// Generated by the protocol buffer compiler. DO NOT EDIT! // source: StubFPGAReadVersionResponse.proto #define INTERNAL_SUPPRESS_PROTOBUF_FIELD_DEPRECATION #include "StubFPGAReadVersionResponse.pb.h" #include #include #include #include #include #include #include #include #include #include // @@protoc_insertion_point(includes) namespace Tango { namespace PMR { namespace Stubs { class StubFPGAReadVersionResponseDefaultTypeInternal { public: ::google::protobuf::internal::ExplicitlyConstructed _instance; } _StubFPGAReadVersionResponse_default_instance_; namespace protobuf_StubFPGAReadVersionResponse_2eproto { namespace { ::google::protobuf::Metadata file_level_metadata[1]; } // namespace PROTOBUF_CONSTEXPR_VAR ::google::protobuf::internal::ParseTableField const TableStruct::entries[] GOOGLE_ATTRIBUTE_SECTION_VARIABLE(protodesc_cold) = { {0, 0, 0, ::google::protobuf::internal::kInvalidMask, 0, 0}, }; PROTOBUF_CONSTEXPR_VAR ::google::protobuf::internal::AuxillaryParseTableField const TableStruct::aux[] GOOGLE_ATTRIBUTE_SECTION_VARIABLE(protodesc_cold) = { ::google::protobuf::internal::AuxillaryParseTableField(), }; PROTOBUF_CONSTEXPR_VAR ::google::protobuf::internal::ParseTable const TableStruct::schema[] GOOGLE_ATTRIBUTE_SECTION_VARIABLE(protodesc_cold) = { { NULL, NULL, 0, -1, -1, -1, -1, NULL, false }, }; const ::google::protobuf::uint32 TableStruct::offsets[] GOOGLE_ATTRIBUTE_SECTION_VARIABLE(protodesc_cold) = { ~0u, // no _has_bits_ GOOGLE_PROTOBUF_GENERATED_MESSAGE_FIELD_OFFSET(StubFPGAReadVersionResponse, _internal_metadata_), ~0u, // no _extensions_ ~0u, // no _oneof_case_ ~0u, // no _weak_field_map_ GOOGLE_PROTOBUF_GENERATED_MESSAGE_FIELD_OFFSET(StubFPGAReadVersionResponse, fpgaid_), GOOGLE_PROTOBUF_GENERATED_MESSAGE_FIELD_OFFSET(StubFPGAReadVersionResponse, day_), GOOGLE_PROTOBUF_GENERATED_MESSAGE_FIELD_OFFSET(StubFPGAReadVersionResponse, month_), GOOGLE_PROTOBUF_GENERATED_MESSAGE_FIELD_OFFSET(StubFPGAReadVersionResponse, year_), GOOGLE_PROTOBUF_GENERATED_MESSAGE_FIELD_OFFSET(StubFPGAReadVersionResponse, ver_num_), GOOGLE_PROTOBUF_GENERATED_MESSAGE_FIELD_OFFSET(StubFPGAReadVersionResponse, status_), GOOGLE_PROTOBUF_GENERATED_MESSAGE_FIELD_OFFSET(StubFPGAReadVersionResponse, statusword_), }; static const ::google::protobuf::internal::MigrationSchema schemas[] GOOGLE_ATTRIBUTE_SECTION_VARIABLE(protodesc_cold) = { { 0, -1, sizeof(StubFPGAReadVersionResponse)}, }; static ::google::protobuf::Message const * const file_default_instances[] = { reinterpret_cast(&_StubFPGAReadVersionResponse_default_instance_), }; namespace { void protobuf_AssignDescriptors() { AddDescriptors(); ::google::protobuf::MessageFactory* factory = NULL; AssignDescriptors( "StubFPGAReadVersionResponse.proto", schemas, file_default_instances, TableStruct::offsets, factory, file_level_metadata, NULL, NULL); } void protobuf_AssignDescriptorsOnce() { static GOOGLE_PROTOBUF_DECLARE_ONCE(once); ::google::protobuf::GoogleOnceInit(&once, &protobuf_AssignDescriptors); } void protobuf_RegisterTypes(const ::std::string&) GOOGLE_ATTRIBUTE_COLD; void protobuf_RegisterTypes(const ::std::string&) { protobuf_AssignDescriptorsOnce(); ::google::protobuf::internal::RegisterAllTypes(file_level_metadata, 1); } } // namespace void