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updating dashboard dependency version and resolve conflicts

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Signed-off-by: junotx <junotx@126.com>
This commit is contained in:
junotx
2021-03-16 10:21:26 +08:00
parent 0c1f994695
commit a8b9211416
131 changed files with 75 additions and 21648 deletions
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683
vendor/google.golang.org/protobuf/encoding/protojson/decode.go generated vendored
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@@ -1,683 +0,0 @@
// Copyright 2019 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 protojson
import (
"encoding/base64"
"fmt"
"math"
"strconv"
"strings"
"google.golang.org/protobuf/internal/encoding/json"
"google.golang.org/protobuf/internal/encoding/messageset"
"google.golang.org/protobuf/internal/errors"
"google.golang.org/protobuf/internal/flags"
"google.golang.org/protobuf/internal/pragma"
"google.golang.org/protobuf/internal/set"
"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 JSON format parser.
type UnmarshalOptions struct {
pragma.NoUnkeyedLiterals
// If AllowPartial is set, input for messages that will result in missing
// required fields will not return an error.
AllowPartial bool
// If DiscardUnknown is set, unknown fields are ignored.
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. It will clear the message first before
// setting the fields. If it returns an error, the given message may be
// partially set.
func (o UnmarshalOptions) Unmarshal(b []byte, m proto.Message) error {
proto.Reset(m)
if o.Resolver == nil {
o.Resolver = protoregistry.GlobalTypes
}
dec := decoder{json.NewDecoder(b), o}
if err := dec.unmarshalMessage(m.ProtoReflect(), false); err != nil {
return err
}
// Check for EOF.
tok, err := dec.Read()
if err != nil {
return err
}
if tok.Kind() != json.EOF {
return dec.unexpectedTokenError(tok)
}
if o.AllowPartial {
return nil
}
return proto.CheckInitialized(m)
}
type decoder struct {
*json.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 json.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 a message into the given protoreflect.Message.
func (d decoder) unmarshalMessage(m pref.Message, skipTypeURL bool) error {
if isCustomType(m.Descriptor().FullName()) {
return d.unmarshalCustomType(m)
}
tok, err := d.Read()
if err != nil {
return err
}
if tok.Kind() != json.ObjectOpen {
return d.unexpectedTokenError(tok)
}
if err := d.unmarshalFields(m, skipTypeURL); err != nil {
return err
}
return nil
}
// unmarshalFields unmarshals the fields into the given protoreflect.Message.
func (d decoder) unmarshalFields(m pref.Message, skipTypeURL bool) error {
messageDesc := m.Descriptor()
if !flags.ProtoLegacy && messageset.IsMessageSet(messageDesc) {
return errors.New("no support for proto1 MessageSets")
}
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 tok.Kind() {
default:
return d.unexpectedTokenError(tok)
case json.ObjectClose:
return nil
case json.Name:
// Continue below.
}
name := tok.Name()
// Unmarshaling a non-custom embedded message in Any will contain the
// JSON field "@type" which should be skipped because it is not a field
// of the embedded message, but simply an artifact of the Any format.
if skipTypeURL && name == "@type" {
d.Read()
continue
}
// Get the FieldDescriptor.
var fd pref.FieldDescriptor
if strings.HasPrefix(name, "[") && strings.HasSuffix(name, "]") {
// Only extension names are in [name] format.
extName := pref.FullName(name[1 : len(name)-1])
extType, err := d.findExtension(extName)
if err != nil && err != protoregistry.NotFound {
return d.newError(tok.Pos(), "unable to resolve %s: %v", tok.RawString(), err)
}
if extType != nil {
fd = extType.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 {
// The name can either be the JSON name or the proto field name.
fd = fieldDescs.ByJSONName(name)
if fd == nil {
fd = fieldDescs.ByName(pref.Name(name))
if fd == nil {
// The proto name of a group field is in all lowercase,
// while the textual field name is the group message name.
gd := fieldDescs.ByName(pref.Name(strings.ToLower(name)))
if gd != nil && gd.Kind() == pref.GroupKind && gd.Message().Name() == pref.Name(name) {
fd = gd
}
} else if fd.Kind() == pref.GroupKind && fd.Message().Name() != pref.Name(name) {
fd = nil // reset since field name is actually the message name
}
}
}
if flags.ProtoLegacy {
if fd != nil && fd.IsWeak() && fd.Message().IsPlaceholder() {
fd = nil // reset since the weak reference is not linked in
}
}
if fd == nil {
// Field is unknown.
if d.opts.DiscardUnknown {
if err := d.skipJSONValue(); err != nil {
return err
}
continue
}
return d.newError(tok.Pos(), "unknown field %v", tok.RawString())
}
// Do not allow duplicate fields.
num := uint64(fd.Number())
if seenNums.Has(num) {
return d.newError(tok.Pos(), "duplicate field %v", tok.RawString())
}
seenNums.Set(num)
// No need to set values for JSON null unless the field type is
// google.protobuf.Value or google.protobuf.NullValue.
if tok, _ := d.Peek(); tok.Kind() == json.Null && !isKnownValue(fd) && !isNullValue(fd) {
d.Read()
continue
}
switch {
case fd.IsList():
list := m.Mutable(fd).List()
if err := d.unmarshalList(list, fd); err != nil {
return err
}
case fd.IsMap():
mmap := m.Mutable(fd).Map()
if err := d.unmarshalMap(mmap, fd); err != nil {
return err
}
default:
// 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 %s, oneof %v is already set", tok.RawString(), od.FullName())
}
seenOneofs.Set(idx)
}
// Required or optional fields.
if err := d.unmarshalSingular(m, fd); err != nil {
return err
}
}
}
}
// 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)
}
func isKnownValue(fd pref.FieldDescriptor) bool {
md := fd.Message()
return md != nil && md.FullName() == "google.protobuf.Value"
}
func isNullValue(fd pref.FieldDescriptor) bool {
ed := fd.Enum()
return ed != nil && ed.FullName() == "google.protobuf.NullValue"
}
// unmarshalSingular unmarshals to the non-repeated field specified
// by the given FieldDescriptor.
func (d decoder) unmarshalSingular(m pref.Message, fd pref.FieldDescriptor) 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(), false)
default:
val, err = d.unmarshalScalar(fd)
}
if err != nil {
return err
}
m.Set(fd, val)
return nil
}
// unmarshalScalar unmarshals to a scalar/enum protoreflect.Value specified by
// the given FieldDescriptor.
func (d decoder) unmarshalScalar(fd pref.FieldDescriptor) (pref.Value, error) {
const b32 int = 32
const b64 int = 64
tok, err := d.Read()
if err != nil {
return pref.Value{}, err
}
kind := fd.Kind()
switch kind {
case pref.BoolKind:
if tok.Kind() == json.Bool {
return pref.ValueOfBool(tok.Bool()), nil
}
case pref.Int32Kind, pref.Sint32Kind, pref.Sfixed32Kind:
if v, ok := unmarshalInt(tok, b32); ok {
return v, nil
}
case pref.Int64Kind, pref.Sint64Kind, pref.Sfixed64Kind:
if v, ok := unmarshalInt(tok, b64); ok {
return v, nil
}
case pref.Uint32Kind, pref.Fixed32Kind:
if v, ok := unmarshalUint(tok, b32); ok {
return v, nil
}
case pref.Uint64Kind, pref.Fixed64Kind:
if v, ok := unmarshalUint(tok, b64); ok {
return v, nil
}
case pref.FloatKind:
if v, ok := unmarshalFloat(tok, b32); ok {
return v, nil
}
case pref.DoubleKind:
if v, ok := unmarshalFloat(tok, b64); ok {
return v, nil
}
case pref.StringKind:
if tok.Kind() == json.String {
return pref.ValueOfString(tok.ParsedString()), nil
}
case pref.BytesKind:
if v, ok := unmarshalBytes(tok); ok {
return v, nil
}
case pref.EnumKind:
if v, ok := unmarshalEnum(tok, fd); ok {
return v, nil
}
default:
panic(fmt.Sprintf("unmarshalScalar: invalid scalar kind %v", kind))
}
return pref.Value{}, d.newError(tok.Pos(), "invalid value for %v type: %v", kind, tok.RawString())
}
func unmarshalInt(tok json.Token, bitSize int) (pref.Value, bool) {
switch tok.Kind() {
case json.Number:
return getInt(tok, bitSize)
case json.String:
// Decode number from string.
s := strings.TrimSpace(tok.ParsedString())
if len(s) != len(tok.ParsedString()) {
return pref.Value{}, false
}
dec := json.NewDecoder([]byte(s))
tok, err := dec.Read()
if err != nil {
return pref.Value{}, false
}
return getInt(tok, bitSize)
}
return pref.Value{}, false
}
func getInt(tok json.Token, bitSize int) (pref.Value, bool) {
n, ok := tok.Int(bitSize)
if !ok {
return pref.Value{}, false
}
if bitSize == 32 {
return pref.ValueOfInt32(int32(n)), true
}
return pref.ValueOfInt64(n), true
}
func unmarshalUint(tok json.Token, bitSize int) (pref.Value, bool) {
switch tok.Kind() {
case json.Number:
return getUint(tok, bitSize)
case json.String:
// Decode number from string.
s := strings.TrimSpace(tok.ParsedString())
if len(s) != len(tok.ParsedString()) {
return pref.Value{}, false
}
dec := json.NewDecoder([]byte(s))
tok, err := dec.Read()
if err != nil {
return pref.Value{}, false
}
return getUint(tok, bitSize)
}
return pref.Value{}, false
}
func getUint(tok json.Token, bitSize int) (pref.Value, bool) {
n, ok := tok.Uint(bitSize)
if !ok {
return pref.Value{}, false
}
if bitSize == 32 {
return pref.ValueOfUint32(uint32(n)), true
}
return pref.ValueOfUint64(n), true
}
func unmarshalFloat(tok json.Token, bitSize int) (pref.Value, bool) {
switch tok.Kind() {
case json.Number:
return getFloat(tok, bitSize)
case json.String:
s := tok.ParsedString()
switch s {
case "NaN":
if bitSize == 32 {
return pref.ValueOfFloat32(float32(math.NaN())), true
}
return pref.ValueOfFloat64(math.NaN()), true
case "Infinity":
if bitSize == 32 {
return pref.ValueOfFloat32(float32(math.Inf(+1))), true
}
return pref.ValueOfFloat64(math.Inf(+1)), true
case "-Infinity":
if bitSize == 32 {
return pref.ValueOfFloat32(float32(math.Inf(-1))), true
}
return pref.ValueOfFloat64(math.Inf(-1)), true
}
// Decode number from string.
if len(s) != len(strings.TrimSpace(s)) {
return pref.Value{}, false
}
dec := json.NewDecoder([]byte(s))
tok, err := dec.Read()
if err != nil {
return pref.Value{}, false
}
return getFloat(tok, bitSize)
}
return pref.Value{}, false
}
func getFloat(tok json.Token, bitSize int) (pref.Value, bool) {
n, ok := tok.Float(bitSize)
if !ok {
return pref.Value{}, false
}
if bitSize == 32 {
return pref.ValueOfFloat32(float32(n)), true
}
return pref.ValueOfFloat64(n), true
}
func unmarshalBytes(tok json.Token) (pref.Value, bool) {
if tok.Kind() != json.String {
return pref.Value{}, false
}
s := tok.ParsedString()
enc := base64.StdEncoding
if strings.ContainsAny(s, "-_") {
enc = base64.URLEncoding
}
if len(s)%4 != 0 {
enc = enc.WithPadding(base64.NoPadding)
}
b, err := enc.DecodeString(s)
if err != nil {
return pref.Value{}, false
}
return pref.ValueOfBytes(b), true
}
func unmarshalEnum(tok json.Token, fd pref.FieldDescriptor) (pref.Value, bool) {
switch tok.Kind() {
case json.String:
// Lookup EnumNumber based on name.
s := tok.ParsedString()
if enumVal := fd.Enum().Values().ByName(pref.Name(s)); enumVal != nil {
return pref.ValueOfEnum(enumVal.Number()), true
}
case json.Number:
if n, ok := tok.Int(32); ok {
return pref.ValueOfEnum(pref.EnumNumber(n)), true
}
case json.Null:
// This is only valid for google.protobuf.NullValue.
if isNullValue(fd) {
return pref.ValueOfEnum(0), true
}
}
return pref.Value{}, false
}
func (d decoder) unmarshalList(list pref.List, fd pref.FieldDescriptor) error {
tok, err := d.Read()
if err != nil {
return err
}
if tok.Kind() != json.ArrayOpen {
return d.unexpectedTokenError(tok)
}
switch fd.Kind() {
case pref.MessageKind, pref.GroupKind:
for {
tok, err := d.Peek()
if err != nil {
return err
}
if tok.Kind() == json.ArrayClose {
d.Read()
return nil
}
val := list.NewElement()
if err := d.unmarshalMessage(val.Message(), false); err != nil {
return err
}
list.Append(val)
}
default:
for {
tok, err := d.Peek()
if err != nil {
return err
}
if tok.Kind() == json.ArrayClose {
d.Read()
return nil
}
val, err := d.unmarshalScalar(fd)
if err != nil {
return err
}
list.Append(val)
}
}
return nil
}
func (d decoder) unmarshalMap(mmap pref.Map, fd pref.FieldDescriptor) error {
tok, err := d.Read()
if err != nil {
return err
}
if tok.Kind() != json.ObjectOpen {
return d.unexpectedTokenError(tok)
}
// Determine ahead whether map entry is a scalar type or a message type in
// order to call the appropriate unmarshalMapValue func inside the for loop
// below.
var unmarshalMapValue func() (pref.Value, error)
switch fd.MapValue().Kind() {
case pref.MessageKind, pref.GroupKind:
unmarshalMapValue = func() (pref.Value, error) {
val := mmap.NewValue()
if err := d.unmarshalMessage(val.Message(), false); err != nil {
return pref.Value{}, err
}
return val, nil
}
default:
unmarshalMapValue = func() (pref.Value, error) {
return d.unmarshalScalar(fd.MapValue())
}
}
Loop:
for {
// Read field name.
tok, err := d.Read()
if err != nil {
return err
}
switch tok.Kind() {
default:
return d.unexpectedTokenError(tok)
case json.ObjectClose:
break Loop
case json.Name:
// Continue.
}
// Unmarshal field name.
pkey, err := d.unmarshalMapKey(tok, fd.MapKey())
if err != nil {
return err
}
// Check for duplicate field name.
if mmap.Has(pkey) {
return d.newError(tok.Pos(), "duplicate map key %v", tok.RawString())
}
// Read and unmarshal field value.
pval, err := unmarshalMapValue()
if err != nil {
return err
}
mmap.Set(pkey, pval)
}
return nil
}
// unmarshalMapKey converts given token of Name kind into a protoreflect.MapKey.
// A map key type is any integral or string type.
func (d decoder) unmarshalMapKey(tok json.Token, fd pref.FieldDescriptor) (pref.MapKey, error) {
const b32 = 32
const b64 = 64
const base10 = 10
name := tok.Name()
kind := fd.Kind()
switch kind {
case pref.StringKind:
return pref.ValueOfString(name).MapKey(), nil
case pref.BoolKind:
switch name {
case "true":
return pref.ValueOfBool(true).MapKey(), nil
case "false":
return pref.ValueOfBool(false).MapKey(), nil
}
case pref.Int32Kind, pref.Sint32Kind, pref.Sfixed32Kind:
if n, err := strconv.ParseInt(name, base10, b32); err == nil {
return pref.ValueOfInt32(int32(n)).MapKey(), nil
}
case pref.Int64Kind, pref.Sint64Kind, pref.Sfixed64Kind:
if n, err := strconv.ParseInt(name, base10, b64); err == nil {
return pref.ValueOfInt64(int64(n)).MapKey(), nil
}
case pref.Uint32Kind, pref.Fixed32Kind:
if n, err := strconv.ParseUint(name, base10, b32); err == nil {
return pref.ValueOfUint32(uint32(n)).MapKey(), nil
}
case pref.Uint64Kind, pref.Fixed64Kind:
if n, err := strconv.ParseUint(name, base10, b64); err == nil {
return pref.ValueOfUint64(uint64(n)).MapKey(), nil
}
default:
panic(fmt.Sprintf("invalid kind for map key: %v", kind))
}
return pref.MapKey{}, d.newError(tok.Pos(), "invalid value for %v key: %s", kind, tok.RawString())
}

11
vendor/google.golang.org/protobuf/encoding/protojson/doc.go generated vendored
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@@ -1,11 +0,0 @@
// Copyright 2019 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 protojson marshals and unmarshals protocol buffer messages as JSON
// format. It follows the guide at
// https://developers.google.com/protocol-buffers/docs/proto3#json.
//
// This package produces a different output than the standard "encoding/json"
// package, which does not operate correctly on protocol buffer messages.
package protojson

