blob: 7cdbcd28e47203ce56ed999de971df166574d908 [file] [log] [blame]
// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc. All rights reserved.
//
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file or at
// https://developers.google.com/open-source/licenses/bsd
// Author: kenton@google.com (Kenton Varda)
// Based on original Protocol Buffers design by
// Sanjay Ghemawat, Jeff Dean, and others.
//
// A proto file we will use for unit testing.
//
// LINT: ALLOW_GROUPS, LEGACY_NAMES
edition = "2023";
// We don't put this in a package within proto2 because we need to make sure
// that the generated code doesn't depend on being in the proto2 namespace.
// In test_util.h we do "using namespace unittest = protobuf_unittest".
package protobuf_unittest;
import "google/protobuf/unittest_import.proto";
option features = {
enum_type: CLOSED
repeated_field_encoding: EXPANDED
utf8_validation: NONE
};
// Some generic_services option(s) added automatically.
// See: http://go/proto2-generic-services-default
option cc_generic_services = true; // auto-added
option java_generic_services = true; // auto-added
option py_generic_services = true; // auto-added
option cc_enable_arenas = true;
// Protos optimized for SPEED use a strict superset of the generated code
// of equivalent ones optimized for CODE_SIZE, so we should optimize all our
// tests for speed unless explicitly testing code size optimization.
option optimize_for = SPEED;
option java_outer_classname = "UnittestProto";
// This proto includes every type of field in both singular and repeated
// forms.
message TestAllTypes {
message NestedMessage {
// The field name "b" fails to compile in proto1 because it conflicts with
// a local variable named "b" in one of the generated methods. Doh.
// This file needs to compile in proto1 to test backwards-compatibility.
int32 bb = 1;
}
enum NestedEnum {
FOO = 1;
BAR = 2;
BAZ = 3;
NEG = -1; // Intentionally negative.
}
// Singular
int32 optional_int32 = 1;
int64 optional_int64 = 2;
uint32 optional_uint32 = 3;
uint64 optional_uint64 = 4;
sint32 optional_sint32 = 5;
sint64 optional_sint64 = 6;
fixed32 optional_fixed32 = 7;
fixed64 optional_fixed64 = 8;
sfixed32 optional_sfixed32 = 9;
sfixed64 optional_sfixed64 = 10;
float optional_float = 11;
double optional_double = 12;
bool optional_bool = 13;
string optional_string = 14;
bytes optional_bytes = 15;
message OptionalGroup {
int32 a = 17;
}
OptionalGroup optionalgroup = 16 [
features.message_encoding = DELIMITED
];
NestedMessage optional_nested_message = 18;
ForeignMessage optional_foreign_message = 19;
protobuf_unittest_import.ImportMessage optional_import_message = 20;
NestedEnum optional_nested_enum = 21;
ForeignEnum optional_foreign_enum = 22;
protobuf_unittest_import.ImportEnum optional_import_enum = 23;
string optional_string_piece = 24 [
ctype = STRING_PIECE
];
string optional_cord = 25 [
ctype = CORD
];
bytes optional_bytes_cord = 86 [ctype=CORD];
// Defined in unittest_import_public.proto
protobuf_unittest_import.PublicImportMessage optional_public_import_message = 26;
NestedMessage optional_lazy_message = 27 [
lazy = true
];
NestedMessage optional_unverified_lazy_message = 28 [
unverified_lazy = true
];
// Repeated
repeated int32 repeated_int32 = 31;
repeated int64 repeated_int64 = 32;
repeated uint32 repeated_uint32 = 33;
repeated uint64 repeated_uint64 = 34;
repeated sint32 repeated_sint32 = 35;
repeated sint64 repeated_sint64 = 36;
repeated fixed32 repeated_fixed32 = 37;
repeated fixed64 repeated_fixed64 = 38;
repeated sfixed32 repeated_sfixed32 = 39;
repeated sfixed64 repeated_sfixed64 = 40;
repeated float repeated_float = 41;
repeated double repeated_double = 42;
repeated bool repeated_bool = 43;
repeated string repeated_string = 44;
repeated bytes repeated_bytes = 45;
message RepeatedGroup {
int32 a = 47;
}
repeated RepeatedGroup repeatedgroup = 46 [
features.message_encoding = DELIMITED
];
repeated NestedMessage repeated_nested_message = 48;
repeated ForeignMessage repeated_foreign_message = 49;
repeated protobuf_unittest_import.ImportMessage repeated_import_message = 50;
repeated NestedEnum repeated_nested_enum = 51;
repeated ForeignEnum repeated_foreign_enum = 52;
repeated protobuf_unittest_import.ImportEnum repeated_import_enum = 53;
repeated string repeated_string_piece = 54 [
ctype = STRING_PIECE
];
repeated string repeated_cord = 55 [
ctype = CORD
];
repeated NestedMessage repeated_lazy_message = 57 [
lazy = true
];
// Singular with defaults
int32 default_int32 = 61 [
default = 41
];
int64 default_int64 = 62 [
default = 42
];
uint32 default_uint32 = 63 [
default = 43
];
uint64 default_uint64 = 64 [
default = 44
];
sint32 default_sint32 = 65 [
default = -45
];
sint64 default_sint64 = 66 [
default = 46
];
fixed32 default_fixed32 = 67 [
default = 47
];
fixed64 default_fixed64 = 68 [
default = 48
];
sfixed32 default_sfixed32 = 69 [
default = 49
];
sfixed64 default_sfixed64 = 70 [
default = -50
];
float default_float = 71 [
default = 51.5
];
double default_double = 72 [
default = 5.2e4
];
bool default_bool = 73 [
default = true
];
string default_string = 74 [
default = "hello"
];
bytes default_bytes = 75 [
default = "world"
];
NestedEnum default_nested_enum = 81 [
default = BAR
];
ForeignEnum default_foreign_enum = 82 [
default = FOREIGN_BAR
];
protobuf_unittest_import.ImportEnum default_import_enum = 83 [
default = IMPORT_BAR
];
string default_string_piece = 84 [
ctype = STRING_PIECE,
default = "abc"
];
string default_cord = 85 [
ctype = CORD,
default = "123"
];
// For oneof test
oneof oneof_field {
uint32 oneof_uint32 = 111;
NestedMessage oneof_nested_message = 112;
string oneof_string = 113;
bytes oneof_bytes = 114;
string oneof_cord = 115 [
ctype = CORD
];
string oneof_string_piece = 116 [
ctype = STRING_PIECE
];
NestedMessage oneof_lazy_nested_message = 117 [
lazy = true
];
}
}
// This proto includes a recursively nested message.
message NestedTestAllTypes {
NestedTestAllTypes child = 1;
TestAllTypes payload = 2;
repeated NestedTestAllTypes repeated_child = 3;
NestedTestAllTypes lazy_child = 4 [
lazy = true
];
TestAllTypes eager_child = 5 [
lazy = false
];
}
message TestDeprecatedFields {
int32 deprecated_int32 = 1 [
deprecated = true
];
repeated string deprecated_repeated_string = 4 [
deprecated = true
];
TestAllTypes.NestedMessage deprecated_message = 3 [
deprecated = true
];
oneof oneof_fields {
int32 deprecated_int32_in_oneof = 2 [
deprecated = true
];
}
TestDeprecatedFields nested = 5;
}
message TestDeprecatedMessage {
option deprecated = true;
}
// Define these after TestAllTypes to make sure the compiler can handle
// that.
message ForeignMessage {
int32 c = 1;
int32 d = 2;
}
enum ForeignEnum {
FOREIGN_FOO = 4;
FOREIGN_BAR = 5;
FOREIGN_BAZ = 6;
FOREIGN_BAX = 32; // (1 << 32) to generate a 64b bitmask would be incorrect.
