vendor/google.golang.org/protobuf/encoding/prototext/decode.go - bbsim - Gitiles

 // Copyright 2018 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package prototext

 import (
 	"fmt"
 	"strings"
 	"unicode/utf8"

 	"google.golang.org/protobuf/internal/encoding/messageset"
 	"google.golang.org/protobuf/internal/encoding/text"
 	"google.golang.org/protobuf/internal/errors"
 	"google.golang.org/protobuf/internal/fieldnum"
 	"google.golang.org/protobuf/internal/flags"
 	"google.golang.org/protobuf/internal/pragma"
 	"google.golang.org/protobuf/internal/set"
 	"google.golang.org/protobuf/internal/strs"
 	"google.golang.org/protobuf/proto"
 	pref "google.golang.org/protobuf/reflect/protoreflect"
 	"google.golang.org/protobuf/reflect/protoregistry"
 )

 // Unmarshal reads the given []byte into the given proto.Message.
 func Unmarshal(b []byte, m proto.Message) error {
 	return UnmarshalOptions{}.Unmarshal(b, m)
 }

 // UnmarshalOptions is a configurable textproto format unmarshaler.
 type UnmarshalOptions struct {
 	pragma.NoUnkeyedLiterals

 	// AllowPartial accepts input for messages that will result in missing
 	// required fields. If AllowPartial is false (the default), Unmarshal will
 	// return error if there are any missing required fields.
 	AllowPartial bool

 	// DiscardUnknown specifies whether to ignore unknown fields when parsing.
 	// An unknown field is any field whose field name or field number does not
 	// resolve to any known or extension field in the message.
 	// By default, unmarshal rejects unknown fields as an error.
 	DiscardUnknown bool

 	// Resolver is used for looking up types when unmarshaling
 	// google.protobuf.Any messages or extension fields.
 	// If nil, this defaults to using protoregistry.GlobalTypes.
 	Resolver interface {
 		protoregistry.MessageTypeResolver
 		protoregistry.ExtensionTypeResolver
 	}
 }

 // Unmarshal reads the given []byte and populates the given proto.Message using options in
 // UnmarshalOptions object.
 func (o UnmarshalOptions) Unmarshal(b []byte, m proto.Message) error {
 	proto.Reset(m)

 	if o.Resolver == nil {
 		o.Resolver = protoregistry.GlobalTypes
 	}

 	dec := decoder{text.NewDecoder(b), o}
 	if err := dec.unmarshalMessage(m.ProtoReflect(), false); err != nil {
 		return err
 	}
 	if o.AllowPartial {
 		return nil
 	}
 	return proto.CheckInitialized(m)
 }

 type decoder struct {
 	*text.Decoder
 	opts UnmarshalOptions
 }

 // newError returns an error object with position info.
 func (d decoder) newError(pos int, f string, x ...interface{}) error {
 	line, column := d.Position(pos)
 	head := fmt.Sprintf("(line %d:%d): ", line, column)
 	return errors.New(head+f, x...)
 }

 // unexpectedTokenError returns a syntax error for the given unexpected token.
 func (d decoder) unexpectedTokenError(tok text.Token) error {
 	return d.syntaxError(tok.Pos(), "unexpected token: %s", tok.RawString())
 }

 // syntaxError returns a syntax error for given position.
 func (d decoder) syntaxError(pos int, f string, x ...interface{}) error {
 	line, column := d.Position(pos)
 	head := fmt.Sprintf("syntax error (line %d:%d): ", line, column)
 	return errors.New(head+f, x...)
 }

 // unmarshalMessage unmarshals into the given protoreflect.Message.
 func (d decoder) unmarshalMessage(m pref.Message, checkDelims bool) error {
 	messageDesc := m.Descriptor()
 	if !flags.ProtoLegacy && messageset.IsMessageSet(messageDesc) {
 		return errors.New("no support for proto1 MessageSets")
 	}

 	if messageDesc.FullName() == "google.protobuf.Any" {
 		return d.unmarshalAny(m, checkDelims)
 	}

 	if checkDelims {
 		tok, err := d.Read()
 		if err != nil {
 			return err
 		}

 		if tok.Kind() != text.MessageOpen {
 			return d.unexpectedTokenError(tok)
 		}
 	}

 	var seenNums set.Ints
 	var seenOneofs set.Ints
 	fieldDescs := messageDesc.Fields()

 	for {
 		// Read field name.
 		tok, err := d.Read()
 		if err != nil {
 			return err
 		}
 		switch typ := tok.Kind(); typ {
 		case text.Name:
 			// Continue below.
 		case text.EOF:
 			if checkDelims {
 				return text.ErrUnexpectedEOF
 			}
 			return nil
 		default:
 			if checkDelims && typ == text.MessageClose {
 				return nil
 			}
 			return d.unexpectedTokenError(tok)
 		}

 		// Resolve the field descriptor.
 		var name pref.Name
 		var fd pref.FieldDescriptor
 		var xt pref.ExtensionType
 		var xtErr error
 		var isFieldNumberName bool

 		switch tok.NameKind() {
 		case text.IdentName:
 			name = pref.Name(tok.IdentName())
 			fd = fieldDescs.ByName(name)
 			if fd == nil {
 				// The proto name of a group field is in all lowercase,
 				// while the textproto field name is the group message name.
 				gd := fieldDescs.ByName(pref.Name(strings.ToLower(string(name))))
 				if gd != nil && gd.Kind() == pref.GroupKind && gd.Message().Name() == name {
 					fd = gd
 				}
 			} else if fd.Kind() == pref.GroupKind && fd.Message().Name() != name {
 				fd = nil // reset since field name is actually the message name
 			}

 		case text.TypeName:
 			// Handle extensions only. This code path is not for Any.
 			xt, xtErr = d.findExtension(pref.FullName(tok.TypeName()))

 		case text.FieldNumber:
 			isFieldNumberName = true
 			num := pref.FieldNumber(tok.FieldNumber())
 			if !num.IsValid() {
 				return d.newError(tok.Pos(), "invalid field number: %d", num)
 			}
 			fd = fieldDescs.ByNumber(num)
 			if fd == nil {
 				xt, xtErr = d.opts.Resolver.FindExtensionByNumber(messageDesc.FullName(), num)
 			}
 		}

 		if xt != nil {
 			fd = xt.TypeDescriptor()
 			if !messageDesc.ExtensionRanges().Has(fd.Number()) || fd.ContainingMessage().FullName() != messageDesc.FullName() {
 				return d.newError(tok.Pos(), "message %v cannot be extended by %v", messageDesc.FullName(), fd.FullName())
 			}
 		} else if xtErr != nil && xtErr != protoregistry.NotFound {
 			return d.newError(tok.Pos(), "unable to resolve [%s]: %v", tok.RawString(), xtErr)
 		}
 		if flags.ProtoLegacy {
 			if fd != nil && fd.IsWeak() && fd.Message().IsPlaceholder() {
 				fd = nil // reset since the weak reference is not linked in
 			}
 		}

