// Code generated by protoc-gen-go-pulsar. DO NOT EDIT. package didv1 import ( _ "cosmossdk.io/api/amino" fmt "fmt" runtime "github.com/cosmos/cosmos-proto/runtime" _ "github.com/cosmos/gogoproto/gogoproto" protoreflect "google.golang.org/protobuf/reflect/protoreflect" protoiface "google.golang.org/protobuf/runtime/protoiface" protoimpl "google.golang.org/protobuf/runtime/protoimpl" io "io" reflect "reflect" sort "sort" sync "sync" ) var ( md_GenesisState protoreflect.MessageDescriptor fd_GenesisState_params protoreflect.FieldDescriptor ) func init() { file_did_v1_genesis_proto_init() md_GenesisState = File_did_v1_genesis_proto.Messages().ByName("GenesisState") fd_GenesisState_params = md_GenesisState.Fields().ByName("params") } var _ protoreflect.Message = (*fastReflection_GenesisState)(nil) type fastReflection_GenesisState GenesisState func (x *GenesisState) ProtoReflect() protoreflect.Message { return (*fastReflection_GenesisState)(x) } func (x *GenesisState) slowProtoReflect() protoreflect.Message { mi := &file_did_v1_genesis_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) } var _fastReflection_GenesisState_messageType fastReflection_GenesisState_messageType var _ protoreflect.MessageType = fastReflection_GenesisState_messageType{} type fastReflection_GenesisState_messageType struct{} func (x fastReflection_GenesisState_messageType) Zero() protoreflect.Message { return (*fastReflection_GenesisState)(nil) } func (x fastReflection_GenesisState_messageType) New() protoreflect.Message { return new(fastReflection_GenesisState) } func (x fastReflection_GenesisState_messageType) Descriptor() protoreflect.MessageDescriptor { return md_GenesisState } // Descriptor returns message descriptor, which contains only the protobuf // type information for the message. func (x *fastReflection_GenesisState) Descriptor() protoreflect.MessageDescriptor { return md_GenesisState } // Type returns the message type, which encapsulates both Go and protobuf // type information. If the Go type information is not needed, // it is recommended that the message descriptor be used instead. func (x *fastReflection_GenesisState) Type() protoreflect.MessageType { return _fastReflection_GenesisState_messageType } // New returns a newly allocated and mutable empty message. func (x *fastReflection_GenesisState) New() protoreflect.Message { return new(fastReflection_GenesisState) } // Interface unwraps the message reflection interface and // returns the underlying ProtoMessage interface. func (x *fastReflection_GenesisState) Interface() protoreflect.ProtoMessage { return (*GenesisState)(x) } // Range iterates over every populated field in an undefined order, // calling f for each field descriptor and value encountered. // Range returns immediately if f returns false. // While iterating, mutating operations may only be performed // on the current field descriptor. func (x *fastReflection_GenesisState) Range(f func(protoreflect.FieldDescriptor, protoreflect.Value) bool) { if x.Params != nil { value := protoreflect.ValueOfMessage(x.Params.ProtoReflect()) if !f(fd_GenesisState_params, value) { return } } } // Has reports whether a field is populated. // // Some fields have the property of nullability where it is possible to // distinguish between the default value of a field and whether the field // was explicitly populated with the default value. Singular message fields, // member fields of a oneof, and proto2 scalar fields are nullable. Such // fields are populated only if explicitly set. // // In other cases (aside from the nullable cases above), // a proto3 scalar field is populated if it contains a non-zero value, and // a repeated field is populated if it is non-empty. func (x *fastReflection_GenesisState) Has(fd protoreflect.FieldDescriptor) bool { switch fd.FullName() { case "did.v1.GenesisState.params": return x.Params != nil default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.GenesisState")) } panic(fmt.Errorf("message did.v1.GenesisState does not contain field %s", fd.FullName())) } } // Clear clears the field such that a subsequent Has call reports false. // // Clearing an extension field clears both the extension type and value // associated with the given field number. // // Clear is a mutating operation and unsafe for concurrent use. func (x *fastReflection_GenesisState) Clear(fd protoreflect.FieldDescriptor) { switch fd.FullName() { case "did.v1.GenesisState.params": x.Params = nil default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.GenesisState")) } panic(fmt.Errorf("message did.v1.GenesisState does not contain field %s", fd.FullName())) } } // Get retrieves the value for a field. // // For unpopulated scalars, it returns the default value, where // the default value of a bytes scalar is guaranteed to be a copy. // For unpopulated composite types, it returns an empty, read-only view // of the value; to obtain a mutable reference, use Mutable. func (x *fastReflection_GenesisState) Get(descriptor protoreflect.FieldDescriptor) protoreflect.Value { switch descriptor.FullName() { case "did.v1.GenesisState.params": value := x.Params return protoreflect.ValueOfMessage(value.ProtoReflect()) default: if descriptor.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.GenesisState")) } panic(fmt.Errorf("message did.v1.GenesisState does not contain field %s", descriptor.FullName())) } } // Set stores the value for a field. // // For a field belonging to a oneof, it implicitly clears any other field // that may be currently set within the same oneof. // For extension fields, it implicitly stores the provided ExtensionType. // When setting a composite type, it is unspecified whether the stored value // aliases the source's memory in any way. If the composite value is an // empty, read-only value, then it panics. // // Set is a mutating operation and unsafe for concurrent use. func (x *fastReflection_GenesisState) Set(fd protoreflect.FieldDescriptor, value protoreflect.Value) { switch fd.FullName() { case "did.v1.GenesisState.params": x.Params = value.Message().Interface().(*Params) default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.GenesisState")) } panic(fmt.Errorf("message did.v1.GenesisState does not contain field %s", fd.FullName())) } } // Mutable returns a mutable reference to a composite type. // // If the field is unpopulated, it may allocate a composite value. // For a field belonging to a oneof, it implicitly clears any other field // that may be currently set within the same oneof. // For extension fields, it implicitly stores the provided ExtensionType // if not already stored. // It panics if the field does not contain a composite type. // // Mutable is a mutating operation and unsafe for concurrent use. func (x *fastReflection_GenesisState) Mutable(fd protoreflect.FieldDescriptor) protoreflect.Value { switch fd.FullName() { case "did.v1.GenesisState.params": if x.Params == nil { x.Params = new(Params) } return protoreflect.ValueOfMessage(x.Params.ProtoReflect()) default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.GenesisState")) } panic(fmt.Errorf("message did.v1.GenesisState does not contain field %s", fd.FullName())) } } // NewField returns a new value that is assignable to the field // for the given descriptor. For scalars, this returns the default value. // For lists, maps, and messages, this returns a new, empty, mutable value. func (x *fastReflection_GenesisState) NewField(fd protoreflect.FieldDescriptor) protoreflect.Value { switch fd.FullName() { case "did.v1.GenesisState.params": m := new(Params) return protoreflect.ValueOfMessage(m.ProtoReflect()) default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.GenesisState")) } panic(fmt.Errorf("message did.v1.GenesisState does not contain field %s", fd.FullName())) } } // WhichOneof reports which field within the oneof is populated, // returning nil if none are populated. // It panics if the oneof descriptor does not belong to this message. func (x *fastReflection_GenesisState) WhichOneof(d protoreflect.OneofDescriptor) protoreflect.FieldDescriptor { switch d.FullName() { default: panic(fmt.Errorf("%s is not a oneof field in did.v1.GenesisState", d.FullName())) } panic("unreachable") } // GetUnknown retrieves the entire list of unknown fields. // The caller may only mutate the contents of the RawFields // if the mutated bytes are stored back into the message with SetUnknown. func (x *fastReflection_GenesisState) GetUnknown() protoreflect.RawFields { return x.unknownFields } // SetUnknown stores an entire list of unknown fields. // The raw fields must be syntactically valid according to the wire format. // An implementation may panic if this is not the case. // Once stored, the caller must not mutate the content of the RawFields. // An empty RawFields may be passed to clear the fields. // // SetUnknown is a mutating operation and unsafe for concurrent use. func (x *fastReflection_GenesisState) SetUnknown(fields protoreflect.RawFields) { x.unknownFields = fields } // IsValid reports whether the message is valid. // // An invalid message is an empty, read-only value. // // An invalid message often corresponds to a nil pointer of the concrete // message type, but the details are implementation dependent. // Validity is not part of the protobuf data model, and may not // be preserved in marshaling or other operations. func (x *fastReflection_GenesisState) IsValid() bool { return x != nil } // ProtoMethods returns optional fastReflectionFeature-path implementations of various operations. // This method may return nil. // // The returned methods type is identical to // "google.golang.org/protobuf/runtime/protoiface".Methods. // Consult the protoiface package documentation for details. func (x *fastReflection_GenesisState) ProtoMethods() *protoiface.Methods { size := func(input protoiface.SizeInput) protoiface.SizeOutput { x := input.Message.Interface().(*GenesisState) if x == nil { return protoiface.SizeOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Size: 0, } } options := runtime.SizeInputToOptions(input) _ = options var n int var l int _ = l if x.Params != nil { l = options.Size(x.Params) n += 1 + l + runtime.Sov(uint64(l)) } if x.unknownFields != nil { n += len(x.unknownFields) } return protoiface.SizeOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Size: n, } } marshal := func(input protoiface.MarshalInput) (protoiface.MarshalOutput, error) { x := input.Message.Interface().(*GenesisState) if x == nil { return protoiface.MarshalOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Buf: input.Buf, }, nil } options := runtime.MarshalInputToOptions(input) _ = options size := options.Size(x) dAtA := make([]byte, size) i := len(dAtA) _ = i var l int _ = l if x.unknownFields != nil { i -= len(x.unknownFields) copy(dAtA[i:], x.unknownFields) } if x.Params != nil { encoded, err := options.Marshal(x.Params) if err != nil { return protoiface.MarshalOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Buf: input.Buf, }, err } i -= len(encoded) copy(dAtA[i:], encoded) i = runtime.EncodeVarint(dAtA, i, uint64(len(encoded))) i-- dAtA[i] = 0xa } if input.Buf != nil { input.Buf = append(input.Buf, dAtA...) } else { input.Buf = dAtA } return protoiface.MarshalOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Buf: input.Buf, }, nil } unmarshal := func(input protoiface.UnmarshalInput) (protoiface.UnmarshalOutput, error) { x := input.Message.Interface().(*GenesisState) if x == nil { return protoiface.UnmarshalOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags, }, nil } options := runtime.UnmarshalInputToOptions(input) _ = options dAtA := input.Buf l := len(dAtA) iNdEx := 0 for iNdEx < l { preIndex := iNdEx var wire uint64 for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ wire |= uint64(b&0x7F) << shift if b < 0x80 { break } } fieldNum := int32(wire >> 3) wireType := int(wire & 0x7) if wireType == 4 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: GenesisState: wiretype end group for non-group") } if fieldNum <= 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: GenesisState: illegal tag %d (wire type %d)", fieldNum, wire) } switch fieldNum { case 1: if wireType != 2 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: wrong wireType = %d for field Params", wireType) } var msglen int for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ msglen |= int(b&0x7F) << shift if b < 0x80 { break } } if msglen < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } postIndex := iNdEx + msglen if postIndex < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if postIndex > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } if x.Params == nil { x.Params = &Params{} } if err := options.Unmarshal(dAtA[iNdEx:postIndex], x.Params); err != nil { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, err } iNdEx = postIndex default: iNdEx = preIndex skippy, err := runtime.Skip(dAtA[iNdEx:]) if err != nil { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, err } if (skippy < 0) || (iNdEx+skippy) < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if (iNdEx + skippy) > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } if !options.DiscardUnknown { x.unknownFields = append(x.unknownFields, dAtA[iNdEx:iNdEx+skippy]...) } iNdEx += skippy } } if iNdEx > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, nil } return &protoiface.Methods{ NoUnkeyedLiterals: struct{}{}, Flags: protoiface.SupportMarshalDeterministic | protoiface.SupportUnmarshalDiscardUnknown, Size: size, Marshal: marshal, Unmarshal: unmarshal, Merge: nil, CheckInitialized: nil, } } var _ protoreflect.Map = (*_Params_2_map)(nil) type _Params_2_map struct { m *map[string]*KeyInfo } func (x *_Params_2_map) Len() int { if x.m == nil { return 0 } return len(*x.m) } func (x *_Params_2_map) Range(f func(protoreflect.MapKey, protoreflect.Value) bool) { if x.m == nil { return } for k, v := range *x.m { mapKey := (protoreflect.MapKey)(protoreflect.ValueOfString(k)) mapValue := protoreflect.ValueOfMessage(v.ProtoReflect()) if !f(mapKey, mapValue) { break } } } func (x *_Params_2_map) Has(key protoreflect.MapKey) bool { if x.m == nil { return false } keyUnwrapped := key.String() concreteValue := keyUnwrapped _, ok := (*x.m)[concreteValue] return ok } func (x *_Params_2_map) Clear(key protoreflect.MapKey) { if x.m == nil { return } keyUnwrapped := key.String() concreteKey := keyUnwrapped delete(*x.m, concreteKey) } func (x *_Params_2_map) Get(key protoreflect.MapKey) protoreflect.Value { if x.m == nil { return protoreflect.Value{} } keyUnwrapped := key.String() concreteKey := keyUnwrapped v, ok := (*x.m)[concreteKey] if !ok { return protoreflect.Value{} } return protoreflect.ValueOfMessage(v.ProtoReflect()) } func (x *_Params_2_map) Set(key protoreflect.MapKey, value protoreflect.Value) { if !key.IsValid() || !value.IsValid() { panic("invalid key or value provided") } keyUnwrapped := key.String() concreteKey := keyUnwrapped valueUnwrapped := value.Message() concreteValue := valueUnwrapped.Interface().