FOREIGN_LARGE = 123456; // Large enough to escape the Boxed Integer cache.
}
enum TestDeprecatedEnum {
option deprecated = true;
TEST_DEPRECATED_ENUM_UNSPECIFIED = 0;
TEST_DEPRECATED_ENUM_VALUE1 = 1;
TEST_DEPRECATED_ENUM_VALUE2 = 2;
}
message TestReservedFields {
reserved 2, 15, 9 to 11;
reserved bar, baz;
}
enum TestReservedEnumFields {
UNKNOWN = 0;
reserved 2, 15, 9 to 11;
reserved bar, baz;
}
message TestAllExtensions {
extensions 1 to max;
}
extend TestAllExtensions {
// Singular
int32 optional_int32_extension = 1;
int64 optional_int64_extension = 2;
uint32 optional_uint32_extension = 3;
uint64 optional_uint64_extension = 4;
sint32 optional_sint32_extension = 5;
sint64 optional_sint64_extension = 6;
fixed32 optional_fixed32_extension = 7;
fixed64 optional_fixed64_extension = 8;
sfixed32 optional_sfixed32_extension = 9;
sfixed64 optional_sfixed64_extension = 10;
float optional_float_extension = 11;
double optional_double_extension = 12;
bool optional_bool_extension = 13;
string optional_string_extension = 14;
bytes optional_bytes_extension = 15;
OptionalGroup_extension optionalgroup_extension = 16 [
features.message_encoding = DELIMITED
];
TestAllTypes.NestedMessage optional_nested_message_extension = 18;
ForeignMessage optional_foreign_message_extension = 19;
protobuf_unittest_import.ImportMessage optional_import_message_extension = 20;
TestAllTypes.NestedEnum optional_nested_enum_extension = 21;
ForeignEnum optional_foreign_enum_extension = 22;
protobuf_unittest_import.ImportEnum optional_import_enum_extension = 23;
string optional_string_piece_extension = 24 [
ctype = STRING_PIECE
];
// TODO: ctype=CORD is not supported for extension. Add
// ctype=CORD option back after it is supported.
string optional_cord_extension = 25;
bytes optional_bytes_cord_extension = 86;
protobuf_unittest_import.PublicImportMessage
optional_public_import_message_extension = 26;
TestAllTypes.NestedMessage optional_lazy_message_extension = 27 [
lazy = true
];
TestAllTypes.NestedMessage optional_unverified_lazy_message_extension = 28 [
unverified_lazy = true
];
// Repeated
repeated int32 repeated_int32_extension = 31;
repeated int64 repeated_int64_extension = 32;
repeated uint32 repeated_uint32_extension = 33;
repeated uint64 repeated_uint64_extension = 34;
repeated sint32 repeated_sint32_extension = 35;
repeated sint64 repeated_sint64_extension = 36;
repeated fixed32 repeated_fixed32_extension = 37;
repeated fixed64 repeated_fixed64_extension = 38;
repeated sfixed32 repeated_sfixed32_extension = 39;
repeated sfixed64 repeated_sfixed64_extension = 40;
repeated float repeated_float_extension = 41;
repeated double repeated_double_extension = 42;
repeated bool repeated_bool_extension = 43;
repeated string repeated_string_extension = 44;
repeated bytes repeated_bytes_extension = 45;
repeated RepeatedGroup_extension repeatedgroup_extension = 46 [
features.message_encoding = DELIMITED
];
repeated TestAllTypes.NestedMessage repeated_nested_message_extension = 48;
repeated ForeignMessage repeated_foreign_message_extension = 49;
repeated protobuf_unittest_import.ImportMessage
repeated_import_message_extension = 50;
repeated TestAllTypes.NestedEnum repeated_nested_enum_extension = 51;
repeated ForeignEnum repeated_foreign_enum_extension = 52;
repeated protobuf_unittest_import.ImportEnum repeated_import_enum_extension = 53;
repeated string repeated_string_piece_extension = 54 [
ctype = STRING_PIECE
];
// TODO: ctype=CORD is not supported for extension. Add
// ctype=CORD option back after it is supported.
repeated string repeated_cord_extension = 55;
repeated TestAllTypes.NestedMessage repeated_lazy_message_extension = 57 [
lazy = true
];
// Singular with defaults
int32 default_int32_extension = 61 [
default = 41
];
int64 default_int64_extension = 62 [
default = 42
];
uint32 default_uint32_extension = 63 [
default = 43
];
uint64 default_uint64_extension = 64 [
default = 44
];
sint32 default_sint32_extension = 65 [
default = -45
];
sint64 default_sint64_extension = 66 [
default = 46
];
fixed32 default_fixed32_extension = 67 [
default = 47
];
fixed64 default_fixed64_extension = 68 [
default = 48
];
sfixed32 default_sfixed32_extension = 69 [
default = 49
];
sfixed64 default_sfixed64_extension = 70 [
default = -50
];
float default_float_extension = 71 [
default = 51.5
];
double default_double_extension = 72 [
default = 5.2e4
];
bool default_bool_extension = 73 [
default = true
];
string default_string_extension = 74 [
default = "hello"
];
bytes default_bytes_extension = 75 [
default = "world"
];
TestAllTypes.NestedEnum default_nested_enum_extension = 81 [
default = BAR
];
ForeignEnum default_foreign_enum_extension = 82 [
default = FOREIGN_BAR
];
protobuf_unittest_import.ImportEnum default_import_enum_extension = 83 [
default = IMPORT_BAR
];
string default_string_piece_extension = 84 [
ctype = STRING_PIECE,
default = "abc"
];
// TODO: ctype=CORD is not supported for extension. Add
// ctype=CORD option back after it is supported.
string default_cord_extension = 85 [
default = "123"
];
// For oneof test
uint32 oneof_uint32_extension = 111;
TestAllTypes.NestedMessage oneof_nested_message_extension = 112;
string oneof_string_extension = 113;
bytes oneof_bytes_extension = 114;
}
message OptionalGroup_extension {
int32 a = 17;
}
message RepeatedGroup_extension {
int32 a = 47;
}
message TestMixedFieldsAndExtensions {
int32 a = 1;
repeated fixed32 b = 3;
extensions 2, 4;
extend TestMixedFieldsAndExtensions {
int32 c = 2;
repeated fixed32 d = 4;
}
}
message TestGroup {
message OptionalGroup {
int32 a = 17;
int32 zz = 89; // fast table size must be at least 16, for this
// field to be parsed by the fast parser, since
// 89 - 17 = 72 is a multiple of 8.