 		// Handle unknown fields.
 		if fd == nil {
 			if d.opts.DiscardUnknown || messageDesc.ReservedNames().Has(name) {
 				d.skipValue()
 				continue
 			}
 			return d.newError(tok.Pos(), "unknown field: %v", tok.RawString())
 		}

 		// Handle fields identified by field number.
 		if isFieldNumberName {
 			// TODO: Add an option to permit parsing field numbers.
 			//
 			// This requires careful thought as the MarshalOptions.EmitUnknown
 			// option allows formatting unknown fields as the field number and the
 			// best-effort textual representation of the field value.  In that case,
 			// it may not be possible to unmarshal the value from a parser that does
 			// have information about the unknown field.
 			return d.newError(tok.Pos(), "cannot specify field by number: %v", tok.RawString())
 		}

 		switch {
 		case fd.IsList():
 			kind := fd.Kind()
 			if kind != pref.MessageKind && kind != pref.GroupKind && !tok.HasSeparator() {
 				return d.syntaxError(tok.Pos(), "missing field separator :")
 			}

 			list := m.Mutable(fd).List()
 			if err := d.unmarshalList(fd, list); err != nil {
 				return err
 			}

 		case fd.IsMap():
 			mmap := m.Mutable(fd).Map()
 			if err := d.unmarshalMap(fd, mmap); err != nil {
 				return err
 			}

 		default:
 			kind := fd.Kind()
 			if kind != pref.MessageKind && kind != pref.GroupKind && !tok.HasSeparator() {
 				return d.syntaxError(tok.Pos(), "missing field separator :")
 			}

 			// If field is a oneof, check if it has already been set.
 			if od := fd.ContainingOneof(); od != nil {
 				idx := uint64(od.Index())
 				if seenOneofs.Has(idx) {
 					return d.newError(tok.Pos(), "error parsing %q, oneof %v is already set", tok.RawString(), od.FullName())
 				}
 				seenOneofs.Set(idx)
 			}

 			num := uint64(fd.Number())
 			if seenNums.Has(num) {
 				return d.newError(tok.Pos(), "non-repeated field %q is repeated", tok.RawString())
 			}

 			if err := d.unmarshalSingular(fd, m); err != nil {
 				return err
 			}
 			seenNums.Set(num)
 		}
 	}

 	return nil
 }

 // findExtension returns protoreflect.ExtensionType from the Resolver if found.
 func (d decoder) findExtension(xtName pref.FullName) (pref.ExtensionType, error) {
 	xt, err := d.opts.Resolver.FindExtensionByName(xtName)
 	if err == nil {
 		return xt, nil
 	}
 	return messageset.FindMessageSetExtension(d.opts.Resolver, xtName)
 }

 // unmarshalSingular unmarshals a non-repeated field value specified by the
 // given FieldDescriptor.
 func (d decoder) unmarshalSingular(fd pref.FieldDescriptor, m pref.Message) error {
 	var val pref.Value
 	var err error
 	switch fd.Kind() {
 	case pref.MessageKind, pref.GroupKind:
 		val = m.NewField(fd)
 		err = d.unmarshalMessage(val.Message(), true)
 	default:
 		val, err = d.unmarshalScalar(fd)
 	}
 	if err == nil {
 		m.Set(fd, val)
 	}
 	return err
 }

 // unmarshalScalar unmarshals a scalar/enum protoreflect.Value specified by the
 // given FieldDescriptor.
 func (d decoder) unmarshalScalar(fd pref.FieldDescriptor) (pref.Value, error) {
 	tok, err := d.Read()
 	if err != nil {
 		return pref.Value{}, err
 	}

 	if tok.Kind() != text.Scalar {
 		return pref.Value{}, d.unexpectedTokenError(tok)
 	}

 	kind := fd.Kind()
 	switch kind {
 	case pref.BoolKind:
 		if b, ok := tok.Bool(); ok {
 			return pref.ValueOfBool(b), nil
 		}

 	case pref.Int32Kind, pref.Sint32Kind, pref.Sfixed32Kind:
 		if n, ok := tok.Int32(); ok {
 			return pref.ValueOfInt32(n), nil
 		}

 	case pref.Int64Kind, pref.Sint64Kind, pref.Sfixed64Kind:
 		if n, ok := tok.Int64(); ok {
 			return pref.ValueOfInt64(n), nil
 		}

 	case pref.Uint32Kind, pref.Fixed32Kind:
 		if n, ok := tok.Uint32(); ok {
 			return pref.ValueOfUint32(n), nil
 		}

 	case pref.Uint64Kind, pref.Fixed64Kind:
 		if n, ok := tok.Uint64(); ok {
 			return pref.ValueOfUint64(n), nil
 		}

 	case pref.FloatKind:
 		if n, ok := tok.Float32(); ok {
 			return pref.ValueOfFloat32(n), nil
 		}

 	case pref.DoubleKind:
 		if n, ok := tok.Float64(); ok {
 			return pref.ValueOfFloat64(n), nil
 		}

 	case pref.StringKind:
 		if s, ok := tok.String(); ok {
 			if strs.EnforceUTF8(fd) && !utf8.ValidString(s) {
 				return pref.Value{}, d.newError(tok.Pos(), "contains invalid UTF-8")
 			}
 			return pref.ValueOfString(s), nil
 		}

 	case pref.BytesKind:
 		if b, ok := tok.String(); ok {
 			return pref.ValueOfBytes([]byte(b)), nil
 		}

 	case pref.EnumKind:
 		if lit, ok := tok.Enum(); ok {
 			// Lookup EnumNumber based on name.
 			if enumVal := fd.Enum().Values().ByName(pref.Name(lit)); enumVal != nil {
 				return pref.ValueOfEnum(enumVal.Number()), nil
 			}
 		}
 		if num, ok := tok.Int32(); ok {
 			return pref.ValueOfEnum(pref.EnumNumber(num)), nil
 		}

 	default:
 		panic(fmt.Sprintf("invalid scalar kind %v", kind))
 	}

 	return pref.Value{}, d.newError(tok.Pos(), "invalid value for %v type: %v", kind, tok.RawString())
 }