(*KeyInfo) (*x.m)[concreteKey] = concreteValue } func (x *_Params_2_map) Mutable(key protoreflect.MapKey) protoreflect.Value { keyUnwrapped := key.String() concreteKey := keyUnwrapped v, ok := (*x.m)[concreteKey] if ok { return protoreflect.ValueOfMessage(v.ProtoReflect()) } newValue := new(KeyInfo) (*x.m)[concreteKey] = newValue return protoreflect.ValueOfMessage(newValue.ProtoReflect()) } func (x *_Params_2_map) NewValue() protoreflect.Value { v := new(KeyInfo) return protoreflect.ValueOfMessage(v.ProtoReflect()) } func (x *_Params_2_map) IsValid() bool { return x.m != nil } var _ protoreflect.List = (*_Params_4_list)(nil) type _Params_4_list struct { list *[]string } func (x *_Params_4_list) Len() int { if x.list == nil { return 0 } return len(*x.list) } func (x *_Params_4_list) Get(i int) protoreflect.Value { return protoreflect.ValueOfString((*x.list)[i]) } func (x *_Params_4_list) Set(i int, value protoreflect.Value) { valueUnwrapped := value.String() concreteValue := valueUnwrapped (*x.list)[i] = concreteValue } func (x *_Params_4_list) Append(value protoreflect.Value) { valueUnwrapped := value.String() concreteValue := valueUnwrapped *x.list = append(*x.list, concreteValue) } func (x *_Params_4_list) AppendMutable() protoreflect.Value { panic(fmt.Errorf("AppendMutable can not be called on message Params at list field AttestationFormats as it is not of Message kind")) } func (x *_Params_4_list) Truncate(n int) { *x.list = (*x.list)[:n] } func (x *_Params_4_list) NewElement() protoreflect.Value { v := "" return protoreflect.ValueOfString(v) } func (x *_Params_4_list) IsValid() bool { return x.list != nil } var ( md_Params protoreflect.MessageDescriptor fd_Params_allowed_public_keys protoreflect.FieldDescriptor fd_Params_conveyance_preference protoreflect.FieldDescriptor fd_Params_attestation_formats protoreflect.FieldDescriptor ) func init() { file_did_v1_genesis_proto_init() md_Params = File_did_v1_genesis_proto.Messages().ByName("Params") fd_Params_allowed_public_keys = md_Params.Fields().ByName("allowed_public_keys") fd_Params_conveyance_preference = md_Params.Fields().ByName("conveyance_preference") fd_Params_attestation_formats = md_Params.Fields().ByName("attestation_formats") } var _ protoreflect.Message = (*fastReflection_Params)(nil) type fastReflection_Params Params func (x *Params) ProtoReflect() protoreflect.Message { return (*fastReflection_Params)(x) } func (x *Params) slowProtoReflect() protoreflect.Message { mi := &file_did_v1_genesis_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) } var _fastReflection_Params_messageType fastReflection_Params_messageType var _ protoreflect.MessageType = fastReflection_Params_messageType{} type fastReflection_Params_messageType struct{} func (x fastReflection_Params_messageType) Zero() protoreflect.Message { return (*fastReflection_Params)(nil) } func (x fastReflection_Params_messageType) New() protoreflect.Message { return new(fastReflection_Params) } func (x fastReflection_Params_messageType) Descriptor() protoreflect.MessageDescriptor { return md_Params } // Descriptor returns message descriptor, which contains only the protobuf // type information for the message. func (x *fastReflection_Params) Descriptor() protoreflect.MessageDescriptor { return md_Params } // Type returns the message type, which encapsulates both Go and protobuf // type information. If the Go type information is not needed, // it is recommended that the message descriptor be used instead. func (x *fastReflection_Params) Type() protoreflect.MessageType { return _fastReflection_Params_messageType } // New returns a newly allocated and mutable empty message. func (x *fastReflection_Params) New() protoreflect.Message { return new(fastReflection_Params) } // Interface unwraps the message reflection interface and // returns the underlying ProtoMessage interface. func (x *fastReflection_Params) Interface() protoreflect.ProtoMessage { return (*Params)(x) } // Range iterates over every populated field in an undefined order, // calling f for each field descriptor and value encountered. // Range returns immediately if f returns false. // While iterating, mutating operations may only be performed // on the current field descriptor. func (x *fastReflection_Params) Range(f func(protoreflect.FieldDescriptor, protoreflect.Value) bool) { if len(x.AllowedPublicKeys) != 0 { value := protoreflect.ValueOfMap(&_Params_2_map{m: &x.AllowedPublicKeys}) if !f(fd_Params_allowed_public_keys, value) { return } } if x.ConveyancePreference != "" { value := protoreflect.ValueOfString(x.ConveyancePreference) if !f(fd_Params_conveyance_preference, value) { return } } if len(x.AttestationFormats) != 0 { value := protoreflect.ValueOfList(&_Params_4_list{list: &x.AttestationFormats}) if !f(fd_Params_attestation_formats, value) { return } } } // Has reports whether a field is populated. // // Some fields have the property of nullability where it is possible to // distinguish between the default value of a field and whether the field // was explicitly populated with the default value. Singular message fields, // member fields of a oneof, and proto2 scalar fields are nullable. Such // fields are populated only if explicitly set. // // In other cases (aside from the nullable cases above), // a proto3 scalar field is populated if it contains a non-zero value, and // a repeated field is populated if it is non-empty. func (x *fastReflection_Params) Has(fd protoreflect.FieldDescriptor) bool { switch fd.FullName() { case "did.v1.Params.allowed_public_keys": return len(x.AllowedPublicKeys) != 0 case "did.v1.Params.conveyance_preference": return x.ConveyancePreference != "" case "did.v1.Params.attestation_formats": return len(x.AttestationFormats) != 0 default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.Params")) } panic(fmt.Errorf("message did.v1.Params does not contain field %s", fd.FullName())) } } // Clear clears the field such that a subsequent Has call reports false. // // Clearing an extension field clears both the extension type and value // associated with the given field number. // // Clear is a mutating operation and unsafe for concurrent use. func (x *fastReflection_Params) Clear(fd protoreflect.FieldDescriptor) { switch fd.FullName() { case "did.v1.Params.allowed_public_keys": x.AllowedPublicKeys = nil case "did.v1.Params.conveyance_preference": x.ConveyancePreference = "" case "did.v1.Params.attestation_formats": x.AttestationFormats = nil default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.Params")) } panic(fmt.Errorf("message did.v1.Params does not contain field %s", fd.FullName())) } } // Get retrieves the value for a field. // // For unpopulated scalars, it returns the default value, where // the default value of a bytes scalar is guaranteed to be a copy. // For unpopulated composite types, it returns an empty, read-only view // of the value; to obtain a mutable reference, use Mutable. func (x *fastReflection_Params) Get(descriptor protoreflect.FieldDescriptor) protoreflect.Value { switch descriptor.FullName() { case "did.v1.Params.allowed_public_keys": if len(x.AllowedPublicKeys) == 0 { return protoreflect.ValueOfMap(&_Params_2_map{}) } mapValue := &_Params_2_map{m: &x.AllowedPublicKeys} return protoreflect.ValueOfMap(mapValue) case "did.v1.Params.conveyance_preference": value := x.ConveyancePreference return protoreflect.ValueOfString(value) case "did.v1.Params.attestation_formats": if len(x.AttestationFormats) == 0 { return protoreflect.ValueOfList(&_Params_4_list{}) } listValue := &_Params_4_list{list: &x.AttestationFormats} return protoreflect.ValueOfList(listValue) default: if descriptor.