(sl, val)
}
v = sl
} else {
v = val
}
}
m.internalSetField(fd, v)
return v, nil
}
func validFieldValue(fd *desc.FieldDescriptor, val interface{}) (interface{}, error) {
return validFieldValueForRv(fd, reflect.ValueOf(val))
}
func validFieldValueForRv(fd *desc.FieldDescriptor, val reflect.Value) (interface{}, error) {
if fd.IsMap() && val.Kind() == reflect.Map {
return validFieldValueForMapField(fd, val)
}
if fd.IsRepeated() { // this will also catch map fields where given value was not a map
if val.Kind() != reflect.Array && val.Kind() != reflect.Slice {
if fd.IsMap() {
return nil, fmt.Errorf("value for map field must be a map; instead was %v", val.Type())
} else {
return nil, fmt.Errorf("value for repeated field must be a slice; instead was %v", val.Type())
}
}
if fd.IsMap() {
// value should be a slice of entry messages that we need convert into a map[interface{}]interface{}
m := map[interface{}]interface{}{}
for i := 0; i < val.Len(); i++ {
e, err := validElementFieldValue(fd, val.Index(i).Interface(), false)
if err != nil {
return nil, err
}
msg := e.(proto.Message)
dm, err := asDynamicMessage(msg, fd.GetMessageType(), nil)
if err != nil {
return nil, err
}
k, err := dm.TryGetFieldByNumber(1)
if err != nil {
return nil, err
}
v, err := dm.TryGetFieldByNumber(2)
if err != nil {
return nil, err
}
m[k] = v
}
return m, nil
}
// make a defensive copy while checking contents (also converts to []interface{})
s := make([]interface{}, val.Len())
for i := 0; i < val.Len(); i++ {
ev := val.Index(i)
if ev.Kind() == reflect.Interface {
// unwrap it
ev = reflect.ValueOf(ev.Interface())
}
e, err := validElementFieldValueForRv(fd, ev, false)
if err != nil {
return nil, err
}
s[i] = e
}
return s, nil
}
return validElementFieldValueForRv(fd, val, false)
}
func asDynamicMessage(m proto.Message, md *desc.MessageDescriptor, mf *MessageFactory) (*Message, error) {
if dm, ok := m.(*Message); ok {
return dm, nil
}
dm := NewMessageWithMessageFactory(md, mf)
if err := dm.mergeFrom(m); err != nil {
return nil, err
}
return dm, nil
}
func validElementFieldValue(fd *desc.FieldDescriptor, val interface{}, allowNilMessage bool) (interface{}, error) {
return validElementFieldValueForRv(fd, reflect.ValueOf(val), allowNilMessage)
}
func validElementFieldValueForRv(fd *desc.FieldDescriptor, val reflect.Value, allowNilMessage bool) (interface{}, error) {
t := fd.GetType()
if !val.IsValid() {
return nil, typeError(fd, nil)
}
switch t {
case descriptor.FieldDescriptorProto_TYPE_SFIXED32,
descriptor.FieldDescriptorProto_TYPE_INT32,
descriptor.FieldDescriptorProto_TYPE_SINT32,
descriptor.FieldDescriptorProto_TYPE_ENUM:
return toInt32(reflect.Indirect(val), fd)
case descriptor.FieldDescriptorProto_TYPE_SFIXED64,
descriptor.FieldDescriptorProto_TYPE_INT64,
descriptor.FieldDescriptorProto_TYPE_SINT64:
return toInt64(reflect.Indirect(val), fd)
case descriptor.FieldDescriptorProto_TYPE_FIXED32,
descriptor.FieldDescriptorProto_TYPE_UINT32:
return toUint32(reflect.Indirect(val), fd)
case descriptor.FieldDescriptorProto_TYPE_FIXED64,
descriptor.FieldDescriptorProto_TYPE_UINT64:
return toUint64(reflect.Indirect(val), fd)
case descriptor.FieldDescriptorProto_TYPE_FLOAT:
return toFloat32(reflect.Indirect(val), fd)
case descriptor.FieldDescriptorProto_TYPE_DOUBLE:
return toFloat64(reflect.Indirect(val), fd)
case descriptor.FieldDescriptorProto_TYPE_BOOL:
return toBool(reflect.Indirect(val), fd)
case descriptor.FieldDescriptorProto_TYPE_BYTES:
return toBytes(reflect.Indirect(val), fd)