}
OptionalGroup optionalgroup = 16 [
features.message_encoding = DELIMITED
];
ForeignEnum optional_foreign_enum = 22;
}
message TestGroupExtension {
extensions 1 to max;
}
message TestNestedExtension {
extend TestAllExtensions {
// Check for bug where string extensions declared in tested scope did not
// compile.
string test = 1002 [
default = "test"
];
// Used to test if generated extension name is correct when there are
// underscores.
string nested_string_extension = 1003;
}
extend TestGroupExtension {
OptionalGroup_extension optionalgroup_extension = 16 [
features.message_encoding = DELIMITED
];
ForeignEnum optional_foreign_enum_extension = 22;
}
message OptionalGroup_extension {
int32 a = 17;
}
}
message TestChildExtension {
string a = 1;
string b = 2;
TestAllExtensions optional_extension = 3;
}
// Emulates wireformat data of TestChildExtension with dynamic extension
// (DynamicExtension).
message TestChildExtensionData {
message NestedTestAllExtensionsData {
message NestedDynamicExtensions {
int32 a = 1;
int32 b = 2;
}
NestedDynamicExtensions dynamic = 409707008;
}
string a = 1;
string b = 2;
NestedTestAllExtensionsData optional_extension = 3;
}
message TestNestedChildExtension {
int32 a = 1;
TestChildExtension child = 2;
}
// Emulates wireformat data of TestNestedChildExtension with dynamic extension
// (DynamicExtension).
message TestNestedChildExtensionData {
int32 a = 1;
TestChildExtensionData child = 2;
}
// Required and closed enum fields are considered unknown fields if the value is
// not valid. We need to make sure it functions as expected.
message TestRequiredEnum {
ForeignEnum required_enum = 1 [
features.field_presence = LEGACY_REQUIRED
];
// A dummy optional field.
int32 a = 2;
}
// Required and open enum accepts invalid enum values.
enum ForeignOpenEnum {
option features.enum_type = OPEN;
FOREIGN_OPEN_UNKNOWN = 0;
FOREIGN_OPEN_FOO = 4;
FOREIGN_OPEN_BAR = 5;
FOREIGN_OPEN_BAZ = 6;
FOREIGN_OPEN_BAX = 32; // (1 << 32) to generate a 64b bitmask would be
// incorrect.
}
message TestRequiredOpenEnum {
ForeignOpenEnum required_enum = 1 [
features.field_presence = LEGACY_REQUIRED
];
// A dummy optional field.
int32 a = 2;
}
// TestRequiredEnum + using enum values that won't fit to 64 bitmask.
message TestRequiredEnumNoMask {
enum NestedEnum {
UNSPECIFIED = 0;
FOO = 2;
BAR = 100;
BAZ = -1; // Intentionally negative.
}
NestedEnum required_enum = 1 [
features.field_presence = LEGACY_REQUIRED
];
// A dummy optional field.
int32 a = 2;
}
message TestRequiredEnumMulti {
enum NestedEnum {
UNSPECIFIED = 0;
FOO = 1;
BAR = 2;
BAZ = 100;
}
// Intentionally placed in descending field number to force sorting in closed
// enum verification.
NestedEnum required_enum_4 = 4 [
features.field_presence = LEGACY_REQUIRED
];
int32 a_3 = 3;
NestedEnum required_enum_2 = 2 [
features.field_presence = LEGACY_REQUIRED
];
ForeignEnum required_enum_1 = 1 [
features.field_presence = LEGACY_REQUIRED
];
}
message TestRequiredNoMaskMulti {
enum NestedEnum {
UNSPECIFIED = 0;
FOO = 1;
BAR = 2;
BAZ = 100;
}
// Intentionally placed in descending field number to force sorting in closed
// enum verification. Also, using large field numbers to use tag only
// matching for required fields.
fixed32 required_fixed32_80 = 80 [
features.field_presence = LEGACY_REQUIRED
];
fixed32 required_fixed32_70 = 70 [
features.field_presence = LEGACY_REQUIRED
];
NestedEnum required_enum_64 = 64 [
features.field_presence = LEGACY_REQUIRED
];
NestedEnum required_enum_4 = 4 [
features.field_presence = LEGACY_REQUIRED
];
int32 a_3 = 3;
NestedEnum required_enum_2 = 2 [
features.field_presence = LEGACY_REQUIRED
];
ForeignEnum required_enum_1 = 1 [
features.field_presence = LEGACY_REQUIRED
];
}
// We have separate messages for testing required fields because it's
// annoying to have to fill in required fields in TestProto in order to
// do anything with it. Note that we don't need to test every type of
// required filed because the code output is basically identical to
// optional fields for all types.
message TestRequired {
int32 a = 1 [
features.field_presence = LEGACY_REQUIRED
];
int32 dummy2 = 2;
int32 b = 3 [
features.field_presence = LEGACY_REQUIRED
];
extend TestAllExtensions {
TestRequired single = 1000;
repeated TestRequired multi = 1001;
}
// Pad the field count to 32 so that we can test that IsInitialized()
// properly checks multiple elements of has_bits_.
int32 dummy4 = 4;
int32 dummy5 = 5;
int32 dummy6 = 6;
int32 dummy7 = 7;
int32 dummy8 = 8;
int32 dummy9 = 9;
int32 dummy10 = 10;
int32 dummy11 = 11;
int32 dummy12 = 12;
int32 dummy13 = 13;
int32 dummy14 = 14;
int32 dummy15 = 15;
int32 dummy16 = 16;
int32 dummy17 = 17;
int32 dummy18 = 18;
int32 dummy19 = 19;
int32 dummy20 = 20;
int32 dummy21 = 21;
int32 dummy22 = 22;
int32 dummy23 = 23;
int32 dummy24 = 24;
int32 dummy25 = 25;
int32 dummy26 = 26;
int32 dummy27 = 27;
int32 dummy28 = 28;
int32 dummy29 = 29;
int32 dummy30 = 30;
int32 dummy31 = 31;
int32 dummy32 = 32;
int32 c = 33 [
features.field_presence = LEGACY_REQUIRED
];
// Add an optional child message to make this non-trivial for go/pdlazy.
ForeignMessage optional_foreign = 34;
}
message TestRequiredForeign {
TestRequired optional_message = 1;
repeated TestRequired repeated_message = 2;
int32 dummy = 3;
// Missing required fields must not affect verification of child messages.
NestedTestAllTypes optional_lazy_message = 4 [
lazy = true
];
}
message TestRequiredMessage {
TestRequired optional_message = 1;
repeated TestRequired repeated_message = 2;
TestRequired required_message = 3 [
features.field_presence = LEGACY_REQUIRED
];
}
message TestNestedRequiredForeign {
TestNestedRequiredForeign child = 1;
TestRequiredForeign payload = 2;
int32 dummy = 3;
// optional message to test required closed enum.