 // unmarshalList unmarshals into given protoreflect.List. A list value can
 // either be in [] syntax or simply just a single scalar/message value.
 func (d decoder) unmarshalList(fd pref.FieldDescriptor, list pref.List) error {
 	tok, err := d.Peek()
 	if err != nil {
 		return err
 	}

 	switch fd.Kind() {
 	case pref.MessageKind, pref.GroupKind:
 		switch tok.Kind() {
 		case text.ListOpen:
 			d.Read()
 			for {
 				tok, err := d.Peek()
 				if err != nil {
 					return err
 				}

 				switch tok.Kind() {
 				case text.ListClose:
 					d.Read()
 					return nil
 				case text.MessageOpen:
 					pval := list.NewElement()
 					if err := d.unmarshalMessage(pval.Message(), true); err != nil {
 						return err
 					}
 					list.Append(pval)
 				default:
 					return d.unexpectedTokenError(tok)
 				}
 			}

 		case text.MessageOpen:
 			pval := list.NewElement()
 			if err := d.unmarshalMessage(pval.Message(), true); err != nil {
 				return err
 			}
 			list.Append(pval)
 			return nil
 		}

 	default:
 		switch tok.Kind() {
 		case text.ListOpen:
 			d.Read()
 			for {
 				tok, err := d.Peek()
 				if err != nil {
 					return err
 				}

 				switch tok.Kind() {
 				case text.ListClose:
 					d.Read()
 					return nil
 				case text.Scalar:
 					pval, err := d.unmarshalScalar(fd)
 					if err != nil {
 						return err
 					}
 					list.Append(pval)
 				default:
 					return d.unexpectedTokenError(tok)
 				}
 			}

 		case text.Scalar:
 			pval, err := d.unmarshalScalar(fd)
 			if err != nil {
 				return err
 			}
 			list.Append(pval)
 			return nil
 		}
 	}

 	return d.unexpectedTokenError(tok)
 }

 // unmarshalMap unmarshals into given protoreflect.Map. A map value is a
 // textproto message containing {key: <kvalue>, value: <mvalue>}.
 func (d decoder) unmarshalMap(fd pref.FieldDescriptor, mmap pref.Map) error {
 	// Determine ahead whether map entry is a scalar type or a message type in
 	// order to call the appropriate unmarshalMapValue func inside
 	// unmarshalMapEntry.
 	var unmarshalMapValue func() (pref.Value, error)
 	switch fd.MapValue().Kind() {
 	case pref.MessageKind, pref.GroupKind:
 		unmarshalMapValue = func() (pref.Value, error) {
 			pval := mmap.NewValue()
 			if err := d.unmarshalMessage(pval.Message(), true); err != nil {
 				return pref.Value{}, err
 			}
 			return pval, nil
 		}
 	default:
 		unmarshalMapValue = func() (pref.Value, error) {
 			return d.unmarshalScalar(fd.MapValue())
 		}
 	}

 	tok, err := d.Read()
 	if err != nil {
 		return err
 	}
 	switch tok.Kind() {
 	case text.MessageOpen:
 		return d.unmarshalMapEntry(fd, mmap, unmarshalMapValue)

 	case text.ListOpen:
 		for {
 			tok, err := d.Read()
 			if err != nil {
 				return err
 			}
 			switch tok.Kind() {
 			case text.ListClose:
 				return nil
 			case text.MessageOpen:
 				if err := d.unmarshalMapEntry(fd, mmap, unmarshalMapValue); err != nil {
 					return err
 				}
 			default:
 				return d.unexpectedTokenError(tok)
 			}
 		}

 	default:
 		return d.unexpectedTokenError(tok)
 	}
 }

 // unmarshalMap unmarshals into given protoreflect.Map. A map value is a
 // textproto message containing {key: <kvalue>, value: <mvalue>}.
 func (d decoder) unmarshalMapEntry(fd pref.FieldDescriptor, mmap pref.Map, unmarshalMapValue func() (pref.Value, error)) error {
 	var key pref.MapKey
 	var pval pref.Value
 Loop:
 	for {
 		// Read field name.
 		tok, err := d.Read()
 		if err != nil {
 			return err
 		}
 		switch tok.Kind() {
 		case text.Name:
 			if tok.NameKind() != text.IdentName {
 				if !d.opts.DiscardUnknown {
 					return d.newError(tok.Pos(), "unknown map entry field %q", tok.RawString())
 				}
 				d.skipValue()
 				continue Loop
 			}
 			// Continue below.
 		case text.MessageClose:
 			break Loop
 		default:
 			return d.unexpectedTokenError(tok)
 		}

 		name := tok.IdentName()
 		switch name {
 		case "key":
 			if !tok.HasSeparator() {
 				return d.syntaxError(tok.Pos(), "missing field separator :")
 			}
 			if key.IsValid() {
 				return d.newError(tok.Pos(), `map entry "key" cannot be repeated`)
 			}
 			val, err := d.unmarshalScalar(fd.MapKey())
 			if err != nil {
 				return err
 			}
 			key = val.MapKey()

 		case "value":
 			if kind := fd.MapValue().Kind(); (kind != pref.MessageKind) && (kind != pref.GroupKind) {
 				if !tok.HasSeparator() {
 					return d.syntaxError(tok.Pos(), "missing field separator :")
 				}
 			}
 			if pval.IsValid() {
 				return d.newError(tok.Pos(), `map entry "value" cannot be repeated`)
 			}
 			pval, err = unmarshalMapValue()
 			if err != nil {
 				return err
 			}

 		default:
 			if !d.opts.DiscardUnknown {
 				return d.newError(tok.Pos(), "unknown map entry field %q", name)
 			}
 			d.skipValue()
 		}
 	}

 	if !key.IsValid() {
 		key = fd.MapKey().Default().MapKey()
 	}
 	if !pval.IsValid() {
 		switch fd.MapValue().Kind() {
 		case pref.MessageKind, pref.GroupKind:
 			// If value field is not set for message/group types, construct an
 			// empty one as default.
 			pval = mmap.NewValue()
 		default:
 			pval = fd.MapValue().Default()
 		}
 	}
 	mmap.Set(key, pval)
 	return nil
 }