case descriptor.FieldDescriptorProto_TYPE_STRING:
return toString(reflect.Indirect(val), fd)
case descriptor.FieldDescriptorProto_TYPE_MESSAGE,
descriptor.FieldDescriptorProto_TYPE_GROUP:
m, err := asMessage(val, fd.GetFullyQualifiedName())
// check that message is correct type
if err != nil {
return nil, err
}
var msgType string
if dm, ok := m.(*Message); ok {
if allowNilMessage && dm == nil {
// if dm == nil, we'll panic below, so early out if that is allowed
// (only allowed for map values, to indicate an entry w/ no value)
return m, nil
}
msgType = dm.GetMessageDescriptor().GetFullyQualifiedName()
} else {
msgType = proto.MessageName(m)
}
if msgType != fd.GetMessageType().GetFullyQualifiedName() {
return nil, fmt.Errorf("message field %s requires value of type %s; received %s", fd.GetFullyQualifiedName(), fd.GetMessageType().GetFullyQualifiedName(), msgType)
}
return m, nil
default:
return nil, fmt.Errorf("unable to handle unrecognized field type: %v", fd.GetType())
}
}
func toInt32(v reflect.Value, fd *desc.FieldDescriptor) (int32, error) {
if v.Kind() == reflect.Int32 {
return int32(v.Int()), nil
}
return 0, typeError(fd, v.Type())
}
func toUint32(v reflect.Value, fd *desc.FieldDescriptor) (uint32, error) {
if v.Kind() == reflect.Uint32 {
return uint32(v.Uint()), nil
}
return 0, typeError(fd, v.Type())
}
func toFloat32(v reflect.Value, fd *desc.FieldDescriptor) (float32, error) {
if v.Kind() == reflect.Float32 {
return float32(v.Float()), nil
}
return 0, typeError(fd, v.Type())
}
func toInt64(v reflect.Value, fd *desc.FieldDescriptor) (int64, error) {
if v.Kind() == reflect.Int64 || v.Kind() == reflect.Int || v.Kind() == reflect.Int32 {
return v.Int(), nil
}
return 0, typeError(fd, v.Type())
}
func toUint64(v reflect.Value, fd *desc.FieldDescriptor) (uint64, error) {
if v.Kind() == reflect.Uint64 || v.Kind() == reflect.Uint || v.Kind() == reflect.Uint32 {
return v.Uint(), nil
}
return 0, typeError(fd, v.Type())
}
func toFloat64(v reflect.Value, fd *desc.FieldDescriptor) (float64, error) {
if v.Kind() == reflect.Float64 || v.Kind() == reflect.Float32 {
return v.Float(), nil
}
return 0, typeError(fd, v.Type())
}
func toBool(v reflect.Value, fd *desc.FieldDescriptor) (bool, error) {
if v.Kind() == reflect.Bool {
return v.Bool(), nil
}
return false, typeError(fd, v.Type())
}
func toBytes(v reflect.Value, fd *desc.FieldDescriptor) ([]byte, error) {
if v.Kind() == reflect.Slice && v.Type().Elem().Kind() == reflect.Uint8 {
return v.Bytes(), nil
}
return nil, typeError(fd, v.Type())
}
func toString(v reflect.Value, fd *desc.FieldDescriptor) (string, error) {
if v.Kind() == reflect.String {
return v.String(), nil
}
return "", typeError(fd, v.Type())
}
func typeError(fd *desc.FieldDescriptor, t reflect.Type) error {
return fmt.Errorf(
"%s field %s is not compatible with value of type %v",
getTypeString(fd), fd.GetFullyQualifiedName(), t)
}
func getTypeString(fd *desc.FieldDescriptor) string {
return strings.ToLower(fd.GetType().String())
}
func asMessage(v reflect.Value, fieldName string) (proto.Message, error) {
t := v.Type()
// we need a pointer to a struct that implements proto.Message
if t.Kind() != reflect.Ptr || t.Elem().Kind() != reflect.Struct || !t.Implements(typeOfProtoMessage) {
return nil, fmt.Errorf("message field %s requires is not compatible with value of type %v", fieldName, v.Type())
}
return v.Interface().(proto.Message), nil
}
// Reset resets this message to an empty message. It removes all values set in
// the message.