TestRequiredEnum required_enum = 5;
TestRequiredEnumNoMask required_enum_no_mask = 6;
TestRequiredEnumMulti required_enum_multi = 7;
TestRequiredNoMaskMulti required_no_mask = 9;
}
// Test that we can use NestedMessage from outside TestAllTypes.
message TestForeignNested {
TestAllTypes.NestedMessage foreign_nested = 1;
}
// TestEmptyMessage is used to test unknown field support.
message TestEmptyMessage {
}
// Like above, but declare all field numbers as potential extensions. No
// actual extensions should ever be defined for this type.
message TestEmptyMessageWithExtensions {
extensions 1 to max;
}
// Needed for a Python test.
message TestPickleNestedMessage {
message NestedMessage {
int32 bb = 1;
message NestedNestedMessage {
int32 cc = 1;
}
}
}
message TestMultipleExtensionRanges {
extensions 42;
extensions 4143 to 4243;
extensions 65536 to max;
}
// Test that really large tag numbers don't break anything.
message TestReallyLargeTagNumber {
// The largest possible tag number is 2^28 - 1, since the wire format uses
// three bits to communicate wire type.
int32 a = 1;
int32 bb = 268435455;
}
message TestRecursiveMessage {
TestRecursiveMessage a = 1;
int32 i = 2;
}
// Test that mutual recursion works.
message TestMutualRecursionA {
message SubMessage {
TestMutualRecursionB b = 1;
}
TestMutualRecursionB bb = 1;
message SubGroup {
SubMessage sub_message = 3; // Needed because of bug in javatest
TestAllTypes not_in_this_scc = 4;
}
SubGroup subgroup = 2 [
features.message_encoding = DELIMITED
];
message SubGroupR {
TestAllTypes payload = 6;
}
repeated SubGroupR subgroupr = 5 [
features.message_encoding = DELIMITED
];
}
message TestMutualRecursionB {
TestMutualRecursionA a = 1;
int32 optional_int32 = 2;
}
message TestIsInitialized {
message SubMessage {
message SubGroup {
int32 i = 2 [
features.field_presence = LEGACY_REQUIRED
];
}
SubGroup subgroup = 1 [
features.message_encoding = DELIMITED
];
}
SubMessage sub_message = 1;
}
// Test that groups have disjoint field numbers from their siblings and
// parents. This is NOT possible in proto1; only google.protobuf. When attempting
// to compile with proto1, this will emit an error; so we only include it
// in protobuf_unittest_proto.
message TestDupFieldNumber {// NO_PROTO1
int32 a = 1; // NO_PROTO1
message Foo { // NO_PROTO1
int32 a = 1; // NO_PROTO1
} // NO_PROTO1
Foo foo = 2 [features.message_encoding = DELIMITED]; // NO_PROTO1
message Bar { // NO_PROTO1
int32 a = 1; // NO_PROTO1
} // NO_PROTO1
Bar bar = 3 [features.message_encoding = DELIMITED]; // NO_PROTO1
} // NO_PROTO1
// Additional messages for testing lazy fields.
message TestEagerMessage {
TestAllTypes sub_message = 1 [
lazy = false
];
}
message TestLazyMessage {
TestAllTypes sub_message = 1 [
lazy = true
];
}
message TestLazyMessageRepeated {
repeated TestLazyMessage repeated_message = 1;
}
message TestEagerMaybeLazy {
message NestedMessage {
TestPackedTypes packed = 1;
}
TestAllTypes message_foo = 1;
TestAllTypes message_bar = 2;
NestedMessage message_baz = 3;
}
// Needed for a Python test.
message TestNestedMessageHasBits {
message NestedMessage {
repeated int32 nestedmessage_repeated_int32 = 1;
repeated ForeignMessage nestedmessage_repeated_foreignmessage = 2;
}
NestedMessage optional_nested_message = 1;
}
// Test an enum that has multiple values with the same number.
enum TestEnumWithDupValue {
option allow_alias = true;
FOO1 = 1;
BAR1 = 2;
BAZ = 3;
FOO2 = 1;
BAR2 = 2;
}
// Test an enum with large, unordered values.
enum TestSparseEnum {
SPARSE_A = 123;
SPARSE_B = 62374;
SPARSE_C = 12589234;
SPARSE_D = -15;
SPARSE_E = -53452;
SPARSE_F = 0;
SPARSE_G = 2;
}
// Test message with CamelCase field names. This violates Protocol Buffer
// standard style.
message TestCamelCaseFieldNames {
int32 PrimitiveField = 1;
string StringField = 2;
ForeignEnum EnumField = 3;
ForeignMessage MessageField = 4;
string StringPieceField = 5 [
ctype = STRING_PIECE
];
string CordField = 6 [
ctype = CORD
];
repeated int32 RepeatedPrimitiveField = 7;
repeated string RepeatedStringField = 8;
repeated ForeignEnum RepeatedEnumField = 9;
repeated ForeignMessage RepeatedMessageField = 10;
repeated string RepeatedStringPieceField = 11 [
ctype = STRING_PIECE
];
repeated string RepeatedCordField = 12 [
ctype = CORD
];
}
// We list fields out of order, to ensure that we're using field number and not
// field index to determine serialization order.
message TestFieldOrderings {
string my_string = 11;
extensions 2 to 10;
int64 my_int = 1;
extensions 12 to 100;
float my_float = 101;
message NestedMessage {
int64 oo = 2;
// The field name "b" fails to compile in proto1 because it conflicts with
// a local variable named "b" in one of the generated methods. Doh.
// This file needs to compile in proto1 to test backwards-compatibility.
int32 bb = 1;
}
NestedMessage optional_nested_message = 200;
}
extend TestFieldOrderings {
string my_extension_string = 50;
int32 my_extension_int = 5;
}
message TestExtensionOrderings1 {
extend TestFieldOrderings {
TestExtensionOrderings1 test_ext_orderings1 = 13;
}
string my_string = 1;
}
message TestExtensionOrderings2 {
extend TestFieldOrderings {
TestExtensionOrderings2 test_ext_orderings2 = 12;
}
message TestExtensionOrderings3 {
extend TestFieldOrderings {
TestExtensionOrderings3 test_ext_orderings3 = 14;
}
string my_string = 1;
}
string my_string = 1;
}
message TestExtremeDefaultValues {
bytes escaped_bytes = 1 [
default =
"\0\001\a\b\f\n\r\t\v\\\'\"\xfe"
];
uint32 large_uint32 = 2 [
default = 0xFFFFFFFF
];
uint64 large_uint64 = 3 [
default = 0xFFFFFFFFFFFFFFFF
];
int32 small_int32 = 4 [
default = -0x7FFFFFFF
];
int64 small_int64 = 5 [
default = -0x7FFFFFFFFFFFFFFF
];
int32 really_small_int32 = 21 [
default = -0x80000000
];
int64 really_small_int64 = 22 [
default = -0x8000000000000000
];
// The default value here is UTF-8 for "\u1234". (We could also just type
// the UTF-8 text directly into this text file rather than escape it, but
// lots of people use editors that would be confused by this.)
string utf8_string = 6 [
default = "\341\210\264"
];
// Tests for single-precision floating-point values.
float zero_float = 7 [
default = 0
];
float one_float = 8 [
default = 1
];
float small_float = 9 [
default = 1.5
];
float negative_one_float = 10 [
default = -1
];
float negative_float = 11 [
default = -1.5
];
// Using exponents
float large_float = 12 [
default = 2e8
];
float small_negative_float = 13 [
default = -8e-28
];
// Text for nonfinite floating-point values.
double inf_double = 14 [
default = inf
];
double neg_inf_double = 15 [
default = -inf
];
double nan_double = 16 [
default = nan
];
float inf_float = 17 [
default = inf
];
float neg_inf_float = 18 [
default = -inf
];
float nan_float = 19 [
default = nan
];
// Tests for C++ trigraphs.
// Trigraphs should be escaped in C++ generated files, but they should not be
// escaped for other languages.