 // unmarshalAny unmarshals an Any textproto. It can either be in expanded form
 // or non-expanded form.
 func (d decoder) unmarshalAny(m pref.Message, checkDelims bool) error {
 	var typeURL string
 	var bValue []byte

 	// hasFields tracks which valid fields have been seen in the loop below in
 	// order to flag an error if there are duplicates or conflicts. It may
 	// contain the strings "type_url", "value" and "expanded".  The literal
 	// "expanded" is used to indicate that the expanded form has been
 	// encountered already.
 	hasFields := map[string]bool{}

 	if checkDelims {
 		tok, err := d.Read()
 		if err != nil {
 			return err
 		}

 		if tok.Kind() != text.MessageOpen {
 			return d.unexpectedTokenError(tok)
 		}
 	}

 Loop:
 	for {
 		// Read field name. Can only have 3 possible field names, i.e. type_url,
 		// value and type URL name inside [].
 		tok, err := d.Read()
 		if err != nil {
 			return err
 		}
 		if typ := tok.Kind(); typ != text.Name {
 			if checkDelims {
 				if typ == text.MessageClose {
 					break Loop
 				}
 			} else if typ == text.EOF {
 				break Loop
 			}
 			return d.unexpectedTokenError(tok)
 		}

 		switch tok.NameKind() {
 		case text.IdentName:
 			// Both type_url and value fields require field separator :.
 			if !tok.HasSeparator() {
 				return d.syntaxError(tok.Pos(), "missing field separator :")
 			}

 			switch tok.IdentName() {
 			case "type_url":
 				if hasFields["type_url"] {
 					return d.newError(tok.Pos(), "duplicate Any type_url field")
 				}
 				if hasFields["expanded"] {
 					return d.newError(tok.Pos(), "conflict with [%s] field", typeURL)
 				}
 				tok, err := d.Read()
 				if err != nil {
 					return err
 				}
 				var ok bool
 				typeURL, ok = tok.String()
 				if !ok {
 					return d.newError(tok.Pos(), "invalid Any type_url: %v", tok.RawString())
 				}
 				hasFields["type_url"] = true

 			case "value":
 				if hasFields["value"] {
 					return d.newError(tok.Pos(), "duplicate Any value field")
 				}
 				if hasFields["expanded"] {
 					return d.newError(tok.Pos(), "conflict with [%s] field", typeURL)
 				}
 				tok, err := d.Read()
 				if err != nil {
 					return err
 				}
 				s, ok := tok.String()
 				if !ok {
 					return d.newError(tok.Pos(), "invalid Any value: %v", tok.RawString())
 				}
 				bValue = []byte(s)
 				hasFields["value"] = true

 			default:
 				if !d.opts.DiscardUnknown {
 					return d.newError(tok.Pos(), "invalid field name %q in google.protobuf.Any message", tok.RawString())
 				}
 			}

 		case text.TypeName:
 			if hasFields["expanded"] {
 				return d.newError(tok.Pos(), "cannot have more than one type")
 			}
 			if hasFields["type_url"] {
 				return d.newError(tok.Pos(), "conflict with type_url field")
 			}
 			typeURL = tok.TypeName()
 			var err error
 			bValue, err = d.unmarshalExpandedAny(typeURL, tok.Pos())
 			if err != nil {
 				return err
 			}
 			hasFields["expanded"] = true

 		default:
 			if !d.opts.DiscardUnknown {
 				return d.newError(tok.Pos(), "invalid field name %q in google.protobuf.Any message", tok.RawString())
 			}
 		}
 	}

 	fds := m.Descriptor().Fields()
 	if len(typeURL) > 0 {
 		m.Set(fds.ByNumber(fieldnum.Any_TypeUrl), pref.ValueOfString(typeURL))
 	}
 	if len(bValue) > 0 {
 		m.Set(fds.ByNumber(fieldnum.Any_Value), pref.ValueOfBytes(bValue))
 	}
 	return nil
 }

 func (d decoder) unmarshalExpandedAny(typeURL string, pos int) ([]byte, error) {
 	mt, err := d.opts.Resolver.FindMessageByURL(typeURL)
 	if err != nil {
 		return nil, d.newError(pos, "unable to resolve message [%v]: %v", typeURL, err)
 	}
 	// Create new message for the embedded message type and unmarshal the value
 	// field into it.
 	m := mt.New()
 	if err := d.unmarshalMessage(m, true); err != nil {
 		return nil, err
 	}
 	// Serialize the embedded message and return the resulting bytes.
 	b, err := proto.MarshalOptions{
 		AllowPartial:  true, // Never check required fields inside an Any.
 		Deterministic: true,
 	}.Marshal(m.Interface())
 	if err != nil {
 		return nil, d.newError(pos, "error in marshaling message into Any.value: %v", err)
 	}
 	return b, nil
 }

 // skipValue makes the decoder parse a field value in order to advance the read
 // to the next field. It relies on Read returning an error if the types are not
 // in valid sequence.
 func (d decoder) skipValue() error {
 	tok, err := d.Read()
 	if err != nil {
 		return err
 	}
 	// Only need to continue reading for messages and lists.
 	switch tok.Kind() {
 	case text.MessageOpen:
 		return d.skipMessageValue()

 	case text.ListOpen:
 		for {
 			tok, err := d.Read()
 			if err != nil {
 				return err
 			}
 			switch tok.Kind() {
 			case text.ListClose:
 				return nil
 			case text.MessageOpen:
 				return d.skipMessageValue()
 			default:
 				// Skip items. This will not validate whether skipped values are
 				// of the same type or not, same behavior as C++
 				// TextFormat::Parser::AllowUnknownField(true) version 3.8.0.
 				if err := d.skipValue(); err != nil {
 					return err
 				}
 			}
 		}
 	}
 	return nil
 }

