vendor/github.com/jhump/protoreflect/dynamic/binary.go - voltha-openolt-adapter - Gitiles

 package dynamic

 // Binary serialization and de-serialization for dynamic messages

 import (
 	"fmt"
 	"github.com/golang/protobuf/proto"
 	"github.com/jhump/protoreflect/codec"
 	"io"
 )

 // defaultDeterminism, if true, will mean that calls to Marshal will produce
 // deterministic output. This is used to make the output of proto.Marshal(...)
 // deterministic (since there is no way to have that convey determinism intent).
 // **This is only used from tests.**
 var defaultDeterminism = false

 // Marshal serializes this message to bytes, returning an error if the operation
 // fails. The resulting bytes are in the standard protocol buffer binary format.
 func (m *Message) Marshal() ([]byte, error) {
 	var b codec.Buffer
 	b.SetDeterministic(defaultDeterminism)
 	if err := m.marshal(&b); err != nil {
 		return nil, err
 	}
 	return b.Bytes(), nil
 }

 // MarshalAppend behaves exactly the same as Marshal, except instead of allocating a
 // new byte slice to marshal into, it uses the provided byte slice. The backing array
 // for the returned byte slice *may* be the same as the one that was passed in, but
 // it's not guaranteed as a new backing array will automatically be allocated if
 // more bytes need to be written than the provided buffer has capacity for.
 func (m *Message) MarshalAppend(b []byte) ([]byte, error) {
 	codedBuf := codec.NewBuffer(b)
 	codedBuf.SetDeterministic(defaultDeterminism)
 	if err := m.marshal(codedBuf); err != nil {
 		return nil, err
 	}
 	return codedBuf.Bytes(), nil
 }

 // MarshalDeterministic serializes this message to bytes in a deterministic way,
 // returning an error if the operation fails. This differs from Marshal in that
 // map keys will be sorted before serializing to bytes. The protobuf spec does
 // not define ordering for map entries, so Marshal will use standard Go map
 // iteration order (which will be random). But for cases where determinism is
 // more important than performance, use this method instead.
 func (m *Message) MarshalDeterministic() ([]byte, error) {
 	var b codec.Buffer
 	b.SetDeterministic(true)
 	if err := m.marshal(&b); err != nil {
 		return nil, err
 	}
 	return b.Bytes(), nil
 }

 // MarshalAppendDeterministic behaves exactly the same as MarshalDeterministic,
 // except instead of allocating a new byte slice to marshal into, it uses the
 // provided byte slice. The backing array for the returned byte slice *may* be
 // the same as the one that was passed in, but it's not guaranteed as a new
 // backing array will automatically be allocated if more bytes need to be written
 // than the provided buffer has capacity for.
 func (m *Message) MarshalAppendDeterministic(b []byte) ([]byte, error) {
 	codedBuf := codec.NewBuffer(b)
 	codedBuf.SetDeterministic(true)
 	if err := m.marshal(codedBuf); err != nil {
 		return nil, err
 	}
 	return codedBuf.Bytes(), nil
 }

 func (m *Message) marshal(b *codec.Buffer) error {
 	if err := m.marshalKnownFields(b); err != nil {
 		return err
 	}
 	return m.marshalUnknownFields(b)
 }

 func (m *Message) marshalKnownFields(b *codec.Buffer) error {
 	for _, tag := range m.knownFieldTags() {
 		itag := int32(tag)
 		val := m.values[itag]
 		fd := m.FindFieldDescriptor(itag)
 		if fd == nil {
 			panic(fmt.Sprintf("Couldn't find field for tag %d", itag))
 		}
 		if err := b.EncodeFieldValue(fd, val); err != nil {
 			return err
 		}
 	}
 	return nil
 }

 func (m *Message) marshalUnknownFields(b *codec.Buffer) error {
 	for _, tag := range m.unknownFieldTags() {
 		itag := int32(tag)
 		sl := m.unknownFields[itag]
 		for _, u := range sl {
 			if err := b.EncodeTagAndWireType(itag, u.Encoding); err != nil {
 				return err
 			}
 			switch u.Encoding {
 			case proto.WireBytes:
 				if err := b.EncodeRawBytes(u.Contents); err != nil {
 					return err
 				}
 			case proto.WireStartGroup:
 				_, _ = b.Write(u.Contents)
 				if err := b.EncodeTagAndWireType(itag, proto.WireEndGroup); err != nil {
 					return err
 				}
 			case proto.WireFixed32:
 				if err := b.EncodeFixed32(u.Value); err != nil {
 					return err
 				}
 			case proto.WireFixed64:
 				if err := b.EncodeFixed64(u.Value); err != nil {
 					return err
 				}
 			case proto.WireVarint:
 				if err := b.EncodeVarint(u.Value); err != nil {
 					return err
 				}
 			default:
 				return codec.ErrBadWireType
 			}
 		}
 	}
 	return nil
 }