// Note that in .proto file, "\?" is a valid way to escape ? in string
// literals.
string cpp_trigraph = 20 [
default = "? \? ?? \?? \??? ??/ ?\?-"
];
// String defaults containing the character '\000'
string string_with_zero = 23 [
default = "hel\000lo"
];
bytes bytes_with_zero = 24 [
default = "wor\000ld"
];
string string_piece_with_zero = 25 [
ctype = STRING_PIECE,
default = "ab\000c"
];
string cord_with_zero = 26 [
ctype = CORD,
default = "12\0003"
];
string replacement_string = 27 [
default = "${unknown}"
];
}
message SparseEnumMessage {
TestSparseEnum sparse_enum = 1;
}
// Test String and Bytes: string is for valid UTF-8 strings
message OneString {
string data = 1;
}
message MoreString {
repeated string data = 1;
}
message OneBytes {
bytes data = 1;
}
message MoreBytes {
repeated bytes data = 1;
}
message ManyOptionalString {
string str1 = 1;
string str2 = 2;
string str3 = 3;
string str4 = 4;
string str5 = 5;
string str6 = 6;
string str7 = 7;
string str8 = 8;
string str9 = 9;
string str10 = 10;
string str11 = 11;
string str12 = 12;
string str13 = 13;
string str14 = 14;
string str15 = 15;
string str16 = 16;
string str17 = 17;
string str18 = 18;
string str19 = 19;
string str20 = 20;
string str21 = 21;
string str22 = 22;
string str23 = 23;
string str24 = 24;
string str25 = 25;
string str26 = 26;
string str27 = 27;
string str28 = 28;
string str29 = 29;
string str30 = 30;
string str31 = 31;
string str32 = 32;
}
// Test int32, uint32, int64, uint64, and bool are all compatible
message Int32Message {
int32 data = 1;
}
message Uint32Message {
uint32 data = 1;
}
message Int64Message {
int64 data = 1;
}
message Uint64Message {
uint64 data = 1;
}
message BoolMessage {
bool data = 1;
}
// Test oneofs.
message TestOneof {
oneof foo {
int32 foo_int = 1;
string foo_string = 2;
TestAllTypes foo_message = 3;
FooGroup foogroup = 4 [
features.message_encoding = DELIMITED
];
}
message FooGroup {
int32 a = 5;
string b = 6;
}
}
message TestOneofBackwardsCompatible {
int32 foo_int = 1;
string foo_string = 2;
TestAllTypes foo_message = 3;
message FooGroup {
int32 a = 5;
string b = 6;
}
FooGroup foogroup = 4 [
features.message_encoding = DELIMITED
];
}
message TestOneof2 {
oneof foo {
int32 foo_int = 1;
string foo_string = 2;
string foo_cord = 3 [
ctype = CORD
];
string foo_string_piece = 4 [
ctype = STRING_PIECE
];
bytes foo_bytes = 5;
NestedEnum foo_enum = 6;
NestedMessage foo_message = 7;
FooGroup foogroup = 8 [
features.message_encoding = DELIMITED
];
NestedMessage foo_lazy_message = 11 [
lazy = true
];
bytes foo_bytes_cord = 30 [
ctype = CORD
];
}
message FooGroup {
int32 a = 9;
string b = 10;
}
oneof bar {
int32 bar_int = 12 [
default = 5
];
string bar_string = 13 [
default = "STRING"
];
string bar_cord = 14 [
ctype = CORD,
default = "CORD"
];
string bar_string_piece = 15 [
ctype = STRING_PIECE,
default = "SPIECE"
];
bytes bar_bytes = 16 [
default = "BYTES"
];
NestedEnum bar_enum = 17 [
default = BAR
];
string bar_string_with_empty_default = 20 [
default = ""
];
string bar_cord_with_empty_default = 21 [
ctype = CORD,
default = ""
];
string bar_string_piece_with_empty_default = 22 [
ctype = STRING_PIECE,
default = ""
];
bytes bar_bytes_with_empty_default = 23 [
default = ""
];
}
int32 baz_int = 18;
string baz_string = 19 [
default = "BAZ"
];
message NestedMessage {
int64 moo_int = 1;
repeated int32 corge_int = 2;
NestedMessage child = 3;
}
enum NestedEnum {
FOO = 1;
BAR = 2;
BAZ = 3;
}
}
message TestRequiredOneof {
oneof foo {
int32 foo_int = 1;
string foo_string = 2;
NestedMessage foo_message = 3;
NestedMessage foo_lazy_message = 4 [
lazy = true
];
}
message NestedMessage {
double required_double = 1 [
features.field_presence = LEGACY_REQUIRED
];
}
}
// Test messages for packed fields
message TestPackedTypes {
repeated int32 packed_int32 = 90 [
features.repeated_field_encoding = PACKED
];
repeated int64 packed_int64 = 91 [
features.repeated_field_encoding = PACKED
];
repeated uint32 packed_uint32 = 92 [
features.repeated_field_encoding = PACKED
];
repeated uint64 packed_uint64 = 93 [
features.repeated_field_encoding = PACKED
];
repeated sint32 packed_sint32 = 94 [
features.repeated_field_encoding = PACKED
];
repeated sint64 packed_sint64 = 95 [
features.repeated_field_encoding = PACKED
];
repeated fixed32 packed_fixed32 = 96 [
features.repeated_field_encoding = PACKED
];
repeated fixed64 packed_fixed64 = 97 [
features.repeated_field_encoding = PACKED
];
repeated sfixed32 packed_sfixed32 = 98 [
features.repeated_field_encoding = PACKED
];
repeated sfixed64 packed_sfixed64 = 99 [
features.repeated_field_encoding = PACKED
];
repeated float packed_float = 100 [
features.repeated_field_encoding = PACKED
];
repeated double packed_double = 101 [
features.repeated_field_encoding = PACKED
];
repeated bool packed_bool = 102 [
features.repeated_field_encoding = PACKED
];
repeated ForeignEnum packed_enum = 103 [
features.repeated_field_encoding = PACKED
];
}
// A message with the same fields as TestPackedTypes, but without packing. Used
// to test packed <-> unpacked wire compatibility.