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.Params")) } panic(fmt.Errorf("message did.v1.Params does not contain field %s", descriptor.FullName())) } } // Set stores the value for a field. // // For a field belonging to a oneof, it implicitly clears any other field // that may be currently set within the same oneof. // For extension fields, it implicitly stores the provided ExtensionType. // When setting a composite type, it is unspecified whether the stored value // aliases the source's memory in any way. If the composite value is an // empty, read-only value, then it panics. // // Set is a mutating operation and unsafe for concurrent use. func (x *fastReflection_Params) Set(fd protoreflect.FieldDescriptor, value protoreflect.Value) { switch fd.FullName() { case "did.v1.Params.allowed_public_keys": mv := value.Map() cmv := mv.(*_Params_2_map) x.AllowedPublicKeys = *cmv.m case "did.v1.Params.conveyance_preference": x.ConveyancePreference = value.Interface().(string) case "did.v1.Params.attestation_formats": lv := value.List() clv := lv.(*_Params_4_list) x.AttestationFormats = *clv.list default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.Params")) } panic(fmt.Errorf("message did.v1.Params does not contain field %s", fd.FullName())) } } // Mutable returns a mutable reference to a composite type. // // If the field is unpopulated, it may allocate a composite value. // For a field belonging to a oneof, it implicitly clears any other field // that may be currently set within the same oneof. // For extension fields, it implicitly stores the provided ExtensionType // if not already stored. // It panics if the field does not contain a composite type. // // Mutable is a mutating operation and unsafe for concurrent use. func (x *fastReflection_Params) Mutable(fd protoreflect.FieldDescriptor) protoreflect.Value { switch fd.FullName() { case "did.v1.Params.allowed_public_keys": if x.AllowedPublicKeys == nil { x.AllowedPublicKeys = make(map[string]*KeyInfo) } value := &_Params_2_map{m: &x.AllowedPublicKeys} return protoreflect.ValueOfMap(value) case "did.v1.Params.attestation_formats": if x.AttestationFormats == nil { x.AttestationFormats = []string{} } value := &_Params_4_list{list: &x.AttestationFormats} return protoreflect.ValueOfList(value) case "did.v1.Params.conveyance_preference": panic(fmt.Errorf("field conveyance_preference of message did.v1.Params is not mutable")) default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.Params")) } panic(fmt.Errorf("message did.v1.Params does not contain field %s", fd.FullName())) } } // NewField returns a new value that is assignable to the field // for the given descriptor. For scalars, this returns the default value. // For lists, maps, and messages, this returns a new, empty, mutable value. func (x *fastReflection_Params) NewField(fd protoreflect.FieldDescriptor) protoreflect.Value { switch fd.FullName() { case "did.v1.Params.allowed_public_keys": m := make(map[string]*KeyInfo) return protoreflect.ValueOfMap(&_Params_2_map{m: &m}) case "did.v1.Params.conveyance_preference": return protoreflect.ValueOfString("") case "did.v1.Params.attestation_formats": list := []string{} return protoreflect.ValueOfList(&_Params_4_list{list: &list}) default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.Params")) } panic(fmt.Errorf("message did.v1.Params does not contain field %s", fd.FullName())) } } // WhichOneof reports which field within the oneof is populated, // returning nil if none are populated. // It panics if the oneof descriptor does not belong to this message. func (x *fastReflection_Params) WhichOneof(d protoreflect.OneofDescriptor) protoreflect.FieldDescriptor { switch d.FullName() { default: panic(fmt.Errorf("%s is not a oneof field in did.v1.Params", d.FullName())) } panic("unreachable") } // GetUnknown retrieves the entire list of unknown fields. // The caller may only mutate the contents of the RawFields // if the mutated bytes are stored back into the message with SetUnknown. func (x *fastReflection_Params) GetUnknown() protoreflect.RawFields { return x.unknownFields } // SetUnknown stores an entire list of unknown fields. // The raw fields must be syntactically valid according to the wire format. // An implementation may panic if this is not the case. // Once stored, the caller must not mutate the content of the RawFields. // An empty RawFields may be passed to clear the fields. // // SetUnknown is a mutating operation and unsafe for concurrent use. func (x *fastReflection_Params) SetUnknown(fields protoreflect.RawFields) { x.unknownFields = fields } // IsValid reports whether the message is valid. // // An invalid message is an empty, read-only value. // // An invalid message often corresponds to a nil pointer of the concrete // message type, but the details are implementation dependent. // Validity is not part of the protobuf data model, and may not // be preserved in marshaling or other operations. func (x *fastReflection_Params) IsValid() bool { return x != nil } // ProtoMethods returns optional fastReflectionFeature-path implementations of various operations. // This method may return nil. // // The returned methods type is identical to // "google.golang.org/protobuf/runtime/protoiface".Methods. // Consult the protoiface package documentation for details. func (x *fastReflection_Params) ProtoMethods() *protoiface.Methods { size := func(input protoiface.SizeInput) protoiface.SizeOutput { x := input.Message.Interface().(*Params) if x == nil { return protoiface.SizeOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Size: 0, } } options := runtime.SizeInputToOptions(input) _ = options var n int var l int _ = l if len(x.AllowedPublicKeys) > 0 { SiZeMaP := func(k string, v *KeyInfo) { l := 0 if v != nil { l = options.Size(v) } l += 1 + runtime.Sov(uint64(l)) mapEntrySize := 1 + len(k) + runtime.Sov(uint64(len(k))) + l n += mapEntrySize + 1 + runtime.Sov(uint64(mapEntrySize)) } if options.Deterministic { sortme := make([]string, 0, len(x.AllowedPublicKeys)) for k := range x.AllowedPublicKeys { sortme = append(sortme, k) } sort.Strings(sortme) for _, k := range sortme { v := x.AllowedPublicKeys[k] SiZeMaP(k, v) } } else { for k, v := range x.AllowedPublicKeys { SiZeMaP(k, v) } } } l = len(x.ConveyancePreference) if l > 0 { n += 1 + l + runtime.Sov(uint64(l)) } if len(x.AttestationFormats) > 0 { for _, s := range x.AttestationFormats { l = len(s) n += 1 + l + runtime.Sov(uint64(l)) } } if x.unknownFields != nil { n += len(x.unknownFields) } return protoiface.SizeOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Size: n, } } marshal := func(input protoiface.MarshalInput) (protoiface.MarshalOutput, error) { x := input.Message.Interface().