TableStruct::InitDefaultsImpl() { GOOGLE_PROTOBUF_VERIFY_VERSION; ::google::protobuf::internal::InitProtobufDefaults(); _StubFPGAReadVersionResponse_default_instance_._instance.DefaultConstruct(); ::google::protobuf::internal::OnShutdownDestroyMessage( &_StubFPGAReadVersionResponse_default_instance_);} void InitDefaults() { static GOOGLE_PROTOBUF_DECLARE_ONCE(once); ::google::protobuf::GoogleOnceInit(&once, &TableStruct::InitDefaultsImpl); } namespace { void AddDescriptorsImpl() { InitDefaults(); static const char descriptor[] GOOGLE_ATTRIBUTE_SECTION_VARIABLE(protodesc_cold) = { "\n!StubFPGAReadVersionResponse.proto\022\017Tan" "go.PMR.Stubs\"\214\001\n\033StubFPGAReadVersionResp" "onse\022\016\n\006FPGAId\030\001 \001(\r\022\013\n\003Day\030\002 \001(\r\022\r\n\005Mon" "th\030\003 \001(\r\022\014\n\004Year\030\004 \001(\r\022\017\n\007Ver_num\030\005 \001(\r\022" "\016\n\006Status\030\006 \001(\t\022\022\n\nStatusWord\030\007 \001(\rB\033\n\031c" "om.twine.tango.pmr.stubsb\006proto3" }; ::google::protobuf::DescriptorPool::InternalAddGeneratedFile( descriptor, 232); ::google::protobuf::MessageFactory::InternalRegisterGeneratedFile( "StubFPGAReadVersionResponse.proto", &protobuf_RegisterTypes); } } // anonymous namespace void AddDescriptors() { static GOOGLE_PROTOBUF_DECLARE_ONCE(once); ::google::protobuf::GoogleOnceInit(&once, &AddDescriptorsImpl); } // Force AddDescriptors() to be called at dynamic initialization time. struct StaticDescriptorInitializer { StaticDescriptorInitializer() { AddDescriptors(); } } static_descriptor_initializer; } // namespace protobuf_StubFPGAReadVersionResponse_2eproto // =================================================================== #if !defined(_MSC_VER) || _MSC_VER >= 1900 const int StubFPGAReadVersionResponse::kFPGAIdFieldNumber; const int StubFPGAReadVersionResponse::kDayFieldNumber; const int StubFPGAReadVersionResponse::kMonthFieldNumber; const int StubFPGAReadVersionResponse::kYearFieldNumber; const int StubFPGAReadVersionResponse::kVerNumFieldNumber; const int StubFPGAReadVersionResponse::kStatusFieldNumber; const int StubFPGAReadVersionResponse::kStatusWordFieldNumber; #endif // !defined(_MSC_VER) || _MSC_VER >= 1900 StubFPGAReadVersionResponse::StubFPGAReadVersionResponse() : ::google::protobuf::Message(), _internal_metadata_(NULL) { if (GOOGLE_PREDICT_TRUE(this != internal_default_instance())) { protobuf_StubFPGAReadVersionResponse_2eproto::InitDefaults(); } SharedCtor(); // @@protoc_insertion_point(constructor:Tango.PMR.Stubs.StubFPGAReadVersionResponse) } StubFPGAReadVersionResponse::StubFPGAReadVersionResponse(const StubFPGAReadVersionResponse& from) : ::google::protobuf::Message(), _internal_metadata_(NULL), _cached_size_(0) { _internal_metadata_.MergeFrom(from._internal_metadata_); status_.UnsafeSetDefault(&::google::protobuf::internal::GetEmptyStringAlreadyInited()); if (from.status().size() > 0) { status_.AssignWithDefault(&::google::protobuf::internal::GetEmptyStringAlreadyInited(), from.status_); } ::memcpy(&fpgaid_, &from.fpgaid_, static_cast(reinterpret_cast(&statusword_) - reinterpret_cast(&fpgaid_)) + sizeof(statusword_)); // @@protoc_insertion_point(copy_constructor:Tango.PMR.Stubs.StubFPGAReadVersionResponse) } void