 // Unmarshal de-serializes the message that is present in the given bytes into
 // this message. It first resets the current message. It returns an error if the
 // given bytes do not contain a valid encoding of this message type.
 func (m *Message) Unmarshal(b []byte) error {
 	m.Reset()
 	if err := m.UnmarshalMerge(b); err != nil {
 		return err
 	}
 	return m.Validate()
 }

 // UnmarshalMerge de-serializes the message that is present in the given bytes
 // into this message. Unlike Unmarshal, it does not first reset the message,
 // instead merging the data in the given bytes into the existing data in this
 // message.
 func (m *Message) UnmarshalMerge(b []byte) error {
 	return m.unmarshal(codec.NewBuffer(b), false)
 }

 func (m *Message) unmarshal(buf *codec.Buffer, isGroup bool) error {
 	for !buf.EOF() {
 		fd, val, err := buf.DecodeFieldValue(m.FindFieldDescriptor, m.mf)
 		if err != nil {
 			if err == codec.ErrWireTypeEndGroup {
 				if isGroup {
 					// finished parsing group
 					return nil
 				}
 				return codec.ErrBadWireType
 			}
 			return err
 		}

 		if fd == nil {
 			if m.unknownFields == nil {
 				m.unknownFields = map[int32][]UnknownField{}
 			}
 			uv := val.(codec.UnknownField)
 			u := UnknownField{
 				Encoding: uv.Encoding,
 				Value:    uv.Value,
 				Contents: uv.Contents,
 			}
 			m.unknownFields[uv.Tag] = append(m.unknownFields[uv.Tag], u)
 		} else if err := mergeField(m, fd, val); err != nil {
 			return err
 		}
 	}
 	if isGroup {
 		return io.ErrUnexpectedEOF
 	}
 	return nil
 }
	package dynamic

	// Binary serialization and de-serialization for dynamic messages

	import (
	"fmt"
	"github.com/golang/protobuf/proto"
	"github.com/jhump/protoreflect/codec"
	"io"
	)

	// defaultDeterminism, if true, will mean that calls to Marshal will produce
	// deterministic output. This is used to make the output of proto.Marshal(...)
	// deterministic (since there is no way to have that convey determinism intent).
	// This is only used from tests.
	var defaultDeterminism = false

	// Marshal serializes this message to bytes, returning an error if the operation
	// fails. The resulting bytes are in the standard protocol buffer binary format.
	func (m *Message) Marshal() ([]byte, error) {
	var b codec.Buffer
	b.SetDeterministic(defaultDeterminism)
	if err := m.marshal(&b); err != nil {
	return nil, err
	}
	return b.Bytes(), nil
	}

	// MarshalAppend behaves exactly the same as Marshal, except instead of allocating a
	// new byte slice to marshal into, it uses the provided byte slice. The backing array
	// for the returned byte slice may be the same as the one that was passed in, but
	// it's not guaranteed as a new backing array will automatically be allocated if
	// more bytes need to be written than the provided buffer has capacity for.
	func (m *Message) MarshalAppend(b []byte) ([]byte, error) {
	codedBuf := codec.NewBuffer(b)
	codedBuf.SetDeterministic(defaultDeterminism)
	if err := m.marshal(codedBuf); err != nil {
	return nil, err
	}
	return codedBuf.Bytes(), nil
	}

	// MarshalDeterministic serializes this message to bytes in a deterministic way,
	// returning an error if the operation fails. This differs from Marshal in that
	// map keys will be sorted before serializing to bytes. The protobuf spec does
	// not define ordering for map entries, so Marshal will use standard Go map
	// iteration order (which will be random). But for cases where determinism is
	// more important than performance, use this method instead.
	func (m *Message) MarshalDeterministic() ([]byte, error) {
	var b codec.Buffer
	b.SetDeterministic(true)
	if err := m.marshal(&b); err != nil {
	return nil, err
	}
	return b.Bytes(), nil
	}