(*Params) if x == nil { return protoiface.MarshalOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Buf: input.Buf, }, nil } options := runtime.MarshalInputToOptions(input) _ = options size := options.Size(x) dAtA := make([]byte, size) i := len(dAtA) _ = i var l int _ = l if x.unknownFields != nil { i -= len(x.unknownFields) copy(dAtA[i:], x.unknownFields) } if len(x.AttestationFormats) > 0 { for iNdEx := len(x.AttestationFormats) - 1; iNdEx >= 0; iNdEx-- { i -= len(x.AttestationFormats[iNdEx]) copy(dAtA[i:], x.AttestationFormats[iNdEx]) i = runtime.EncodeVarint(dAtA, i, uint64(len(x.AttestationFormats[iNdEx]))) i-- dAtA[i] = 0x22 } } if len(x.ConveyancePreference) > 0 { i -= len(x.ConveyancePreference) copy(dAtA[i:], x.ConveyancePreference) i = runtime.EncodeVarint(dAtA, i, uint64(len(x.ConveyancePreference))) i-- dAtA[i] = 0x1a } if len(x.AllowedPublicKeys) > 0 { MaRsHaLmAp := func(k string, v *KeyInfo) (protoiface.MarshalOutput, error) { baseI := i encoded, err := options.Marshal(v) if err != nil { return protoiface.MarshalOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Buf: input.Buf, }, err } i -= len(encoded) copy(dAtA[i:], encoded) i = runtime.EncodeVarint(dAtA, i, uint64(len(encoded))) i-- dAtA[i] = 0x12 i -= len(k) copy(dAtA[i:], k) i = runtime.EncodeVarint(dAtA, i, uint64(len(k))) i-- dAtA[i] = 0xa i = runtime.EncodeVarint(dAtA, i, uint64(baseI-i)) i-- dAtA[i] = 0x12 return protoiface.MarshalOutput{}, nil } if options.Deterministic { keysForAllowedPublicKeys := make([]string, 0, len(x.AllowedPublicKeys)) for k := range x.AllowedPublicKeys { keysForAllowedPublicKeys = append(keysForAllowedPublicKeys, string(k)) } sort.Slice(keysForAllowedPublicKeys, func(i, j int) bool { return keysForAllowedPublicKeys[i] < keysForAllowedPublicKeys[j] }) for iNdEx := len(keysForAllowedPublicKeys) - 1; iNdEx >= 0; iNdEx-- { v := x.AllowedPublicKeys[string(keysForAllowedPublicKeys[iNdEx])] out, err := MaRsHaLmAp(keysForAllowedPublicKeys[iNdEx], v) if err != nil { return out, err } } } else { for k := range x.AllowedPublicKeys { v := x.AllowedPublicKeys[k] out, err := MaRsHaLmAp(k, v) if err != nil { return out, err } } } } if input.Buf != nil { input.Buf = append(input.Buf, dAtA...) } else { input.Buf = dAtA } return protoiface.MarshalOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Buf: input.Buf, }, nil } unmarshal := func(input protoiface.UnmarshalInput) (protoiface.UnmarshalOutput, error) { x := input.Message.Interface().(*Params) if x == nil { return protoiface.UnmarshalOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags, }, nil } options := runtime.UnmarshalInputToOptions(input) _ = options dAtA := input.Buf l := len(dAtA) iNdEx := 0 for iNdEx < l { preIndex := iNdEx var wire uint64 for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ wire |= uint64(b&0x7F) << shift if b < 0x80 { break } } fieldNum := int32(wire >> 3) wireType := int(wire & 0x7) if wireType == 4 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: Params: wiretype end group for non-group") } if fieldNum <= 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: Params: illegal tag %d (wire type %d)", fieldNum, wire) } switch fieldNum { case 2: if wireType != 2 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: wrong wireType = %d for field AllowedPublicKeys", wireType) } var msglen int for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ msglen |= int(b&0x7F) << shift if b < 0x80 { break } } if msglen < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } postIndex := iNdEx + msglen if postIndex < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if postIndex > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } if x.AllowedPublicKeys == nil { x.AllowedPublicKeys = make(map[string]*KeyInfo) } var mapkey string var mapvalue *KeyInfo for iNdEx < postIndex { entryPreIndex := iNdEx var wire uint64 for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ wire |= uint64(b&0x7F) << shift if b < 0x80 { break } } fieldNum := int32(wire >> 3) if fieldNum == 1 { var stringLenmapkey uint64 for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ stringLenmapkey |= uint64(b&0x7F) << shift if b < 0x80 { break } } intStringLenmapkey := int(stringLenmapkey) if intStringLenmapkey < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } postStringIndexmapkey := iNdEx + intStringLenmapkey if postStringIndexmapkey < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if postStringIndexmapkey > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } mapkey = string(dAtA[iNdEx:postStringIndexmapkey]) iNdEx = postStringIndexmapkey } else if fieldNum == 2 { var mapmsglen int for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ mapmsglen |= int(b&0x7F) << shift if b < 0x80 { break } } if mapmsglen < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } postmsgIndex := iNdEx + mapmsglen if postmsgIndex < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if postmsgIndex > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } mapvalue = &KeyInfo{} if err := options.Unmarshal(dAtA[iNdEx:postmsgIndex], mapvalue); err != nil { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, err } iNdEx = postmsgIndex } else { iNdEx = entryPreIndex skippy, err := runtime.Skip(dAtA[iNdEx:]) if err != nil { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, err } if (skippy < 0) || (iNdEx+skippy) < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if (iNdEx + skippy) > postIndex { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } iNdEx += skippy } } x.AllowedPublicKeys[mapkey] = mapvalue iNdEx = postIndex case 3: if wireType != 2 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: wrong wireType = %d for field ConveyancePreference", wireType) } var stringLen uint64 for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ stringLen |= uint64(b&0x7F) << shift if b < 0x80 { break } } intStringLen := int(stringLen) if intStringLen < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } postIndex := iNdEx + intStringLen if postIndex < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if postIndex > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } x.ConveyancePreference = string(dAtA[iNdEx:postIndex]) iNdEx = postIndex case 4: if wireType != 2 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: wrong wireType = %d for field AttestationFormats", wireType) } var stringLen uint64 for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ stringLen |= uint64(b&0x7F) << shift if b < 0x80 { break } } intStringLen := int(stringLen) if intStringLen < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } postIndex := iNdEx + intStringLen if postIndex < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if postIndex > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } x.AttestationFormats = append(x.AttestationFormats, string(dAtA[iNdEx:postIndex])) iNdEx = postIndex default: iNdEx = preIndex skippy, err := runtime.Skip(dAtA[iNdEx:]) if err != nil { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, err } if (skippy < 0) || (iNdEx+skippy) < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if (iNdEx + skippy) > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } if !options.DiscardUnknown { x.unknownFields = append(x.unknownFields, dAtA[iNdEx:iNdEx+skippy]...) } iNdEx += skippy } } if iNdEx > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, nil } return &protoiface.Methods{ NoUnkeyedLiterals: struct{}{}, Flags: protoiface.SupportMarshalDeterministic | protoiface.SupportUnmarshalDiscardUnknown, Size: size, Marshal: marshal, Unmarshal: unmarshal, Merge: nil, CheckInitialized: nil, } } var ( md_KeyInfo protoreflect.MessageDescriptor fd_KeyInfo_role protoreflect.FieldDescriptor fd_KeyInfo_algorithm protoreflect.FieldDescriptor fd_KeyInfo_encoding protoreflect.FieldDescriptor fd_KeyInfo_curve protoreflect.FieldDescriptor ) func init() { file_did_v1_genesis_proto_init() md_KeyInfo = File_did_v1_genesis_proto.Messages().ByName("KeyInfo") fd_KeyInfo_role = md_KeyInfo.Fields().ByName("role") fd_KeyInfo_algorithm = md_KeyInfo.Fields().ByName("algorithm") fd_KeyInfo_encoding = md_KeyInfo.Fields().ByName("encoding") fd_KeyInfo_curve = md_KeyInfo.Fields().ByName("curve") } var _ protoreflect.Message = (*fastReflection_KeyInfo)(nil) type fastReflection_KeyInfo KeyInfo func (x *KeyInfo) ProtoReflect() protoreflect.Message { return (*fastReflection_KeyInfo)(x) } func (x *KeyInfo) slowProtoReflect() protoreflect.Message { mi := &file_did_v1_genesis_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) } var _fastReflection_KeyInfo_messageType fastReflection_KeyInfo_messageType var _ protoreflect.MessageType = fastReflection_KeyInfo_messageType{} type fastReflection_KeyInfo_messageType struct{} func (x fastReflection_KeyInfo_messageType) Zero() protoreflect.Message { return (*fastReflection_KeyInfo)(nil) } func (x fastReflection_KeyInfo_messageType) New() protoreflect.Message { return new(fastReflection_KeyInfo) } func (x fastReflection_KeyInfo_messageType) Descriptor() protoreflect.MessageDescriptor { return md_KeyInfo } // Descriptor returns message descriptor, which contains only the protobuf // type information for the message. func (x *fastReflection_KeyInfo) Descriptor() protoreflect.MessageDescriptor { return md_KeyInfo } // Type returns the message type, which encapsulates both Go and protobuf // type information. If the Go type information is not needed, // it is recommended that the message descriptor be used instead. func (x *fastReflection_KeyInfo) Type() protoreflect.MessageType { return _fastReflection_KeyInfo_messageType } // New returns a newly allocated and mutable empty message. func (x *fastReflection_KeyInfo) New() protoreflect.Message { return new(fastReflection_KeyInfo) } // Interface unwraps the message reflection interface and // returns the underlying ProtoMessage interface. func (x *fastReflection_KeyInfo) Interface() protoreflect.ProtoMessage { return (*KeyInfo)(x) } // Range iterates over every populated field in an undefined order, // calling f for each field descriptor and value encountered. // Range returns immediately if f returns false. // While iterating, mutating operations may only be performed // on the current field descriptor. func (x *fastReflection_KeyInfo) Range(f func(protoreflect.FieldDescriptor, protoreflect.Value) bool) { if x.Role != "" { value := protoreflect.ValueOfString(x.Role) if !f(fd_KeyInfo_role, value) { return } } if x.Algorithm != "" { value := protoreflect.ValueOfString(x.Algorithm) if !f(fd_KeyInfo_algorithm, value) { return } } if x.Encoding != "" { value := protoreflect.ValueOfString(x.Encoding) if !f(fd_KeyInfo_encoding, value) { return } } if x.Curve != "" { value := protoreflect.ValueOfString(x.Curve) if !f(fd_KeyInfo_curve, value) { return } } } // Has reports whether a field is populated. // // Some fields have the property of nullability where it is possible to // distinguish between the default value of a field and whether the field // was explicitly populated with the default value. Singular message fields, // member fields of a oneof, and proto2 scalar fields are nullable. Such // fields are populated only if explicitly set. // // In other cases (aside from the nullable cases above), // a proto3 scalar field is populated if it contains a non-zero value, and // a repeated field is populated if it is non-empty. func (x *fastReflection_KeyInfo) Has(fd protoreflect.FieldDescriptor) bool { switch fd.FullName() { case "did.v1.KeyInfo.role": return x.Role != "" case "did.v1.KeyInfo.algorithm": return x.Algorithm != "" case "did.v1.KeyInfo.encoding": return x.Encoding != "" case "did.v1.KeyInfo.curve": return x.Curve != "" default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.KeyInfo")) } panic(fmt.Errorf("message did.v1.KeyInfo does not contain field %s", fd.FullName())) } } // Clear clears the field such that a subsequent Has call reports false. // // Clearing an extension field clears both the extension type and value // associated with the given field number. // // Clear is a mutating operation and unsafe for concurrent use. func (x *fastReflection_KeyInfo) Clear(fd protoreflect.FieldDescriptor) { switch fd.FullName() { case "did.v1.KeyInfo.role": x.Role = "" case "did.v1.KeyInfo.algorithm": x.Algorithm = "" case "did.v1.KeyInfo.encoding": x.Encoding = "" case "did.v1.KeyInfo.curve": x.Curve = "" default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.KeyInfo")) } panic(fmt.Errorf("message did.v1.KeyInfo does not contain field %s", fd.FullName())) } } // Get retrieves the value for a field. // // For unpopulated scalars, it returns the default value, where // the default value of a bytes scalar is guaranteed to be a copy. // For unpopulated composite types, it returns an empty, read-only view // of the value; to obtain a mutable reference, use Mutable. func (x *fastReflection_KeyInfo) Get(descriptor protoreflect.FieldDescriptor) protoreflect.Value { switch descriptor.FullName() { case "did.v1.KeyInfo.role": value := x.Role return protoreflect.ValueOfString(value) case "did.v1.KeyInfo.algorithm": value := x.Algorithm return protoreflect.ValueOfString(value) case "did.v1.KeyInfo.encoding": value := x.Encoding return protoreflect.ValueOfString(value) case "did.v1.KeyInfo.curve": value := x.Curve return protoreflect.ValueOfString(value) default: if descriptor.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.KeyInfo")) } panic(fmt.Errorf("message did.v1.KeyInfo does not contain field %s", descriptor.FullName())) } } // Set stores the value for a field. // // For a field belonging to a oneof, it implicitly clears any other field // that may be currently set within the same oneof. // For extension fields, it implicitly stores the provided ExtensionType. // When setting a composite type, it is unspecified whether the stored value // aliases the source's memory in any way. If the composite value is an // empty, read-only value, then it panics. // // Set is a mutating operation and unsafe for concurrent use. func (x *fastReflection_KeyInfo) Set(fd protoreflect.FieldDescriptor, value protoreflect.Value) { switch fd.FullName() { case "did.v1.KeyInfo.role": x.Role = value.Interface().