394
vendor/google.golang.org/protobuf/encoding/protojson/encode.go generated vendored
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@@ -1,394 +0,0 @@
// Copyright 2019 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 protojson
import (
"encoding/base64"
"fmt"
"sort"
"google.golang.org/protobuf/internal/encoding/json"
"google.golang.org/protobuf/internal/encoding/messageset"
"google.golang.org/protobuf/internal/errors"
"google.golang.org/protobuf/internal/flags"
"google.golang.org/protobuf/internal/pragma"
"google.golang.org/protobuf/proto"
pref "google.golang.org/protobuf/reflect/protoreflect"
"google.golang.org/protobuf/reflect/protoregistry"
)
const defaultIndent = " "
// Format formats the message as a multiline string.
// This function is only intended for human consumption and ignores errors.
// Do not depend on the output being stable. It may change over time across
// different versions of the program.
func Format(m proto.Message) string {
return MarshalOptions{Multiline: true}.Format(m)
}
// Marshal writes the given proto.Message in JSON format using default options.
// Do not depend on the output being stable. It may change over time across
// different versions of the program.
func Marshal(m proto.Message) ([]byte, error) {
return MarshalOptions{}.Marshal(m)
}
// MarshalOptions is a configurable JSON format marshaler.
type MarshalOptions struct {
pragma.NoUnkeyedLiterals
// Multiline specifies whether the marshaler should format the output in
// indented-form with every textual element on a new line.
// If Indent is an empty string, then an arbitrary indent is chosen.
Multiline bool
// Indent specifies the set of indentation characters to use in a multiline
// formatted output such that every entry is preceded by Indent and
// terminated by a newline. If non-empty, then Multiline is treated as true.
// Indent can only be composed of space or tab characters.
Indent string
// AllowPartial allows messages that have missing required fields to marshal
// without returning an error. If AllowPartial is false (the default),
// Marshal will return error if there are any missing required fields.
AllowPartial bool
// UseProtoNames uses proto field name instead of lowerCamelCase name in JSON
// field names.
UseProtoNames bool
// UseEnumNumbers emits enum values as numbers.
UseEnumNumbers bool
// EmitUnpopulated specifies whether to emit unpopulated fields. It does not
// emit unpopulated oneof fields or unpopulated extension fields.
// The JSON value emitted for unpopulated fields are as follows:
// ╔═══════╤════════════════════════════╗
// ║ JSON │ Protobuf field ║
// ╠═══════╪════════════════════════════╣
// ║ false │ proto3 boolean fields ║
// ║ 0 │ proto3 numeric fields ║
// ║ "" │ proto3 string/bytes fields ║
// ║ null │ proto2 scalar fields ║
// ║ null │ message fields ║
// ║ [] │ list fields ║
// ║ {} │ map fields ║
// ╚═══════╧════════════════════════════╝
EmitUnpopulated bool
// Resolver is used for looking up types when expanding google.protobuf.Any
// messages. If nil, this defaults to using protoregistry.GlobalTypes.
Resolver interface {
protoregistry.ExtensionTypeResolver
protoregistry.MessageTypeResolver
}
}
// Format formats the message as a string.
// This method is only intended for human consumption and ignores errors.
// Do not depend on the output being stable. It may change over time across
// different versions of the program.
func (o MarshalOptions) Format(m proto.Message) string {
if m == nil || !m.ProtoReflect().IsValid() {
return "<nil>" // invalid syntax, but okay since this is for debugging
}
o.AllowPartial = true
b, _ := o.Marshal(m)
return string(b)
}
// Marshal marshals the given proto.Message in the JSON format using options in
// MarshalOptions. Do not depend on the output being stable. It may change over
// time across different versions of the program.
func (o MarshalOptions) Marshal(m proto.Message) ([]byte, error) {
if o.Multiline && o.Indent == "" {
o.Indent = defaultIndent
}
if o.Resolver == nil {
o.Resolver = protoregistry.GlobalTypes
}
internalEnc, err := json.NewEncoder(o.Indent)
if err != nil {
return nil, err
}
// Treat nil message interface as an empty message,
// in which case the output in an empty JSON object.
if m == nil {
return []byte("{}"), nil
}
enc := encoder{internalEnc, o}
if err := enc.marshalMessage(m.ProtoReflect()); err != nil {
return nil, err
}
if o.AllowPartial {
return enc.Bytes(), nil
}
return enc.Bytes(), proto.CheckInitialized(m)
}
type encoder struct {
*json.Encoder
opts MarshalOptions
}
// marshalMessage marshals the given protoreflect.Message.
func (e encoder) marshalMessage(m pref.Message) error {
if isCustomType(m.Descriptor().FullName()) {
return e.marshalCustomType(m)
}
e.StartObject()
defer e.EndObject()
if err := e.marshalFields(m); err != nil {
return err
}
return nil
}
// marshalFields marshals the fields in the given protoreflect.Message.
func (e encoder) marshalFields(m pref.Message) error {
messageDesc := m.Descriptor()
if !flags.ProtoLegacy && messageset.IsMessageSet(messageDesc) {
return errors.New("no support for proto1 MessageSets")
}
// Marshal out known fields.
fieldDescs := messageDesc.Fields()
for i := 0; i < fieldDescs.Len(); {
fd := fieldDescs.Get(i)
if od := fd.ContainingOneof(); od != nil {
fd = m.WhichOneof(od)
i += od.Fields().Len()
if fd == nil {
continue // unpopulated oneofs are not affected by EmitUnpopulated
}
} else {
i++
}
val := m.Get(fd)
if !m.Has(fd) {
if !e.opts.EmitUnpopulated {
continue
}
isProto2Scalar := fd.Syntax() == pref.Proto2 && fd.Default().IsValid()
isSingularMessage := fd.Cardinality() != pref.Repeated && fd.Message() != nil
if isProto2Scalar || isSingularMessage {
// Use invalid value to emit null.
val = pref.Value{}
}
}
name := fd.JSONName()
if e.opts.UseProtoNames {
name = string(fd.Name())
// Use type name for group field name.
if fd.Kind() == pref.GroupKind {
name = string(fd.Message().Name())
}
}
if err := e.WriteName(name); err != nil {
return err
}
if err := e.marshalValue(val, fd); err != nil {
return err
}
}
// Marshal out extensions.
if err := e.marshalExtensions(m); err != nil {
return err
}
return nil
}
// marshalValue marshals the given protoreflect.Value.
func (e encoder) marshalValue(val pref.Value, fd pref.FieldDescriptor) error {
switch {
case fd.IsList():
return e.marshalList(val.List(), fd)
case fd.IsMap():
return e.marshalMap(val.Map(), fd)
default:
return e.marshalSingular(val, fd)
}
}
// marshalSingular marshals the given non-repeated field value. This includes
// all scalar types, enums, messages, and groups.
func (e encoder) marshalSingular(val pref.Value, fd pref.FieldDescriptor) error {
if !val.IsValid() {
e.WriteNull()
return nil
}
switch kind := fd.Kind(); kind {
case pref.BoolKind:
e.WriteBool(val.Bool())
case pref.StringKind:
if e.WriteString(val.String()) != nil {
return errors.InvalidUTF8(string(fd.FullName()))
}
case pref.Int32Kind, pref.Sint32Kind, pref.Sfixed32Kind:
e.WriteInt(val.Int())
case pref.Uint32Kind, pref.Fixed32Kind:
e.WriteUint(val.Uint())
case pref.Int64Kind, pref.Sint64Kind, pref.Uint64Kind,
pref.Sfixed64Kind, pref.Fixed64Kind:
// 64-bit integers are written out as JSON string.
e.WriteString(val.String())
case pref.FloatKind:
// Encoder.WriteFloat handles the special numbers NaN and infinites.
e.WriteFloat(val.Float(), 32)
case pref.DoubleKind:
// Encoder.WriteFloat handles the special numbers NaN and infinites.
e.WriteFloat(val.Float(), 64)
case pref.BytesKind:
e.WriteString(base64.StdEncoding.EncodeToString(val.Bytes()))
case pref.EnumKind:
if fd.Enum().FullName() == "google.protobuf.NullValue" {
e.WriteNull()
} else {
desc := fd.Enum().Values().ByNumber(val.Enum())
if e.opts.UseEnumNumbers || desc == nil {
e.WriteInt(int64(val.Enum()))
} else {
e.WriteString(string(desc.Name()))
}
}
case pref.MessageKind, pref.GroupKind:
if err := e.marshalMessage(val.Message()); err != nil {
return err
}
default:
panic(fmt.Sprintf("%v has unknown kind: %v", fd.FullName(), kind))
}
return nil
}
// marshalList marshals the given protoreflect.List.
func (e encoder) marshalList(list pref.List, fd pref.FieldDescriptor) error {
e.StartArray()
defer e.EndArray()
for i := 0; i < list.Len(); i++ {
item := list.Get(i)
if err := e.marshalSingular(item, fd); err != nil {
return err
}
}
return nil
}
type mapEntry struct {
key pref.MapKey
value pref.Value
}
// marshalMap marshals given protoreflect.Map.
func (e encoder) marshalMap(mmap pref.Map, fd pref.FieldDescriptor) error {
e.StartObject()
defer e.EndObject()
// Get a sorted list based on keyType first.
entries := make([]mapEntry, 0, mmap.Len())
mmap.Range(func(key pref.MapKey, val pref.Value) bool {
entries = append(entries, mapEntry{key: key, value: val})
return true
})
sortMap(fd.MapKey().Kind(), entries)
// Write out sorted list.
for _, entry := range entries {
if err := e.WriteName(entry.key.String()); err != nil {
return err
}
if err := e.marshalSingular(entry.value, fd.MapValue()); err != nil {
return err
}
}
return nil
}
// sortMap orders list based on value of key field for deterministic ordering.
func sortMap(keyKind pref.Kind, values []mapEntry) {
sort.Slice(values, func(i, j int) bool {
switch keyKind {
case pref.Int32Kind, pref.Sint32Kind, pref.Sfixed32Kind,
pref.Int64Kind, pref.Sint64Kind, pref.Sfixed64Kind:
return values[i].key.Int() < values[j].key.Int()
case pref.Uint32Kind, pref.Fixed32Kind,
pref.Uint64Kind, pref.Fixed64Kind:
return values[i].key.Uint() < values[j].key.Uint()
}
return values[i].key.String() < values[j].key.String()
})
}
// marshalExtensions marshals extension fields.
func (e encoder) marshalExtensions(m pref.Message) error {
type entry struct {
key string
value pref.Value
desc pref.FieldDescriptor
}
// Get a sorted list based on field key first.
var entries []entry
m.Range(func(fd pref.FieldDescriptor, v pref.Value) bool {
if !fd.IsExtension() {
return true
}
// For MessageSet extensions, the name used is the parent message.
name := fd.FullName()
if messageset.IsMessageSetExtension(fd) {
name = name.Parent()
}
// Use [name] format for JSON field name.
entries = append(entries, entry{
key: string(name),
value: v,
desc: fd,
})
return true
})
// Sort extensions lexicographically.
sort.Slice(entries, func(i, j int) bool {
return entries[i].key < entries[j].key
})
// Write out sorted list.
for _, entry := range entries {
// JSON field name is the proto field name enclosed in [], similar to
// textproto. This is consistent with Go v1 lib. C++ lib v3.7.0 does not
// marshal out extension fields.
if err := e.WriteName("[" + entry.key + "]"); err != nil {
return err
}
if err := e.marshalValue(entry.value, entry.desc); err != nil {
return err
}
}
return nil
}

903
vendor/google.golang.org/protobuf/encoding/protojson/well_known_types.go generated vendored
View File