StubFPGAReadVersionResponse::SharedCtor() { status_.UnsafeSetDefault(&::google::protobuf::internal::GetEmptyStringAlreadyInited()); ::memset(&fpgaid_, 0, static_cast( reinterpret_cast(&statusword_) - reinterpret_cast(&fpgaid_)) + sizeof(statusword_)); _cached_size_ = 0; } StubFPGAReadVersionResponse::~StubFPGAReadVersionResponse() { // @@protoc_insertion_point(destructor:Tango.PMR.Stubs.StubFPGAReadVersionResponse) SharedDtor(); } void StubFPGAReadVersionResponse::SharedDtor() { status_.DestroyNoArena(&::google::protobuf::internal::GetEmptyStringAlreadyInited()); } void StubFPGAReadVersionResponse::SetCachedSize(int size) const { GOOGLE_SAFE_CONCURRENT_WRITES_BEGIN(); _cached_size_ = size; GOOGLE_SAFE_CONCURRENT_WRITES_END(); } const ::google::protobuf::Descriptor* StubFPGAReadVersionResponse::descriptor() { protobuf_StubFPGAReadVersionResponse_2eproto::protobuf_AssignDescriptorsOnce(); return protobuf_StubFPGAReadVersionResponse_2eproto::file_level_metadata[kIndexInFileMessages].descriptor; } const StubFPGAReadVersionResponse& StubFPGAReadVersionResponse::default_instance() { protobuf_StubFPGAReadVersionResponse_2eproto::InitDefaults(); return *internal_default_instance(); } StubFPGAReadVersionResponse* StubFPGAReadVersionResponse::New(::google::protobuf::Arena* arena) const { StubFPGAReadVersionResponse* n = new StubFPGAReadVersionResponse; if (arena != NULL) { arena->Own(n); } return n; } void StubFPGAReadVersionResponse::Clear() { // @@protoc_insertion_point(message_clear_start:Tango.PMR.Stubs.StubFPGAReadVersionResponse) ::google::protobuf::uint32 cached_has_bits = 0; // Prevent compiler warnings about cached_has_bits being unused (void) cached_has_bits; status_.ClearToEmptyNoArena(&::google::protobuf::internal::GetEmptyStringAlreadyInited()); ::memset(&fpgaid_, 0, static_cast( reinterpret_cast(&statusword_) - reinterpret_cast(&fpgaid_)) + sizeof(statusword_)); _internal_metadata_.Clear(); } bool StubFPGAReadVersionResponse::MergePartialFromCodedStream( ::google::protobuf::io::CodedInputStream* input) { #define DO_(EXPRESSION) if (!GOOGLE_PREDICT_TRUE(EXPRESSION)) goto failure ::google::protobuf::uint32 tag; // @@protoc_insertion_point(parse_start:Tango.PMR.Stubs.StubFPGAReadVersionResponse) for (;;) { ::std::pair< ::google::protobuf::uint32, bool> p = input->ReadTagWithCutoffNoLastTag(127u); tag = p.first; if (!p.second) goto handle_unusual; switch (::google::protobuf::internal::WireFormatLite::GetTagFieldNumber(tag)) { // uint32 FPGAId = 1; case 1: { if (static_cast< ::google::protobuf::uint8>(tag) == static_cast< ::google::protobuf::uint8>(8u /* 8 & 0xFF */)) { DO_((::google::protobuf::internal::WireFormatLite::ReadPrimitive< ::google::protobuf::uint32, ::google::protobuf::internal::WireFormatLite::TYPE_UINT32>( input, &fpgaid_))); } else { goto handle_unusual; } break; } // uint32 Day = 2; case 2: { if (static_cast< ::google::protobuf::uint8>(tag) == static_cast< ::google::protobuf::uint8>(16u /* 16 & 0xFF */)) { DO_((::google::protobuf::internal::WireFormatLite::ReadPrimitive< ::google::protobuf::uint32, ::google::protobuf::internal::WireFormatLite::TYPE_UINT32>( input, &day_))); } else { goto handle_unusual; } break; } // uint32 Month = 3; case 3: { if (static_cast< ::google::protobuf::uint8>(tag) == static_cast< ::google::protobuf::uint8>(24u /* 24 & 0xFF */)) { DO_((::google::protobuf::internal::WireFormatLite::ReadPrimitive< ::google::protobuf::uint32, ::google::protobuf::internal::WireFormatLite::TYPE_UINT32>( input, &month_))); } else { goto handle_unusual; } break; } // uint32 Year = 4; case 4: { if (static_cast< ::google::protobuf::uint8>(tag) == static_cast< ::google::protobuf::uint8>(32u /* 32 & 0xFF */)) { DO_((::google::protobuf::internal::WireFormatLite::ReadPrimitive< ::google::protobuf::uint32, ::google::protobuf::internal::WireFormatLite::TYPE_UINT32>( input, &year_))); } else { goto handle_unusual; } break; } // uint32 Ver_num = 5; case 5: { if (static_cast< ::google::protobuf::uint8>(tag) == static_cast< ::google::protobuf::uint8>(40u /* 40 & 0xFF */)) { DO_((::google::protobuf::internal::WireFormatLite::ReadPrimitive< ::google::protobuf::uint32, ::google::protobuf::internal::WireFormatLite::TYPE_UINT32>( input, &ver_num_))); } else { goto handle_unusual; } break; } // string Status = 6; case 6: { if (static_cast< ::google::protobuf::uint8>(tag) == static_cast< ::google::protobuf::uint8>(50u /* 50 & 0xFF */)) { DO_(::google::protobuf::internal::WireFormatLite::ReadString( input, this->mutable_status())); DO_(::google::protobuf::internal::WireFormatLite::VerifyUtf8String( this->status().data(), static_cast(this->status().length()), ::google::protobuf::internal::WireFormatLite::PARSE, "Tango.PMR.Stubs.StubFPGAReadVersionResponse.Status")); } else { goto handle_unusual; } break; } // uint32 StatusWord = 7; case 7: { if (static_cast< ::google::protobuf::uint8>(tag) == static_cast< ::google::protobuf::uint8>(56u /* 56 & 0xFF */)) { DO_((::google::protobuf::internal::WireFormatLite::ReadPrimitive< ::google::protobuf::uint32, ::google::protobuf::internal::WireFormatLite::TYPE_UINT32>( input, &statusword_))); } else { goto handle_unusual; } break; } default: { handle_unusual: if (tag == 0) { goto success; } DO_(::google::protobuf::internal::WireFormat::SkipField( input, tag, _internal_metadata_.mutable_unknown_fields())); break; } } } success: // @@protoc_insertion_point(parse_success:Tango.PMR.Stubs.StubFPGAReadVersionResponse) return true; failure: // @@protoc_insertion_point(parse_failure:Tango.PMR.Stubs.StubFPGAReadVersionResponse) return false; #undef DO_ } void StubFPGAReadVersionResponse::SerializeWithCachedSizes( ::google::protobuf::io::CodedOutputStream* output) const { // @@protoc_insertion_point(serialize_start:Tango.PMR.Stubs.StubFPGAReadVersionResponse) ::google::protobuf::uint32 cached_has_bits = 0; (void) cached_has_bits; // uint32 FPGAId = 1; if (this->fpgaid() != 0) { ::google::protobuf::internal::WireFormatLite::WriteUInt32(1, this->fpgaid(), output); } // uint32 Day = 2; if (this->day() != 0) { ::google::protobuf::internal::WireFormatLite::WriteUInt32(2, this->day(), output); } // uint32 Month = 3; if (this->month() != 0) { ::google::protobuf::internal::WireFormatLite::WriteUInt32(3, this->month(), output); } // uint32 Year = 4; if (this->year() != 0) { ::google::protobuf::internal::WireFormatLite::WriteUInt32(4, this->year(), output); } // uint32 Ver_num = 5; if (this->ver_num() != 0) { ::google::protobuf::internal::WireFormatLite::WriteUInt32(5, this->ver_num(), output); } // string Status = 6; if (this->status().size() > 