(string) case "did.v1.KeyInfo.algorithm": x.Algorithm = value.Interface().(string) case "did.v1.KeyInfo.encoding": x.Encoding = value.Interface().(string) case "did.v1.KeyInfo.curve": x.Curve = value.Interface().(string) default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.KeyInfo")) } panic(fmt.Errorf("message did.v1.KeyInfo does not contain field %s", fd.FullName())) } } // Mutable returns a mutable reference to a composite type. // // If the field is unpopulated, it may allocate a composite value. // For a field belonging to a oneof, it implicitly clears any other field // that may be currently set within the same oneof. // For extension fields, it implicitly stores the provided ExtensionType // if not already stored. // It panics if the field does not contain a composite type. // // Mutable is a mutating operation and unsafe for concurrent use. func (x *fastReflection_KeyInfo) Mutable(fd protoreflect.FieldDescriptor) protoreflect.Value { switch fd.FullName() { case "did.v1.KeyInfo.role": panic(fmt.Errorf("field role of message did.v1.KeyInfo is not mutable")) case "did.v1.KeyInfo.algorithm": panic(fmt.Errorf("field algorithm of message did.v1.KeyInfo is not mutable")) case "did.v1.KeyInfo.encoding": panic(fmt.Errorf("field encoding of message did.v1.KeyInfo is not mutable")) case "did.v1.KeyInfo.curve": panic(fmt.Errorf("field curve of message did.v1.KeyInfo is not mutable")) default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.KeyInfo")) } panic(fmt.Errorf("message did.v1.KeyInfo does not contain field %s", fd.FullName())) } } // NewField returns a new value that is assignable to the field // for the given descriptor. For scalars, this returns the default value. // For lists, maps, and messages, this returns a new, empty, mutable value. func (x *fastReflection_KeyInfo) NewField(fd protoreflect.FieldDescriptor) protoreflect.Value { switch fd.FullName() { case "did.v1.KeyInfo.role": return protoreflect.ValueOfString("") case "did.v1.KeyInfo.algorithm": return protoreflect.ValueOfString("") case "did.v1.KeyInfo.encoding": return protoreflect.ValueOfString("") case "did.v1.KeyInfo.curve": return protoreflect.ValueOfString("") default: if fd.IsExtension() { panic(fmt.Errorf("proto3 declared messages do not support extensions: did.v1.KeyInfo")) } panic(fmt.Errorf("message did.v1.KeyInfo does not contain field %s", fd.FullName())) } } // WhichOneof reports which field within the oneof is populated, // returning nil if none are populated. // It panics if the oneof descriptor does not belong to this message. func (x *fastReflection_KeyInfo) WhichOneof(d protoreflect.OneofDescriptor) protoreflect.FieldDescriptor { switch d.FullName() { default: panic(fmt.Errorf("%s is not a oneof field in did.v1.KeyInfo", d.FullName())) } panic("unreachable") } // GetUnknown retrieves the entire list of unknown fields. // The caller may only mutate the contents of the RawFields // if the mutated bytes are stored back into the message with SetUnknown. func (x *fastReflection_KeyInfo) GetUnknown() protoreflect.RawFields { return x.unknownFields } // SetUnknown stores an entire list of unknown fields. // The raw fields must be syntactically valid according to the wire format. // An implementation may panic if this is not the case. // Once stored, the caller must not mutate the content of the RawFields. // An empty RawFields may be passed to clear the fields. // // SetUnknown is a mutating operation and unsafe for concurrent use. func (x *fastReflection_KeyInfo) SetUnknown(fields protoreflect.RawFields) { x.unknownFields = fields } // IsValid reports whether the message is valid. // // An invalid message is an empty, read-only value. // // An invalid message often corresponds to a nil pointer of the concrete // message type, but the details are implementation dependent. // Validity is not part of the protobuf data model, and may not // be preserved in marshaling or other operations. func (x *fastReflection_KeyInfo) IsValid() bool { return x != nil } // ProtoMethods returns optional fastReflectionFeature-path implementations of various operations. // This method may return nil. // // The returned methods type is identical to // "google.golang.org/protobuf/runtime/protoiface".Methods. // Consult the protoiface package documentation for details. func (x *fastReflection_KeyInfo) ProtoMethods() *protoiface.Methods { size := func(input protoiface.SizeInput) protoiface.SizeOutput { x := input.Message.Interface().(*KeyInfo) if x == nil { return protoiface.SizeOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Size: 0, } } options := runtime.SizeInputToOptions(input) _ = options var n int var l int _ = l l = len(x.Role) if l > 0 { n += 1 + l + runtime.Sov(uint64(l)) } l = len(x.Algorithm) if l > 0 { n += 1 + l + runtime.Sov(uint64(l)) } l = len(x.Encoding) if l > 0 { n += 1 + l + runtime.Sov(uint64(l)) } l = len(x.Curve) if l > 0 { n += 1 + l + runtime.Sov(uint64(l)) } if x.unknownFields != nil { n += len(x.unknownFields) } return protoiface.SizeOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Size: n, } } marshal := func(input protoiface.MarshalInput) (protoiface.MarshalOutput, error) { x := input.Message.Interface().(*KeyInfo) if x == nil { return protoiface.MarshalOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Buf: input.Buf, }, nil } options := runtime.MarshalInputToOptions(input) _ = options size := options.Size(x) dAtA := make([]byte, size) i := len(dAtA) _ = i var l int _ = l if x.unknownFields != nil { i -= len(x.unknownFields) copy(dAtA[i:], x.unknownFields) } if len(x.Curve) > 0 { i -= len(x.Curve) copy(dAtA[i:], x.Curve) i = runtime.EncodeVarint(dAtA, i, uint64(len(x.Curve))) i-- dAtA[i] = 0x22 } if len(x.Encoding) > 0 { i -= len(x.Encoding) copy(dAtA[i:], x.Encoding) i = runtime.EncodeVarint(dAtA, i, uint64(len(x.Encoding))) i-- dAtA[i] = 0x1a } if len(x.Algorithm) > 0 { i -= len(x.Algorithm) copy(dAtA[i:], x.Algorithm) i = runtime.EncodeVarint(dAtA, i, uint64(len(x.Algorithm))) i-- dAtA[i] = 0x12 } if len(x.Role) > 0 { i -= len(x.Role) copy(dAtA[i:], x.Role) i = runtime.EncodeVarint(dAtA, i, uint64(len(x.Role))) i-- dAtA[i] = 0xa } if input.Buf != nil { input.Buf = append(input.Buf, dAtA...) } else { input.Buf = dAtA } return protoiface.MarshalOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Buf: input.Buf, }, nil } unmarshal := func(input protoiface.UnmarshalInput) (protoiface.UnmarshalOutput, error) { x := input.Message.Interface().