@@ -1,903 +0,0 @@
// Copyright 2019 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 protojson
import (
"bytes"
"fmt"
"strconv"
"strings"
"time"
"google.golang.org/protobuf/internal/detectknown"
"google.golang.org/protobuf/internal/encoding/json"
"google.golang.org/protobuf/internal/errors"
"google.golang.org/protobuf/internal/fieldnum"
"google.golang.org/protobuf/internal/strs"
"google.golang.org/protobuf/proto"
pref "google.golang.org/protobuf/reflect/protoreflect"
)
// isCustomType returns true if type name has special JSON conversion rules.
// The list of custom types here has to match the ones in marshalCustomType and
// unmarshalCustomType.
func isCustomType(name pref.FullName) bool {
switch detectknown.Which(name) {
case detectknown.AnyProto:
case detectknown.TimestampProto:
case detectknown.DurationProto:
case detectknown.WrappersProto:
case detectknown.StructProto:
case detectknown.FieldMaskProto:
case detectknown.EmptyProto:
default:
return false
}
return true
}
// marshalCustomType marshals given well-known type message that have special
// JSON conversion rules. It needs to be a message type where isCustomType
// returns true, else it will panic.
func (e encoder) marshalCustomType(m pref.Message) error {
name := m.Descriptor().FullName()
switch detectknown.Which(name) {
case detectknown.AnyProto:
return e.marshalAny(m)
case detectknown.TimestampProto:
return e.marshalTimestamp(m)
case detectknown.DurationProto:
return e.marshalDuration(m)
case detectknown.WrappersProto:
return e.marshalWrapperType(m)
case detectknown.StructProto:
return e.marshalStructType(m)
case detectknown.FieldMaskProto:
return e.marshalFieldMask(m)
case detectknown.EmptyProto:
return e.marshalEmpty(m)
default:
panic(fmt.Sprintf("%s does not have a custom marshaler", name))
}
}
// unmarshalCustomType unmarshals given well-known type message that have
// special JSON conversion rules. It needs to be a message type where
// isCustomType returns true, else it will panic.
func (d decoder) unmarshalCustomType(m pref.Message) error {
name := m.Descriptor().FullName()
switch detectknown.Which(name) {
case detectknown.AnyProto:
return d.unmarshalAny(m)
case detectknown.TimestampProto:
return d.unmarshalTimestamp(m)
case detectknown.DurationProto:
return d.unmarshalDuration(m)
case detectknown.WrappersProto:
return d.unmarshalWrapperType(m)
case detectknown.StructProto:
return d.unmarshalStructType(m)
case detectknown.FieldMaskProto:
return d.unmarshalFieldMask(m)
case detectknown.EmptyProto:
return d.unmarshalEmpty(m)
default:
panic(fmt.Sprintf("%s does not have a custom unmarshaler", name))
}
}
// The JSON representation of an Any message uses the regular representation of
// the deserialized, embedded message, with an additional field `@type` which
// contains the type URL. If the embedded message type is well-known and has a
// custom JSON representation, that representation will be embedded adding a
// field `value` which holds the custom JSON in addition to the `@type` field.
func (e encoder) marshalAny(m pref.Message) error {
fds := m.Descriptor().Fields()
fdType := fds.ByNumber(fieldnum.Any_TypeUrl)
fdValue := fds.ByNumber(fieldnum.Any_Value)
// Start writing the JSON object.
e.StartObject()
defer e.EndObject()
if !m.Has(fdType) {
if !m.Has(fdValue) {
// If message is empty, marshal out empty JSON object.
return nil
} else {
// Return error if type_url field is not set, but value is set.
return errors.New("%s: type_url is not set", m.Descriptor().FullName())
}
}
typeVal := m.Get(fdType)
valueVal := m.Get(fdValue)
// Marshal out @type field.
typeURL := typeVal.String()
e.WriteName("@type")
if err := e.WriteString(typeURL); err != nil {
return err
}
// Resolve the type in order to unmarshal value field.
emt, err := e.opts.Resolver.FindMessageByURL(typeURL)
if err != nil {
return errors.New("%s: unable to resolve %q: %v", m.Descriptor().FullName(), typeURL, err)
}
em := emt.New()
err = proto.UnmarshalOptions{
AllowPartial: true, // never check required fields inside an Any
Resolver: e.opts.Resolver,
}.Unmarshal(valueVal.Bytes(), em.Interface())
if err != nil {
return errors.New("%s: unable to unmarshal %q: %v", m.Descriptor().FullName(), typeURL, err)
}
// If type of value has custom JSON encoding, marshal out a field "value"
// with corresponding custom JSON encoding of the embedded message as a
// field.
if isCustomType(emt.Descriptor().FullName()) {
e.WriteName("value")
return e.marshalCustomType(em)
}
// Else, marshal out the embedded message's fields in this Any object.
if err := e.marshalFields(em); err != nil {
return err
}
return nil
}
func (d decoder) unmarshalAny(m pref.Message) error {
// Peek to check for json.ObjectOpen to avoid advancing a read.
start, err := d.Peek()
if err != nil {
return err
}
if start.Kind() != json.ObjectOpen {
return d.unexpectedTokenError(start)
}
// Use another decoder to parse the unread bytes for @type field. This
// avoids advancing a read from current decoder because the current JSON
// object may contain the fields of the embedded type.
dec := decoder{d.Clone(), UnmarshalOptions{}}
tok, err := findTypeURL(dec)
switch err {
case errEmptyObject:
// An empty JSON object translates to an empty Any message.
d.Read() // Read json.ObjectOpen.
d.Read() // Read json.ObjectClose.
return nil
case errMissingType:
if d.opts.DiscardUnknown {
// Treat all fields as unknowns, similar to an empty object.
return d.skipJSONValue()
}
// Use start.Pos() for line position.
return d.newError(start.Pos(), err.Error())
default:
if err != nil {
return err
}
}
typeURL := tok.ParsedString()
emt, err := d.opts.Resolver.FindMessageByURL(typeURL)
if err != nil {
return d.newError(tok.Pos(), "unable to resolve %v: %q", tok.RawString(), err)
}
// Create new message for the embedded message type and unmarshal into it.
em := emt.New()
if isCustomType(emt.Descriptor().FullName()) {
// If embedded message is a custom type,
// unmarshal the JSON "value" field into it.
if err := d.unmarshalAnyValue(em); err != nil {
return err
}
} else {
// Else unmarshal the current JSON object into it.
if err := d.unmarshalMessage(em, true); err != nil {
return err
}
}
// Serialize the embedded message and assign the resulting bytes to the
// proto value field.
b, err := proto.MarshalOptions{
AllowPartial: true, // No need to check required fields inside an Any.
Deterministic: true,
}.Marshal(em.Interface())
if err != nil {
return d.newError(start.Pos(), "error in marshaling Any.value field: %v", err)
}
fds := m.Descriptor().Fields()
fdType := fds.ByNumber(fieldnum.Any_TypeUrl)
fdValue := fds.ByNumber(fieldnum.Any_Value)
m.Set(fdType, pref.ValueOfString(typeURL))
m.Set(fdValue, pref.ValueOfBytes(b))
return nil
}
var errEmptyObject = fmt.Errorf(`empty object`)
var errMissingType = fmt.Errorf(`missing "@type" field`)
// findTypeURL returns the token for the "@type" field value from the given
// JSON bytes. It is expected that the given bytes start with json.ObjectOpen.
// It returns errEmptyObject if the JSON object is empty or errMissingType if
// @type field does not exist. It returns other error if the @type field is not
// valid or other decoding issues.
func findTypeURL(d decoder) (json.Token, error) {
var typeURL string
var typeTok json.Token
numFields := 0
// Skip start object.
d.Read()
Loop:
for {
tok, err := d.Read()
if err != nil {
return json.Token{}, err
}
switch tok.Kind() {
case json.ObjectClose:
if typeURL == "" {
// Did not find @type field.
if numFields > 0 {
return json.Token{}, errMissingType
}
return json.Token{}, errEmptyObject
}
break Loop
case json.Name:
numFields++
if tok.Name() != "@type" {
// Skip value.
if err := d.skipJSONValue(); err != nil {
return json.Token{}, err
}
continue
}
// Return error if this was previously set already.
if typeURL != "" {
return json.Token{}, d.newError(tok.Pos(), `duplicate "@type" field`)
}
// Read field value.
tok, err := d.Read()
if err != nil {
return json.Token{}, err
}
if tok.Kind() != json.String {
return json.Token{}, d.newError(tok.Pos(), `@type field value is not a string: %v`, tok.RawString())
}
typeURL = tok.ParsedString()
if typeURL == "" {
return json.Token{}, d.newError(tok.Pos(), `@type field contains empty value`)
}
typeTok = tok
}
}
return typeTok, nil
}
// skipJSONValue parses a JSON value (null, boolean, string, number, object and
// array) in order to advance the read to the next JSON value. It relies on
// the decoder returning an error if the types are not in valid sequence.
func (d decoder) skipJSONValue() error {
tok, err := d.Read()
if err != nil {
return err
}
// Only need to continue reading for objects and arrays.
switch tok.Kind() {
case json.ObjectOpen:
for {
tok, err := d.Read()
if err != nil {
return err
}
switch tok.Kind() {
case json.ObjectClose:
return nil
case json.Name:
// Skip object field value.
if err := d.skipJSONValue(); err != nil {
return err
}
}
}
case json.ArrayOpen:
for {
tok, err := d.Peek()
if err != nil {
return err
}
switch tok.Kind() {
case json.ArrayClose:
d.Read()
return nil
default:
// Skip array item.
if err := d.skipJSONValue(); err != nil {
return err
}
}
}
}
return nil
}
// unmarshalAnyValue unmarshals the given custom-type message from the JSON
// object's "value" field.
func (d decoder) unmarshalAnyValue(m pref.Message) error {
// Skip ObjectOpen, and start reading the fields.
d.Read()
var found bool // Used for detecting duplicate "value".
for {
tok, err := d.Read()
if err != nil {
return err
}
switch tok.Kind() {
case json.ObjectClose:
if !found {
return d.newError(tok.Pos(), `missing "value" field`)
}
return nil
case json.Name:
switch tok.Name() {
case "@type":
// Skip the value as this was previously parsed already.
d.Read()
case "value":
if found {
return d.newError(tok.Pos(), `duplicate "value" field`)
}
// Unmarshal the field value into the given message.
if err := d.unmarshalCustomType(m); err != nil {
return err
}
found = true
default:
if d.opts.DiscardUnknown {
if err := d.skipJSONValue(); err != nil {
return err
}
continue
}
return d.newError(tok.Pos(), "unknown field %v", tok.RawString())
}
}
}
}
// Wrapper types are encoded as JSON primitives like string, number or boolean.
// The "value" field has the same field number for all wrapper types.
const wrapperFieldNumber = fieldnum.BoolValue_Value
func (e encoder) marshalWrapperType(m pref.Message) error {
fd := m.Descriptor().Fields().ByNumber(wrapperFieldNumber)
val := m.Get(fd)
return e.marshalSingular(val, fd)
}
func (d decoder) unmarshalWrapperType(m pref.Message) error {
fd := m.Descriptor().Fields().ByNumber(wrapperFieldNumber)
val, err := d.unmarshalScalar(fd)
if err != nil {
return err
}
m.Set(fd, val)
return nil
}
// The JSON representation for Empty is an empty JSON object.
func (e encoder) marshalEmpty(pref.Message) error {
e.StartObject()
e.EndObject()
return nil
}
func (d decoder) unmarshalEmpty(pref.Message) error {
tok, err := d.Read()
if err != nil {
return err
}
if tok.Kind() != json.ObjectOpen {
return d.unexpectedTokenError(tok)
}
for {
tok, err := d.Read()
if err != nil {
return err
}
switch tok.Kind() {
case json.ObjectClose:
return nil
case json.Name:
if d.opts.DiscardUnknown {
if err := d.skipJSONValue(); err != nil {
return err
}
continue
}
return d.newError(tok.Pos(), "unknown field %v", tok.RawString())
default:
return d.unexpectedTokenError(tok)
}
}
}
func (e encoder) marshalStructType(m pref.Message) error {
switch m.Descriptor().Name() {
case "Struct":
return e.marshalStruct(m)
case "ListValue":
return e.marshalListValue(m)
case "Value":
return e.marshalKnownValue(m)
default:
panic(fmt.Sprintf("invalid struct type: %v", m.Descriptor().FullName()))
}
}
func (d decoder) unmarshalStructType(m pref.Message) error {
switch m.Descriptor().Name() {
case "Struct":
return d.unmarshalStruct(m)
case "ListValue":
return d.unmarshalListValue(m)
case "Value":
return d.unmarshalKnownValue(m)
default:
panic(fmt.Sprintf("invalid struct type: %v", m.Descriptor().FullName()))
}
}
// The JSON representation for Struct is a JSON object that contains the encoded
// Struct.fields map and follows the serialization rules for a map.
func (e encoder) marshalStruct(m pref.Message) error {
fd := m.Descriptor().Fields().ByNumber(fieldnum.Struct_Fields)
return e.marshalMap(m.Get(fd).Map(), fd)
}
func (d decoder) unmarshalStruct(m pref.Message) error {
fd := m.Descriptor().Fields().ByNumber(fieldnum.Struct_Fields)
return d.unmarshalMap(m.Mutable(fd).Map(), fd)
}
// The JSON representation for ListValue is JSON array that contains the encoded
// ListValue.values repeated field and follows the serialization rules for a
// repeated field.
func (e encoder) marshalListValue(m pref.Message) error {
fd := m.Descriptor().Fields().ByNumber(fieldnum.ListValue_Values)
return e.marshalList(m.Get(fd).List(), fd)
}
func (d decoder) unmarshalListValue(m pref.Message) error {
fd := m.Descriptor().Fields().ByNumber(fieldnum.ListValue_Values)
return d.unmarshalList(m.Mutable(fd).List(), fd)
}
// The JSON representation for a Value is dependent on the oneof field that is
// set. Each of the field in the oneof has its own custom serialization rule. A
// Value message needs to be a oneof field set, else it is an error.
func (e encoder) marshalKnownValue(m pref.Message) error {
od := m.Descriptor().Oneofs().ByName("kind")
fd := m.WhichOneof(od)
if fd == nil {
return errors.New("%s: none of the oneof fields is set", m.Descriptor().FullName())
}
return e.marshalSingular(m.Get(fd), fd)
}
func (d decoder) unmarshalKnownValue(m pref.Message) error {
tok, err := d.Peek()
if err != nil {
return err
}
var fd pref.FieldDescriptor
var val pref.Value
switch tok.Kind() {
case json.Null:
d.Read()
fd = m.Descriptor().Fields().ByNumber(fieldnum.Value_NullValue)
val = pref.ValueOfEnum(0)
case json.Bool:
tok, err := d.Read()
if err != nil {
return err
}
fd = m.Descriptor().Fields().ByNumber(fieldnum.Value_BoolValue)
val = pref.ValueOfBool(tok.Bool())
case json.Number:
tok, err := d.Read()
if err != nil {
return err
}
fd = m.Descriptor().Fields().ByNumber(fieldnum.Value_NumberValue)
var ok bool
val, ok = unmarshalFloat(tok, 64)
if !ok {
return d.newError(tok.Pos(), "invalid google.protobuf.Value: %v", tok.RawString())
}
case json.String:
// A JSON string may have been encoded from the number_value field,
// e.g. "NaN", "Infinity", etc. Parsing a proto double type also allows
// for it to be in JSON string form. Given this custom encoding spec,
// however, there is no way to identify that and hence a JSON string is
// always assigned to the string_value field, which means that certain
// encoding cannot be parsed back to the same field.
tok, err := d.Read()
if err != nil {
return err
}
fd = m.Descriptor().Fields().ByNumber(fieldnum.Value_StringValue)
val = pref.ValueOfString(tok.ParsedString())
case json.ObjectOpen:
fd = m.Descriptor().Fields().ByNumber(fieldnum.Value_StructValue)
val = m.NewField(fd)
if err := d.unmarshalStruct(val.Message()); err != nil {
return err
}
case json.ArrayOpen:
fd = m.Descriptor().Fields().ByNumber(fieldnum.Value_ListValue)
val = m.NewField(fd)
if err := d.unmarshalListValue(val.Message()); err != nil {
return err
}
default:
return d.newError(tok.Pos(), "invalid google.protobuf.Value: %v", tok.RawString())
}
m.Set(fd, val)
return nil
}
// The JSON representation for a Duration is a JSON string that ends in the
// suffix "s" (indicating seconds) and is preceded by the number of seconds,
// with nanoseconds expressed as fractional seconds.
//
// Durations less than one second are represented with a 0 seconds field and a
// positive or negative nanos field. For durations of one second or more, a
// non-zero value for the nanos field must be of the same sign as the seconds
// field.
//
// Duration.seconds must be from -315,576,000,000 to +315,576,000,000 inclusive.
// Duration.nanos must be from -999,999,999 to +999,999,999 inclusive.
const (
secondsInNanos = 999999999
maxSecondsInDuration = 315576000000
)
func (e encoder) marshalDuration(m pref.Message) error {
fds := m.Descriptor().Fields()
fdSeconds := fds.ByNumber(fieldnum.Duration_Seconds)
fdNanos := fds.ByNumber(fieldnum.Duration_Nanos)
secsVal := m.Get(fdSeconds)
nanosVal := m.Get(fdNanos)
secs := secsVal.Int()
nanos := nanosVal.Int()
if secs < -maxSecondsInDuration || secs > maxSecondsInDuration {
return errors.New("%s: seconds out of range %v", m.Descriptor().FullName(), secs)
}
if nanos < -secondsInNanos || nanos > secondsInNanos {
return errors.New("%s: nanos out of range %v", m.Descriptor().FullName(), nanos)
}
if (secs > 0 && nanos < 0) || (secs < 0 && nanos > 0) {
return errors.New("%s: signs of seconds and nanos do not match", m.Descriptor().FullName())
}
// Generated output always contains 0, 3, 6, or 9 fractional digits,
// depending on required precision, followed by the suffix "s".
f := "%d.%09d"
if nanos < 0 {
nanos = -nanos
if secs == 0 {
f = "-%d.%09d"
}
}
x := fmt.Sprintf(f, secs, nanos)
x = strings.TrimSuffix(x, "000")
x = strings.TrimSuffix(x, "000")
x = strings.TrimSuffix(x, ".000")
e.WriteString(x + "s")
return nil
}
func (d decoder) unmarshalDuration(m pref.Message) error {
tok, err := d.Read()
if err != nil {
return err
}
if tok.Kind() != json.String {
return d.unexpectedTokenError(tok)
}
secs, nanos, ok := parseDuration(tok.ParsedString())
if !ok {
return d.newError(tok.Pos(), "invalid google.protobuf.Duration value %v", tok.RawString())
}
// Validate seconds. No need to validate nanos because parseDuration would
// have covered that already.
if secs < -maxSecondsInDuration || secs > maxSecondsInDuration {
return d.newError(tok.Pos(), "google.protobuf.Duration value out of range: %v", tok.RawString())
}
fds := m.Descriptor().Fields()
fdSeconds := fds.ByNumber(fieldnum.Duration_Seconds)
fdNanos := fds.ByNumber(fieldnum.Duration_Nanos)
m.Set(fdSeconds, pref.ValueOfInt64(secs))
m.Set(fdNanos, pref.ValueOfInt32(nanos))
return nil
}
// parseDuration parses the given input string for seconds and nanoseconds value
// for the Duration JSON format. The format is a decimal number with a suffix
// 's'. It can have optional plus/minus sign. There needs to be at least an
// integer or fractional part. Fractional part is limited to 9 digits only for
// nanoseconds precision, regardless of whether there are trailing zero digits.
// Example values are 1s, 0.1s, 1.s, .1s, +1s, -1s, -.1s.
func parseDuration(input string) (int64, int32, bool) {
b := []byte(input)
size := len(b)
if size < 2 {
return 0, 0, false
}
if b[size-1] != 's' {
return 0, 0, false
}
b = b[:size-1]
// Read optional plus/minus symbol.
var neg bool
switch b[0] {
case '-':
neg = true
b = b[1:]
case '+':
b = b[1:]
}
if len(b) == 0 {
return 0, 0, false
}
// Read the integer part.
var intp []byte
switch {
case b[0] == '0':
b = b[1:]
case '1' <= b[0] && b[0] <= '9':
intp = b[0:]
b = b[1:]
n := 1
for len(b) > 0 && '0' <= b[0] && b[0] <= '9' {
n++
b = b[1:]
}
intp = intp[:n]
case b[0] == '.':
// Continue below.
default:
return 0, 0, false
}
hasFrac := false
var frac [9]byte
if len(b) > 0 {
if b[0] != '.' {
return 0, 0, false
}
// Read the fractional part.
b = b[1:]
n := 0
for len(b) > 0 && n < 9 && '0' <= b[0] && b[0] <= '9' {
frac[n] = b[0]
n++
b = b[1:]
}
// It is not valid if there are more bytes left.
if len(b) > 0 {
return 0, 0, false
}
// Pad fractional part with 0s.
for i := n; i < 9; i++ {
frac[i] = '0'
}
hasFrac = true
}
var secs int64
if len(intp) > 0 {
var err error
secs, err = strconv.ParseInt(string(intp), 10, 64)
if err != nil {
return 0, 0, false
}
}
var nanos int64
if hasFrac {
nanob := bytes.TrimLeft(frac[:], "0")
if len(nanob) > 0 {
var err error
nanos, err = strconv.ParseInt(string(nanob), 10, 32)
if err != nil {
return 0, 0, false
}
}
}
if neg {
if secs > 0 {
secs = -secs
}
if nanos > 0 {
nanos = -nanos
}
}
return secs, int32(nanos), true
}
// The JSON representation for a Timestamp is a JSON string in the RFC 3339
// format, i.e. "{year}-{month}-{day}T{hour}:{min}:{sec}[.{frac_sec}]Z" where
// {year} is always expressed using four digits while {month}, {day}, {hour},
// {min}, and {sec} are zero-padded to two digits each. The fractional seconds,
// which can go up to 9 digits, up to 1 nanosecond resolution, is optional. The
// "Z" suffix indicates the timezone ("UTC"); the timezone is required. Encoding
// should always use UTC (as indicated by "Z") and a decoder should be able to
// accept both UTC and other timezones (as indicated by an offset).
//
// Timestamp.seconds must be from 0001-01-01T00:00:00Z to 9999-12-31T23:59:59Z
// inclusive.
// Timestamp.nanos must be from 0 to 999,999,999 inclusive.
const (
maxTimestampSeconds = 253402300799
minTimestampSeconds = -62135596800
)
func (e encoder) marshalTimestamp(m pref.Message) error {
fds := m.Descriptor().Fields()
fdSeconds := fds.ByNumber(fieldnum.Timestamp_Seconds)
fdNanos := fds.ByNumber(fieldnum.Timestamp_Nanos)
secsVal := m.Get(fdSeconds)
nanosVal := m.Get(fdNanos)
secs := secsVal.Int()
nanos := nanosVal.Int()
if secs < minTimestampSeconds || secs > maxTimestampSeconds {
return errors.New("%s: seconds out of range %v", m.Descriptor().FullName(), secs)
}
if nanos < 0 || nanos > secondsInNanos {
return errors.New("%s: nanos out of range %v", m.Descriptor().FullName(), nanos)
}
// Uses RFC 3339, where generated output will be Z-normalized and uses 0, 3,
// 6 or 9 fractional digits.
t := time.Unix(secs, nanos).UTC()
x := t.Format("2006-01-02T15:04:05.000000000")
x = strings.TrimSuffix(x, "000")
x = strings.TrimSuffix(x, "000")
x = strings.TrimSuffix(x, ".000")
e.WriteString(x + "Z")
return nil
}
func (d decoder) unmarshalTimestamp(m pref.Message) error {
tok, err := d.Read()
if err != nil {
return err
}
if tok.Kind() != json.String {
return d.unexpectedTokenError(tok)
}
t, err := time.Parse(time.RFC3339Nano, tok.ParsedString())
if err != nil {
return d.newError(tok.Pos(), "invalid google.protobuf.Timestamp value %v", tok.RawString())
}
// Validate seconds. No need to validate nanos because time.Parse would have
// covered that already.
secs := t.Unix()
if secs < minTimestampSeconds || secs > maxTimestampSeconds {
return d.newError(tok.Pos(), "google.protobuf.Timestamp value out of range: %v", tok.RawString())
}
fds := m.Descriptor().Fields()
fdSeconds := fds.ByNumber(fieldnum.Timestamp_Seconds)
fdNanos := fds.ByNumber(fieldnum.Timestamp_Nanos)
m.Set(fdSeconds, pref.ValueOfInt64(secs))
m.Set(fdNanos, pref.ValueOfInt32(int32(t.Nanosecond())))
return nil
}
// The JSON representation for a FieldMask is a JSON string where paths are
// separated by a comma. Fields name in each path are converted to/from
// lower-camel naming conventions. Encoding should fail if the path name would
// end up differently after a round-trip.
func (e encoder) marshalFieldMask(m pref.Message) error {
fd := m.Descriptor().Fields().ByNumber(fieldnum.FieldMask_Paths)
list := m.Get(fd).List()
paths := make([]string, 0, list.Len())
for i := 0; i < list.Len(); i++ {
s := list.Get(i).String()
// Return error if conversion to camelCase is not reversible.
cc := strs.JSONCamelCase(s)
if s != strs.JSONSnakeCase(cc) {
return errors.New("%s.paths contains irreversible value %q", m.Descriptor().FullName(), s)
}
paths = append(paths, cc)
}
e.WriteString(strings.Join(paths, ","))
return nil
}
func (d decoder) unmarshalFieldMask(m pref.Message) error {
tok, err := d.Read()
if err != nil {
return err
}
if tok.Kind() != json.String {
return d.unexpectedTokenError(tok)
}
str := strings.TrimSpace(tok.ParsedString())
if str == "" {
return nil
}
paths := strings.Split(str, ",")
fd := m.Descriptor().Fields().ByNumber(fieldnum.FieldMask_Paths)
list := m.Mutable(fd).List()
for _, s := range paths {
s = strings.TrimSpace(s)
// Convert to snake_case. Unlike encoding, no validation is done because
// it is not possible to know the original path names.
list.Append(pref.ValueOfString(strs.JSONSnakeCase(s)))
}
return nil
}

47
vendor/google.golang.org/protobuf/internal/detectknown/detect.go generated vendored
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@@ -1,47 +0,0 @@
// Copyright 2020 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 detectknown provides functionality for detecting well-known types
// and identifying them by name.
package detectknown
import "google.golang.org/protobuf/reflect/protoreflect"
type ProtoFile int
const (
Unknown ProtoFile = iota
AnyProto
TimestampProto
DurationProto
WrappersProto
StructProto
FieldMaskProto
EmptyProto
)
var wellKnownTypes = map[protoreflect.FullName]ProtoFile{
"google.protobuf.Any": AnyProto,
"google.protobuf.Timestamp": TimestampProto,
"google.protobuf.Duration": DurationProto,
"google.protobuf.BoolValue": WrappersProto,
"google.protobuf.Int32Value": WrappersProto,
"google.protobuf.Int64Value": WrappersProto,
"google.protobuf.UInt32Value": WrappersProto,
"google.protobuf.UInt64Value": WrappersProto,
"google.protobuf.FloatValue": WrappersProto,
"google.protobuf.DoubleValue": WrappersProto,
"google.protobuf.BytesValue": WrappersProto,
"google.protobuf.StringValue": WrappersProto,
"google.protobuf.Struct": StructProto,
"google.protobuf.ListValue": StructProto,
"google.protobuf.Value": StructProto,
"google.protobuf.FieldMask": FieldMaskProto,
"google.protobuf.Empty": EmptyProto,
}
// Which identifies the proto file that a well-known type belongs to.
func Which(s protoreflect.FullName) ProtoFile {
return wellKnownTypes[s]
}

340
vendor/google.golang.org/protobuf/internal/encoding/json/decode.go generated vendored
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@@ -1,340 +0,0 @@
// 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 json
import (
"bytes"
"fmt"
"io"
"regexp"
"unicode/utf8"
"google.golang.org/protobuf/internal/errors"
)
// call specifies which Decoder method was invoked.
type call uint8
const (
readCall call = iota
peekCall
)
const unexpectedFmt = "unexpected token %s"
// ErrUnexpectedEOF means that EOF was encountered in the middle of the input.
var ErrUnexpectedEOF = errors.New("%v", io.ErrUnexpectedEOF)
// Decoder is a token-based JSON decoder.
type Decoder struct {
// lastCall is last method called, either readCall or peekCall.
// Initial value is readCall.
lastCall call
// lastToken contains the last read token.
lastToken Token
// lastErr contains the last read error.
lastErr error
// openStack is a stack containing ObjectOpen and ArrayOpen values. The
// top of stack represents the object or the array the current value is
// directly located in.
openStack []Kind
// orig is used in reporting line and column.
orig []byte
// in contains the unconsumed input.
in []byte
}
// NewDecoder returns a Decoder to read the given []byte.
func NewDecoder(b []byte) *Decoder {
return &Decoder{orig: b, in: b}
}
// Peek looks ahead and returns the next token kind without advancing a read.
func (d *Decoder) Peek() (Token, error) {
defer func() { d.lastCall = peekCall }()
if d.lastCall == readCall {
d.lastToken, d.lastErr = d.Read()
}
return d.lastToken, d.lastErr
}
// Read returns the next JSON token.
// It will return an error if there is no valid token.
func (d *Decoder) Read() (Token, error) {
const scalar = Null | Bool | Number | String
defer func() { d.lastCall = readCall }()
if d.lastCall == peekCall {
return d.lastToken, d.lastErr
}
tok, err := d.parseNext()
if err != nil {
return Token{}, err
}
switch tok.kind {
case EOF:
if len(d.openStack) != 0 ||
d.lastToken.kind&scalar|ObjectClose|ArrayClose == 0 {
return Token{}, ErrUnexpectedEOF
}
case Null:
if !d.isValueNext() {
return Token{}, d.newSyntaxError(tok.pos, unexpectedFmt, tok.RawString())
}
case Bool, Number:
if !d.isValueNext() {
return Token{}, d.newSyntaxError(tok.pos, unexpectedFmt, tok.RawString())
}
case String:
if d.isValueNext() {
break
}
// This string token should only be for a field name.
if d.lastToken.kind&(ObjectOpen|comma) == 0 {
return Token{}, d.newSyntaxError(tok.pos, unexpectedFmt, tok.RawString())
}
if len(d.in) == 0 {
return Token{}, ErrUnexpectedEOF
}
if c := d.in[0]; c != ':' {
return Token{}, d.newSyntaxError(d.currPos(), `unexpected character %s, missing ":" after field name`, string(c))
}
tok.kind = Name
d.consume(1)
case ObjectOpen, ArrayOpen:
if !d.isValueNext() {
return Token{}, d.newSyntaxError(tok.pos, unexpectedFmt, tok.RawString())
}
d.openStack = append(d.openStack, tok.kind)
case ObjectClose:
if len(d.openStack) == 0 ||
d.lastToken.kind == comma ||
d.openStack[len(d.openStack)-1] != ObjectOpen {
return Token{}, d.newSyntaxError(tok.pos, unexpectedFmt, tok.RawString())
}
d.openStack = d.openStack[:len(d.openStack)-1]
case ArrayClose:
if len(d.openStack) == 0 ||
d.lastToken.kind == comma ||
d.openStack[len(d.openStack)-1] != ArrayOpen {
return Token{}, d.newSyntaxError(tok.pos, unexpectedFmt, tok.RawString())
}
d.openStack = d.openStack[:len(d.openStack)-1]
case comma:
if len(d.openStack) == 0 ||
d.lastToken.kind&(scalar|ObjectClose|ArrayClose) == 0 {
return Token{}, d.newSyntaxError(tok.pos, unexpectedFmt, tok.RawString())
}
}
// Update d.lastToken only after validating token to be in the right sequence.
d.lastToken = tok
if d.lastToken.kind == comma {
return d.Read()
}
return tok, nil
}
// Any sequence that looks like a non-delimiter (for error reporting).
var errRegexp = regexp.MustCompile(`^([-+._a-zA-Z0-9]{1,32}|.)`)
// parseNext parses for the next JSON token. It returns a Token object for
// different types, except for Name. It does not handle whether the next token
// is in a valid sequence or not.
func (d *Decoder) parseNext() (Token, error) {
// Trim leading spaces.
d.consume(0)
in := d.in
if len(in) == 0 {
return d.consumeToken(EOF, 0), nil
}
switch in[0] {
case 'n':
if n := matchWithDelim("null", in); n != 0 {
return d.consumeToken(Null, n), nil
}
case 't':
if n := matchWithDelim("true", in); n != 0 {
return d.consumeBoolToken(true, n), nil
}
case 'f':
if n := matchWithDelim("false", in); n != 0 {
return d.consumeBoolToken(false, n), nil
}
case '-', '0', '1', '2', '3', '4', '5', '6', '7', '8', '9':
if n, ok := parseNumber(in); ok {
return d.consumeToken(Number, n), nil
}
case '"':
s, n, err := d.parseString(in)
if err != nil {
return Token{}, err
}
return d.consumeStringToken(s, n), nil
case '{':
return d.consumeToken(ObjectOpen, 1), nil
case '}':
return d.consumeToken(ObjectClose, 1), nil
case '[':
return d.consumeToken(ArrayOpen, 1), nil
case ']':
return d.consumeToken(ArrayClose, 1), nil
case ',':
return d.consumeToken(comma, 1), nil
}
return Token{}, d.newSyntaxError(d.currPos(), "invalid value %s", errRegexp.Find(in))
}
// newSyntaxError returns an error with line and column information useful for
// syntax errors.
func (d *Decoder) newSyntaxError(pos int, f string, x ...interface{}) error {
e := errors.New(f, x...)
line, column := d.Position(pos)
return errors.New("syntax error (line %d:%d): %v", line, column, e)
}
// Position returns line and column number of given index of the original input.
// It will panic if index is out of range.
func (d *Decoder) Position(idx int) (line int, column int) {
b := d.orig[:idx]
line = bytes.Count(b, []byte("\n")) + 1
if i := bytes.LastIndexByte(b, '\n'); i >= 0 {
b = b[i+1:]
}
column = utf8.RuneCount(b) + 1 // ignore multi-rune characters
return line, column
}
// currPos returns the current index position of d.in from d.orig.
func (d *Decoder) currPos() int {
return len(d.orig) - len(d.in)
}
// matchWithDelim matches s with the input b and verifies that the match
// terminates with a delimiter of some form (e.g., r"[^-+_.a-zA-Z0-9]").
// As a special case, EOF is considered a delimiter. It returns the length of s
// if there is a match, else 0.
func matchWithDelim(s string, b []byte) int {
if !bytes.HasPrefix(b, []byte(s)) {
return 0
}
n := len(s)
if n < len(b) && isNotDelim(b[n]) {
return 0
}
return n
}
// isNotDelim returns true if given byte is a not delimiter character.
func isNotDelim(c byte) bool {
return (c == '-' || c == '+' || c == '.' || c == '_' ||
('a' <= c && c <= 'z') ||
('A' <= c && c <= 'Z') ||
('0' <= c && c <= '9'))
}
// consume consumes n bytes of input and any subsequent whitespace.
func (d *Decoder) consume(n int) {
d.in = d.in[n:]
for len(d.in) > 0 {
switch d.in[0] {
case ' ', '\n', '\r', '\t':
d.in = d.in[1:]
default:
return
}
}
}
// isValueNext returns true if next type should be a JSON value: Null,
// Number, String or Bool.
func (d *Decoder) isValueNext() bool {
if len(d.openStack) == 0 {
return d.lastToken.kind == 0
}
start := d.openStack[len(d.openStack)-1]
switch start {
case ObjectOpen:
return d.lastToken.kind&Name != 0
case ArrayOpen:
return d.lastToken.kind&(ArrayOpen|comma) != 0
}
panic(fmt.Sprintf(
"unreachable logic in Decoder.isValueNext, lastToken.kind: %v, openStack: %v",
d.lastToken.kind, start))
}
// consumeToken constructs a Token for given Kind with raw value derived from
// current d.in and given size, and consumes the given size-lenght of it.
func (d *Decoder) consumeToken(kind Kind, size int) Token {
tok := Token{
kind: kind,
raw: d.in[:size],
pos: len(d.orig) - len(d.in),
}
d.consume(size)
return tok
}
// consumeBoolToken constructs a Token for a Bool kind with raw value derived from
// current d.in and given size.
func (d *Decoder) consumeBoolToken(b bool, size int) Token {
tok := Token{
kind: Bool,
raw: d.in[:size],
pos: len(d.orig) - len(d.in),
boo: b,
}
d.consume(size)
return tok
}
// consumeStringToken constructs a Token for a String kind with raw value derived
// from current d.in and given size.
func (d *Decoder) consumeStringToken(s string, size int) Token {
tok := Token{
kind: String,
raw: d.in[:size],
pos: len(d.orig) - len(d.in),
str: s,
}
d.consume(size)
return tok
}
// Clone returns a copy of the Decoder for use in reading ahead the next JSON
// object, array or other values without affecting current Decoder.
func (d *Decoder) Clone() *Decoder {
ret := *d
ret.openStack = append([]Kind(nil), ret.openStack...)
return &ret
}