message TestUnpackedTypes {
repeated int32 unpacked_int32 = 90;
repeated int64 unpacked_int64 = 91;
repeated uint32 unpacked_uint32 = 92;
repeated uint64 unpacked_uint64 = 93;
repeated sint32 unpacked_sint32 = 94;
repeated sint64 unpacked_sint64 = 95;
repeated fixed32 unpacked_fixed32 = 96;
repeated fixed64 unpacked_fixed64 = 97;
repeated sfixed32 unpacked_sfixed32 = 98;
repeated sfixed64 unpacked_sfixed64 = 99;
repeated float unpacked_float = 100;
repeated double unpacked_double = 101;
repeated bool unpacked_bool = 102;
repeated ForeignEnum unpacked_enum = 103;
}
message TestPackedExtensions {
extensions 1 to max;
}
extend TestPackedExtensions {
repeated int32 packed_int32_extension = 90 [
features.repeated_field_encoding = PACKED
];
repeated int64 packed_int64_extension = 91 [
features.repeated_field_encoding = PACKED
];
repeated uint32 packed_uint32_extension = 92 [
features.repeated_field_encoding = PACKED
];
repeated uint64 packed_uint64_extension = 93 [
features.repeated_field_encoding = PACKED
];
repeated sint32 packed_sint32_extension = 94 [
features.repeated_field_encoding = PACKED
];
repeated sint64 packed_sint64_extension = 95 [
features.repeated_field_encoding = PACKED
];
repeated fixed32 packed_fixed32_extension = 96 [
features.repeated_field_encoding = PACKED
];
repeated fixed64 packed_fixed64_extension = 97 [
features.repeated_field_encoding = PACKED
];
repeated sfixed32 packed_sfixed32_extension = 98 [
features.repeated_field_encoding = PACKED
];
repeated sfixed64 packed_sfixed64_extension = 99 [
features.repeated_field_encoding = PACKED
];
repeated float packed_float_extension = 100 [
features.repeated_field_encoding = PACKED
];
repeated double packed_double_extension = 101 [
features.repeated_field_encoding = PACKED
];
repeated bool packed_bool_extension = 102 [
features.repeated_field_encoding = PACKED
];
repeated ForeignEnum packed_enum_extension = 103 [
features.repeated_field_encoding = PACKED
];
}
message TestUnpackedExtensions {
extensions 1 to max;
}
extend TestUnpackedExtensions {
repeated int32 unpacked_int32_extension = 90;
repeated int64 unpacked_int64_extension = 91;
repeated uint32 unpacked_uint32_extension = 92;
repeated uint64 unpacked_uint64_extension = 93;
repeated sint32 unpacked_sint32_extension = 94;
repeated sint64 unpacked_sint64_extension = 95;
repeated fixed32 unpacked_fixed32_extension = 96;
repeated fixed64 unpacked_fixed64_extension = 97;
repeated sfixed32 unpacked_sfixed32_extension = 98;
repeated sfixed64 unpacked_sfixed64_extension = 99;
repeated float unpacked_float_extension = 100;
repeated double unpacked_double_extension = 101;
repeated bool unpacked_bool_extension = 102;
repeated ForeignEnum unpacked_enum_extension = 103;
}
// Used by ExtensionSetTest/DynamicExtensions. The test actually builds
// a set of extensions to TestAllExtensions dynamically, based on the fields
// of this message type.
message TestDynamicExtensions {
enum DynamicEnumType {
DYNAMIC_FOO = 2200;
DYNAMIC_BAR = 2201;
DYNAMIC_BAZ = 2202;
}
message DynamicMessageType {
int32 dynamic_field = 2100;
}
fixed32 scalar_extension = 2000;
ForeignEnum enum_extension = 2001;
DynamicEnumType dynamic_enum_extension = 2002;
ForeignMessage message_extension = 2003;
DynamicMessageType dynamic_message_extension = 2004;
repeated string repeated_extension = 2005;
repeated sint32 packed_extension = 2006 [
features.repeated_field_encoding = PACKED
];
}
message TestRepeatedString {
repeated string repeated_string1 = 1;
repeated string repeated_string2 = 2;
repeated bytes repeated_bytes11 = 11;
repeated bytes repeated_bytes12 = 12;
}
message TestRepeatedScalarDifferentTagSizes {
// Parsing repeated fixed size values used to fail. This message needs to be
// used in order to get a tag of the right size; all of the repeated fields
// in TestAllTypes didn't trigger the check.
repeated fixed32 repeated_fixed32 = 12;
// Check for a varint type, just for good measure.
repeated int32 repeated_int32 = 13;
// These have two-byte tags.
repeated fixed64 repeated_fixed64 = 2046;
repeated int64 repeated_int64 = 2047;
// Three byte tags.
repeated float repeated_float = 262142;
repeated uint64 repeated_uint64 = 262143;
}
// Test that if an optional or required message/group field appears multiple
// times in the input, they need to be merged.
message TestParsingMerge {
// RepeatedFieldsGenerator defines matching field types as TestParsingMerge,
// except that all fields are repeated. In the tests, we will serialize the
// RepeatedFieldsGenerator to bytes, and parse the bytes to TestParsingMerge.
// Repeated fields in RepeatedFieldsGenerator are expected to be merged into
// the corresponding required/optional fields in TestParsingMerge.
message RepeatedFieldsGenerator {
repeated TestAllTypes field1 = 1;
repeated TestAllTypes field2 = 2;
repeated TestAllTypes field3 = 3;
message Group1 {
TestAllTypes field1 = 11;
}
repeated Group1 group1 = 10 [
features.message_encoding = DELIMITED
];
message Group2 {
TestAllTypes field1 = 21;
}
repeated Group2 group2 = 20 [
features.message_encoding = DELIMITED
];
repeated TestAllTypes ext1 = 1000;
repeated TestAllTypes ext2 = 1001;
}
TestAllTypes required_all_types = 1 [
features.field_presence = LEGACY_REQUIRED
];
TestAllTypes optional_all_types = 2;
repeated TestAllTypes repeated_all_types = 3;
message OptionalGroup {
TestAllTypes optional_group_all_types = 11;
}
OptionalGroup optionalgroup = 10 [
features.message_encoding = DELIMITED
];
message RepeatedGroup {
TestAllTypes repeated_group_all_types = 21;
}
repeated RepeatedGroup repeatedgroup = 20 [
features.message_encoding = DELIMITED
];
extensions 1000 to max;
extend TestParsingMerge {
TestAllTypes optional_ext = 1000;
repeated TestAllTypes repeated_ext = 1001;
}
}
// Test that the correct exception is thrown by parseFrom in a corner case
// involving merging, extensions, and required fields.
message TestMergeException {
TestAllExtensions all_extensions = 1;
}
message TestCommentInjectionMessage {
// */ <- This should not close the generated doc comment
string a = 1 [
default = "*/ <- Neither should this."
];
}
// Used to check that the c++ code generator re-orders messages to reduce
// padding.
message TestMessageSize {
bool m1 = 1;
int64 m2 = 2;
bool m3 = 3;
string m4 = 4;
int32 m5 = 5;
int64 m6 = 6;
}
message OpenEnumMessage {
enum TestEnum {
option features.enum_type = OPEN;
UNKNOWN = 0;
FOO = 1;
BAR = 2;
BAZ = 3;
}
TestEnum opt_open = 1;
ForeignEnum opt_closed = 2;
repeated TestEnum repeated_open = 3;
repeated ForeignEnum repeated_closed = 4;
}
// Tests eager verification of a lazy message field.
message TestEagerlyVerifiedLazyMessage {
message LazyMessage {
bytes bytes_field = 1;
}
LazyMessage lazy_message = 1 [lazy = true];
}
// Test that RPC services work.