 // skipMessageValue makes the decoder parse and skip over all fields in a
 // message. It assumes that the previous read type is MessageOpen.
 func (d decoder) skipMessageValue() error {
 	for {
 		tok, err := d.Read()
 		if err != nil {
 			return err
 		}
 		switch tok.Kind() {
 		case text.MessageClose:
 			return nil
 		case text.Name:
 			if err := d.skipValue(); err != nil {
 				return err
 			}
 		}
 	}
 }
	// Copyright 2018 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package prototext

	import (
	"fmt"
	"strings"
	"unicode/utf8"

	"google.golang.org/protobuf/internal/encoding/messageset"
	"google.golang.org/protobuf/internal/encoding/text"
	"google.golang.org/protobuf/internal/errors"
	"google.golang.org/protobuf/internal/fieldnum"
	"google.golang.org/protobuf/internal/flags"
	"google.golang.org/protobuf/internal/pragma"
	"google.golang.org/protobuf/internal/set"
	"google.golang.org/protobuf/internal/strs"
	"google.golang.org/protobuf/proto"
	pref "google.golang.org/protobuf/reflect/protoreflect"
	"google.golang.org/protobuf/reflect/protoregistry"
	)

	// Unmarshal reads the given []byte into the given proto.Message.
	func Unmarshal(b []byte, m proto.Message) error {
	return UnmarshalOptions{}.Unmarshal(b, m)
	}

	// UnmarshalOptions is a configurable textproto format unmarshaler.
	type UnmarshalOptions struct {
	pragma.NoUnkeyedLiterals

	// AllowPartial accepts input for messages that will result in missing
	// required fields. If AllowPartial is false (the default), Unmarshal will
	// return error if there are any missing required fields.
	AllowPartial bool

	// DiscardUnknown specifies whether to ignore unknown fields when parsing.
	// An unknown field is any field whose field name or field number does not
	// resolve to any known or extension field in the message.
	// By default, unmarshal rejects unknown fields as an error.
	DiscardUnknown bool

	// Resolver is used for looking up types when unmarshaling
	// google.protobuf.Any messages or extension fields.
	// If nil, this defaults to using protoregistry.GlobalTypes.
	Resolver interface {
	protoregistry.MessageTypeResolver
	protoregistry.ExtensionTypeResolver
	}
	}

	// Unmarshal reads the given []byte and populates the given proto.Message using options in
	// UnmarshalOptions object.
	func (o UnmarshalOptions) Unmarshal(b []byte, m proto.Message) error {
	proto.Reset(m)

	if o.Resolver == nil {
	o.Resolver = protoregistry.GlobalTypes
	}

	dec := decoder{text.NewDecoder(b), o}
	if err := dec.unmarshalMessage(m.ProtoReflect(), false); err != nil {
	return err
	}
	if o.AllowPartial {
	return nil
	}
	return proto.CheckInitialized(m)
	}

	type decoder struct {
	*text.Decoder
	opts UnmarshalOptions
	}

	// newError returns an error object with position info.
	func (d decoder) newError(pos int, f string, x ...interface{}) error {
	line, column := d.Position(pos)
	head := fmt.Sprintf("(line %d:%d): ", line, column)
	return errors.New(head+f, x...)
	}

	// unexpectedTokenError returns a syntax error for the given unexpected token.
	func (d decoder) unexpectedTokenError(tok text.Token) error {
	return d.syntaxError(tok.Pos(), "unexpected token: %s", tok.RawString())
	}

	// syntaxError returns a syntax error for given position.
	func (d decoder) syntaxError(pos int, f string, x ...interface{}) error {
	line, column := d.Position(pos)
	head := fmt.Sprintf("syntax error (line %d:%d): ", line, column)
	return errors.New(head+f, x...)
	}

	// unmarshalMessage unmarshals into the given protoreflect.Message.
	func (d decoder) unmarshalMessage(m pref.Message, checkDelims bool) error {
	messageDesc := m.Descriptor()
	if !flags.ProtoLegacy && messageset.IsMessageSet(messageDesc) {
	return errors.New("no support for proto1 MessageSets")
	}

	if messageDesc.FullName() == "google.protobuf.Any" {
	return d.unmarshalAny(m, checkDelims)
	}

	if checkDelims {
	tok, err := d.Read()
	if err != nil {
	return err
	}

	if tok.Kind() != text.MessageOpen {
	return d.unexpectedTokenError(tok)
	}
	}

	var seenNums set.Ints
	var seenOneofs set.Ints
	fieldDescs := messageDesc.Fields()

	for {
	// Read field name.
	tok, err := d.Read()
	if err != nil {
	return err
	}
	switch typ := tok.Kind(); typ {
	case text.Name:
	// Continue below.
	case text.EOF:
	if checkDelims {
	return text.ErrUnexpectedEOF
	}
	return nil
	default:
	if checkDelims && typ == text.MessageClose {
	return nil
	}
	return d.unexpectedTokenError(tok)
	}