func (m *Message) Reset() {
for k := range m.values {
delete(m.values, k)
}
for k := range m.unknownFields {
delete(m.unknownFields, k)
}
}
// String returns this message rendered in compact text format.
func (m *Message) String() string {
b, err := m.MarshalText()
if err != nil {
panic(fmt.Sprintf("Failed to create string representation of message: %s", err.Error()))
}
return string(b)
}
// ProtoMessage is present to satisfy the proto.Message interface.
func (m *Message) ProtoMessage() {
}
// ConvertTo converts this dynamic message into the given message. This is
// shorthand for resetting then merging:
// target.Reset()
// m.MergeInto(target)
func (m *Message) ConvertTo(target proto.Message) error {
if err := m.checkType(target); err != nil {
return err
}
target.Reset()
return m.mergeInto(target, defaultDeterminism)
}
// ConvertToDeterministic converts this dynamic message into the given message.
// It is just like ConvertTo, but it attempts to produce deterministic results.
// That means that if the target is a generated message (not another dynamic
// message) and the current runtime is unaware of any fields or extensions that
// are present in m, they will be serialized into the target's unrecognized
// fields deterministically.
func (m *Message) ConvertToDeterministic(target proto.Message) error {
if err := m.checkType(target); err != nil {
return err
}
target.Reset()
return m.mergeInto(target, true)
}
// ConvertFrom converts the given message into this dynamic message. This is
// shorthand for resetting then merging:
// m.Reset()
// m.MergeFrom(target)
func (m *Message) ConvertFrom(target proto.Message) error {
if err := m.checkType(target); err != nil {
return err
}
m.Reset()
return m.mergeFrom(target)
}
// MergeInto merges this dynamic message into the given message. All field
// values in this message will be set on the given message. For map fields,
// entries are added to the given message (if the given message has existing
// values for like keys, they are overwritten). For slice fields, elements are
// added.
//
// If the given message has a different set of known fields, it is possible for
// some known fields in this message to be represented as unknown fields in the
// given message after merging, and vice versa.
func (m *Message) MergeInto(target proto.Message) error {
if err := m.checkType(target); err != nil {
return err
}
return m.mergeInto(target, defaultDeterminism)
}
// MergeIntoDeterministic merges this dynamic message into the given message.
// It is just like MergeInto, but it attempts to produce deterministic results.
// That means that if the target is a generated message (not another dynamic
// message) and the current runtime is unaware of any fields or extensions that
// are present in m, they will be serialized into the target's unrecognized
// fields deterministically.
func (m *Message) MergeIntoDeterministic(target proto.Message) error {
if err := m.checkType(target); err != nil {
return err
}
return m.mergeInto(target, true)
}
// MergeFrom merges the given message into this dynamic message. All field
// values in the given message will be set on this message. For map fields,
// entries are added to this message (if this message has existing values for
// like keys, they are overwritten). For slice fields, elements are added.
//
// If the given message has a different set of known fields, it is possible for
// some known fields in that message to be represented as unknown fields in this
// message after merging, and vice versa.
func (m *Message) MergeFrom(source proto.Message) error {
if err := m.checkType(source); err != nil {
return err
}
return m.mergeFrom(source)
}
// Merge implements the proto.Merger interface so that dynamic messages are
// compatible with the proto.Merge function. It delegates to MergeFrom but will
// panic on error as the proto.Merger interface doesn't allow for returning an
// error.
//
// Unlike nearly all other methods, this method can work if this message's type
// is not defined (such as instantiating the message without using NewMessage).
// This is strictly so that dynamic message's are compatible with the
// proto.Clone function, which instantiates a new message via reflection (thus
// its message descriptor will not be set) and than calls Merge.
func (m *Message) Merge(source proto.Message) {
if m.md == nil {
// To support proto.Clone, initialize the descriptor from the source.
