ceph-csi/vendor/google.golang.org/protobuf/internal/filedesc/desc.go
dependabot[bot] 86bc40fbff rebase: bump google.golang.org/protobuf from 1.33.0 to 1.34.1
Bumps google.golang.org/protobuf from 1.33.0 to 1.34.1.

---
updated-dependencies:
- dependency-name: google.golang.org/protobuf
  dependency-type: direct:production
  update-type: version-update:semver-minor
...

Signed-off-by: dependabot[bot] <support@github.com>
2024-05-07 13:43:40 +00:00

730 lines
26 KiB
Go

// 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 filedesc
import (
"bytes"
"fmt"
"strings"
"sync"
"sync/atomic"
"google.golang.org/protobuf/internal/descfmt"
"google.golang.org/protobuf/internal/descopts"
"google.golang.org/protobuf/internal/encoding/defval"
"google.golang.org/protobuf/internal/encoding/messageset"
"google.golang.org/protobuf/internal/genid"
"google.golang.org/protobuf/internal/pragma"
"google.golang.org/protobuf/internal/strs"
"google.golang.org/protobuf/reflect/protoreflect"
"google.golang.org/protobuf/reflect/protoregistry"
)
// Edition is an Enum for proto2.Edition
type Edition int32
// These values align with the value of Enum in descriptor.proto which allows
// direct conversion between the proto enum and this enum.
const (
EditionUnknown Edition = 0
EditionProto2 Edition = 998
EditionProto3 Edition = 999
Edition2023 Edition = 1000
EditionUnsupported Edition = 100000
)
// The types in this file may have a suffix:
// • L0: Contains fields common to all descriptors (except File) and
// must be initialized up front.
// • L1: Contains fields specific to a descriptor and
// must be initialized up front. If the associated proto uses Editions, the
// Editions features must always be resolved. If not explicitly set, the
// appropriate default must be resolved and set.
// • L2: Contains fields that are lazily initialized when constructing
// from the raw file descriptor. When constructing as a literal, the L2
// fields must be initialized up front.
//
// The types are exported so that packages like reflect/protodesc can
// directly construct descriptors.
type (
File struct {
fileRaw
L1 FileL1
once uint32 // atomically set if L2 is valid
mu sync.Mutex // protects L2
L2 *FileL2
}
FileL1 struct {
Syntax protoreflect.Syntax
Edition Edition // Only used if Syntax == Editions
Path string
Package protoreflect.FullName
Enums Enums
Messages Messages
Extensions Extensions
Services Services
EditionFeatures EditionFeatures
}
FileL2 struct {
Options func() protoreflect.ProtoMessage
Imports FileImports
Locations SourceLocations
}
EditionFeatures struct {
// IsFieldPresence is true if field_presence is EXPLICIT
// https://protobuf.dev/editions/features/#field_presence
IsFieldPresence bool
// IsFieldPresence is true if field_presence is LEGACY_REQUIRED
// https://protobuf.dev/editions/features/#field_presence
IsLegacyRequired bool
// IsOpenEnum is true if enum_type is OPEN
// https://protobuf.dev/editions/features/#enum_type
IsOpenEnum bool
// IsPacked is true if repeated_field_encoding is PACKED
// https://protobuf.dev/editions/features/#repeated_field_encoding
IsPacked bool
// IsUTF8Validated is true if utf_validation is VERIFY
// https://protobuf.dev/editions/features/#utf8_validation
IsUTF8Validated bool
// IsDelimitedEncoded is true if message_encoding is DELIMITED
// https://protobuf.dev/editions/features/#message_encoding
IsDelimitedEncoded bool
// IsJSONCompliant is true if json_format is ALLOW
// https://protobuf.dev/editions/features/#json_format
IsJSONCompliant bool
// GenerateLegacyUnmarshalJSON determines if the plugin generates the
// UnmarshalJSON([]byte) error method for enums.