254
vendor/google.golang.org/protobuf/internal/encoding/json/decode_number.go generated vendored
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@@ -1,254 +0,0 @@
// 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 json
import (
"bytes"
"strconv"
)
// parseNumber reads the given []byte for a valid JSON number. If it is valid,
// it returns the number of bytes. Parsing logic follows the definition in
// https://tools.ietf.org/html/rfc7159#section-6, and is based off
// encoding/json.isValidNumber function.
func parseNumber(input []byte) (int, bool) {
var n int
s := input
if len(s) == 0 {
return 0, false
}
// Optional -
if s[0] == '-' {
s = s[1:]
n++
if len(s) == 0 {
return 0, false
}
}
// Digits
switch {
case s[0] == '0':
s = s[1:]
n++
case '1' <= s[0] && s[0] <= '9':
s = s[1:]
n++
for len(s) > 0 && '0' <= s[0] && s[0] <= '9' {
s = s[1:]
n++
}
default:
return 0, false
}
// . followed by 1 or more digits.
if len(s) >= 2 && s[0] == '.' && '0' <= s[1] && s[1] <= '9' {
s = s[2:]
n += 2
for len(s) > 0 && '0' <= s[0] && s[0] <= '9' {
s = s[1:]
n++
}
}
// e or E followed by an optional - or + and
// 1 or more digits.
if len(s) >= 2 && (s[0] == 'e' || s[0] == 'E') {
s = s[1:]
n++
if s[0] == '+' || s[0] == '-' {
s = s[1:]
n++
if len(s) == 0 {
return 0, false
}
}
for len(s) > 0 && '0' <= s[0] && s[0] <= '9' {
s = s[1:]
n++
}
}
// Check that next byte is a delimiter or it is at the end.
if n < len(input) && isNotDelim(input[n]) {
return 0, false
}
return n, true
}
// numberParts is the result of parsing out a valid JSON number. It contains
// the parts of a number. The parts are used for integer conversion.
type numberParts struct {
neg bool
intp []byte
frac []byte
exp []byte
}
// parseNumber constructs numberParts from given []byte. The logic here is
// similar to consumeNumber above with the difference of having to construct
// numberParts. The slice fields in numberParts are subslices of the input.
func parseNumberParts(input []byte) (numberParts, bool) {
var neg bool
var intp []byte
var frac []byte
var exp []byte
s := input
if len(s) == 0 {
return numberParts{}, false
}
// Optional -
if s[0] == '-' {
neg = true
s = s[1:]
if len(s) == 0 {
return numberParts{}, false
}
}
// Digits
switch {
case s[0] == '0':
// Skip first 0 and no need to store.
s = s[1:]
case '1' <= s[0] && s[0] <= '9':
intp = s
n := 1
s = s[1:]
for len(s) > 0 && '0' <= s[0] && s[0] <= '9' {
s = s[1:]
n++
}
intp = intp[:n]
default:
return numberParts{}, false
}
// . followed by 1 or more digits.
if len(s) >= 2 && s[0] == '.' && '0' <= s[1] && s[1] <= '9' {
frac = s[1:]
n := 1
s = s[2:]
for len(s) > 0 && '0' <= s[0] && s[0] <= '9' {
s = s[1:]
n++
}
frac = frac[:n]
}
// e or E followed by an optional - or + and
// 1 or more digits.
if len(s) >= 2 && (s[0] == 'e' || s[0] == 'E') {
s = s[1:]
exp = s
n := 0
if s[0] == '+' || s[0] == '-' {
s = s[1:]
n++
if len(s) == 0 {
return numberParts{}, false
}
}
for len(s) > 0 && '0' <= s[0] && s[0] <= '9' {
s = s[1:]
n++
}
exp = exp[:n]
}
return numberParts{
neg: neg,
intp: intp,
frac: bytes.TrimRight(frac, "0"), // Remove unnecessary 0s to the right.
exp: exp,
}, true
}
// normalizeToIntString returns an integer string in normal form without the
// E-notation for given numberParts. It will return false if it is not an
// integer or if the exponent exceeds than max/min int value.
func normalizeToIntString(n numberParts) (string, bool) {
intpSize := len(n.intp)
fracSize := len(n.frac)
if intpSize == 0 && fracSize == 0 {
return "0", true
}
var exp int
if len(n.exp) > 0 {
i, err := strconv.ParseInt(string(n.exp), 10, 32)
if err != nil {
return "", false
}
exp = int(i)
}
var num []byte
if exp >= 0 {
// For positive E, shift fraction digits into integer part and also pad
// with zeroes as needed.
// If there are more digits in fraction than the E value, then the
// number is not an integer.
if fracSize > exp {
return "", false
}
// Make sure resulting digits are within max value limit to avoid
// unnecessarily constructing a large byte slice that may simply fail
// later on.
const maxDigits = 20 // Max uint64 value has 20 decimal digits.
if intpSize+exp > maxDigits {
return "", false
}
// Set cap to make a copy of integer part when appended.
num = n.intp[:len(n.intp):len(n.intp)]
num = append(num, n.frac...)
for i := 0; i < exp-fracSize; i++ {
num = append(num, '0')
}
} else {
// For negative E, shift digits in integer part out.
// If there are fractions, then the number is not an integer.
if fracSize > 0 {
return "", false
}
// index is where the decimal point will be after adjusting for negative
// exponent.
index := intpSize + exp
if index < 0 {
return "", false
}
num = n.intp
// If any of the digits being shifted to the right of the decimal point
// is non-zero, then the number is not an integer.
for i := index; i < intpSize; i++ {
if num[i] != '0' {
return "", false
}
}
num = num[:index]
}
if n.neg {
return "-" + string(num), true
}
return string(num), true
}

91
vendor/google.golang.org/protobuf/internal/encoding/json/decode_string.go generated vendored
View File

@@ -1,91 +0,0 @@
// 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 json
import (
"strconv"
"unicode"
"unicode/utf16"
"unicode/utf8"
"google.golang.org/protobuf/internal/strs"
)
func (d *Decoder) parseString(in []byte) (string, int, error) {
in0 := in
if len(in) == 0 {
return "", 0, ErrUnexpectedEOF
}
if in[0] != '"' {
return "", 0, d.newSyntaxError(d.currPos(), "invalid character %q at start of string", in[0])
}
in = in[1:]
i := indexNeedEscapeInBytes(in)
in, out := in[i:], in[:i:i] // set cap to prevent mutations
for len(in) > 0 {
switch r, n := utf8.DecodeRune(in); {
case r == utf8.RuneError && n == 1:
return "", 0, d.newSyntaxError(d.currPos(), "invalid UTF-8 in string")
case r < ' ':
return "", 0, d.newSyntaxError(d.currPos(), "invalid character %q in string", r)
case r == '"':
in = in[1:]
n := len(in0) - len(in)
return string(out), n, nil
case r == '\\':
if len(in) < 2 {
return "", 0, ErrUnexpectedEOF
}
switch r := in[1]; r {
case '"', '\\', '/':
in, out = in[2:], append(out, r)
case 'b':
in, out = in[2:], append(out, '\b')
case 'f':
in, out = in[2:], append(out, '\f')
case 'n':
in, out = in[2:], append(out, '\n')
case 'r':
in, out = in[2:], append(out, '\r')
case 't':
in, out = in[2:], append(out, '\t')
case 'u':
if len(in) < 6 {
return "", 0, ErrUnexpectedEOF
}
v, err := strconv.ParseUint(string(in[2:6]), 16, 16)
if err != nil {
return "", 0, d.newSyntaxError(d.currPos(), "invalid escape code %q in string", in[:6])
}
in = in[6:]
r := rune(v)
if utf16.IsSurrogate(r) {
if len(in) < 6 {
return "", 0, ErrUnexpectedEOF
}
v, err := strconv.ParseUint(string(in[2:6]), 16, 16)
r = utf16.DecodeRune(r, rune(v))
if in[0] != '\\' || in[1] != 'u' ||
r == unicode.ReplacementChar || err != nil {
return "", 0, d.newSyntaxError(d.currPos(), "invalid escape code %q in string", in[:6])
}
in = in[6:]
}
out = append(out, string(r)...)
default:
return "", 0, d.newSyntaxError(d.currPos(), "invalid escape code %q in string", in[:2])
}
default:
i := indexNeedEscapeInBytes(in[n:])
in, out = in[n+i:], append(out, in[:n+i]...)
}
}
return "", 0, ErrUnexpectedEOF
}
// indexNeedEscapeInBytes returns the index of the character that needs
// escaping. If no characters need escaping, this returns the input length.
func indexNeedEscapeInBytes(b []byte) int { return indexNeedEscapeInString(strs.UnsafeString(b)) }

193
vendor/google.golang.org/protobuf/internal/encoding/json/decode_token.go generated vendored
View File

@@ -1,193 +0,0 @@
// Copyright 2019 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 json
import (
"bytes"
"fmt"
"strconv"
)
// Kind represents a token kind expressible in the JSON format.
type Kind uint16
const (
Invalid Kind = (1 << iota) / 2
EOF
Null
Bool
Number
String
Name
ObjectOpen
ObjectClose
ArrayOpen
ArrayClose
// comma is only for parsing in between tokens and
// does not need to be exported.
comma
)
func (k Kind) String() string {
switch k {
case EOF:
return "eof"
case Null:
return "null"
case Bool:
return "bool"
case Number:
return "number"
case String:
return "string"
case ObjectOpen:
return "{"
case ObjectClose:
return "}"
case Name:
return "name"
case ArrayOpen:
return "["
case ArrayClose:
return "]"
case comma:
return ","
}
return "<invalid>"
}
// Token provides a parsed token kind and value.
//
// Values are provided by the difference accessor methods. The accessor methods
// Name, Bool, and ParsedString will panic if called on the wrong kind. There
// are different accessor methods for the Number kind for converting to the
// appropriate Go numeric type and those methods have the ok return value.
type Token struct {
// Token kind.
kind Kind
// pos provides the position of the token in the original input.
pos int
// raw bytes of the serialized token.
// This is a subslice into the original input.
raw []byte
// boo is parsed boolean value.
boo bool
// str is parsed string value.
str string
}
// Kind returns the token kind.
func (t Token) Kind() Kind {
return t.kind
}
// RawString returns the read value in string.
func (t Token) RawString() string {
return string(t.raw)
}
// Pos returns the token position from the input.
func (t Token) Pos() int {
return t.pos
}
// Name returns the object name if token is Name, else it will return an error.
func (t Token) Name() string {
if t.kind == Name {
return t.str
}
panic(fmt.Sprintf("Token is not a Name: %v", t.RawString()))
}
// Bool returns the bool value if token kind is Bool, else it panics.
func (t Token) Bool() bool {
if t.kind == Bool {
return t.boo
}
panic(fmt.Sprintf("Token is not a Bool: %v", t.RawString()))
}
// ParsedString returns the string value for a JSON string token or the read
// value in string if token is not a string.
func (t Token) ParsedString() string {
if t.kind == String {
return t.str
}
panic(fmt.Sprintf("Token is not a String: %v", t.RawString()))
}
// Float returns the floating-point number if token kind is Number.
//
// The floating-point precision is specified by the bitSize parameter: 32 for
// float32 or 64 for float64. If bitSize=32, the result still has type float64,
// but it will be convertible to float32 without changing its value. It will
// return false if the number exceeds the floating point limits for given
// bitSize.
func (t Token) Float(bitSize int) (float64, bool) {
if t.kind != Number {
return 0, false
}
f, err := strconv.ParseFloat(t.RawString(), bitSize)
if err != nil {
return 0, false
}
return f, true
}
// Int returns the signed integer number if token is Number.
//
// The given bitSize specifies the integer type that the result must fit into.
// It returns false if the number is not an integer value or if the result
// exceeds the limits for given bitSize.
func (t Token) Int(bitSize int) (int64, bool) {
s, ok := t.getIntStr()
if !ok {
return 0, false
}
n, err := strconv.ParseInt(s, 10, bitSize)
if err != nil {
return 0, false
}
return n, true
}
// Uint returns the signed integer number if token is Number, else it will
// return an error.
//
// The given bitSize specifies the unsigned integer type that the result must
// fit into. It returns false if the number is not an unsigned integer value
// or if the result exceeds the limits for given bitSize.
func (t Token) Uint(bitSize int) (uint64, bool) {
s, ok := t.getIntStr()
if !ok {
return 0, false
}
n, err := strconv.ParseUint(s, 10, bitSize)
if err != nil {
return 0, false
}
return n, true
}
func (t Token) getIntStr() (string, bool) {
if t.kind != Number {
return "", false
}
parts, ok := parseNumberParts(t.raw)
if !ok {
return "", false
}
return normalizeToIntString(parts)
}
// TokenEquals returns true if given Tokens are equal, else false.
func TokenEquals(x, y Token) bool {
return x.kind == y.kind &&
x.pos == y.pos &&
bytes.Equal(x.raw, y.raw) &&
x.boo == y.boo &&
x.str == y.str
}

276
vendor/google.golang.org/protobuf/internal/encoding/json/encode.go generated vendored
View File

@@ -1,276 +0,0 @@
// 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 json
import (
"math"
"math/bits"
"strconv"
"strings"
"unicode/utf8"
"google.golang.org/protobuf/internal/detrand"
"google.golang.org/protobuf/internal/errors"
)
// kind represents an encoding type.
type kind uint8
const (
_ kind = (1 << iota) / 2
name
scalar
objectOpen
objectClose
arrayOpen
arrayClose
)
// Encoder provides methods to write out JSON constructs and values. The user is
// responsible for producing valid sequences of JSON constructs and values.
type Encoder struct {
indent string
lastKind kind
indents []byte
out []byte
}
// NewEncoder returns an Encoder.
//
// If indent is a non-empty string, it causes every entry for an Array or Object
// to be preceded by the indent and trailed by a newline.
func NewEncoder(indent string) (*Encoder, error) {
e := &Encoder{}
if len(indent) > 0 {
if strings.Trim(indent, " \t") != "" {
return nil, errors.New("indent may only be composed of space or tab characters")
}
e.indent = indent
}
return e, nil
}
// Bytes returns the content of the written bytes.
func (e *Encoder) Bytes() []byte {
return e.out
}
// WriteNull writes out the null value.
func (e *Encoder) WriteNull() {
e.prepareNext(scalar)
e.out = append(e.out, "null"...)
}
// WriteBool writes out the given boolean value.
func (e *Encoder) WriteBool(b bool) {
e.prepareNext(scalar)
if b {
e.out = append(e.out, "true"...)
} else {
e.out = append(e.out, "false"...)
}
}
// WriteString writes out the given string in JSON string value. Returns error
// if input string contains invalid UTF-8.
func (e *Encoder) WriteString(s string) error {
e.prepareNext(scalar)
var err error
if e.out, err = appendString(e.out, s); err != nil {
return err
}
return nil
}
// Sentinel error used for indicating invalid UTF-8.
var errInvalidUTF8 = errors.New("invalid UTF-8")
func appendString(out []byte, in string) ([]byte, error) {
out = append(out, '"')
i := indexNeedEscapeInString(in)
in, out = in[i:], append(out, in[:i]...)
for len(in) > 0 {
switch r, n := utf8.DecodeRuneInString(in); {
case r == utf8.RuneError && n == 1:
return out, errInvalidUTF8
case r < ' ' || r == '"' || r == '\\':
out = append(out, '\\')
switch r {
case '"', '\\':
out = append(out, byte(r))
case '\b':
out = append(out, 'b')
case '\f':
out = append(out, 'f')
case '\n':
out = append(out, 'n')
case '\r':
out = append(out, 'r')
case '\t':
out = append(out, 't')
default:
out = append(out, 'u')
out = append(out, "0000"[1+(bits.Len32(uint32(r))-1)/4:]...)
out = strconv.AppendUint(out, uint64(r), 16)
}
in = in[n:]
default:
i := indexNeedEscapeInString(in[n:])
in, out = in[n+i:], append(out, in[:n+i]...)
}
}
out = append(out, '"')
return out, nil
}
// indexNeedEscapeInString returns the index of the character that needs
// escaping. If no characters need escaping, this returns the input length.
func indexNeedEscapeInString(s string) int {
for i, r := range s {
if r < ' ' || r == '\\' || r == '"' || r == utf8.RuneError {
return i
}
}
return len(s)
}
// WriteFloat writes out the given float and bitSize in JSON number value.
func (e *Encoder) WriteFloat(n float64, bitSize int) {
e.prepareNext(scalar)
e.out = appendFloat(e.out, n, bitSize)
}
// appendFloat formats given float in bitSize, and appends to the given []byte.
func appendFloat(out []byte, n float64, bitSize int) []byte {
switch {
case math.IsNaN(n):
return append(out, `"NaN"`...)
case math.IsInf(n, +1):
return append(out, `"Infinity"`...)
case math.IsInf(n, -1):
return append(out, `"-Infinity"`...)
}
// JSON number formatting logic based on encoding/json.
// See floatEncoder.encode for reference.
fmt := byte('f')
if abs := math.Abs(n); abs != 0 {
if bitSize == 64 && (abs < 1e-6 || abs >= 1e21) ||
bitSize == 32 && (float32(abs) < 1e-6 || float32(abs) >= 1e21) {
fmt = 'e'
}
}
out = strconv.AppendFloat(out, n, fmt, -1, bitSize)
if fmt == 'e' {
n := len(out)
if n >= 4 && out[n-4] == 'e' && out[n-3] == '-' && out[n-2] == '0' {
out[n-2] = out[n-1]
out = out[:n-1]
}
}
return out
}
// WriteInt writes out the given signed integer in JSON number value.
func (e *Encoder) WriteInt(n int64) {
e.prepareNext(scalar)
e.out = append(e.out, strconv.FormatInt(n, 10)...)
}
// WriteUint writes out the given unsigned integer in JSON number value.
func (e *Encoder) WriteUint(n uint64) {
e.prepareNext(scalar)
e.out = append(e.out, strconv.FormatUint(n, 10)...)
}
// StartObject writes out the '{' symbol.
func (e *Encoder) StartObject() {
e.prepareNext(objectOpen)
e.out = append(e.out, '{')
}
// EndObject writes out the '}' symbol.
func (e *Encoder) EndObject() {
e.prepareNext(objectClose)
e.out = append(e.out, '}')
}
// WriteName writes out the given string in JSON string value and the name
// separator ':'. Returns error if input string contains invalid UTF-8, which
// should not be likely as protobuf field names should be valid.
func (e *Encoder) WriteName(s string) error {
e.prepareNext(name)
var err error
// Append to output regardless of error.
e.out, err = appendString(e.out, s)
e.out = append(e.out, ':')
return err
}
// StartArray writes out the '[' symbol.
func (e *Encoder) StartArray() {
e.prepareNext(arrayOpen)
e.out = append(e.out, '[')
}
// EndArray writes out the ']' symbol.
func (e *Encoder) EndArray() {
e.prepareNext(arrayClose)
e.out = append(e.out, ']')
}
// prepareNext adds possible comma and indentation for the next value based
// on last type and indent option. It also updates lastKind to next.
func (e *Encoder) prepareNext(next kind) {
defer func() {
// Set lastKind to next.
e.lastKind = next
}()
if len(e.indent) == 0 {
// Need to add comma on the following condition.
if e.lastKind&(scalar|objectClose|arrayClose) != 0 &&
next&(name|scalar|objectOpen|arrayOpen) != 0 {
e.out = append(e.out, ',')
// For single-line output, add a random extra space after each
// comma to make output unstable.
if detrand.Bool() {
e.out = append(e.out, ' ')
}
}
return
}
switch {
case e.lastKind&(objectOpen|arrayOpen) != 0:
// If next type is NOT closing, add indent and newline.
if next&(objectClose|arrayClose) == 0 {
e.indents = append(e.indents, e.indent...)
e.out = append(e.out, '\n')
e.out = append(e.out, e.indents...)
}
case e.lastKind&(scalar|objectClose|arrayClose) != 0:
switch {
// If next type is either a value or name, add comma and newline.
case next&(name|scalar|objectOpen|arrayOpen) != 0:
e.out = append(e.out, ',', '\n')
// If next type is a closing object or array, adjust indentation.
case next&(objectClose|arrayClose) != 0:
e.indents = e.indents[:len(e.indents)-len(e.indent)]
e.out = append(e.out, '\n')
}
e.out = append(e.out, e.indents...)
case e.lastKind&name != 0:
e.out = append(e.out, ' ')
// For multi-line output, add a random extra space after key: to make
// output unstable.
if detrand.Bool() {
e.out = append(e.out, ' ')
}
}
}