if dm, ok := source.(*Message); ok {
m.md = dm.md
// also make sure the clone uses the same message factory and
// extensions and also knows about the same extra fields (if any)
m.mf = dm.mf
m.er = dm.er
m.extraFields = dm.extraFields
} else if md, err := desc.LoadMessageDescriptorForMessage(source); err != nil {
panic(err.Error())
} else {
m.md = md
}
}
if err := m.MergeFrom(source); err != nil {
panic(err.Error())
}
}
func (m *Message) checkType(target proto.Message) error {
if dm, ok := target.(*Message); ok {
if dm.md.GetFullyQualifiedName() != m.md.GetFullyQualifiedName() {
return fmt.Errorf("given message has wrong type: %q; expecting %q", dm.md.GetFullyQualifiedName(), m.md.GetFullyQualifiedName())
}
return nil
}
msgName := proto.MessageName(target)
if msgName != m.md.GetFullyQualifiedName() {
return fmt.Errorf("given message has wrong type: %q; expecting %q", msgName, m.md.GetFullyQualifiedName())
}
return nil
}
func (m *Message) mergeInto(pm proto.Message, deterministic bool) error {
if dm, ok := pm.(*Message); ok {
return dm.mergeFrom(m)
}
target := reflect.ValueOf(pm)
if target.Kind() == reflect.Ptr {
target = target.Elem()
}
// track tags for which the dynamic message has data but the given
// message doesn't know about it
unknownTags := map[int32]struct{}{}
for tag := range m.values {
unknownTags[tag] = struct{}{}
}
// check that we can successfully do the merge
structProps := proto.GetProperties(reflect.TypeOf(pm).Elem())
for _, prop := range structProps.Prop {
if prop.Tag == 0 {
continue // one-of or special field (such as XXX_unrecognized, etc.)
}
tag := int32(prop.Tag)
v, ok := m.values[tag]
if !ok {
continue
}
if unknownTags != nil {
delete(unknownTags, tag)
}
f := target.FieldByName(prop.Name)
ft := f.Type()
val := reflect.ValueOf(v)
if !canConvert(val, ft) {
return fmt.Errorf("cannot convert %v to %v", val.Type(), ft)
}
}
// check one-of fields
for _, oop := range structProps.OneofTypes {
prop := oop.Prop
tag := int32(prop.Tag)
v, ok := m.values[tag]
if !ok {
continue
}
if unknownTags != nil {
delete(unknownTags, tag)
}
stf, ok := oop.Type.Elem().FieldByName(prop.Name)
if !ok {
return fmt.Errorf("one-of field indicates struct field name %s, but type %v has no such field", prop.Name, oop.Type.Elem())
}
ft := stf.Type
val := reflect.ValueOf(v)
if !canConvert(val, ft) {
return fmt.Errorf("cannot convert %v to %v", val.Type(), ft)
}
}
// and check extensions, too
for tag, ext := range proto.RegisteredExtensions(pm) {
v, ok := m.values[tag]
if !ok {
continue
}
if unknownTags != nil {
delete(unknownTags, tag)
}
ft := reflect.TypeOf(ext.ExtensionType)
val := reflect.ValueOf(v)
if !canConvert(val, ft) {
return fmt.Errorf("cannot convert %v to %v", val.Type(), ft)
}
}
// now actually perform the merge
for _, prop := range structProps.Prop {
v, ok := m.values[int32(prop.Tag)]
if !ok {
continue
}
f := target.FieldByName(prop.Name)
if err := mergeVal(reflect.ValueOf(v), f, deterministic); err != nil {
return err
}
}
// merge one-ofs
for _, oop := range structProps.OneofTypes {
prop := oop.Prop
tag := int32(prop.Tag)
v, ok := m.values[tag]
if !ok {
continue
}
oov := reflect.New(oop.Type.Elem())
f := oov.Elem().FieldByName(prop.Name)
if err := mergeVal(reflect.ValueOf(v), f, deterministic); err != nil {
return err
}
target.Field(oop.Field).Set(oov)
}
// merge extensions, too
for tag, ext := range proto.RegisteredExtensions(pm) {
v, ok := m.values[tag]
if !ok {
continue
}
e := reflect.New(reflect.TypeOf(ext.ExtensionType)).Elem()
if err := mergeVal(reflect.ValueOf(v), e, deterministic); err != nil {
return err
}
if err := proto.SetExtension(pm, ext, e.Interface()); err != nil {
// shouldn't happen since we already checked that the extension type was compatible above
return err
}
}