GenerateLegacyUnmarshalJSON bool
}
)
func (fd *File) ParentFile() protoreflect.FileDescriptor { return fd }
func (fd *File) Parent() protoreflect.Descriptor { return nil }
func (fd *File) Index() int { return 0 }
func (fd *File) Syntax() protoreflect.Syntax { return fd.L1.Syntax }
// Not exported and just used to reconstruct the original FileDescriptor proto
func (fd *File) Edition() int32 { return int32(fd.L1.Edition) }
func (fd *File) Name() protoreflect.Name { return fd.L1.Package.Name() }
func (fd *File) FullName() protoreflect.FullName { return fd.L1.Package }
func (fd *File) IsPlaceholder() bool { return false }
func (fd *File) Options() protoreflect.ProtoMessage {
if f := fd.lazyInit().Options; f != nil {
return f()
}
return descopts.File
}
func (fd *File) Path() string { return fd.L1.Path }
func (fd *File) Package() protoreflect.FullName { return fd.L1.Package }
func (fd *File) Imports() protoreflect.FileImports { return &fd.lazyInit().Imports }
func (fd *File) Enums() protoreflect.EnumDescriptors { return &fd.L1.Enums }
func (fd *File) Messages() protoreflect.MessageDescriptors { return &fd.L1.Messages }
func (fd *File) Extensions() protoreflect.ExtensionDescriptors { return &fd.L1.Extensions }
func (fd *File) Services() protoreflect.ServiceDescriptors { return &fd.L1.Services }
func (fd *File) SourceLocations() protoreflect.SourceLocations { return &fd.lazyInit().Locations }
func (fd *File) Format(s fmt.State, r rune) { descfmt.FormatDesc(s, r, fd) }
func (fd *File) ProtoType(protoreflect.FileDescriptor) {}
func (fd *File) ProtoInternal(pragma.DoNotImplement) {}
func (fd *File) lazyInit() *FileL2 {
if atomic.LoadUint32(&fd.once) == 0 {
fd.lazyInitOnce()
}
return fd.L2
}
func (fd *File) lazyInitOnce() {
fd.mu.Lock()
if fd.L2 == nil {
fd.lazyRawInit() // recursively initializes all L2 structures
}
atomic.StoreUint32(&fd.once, 1)
fd.mu.Unlock()
}
// GoPackagePath is a pseudo-internal API for determining the Go package path
// that this file descriptor is declared in.
//
// WARNING: This method is exempt from the compatibility promise and may be
// removed in the future without warning.
func (fd *File) GoPackagePath() string {
return fd.builder.GoPackagePath
}
type (
Enum struct {
Base
L1 EnumL1
L2 *EnumL2 // protected by fileDesc.once
}
EnumL1 struct {
eagerValues bool // controls whether EnumL2.Values is already populated
EditionFeatures EditionFeatures
}
EnumL2 struct {
Options func() protoreflect.ProtoMessage
Values EnumValues
ReservedNames Names
ReservedRanges EnumRanges
}
EnumValue struct {
Base
L1 EnumValueL1
}
EnumValueL1 struct {
Options func() protoreflect.ProtoMessage
Number protoreflect.EnumNumber
}
)
func (ed *Enum) Options() protoreflect.ProtoMessage {
if f := ed.lazyInit().Options; f != nil {
return f()
}
return descopts.Enum
}
func (ed *Enum) Values() protoreflect.EnumValueDescriptors {
if ed.L1.eagerValues {
return &ed.L2.Values
}
return &ed.lazyInit().Values
}
func (ed *Enum) ReservedNames() protoreflect.Names { return &ed.lazyInit().ReservedNames }
func (ed *Enum) ReservedRanges() protoreflect.EnumRanges { return &ed.lazyInit().ReservedRanges }
func (ed *Enum) Format(s fmt.State, r rune) { descfmt.FormatDesc(s, r, ed) }
func (ed *Enum) ProtoType(protoreflect.EnumDescriptor) {}
func (ed *Enum) lazyInit() *EnumL2 {
ed.L0.ParentFile.lazyInit() // implicitly initializes L2
return ed.L2
}
func (ed *Enum) IsClosed() bool {
return !ed.L1.EditionFeatures.IsOpenEnum
}
func (ed *EnumValue) Options() protoreflect.ProtoMessage {