275
vendor/google.golang.org/protobuf/reflect/protodesc/desc.go generated vendored
View File

@@ -1,275 +0,0 @@
// 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 protodesc provides functionality for converting
// FileDescriptorProto messages to/from protoreflect.FileDescriptor values.
//
// The google.protobuf.FileDescriptorProto is a protobuf message that describes
// the type information for a .proto file in a form that is easily serializable.
// The protoreflect.FileDescriptor is a more structured representation of
// the FileDescriptorProto message where references and remote dependencies
// can be directly followed.
package protodesc
import (
"google.golang.org/protobuf/internal/errors"
"google.golang.org/protobuf/internal/filedesc"
"google.golang.org/protobuf/internal/pragma"
"google.golang.org/protobuf/internal/strs"
"google.golang.org/protobuf/proto"
"google.golang.org/protobuf/reflect/protoreflect"
"google.golang.org/protobuf/reflect/protoregistry"
"google.golang.org/protobuf/types/descriptorpb"
)
// Resolver is the resolver used by NewFile to resolve dependencies.
// The enums and messages provided must belong to some parent file,
// which is also registered.
//
// It is implemented by protoregistry.Files.
type Resolver interface {
FindFileByPath(string) (protoreflect.FileDescriptor, error)
FindDescriptorByName(protoreflect.FullName) (protoreflect.Descriptor, error)
}
// FileOptions configures the construction of file descriptors.
type FileOptions struct {
pragma.NoUnkeyedLiterals
// AllowUnresolvable configures New to permissively allow unresolvable
// file, enum, or message dependencies. Unresolved dependencies are replaced
// by placeholder equivalents.
//
// The following dependencies may be left unresolved:
// • Resolving an imported file.
// • Resolving the type for a message field or extension field.
// If the kind of the field is unknown, then a placeholder is used for both
// the Enum and Message accessors on the protoreflect.FieldDescriptor.
// • Resolving an enum value set as the default for an optional enum field.
// If unresolvable, the protoreflect.FieldDescriptor.Default is set to the
// first value in the associated enum (or zero if the also enum dependency
// is also unresolvable). The protoreflect.FieldDescriptor.DefaultEnumValue
// is populated with a placeholder.
// • Resolving the extended message type for an extension field.
// • Resolving the input or output message type for a service method.
//
// If the unresolved dependency uses a relative name,
// then the placeholder will contain an invalid FullName with a "*." prefix,
// indicating that the starting prefix of the full name is unknown.
AllowUnresolvable bool
}
// NewFile creates a new protoreflect.FileDescriptor from the provided
// file descriptor message. See FileOptions.New for more information.
func NewFile(fd *descriptorpb.FileDescriptorProto, r Resolver) (protoreflect.FileDescriptor, error) {
return FileOptions{}.New(fd, r)
}
// NewFiles creates a new protoregistry.Files from the provided
// FileDescriptorSet message. See FileOptions.NewFiles for more information.
func NewFiles(fd *descriptorpb.FileDescriptorSet) (*protoregistry.Files, error) {
return FileOptions{}.NewFiles(fd)
}
// New creates a new protoreflect.FileDescriptor from the provided
// file descriptor message. The file must represent a valid proto file according
// to protobuf semantics. The returned descriptor is a deep copy of the input.
//
// Any imported files, enum types, or message types referenced in the file are
// resolved using the provided registry. When looking up an import file path,
// the path must be unique. The newly created file descriptor is not registered
// back into the provided file registry.
func (o FileOptions) New(fd *descriptorpb.FileDescriptorProto, r Resolver) (protoreflect.FileDescriptor, error) {
if r == nil {
r = (*protoregistry.Files)(nil) // empty resolver
}
// Handle the file descriptor content.
f := &filedesc.File{L2: &filedesc.FileL2{}}
switch fd.GetSyntax() {
case "proto2", "":
f.L1.Syntax = protoreflect.Proto2
case "proto3":
f.L1.Syntax = protoreflect.Proto3
default:
return nil, errors.New("invalid syntax: %q", fd.GetSyntax())
}
f.L1.Path = fd.GetName()
if f.L1.Path == "" {
return nil, errors.New("file path must be populated")
}
f.L1.Package = protoreflect.FullName(fd.GetPackage())
if !f.L1.Package.IsValid() && f.L1.Package != "" {
return nil, errors.New("invalid package: %q", f.L1.Package)
}
if opts := fd.GetOptions(); opts != nil {
opts = proto.Clone(opts).(*descriptorpb.FileOptions)
f.L2.Options = func() protoreflect.ProtoMessage { return opts }
}
f.L2.Imports = make(filedesc.FileImports, len(fd.GetDependency()))
for _, i := range fd.GetPublicDependency() {
if !(0 <= i && int(i) < len(f.L2.Imports)) || f.L2.Imports[i].IsPublic {
return nil, errors.New("invalid or duplicate public import index: %d", i)
}
f.L2.Imports[i].IsPublic = true
}
for _, i := range fd.GetWeakDependency() {
if !(0 <= i && int(i) < len(f.L2.Imports)) || f.L2.Imports[i].IsWeak {
return nil, errors.New("invalid or duplicate weak import index: %d", i)
}
f.L2.Imports[i].IsWeak = true
}
imps := importSet{f.Path(): true}
for i, path := range fd.GetDependency() {
imp := &f.L2.Imports[i]
f, err := r.FindFileByPath(path)
if err == protoregistry.NotFound && (o.AllowUnresolvable || imp.IsWeak) {
f = filedesc.PlaceholderFile(path)
} else if err != nil {
return nil, errors.New("could not resolve import %q: %v", path, err)
}
imp.FileDescriptor = f
if imps[imp.Path()] {
return nil, errors.New("already imported %q", path)
}
imps[imp.Path()] = true
}
for i := range fd.GetDependency() {
imp := &f.L2.Imports[i]
imps.importPublic(imp.Imports())
}
// Handle source locations.
for _, loc := range fd.GetSourceCodeInfo().GetLocation() {
var l protoreflect.SourceLocation
// TODO: Validate that the path points to an actual declaration?
l.Path = protoreflect.SourcePath(loc.GetPath())
s := loc.GetSpan()
switch len(s) {
case 3:
l.StartLine, l.StartColumn, l.EndLine, l.EndColumn = int(s[0]), int(s[1]), int(s[0]), int(s[2])
case 4:
l.StartLine, l.StartColumn, l.EndLine, l.EndColumn = int(s[0]), int(s[1]), int(s[2]), int(s[3])
default:
return nil, errors.New("invalid span: %v", s)
}
// TODO: Validate that the span information is sensible?
// See https://github.com/protocolbuffers/protobuf/issues/6378.
if false && (l.EndLine < l.StartLine || l.StartLine < 0 || l.StartColumn < 0 || l.EndColumn < 0 ||
(l.StartLine == l.EndLine && l.EndColumn <= l.StartColumn)) {
return nil, errors.New("invalid span: %v", s)
}
l.LeadingDetachedComments = loc.GetLeadingDetachedComments()
l.LeadingComments = loc.GetLeadingComments()
l.TrailingComments = loc.GetTrailingComments()
f.L2.Locations.List = append(f.L2.Locations.List, l)
}
// Step 1: Allocate and derive the names for all declarations.
// This copies all fields from the descriptor proto except:
// google.protobuf.FieldDescriptorProto.type_name
// google.protobuf.FieldDescriptorProto.default_value
// google.protobuf.FieldDescriptorProto.oneof_index
// google.protobuf.FieldDescriptorProto.extendee
// google.protobuf.MethodDescriptorProto.input
// google.protobuf.MethodDescriptorProto.output
var err error
sb := new(strs.Builder)
r1 := make(descsByName)
if f.L1.Enums.List, err = r1.initEnumDeclarations(fd.GetEnumType(), f, sb); err != nil {
return nil, err
}
if f.L1.Messages.List, err = r1.initMessagesDeclarations(fd.GetMessageType(), f, sb); err != nil {
return nil, err
}
if f.L1.Extensions.List, err = r1.initExtensionDeclarations(fd.GetExtension(), f, sb); err != nil {
return nil, err
}
if f.L1.Services.List, err = r1.initServiceDeclarations(fd.GetService(), f, sb); err != nil {
return nil, err
}
// Step 2: Resolve every dependency reference not handled by step 1.
r2 := &resolver{local: r1, remote: r, imports: imps, allowUnresolvable: o.AllowUnresolvable}
if err := r2.resolveMessageDependencies(f.L1.Messages.List, fd.GetMessageType()); err != nil {
return nil, err
}
if err := r2.resolveExtensionDependencies(f.L1.Extensions.List, fd.GetExtension()); err != nil {
return nil, err
}
if err := r2.resolveServiceDependencies(f.L1.Services.List, fd.GetService()); err != nil {
return nil, err
}
// Step 3: Validate every enum, message, and extension declaration.
if err := validateEnumDeclarations(f.L1.Enums.List, fd.GetEnumType()); err != nil {
return nil, err
}
if err := validateMessageDeclarations(f.L1.Messages.List, fd.GetMessageType()); err != nil {
return nil, err
}
if err := validateExtensionDeclarations(f.L1.Extensions.List, fd.GetExtension()); err != nil {
return nil, err
}
return f, nil
}
type importSet map[string]bool
func (is importSet) importPublic(imps protoreflect.FileImports) {
for i := 0; i < imps.Len(); i++ {
if imp := imps.Get(i); imp.IsPublic {
is[imp.Path()] = true
is.importPublic(imp.Imports())
}
}
}
// NewFiles creates a new protoregistry.Files from the provided
// FileDescriptorSet message. The descriptor set must include only
// valid files according to protobuf semantics. The returned descriptors
// are a deep copy of the input.
func (o FileOptions) NewFiles(fds *descriptorpb.FileDescriptorSet) (*protoregistry.Files, error) {
files := make(map[string]*descriptorpb.FileDescriptorProto)
for _, fd := range fds.File {
if _, ok := files[fd.GetName()]; ok {
return nil, errors.New("file appears multiple times: %q", fd.GetName())
}
files[fd.GetName()] = fd
}
r := &protoregistry.Files{}
for _, fd := range files {
if err := o.addFileDeps(r, fd, files); err != nil {
return nil, err
}
}
return r, nil
}
func (o FileOptions) addFileDeps(r *protoregistry.Files, fd *descriptorpb.FileDescriptorProto, files map[string]*descriptorpb.FileDescriptorProto) error {
// Set the entry to nil while descending into a file's dependencies to detect cycles.
files[fd.GetName()] = nil
for _, dep := range fd.Dependency {
depfd, ok := files[dep]
if depfd == nil {
if ok {
return errors.New("import cycle in file: %q", dep)
}
continue
}
if err := o.addFileDeps(r, depfd, files); err != nil {
return err
}
}
// Delete the entry once dependencies are processed.
delete(files, fd.GetName())
f, err := o.New(fd, r)
if err != nil {
return err
}
return r.RegisterFile(f)
}

248
vendor/google.golang.org/protobuf/reflect/protodesc/desc_init.go generated vendored
View File

@@ -1,248 +0,0 @@
// Copyright 2019 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 protodesc
import (
"google.golang.org/protobuf/internal/errors"
"google.golang.org/protobuf/internal/filedesc"
"google.golang.org/protobuf/internal/strs"
"google.golang.org/protobuf/proto"
"google.golang.org/protobuf/reflect/protoreflect"
"google.golang.org/protobuf/types/descriptorpb"
)
type descsByName map[protoreflect.FullName]protoreflect.Descriptor
func (r descsByName) initEnumDeclarations(eds []*descriptorpb.EnumDescriptorProto, parent protoreflect.Descriptor, sb *strs.Builder) (es []filedesc.Enum, err error) {
es = make([]filedesc.Enum, len(eds)) // allocate up-front to ensure stable pointers
for i, ed := range eds {
e := &es[i]
e.L2 = new(filedesc.EnumL2)
if e.L0, err = r.makeBase(e, parent, ed.GetName(), i, sb); err != nil {
return nil, err
}
if opts := ed.GetOptions(); opts != nil {
opts = proto.Clone(opts).(*descriptorpb.EnumOptions)
e.L2.Options = func() protoreflect.ProtoMessage { return opts }
}
for _, s := range ed.GetReservedName() {
e.L2.ReservedNames.List = append(e.L2.ReservedNames.List, protoreflect.Name(s))
}
for _, rr := range ed.GetReservedRange() {
e.L2.ReservedRanges.List = append(e.L2.ReservedRanges.List, [2]protoreflect.EnumNumber{
protoreflect.EnumNumber(rr.GetStart()),
protoreflect.EnumNumber(rr.GetEnd()),
})
}
if e.L2.Values.List, err = r.initEnumValuesFromDescriptorProto(ed.GetValue(), e, sb); err != nil {
return nil, err
}
}
return es, nil
}
func (r descsByName) initEnumValuesFromDescriptorProto(vds []*descriptorpb.EnumValueDescriptorProto, parent protoreflect.Descriptor, sb *strs.Builder) (vs []filedesc.EnumValue, err error) {
vs = make([]filedesc.EnumValue, len(vds)) // allocate up-front to ensure stable pointers
for i, vd := range vds {
v := &vs[i]
if v.L0, err = r.makeBase(v, parent, vd.GetName(), i, sb); err != nil {
return nil, err
}
if opts := vd.GetOptions(); opts != nil {
opts = proto.Clone(opts).(*descriptorpb.EnumValueOptions)
v.L1.Options = func() protoreflect.ProtoMessage { return opts }
}
v.L1.Number = protoreflect.EnumNumber(vd.GetNumber())
}
return vs, nil
}
func (r descsByName) initMessagesDeclarations(mds []*descriptorpb.DescriptorProto, parent protoreflect.Descriptor, sb *strs.Builder) (ms []filedesc.Message, err error) {
ms = make([]filedesc.Message, len(mds)) // allocate up-front to ensure stable pointers
for i, md := range mds {
m := &ms[i]
m.L2 = new(filedesc.MessageL2)
if m.L0, err = r.makeBase(m, parent, md.GetName(), i, sb); err != nil {
return nil, err
}
if opts := md.GetOptions(); opts != nil {
opts = proto.Clone(opts).(*descriptorpb.MessageOptions)
m.L2.Options = func() protoreflect.ProtoMessage { return opts }
m.L1.IsMapEntry = opts.GetMapEntry()
m.L1.IsMessageSet = opts.GetMessageSetWireFormat()
}
for _, s := range md.GetReservedName() {
m.L2.ReservedNames.List = append(m.L2.ReservedNames.List, protoreflect.Name(s))
}
for _, rr := range md.GetReservedRange() {
m.L2.ReservedRanges.List = append(m.L2.ReservedRanges.List, [2]protoreflect.FieldNumber{
protoreflect.FieldNumber(rr.GetStart()),
protoreflect.FieldNumber(rr.GetEnd()),
})
}
for _, xr := range md.GetExtensionRange() {
m.L2.ExtensionRanges.List = append(m.L2.ExtensionRanges.List, [2]protoreflect.FieldNumber{
protoreflect.FieldNumber(xr.GetStart()),
protoreflect.FieldNumber(xr.GetEnd()),
})
var optsFunc func() protoreflect.ProtoMessage
if opts := xr.GetOptions(); opts != nil {
opts = proto.Clone(opts).(*descriptorpb.ExtensionRangeOptions)
optsFunc = func() protoreflect.ProtoMessage { return opts }
}
m.L2.ExtensionRangeOptions = append(m.L2.ExtensionRangeOptions, optsFunc)
}
if m.L2.Fields.List, err = r.initFieldsFromDescriptorProto(md.GetField(), m, sb); err != nil {
return nil, err
}
if m.L2.Oneofs.List, err = r.initOneofsFromDescriptorProto(md.GetOneofDecl(), m, sb); err != nil {
return nil, err
}
if m.L1.Enums.List, err = r.initEnumDeclarations(md.GetEnumType(), m, sb); err != nil {
return nil, err
}
if m.L1.Messages.List, err = r.initMessagesDeclarations(md.GetNestedType(), m, sb); err != nil {
return nil, err
}
if m.L1.Extensions.List, err = r.initExtensionDeclarations(md.GetExtension(), m, sb); err != nil {
return nil, err
}
}
return ms, nil
}
func (r descsByName) initFieldsFromDescriptorProto(fds []*descriptorpb.FieldDescriptorProto, parent protoreflect.Descriptor, sb *strs.Builder) (fs []filedesc.Field, err error) {
fs = make([]filedesc.Field, len(fds)) // allocate up-front to ensure stable pointers
for i, fd := range fds {
f := &fs[i]
if f.L0, err = r.makeBase(f, parent, fd.GetName(), i, sb); err != nil {
return nil, err
}
f.L1.IsProto3Optional = fd.GetProto3Optional()
if opts := fd.GetOptions(); opts != nil {
opts = proto.Clone(opts).(*descriptorpb.FieldOptions)
f.L1.Options = func() protoreflect.ProtoMessage { return opts }
f.L1.IsWeak = opts.GetWeak()
f.L1.HasPacked = opts.Packed != nil
f.L1.IsPacked = opts.GetPacked()
}
f.L1.Number = protoreflect.FieldNumber(fd.GetNumber())
f.L1.Cardinality = protoreflect.Cardinality(fd.GetLabel())
if fd.Type != nil {
f.L1.Kind = protoreflect.Kind(fd.GetType())
}
if fd.JsonName != nil {
f.L1.JSONName.Init(fd.GetJsonName())
}
}
return fs, nil
}
func (r descsByName) initOneofsFromDescriptorProto(ods []*descriptorpb.OneofDescriptorProto, parent protoreflect.Descriptor, sb *strs.Builder) (os []filedesc.Oneof, err error) {
os = make([]filedesc.Oneof, len(ods)) // allocate up-front to ensure stable pointers
for i, od := range ods {
o := &os[i]
if o.L0, err = r.makeBase(o, parent, od.GetName(), i, sb); err != nil {
return nil, err
}
if opts := od.GetOptions(); opts != nil {
opts = proto.Clone(opts).(*descriptorpb.OneofOptions)
o.L1.Options = func() protoreflect.ProtoMessage { return opts }
}
}
return os, nil
}
func (r descsByName) initExtensionDeclarations(xds []*descriptorpb.FieldDescriptorProto, parent protoreflect.Descriptor, sb *strs.Builder) (xs []filedesc.Extension, err error) {
xs = make([]filedesc.Extension, len(xds)) // allocate up-front to ensure stable pointers
for i, xd := range xds {
x := &xs[i]
x.L2 = new(filedesc.ExtensionL2)
if x.L0, err = r.makeBase(x, parent, xd.GetName(), i, sb); err != nil {
return nil, err
}
if opts := xd.GetOptions(); opts != nil {
opts = proto.Clone(opts).(*descriptorpb.FieldOptions)
x.L2.Options = func() protoreflect.ProtoMessage { return opts }
x.L2.IsPacked = opts.GetPacked()
}
x.L1.Number = protoreflect.FieldNumber(xd.GetNumber())
x.L1.Cardinality = protoreflect.Cardinality(xd.GetLabel())
if xd.Type != nil {
x.L1.Kind = protoreflect.Kind(xd.GetType())
}
if xd.JsonName != nil {
x.L2.JSONName.Init(xd.GetJsonName())
}
}
return xs, nil
}
func (r descsByName) initServiceDeclarations(sds []*descriptorpb.ServiceDescriptorProto, parent protoreflect.Descriptor, sb *strs.Builder) (ss []filedesc.Service, err error) {
ss = make([]filedesc.Service, len(sds)) // allocate up-front to ensure stable pointers
for i, sd := range sds {
s := &ss[i]
s.L2 = new(filedesc.ServiceL2)
if s.L0, err = r.makeBase(s, parent, sd.GetName(), i, sb); err != nil {
return nil, err
}
if opts := sd.GetOptions(); opts != nil {
opts = proto.Clone(opts).(*descriptorpb.ServiceOptions)
s.L2.Options = func() protoreflect.ProtoMessage { return opts }
}
if s.L2.Methods.List, err = r.initMethodsFromDescriptorProto(sd.GetMethod(), s, sb); err != nil {
return nil, err
}
}
return ss, nil
}
func (r descsByName) initMethodsFromDescriptorProto(mds []*descriptorpb.MethodDescriptorProto, parent protoreflect.Descriptor, sb *strs.Builder) (ms []filedesc.Method, err error) {
ms = make([]filedesc.Method, len(mds)) // allocate up-front to ensure stable pointers
for i, md := range mds {
m := &ms[i]
if m.L0, err = r.makeBase(m, parent, md.GetName(), i, sb); err != nil {
return nil, err
}
if opts := md.GetOptions(); opts != nil {
opts = proto.Clone(opts).(*descriptorpb.MethodOptions)
m.L1.Options = func() protoreflect.ProtoMessage { return opts }
}
m.L1.IsStreamingClient = md.GetClientStreaming()
m.L1.IsStreamingServer = md.GetServerStreaming()
}
return ms, nil
}
func (r descsByName) makeBase(child, parent protoreflect.Descriptor, name string, idx int, sb *strs.Builder) (filedesc.BaseL0, error) {
if !protoreflect.Name(name).IsValid() {
return filedesc.BaseL0{}, errors.New("descriptor %q has an invalid nested name: %q", parent.FullName(), name)
}
// Derive the full name of the child.
// Note that enum values are a sibling to the enum parent in the namespace.
var fullName protoreflect.FullName
if _, ok := parent.(protoreflect.EnumDescriptor); ok {
fullName = sb.AppendFullName(parent.FullName().Parent(), protoreflect.Name(name))
} else {
fullName = sb.AppendFullName(parent.FullName(), protoreflect.Name(name))
}
if _, ok := r[fullName]; ok {
return filedesc.BaseL0{}, errors.New("descriptor %q already declared", fullName)
}
r[fullName] = child
// TODO: Verify that the full name does not already exist in the resolver?
// This is not as critical since most usages of NewFile will register
// the created file back into the registry, which will perform this check.
return filedesc.BaseL0{
FullName: fullName,
ParentFile: parent.ParentFile().(*filedesc.File),
Parent: parent,
Index: idx,
}, nil
}