message FooRequest {
}
message FooResponse {
}
message FooClientMessage {
}
message FooServerMessage {
}
service TestService {
rpc Foo(FooRequest) returns (FooResponse);
rpc Bar(BarRequest) returns (BarResponse);
}
message BarRequest {
}
message BarResponse {
}
message TestJsonName {
int32 field_name1 = 1;
int32 fieldName2 = 2;
int32 FieldName3 = 3;
int32 _field_name4 = 4;
int32 FIELD_NAME5 = 5;
int32 field_name6 = 6 [
json_name = "@type"
];
int32 fieldname7 = 7;
}
message TestHugeFieldNumbers {
int32 optional_int32 = 536870000;
int32 fixed_32 = 536870001;
repeated int32 repeated_int32 = 536870002;
repeated int32 packed_int32 = 536870003 [
features.repeated_field_encoding = PACKED
];
ForeignEnum optional_enum = 536870004;
string optional_string = 536870005;
bytes optional_bytes = 536870006;
ForeignMessage optional_message = 536870007;
message OptionalGroup {
int32 group_a = 536870009;
}
OptionalGroup optionalgroup = 536870008 [
features.message_encoding = DELIMITED
];
map<string, string> string_string_map = 536870010;
oneof oneof_field {
uint32 oneof_uint32 = 536870011;
TestAllTypes oneof_test_all_types = 536870012;
string oneof_string = 536870013;
bytes oneof_bytes = 536870014;
}
extensions 536860000 to 536869999 [
declaration = {
number: 536860000
full_name: ".protobuf_unittest.test_all_types"
type: ".protobuf_unittest.TestAllTypes"
}
];
}
extend TestHugeFieldNumbers {
TestAllTypes test_all_types = 536860000;
}
message TestExtensionInsideTable {
int32 field1 = 1;
int32 field2 = 2;
int32 field3 = 3;
int32 field4 = 4;
extensions 5;
int32 field6 = 6;
int32 field7 = 7;
int32 field8 = 8;
int32 field9 = 9;
int32 field10 = 10;
}
extend TestExtensionInsideTable {
int32 test_extension_inside_table_extension = 5;
}
// NOTE: Intentionally nested to mirror go/glep.
message TestNestedGroupExtensionOuter {
message Layer1OptionalGroup {
message Layer2RepeatedGroup {
extensions 3
// NOTE: extension metadata is not supported due to targets such as
// `//google/protobuf_legacy_opensource/src:shell_scripts_test`,
// eee https://screenshot.googleplex.com/Axz2QD8nxjdpyFF
// [metadata = {
// NOTE: can't write type there due to some clever build gen code at
// http://google3/google/protobuf/BUILD;l=1247;rcl=411090862
// type: "protobuf_unittest.TestNestedGroupExtensionInnerExtension",
// name: "inner",
// }]
;
string another_field = 6;
}
repeated Layer2RepeatedGroup layer2repeatedgroup = 2 [
features.message_encoding = DELIMITED
];
message Layer2AnotherOptionalRepeatedGroup {
string but_why_tho = 5;
}
repeated Layer2AnotherOptionalRepeatedGroup
layer2anotheroptionalrepeatedgroup = 4 [
features.message_encoding = DELIMITED
];
}
Layer1OptionalGroup layer1optionalgroup = 1 [
features.message_encoding = DELIMITED
];
}
message TestNestedGroupExtensionInnerExtension {
string inner_name = 1;
}
extend TestNestedGroupExtensionOuter.Layer1OptionalGroup.Layer2RepeatedGroup {
TestNestedGroupExtensionInnerExtension inner = 3;
}
enum VeryLargeEnum {
ENUM_LABEL_DEFAULT = 0;
ENUM_LABEL_1 = 1;
ENUM_LABEL_2 = 2;
ENUM_LABEL_3 = 3;
ENUM_LABEL_4 = 4;
ENUM_LABEL_5 = 5;
ENUM_LABEL_6 = 6;
ENUM_LABEL_7 = 7;
ENUM_LABEL_8 = 8;
ENUM_LABEL_9 = 9;
ENUM_LABEL_10 = 10;
ENUM_LABEL_11 = 11;
ENUM_LABEL_12 = 12;
ENUM_LABEL_13 = 13;
ENUM_LABEL_14 = 14;
ENUM_LABEL_15 = 15;
ENUM_LABEL_16 = 16;
ENUM_LABEL_17 = 17;
ENUM_LABEL_18 = 18;
ENUM_LABEL_19 = 19;
ENUM_LABEL_20 = 20;
ENUM_LABEL_21 = 21;
ENUM_LABEL_22 = 22;
ENUM_LABEL_23 = 23;
ENUM_LABEL_24 = 24;
ENUM_LABEL_25 = 25;
ENUM_LABEL_26 = 26;
ENUM_LABEL_27 = 27;
ENUM_LABEL_28 = 28;
ENUM_LABEL_29 = 29;
ENUM_LABEL_30 = 30;
ENUM_LABEL_31 = 31;
ENUM_LABEL_32 = 32;
ENUM_LABEL_33 = 33;
ENUM_LABEL_34 = 34;
ENUM_LABEL_35 = 35;
ENUM_LABEL_36 = 36;
ENUM_LABEL_37 = 37;
ENUM_LABEL_38 = 38;
ENUM_LABEL_39 = 39;
ENUM_LABEL_40 = 40;
ENUM_LABEL_41 = 41;
ENUM_LABEL_42 = 42;
ENUM_LABEL_43 = 43;
ENUM_LABEL_44 = 44;
ENUM_LABEL_45 = 45;
ENUM_LABEL_46 = 46;
ENUM_LABEL_47 = 47;
ENUM_LABEL_48 = 48;
ENUM_LABEL_49 = 49;
ENUM_LABEL_50 = 50;
ENUM_LABEL_51 = 51;
ENUM_LABEL_52 = 52;
ENUM_LABEL_53 = 53;
ENUM_LABEL_54 = 54;
ENUM_LABEL_55 = 55;
ENUM_LABEL_56 = 56;
ENUM_LABEL_57 = 57;
ENUM_LABEL_58 = 58;
ENUM_LABEL_59 = 59;
ENUM_LABEL_60 = 60;
ENUM_LABEL_61 = 61;
ENUM_LABEL_62 = 62;
ENUM_LABEL_63 = 63;
ENUM_LABEL_64 = 64;
ENUM_LABEL_65 = 65;
ENUM_LABEL_66 = 66;
ENUM_LABEL_67 = 67;
ENUM_LABEL_68 = 68;
ENUM_LABEL_69 = 69;
ENUM_LABEL_70 = 70;
ENUM_LABEL_71 = 71;
ENUM_LABEL_72 = 72;
ENUM_LABEL_73 = 73;
ENUM_LABEL_74 = 74;
ENUM_LABEL_75 = 75;
ENUM_LABEL_76 = 76;
ENUM_LABEL_77 = 77;
ENUM_LABEL_78 = 78;
ENUM_LABEL_79 = 79;
ENUM_LABEL_80 = 80;
ENUM_LABEL_81 = 81;
ENUM_LABEL_82 = 82;
ENUM_LABEL_83 = 83;
ENUM_LABEL_84 = 84;
ENUM_LABEL_85 = 85;
ENUM_LABEL_86 = 86;
ENUM_LABEL_87 = 87;
ENUM_LABEL_88 = 88;
ENUM_LABEL_89 = 89;
ENUM_LABEL_90 = 90;
ENUM_LABEL_91 = 91;
ENUM_LABEL_92 = 92;
ENUM_LABEL_93 = 93;
ENUM_LABEL_94 = 94;
ENUM_LABEL_95 = 95;
ENUM_LABEL_96 = 96;
ENUM_LABEL_97 = 97;
ENUM_LABEL_98 = 98;
ENUM_LABEL_99 = 99;
ENUM_LABEL_100 = 100;
}
message TestExtensionRangeSerialize {
int32 foo_one = 1;
extensions 2;
extensions 3 to 4;
int32 foo_two = 6;
int32 foo_three = 7;
extensions 9 to 10;
int32 foo_four = 13;
extensions 15 to 15;
extensions 17 to 17;
extensions 19 to 19;