	// Resolve the field descriptor.
	var name pref.Name
	var fd pref.FieldDescriptor
	var xt pref.ExtensionType
	var xtErr error
	var isFieldNumberName bool

	switch tok.NameKind() {
	case text.IdentName:
	name = pref.Name(tok.IdentName())
	fd = fieldDescs.ByName(name)
	if fd == nil {
	// The proto name of a group field is in all lowercase,
	// while the textproto field name is the group message name.
	gd := fieldDescs.ByName(pref.Name(strings.ToLower(string(name))))
	if gd != nil && gd.Kind() == pref.GroupKind && gd.Message().Name() == name {
	fd = gd
	}
	} else if fd.Kind() == pref.GroupKind && fd.Message().Name() != name {
	fd = nil // reset since field name is actually the message name
	}

	case text.TypeName:
	// Handle extensions only. This code path is not for Any.
	xt, xtErr = d.findExtension(pref.FullName(tok.TypeName()))

	case text.FieldNumber:
	isFieldNumberName = true
	num := pref.FieldNumber(tok.FieldNumber())
	if !num.IsValid() {
	return d.newError(tok.Pos(), "invalid field number: %d", num)
	}
	fd = fieldDescs.ByNumber(num)
	if fd == nil {
	xt, xtErr = d.opts.Resolver.FindExtensionByNumber(messageDesc.FullName(), num)
	}
	}

	if xt != nil {
	fd = xt.TypeDescriptor()
	if !messageDesc.ExtensionRanges().Has(fd.Number()) \|\| fd.ContainingMessage().FullName() != messageDesc.FullName() {
	return d.newError(tok.Pos(), "message %v cannot be extended by %v", messageDesc.FullName(), fd.FullName())
	}
	} else if xtErr != nil && xtErr != protoregistry.NotFound {
	return d.newError(tok.Pos(), "unable to resolve [%s]: %v", tok.RawString(), xtErr)
	}
	if flags.ProtoLegacy {
	if fd != nil && fd.IsWeak() && fd.Message().IsPlaceholder() {
	fd = nil // reset since the weak reference is not linked in
	}
	}

	// Handle unknown fields.
	if fd == nil {
	if d.opts.DiscardUnknown \|\| messageDesc.ReservedNames().Has(name) {
	d.skipValue()
	continue
	}
	return d.newError(tok.Pos(), "unknown field: %v", tok.RawString())
	}

	// Handle fields identified by field number.
	if isFieldNumberName {
	// TODO: Add an option to permit parsing field numbers.
	//
	// This requires careful thought as the MarshalOptions.EmitUnknown
	// option allows formatting unknown fields as the field number and the
	// best-effort textual representation of the field value. In that case,
	// it may not be possible to unmarshal the value from a parser that does
	// have information about the unknown field.
	return d.newError(tok.Pos(), "cannot specify field by number: %v", tok.RawString())
	}

	switch {
	case fd.IsList():
	kind := fd.Kind()
	if kind != pref.MessageKind && kind != pref.GroupKind && !tok.HasSeparator() {
	return d.syntaxError(tok.Pos(), "missing field separator :")
	}

	list := m.Mutable(fd).List()
	if err := d.unmarshalList(fd, list); err != nil {
	return err
	}

	case fd.IsMap():
	mmap := m.Mutable(fd).Map()
	if err := d.unmarshalMap(fd, mmap); err != nil {
	return err
	}

	default:
	kind := fd.Kind()
	if kind != pref.MessageKind && kind != pref.GroupKind && !tok.HasSeparator() {
	return d.syntaxError(tok.Pos(), "missing field separator :")
	}

	// If field is a oneof, check if it has already been set.
	if od := fd.ContainingOneof(); od != nil {
	idx := uint64(od.Index())
	if seenOneofs.Has(idx) {
	return d.newError(tok.Pos(), "error parsing %q, oneof %v is already set", tok.RawString(), od.FullName())
	}
	seenOneofs.Set(idx)
	}

	num := uint64(fd.Number())
	if seenNums.Has(num) {
	return d.newError(tok.Pos(), "non-repeated field %q is repeated", tok.RawString())
	}

	if err := d.unmarshalSingular(fd, m); err != nil {
	return err
	}
	seenNums.Set(num)
	}
	}

	return nil
	}

	// findExtension returns protoreflect.ExtensionType from the Resolver if found.
	func (d decoder) findExtension(xtName pref.FullName) (pref.ExtensionType, error) {
	xt, err := d.opts.Resolver.FindExtensionByName(xtName)
	if err == nil {
	return xt, nil
	}
	return messageset.FindMessageSetExtension(d.opts.Resolver, xtName)
	}

	// unmarshalSingular unmarshals a non-repeated field value specified by the
	// given FieldDescriptor.
	func (d decoder) unmarshalSingular(fd pref.FieldDescriptor, m pref.Message) error {
	var val pref.Value
	var err error
	switch fd.Kind() {
	case pref.MessageKind, pref.GroupKind:
	val = m.NewField(fd)
	err = d.unmarshalMessage(val.Message(), true)
	default:
	val, err = d.unmarshalScalar(fd)
	}
	if err == nil {
	m.Set(fd, val)
	}
	return err
	}

	// unmarshalScalar unmarshals a scalar/enum protoreflect.Value specified by the
	// given FieldDescriptor.
	func (d decoder) unmarshalScalar(fd pref.FieldDescriptor) (pref.Value, error) {
	tok, err := d.Read()
	if err != nil {
	return pref.Value{}, err
	}

	if tok.Kind() != text.Scalar {
	return pref.Value{}, d.unexpectedTokenError(tok)
	}

	kind := fd.Kind()
	switch kind {
	case pref.BoolKind:
	if b, ok := tok.Bool(); ok {
	return pref.ValueOfBool(b), nil
	}

	case pref.Int32Kind, pref.Sint32Kind, pref.Sfixed32Kind:
	if n, ok := tok.Int32(); ok {
	return pref.ValueOfInt32(n), nil
	}

	case pref.Int64Kind, pref.Sint64Kind, pref.Sfixed64Kind:
	if n, ok := tok.Int64(); ok {
	return pref.ValueOfInt64(n), nil
	}

	case pref.Uint32Kind, pref.Fixed32Kind:
	if n, ok := tok.Uint32(); ok {
	return pref.ValueOfUint32(n), nil
	}

	case pref.Uint64Kind, pref.Fixed64Kind:
	if n, ok := tok.Uint64(); ok {
	return pref.ValueOfUint64(n), nil
	}

	case pref.FloatKind:
	if n, ok := tok.Float32(); ok {
	return pref.ValueOfFloat32(n), nil
	}

	case pref.DoubleKind:
	if n, ok := tok.Float64(); ok {
	return pref.ValueOfFloat64(n), nil
	}

	case pref.StringKind:
	if s, ok := tok.String(); ok {
	if strs.EnforceUTF8(fd) && !utf8.ValidString(s) {
	return pref.Value{}, d.newError(tok.Pos(), "contains invalid UTF-8")
	}
	return pref.ValueOfString(s), nil
	}

	case pref.BytesKind:
	if b, ok := tok.String(); ok {
	return pref.ValueOfBytes([]byte(b)), nil
	}

	case pref.EnumKind:
	if lit, ok := tok.Enum(); ok {
	// Lookup EnumNumber based on name.
	if enumVal := fd.Enum().Values().ByName(pref.Name(lit)); enumVal != nil {
	return pref.ValueOfEnum(enumVal.Number()), nil
	}
	}
	if num, ok := tok.Int32(); ok {
	return pref.ValueOfEnum(pref.EnumNumber(num)), nil
	}

	default:
	panic(fmt.Sprintf("invalid scalar kind %v", kind))
	}

	return pref.Value{}, d.newError(tok.Pos(), "invalid value for %v type: %v", kind, tok.RawString())
	}