286
vendor/google.golang.org/protobuf/reflect/protodesc/desc_resolve.go generated vendored
View File

@@ -1,286 +0,0 @@
// Copyright 2019 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 protodesc
import (
"google.golang.org/protobuf/internal/encoding/defval"
"google.golang.org/protobuf/internal/errors"
"google.golang.org/protobuf/internal/filedesc"
"google.golang.org/protobuf/reflect/protoreflect"
"google.golang.org/protobuf/reflect/protoregistry"
"google.golang.org/protobuf/types/descriptorpb"
)
// resolver is a wrapper around a local registry of declarations within the file
// and the remote resolver. The remote resolver is restricted to only return
// descriptors that have been imported.
type resolver struct {
local descsByName
remote Resolver
imports importSet
allowUnresolvable bool
}
func (r *resolver) resolveMessageDependencies(ms []filedesc.Message, mds []*descriptorpb.DescriptorProto) (err error) {
for i, md := range mds {
m := &ms[i]
for j, fd := range md.GetField() {
f := &m.L2.Fields.List[j]
if f.L1.Cardinality == protoreflect.Required {
m.L2.RequiredNumbers.List = append(m.L2.RequiredNumbers.List, f.L1.Number)
}
if fd.OneofIndex != nil {
k := int(fd.GetOneofIndex())
if !(0 <= k && k < len(md.GetOneofDecl())) {
return errors.New("message field %q has an invalid oneof index: %d", f.FullName(), k)
}
o := &m.L2.Oneofs.List[k]
f.L1.ContainingOneof = o
o.L1.Fields.List = append(o.L1.Fields.List, f)
}
if f.L1.Kind, f.L1.Enum, f.L1.Message, err = r.findTarget(f.Kind(), f.Parent().FullName(), partialName(fd.GetTypeName()), f.IsWeak()); err != nil {
return errors.New("message field %q cannot resolve type: %v", f.FullName(), err)
}
if fd.DefaultValue != nil {
v, ev, err := unmarshalDefault(fd.GetDefaultValue(), f, r.allowUnresolvable)
if err != nil {
return errors.New("message field %q has invalid default: %v", f.FullName(), err)
}
f.L1.Default = filedesc.DefaultValue(v, ev)
}
}
if err := r.resolveMessageDependencies(m.L1.Messages.List, md.GetNestedType()); err != nil {
return err
}
if err := r.resolveExtensionDependencies(m.L1.Extensions.List, md.GetExtension()); err != nil {
return err
}
}
return nil
}
func (r *resolver) resolveExtensionDependencies(xs []filedesc.Extension, xds []*descriptorpb.FieldDescriptorProto) (err error) {
for i, xd := range xds {
x := &xs[i]
if x.L1.Extendee, err = r.findMessageDescriptor(x.Parent().FullName(), partialName(xd.GetExtendee()), false); err != nil {
return errors.New("extension field %q cannot resolve extendee: %v", x.FullName(), err)
}
if x.L1.Kind, x.L2.Enum, x.L2.Message, err = r.findTarget(x.Kind(), x.Parent().FullName(), partialName(xd.GetTypeName()), false); err != nil {
return errors.New("extension field %q cannot resolve type: %v", x.FullName(), err)
}
if xd.DefaultValue != nil {
v, ev, err := unmarshalDefault(xd.GetDefaultValue(), x, r.allowUnresolvable)
if err != nil {
return errors.New("extension field %q has invalid default: %v", x.FullName(), err)
}
x.L2.Default = filedesc.DefaultValue(v, ev)
}
}
return nil
}
func (r *resolver) resolveServiceDependencies(ss []filedesc.Service, sds []*descriptorpb.ServiceDescriptorProto) (err error) {
for i, sd := range sds {
s := &ss[i]
for j, md := range sd.GetMethod() {
m := &s.L2.Methods.List[j]
m.L1.Input, err = r.findMessageDescriptor(m.Parent().FullName(), partialName(md.GetInputType()), false)
if err != nil {
return errors.New("service method %q cannot resolve input: %v", m.FullName(), err)
}
m.L1.Output, err = r.findMessageDescriptor(s.FullName(), partialName(md.GetOutputType()), false)
if err != nil {
return errors.New("service method %q cannot resolve output: %v", m.FullName(), err)
}
}
}
return nil
}
// findTarget finds an enum or message descriptor if k is an enum, message,
// group, or unknown. If unknown, and the name could be resolved, the kind
// returned kind is set based on the type of the resolved descriptor.
func (r *resolver) findTarget(k protoreflect.Kind, scope protoreflect.FullName, ref partialName, isWeak bool) (protoreflect.Kind, protoreflect.EnumDescriptor, protoreflect.MessageDescriptor, error) {
switch k {
case protoreflect.EnumKind:
ed, err := r.findEnumDescriptor(scope, ref, isWeak)
if err != nil {
return 0, nil, nil, err
}
return k, ed, nil, nil
case protoreflect.MessageKind, protoreflect.GroupKind:
md, err := r.findMessageDescriptor(scope, ref, isWeak)
if err != nil {
return 0, nil, nil, err
}
return k, nil, md, nil
case 0:
// Handle unspecified kinds (possible with parsers that operate
// on a per-file basis without knowledge of dependencies).
d, err := r.findDescriptor(scope, ref)
if err == protoregistry.NotFound && (r.allowUnresolvable || isWeak) {
return k, filedesc.PlaceholderEnum(ref.FullName()), filedesc.PlaceholderMessage(ref.FullName()), nil
} else if err == protoregistry.NotFound {
return 0, nil, nil, errors.New("%q not found", ref.FullName())
} else if err != nil {
return 0, nil, nil, err
}
switch d := d.(type) {
case protoreflect.EnumDescriptor:
return protoreflect.EnumKind, d, nil, nil
case protoreflect.MessageDescriptor:
return protoreflect.MessageKind, nil, d, nil
default:
return 0, nil, nil, errors.New("unknown kind")
}
default:
if ref != "" {
return 0, nil, nil, errors.New("target name cannot be specified for %v", k)
}
if !k.IsValid() {
return 0, nil, nil, errors.New("invalid kind: %d", k)
}
return k, nil, nil, nil
}
}
// findDescriptor finds the descriptor by name,
// which may be a relative name within some scope.
//
// Suppose the scope was "fizz.buzz" and the reference was "Foo.Bar",
// then the following full names are searched:
// * fizz.buzz.Foo.Bar
// * fizz.Foo.Bar
// * Foo.Bar
func (r *resolver) findDescriptor(scope protoreflect.FullName, ref partialName) (protoreflect.Descriptor, error) {
if !ref.IsValid() {
return nil, errors.New("invalid name reference: %q", ref)
}
if ref.IsFull() {
scope, ref = "", ref[1:]
}
var foundButNotImported protoreflect.Descriptor
for {
// Derive the full name to search.
s := protoreflect.FullName(ref)
if scope != "" {
s = scope + "." + s
}
// Check the current file for the descriptor.
if d, ok := r.local[s]; ok {
return d, nil
}
// Check the remote registry for the descriptor.
d, err := r.remote.FindDescriptorByName(s)
if err == nil {
// Only allow descriptors covered by one of the imports.
if r.imports[d.ParentFile().Path()] {
return d, nil
}
foundButNotImported = d
} else if err != protoregistry.NotFound {
return nil, errors.Wrap(err, "%q", s)
}
// Continue on at a higher level of scoping.
if scope == "" {
if d := foundButNotImported; d != nil {
return nil, errors.New("resolved %q, but %q is not imported", d.FullName(), d.ParentFile().Path())
}
return nil, protoregistry.NotFound
}
scope = scope.Parent()
}
}
func (r *resolver) findEnumDescriptor(scope protoreflect.FullName, ref partialName, isWeak bool) (protoreflect.EnumDescriptor, error) {
d, err := r.findDescriptor(scope, ref)
if err == protoregistry.NotFound && (r.allowUnresolvable || isWeak) {
return filedesc.PlaceholderEnum(ref.FullName()), nil
} else if err == protoregistry.NotFound {
return nil, errors.New("%q not found", ref.FullName())
} else if err != nil {
return nil, err
}
ed, ok := d.(protoreflect.EnumDescriptor)
if !ok {
return nil, errors.New("resolved %q, but it is not an enum", d.FullName())
}
return ed, nil
}
func (r *resolver) findMessageDescriptor(scope protoreflect.FullName, ref partialName, isWeak bool) (protoreflect.MessageDescriptor, error) {
d, err := r.findDescriptor(scope, ref)
if err == protoregistry.NotFound && (r.allowUnresolvable || isWeak) {
return filedesc.PlaceholderMessage(ref.FullName()), nil
} else if err == protoregistry.NotFound {
return nil, errors.New("%q not found", ref.FullName())
} else if err != nil {
return nil, err
}
md, ok := d.(protoreflect.MessageDescriptor)
if !ok {
return nil, errors.New("resolved %q, but it is not an message", d.FullName())
}
return md, nil
}
// partialName is the partial name. A leading dot means that the name is full,
// otherwise the name is relative to some current scope.
// See google.protobuf.FieldDescriptorProto.type_name.
type partialName string
func (s partialName) IsFull() bool {
return len(s) > 0 && s[0] == '.'
}
func (s partialName) IsValid() bool {
if s.IsFull() {
return protoreflect.FullName(s[1:]).IsValid()
}
return protoreflect.FullName(s).IsValid()
}
const unknownPrefix = "*."
// FullName converts the partial name to a full name on a best-effort basis.
// If relative, it creates an invalid full name, using a "*." prefix
// to indicate that the start of the full name is unknown.
func (s partialName) FullName() protoreflect.FullName {
if s.IsFull() {
return protoreflect.FullName(s[1:])
}
return protoreflect.FullName(unknownPrefix + s)
}
func unmarshalDefault(s string, fd protoreflect.FieldDescriptor, allowUnresolvable bool) (protoreflect.Value, protoreflect.EnumValueDescriptor, error) {
var evs protoreflect.EnumValueDescriptors
if fd.Enum() != nil {
evs = fd.Enum().Values()
}
v, ev, err := defval.Unmarshal(s, fd.Kind(), evs, defval.Descriptor)
if err != nil && allowUnresolvable && evs != nil && protoreflect.Name(s).IsValid() {
v = protoreflect.ValueOfEnum(0)
if evs.Len() > 0 {
v = protoreflect.ValueOfEnum(evs.Get(0).Number())
}
ev = filedesc.PlaceholderEnumValue(fd.Enum().FullName().Parent().Append(protoreflect.Name(s)))
} else if err != nil {
return v, ev, err
}
if fd.Syntax() == protoreflect.Proto3 {
return v, ev, errors.New("cannot be specified under proto3 semantics")
}
if fd.Kind() == protoreflect.MessageKind || fd.Kind() == protoreflect.GroupKind || fd.Cardinality() == protoreflect.Repeated {
return v, ev, errors.New("cannot be specified on composite types")
}
return v, ev, nil
}

370
vendor/google.golang.org/protobuf/reflect/protodesc/desc_validate.go generated vendored
View File