	// MarshalAppendDeterministic behaves exactly the same as MarshalDeterministic,
	// except instead of allocating a new byte slice to marshal into, it uses the
	// provided byte slice. The backing array for the returned byte slice may be
	// the same as the one that was passed in, but it's not guaranteed as a new
	// backing array will automatically be allocated if more bytes need to be written
	// than the provided buffer has capacity for.
	func (m *Message) MarshalAppendDeterministic(b []byte) ([]byte, error) {
	codedBuf := codec.NewBuffer(b)
	codedBuf.SetDeterministic(true)
	if err := m.marshal(codedBuf); err != nil {
	return nil, err
	}
	return codedBuf.Bytes(), nil
	}

	func (m Message) marshal(b codec.Buffer) error {
	if err := m.marshalKnownFields(b); err != nil {
	return err
	}
	return m.marshalUnknownFields(b)
	}

	func (m Message) marshalKnownFields(b codec.Buffer) error {
	for _, tag := range m.knownFieldTags() {
	itag := int32(tag)
	val := m.values[itag]
	fd := m.FindFieldDescriptor(itag)
	if fd == nil {
	panic(fmt.Sprintf("Couldn't find field for tag %d", itag))
	}
	if err := b.EncodeFieldValue(fd, val); err != nil {
	return err
	}
	}
	return nil
	}

	func (m Message) marshalUnknownFields(b codec.Buffer) error {
	for _, tag := range m.unknownFieldTags() {
	itag := int32(tag)
	sl := m.unknownFields[itag]
	for _, u := range sl {
	if err := b.EncodeTagAndWireType(itag, u.Encoding); err != nil {
	return err
	}
	switch u.Encoding {
	case proto.WireBytes:
	if err := b.EncodeRawBytes(u.Contents); err != nil {
	return err
	}
	case proto.WireStartGroup:
	_, _ = b.Write(u.Contents)
	if err := b.EncodeTagAndWireType(itag, proto.WireEndGroup); err != nil {
	return err
	}
	case proto.WireFixed32:
	if err := b.EncodeFixed32(u.Value); err != nil {
	return err
	}
	case proto.WireFixed64:
	if err := b.EncodeFixed64(u.Value); err != nil {
	return err
	}
	case proto.WireVarint:
	if err := b.EncodeVarint(u.Value); err != nil {
	return err
	}
	default:
	return codec.ErrBadWireType
	}
	}
	}
	return nil
	}

	// Unmarshal de-serializes the message that is present in the given bytes into
	// this message. It first resets the current message. It returns an error if the
	// given bytes do not contain a valid encoding of this message type.
	func (m *Message) Unmarshal(b []byte) error {
	m.Reset()
	if err := m.UnmarshalMerge(b); err != nil {
	return err
	}
	return m.Validate()
	}

	// UnmarshalMerge de-serializes the message that is present in the given bytes
	// into this message. Unlike Unmarshal, it does not first reset the message,
	// instead merging the data in the given bytes into the existing data in this
	// message.
	func (m *Message) UnmarshalMerge(b []byte) error {
	return m.unmarshal(codec.NewBuffer(b), false)
	}

	func (m Message) unmarshal(buf codec.Buffer, isGroup bool) error {
	for !buf.EOF() {
	fd, val, err := buf.DecodeFieldValue(m.FindFieldDescriptor, m.mf)
	if err != nil {
	if err == codec.ErrWireTypeEndGroup {
	if isGroup {
	// finished parsing group
	return nil
	}
	return codec.ErrBadWireType
	}
	return err
	}

	if fd == nil {
	if m.unknownFields == nil {
	m.unknownFields = map[int32][]UnknownField{}
	}
	uv := val.(codec.UnknownField)
	u := UnknownField{
	Encoding: uv.Encoding,
	Value: uv.Value,
	Contents: uv.Contents,
	}
	m.unknownFields[uv.Tag] = append(m.unknownFields[uv.Tag], u)
	} else if err := mergeField(m, fd, val); err != nil {
	return err
	}
	}
	if isGroup {
	return io.ErrUnexpectedEOF
	}
	return nil
	}