// if we have fields that the given message doesn't know about, add to its unknown fields
if len(unknownTags) > 0 {
var b codec.Buffer
b.SetDeterministic(deterministic)
if deterministic {
// if we need to emit things deterministically, sort the
// extensions by their tag number
sortedUnknownTags := make([]int32, 0, len(unknownTags))
for tag := range unknownTags {
sortedUnknownTags = append(sortedUnknownTags, tag)
}
sort.Slice(sortedUnknownTags, func(i, j int) bool {
return sortedUnknownTags[i] < sortedUnknownTags[j]
})
for _, tag := range sortedUnknownTags {
fd := m.FindFieldDescriptor(tag)
if err := b.EncodeFieldValue(fd, m.values[tag]); err != nil {
return err
}
}
} else {
for tag := range unknownTags {
fd := m.FindFieldDescriptor(tag)
if err := b.EncodeFieldValue(fd, m.values[tag]); err != nil {
return err
}
}
}
internal.SetUnrecognized(pm, b.Bytes())
}
// finally, convey unknown fields into the given message by letting it unmarshal them
// (this will append to its unknown fields if not known; if somehow the given message recognizes
// a field even though the dynamic message did not, it will get correctly unmarshalled)
if unknownTags != nil && len(m.unknownFields) > 0 {
var b codec.Buffer
_ = m.marshalUnknownFields(&b)
_ = proto.UnmarshalMerge(b.Bytes(), pm)
}
return nil
}
func canConvert(src reflect.Value, target reflect.Type) bool {
if src.Kind() == reflect.Interface {
src = reflect.ValueOf(src.Interface())
}
srcType := src.Type()
// we allow convertible types instead of requiring exact types so that calling
// code can, for example, assign an enum constant to an enum field. In that case,
// one type is the enum type (a sub-type of int32) and the other may be the int32
// type. So we automatically do the conversion in that case.
if srcType.ConvertibleTo(target) {
return true
} else if target.Kind() == reflect.Ptr && srcType.ConvertibleTo(target.Elem()) {
return true
} else if target.Kind() == reflect.Slice {
if srcType.Kind() != reflect.Slice {
return false
}
et := target.Elem()
for i := 0; i < src.Len(); i++ {
if !canConvert(src.Index(i), et) {
return false
}
}
return true
} else if target.Kind() == reflect.Map {
if srcType.Kind() != reflect.Map {
return false
}
return canConvertMap(src, target)
} else if srcType == typeOfDynamicMessage && target.Implements(typeOfProtoMessage) {
z := reflect.Zero(target).Interface()
msgType := proto.MessageName(z.(proto.Message))
return msgType == src.Interface().(*Message).GetMessageDescriptor().GetFullyQualifiedName()
} else {
return false
}
}
func mergeVal(src, target reflect.Value, deterministic bool) error {
if src.Kind() == reflect.Interface && !src.IsNil() {
src = src.Elem()
}
srcType := src.Type()
targetType := target.Type()
if srcType.ConvertibleTo(targetType) {
if targetType.Implements(typeOfProtoMessage) && !target.IsNil() {
Merge(target.Interface().(proto.Message), src.Convert(targetType).Interface().(proto.Message))
} else {
target.Set(src.Convert(targetType))
}
} else if targetType.Kind() == reflect.Ptr && srcType.ConvertibleTo(targetType.Elem()) {
if !src.CanAddr() {
target.Set(reflect.New(targetType.Elem()))
target.Elem().Set(src.Convert(targetType.Elem()))
} else {
target.Set(src.Addr().Convert(targetType))
}
} else if targetType.Kind() == reflect.Slice {
l := target.Len()
newL := l + src.Len()
if target.Cap() < newL {
// expand capacity of the slice and copy
newSl := reflect.MakeSlice(targetType, newL, newL)
for i := 0; i < target.Len(); i++ {
newSl.Index(i).Set(target.Index(i))
}
target.Set(newSl)
} else {
target.SetLen(newL)
}
for i := 0; i < src.Len(); i++ {
dest := target.Index(l + i)
if dest.Kind() == reflect.Ptr {
dest.Set(reflect.New(dest.Type().Elem()))
}
if err := mergeVal(src.Index(i), dest, deterministic); err != nil {
return err
}
}
} else if targetType.Kind() == reflect.Map {