@@ -1,370 +0,0 @@
// Copyright 2019 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 protodesc
import (
"strings"
"unicode"
"google.golang.org/protobuf/encoding/protowire"
"google.golang.org/protobuf/internal/errors"
"google.golang.org/protobuf/internal/filedesc"
"google.golang.org/protobuf/internal/flags"
"google.golang.org/protobuf/internal/strs"
"google.golang.org/protobuf/reflect/protoreflect"
"google.golang.org/protobuf/types/descriptorpb"
)
func validateEnumDeclarations(es []filedesc.Enum, eds []*descriptorpb.EnumDescriptorProto) error {
for i, ed := range eds {
e := &es[i]
if err := e.L2.ReservedNames.CheckValid(); err != nil {
return errors.New("enum %q reserved names has %v", e.FullName(), err)
}
if err := e.L2.ReservedRanges.CheckValid(); err != nil {
return errors.New("enum %q reserved ranges has %v", e.FullName(), err)
}
if len(ed.GetValue()) == 0 {
return errors.New("enum %q must contain at least one value declaration", e.FullName())
}
allowAlias := ed.GetOptions().GetAllowAlias()
foundAlias := false
for i := 0; i < e.Values().Len(); i++ {
v1 := e.Values().Get(i)
if v2 := e.Values().ByNumber(v1.Number()); v1 != v2 {
foundAlias = true
if !allowAlias {
return errors.New("enum %q has conflicting non-aliased values on number %d: %q with %q", e.FullName(), v1.Number(), v1.Name(), v2.Name())
}
}
}
if allowAlias && !foundAlias {
return errors.New("enum %q allows aliases, but none were found", e.FullName())
}
if e.Syntax() == protoreflect.Proto3 {
if v := e.Values().Get(0); v.Number() != 0 {
return errors.New("enum %q using proto3 semantics must have zero number for the first value", v.FullName())
}
// Verify that value names in proto3 do not conflict if the
// case-insensitive prefix is removed.
// See protoc v3.8.0: src/google/protobuf/descriptor.cc:4991-5055
names := map[string]protoreflect.EnumValueDescriptor{}
prefix := strings.Replace(strings.ToLower(string(e.Name())), "_", "", -1)
for i := 0; i < e.Values().Len(); i++ {
v1 := e.Values().Get(i)
s := strs.EnumValueName(strs.TrimEnumPrefix(string(v1.Name()), prefix))
if v2, ok := names[s]; ok && v1.Number() != v2.Number() {
return errors.New("enum %q using proto3 semantics has conflict: %q with %q", e.FullName(), v1.Name(), v2.Name())
}
names[s] = v1
}
}
for j, vd := range ed.GetValue() {
v := &e.L2.Values.List[j]
if vd.Number == nil {
return errors.New("enum value %q must have a specified number", v.FullName())
}
if e.L2.ReservedNames.Has(v.Name()) {
return errors.New("enum value %q must not use reserved name", v.FullName())
}
if e.L2.ReservedRanges.Has(v.Number()) {
return errors.New("enum value %q must not use reserved number %d", v.FullName(), v.Number())
}
}
}
return nil
}
func validateMessageDeclarations(ms []filedesc.Message, mds []*descriptorpb.DescriptorProto) error {
for i, md := range mds {
m := &ms[i]
// Handle the message descriptor itself.
isMessageSet := md.GetOptions().GetMessageSetWireFormat()
if err := m.L2.ReservedNames.CheckValid(); err != nil {
return errors.New("message %q reserved names has %v", m.FullName(), err)
}
if err := m.L2.ReservedRanges.CheckValid(isMessageSet); err != nil {
return errors.New("message %q reserved ranges has %v", m.FullName(), err)
}
if err := m.L2.ExtensionRanges.CheckValid(isMessageSet); err != nil {
return errors.New("message %q extension ranges has %v", m.FullName(), err)
}
if err := (*filedesc.FieldRanges).CheckOverlap(&m.L2.ReservedRanges, &m.L2.ExtensionRanges); err != nil {
return errors.New("message %q reserved and extension ranges has %v", m.FullName(), err)
}
for i := 0; i < m.Fields().Len(); i++ {
f1 := m.Fields().Get(i)
if f2 := m.Fields().ByNumber(f1.Number()); f1 != f2 {
return errors.New("message %q has conflicting fields: %q with %q", m.FullName(), f1.Name(), f2.Name())
}
}
if isMessageSet && !flags.ProtoLegacy {
return errors.New("message %q is a MessageSet, which is a legacy proto1 feature that is no longer supported", m.FullName())
}
if isMessageSet && (m.Syntax() != protoreflect.Proto2 || m.Fields().Len() > 0 || m.ExtensionRanges().Len() == 0) {
return errors.New("message %q is an invalid proto1 MessageSet", m.FullName())
}
if m.Syntax() == protoreflect.Proto3 {
if m.ExtensionRanges().Len() > 0 {
return errors.New("message %q using proto3 semantics cannot have extension ranges", m.FullName())
}
// Verify that field names in proto3 do not conflict if lowercased
// with all underscores removed.
// See protoc v3.8.0: src/google/protobuf/descriptor.cc:5830-5847
names := map[string]protoreflect.FieldDescriptor{}
for i := 0; i < m.Fields().Len(); i++ {
f1 := m.Fields().Get(i)
s := strings.Replace(strings.ToLower(string(f1.Name())), "_", "", -1)
if f2, ok := names[s]; ok {
return errors.New("message %q using proto3 semantics has conflict: %q with %q", m.FullName(), f1.Name(), f2.Name())
}
names[s] = f1
}
}
for j, fd := range md.GetField() {
f := &m.L2.Fields.List[j]
if m.L2.ReservedNames.Has(f.Name()) {
return errors.New("message field %q must not use reserved name", f.FullName())
}
if !f.Number().IsValid() {
return errors.New("message field %q has an invalid number: %d", f.FullName(), f.Number())
}
if !f.Cardinality().IsValid() {
return errors.New("message field %q has an invalid cardinality: %d", f.FullName(), f.Cardinality())
}
if m.L2.ReservedRanges.Has(f.Number()) {
return errors.New("message field %q must not use reserved number %d", f.FullName(), f.Number())
}
if m.L2.ExtensionRanges.Has(f.Number()) {
return errors.New("message field %q with number %d in extension range", f.FullName(), f.Number())
}
if fd.Extendee != nil {
return errors.New("message field %q may not have extendee: %q", f.FullName(), fd.GetExtendee())
}
if f.L1.IsProto3Optional {
if f.Syntax() != protoreflect.Proto3 {
return errors.New("message field %q under proto3 optional semantics must be specified in the proto3 syntax", f.FullName())
}
if f.Cardinality() != protoreflect.Optional {
return errors.New("message field %q under proto3 optional semantics must have optional cardinality", f.FullName())
}
if f.ContainingOneof() != nil && f.ContainingOneof().Fields().Len() != 1 {
return errors.New("message field %q under proto3 optional semantics must be within a single element oneof", f.FullName())
}
}
if f.IsWeak() && !flags.ProtoLegacy {
return errors.New("message field %q is a weak field, which is a legacy proto1 feature that is no longer supported", f.FullName())
}
if f.IsWeak() && (f.Syntax() != protoreflect.Proto2 || !isOptionalMessage(f) || f.ContainingOneof() != nil) {
return errors.New("message field %q may only be weak for an optional message", f.FullName())
}
if f.IsPacked() && !isPackable(f) {
return errors.New("message field %q is not packable", f.FullName())
}
if err := checkValidGroup(f); err != nil {
return errors.New("message field %q is an invalid group: %v", f.FullName(), err)
}
if err := checkValidMap(f); err != nil {
return errors.New("message field %q is an invalid map: %v", f.FullName(), err)
}
if f.Syntax() == protoreflect.Proto3 {
if f.Cardinality() == protoreflect.Required {
return errors.New("message field %q using proto3 semantics cannot be required", f.FullName())
}
if f.Enum() != nil && !f.Enum().IsPlaceholder() && f.Enum().Syntax() != protoreflect.Proto3 {
return errors.New("message field %q using proto3 semantics may only depend on a proto3 enum", f.FullName())
}
}
}
seenSynthetic := false // synthetic oneofs for proto3 optional must come after real oneofs
for j := range md.GetOneofDecl() {
o := &m.L2.Oneofs.List[j]
if o.Fields().Len() == 0 {
return errors.New("message oneof %q must contain at least one field declaration", o.FullName())
}
if n := o.Fields().Len(); n-1 != (o.Fields().Get(n-1).Index() - o.Fields().Get(0).Index()) {
return errors.New("message oneof %q must have consecutively declared fields", o.FullName())
}
if o.IsSynthetic() {
seenSynthetic = true
continue
}
if !o.IsSynthetic() && seenSynthetic {
return errors.New("message oneof %q must be declared before synthetic oneofs", o.FullName())
}
for i := 0; i < o.Fields().Len(); i++ {
f := o.Fields().Get(i)
if f.Cardinality() != protoreflect.Optional {
return errors.New("message field %q belongs in a oneof and must be optional", f.FullName())
}
if f.IsWeak() {
return errors.New("message field %q belongs in a oneof and must not be a weak reference", f.FullName())
}
}
}
if err := validateEnumDeclarations(m.L1.Enums.List, md.GetEnumType()); err != nil {
return err
}
if err := validateMessageDeclarations(m.L1.Messages.List, md.GetNestedType()); err != nil {
return err
}
if err := validateExtensionDeclarations(m.L1.Extensions.List, md.GetExtension()); err != nil {
return err
}
}
return nil
}
func validateExtensionDeclarations(xs []filedesc.Extension, xds []*descriptorpb.FieldDescriptorProto) error {
for i, xd := range xds {
x := &xs[i]
// NOTE: Avoid using the IsValid method since extensions to MessageSet
// may have a field number higher than normal. This check only verifies
// that the number is not negative or reserved. We check again later
// if we know that the extendee is definitely not a MessageSet.
if n := x.Number(); n < 0 || (protowire.FirstReservedNumber <= n && n <= protowire.LastReservedNumber) {
return errors.New("extension field %q has an invalid number: %d", x.FullName(), x.Number())
}
if !x.Cardinality().IsValid() || x.Cardinality() == protoreflect.Required {
return errors.New("extension field %q has an invalid cardinality: %d", x.FullName(), x.Cardinality())
}
if xd.JsonName != nil {
if xd.GetJsonName() != strs.JSONCamelCase(string(x.Name())) {
return errors.New("extension field %q may not have an explicitly set JSON name: %q", x.FullName(), xd.GetJsonName())
}
}
if xd.OneofIndex != nil {
return errors.New("extension field %q may not be part of a oneof", x.FullName())
}
if md := x.ContainingMessage(); !md.IsPlaceholder() {
if !md.ExtensionRanges().Has(x.Number()) {
return errors.New("extension field %q extends %q with non-extension field number: %d", x.FullName(), md.FullName(), x.Number())
}
isMessageSet := md.Options().(*descriptorpb.MessageOptions).GetMessageSetWireFormat()
if isMessageSet && !isOptionalMessage(x) {
return errors.New("extension field %q extends MessageSet and must be an optional message", x.FullName())
}
if !isMessageSet && !x.Number().IsValid() {
return errors.New("extension field %q has an invalid number: %d", x.FullName(), x.Number())
}
}
if xd.GetOptions().GetWeak() {
return errors.New("extension field %q cannot be a weak reference", x.FullName())
}
if x.IsPacked() && !isPackable(x) {
return errors.New("extension field %q is not packable", x.FullName())
}
if err := checkValidGroup(x); err != nil {
return errors.New("extension field %q is an invalid group: %v", x.FullName(), err)
}
if md := x.Message(); md != nil && md.IsMapEntry() {
return errors.New("extension field %q cannot be a map entry", x.FullName())
}
if x.Syntax() == protoreflect.Proto3 {
switch x.ContainingMessage().FullName() {
case (*descriptorpb.FileOptions)(nil).ProtoReflect().Descriptor().FullName():
case (*descriptorpb.EnumOptions)(nil).ProtoReflect().Descriptor().FullName():
case (*descriptorpb.EnumValueOptions)(nil).ProtoReflect().Descriptor().FullName():
case (*descriptorpb.MessageOptions)(nil).ProtoReflect().Descriptor().FullName():
case (*descriptorpb.FieldOptions)(nil).ProtoReflect().Descriptor().FullName():
case (*descriptorpb.OneofOptions)(nil).ProtoReflect().Descriptor().FullName():
case (*descriptorpb.ExtensionRangeOptions)(nil).ProtoReflect().Descriptor().FullName():
case (*descriptorpb.ServiceOptions)(nil).ProtoReflect().Descriptor().FullName():
case (*descriptorpb.MethodOptions)(nil).ProtoReflect().Descriptor().FullName():
default:
return errors.New("extension field %q cannot be declared in proto3 unless extended descriptor options", x.FullName())
}
}
}
return nil
}
// isOptionalMessage reports whether this is an optional message.
// If the kind is unknown, it is assumed to be a message.
func isOptionalMessage(fd protoreflect.FieldDescriptor) bool {
return (fd.Kind() == 0 || fd.Kind() == protoreflect.MessageKind) && fd.Cardinality() == protoreflect.Optional
}
// isPackable checks whether the pack option can be specified.
func isPackable(fd protoreflect.FieldDescriptor) bool {
switch fd.Kind() {
case protoreflect.StringKind, protoreflect.BytesKind, protoreflect.MessageKind, protoreflect.GroupKind:
return false
}
return fd.IsList()
}
// checkValidGroup reports whether fd is a valid group according to the same
// rules that protoc imposes.
func checkValidGroup(fd protoreflect.FieldDescriptor) error {
md := fd.Message()
switch {
case fd.Kind() != protoreflect.GroupKind:
return nil
case fd.Syntax() != protoreflect.Proto2:
return errors.New("invalid under proto2 semantics")
case md == nil || md.IsPlaceholder():
return errors.New("message must be resolvable")
case fd.FullName().Parent() != md.FullName().Parent():
return errors.New("message and field must be declared in the same scope")
case !unicode.IsUpper(rune(md.Name()[0])):
return errors.New("message name must start with an uppercase")
case fd.Name() != protoreflect.Name(strings.ToLower(string(md.Name()))):
return errors.New("field name must be lowercased form of the message name")
}
return nil
}
// checkValidMap checks whether the field is a valid map according to the same
// rules that protoc imposes.
// See protoc v3.8.0: src/google/protobuf/descriptor.cc:6045-6115
func checkValidMap(fd protoreflect.FieldDescriptor) error {
md := fd.Message()
switch {
case md == nil || !md.IsMapEntry():
return nil
case fd.FullName().Parent() != md.FullName().Parent():
return errors.New("message and field must be declared in the same scope")
case md.Name() != protoreflect.Name(strs.MapEntryName(string(fd.Name()))):
return errors.New("incorrect implicit map entry name")
case fd.Cardinality() != protoreflect.Repeated:
return errors.New("field must be repeated")
case md.Fields().Len() != 2:
return errors.New("message must have exactly two fields")
case md.ExtensionRanges().Len() > 0:
return errors.New("message must not have any extension ranges")
case md.Enums().Len()+md.Messages().Len()+md.Extensions().Len() > 0:
return errors.New("message must not have any nested declarations")
}
kf := md.Fields().Get(0)
vf := md.Fields().Get(1)
switch {
case kf.Name() != "key" || kf.Number() != 1 || kf.Cardinality() != protoreflect.Optional || kf.ContainingOneof() != nil || kf.HasDefault():
return errors.New("invalid key field")
case vf.Name() != "value" || vf.Number() != 2 || vf.Cardinality() != protoreflect.Optional || vf.ContainingOneof() != nil || vf.HasDefault():
return errors.New("invalid value field")
}
switch kf.Kind() {
case protoreflect.BoolKind: // bool
case protoreflect.Int32Kind, protoreflect.Sint32Kind, protoreflect.Sfixed32Kind: // int32
case protoreflect.Int64Kind, protoreflect.Sint64Kind, protoreflect.Sfixed64Kind: // int64
case protoreflect.Uint32Kind, protoreflect.Fixed32Kind: // uint32
case protoreflect.Uint64Kind, protoreflect.Fixed64Kind: // uint64
case protoreflect.StringKind: // string
default:
return errors.New("invalid key kind: %v", kf.Kind())
}
if e := vf.Enum(); e != nil && e.Values().Len() > 0 && e.Values().Get(0).Number() != 0 {
return errors.New("map enum value must have zero number for the first value")
}
return nil
}

242
vendor/google.golang.org/protobuf/reflect/protodesc/proto.go generated vendored
View File

@@ -1,242 +0,0 @@
// Copyright 2019 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 protodesc
import (
"fmt"
"strings"
"google.golang.org/protobuf/internal/encoding/defval"
"google.golang.org/protobuf/proto"
"google.golang.org/protobuf/reflect/protoreflect"
"google.golang.org/protobuf/types/descriptorpb"
)
// ToFileDescriptorProto copies a protoreflect.FileDescriptor into a
// google.protobuf.FileDescriptorProto message.
func ToFileDescriptorProto(file protoreflect.FileDescriptor) *descriptorpb.FileDescriptorProto {
p := &descriptorpb.FileDescriptorProto{
Name: proto.String(file.Path()),
Package: proto.String(string(file.Package())),
Options: proto.Clone(file.Options()).(*descriptorpb.FileOptions),
}
for i, imports := 0, file.Imports(); i < imports.Len(); i++ {
imp := imports.Get(i)
p.Dependency = append(p.Dependency, imp.Path())
if imp.IsPublic {
p.PublicDependency = append(p.PublicDependency, int32(i))
}
if imp.IsWeak {
p.WeakDependency = append(p.WeakDependency, int32(i))
}
}
for i, locs := 0, file.SourceLocations(); i < locs.Len(); i++ {
loc := locs.Get(i)
l := &descriptorpb.SourceCodeInfo_Location{}
l.Path = append(l.Path, loc.Path...)
if loc.StartLine == loc.EndLine {
l.Span = []int32{int32(loc.StartLine), int32(loc.StartColumn), int32(loc.EndColumn)}
} else {
l.Span = []int32{int32(loc.StartLine), int32(loc.StartColumn), int32(loc.EndLine), int32(loc.EndColumn)}
}
l.LeadingDetachedComments = append([]string(nil), loc.LeadingDetachedComments...)
if loc.LeadingComments != "" {
l.LeadingComments = proto.String(loc.LeadingComments)
}
if loc.TrailingComments != "" {
l.TrailingComments = proto.String(loc.TrailingComments)
}
if p.SourceCodeInfo == nil {
p.SourceCodeInfo = &descriptorpb.SourceCodeInfo{}
}
p.SourceCodeInfo.Location = append(p.SourceCodeInfo.Location, l)
}
for i, messages := 0, file.Messages(); i < messages.Len(); i++ {
p.MessageType = append(p.MessageType, ToDescriptorProto(messages.Get(i)))
}
for i, enums := 0, file.Enums(); i < enums.Len(); i++ {
p.EnumType = append(p.EnumType, ToEnumDescriptorProto(enums.Get(i)))
}
for i, services := 0, file.Services(); i < services.Len(); i++ {
p.Service = append(p.Service, ToServiceDescriptorProto(services.Get(i)))
}
for i, exts := 0, file.Extensions(); i < exts.Len(); i++ {
p.Extension = append(p.Extension, ToFieldDescriptorProto(exts.Get(i)))
}
if syntax := file.Syntax(); syntax != protoreflect.Proto2 {
p.Syntax = proto.String(file.Syntax().String())
}
return p
}
// ToDescriptorProto copies a protoreflect.MessageDescriptor into a
// google.protobuf.DescriptorProto message.
func ToDescriptorProto(message protoreflect.MessageDescriptor) *descriptorpb.DescriptorProto {
p := &descriptorpb.DescriptorProto{
Name: proto.String(string(message.Name())),
Options: proto.Clone(message.Options()).(*descriptorpb.MessageOptions),
}
for i, fields := 0, message.Fields(); i < fields.Len(); i++ {
p.Field = append(p.Field, ToFieldDescriptorProto(fields.Get(i)))
}
for i, exts := 0, message.Extensions(); i < exts.Len(); i++ {
p.Extension = append(p.Extension, ToFieldDescriptorProto(exts.Get(i)))
}
for i, messages := 0, message.Messages(); i < messages.Len(); i++ {
p.NestedType = append(p.NestedType, ToDescriptorProto(messages.Get(i)))
}
for i, enums := 0, message.Enums(); i < enums.Len(); i++ {
p.EnumType = append(p.EnumType, ToEnumDescriptorProto(enums.Get(i)))
}
for i, xranges := 0, message.ExtensionRanges(); i < xranges.Len(); i++ {
xrange := xranges.Get(i)
p.ExtensionRange = append(p.ExtensionRange, &descriptorpb.DescriptorProto_ExtensionRange{
Start: proto.Int32(int32(xrange[0])),
End: proto.Int32(int32(xrange[1])),
Options: proto.Clone(message.ExtensionRangeOptions(i)).(*descriptorpb.ExtensionRangeOptions),
})
}
for i, oneofs := 0, message.Oneofs(); i < oneofs.Len(); i++ {
p.OneofDecl = append(p.OneofDecl, ToOneofDescriptorProto(oneofs.Get(i)))
}
for i, ranges := 0, message.ReservedRanges(); i < ranges.Len(); i++ {
rrange := ranges.Get(i)
p.ReservedRange = append(p.ReservedRange, &descriptorpb.DescriptorProto_ReservedRange{
Start: proto.Int32(int32(rrange[0])),
End: proto.Int32(int32(rrange[1])),
})
}
for i, names := 0, message.ReservedNames(); i < names.Len(); i++ {
p.ReservedName = append(p.ReservedName, string(names.Get(i)))
}
return p
}
// ToFieldDescriptorProto copies a protoreflect.FieldDescriptor into a
// google.protobuf.FieldDescriptorProto message.
func ToFieldDescriptorProto(field protoreflect.FieldDescriptor) *descriptorpb.FieldDescriptorProto {
p := &descriptorpb.FieldDescriptorProto{
Name: proto.String(string(field.Name())),
Number: proto.Int32(int32(field.Number())),
Label: descriptorpb.FieldDescriptorProto_Label(field.Cardinality()).Enum(),
Options: proto.Clone(field.Options()).(*descriptorpb.FieldOptions),
}
if field.IsExtension() {
p.Extendee = fullNameOf(field.ContainingMessage())
}
if field.Kind().IsValid() {
p.Type = descriptorpb.FieldDescriptorProto_Type(field.Kind()).Enum()
}
if field.Enum() != nil {
p.TypeName = fullNameOf(field.Enum())
}
if field.Message() != nil {
p.TypeName = fullNameOf(field.Message())
}
if field.HasJSONName() {
p.JsonName = proto.String(field.JSONName())
}
if field.Syntax() == protoreflect.Proto3 && field.HasOptionalKeyword() {
p.Proto3Optional = proto.Bool(true)
}
if field.HasDefault() {
def, err := defval.Marshal(field.Default(), field.DefaultEnumValue(), field.Kind(), defval.Descriptor)
if err != nil && field.DefaultEnumValue() != nil {
def = string(field.DefaultEnumValue().Name()) // occurs for unresolved enum values
} else if err != nil {
panic(fmt.Sprintf("%v: %v", field.FullName(), err))
}
p.DefaultValue = proto.String(def)
}
if oneof := field.ContainingOneof(); oneof != nil {
p.OneofIndex = proto.Int32(int32(oneof.Index()))
}
return p
}
// ToOneofDescriptorProto copies a protoreflect.OneofDescriptor into a
// google.protobuf.OneofDescriptorProto message.
func ToOneofDescriptorProto(oneof protoreflect.OneofDescriptor) *descriptorpb.OneofDescriptorProto {
return &descriptorpb.OneofDescriptorProto{
Name: proto.String(string(oneof.Name())),
Options: proto.Clone(oneof.Options()).(*descriptorpb.OneofOptions),
}
}
// ToEnumDescriptorProto copies a protoreflect.EnumDescriptor into a
// google.protobuf.EnumDescriptorProto message.
func ToEnumDescriptorProto(enum protoreflect.EnumDescriptor) *descriptorpb.EnumDescriptorProto {
p := &descriptorpb.EnumDescriptorProto{
Name: proto.String(string(enum.Name())),
Options: proto.Clone(enum.Options()).(*descriptorpb.EnumOptions),
}
for i, values := 0, enum.Values(); i < values.Len(); i++ {
p.Value = append(p.Value, ToEnumValueDescriptorProto(values.Get(i)))
}
for i, ranges := 0, enum.ReservedRanges(); i < ranges.Len(); i++ {
rrange := ranges.Get(i)
p.ReservedRange = append(p.ReservedRange, &descriptorpb.EnumDescriptorProto_EnumReservedRange{
Start: proto.Int32(int32(rrange[0])),
End: proto.Int32(int32(rrange[1])),
})
}
for i, names := 0, enum.ReservedNames(); i < names.Len(); i++ {
p.ReservedName = append(p.ReservedName, string(names.Get(i)))
}
return p
}
// ToEnumValueDescriptorProto copies a protoreflect.EnumValueDescriptor into a
// google.protobuf.EnumValueDescriptorProto message.
func ToEnumValueDescriptorProto(value protoreflect.EnumValueDescriptor) *descriptorpb.EnumValueDescriptorProto {
return &descriptorpb.EnumValueDescriptorProto{
Name: proto.String(string(value.Name())),
Number: proto.Int32(int32(value.Number())),
Options: proto.Clone(value.Options()).(*descriptorpb.EnumValueOptions),
}
}
// ToServiceDescriptorProto copies a protoreflect.ServiceDescriptor into a
// google.protobuf.ServiceDescriptorProto message.
func ToServiceDescriptorProto(service protoreflect.ServiceDescriptor) *descriptorpb.ServiceDescriptorProto {
p := &descriptorpb.ServiceDescriptorProto{
Name: proto.String(string(service.Name())),
Options: proto.Clone(service.Options()).(*descriptorpb.ServiceOptions),
}
for i, methods := 0, service.Methods(); i < methods.Len(); i++ {
p.Method = append(p.Method, ToMethodDescriptorProto(methods.Get(i)))
}
return p
}
// ToMethodDescriptorProto copies a protoreflect.MethodDescriptor into a
// google.protobuf.MethodDescriptorProto message.
func ToMethodDescriptorProto(method protoreflect.MethodDescriptor) *descriptorpb.MethodDescriptorProto {
p := &descriptorpb.MethodDescriptorProto{
Name: proto.String(string(method.Name())),
InputType: fullNameOf(method.Input()),
OutputType: fullNameOf(method.Output()),
Options: proto.Clone(method.Options()).(*descriptorpb.MethodOptions),
}
if method.IsStreamingClient() {
p.ClientStreaming = proto.Bool(true)
}
if method.IsStreamingServer() {
p.ServerStreaming = proto.Bool(true)
}
return p
}
func fullNameOf(d protoreflect.Descriptor) *string {
if d == nil {
return nil
}
if strings.HasPrefix(string(d.FullName()), unknownPrefix) {
return proto.String(string(d.FullName()[len(unknownPrefix):]))
}
return proto.String("." + string(d.FullName()))
}