0) { ::google::protobuf::internal::WireFormatLite::VerifyUtf8String( this->status().data(), static_cast(this->status().length()), ::google::protobuf::internal::WireFormatLite::SERIALIZE, "Tango.PMR.Stubs.StubFPGAReadVersionResponse.Status"); ::google::protobuf::internal::WireFormatLite::WriteStringMaybeAliased( 6, this->status(), output); } // uint32 StatusWord = 7; if (this->statusword() != 0) { ::google::protobuf::internal::WireFormatLite::WriteUInt32(7, this->statusword(), output); } if ((_internal_metadata_.have_unknown_fields() && ::google::protobuf::internal::GetProto3PreserveUnknownsDefault())) { ::google::protobuf::internal::WireFormat::SerializeUnknownFields( (::google::protobuf::internal::GetProto3PreserveUnknownsDefault() ? _internal_metadata_.unknown_fields() : _internal_metadata_.default_instance()), output); } // @@protoc_insertion_point(serialize_end:Tango.PMR.Stubs.StubFPGAReadVersionResponse) } ::google::protobuf::uint8* StubFPGAReadVersionResponse::InternalSerializeWithCachedSizesToArray( bool deterministic, ::google::protobuf::uint8* target) const { (void)deterministic; // Unused // @@protoc_insertion_point(serialize_to_array_start:Tango.PMR.Stubs.StubFPGAReadVersionResponse) ::google::protobuf::uint32 cached_has_bits = 0; (void) cached_has_bits; // uint32 FPGAId = 1; if (this->fpgaid() != 0) { target = ::google::protobuf::internal::WireFormatLite::WriteUInt32ToArray(1, this->fpgaid(), target); } // uint32 Day = 2; if (this->day() != 0) { target = ::google::protobuf::internal::WireFormatLite::WriteUInt32ToArray(2, this->day(), target); } // uint32 Month = 3; if (this->month() != 0) { target = ::google::protobuf::internal::WireFormatLite::WriteUInt32ToArray(3, this->month(), target); } // uint32 Year = 4; if (this->year() != 0) { target = ::google::protobuf::internal::WireFormatLite::WriteUInt32ToArray(4, this->year(), target); } // uint32 Ver_num = 5; if (this->ver_num() != 0) { target = ::google::protobuf::internal::WireFormatLite::WriteUInt32ToArray(5, this->ver_num(), target); } // string Status = 6; if (this->status().size() > 0) { ::google::protobuf::internal::WireFormatLite::VerifyUtf8String( this->status().data(), static_cast(this->status().length()), ::google::protobuf::internal::WireFormatLite::SERIALIZE, "Tango.PMR.Stubs.StubFPGAReadVersionResponse.Status"); target = ::google::protobuf::internal::WireFormatLite::WriteStringToArray( 6, this->status(), target); } // uint32 StatusWord = 7; if (this->statusword() != 0) { target = ::google::protobuf::internal::WireFormatLite::WriteUInt32ToArray(7, this->statusword(), target); } if ((_internal_metadata_.have_unknown_fields() && ::google::protobuf::internal::GetProto3PreserveUnknownsDefault())) { target = ::google::protobuf::internal::WireFormat::SerializeUnknownFieldsToArray( (::google::protobuf::internal::GetProto3PreserveUnknownsDefault() ? _internal_metadata_.unknown_fields() : _internal_metadata_.default_instance()), target); } // @@protoc_insertion_point(serialize_to_array_end:Tango.PMR.Stubs.StubFPGAReadVersionResponse) return target; } size_t StubFPGAReadVersionResponse::ByteSizeLong() const { // @@protoc_insertion_point(message_byte_size_start:Tango.PMR.Stubs.StubFPGAReadVersionResponse) size_t total_size = 0; if ((_internal_metadata_.have_unknown_fields() && ::google::protobuf::internal::GetProto3PreserveUnknownsDefault())) { total_size += ::google::protobuf::internal::WireFormat::ComputeUnknownFieldsSize( (::google::protobuf::internal::GetProto3PreserveUnknownsDefault() ? _internal_metadata_.unknown_fields() : _internal_metadata_.default_instance())); } // string Status = 6; if (this->status().size() > 0) { total_size += 1 + ::google::protobuf::internal::WireFormatLite::StringSize( this->status()); } // uint32 FPGAId = 1; if (this->fpgaid() != 0) { total_size += 1 + ::google::protobuf::internal::WireFormatLite::UInt32Size( this->fpgaid()); } // uint32 Day = 2; if (this->day() != 0) { total_size += 1 + ::google::protobuf::internal::WireFormatLite::UInt32Size( this->day()); } // uint32 Month = 3; if (this->month() != 0) { total_size += 1 + ::google::protobuf::internal::WireFormatLite::UInt32Size( this->month()); } // uint32 Year = 4; if (this->year() != 0) { total_size += 1 + ::google::protobuf::internal::WireFormatLite::UInt32Size( this->year()); } // uint32 Ver_num = 5; if (this->ver_num() != 0) { total_size += 1 + ::google::protobuf::internal::WireFormatLite::UInt32Size( this->ver_num()); } // uint32 StatusWord = 7; if (this->statusword() != 0) { total_size += 1 + ::google::protobuf::internal::WireFormatLite::UInt32Size( this->statusword()); } int cached_size = ::google::protobuf::internal::ToCachedSize(total_size); GOOGLE_SAFE_CONCURRENT_WRITES_BEGIN(); _cached_size_ = cached_size; GOOGLE_SAFE_CONCURRENT_WRITES_END(); return total_size; } void StubFPGAReadVersionResponse::MergeFrom(const ::google::protobuf::Message& from) { // @@protoc_insertion_point(generalized_merge_from_start:Tango.PMR.Stubs.StubFPGAReadVersionResponse) GOOGLE_DCHECK_NE(&from, this); const StubFPGAReadVersionResponse* source = ::google::protobuf::internal::DynamicCastToGenerated( &from); if (source == NULL) { // @@protoc_insertion_point(generalized_merge_from_cast_fail:Tango.PMR.Stubs.StubFPGAReadVersionResponse) ::google::protobuf::internal::ReflectionOps::Merge(from, this); } else { // @@protoc_insertion_point(generalized_merge_from_cast_success:Tango.PMR.Stubs.StubFPGAReadVersionResponse) MergeFrom(*source); } } void StubFPGAReadVersionResponse::MergeFrom(const StubFPGAReadVersionResponse& from) { // @@protoc_insertion_point(class_specific_merge_from_start:Tango.PMR.Stubs.StubFPGAReadVersionResponse) GOOGLE_DCHECK_NE(&from, this); _internal_metadata_.MergeFrom(from._internal_metadata_); ::google::protobuf::uint32 cached_has_bits = 0; (void) cached_has_bits; if (from.status().size() > 0) { status_.AssignWithDefault(&::google::protobuf::internal::GetEmptyStringAlreadyInited(), from.status_); } if (from.fpgaid() != 0) { set_fpgaid(from.fpgaid()); } if (from.day() != 0) { set_day(from.day()); } if (from.month() != 0) { set_month(from.month()); } if (from.year() != 0) { set_year(from.year()); } if (from.ver_num() != 0) { set_ver_num(from.ver_num()); } if (from.statusword() != 0) { set_statusword(from.statusword()); } } void StubFPGAReadVersionResponse::CopyFrom(const ::google::protobuf::Message& from) { // @@protoc_insertion_point(generalized_copy_from_start:Tango.PMR.Stubs.StubFPGAReadVersionResponse) if (&from == this) return; Clear(); MergeFrom(from); } void StubFPGAReadVersionResponse::CopyFrom(const