if f := ed.L1.Options; f != nil {
return f()
}
return descopts.EnumValue
}
func (ed *EnumValue) Number() protoreflect.EnumNumber { return ed.L1.Number }
func (ed *EnumValue) Format(s fmt.State, r rune) { descfmt.FormatDesc(s, r, ed) }
func (ed *EnumValue) ProtoType(protoreflect.EnumValueDescriptor) {}
type (
Message struct {
Base
L1 MessageL1
L2 *MessageL2 // protected by fileDesc.once
}
MessageL1 struct {
Enums Enums
Messages Messages
Extensions Extensions
IsMapEntry bool // promoted from google.protobuf.MessageOptions
IsMessageSet bool // promoted from google.protobuf.MessageOptions
EditionFeatures EditionFeatures
}
MessageL2 struct {
Options func() protoreflect.ProtoMessage
Fields Fields
Oneofs Oneofs
ReservedNames Names
ReservedRanges FieldRanges
RequiredNumbers FieldNumbers // must be consistent with Fields.Cardinality
ExtensionRanges FieldRanges
ExtensionRangeOptions []func() protoreflect.ProtoMessage // must be same length as ExtensionRanges
}
Field struct {
Base
L1 FieldL1
}
FieldL1 struct {
Options func() protoreflect.ProtoMessage
Number protoreflect.FieldNumber
Cardinality protoreflect.Cardinality // must be consistent with Message.RequiredNumbers
Kind protoreflect.Kind
StringName stringName
IsProto3Optional bool // promoted from google.protobuf.FieldDescriptorProto
IsWeak bool // promoted from google.protobuf.FieldOptions
Default defaultValue
ContainingOneof protoreflect.OneofDescriptor // must be consistent with Message.Oneofs.Fields
Enum protoreflect.EnumDescriptor
Message protoreflect.MessageDescriptor
EditionFeatures EditionFeatures
}
Oneof struct {
Base
L1 OneofL1
}
OneofL1 struct {
Options func() protoreflect.ProtoMessage
Fields OneofFields // must be consistent with Message.Fields.ContainingOneof
EditionFeatures EditionFeatures
}
)
func (md *Message) Options() protoreflect.ProtoMessage {
if f := md.lazyInit().Options; f != nil {
return f()
}
return descopts.Message
}
func (md *Message) IsMapEntry() bool { return md.L1.IsMapEntry }
func (md *Message) Fields() protoreflect.FieldDescriptors { return &md.lazyInit().Fields }
func (md *Message) Oneofs() protoreflect.OneofDescriptors { return &md.lazyInit().Oneofs }
func (md *Message) ReservedNames() protoreflect.Names { return &md.lazyInit().ReservedNames }
func (md *Message) ReservedRanges() protoreflect.FieldRanges { return &md.lazyInit().ReservedRanges }
func (md *Message) RequiredNumbers() protoreflect.FieldNumbers { return &md.lazyInit().RequiredNumbers }
func (md *Message) ExtensionRanges() protoreflect.FieldRanges { return &md.lazyInit().ExtensionRanges }
func (md *Message) ExtensionRangeOptions(i int) protoreflect.ProtoMessage {
if f := md.lazyInit().ExtensionRangeOptions[i]; f != nil {
return f()
}
return descopts.ExtensionRange
}
func (md *Message) Enums() protoreflect.EnumDescriptors { return &md.L1.Enums }
func (md *Message) Messages() protoreflect.MessageDescriptors { return &md.L1.Messages }
func (md *Message) Extensions() protoreflect.ExtensionDescriptors { return &md.L1.Extensions }
func (md *Message) ProtoType(protoreflect.MessageDescriptor) {}
func (md *Message) Format(s fmt.State, r rune) { descfmt.FormatDesc(s, r, md) }
func (md *Message) lazyInit() *MessageL2 {
md.L0.ParentFile.lazyInit() // implicitly initializes L2
return md.L2
}
// IsMessageSet is a pseudo-internal API for checking whether a message
// should serialize in the proto1 message format.
//
// WARNING: This method is exempt from the compatibility promise and may be
// removed in the future without warning.