168
vendor/google.golang.org/protobuf/types/known/emptypb/empty.pb.go generated vendored
View File

@@ -1,168 +0,0 @@
// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc. All rights reserved.
// https://developers.google.com/protocol-buffers/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// Code generated by protoc-gen-go. DO NOT EDIT.
// source: google/protobuf/empty.proto
package emptypb
import (
protoreflect "google.golang.org/protobuf/reflect/protoreflect"
protoimpl "google.golang.org/protobuf/runtime/protoimpl"
reflect "reflect"
sync "sync"
)
// A generic empty message that you can re-use to avoid defining duplicated
// empty messages in your APIs. A typical example is to use it as the request
// or the response type of an API method. For instance:
//
// service Foo {
// rpc Bar(google.protobuf.Empty) returns (google.protobuf.Empty);
// }
//
// The JSON representation for `Empty` is empty JSON object `{}`.
type Empty struct {
state protoimpl.MessageState
sizeCache protoimpl.SizeCache
unknownFields protoimpl.UnknownFields
}
func (x *Empty) Reset() {
*x = Empty{}
if protoimpl.UnsafeEnabled {
mi := &file_google_protobuf_empty_proto_msgTypes[0]
ms := protoimpl.X.MessageStateOf(protoimpl.Pointer(x))
ms.StoreMessageInfo(mi)
}
}
func (x *Empty) String() string {
return protoimpl.X.MessageStringOf(x)
}
func (*Empty) ProtoMessage() {}
func (x *Empty) ProtoReflect() protoreflect.Message {
mi := &file_google_protobuf_empty_proto_msgTypes[0]
if protoimpl.UnsafeEnabled && x != nil {
ms := protoimpl.X.MessageStateOf(protoimpl.Pointer(x))
if ms.LoadMessageInfo() == nil {
ms.StoreMessageInfo(mi)
}
return ms
}
return mi.MessageOf(x)
}
// Deprecated: Use Empty.ProtoReflect.Descriptor instead.
func (*Empty) Descriptor() ([]byte, []int) {
return file_google_protobuf_empty_proto_rawDescGZIP(), []int{0}
}
var File_google_protobuf_empty_proto protoreflect.FileDescriptor
var file_google_protobuf_empty_proto_rawDesc = []byte{
0x0a, 0x1b, 0x67, 0x6f, 0x6f, 0x67, 0x6c, 0x65, 0x2f, 0x70, 0x72, 0x6f, 0x74, 0x6f, 0x62, 0x75,
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0x06, 0x70, 0x72, 0x6f, 0x74, 0x6f, 0x33,
}
var (
file_google_protobuf_empty_proto_rawDescOnce sync.Once
file_google_protobuf_empty_proto_rawDescData = file_google_protobuf_empty_proto_rawDesc
)
func file_google_protobuf_empty_proto_rawDescGZIP() []byte {
file_google_protobuf_empty_proto_rawDescOnce.Do(func() {
file_google_protobuf_empty_proto_rawDescData = protoimpl.X.CompressGZIP(file_google_protobuf_empty_proto_rawDescData)
})
return file_google_protobuf_empty_proto_rawDescData
}
var file_google_protobuf_empty_proto_msgTypes = make([]protoimpl.MessageInfo, 1)
var file_google_protobuf_empty_proto_goTypes = []interface{}{
(*Empty)(nil), // 0: google.protobuf.Empty
}
var file_google_protobuf_empty_proto_depIdxs = []int32{
0, // [0:0] is the sub-list for method output_type
0, // [0:0] is the sub-list for method input_type
0, // [0:0] is the sub-list for extension type_name
0, // [0:0] is the sub-list for extension extendee
0, // [0:0] is the sub-list for field type_name
}
func init() { file_google_protobuf_empty_proto_init() }
func file_google_protobuf_empty_proto_init() {
if File_google_protobuf_empty_proto != nil {
return
}
if !protoimpl.UnsafeEnabled {
file_google_protobuf_empty_proto_msgTypes[0].Exporter = func(v interface{}, i int) interface{} {
switch v := v.(*Empty); i {
case 0:
return &v.state
case 1:
return &v.sizeCache
case 2:
return &v.unknownFields
default:
return nil
}
}
}
type x struct{}
out := protoimpl.TypeBuilder{
File: protoimpl.DescBuilder{
GoPackagePath: reflect.TypeOf(x{}).PkgPath(),
RawDescriptor: file_google_protobuf_empty_proto_rawDesc,
NumEnums: 0,
NumMessages: 1,
NumExtensions: 0,
NumServices: 0,
},
GoTypes: file_google_protobuf_empty_proto_goTypes,
DependencyIndexes: file_google_protobuf_empty_proto_depIdxs,
MessageInfos: file_google_protobuf_empty_proto_msgTypes,
}.Build()
File_google_protobuf_empty_proto = out.File
file_google_protobuf_empty_proto_rawDesc = nil
file_google_protobuf_empty_proto_goTypes = nil
file_google_protobuf_empty_proto_depIdxs = nil
}

505
vendor/google.golang.org/protobuf/types/known/structpb/struct.pb.go generated vendored
View File

@@ -1,505 +0,0 @@
// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc. All rights reserved.
// https://developers.google.com/protocol-buffers/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// Code generated by protoc-gen-go. DO NOT EDIT.
// source: google/protobuf/struct.proto
package structpb
import (
protoreflect "google.golang.org/protobuf/reflect/protoreflect"
protoimpl "google.golang.org/protobuf/runtime/protoimpl"
reflect "reflect"
sync "sync"
)
// `NullValue` is a singleton enumeration to represent the null value for the
// `Value` type union.
//
// The JSON representation for `NullValue` is JSON `null`.
type NullValue int32
const (
// Null value.
NullValue_NULL_VALUE NullValue = 0
)
// Enum value maps for NullValue.
var (
NullValue_name = map[int32]string{
0: "NULL_VALUE",
}
NullValue_value = map[string]int32{
"NULL_VALUE": 0,
}
)
func (x NullValue) Enum() *NullValue {
p := new(NullValue)
*p = x
return p
}
func (x NullValue) String() string {
return protoimpl.X.EnumStringOf(x.Descriptor(), protoreflect.EnumNumber(x))
}
func (NullValue) Descriptor() protoreflect.EnumDescriptor {
return file_google_protobuf_struct_proto_enumTypes[0].Descriptor()
}
func (NullValue) Type() protoreflect.EnumType {
return &file_google_protobuf_struct_proto_enumTypes[0]
}
func (x NullValue) Number() protoreflect.EnumNumber {
return protoreflect.EnumNumber(x)
}
// Deprecated: Use NullValue.Descriptor instead.
func (NullValue) EnumDescriptor() ([]byte, []int) {
return file_google_protobuf_struct_proto_rawDescGZIP(), []int{0}
}
// `Struct` represents a structured data value, consisting of fields
// which map to dynamically typed values. In some languages, `Struct`
// might be supported by a native representation. For example, in
// scripting languages like JS a struct is represented as an
// object. The details of that representation are described together
// with the proto support for the language.
//
// The JSON representation for `Struct` is JSON object.
type Struct struct {
state protoimpl.MessageState
sizeCache protoimpl.SizeCache
unknownFields protoimpl.UnknownFields
// Unordered map of dynamically typed values.
Fields map[string]*Value `protobuf:"bytes,1,rep,name=fields,proto3" json:"fields,omitempty" protobuf_key:"bytes,1,opt,name=key,proto3" protobuf_val:"bytes,2,opt,name=value,proto3"`
}
func (x *Struct) Reset() {
*x = Struct{}
if protoimpl.UnsafeEnabled {
mi := &file_google_protobuf_struct_proto_msgTypes[0]
ms := protoimpl.X.MessageStateOf(protoimpl.Pointer(x))
ms.StoreMessageInfo(mi)
}
}
func (x *Struct) String() string {
return protoimpl.X.MessageStringOf(x)
}
func (*Struct) ProtoMessage() {}
func (x *Struct) ProtoReflect() protoreflect.Message {
mi := &file_google_protobuf_struct_proto_msgTypes[0]
if protoimpl.UnsafeEnabled && x != nil {
ms := protoimpl.X.MessageStateOf(protoimpl.Pointer(x))
if ms.LoadMessageInfo() == nil {
ms.StoreMessageInfo(mi)
}
return ms
}
return mi.MessageOf(x)
}
// Deprecated: Use Struct.ProtoReflect.Descriptor instead.
func (*Struct) Descriptor() ([]byte, []int) {
return file_google_protobuf_struct_proto_rawDescGZIP(), []int{0}
}
func (x *Struct) GetFields() map[string]*Value {
if x != nil {
return x.Fields
}
return nil
}
// `Value` represents a dynamically typed value which can be either
// null, a number, a string, a boolean, a recursive struct value, or a
// list of values. A producer of value is expected to set one of that
// variants, absence of any variant indicates an error.
//
// The JSON representation for `Value` is JSON value.
type Value struct {
state protoimpl.MessageState
sizeCache protoimpl.SizeCache
unknownFields protoimpl.UnknownFields
// The kind of value.
//
// Types that are assignable to Kind:
// *Value_NullValue
// *Value_NumberValue
// *Value_StringValue
// *Value_BoolValue
// *Value_StructValue
// *Value_ListValue
Kind isValue_Kind `protobuf_oneof:"kind"`
}
func (x *Value) Reset() {
*x = Value{}
if protoimpl.UnsafeEnabled {
mi := &file_google_protobuf_struct_proto_msgTypes[1]
ms := protoimpl.X.MessageStateOf(protoimpl.Pointer(x))
ms.StoreMessageInfo(mi)
}
}
func (x *Value) String() string {
return protoimpl.X.MessageStringOf(x)
}
func (*Value) ProtoMessage() {}
func (x *Value) ProtoReflect() protoreflect.Message {
mi := &file_google_protobuf_struct_proto_msgTypes[1]
if protoimpl.UnsafeEnabled && x != nil {
ms := protoimpl.X.MessageStateOf(protoimpl.Pointer(x))
if ms.LoadMessageInfo() == nil {
ms.StoreMessageInfo(mi)
}
return ms
}
return mi.MessageOf(x)
}
// Deprecated: Use Value.ProtoReflect.Descriptor instead.
func (*Value) Descriptor() ([]byte, []int) {
return file_google_protobuf_struct_proto_rawDescGZIP(), []int{1}
}
func (m *Value) GetKind() isValue_Kind {
if m != nil {
return m.Kind
}
return nil
}
func (x *Value) GetNullValue() NullValue {
if x, ok := x.GetKind().(*Value_NullValue); ok {
return x.NullValue
}
return NullValue_NULL_VALUE
}
func (x *Value) GetNumberValue() float64 {
if x, ok := x.GetKind().(*Value_NumberValue); ok {
return x.NumberValue
}
return 0
}
func (x *Value) GetStringValue() string {
if x, ok := x.GetKind().(*Value_StringValue); ok {
return x.StringValue
}
return ""
}
func (x *Value) GetBoolValue() bool {
if x, ok := x.GetKind().(*Value_BoolValue); ok {
return x.BoolValue
}
return false
}
func (x *Value) GetStructValue() *Struct {
if x, ok := x.GetKind().(*Value_StructValue); ok {
return x.StructValue
}
return nil
}
func (x *Value) GetListValue() *ListValue {
if x, ok := x.GetKind().(*Value_ListValue); ok {
return x.ListValue
}
return nil
}
type isValue_Kind interface {
isValue_Kind()
}
type Value_NullValue struct {
// Represents a null value.
NullValue NullValue `protobuf:"varint,1,opt,name=null_value,json=nullValue,proto3,enum=google.protobuf.NullValue,oneof"`
}
type Value_NumberValue struct {
// Represents a double value.
NumberValue float64 `protobuf:"fixed64,2,opt,name=number_value,json=numberValue,proto3,oneof"`
}
type Value_StringValue struct {
// Represents a string value.
StringValue string `protobuf:"bytes,3,opt,name=string_value,json=stringValue,proto3,oneof"`
}
type Value_BoolValue struct {
// Represents a boolean value.
BoolValue bool `protobuf:"varint,4,opt,name=bool_value,json=boolValue,proto3,oneof"`
}
type Value_StructValue struct {
// Represents a structured value.
StructValue *Struct `protobuf:"bytes,5,opt,name=struct_value,json=structValue,proto3,oneof"`
}
type Value_ListValue struct {
// Represents a repeated `Value`.
ListValue *ListValue `protobuf:"bytes,6,opt,name=list_value,json=listValue,proto3,oneof"`
}
func (*Value_NullValue) isValue_Kind() {}
func (*Value_NumberValue) isValue_Kind() {}
func (*Value_StringValue) isValue_Kind() {}
func (*Value_BoolValue) isValue_Kind() {}
func (*Value_StructValue) isValue_Kind() {}
func (*Value_ListValue) isValue_Kind() {}
// `ListValue` is a wrapper around a repeated field of values.
//
// The JSON representation for `ListValue` is JSON array.
type ListValue struct {
state protoimpl.MessageState
sizeCache protoimpl.SizeCache
unknownFields protoimpl.UnknownFields
// Repeated field of dynamically typed values.
Values []*Value `protobuf:"bytes,1,rep,name=values,proto3" json:"values,omitempty"`
}
func (x *ListValue) Reset() {
*x = ListValue{}
if protoimpl.UnsafeEnabled {
mi := &file_google_protobuf_struct_proto_msgTypes[2]
ms := protoimpl.X.MessageStateOf(protoimpl.Pointer(x))
ms.StoreMessageInfo(mi)
}
}
func (x *ListValue) String() string {
return protoimpl.X.MessageStringOf(x)
}
func (*ListValue) ProtoMessage() {}
func (x *ListValue) ProtoReflect() protoreflect.Message {
mi := &file_google_protobuf_struct_proto_msgTypes[2]
if protoimpl.UnsafeEnabled && x != nil {
ms := protoimpl.X.MessageStateOf(protoimpl.Pointer(x))
if ms.LoadMessageInfo() == nil {
ms.StoreMessageInfo(mi)
}
return ms
}
return mi.MessageOf(x)
}
// Deprecated: Use ListValue.ProtoReflect.Descriptor instead.
func (*ListValue) Descriptor() ([]byte, []int) {
return file_google_protobuf_struct_proto_rawDescGZIP(), []int{2}
}
func (x *ListValue) GetValues() []*Value {
if x != nil {
return x.Values
}
return nil
}
var File_google_protobuf_struct_proto protoreflect.FileDescriptor
var file_google_protobuf_struct_proto_rawDesc = []byte{
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var (
file_google_protobuf_struct_proto_rawDescOnce sync.Once
file_google_protobuf_struct_proto_rawDescData = file_google_protobuf_struct_proto_rawDesc
)
func file_google_protobuf_struct_proto_rawDescGZIP() []byte {
file_google_protobuf_struct_proto_rawDescOnce.Do(func() {
file_google_protobuf_struct_proto_rawDescData = protoimpl.X.CompressGZIP(file_google_protobuf_struct_proto_rawDescData)
})
return file_google_protobuf_struct_proto_rawDescData
}
var file_google_protobuf_struct_proto_enumTypes = make([]protoimpl.EnumInfo, 1)
var file_google_protobuf_struct_proto_msgTypes = make([]protoimpl.MessageInfo, 4)
var file_google_protobuf_struct_proto_goTypes = []interface{}{
(NullValue)(0), // 0: google.protobuf.NullValue
(*Struct)(nil), // 1: google.protobuf.Struct
(*Value)(nil), // 2: google.protobuf.Value
(*ListValue)(nil), // 3: google.protobuf.ListValue
nil, // 4: google.protobuf.Struct.FieldsEntry
}
var file_google_protobuf_struct_proto_depIdxs = []int32{
4, // 0: google.protobuf.Struct.fields:type_name -> google.protobuf.Struct.FieldsEntry
0, // 1: google.protobuf.Value.null_value:type_name -> google.protobuf.NullValue
1, // 2: google.protobuf.Value.struct_value:type_name -> google.protobuf.Struct
3, // 3: google.protobuf.Value.list_value:type_name -> google.protobuf.ListValue
2, // 4: google.protobuf.ListValue.values:type_name -> google.protobuf.Value
2, // 5: google.protobuf.Struct.FieldsEntry.value:type_name -> google.protobuf.Value
6, // [6:6] is the sub-list for method output_type
6, // [6:6] is the sub-list for method input_type
6, // [6:6] is the sub-list for extension type_name
6, // [6:6] is the sub-list for extension extendee
0, // [0:6] is the sub-list for field type_name
}
func init() { file_google_protobuf_struct_proto_init() }
func file_google_protobuf_struct_proto_init() {
if File_google_protobuf_struct_proto != nil {
return
}
if !protoimpl.UnsafeEnabled {
file_google_protobuf_struct_proto_msgTypes[0].Exporter = func(v interface{}, i int) interface{} {
switch v := v.(*Struct); i {
case 0:
return &v.state
case 1:
return &v.sizeCache
case 2:
return &v.unknownFields
default:
return nil
}
}
file_google_protobuf_struct_proto_msgTypes[1].Exporter = func(v interface{}, i int) interface{} {
switch v := v.(*Value); i {
case 0:
return &v.state
case 1:
return &v.sizeCache
case 2:
return &v.unknownFields
default:
return nil
}
}
file_google_protobuf_struct_proto_msgTypes[2].Exporter = func(v interface{}, i int) interface{} {
switch v := v.(*ListValue); i {
case 0:
return &v.state
case 1:
return &v.sizeCache
case 2:
return &v.unknownFields
default:
return nil
}
}
}
file_google_protobuf_struct_proto_msgTypes[1].OneofWrappers = []interface{}{
(*Value_NullValue)(nil),
(*Value_NumberValue)(nil),
(*Value_StringValue)(nil),
(*Value_BoolValue)(nil),
(*Value_StructValue)(nil),
(*Value_ListValue)(nil),
}
type x struct{}
out := protoimpl.TypeBuilder{
File: protoimpl.DescBuilder{
GoPackagePath: reflect.TypeOf(x{}).PkgPath(),
RawDescriptor: file_google_protobuf_struct_proto_rawDesc,
NumEnums: 1,
NumMessages: 4,
NumExtensions: 0,
NumServices: 0,
},
GoTypes: file_google_protobuf_struct_proto_goTypes,
DependencyIndexes: file_google_protobuf_struct_proto_depIdxs,
EnumInfos: file_google_protobuf_struct_proto_enumTypes,
MessageInfos: file_google_protobuf_struct_proto_msgTypes,
}.Build()
File_google_protobuf_struct_proto = out.File
file_google_protobuf_struct_proto_rawDesc = nil
file_google_protobuf_struct_proto_goTypes = nil
file_google_protobuf_struct_proto_depIdxs = nil
}