return mergeMapVal(src, target, targetType, deterministic)
} else if srcType == typeOfDynamicMessage && targetType.Implements(typeOfProtoMessage) {
dm := src.Interface().(*Message)
if target.IsNil() {
target.Set(reflect.New(targetType.Elem()))
}
m := target.Interface().(proto.Message)
if err := dm.mergeInto(m, deterministic); err != nil {
return err
}
} else {
return fmt.Errorf("cannot convert %v to %v", srcType, targetType)
}
return nil
}
func (m *Message) mergeFrom(pm proto.Message) error {
if dm, ok := pm.(*Message); ok {
// if given message is also a dynamic message, we merge differently
for tag, v := range dm.values {
fd := m.FindFieldDescriptor(tag)
if fd == nil {
fd = dm.FindFieldDescriptor(tag)
}
if err := mergeField(m, fd, v); err != nil {
return err
}
}
return nil
}
pmrv := reflect.ValueOf(pm)
if pmrv.IsNil() {
// nil is an empty message, so nothing to do
return nil
}
// check that we can successfully do the merge
src := pmrv.Elem()
values := map[*desc.FieldDescriptor]interface{}{}
props := proto.GetProperties(reflect.TypeOf(pm).Elem())
if props == nil {
return fmt.Errorf("could not determine message properties to merge for %v", reflect.TypeOf(pm).Elem())
}
// regular fields
for _, prop := range props.Prop {
if prop.Tag == 0 {
continue // one-of or special field (such as XXX_unrecognized, etc.)
}
fd := m.FindFieldDescriptor(int32(prop.Tag))
if fd == nil {
// Our descriptor has different fields than this message object. So
// try to reflect on the message object's fields.
md, err := desc.LoadMessageDescriptorForMessage(pm)
if err != nil {
return err
}
fd = md.FindFieldByNumber(int32(prop.Tag))
if fd == nil {
return fmt.Errorf("message descriptor %q did not contain field for tag %d (%q)", md.GetFullyQualifiedName(), prop.Tag, prop.Name)
}
}
rv := src.FieldByName(prop.Name)
if (rv.Kind() == reflect.Ptr || rv.Kind() == reflect.Slice) && rv.IsNil() {
continue
}
if v, err := validFieldValueForRv(fd, rv); err != nil {
return err
} else {
values[fd] = v
}
}
// one-of fields
for _, oop := range props.OneofTypes {
oov := src.Field(oop.Field).Elem()
if !oov.IsValid() || oov.Type() != oop.Type {
// this field is unset (in other words, one-of message field is not currently set to this option)
continue
}
prop := oop.Prop
rv := oov.Elem().FieldByName(prop.Name)
fd := m.FindFieldDescriptor(int32(prop.Tag))
if fd == nil {
// Our descriptor has different fields than this message object. So
// try to reflect on the message object's fields.
md, err := desc.LoadMessageDescriptorForMessage(pm)
if err != nil {
return err
}
fd = md.FindFieldByNumber(int32(prop.Tag))
if fd == nil {
return fmt.Errorf("message descriptor %q did not contain field for tag %d (%q in one-of %q)", md.GetFullyQualifiedName(), prop.Tag, prop.Name, src.Type().Field(oop.Field).Name)
}
}
if v, err := validFieldValueForRv(fd, rv); err != nil {
return err
} else {
values[fd] = v
}
}
// extension fields
rexts, _ := proto.ExtensionDescs(pm)
for _, ed := range rexts {
v, _ := proto.GetExtension(pm, ed)
if v == nil {
continue
}
if ed.ExtensionType == nil {
// unrecognized extension: we'll handle that below when we
// handle other unrecognized fields
continue
}
fd := m.er.FindExtension(m.md.GetFullyQualifiedName(), ed.Field)
if fd == nil {
var err error
if fd, err = desc.LoadFieldDescriptorForExtension(ed); err != nil {
return err
}
}
if v, err := validFieldValue(fd, v); err != nil {
return err
} else {
values[fd] = v
}
}
// now actually perform the merge
for fd, v := range values {
if err := mergeField(m, fd, v); err != nil {
return err
}
}
data := internal.GetUnrecognized(pm)
if len(data) > 0 {
// ignore any error returned: pulling in unknown fields is best-effort
_ = m.UnmarshalMerge(data)
}
return nil
}
// Validate checks that all required fields are present. It returns an error if any are absent.