func (md *Message) IsMessageSet() bool {
return md.L1.IsMessageSet
}
func (fd *Field) Options() protoreflect.ProtoMessage {
if f := fd.L1.Options; f != nil {
return f()
}
return descopts.Field
}
func (fd *Field) Number() protoreflect.FieldNumber { return fd.L1.Number }
func (fd *Field) Cardinality() protoreflect.Cardinality { return fd.L1.Cardinality }
func (fd *Field) Kind() protoreflect.Kind {
return fd.L1.Kind
}
func (fd *Field) HasJSONName() bool { return fd.L1.StringName.hasJSON }
func (fd *Field) JSONName() string { return fd.L1.StringName.getJSON(fd) }
func (fd *Field) TextName() string { return fd.L1.StringName.getText(fd) }
func (fd *Field) HasPresence() bool {
if fd.L1.Cardinality == protoreflect.Repeated {
return false
}
return fd.IsExtension() || fd.L1.EditionFeatures.IsFieldPresence || fd.L1.Message != nil || fd.L1.ContainingOneof != nil
}
func (fd *Field) HasOptionalKeyword() bool {
return (fd.L0.ParentFile.L1.Syntax == protoreflect.Proto2 && fd.L1.Cardinality == protoreflect.Optional && fd.L1.ContainingOneof == nil) || fd.L1.IsProto3Optional
}
func (fd *Field) IsPacked() bool {
if fd.L1.Cardinality != protoreflect.Repeated {
return false
}
switch fd.L1.Kind {
case protoreflect.StringKind, protoreflect.BytesKind, protoreflect.MessageKind, protoreflect.GroupKind:
return false
}
return fd.L1.EditionFeatures.IsPacked
}
func (fd *Field) IsExtension() bool { return false }
func (fd *Field) IsWeak() bool { return fd.L1.IsWeak }
func (fd *Field) IsList() bool { return fd.Cardinality() == protoreflect.Repeated && !fd.IsMap() }
func (fd *Field) IsMap() bool { return fd.Message() != nil && fd.Message().IsMapEntry() }
func (fd *Field) MapKey() protoreflect.FieldDescriptor {
if !fd.IsMap() {
return nil
}
return fd.Message().Fields().ByNumber(genid.MapEntry_Key_field_number)
}
func (fd *Field) MapValue() protoreflect.FieldDescriptor {
if !fd.IsMap() {
return nil
}
return fd.Message().Fields().ByNumber(genid.MapEntry_Value_field_number)
}
func (fd *Field) HasDefault() bool { return fd.L1.Default.has }
func (fd *Field) Default() protoreflect.Value { return fd.L1.Default.get(fd) }
func (fd *Field) DefaultEnumValue() protoreflect.EnumValueDescriptor { return fd.L1.Default.enum }
func (fd *Field) ContainingOneof() protoreflect.OneofDescriptor { return fd.L1.ContainingOneof }
func (fd *Field) ContainingMessage() protoreflect.MessageDescriptor {
return fd.L0.Parent.(protoreflect.MessageDescriptor)
}
func (fd *Field) Enum() protoreflect.EnumDescriptor {
return fd.L1.Enum
}
func (fd *Field) Message() protoreflect.MessageDescriptor {
if fd.L1.IsWeak {
if d, _ := protoregistry.GlobalFiles.FindDescriptorByName(fd.L1.Message.FullName()); d != nil {
return d.(protoreflect.MessageDescriptor)
}
}
return fd.L1.Message
}
func (fd *Field) Format(s fmt.State, r rune) { descfmt.FormatDesc(s, r, fd) }
func (fd *Field) ProtoType(protoreflect.FieldDescriptor) {}
// EnforceUTF8 is a pseudo-internal API to determine whether to enforce UTF-8
// validation for the string field. This exists for Google-internal use only
// since proto3 did not enforce UTF-8 validity prior to the open-source release.
// If this method does not exist, the default is to enforce valid UTF-8.
//
// WARNING: This method is exempt from the compatibility promise and may be
// removed in the future without warning.