	// unmarshalList unmarshals into given protoreflect.List. A list value can
	// either be in [] syntax or simply just a single scalar/message value.
	func (d decoder) unmarshalList(fd pref.FieldDescriptor, list pref.List) error {
	tok, err := d.Peek()
	if err != nil {
	return err
	}

	switch fd.Kind() {
	case pref.MessageKind, pref.GroupKind:
	switch tok.Kind() {
	case text.ListOpen:
	d.Read()
	for {
	tok, err := d.Peek()
	if err != nil {
	return err
	}

	switch tok.Kind() {
	case text.ListClose:
	d.Read()
	return nil
	case text.MessageOpen:
	pval := list.NewElement()
	if err := d.unmarshalMessage(pval.Message(), true); err != nil {
	return err
	}
	list.Append(pval)
	default:
	return d.unexpectedTokenError(tok)
	}
	}

	case text.MessageOpen:
	pval := list.NewElement()
	if err := d.unmarshalMessage(pval.Message(), true); err != nil {
	return err
	}
	list.Append(pval)
	return nil
	}

	default:
	switch tok.Kind() {
	case text.ListOpen:
	d.Read()
	for {
	tok, err := d.Peek()
	if err != nil {
	return err
	}

	switch tok.Kind() {
	case text.ListClose:
	d.Read()
	return nil
	case text.Scalar:
	pval, err := d.unmarshalScalar(fd)
	if err != nil {
	return err
	}
	list.Append(pval)
	default:
	return d.unexpectedTokenError(tok)
	}
	}

	case text.Scalar:
	pval, err := d.unmarshalScalar(fd)
	if err != nil {
	return err
	}
	list.Append(pval)
	return nil
	}
	}

	return d.unexpectedTokenError(tok)
	}

	// unmarshalMap unmarshals into given protoreflect.Map. A map value is a
	// textproto message containing {key: <kvalue>, value: <mvalue>}.
	func (d decoder) unmarshalMap(fd pref.FieldDescriptor, mmap pref.Map) error {
	// Determine ahead whether map entry is a scalar type or a message type in
	// order to call the appropriate unmarshalMapValue func inside
	// unmarshalMapEntry.
	var unmarshalMapValue func() (pref.Value, error)
	switch fd.MapValue().Kind() {
	case pref.MessageKind, pref.GroupKind:
	unmarshalMapValue = func() (pref.Value, error) {
	pval := mmap.NewValue()
	if err := d.unmarshalMessage(pval.Message(), true); err != nil {
	return pref.Value{}, err
	}
	return pval, nil
	}
	default:
	unmarshalMapValue = func() (pref.Value, error) {
	return d.unmarshalScalar(fd.MapValue())
	}
	}

	tok, err := d.Read()
	if err != nil {
	return err
	}
	switch tok.Kind() {
	case text.MessageOpen:
	return d.unmarshalMapEntry(fd, mmap, unmarshalMapValue)

	case text.ListOpen:
	for {
	tok, err := d.Read()
	if err != nil {
	return err
	}
	switch tok.Kind() {
	case text.ListClose:
	return nil
	case text.MessageOpen:
	if err := d.unmarshalMapEntry(fd, mmap, unmarshalMapValue); err != nil {
	return err
	}
	default:
	return d.unexpectedTokenError(tok)
	}
	}

	default:
	return d.unexpectedTokenError(tok)
	}
	}

	// unmarshalMap unmarshals into given protoreflect.Map. A map value is a
	// textproto message containing {key: <kvalue>, value: <mvalue>}.
	func (d decoder) unmarshalMapEntry(fd pref.FieldDescriptor, mmap pref.Map, unmarshalMapValue func() (pref.Value, error)) error {
	var key pref.MapKey
	var pval pref.Value
	Loop:
	for {
	// Read field name.
	tok, err := d.Read()
	if err != nil {
	return err
	}
	switch tok.Kind() {
	case text.Name:
	if tok.NameKind() != text.IdentName {
	if !d.opts.DiscardUnknown {
	return d.newError(tok.Pos(), "unknown map entry field %q", tok.RawString())
	}
	d.skipValue()
	continue Loop
	}
	// Continue below.
	case text.MessageClose:
	break Loop
	default:
	return d.unexpectedTokenError(tok)
	}

	name := tok.IdentName()
	switch name {
	case "key":
	if !tok.HasSeparator() {
	return d.syntaxError(tok.Pos(), "missing field separator :")
	}
	if key.IsValid() {
	return d.newError(tok.Pos(), `map entry "key" cannot be repeated`)
	}
	val, err := d.unmarshalScalar(fd.MapKey())
	if err != nil {
	return err
	}
	key = val.MapKey()

	case "value":
	if kind := fd.MapValue().Kind(); (kind != pref.MessageKind) && (kind != pref.GroupKind) {
	if !tok.HasSeparator() {
	return d.syntaxError(tok.Pos(), "missing field separator :")
	}
	}
	if pval.IsValid() {
	return d.newError(tok.Pos(), `map entry "value" cannot be repeated`)
	}
	pval, err = unmarshalMapValue()
	if err != nil {
	return err
	}

	default:
	if !d.opts.DiscardUnknown {
	return d.newError(tok.Pos(), "unknown map entry field %q", name)
	}
	d.skipValue()
	}
	}

	if !key.IsValid() {
	key = fd.MapKey().Default().MapKey()
	}
	if !pval.IsValid() {
	switch fd.MapValue().Kind() {
	case pref.MessageKind, pref.GroupKind:
	// If value field is not set for message/group types, construct an
	// empty one as default.
	pval = mmap.NewValue()
	default:
	pval = fd.MapValue().Default()
	}
	}
	mmap.Set(key, pval)
	return nil
	}