StubFPGAReadVersionResponse& from) { // @@protoc_insertion_point(class_specific_copy_from_start:Tango.PMR.Stubs.StubFPGAReadVersionResponse) if (&from == this) return; Clear(); MergeFrom(from); } bool StubFPGAReadVersionResponse::IsInitialized() const { return true; } void StubFPGAReadVersionResponse::Swap(StubFPGAReadVersionResponse* other) { if (other == this) return; InternalSwap(other); } void StubFPGAReadVersionResponse::InternalSwap(StubFPGAReadVersionResponse* other) { using std::swap; status_.Swap(&other->status_); swap(fpgaid_, other->fpgaid_); swap(day_, other->day_); swap(month_, other->month_); swap(year_, other->year_); swap(ver_num_, other->ver_num_); swap(statusword_, other->statusword_); _internal_metadata_.Swap(&other->_internal_metadata_); swap(_cached_size_, other->_cached_size_); } ::google::protobuf::Metadata StubFPGAReadVersionResponse::GetMetadata() const { protobuf_StubFPGAReadVersionResponse_2eproto::protobuf_AssignDescriptorsOnce(); return protobuf_StubFPGAReadVersionResponse_2eproto::file_level_metadata[kIndexInFileMessages]; } #if PROTOBUF_INLINE_NOT_IN_HEADERS // StubFPGAReadVersionResponse // uint32 FPGAId = 1; void StubFPGAReadVersionResponse::clear_fpgaid() { fpgaid_ = 0u; } ::google::protobuf::uint32 StubFPGAReadVersionResponse::fpgaid() const { // @@protoc_insertion_point(field_get:Tango.PMR.Stubs.StubFPGAReadVersionResponse.FPGAId) return fpgaid_; } void StubFPGAReadVersionResponse::set_fpgaid(::google::protobuf::uint32 value) { fpgaid_ = value; // @@protoc_insertion_point(field_set:Tango.PMR.Stubs.StubFPGAReadVersionResponse.FPGAId) } // uint32 Day = 2; void StubFPGAReadVersionResponse::clear_day() { day_ = 0u; } ::google::protobuf::uint32 StubFPGAReadVersionResponse::day() const { // @@protoc_insertion_point(field_get:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Day) return day_; } void StubFPGAReadVersionResponse::set_day(::google::protobuf::uint32 value) { day_ = value; // @@protoc_insertion_point(field_set:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Day) } // uint32 Month = 3; void StubFPGAReadVersionResponse::clear_month() { month_ = 0u; } ::google::protobuf::uint32 StubFPGAReadVersionResponse::month() const { // @@protoc_insertion_point(field_get:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Month) return month_; } void StubFPGAReadVersionResponse::set_month(::google::protobuf::uint32 value) { month_ = value; // @@protoc_insertion_point(field_set:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Month) } // uint32 Year = 4; void StubFPGAReadVersionResponse::clear_year() { year_ = 0u; } ::google::protobuf::uint32 StubFPGAReadVersionResponse::year() const { // @@protoc_insertion_point(field_get:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Year) return year_; } void StubFPGAReadVersionResponse::set_year(::google::protobuf::uint32 value) { year_ = value; // @@protoc_insertion_point(field_set:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Year) } // uint32 Ver_num = 5; void StubFPGAReadVersionResponse::clear_ver_num() { ver_num_ = 0u; } ::google::protobuf::uint32 StubFPGAReadVersionResponse::ver_num() const { // @@protoc_insertion_point(field_get:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Ver_num) return ver_num_; } void