func (fd *Field) EnforceUTF8() bool {
return fd.L1.EditionFeatures.IsUTF8Validated
}
func (od *Oneof) IsSynthetic() bool {
return od.L0.ParentFile.L1.Syntax == protoreflect.Proto3 && len(od.L1.Fields.List) == 1 && od.L1.Fields.List[0].HasOptionalKeyword()
}
func (od *Oneof) Options() protoreflect.ProtoMessage {
if f := od.L1.Options; f != nil {
return f()
}
return descopts.Oneof
}
func (od *Oneof) Fields() protoreflect.FieldDescriptors { return &od.L1.Fields }
func (od *Oneof) Format(s fmt.State, r rune) { descfmt.FormatDesc(s, r, od) }
func (od *Oneof) ProtoType(protoreflect.OneofDescriptor) {}
type (
Extension struct {
Base
L1 ExtensionL1
L2 *ExtensionL2 // protected by fileDesc.once
}
ExtensionL1 struct {
Number protoreflect.FieldNumber
Extendee protoreflect.MessageDescriptor
Cardinality protoreflect.Cardinality
Kind protoreflect.Kind
EditionFeatures EditionFeatures
}
ExtensionL2 struct {
Options func() protoreflect.ProtoMessage
StringName stringName
IsProto3Optional bool // promoted from google.protobuf.FieldDescriptorProto
Default defaultValue
Enum protoreflect.EnumDescriptor
Message protoreflect.MessageDescriptor
}
)
func (xd *Extension) Options() protoreflect.ProtoMessage {
if f := xd.lazyInit().Options; f != nil {
return f()
}
return descopts.Field
}
func (xd *Extension) Number() protoreflect.FieldNumber { return xd.L1.Number }
func (xd *Extension) Cardinality() protoreflect.Cardinality { return xd.L1.Cardinality }
func (xd *Extension) Kind() protoreflect.Kind { return xd.L1.Kind }
func (xd *Extension) HasJSONName() bool { return xd.lazyInit().StringName.hasJSON }
func (xd *Extension) JSONName() string { return xd.lazyInit().StringName.getJSON(xd) }
func (xd *Extension) TextName() string { return xd.lazyInit().StringName.getText(xd) }
func (xd *Extension) HasPresence() bool { return xd.L1.Cardinality != protoreflect.Repeated }
func (xd *Extension) HasOptionalKeyword() bool {
return (xd.L0.ParentFile.L1.Syntax == protoreflect.Proto2 && xd.L1.Cardinality == protoreflect.Optional) || xd.lazyInit().IsProto3Optional
}
func (xd *Extension) IsPacked() bool {
if xd.L1.Cardinality != protoreflect.Repeated {
return false
}
switch xd.L1.Kind {
case protoreflect.StringKind, protoreflect.BytesKind, protoreflect.MessageKind, protoreflect.GroupKind:
return false
}
return xd.L1.EditionFeatures.IsPacked
}
func (xd *Extension) IsExtension() bool { return true }
func (xd *Extension) IsWeak() bool { return false }
func (xd *Extension) IsList() bool { return xd.Cardinality() == protoreflect.Repeated }
func (xd *Extension) IsMap() bool { return false }
func (xd *Extension) MapKey() protoreflect.FieldDescriptor { return nil }
func (xd *Extension) MapValue() protoreflect.FieldDescriptor { return nil }
func (xd *Extension) HasDefault() bool { return xd.lazyInit().Default.has }
func (xd *Extension) Default() protoreflect.Value { return xd.lazyInit().Default.get(xd) }
func (xd *Extension) DefaultEnumValue() protoreflect.EnumValueDescriptor {
return xd.lazyInit().Default.enum
}
func (xd *Extension) ContainingOneof() protoreflect.OneofDescriptor { return nil }
func (xd *Extension) ContainingMessage() protoreflect.MessageDescriptor { return xd.L1.Extendee }
func (xd *Extension) Enum() protoreflect.EnumDescriptor { return xd.lazyInit().Enum }
func (xd *Extension) Message() protoreflect.MessageDescriptor { return xd.lazyInit().Message }
func (xd *Extension) Format(s fmt.State, r rune) { descfmt.FormatDesc(s, r, xd) }
func (xd *Extension) ProtoType(protoreflect.FieldDescriptor) {}
func (xd *Extension) ProtoInternal(pragma.DoNotImplement) {}
func (xd *Extension) lazyInit() *ExtensionL2 {
xd.L0.ParentFile.lazyInit() // implicitly initializes L2
return xd.L2
}
type (
Service struct {
Base
L1 ServiceL1
L2 *ServiceL2 // protected by fileDesc.once
}
ServiceL1 struct{}
ServiceL2 struct {
Options func() protoreflect.ProtoMessage
Methods Methods
}
Method struct {
Base
L1 MethodL1
}
MethodL1 struct {
Options func() protoreflect.ProtoMessage