(*KeyInfo) if x == nil { return protoiface.UnmarshalOutput{ NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags, }, nil } options := runtime.UnmarshalInputToOptions(input) _ = options dAtA := input.Buf l := len(dAtA) iNdEx := 0 for iNdEx < l { preIndex := iNdEx var wire uint64 for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ wire |= uint64(b&0x7F) << shift if b < 0x80 { break } } fieldNum := int32(wire >> 3) wireType := int(wire & 0x7) if wireType == 4 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: KeyInfo: wiretype end group for non-group") } if fieldNum <= 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: KeyInfo: illegal tag %d (wire type %d)", fieldNum, wire) } switch fieldNum { case 1: if wireType != 2 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: wrong wireType = %d for field Role", wireType) } var stringLen uint64 for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ stringLen |= uint64(b&0x7F) << shift if b < 0x80 { break } } intStringLen := int(stringLen) if intStringLen < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } postIndex := iNdEx + intStringLen if postIndex < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if postIndex > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } x.Role = string(dAtA[iNdEx:postIndex]) iNdEx = postIndex case 2: if wireType != 2 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: wrong wireType = %d for field Algorithm", wireType) } var stringLen uint64 for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ stringLen |= uint64(b&0x7F) << shift if b < 0x80 { break } } intStringLen := int(stringLen) if intStringLen < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } postIndex := iNdEx + intStringLen if postIndex < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if postIndex > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } x.Algorithm = string(dAtA[iNdEx:postIndex]) iNdEx = postIndex case 3: if wireType != 2 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: wrong wireType = %d for field Encoding", wireType) } var stringLen uint64 for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ stringLen |= uint64(b&0x7F) << shift if b < 0x80 { break } } intStringLen := int(stringLen) if intStringLen < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } postIndex := iNdEx + intStringLen if postIndex < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if postIndex > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } x.Encoding = string(dAtA[iNdEx:postIndex]) iNdEx = postIndex case 4: if wireType != 2 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, fmt.Errorf("proto: wrong wireType = %d for field Curve", wireType) } var stringLen uint64 for shift := uint(0); ; shift += 7 { if shift >= 64 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrIntOverflow } if iNdEx >= l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } b := dAtA[iNdEx] iNdEx++ stringLen |= uint64(b&0x7F) << shift if b < 0x80 { break } } intStringLen := int(stringLen) if intStringLen < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } postIndex := iNdEx + intStringLen if postIndex < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if postIndex > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } x.Curve = string(dAtA[iNdEx:postIndex]) iNdEx = postIndex default: iNdEx = preIndex skippy, err := runtime.Skip(dAtA[iNdEx:]) if err != nil { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, err } if (skippy < 0) || (iNdEx+skippy) < 0 { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, runtime.ErrInvalidLength } if (iNdEx + skippy) > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } if !options.DiscardUnknown { x.unknownFields = append(x.unknownFields, dAtA[iNdEx:iNdEx+skippy]...) } iNdEx += skippy } } if iNdEx > l { return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, io.ErrUnexpectedEOF } return protoiface.UnmarshalOutput{NoUnkeyedLiterals: input.NoUnkeyedLiterals, Flags: input.Flags}, nil } return &protoiface.Methods{ NoUnkeyedLiterals: struct{}{}, Flags: protoiface.SupportMarshalDeterministic | protoiface.SupportUnmarshalDiscardUnknown, Size: size, Marshal: marshal, Unmarshal: unmarshal, Merge: nil, CheckInitialized: nil, } } // Code generated by protoc-gen-go. DO NOT EDIT. // versions: // protoc-gen-go v1.27.0 // protoc (unknown) // source: did/v1/genesis.proto const ( // Verify that this generated code is sufficiently up-to-date. _ = protoimpl.EnforceVersion(20 - protoimpl.MinVersion) // Verify that runtime/protoimpl is sufficiently up-to-date. _ = protoimpl.EnforceVersion(protoimpl.MaxVersion - 20) ) // GenesisState defines the module genesis state type GenesisState struct { state protoimpl.MessageState sizeCache protoimpl.SizeCache unknownFields protoimpl.UnknownFields // Params defines all the parameters of the module. Params *Params `protobuf:"bytes,1,opt,name=params,proto3" json:"params,omitempty"` } func (x *GenesisState) Reset() { *x = GenesisState{} if protoimpl.UnsafeEnabled { mi := &file_did_v1_genesis_proto_msgTypes[0] ms := protoimpl.X.MessageStateOf(protoimpl.Pointer(x)) ms.StoreMessageInfo(mi) } } func (x *GenesisState) String() string { return protoimpl.X.MessageStringOf(x) } func (*GenesisState) ProtoMessage() {} // Deprecated: Use GenesisState.ProtoReflect.Descriptor instead. func (*GenesisState) Descriptor() ([]byte, []int) { return file_did_v1_genesis_proto_rawDescGZIP(), []int{0} } func (x *GenesisState) GetParams() *Params { if x != nil { return x.Params } return nil } // Params defines the set of module parameters. type Params struct { state protoimpl.MessageState sizeCache protoimpl.SizeCache unknownFields protoimpl.UnknownFields // Whitelisted Key Types AllowedPublicKeys map[string]*KeyInfo `protobuf:"bytes,2,rep,name=allowed_public_keys,json=allowedPublicKeys,proto3" json:"allowed_public_keys,omitempty" protobuf_key:"bytes,1,opt,name=key,proto3" protobuf_val:"bytes,2,opt,name=value,proto3"` // ConveyancePreference defines the conveyance preference ConveyancePreference string `protobuf:"bytes,3,opt,name=conveyance_preference,json=conveyancePreference,proto3" json:"conveyance_preference,omitempty"` // AttestationFormats defines the attestation formats AttestationFormats []string `protobuf:"bytes,4,rep,name=attestation_formats,json=attestationFormats,proto3" json:"attestation_formats,omitempty"` } func (x *Params) Reset() { *x = Params{} if protoimpl.UnsafeEnabled { mi := &file_did_v1_genesis_proto_msgTypes[1] ms := protoimpl.X.MessageStateOf(protoimpl.Pointer(x)) ms.StoreMessageInfo(mi) } } func (x *Params) String() string { return protoimpl.X.MessageStringOf(x) } func (*Params) ProtoMessage() {} // Deprecated: Use Params.ProtoReflect.Descriptor instead. func (*Params) Descriptor() ([]byte, []int) { return file_did_v1_genesis_proto_rawDescGZIP(), []int{1} } func (x *Params) GetAllowedPublicKeys() map[string]*KeyInfo { if x != nil { return x.AllowedPublicKeys } return nil } func (x *Params) GetConveyancePreference() string { if x != nil { return x.ConveyancePreference } return "" } func (x *Params) GetAttestationFormats() []string { if x != nil { return x.AttestationFormats } return nil } // KeyInfo defines information for accepted PubKey types type KeyInfo struct { state protoimpl.MessageState sizeCache protoimpl.SizeCache unknownFields protoimpl.UnknownFields Role string `protobuf:"bytes,1,opt,name=role,proto3" json:"role,omitempty"` Algorithm string `protobuf:"bytes,2,opt,name=algorithm,proto3" json:"algorithm,omitempty"` // e.g., "ES256", "EdDSA", "ES256K" Encoding string `protobuf:"bytes,3,opt,name=encoding,proto3" json:"encoding,omitempty"` // e.g., "hex", "base64", "multibase" Curve string `protobuf:"bytes,4,opt,name=curve,proto3" json:"curve,omitempty"` // e.g., "P256", "P384", "P521", "X25519", "X448", } func (x 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