StubFPGAReadVersionResponse::set_ver_num(::google::protobuf::uint32 value) { ver_num_ = value; // @@protoc_insertion_point(field_set:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Ver_num) } // string Status = 6; void StubFPGAReadVersionResponse::clear_status() { status_.ClearToEmptyNoArena(&::google::protobuf::internal::GetEmptyStringAlreadyInited()); } const ::std::string& StubFPGAReadVersionResponse::status() const { // @@protoc_insertion_point(field_get:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Status) return status_.GetNoArena(); } void StubFPGAReadVersionResponse::set_status(const ::std::string& value) { status_.SetNoArena(&::google::protobuf::internal::GetEmptyStringAlreadyInited(), value); // @@protoc_insertion_point(field_set:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Status) } #if LANG_CXX11 void StubFPGAReadVersionResponse::set_status(::std::string&& value) { status_.SetNoArena( &::google::protobuf::internal::GetEmptyStringAlreadyInited(), ::std::move(value)); // @@protoc_insertion_point(field_set_rvalue:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Status) } #endif void StubFPGAReadVersionResponse::set_status(const char* value) { GOOGLE_DCHECK(value != NULL); status_.SetNoArena(&::google::protobuf::internal::GetEmptyStringAlreadyInited(), ::std::string(value)); // @@protoc_insertion_point(field_set_char:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Status) } void StubFPGAReadVersionResponse::set_status(const char* value, size_t size) { status_.SetNoArena(&::google::protobuf::internal::GetEmptyStringAlreadyInited(), ::std::string(reinterpret_cast(value), size)); // @@protoc_insertion_point(field_set_pointer:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Status) } ::std::string* StubFPGAReadVersionResponse::mutable_status() { // @@protoc_insertion_point(field_mutable:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Status) return status_.MutableNoArena(&::google::protobuf::internal::GetEmptyStringAlreadyInited()); } ::std::string* StubFPGAReadVersionResponse::release_status() { // @@protoc_insertion_point(field_release:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Status) return status_.ReleaseNoArena(&::google::protobuf::internal::GetEmptyStringAlreadyInited()); } void StubFPGAReadVersionResponse::set_allocated_status(::std::string* status) { if (status != NULL) { } else { } status_.SetAllocatedNoArena(&::google::protobuf::internal::GetEmptyStringAlreadyInited(), status); // @@protoc_insertion_point(field_set_allocated:Tango.PMR.Stubs.StubFPGAReadVersionResponse.Status) } // uint32 StatusWord = 7; void StubFPGAReadVersionResponse::clear_statusword() { statusword_ = 0u; } ::google::protobuf::uint32 StubFPGAReadVersionResponse::statusword() const { // @@protoc_insertion_point(field_get:Tango.PMR.Stubs.StubFPGAReadVersionResponse.StatusWord) return statusword_; } void StubFPGAReadVersionResponse::set_statusword(::google::protobuf::uint32 value) { statusword_ = value; // @@protoc_insertion_point(field_set:Tango.PMR.Stubs.StubFPGAReadVersionResponse.StatusWord) } #endif // PROTOBUF_INLINE_NOT_IN_HEADERS // @@protoc_insertion_point(namespace_scope) } // namespace Stubs } // namespace PMR } // namespace Tango // @@protoc_insertion_point(global_scope)