Input protoreflect.MessageDescriptor
Output protoreflect.MessageDescriptor
IsStreamingClient bool
IsStreamingServer bool
}
)
func (sd *Service) Options() protoreflect.ProtoMessage {
if f := sd.lazyInit().Options; f != nil {
return f()
}
return descopts.Service
}
func (sd *Service) Methods() protoreflect.MethodDescriptors { return &sd.lazyInit().Methods }
func (sd *Service) Format(s fmt.State, r rune) { descfmt.FormatDesc(s, r, sd) }
func (sd *Service) ProtoType(protoreflect.ServiceDescriptor) {}
func (sd *Service) ProtoInternal(pragma.DoNotImplement) {}
func (sd *Service) lazyInit() *ServiceL2 {
sd.L0.ParentFile.lazyInit() // implicitly initializes L2
return sd.L2
}
func (md *Method) Options() protoreflect.ProtoMessage {
if f := md.L1.Options; f != nil {
return f()
}
return descopts.Method
}
func (md *Method) Input() protoreflect.MessageDescriptor { return md.L1.Input }
func (md *Method) Output() protoreflect.MessageDescriptor { return md.L1.Output }
func (md *Method) IsStreamingClient() bool { return md.L1.IsStreamingClient }
func (md *Method) IsStreamingServer() bool { return md.L1.IsStreamingServer }
func (md *Method) Format(s fmt.State, r rune) { descfmt.FormatDesc(s, r, md) }
func (md *Method) ProtoType(protoreflect.MethodDescriptor) {}
func (md *Method) ProtoInternal(pragma.DoNotImplement) {}
// Surrogate files are can be used to create standalone descriptors
// where the syntax is only information derived from the parent file.
var (
SurrogateProto2 = &File{L1: FileL1{Syntax: protoreflect.Proto2}, L2: &FileL2{}}
SurrogateProto3 = &File{L1: FileL1{Syntax: protoreflect.Proto3}, L2: &FileL2{}}
SurrogateEdition2023 = &File{L1: FileL1{Syntax: protoreflect.Editions, Edition: Edition2023}, L2: &FileL2{}}
)
type (
Base struct {
L0 BaseL0
}
BaseL0 struct {
FullName protoreflect.FullName // must be populated
ParentFile *File // must be populated
Parent protoreflect.Descriptor
Index int
}
)
func (d *Base) Name() protoreflect.Name { return d.L0.FullName.Name() }
func (d *Base) FullName() protoreflect.FullName { return d.L0.FullName }
func (d *Base) ParentFile() protoreflect.FileDescriptor {
if d.L0.ParentFile == SurrogateProto2 || d.L0.ParentFile == SurrogateProto3 {
return nil // surrogate files are not real parents
}
return d.L0.ParentFile
}
func (d *Base) Parent() protoreflect.Descriptor { return d.L0.Parent }
func (d *Base) Index() int { return d.L0.Index }
func (d *Base) Syntax() protoreflect.Syntax { return d.L0.ParentFile.Syntax() }
func (d *Base) IsPlaceholder() bool { return false }
func (d *Base) ProtoInternal(pragma.DoNotImplement) {}
type stringName struct {
hasJSON bool
once sync.Once
nameJSON string
nameText string
}
// InitJSON initializes the name. It is exported for use by other internal packages.
func (s *stringName) InitJSON(name string) {
s.hasJSON = true
s.nameJSON = name
}
// Returns true if this field is structured like the synthetic field of a proto2
// group. This allows us to expand our treatment of delimited fields without
// breaking proto2 files that have been upgraded to editions.
func isGroupLike(fd protoreflect.FieldDescriptor) bool {
// Groups are always group types.
if fd.Kind() != protoreflect.GroupKind {
return false
}
// Group fields are always the lowercase type name.
if strings.ToLower(string(fd.Message().Name())) != string(fd.Name()) {
return false
}
// Groups could only be defined in the same file they're used.
if fd.Message().ParentFile() != fd.ParentFile() {
return false
}
// Group messages are always defined in the same scope as the field. File
// level extensions will compare NULL == NULL here, which is why the file
// comparison above is necessary to ensure both come from the same file.
if fd.IsExtension() {
return fd.Parent() == fd.Message().Parent()
}
return fd.ContainingMessage() == fd.Message().Parent()
}
func (s *stringName) lazyInit(fd protoreflect.FieldDescriptor) *stringName {
s.once.Do(func() {
if fd.IsExtension() {
// For extensions, JSON and text are formatted the same way.