func (m *Message) Validate() error {
missingFields := m.findMissingFields()
if len(missingFields) == 0 {
return nil
}
return fmt.Errorf("some required fields missing: %v", strings.Join(missingFields, ", "))
}
func (m *Message) findMissingFields() []string {
if m.md.IsProto3() {
// proto3 does not allow required fields
return nil
}
var missingFields []string
for _, fd := range m.md.GetFields() {
if fd.IsRequired() {
if _, ok := m.values[fd.GetNumber()]; !ok {
missingFields = append(missingFields, fd.GetName())
}
}
}
return missingFields
}
// ValidateRecursive checks that all required fields are present and also
// recursively validates all fields who are also messages. It returns an error
// if any required fields, in this message or nested within, are absent.
func (m *Message) ValidateRecursive() error {
return m.validateRecursive("")
}
func (m *Message) validateRecursive(prefix string) error {
if missingFields := m.findMissingFields(); len(missingFields) > 0 {
for i := range missingFields {
missingFields[i] = fmt.Sprintf("%s%s", prefix, missingFields[i])
}
return fmt.Errorf("some required fields missing: %v", strings.Join(missingFields, ", "))
}
for tag, fld := range m.values {
fd := m.FindFieldDescriptor(tag)
var chprefix string
var md *desc.MessageDescriptor
checkMsg := func(pm proto.Message) error {
var dm *Message
if d, ok := pm.(*Message); ok {
dm = d
} else if pm != nil {
dm = m.mf.NewDynamicMessage(md)
if err := dm.ConvertFrom(pm); err != nil {
return nil
}
}
if dm == nil {
return nil
}
if err := dm.validateRecursive(chprefix); err != nil {
return err
}
return nil
}
isMap := fd.IsMap()
if isMap && fd.GetMapValueType().GetMessageType() != nil {
md = fd.GetMapValueType().GetMessageType()
mp := fld.(map[interface{}]interface{})
for k, v := range mp {
chprefix = fmt.Sprintf("%s%s[%v].", prefix, getName(fd), k)
if err := checkMsg(v.(proto.Message)); err != nil {
return err
}
}
} else if !isMap && fd.GetMessageType() != nil {
md = fd.GetMessageType()
if fd.IsRepeated() {
sl := fld.([]interface{})
for i, v := range sl {
chprefix = fmt.Sprintf("%s%s[%d].", prefix, getName(fd), i)
if err := checkMsg(v.(proto.Message)); err != nil {
return err
}
}
} else {
chprefix = fmt.Sprintf("%s%s.", prefix, getName(fd))
if err := checkMsg(fld.(proto.Message)); err != nil {
return err
}
}
}
}
return nil
}
func getName(fd *desc.FieldDescriptor) string {
if fd.IsExtension() {
return fmt.Sprintf("(%s)", fd.GetFullyQualifiedName())
} else {
return fd.GetName()
}
}
// knownFieldTags return tags of present and recognized fields, in sorted order.
func (m *Message) knownFieldTags() []int {
if len(m.values) == 0 {
return []int(nil)
}
keys := make([]int, len(m.values))
i := 0
for k := range m.values {
keys[i] = int(k)
i++
}
sort.Ints(keys)
return keys
}
// allKnownFieldTags return tags of present and recognized fields, including
// those that are unset, in sorted order. This only includes extensions that are
// present. Known but not-present extensions are not included in the returned
// set of tags.
func (m *Message) allKnownFieldTags() []int {
fds := m.md.GetFields()
keys := make([]int, 0, len(fds)+len(m.extraFields))
for k := range m.values {
keys = append(keys, int(k))
}
// also include known fields that are not present
for _, fd := range fds {
if _, ok := m.values[fd.GetNumber()]; !ok {
keys = append(keys, int(fd.GetNumber()))
}
}
for _, fd := range m.extraFields {
if !fd.IsExtension() { // skip extensions that are not present
if _, ok := m.values[fd.GetNumber()]; !ok {
keys = append(keys, int(fd.GetNumber()))
}
}
}
sort.Ints(keys)
return keys
}
// unknownFieldTags return tags of present but unrecognized fields, in sorted order.
func (m *Message) unknownFieldTags() []int {
if len(m.unknownFields) == 0 {
return []int(nil)
}
keys := make([]int, len(m.unknownFields))
i := 0
for k := range m.unknownFields {
keys[i] = int(k)
i++
}
sort.Ints(keys)
return keys
}