	// unmarshalAny unmarshals an Any textproto. It can either be in expanded form
	// or non-expanded form.
	func (d decoder) unmarshalAny(m pref.Message, checkDelims bool) error {
	var typeURL string
	var bValue []byte

	// hasFields tracks which valid fields have been seen in the loop below in
	// order to flag an error if there are duplicates or conflicts. It may
	// contain the strings "type_url", "value" and "expanded". The literal
	// "expanded" is used to indicate that the expanded form has been
	// encountered already.
	hasFields := map[string]bool{}

	if checkDelims {
	tok, err := d.Read()
	if err != nil {
	return err
	}

	if tok.Kind() != text.MessageOpen {
	return d.unexpectedTokenError(tok)
	}
	}

	Loop:
	for {
	// Read field name. Can only have 3 possible field names, i.e. type_url,
	// value and type URL name inside [].
	tok, err := d.Read()
	if err != nil {
	return err
	}
	if typ := tok.Kind(); typ != text.Name {
	if checkDelims {
	if typ == text.MessageClose {
	break Loop
	}
	} else if typ == text.EOF {
	break Loop
	}
	return d.unexpectedTokenError(tok)
	}

	switch tok.NameKind() {
	case text.IdentName:
	// Both type_url and value fields require field separator :.
	if !tok.HasSeparator() {
	return d.syntaxError(tok.Pos(), "missing field separator :")
	}

	switch tok.IdentName() {
	case "type_url":
	if hasFields["type_url"] {
	return d.newError(tok.Pos(), "duplicate Any type_url field")
	}
	if hasFields["expanded"] {
	return d.newError(tok.Pos(), "conflict with [%s] field", typeURL)
	}
	tok, err := d.Read()
	if err != nil {
	return err
	}
	var ok bool
	typeURL, ok = tok.String()
	if !ok {
	return d.newError(tok.Pos(), "invalid Any type_url: %v", tok.RawString())
	}
	hasFields["type_url"] = true

	case "value":
	if hasFields["value"] {
	return d.newError(tok.Pos(), "duplicate Any value field")
	}
	if hasFields["expanded"] {
	return d.newError(tok.Pos(), "conflict with [%s] field", typeURL)
	}
	tok, err := d.Read()
	if err != nil {
	return err
	}
	s, ok := tok.String()
	if !ok {
	return d.newError(tok.Pos(), "invalid Any value: %v", tok.RawString())
	}
	bValue = []byte(s)
	hasFields["value"] = true

	default:
	if !d.opts.DiscardUnknown {
	return d.newError(tok.Pos(), "invalid field name %q in google.protobuf.Any message", tok.RawString())
	}
	}

	case text.TypeName:
	if hasFields["expanded"] {
	return d.newError(tok.Pos(), "cannot have more than one type")
	}
	if hasFields["type_url"] {
	return d.newError(tok.Pos(), "conflict with type_url field")
	}
	typeURL = tok.TypeName()
	var err error
	bValue, err = d.unmarshalExpandedAny(typeURL, tok.Pos())
	if err != nil {
	return err
	}
	hasFields["expanded"] = true

	default:
	if !d.opts.DiscardUnknown {
	return d.newError(tok.Pos(), "invalid field name %q in google.protobuf.Any message", tok.RawString())
	}
	}
	}

	fds := m.Descriptor().Fields()
	if len(typeURL) > 0 {
	m.Set(fds.ByNumber(fieldnum.Any_TypeUrl), pref.ValueOfString(typeURL))
	}
	if len(bValue) > 0 {
	m.Set(fds.ByNumber(fieldnum.Any_Value), pref.ValueOfBytes(bValue))
	}
	return nil
	}

	func (d decoder) unmarshalExpandedAny(typeURL string, pos int) ([]byte, error) {
	mt, err := d.opts.Resolver.FindMessageByURL(typeURL)
	if err != nil {
	return nil, d.newError(pos, "unable to resolve message [%v]: %v", typeURL, err)
	}
	// Create new message for the embedded message type and unmarshal the value
	// field into it.
	m := mt.New()
	if err := d.unmarshalMessage(m, true); err != nil {
	return nil, err
	}
	// Serialize the embedded message and return the resulting bytes.
	b, err := proto.MarshalOptions{
	AllowPartial: true, // Never check required fields inside an Any.
	Deterministic: true,
	}.Marshal(m.Interface())
	if err != nil {
	return nil, d.newError(pos, "error in marshaling message into Any.value: %v", err)
	}
	return b, nil
	}

	// skipValue makes the decoder parse a field value in order to advance the read
	// to the next field. It relies on Read returning an error if the types are not
	// in valid sequence.
	func (d decoder) skipValue() error {
	tok, err := d.Read()
	if err != nil {
	return err
	}
	// Only need to continue reading for messages and lists.
	switch tok.Kind() {
	case text.MessageOpen:
	return d.skipMessageValue()

	case text.ListOpen:
	for {
	tok, err := d.Read()
	if err != nil {
	return err
	}
	switch tok.Kind() {
	case text.ListClose:
	return nil
	case text.MessageOpen:
	return d.skipMessageValue()
	default:
	// Skip items. This will not validate whether skipped values are
	// of the same type or not, same behavior as C++
	// TextFormat::Parser::AllowUnknownField(true) version 3.8.0.
	if err := d.skipValue(); err != nil {
	return err
	}
	}
	}
	}
	return nil
	}

	// skipMessageValue makes the decoder parse and skip over all fields in a
	// message. It assumes that the previous read type is MessageOpen.
	func (d decoder) skipMessageValue() error {
	for {
	tok, err := d.Read()
	if err != nil {
	return err
	}
	switch tok.Kind() {
	case text.MessageClose:
	return nil
	case text.Name:
	if err := d.skipValue(); err != nil {
	return err
	}
	}
	}
	}