var name string
if messageset.IsMessageSetExtension(fd) {
name = string("[" + fd.FullName().Parent() + "]")
} else {
name = string("[" + fd.FullName() + "]")
}
s.nameJSON = name
s.nameText = name
} else {
// Format the JSON name.
if !s.hasJSON {
s.nameJSON = strs.JSONCamelCase(string(fd.Name()))
}
// Format the text name.
s.nameText = string(fd.Name())
if isGroupLike(fd) {
s.nameText = string(fd.Message().Name())
}
}
})
return s
}
func (s *stringName) getJSON(fd protoreflect.FieldDescriptor) string { return s.lazyInit(fd).nameJSON }
func (s *stringName) getText(fd protoreflect.FieldDescriptor) string { return s.lazyInit(fd).nameText }
func DefaultValue(v protoreflect.Value, ev protoreflect.EnumValueDescriptor) defaultValue {
dv := defaultValue{has: v.IsValid(), val: v, enum: ev}
if b, ok := v.Interface().([]byte); ok {
// Store a copy of the default bytes, so that we can detect
// accidental mutations of the original value.
dv.bytes = append([]byte(nil), b...)
}
return dv
}
func unmarshalDefault(b []byte, k protoreflect.Kind, pf *File, ed protoreflect.EnumDescriptor) defaultValue {
var evs protoreflect.EnumValueDescriptors
if k == protoreflect.EnumKind {
// If the enum is declared within the same file, be careful not to
// blindly call the Values method, lest we bind ourselves in a deadlock.
if e, ok := ed.(*Enum); ok && e.L0.ParentFile == pf {
evs = &e.L2.Values
} else {
evs = ed.Values()
}
// If we are unable to resolve the enum dependency, use a placeholder
// enum value since we will not be able to parse the default value.
if ed.IsPlaceholder() && protoreflect.Name(b).IsValid() {
v := protoreflect.ValueOfEnum(0)
ev := PlaceholderEnumValue(ed.FullName().Parent().Append(protoreflect.Name(b)))
return DefaultValue(v, ev)
}
}
v, ev, err := defval.Unmarshal(string(b), k, evs, defval.Descriptor)
if err != nil {
panic(err)
}
return DefaultValue(v, ev)
}
type defaultValue struct {
has bool
val protoreflect.Value
enum protoreflect.EnumValueDescriptor
bytes []byte
}
func (dv *defaultValue) get(fd protoreflect.FieldDescriptor) protoreflect.Value {
// Return the zero value as the default if unpopulated.
if !dv.has {
if fd.Cardinality() == protoreflect.Repeated {
return protoreflect.Value{}
}
switch fd.Kind() {
case protoreflect.BoolKind:
return protoreflect.ValueOfBool(false)
case protoreflect.Int32Kind, protoreflect.Sint32Kind, protoreflect.Sfixed32Kind:
return protoreflect.ValueOfInt32(0)
case protoreflect.Int64Kind, protoreflect.Sint64Kind, protoreflect.Sfixed64Kind:
return protoreflect.ValueOfInt64(0)
case protoreflect.Uint32Kind, protoreflect.Fixed32Kind:
return protoreflect.ValueOfUint32(0)
case protoreflect.Uint64Kind, protoreflect.Fixed64Kind:
return protoreflect.ValueOfUint64(0)
case protoreflect.FloatKind:
return protoreflect.ValueOfFloat32(0)
case protoreflect.DoubleKind:
return protoreflect.ValueOfFloat64(0)
case protoreflect.StringKind:
return protoreflect.ValueOfString("")
case protoreflect.BytesKind:
return protoreflect.ValueOfBytes(nil)
case protoreflect.EnumKind:
if evs := fd.Enum().Values(); evs.Len() > 0 {
return protoreflect.ValueOfEnum(evs.Get(0).Number())
}
return protoreflect.ValueOfEnum(0)
}
}
if len(dv.bytes) > 0 && !bytes.Equal(dv.bytes, dv.val.Bytes()) {
// TODO: Avoid panic if we're running with the race detector
// and instead spawn a goroutine that periodically resets
// this value back to the original to induce a race.
panic(fmt.Sprintf("detected mutation on the default bytes for %v", fd.FullName()))
}
return dv.val
}