extend TestExtensionRangeSerialize {
int32 bar_one = 2;
int32 bar_two = 4;
int32 bar_three = 10;
int32 bar_four = 15;
int32 bar_five = 19;
}
}
message TestVerifyInt32Simple {
int32 optional_int32_1 = 1;
int32 optional_int32_2 = 2;
int32 optional_int32_63 = 63;
int32 optional_int32_64 = 64;
}
message TestVerifyInt32 {
int32 optional_int32_1 = 1;
int32 optional_int32_2 = 2;
int32 optional_int32_63 = 63;
int32 optional_int32_64 = 64;
TestAllTypes optional_all_types = 9;
repeated TestAllTypes repeated_all_types = 10;
}
message TestVerifyMostlyInt32 {
int64 optional_int64_30 = 30;
int32 optional_int32_1 = 1;
int32 optional_int32_2 = 2;
int32 optional_int32_3 = 3;
int32 optional_int32_4 = 4;
int32 optional_int32_63 = 63;
int32 optional_int32_64 = 64;
TestAllTypes optional_all_types = 9;
repeated TestAllTypes repeated_all_types = 10;
}
message TestVerifyMostlyInt32BigFieldNumber {
int64 optional_int64_30 = 30;
int32 optional_int32_300 = 300;
int32 optional_int32_1 = 1;
int32 optional_int32_2 = 2;
int32 optional_int32_3 = 3;
int32 optional_int32_4 = 4;
int32 optional_int32_63 = 63;
int32 optional_int32_64 = 64;
TestAllTypes optional_all_types = 9;
repeated TestAllTypes repeated_all_types = 10;
}
message TestVerifyUint32Simple {
uint32 optional_uint32_1 = 1;
uint32 optional_uint32_2 = 2;
uint32 optional_uint32_63 = 63;
uint32 optional_uint32_64 = 64;
}
message TestVerifyUint32 {
uint32 optional_uint32_1 = 1;
uint32 optional_uint32_2 = 2;
uint32 optional_uint32_63 = 63;
uint32 optional_uint32_64 = 64;
TestAllTypes optional_all_types = 9;
repeated TestAllTypes repeated_all_types = 10;
}
message TestVerifyOneUint32 {
uint32 optional_uint32_1 = 1;
int32 optional_int32_2 = 2;
int32 optional_int32_63 = 63;
int32 optional_int32_64 = 64;
TestAllTypes optional_all_types = 9;
repeated TestAllTypes repeated_all_types = 10;
}
message TestVerifyOneInt32BigFieldNumber {
int32 optional_int32_65 = 65;
int64 optional_int64_1 = 1;
int64 optional_int64_2 = 2;
int64 optional_int64_63 = 63;
int64 optional_int64_64 = 64;
TestAllTypes optional_all_types = 9;
repeated TestAllTypes repeated_all_types = 10;
}
message TestVerifyInt32BigFieldNumber {
int32 optional_int32_1000 = 1000;
int32 optional_int32_65 = 65;
int32 optional_int32_1 = 1;
int32 optional_int32_2 = 2;
int32 optional_int32_63 = 63;
int32 optional_int32_64 = 64;
TestAllTypes optional_all_types = 9;
repeated TestAllTypes repeated_all_types = 10;
}
message TestVerifyUint32BigFieldNumber {
uint32 optional_uint32_1000 = 1000;
uint32 optional_uint32_65 = 65;
uint32 optional_uint32_1 = 1;
uint32 optional_uint32_2 = 2;
uint32 optional_uint32_63 = 63;
uint32 optional_uint32_64 = 64;
TestAllTypes optional_all_types = 9;
repeated TestAllTypes repeated_all_types = 10;
}
message TestVerifyBigFieldNumberUint32 {
message Nested {
uint32 optional_uint32_5000 = 5000;
uint32 optional_uint32_1000 = 1000;
uint32 optional_uint32_66 = 66;
uint32 optional_uint32_65 = 65;
uint32 optional_uint32_1 = 1;
uint32 optional_uint32_2 = 2;
uint32 optional_uint32_63 = 63;
uint32 optional_uint32_64 = 64;
Nested optional_nested = 9;
repeated Nested repeated_nested = 10;
}
Nested optional_nested = 1;
}
// This message contains different kind of enums to exercise the different
// parsers in table-driven.
message EnumParseTester {
enum SeqSmall0 {
SEQ_SMALL_0_DEFAULT = 0;
SEQ_SMALL_0_1 = 1;
SEQ_SMALL_0_2 = 2;
}
SeqSmall0 optional_seq_small_0_lowfield = 1;
SeqSmall0 optional_seq_small_0_midfield = 1001;
SeqSmall0 optional_seq_small_0_hifield = 1000001;
repeated SeqSmall0 repeated_seq_small_0_lowfield = 2;
repeated SeqSmall0 repeated_seq_small_0_midfield = 1002;
repeated SeqSmall0 repeated_seq_small_0_hifield = 1000002;
repeated SeqSmall0 packed_seq_small_0_lowfield = 3 [
features.repeated_field_encoding = PACKED
];
repeated SeqSmall0 packed_seq_small_0_midfield = 1003 [
features.repeated_field_encoding = PACKED
];
repeated SeqSmall0 packed_seq_small_0_hifield = 1000003 [
features.repeated_field_encoding = PACKED
];
enum SeqSmall1 {
SEQ_SMALL_1_DEFAULT = 1;
SEQ_SMALL_1_2 = 2;
SEQ_SMALL_1_3 = 3;
}
SeqSmall1 optional_seq_small_1_lowfield = 4;
SeqSmall1 optional_seq_small_1_midfield = 1004;
SeqSmall1 optional_seq_small_1_hifield = 1000004;
repeated SeqSmall1 repeated_seq_small_1_lowfield = 5;
repeated SeqSmall1 repeated_seq_small_1_midfield = 1005;
repeated SeqSmall1 repeated_seq_small_1_hifield = 1000005;
repeated SeqSmall1 packed_seq_small_1_lowfield = 6 [
features.repeated_field_encoding = PACKED
];
repeated SeqSmall1 packed_seq_small_1_midfield = 1006 [
features.repeated_field_encoding = PACKED
];
repeated SeqSmall1 packed_seq_small_1_hifield = 1000006 [
features.repeated_field_encoding = PACKED
];
enum SeqLarge {
SEQ_LARGE_DEFAULT = -1;
SEQ_LARGE_0 = 0;
SEQ_LARGE_1 = 1;
SEQ_LARGE_2 = 2;
SEQ_LARGE_3 = 3;
SEQ_LARGE_4 = 4;
SEQ_LARGE_5 = 5;
SEQ_LARGE_6 = 6;
SEQ_LARGE_7 = 7;
SEQ_LARGE_8 = 8;
SEQ_LARGE_9 = 9;
SEQ_LARGE_10 = 10;
SEQ_LARGE_11 = 11;
SEQ_LARGE_12 = 12;
SEQ_LARGE_13 = 13;
SEQ_LARGE_14 = 14;
SEQ_LARGE_15 = 15;
SEQ_LARGE_16 = 16;
SEQ_LARGE_17 = 17;
SEQ_LARGE_18 = 18;
SEQ_LARGE_19 = 19;
SEQ_LARGE_20 = 20;
SEQ_LARGE_21 = 21;
SEQ_LARGE_22 = 22;
SEQ_LARGE_23 = 23;
SEQ_LARGE_24 = 24;
SEQ_LARGE_25 = 25;
SEQ_LARGE_26 = 26;
SEQ_LARGE_27 = 27;
SEQ_LARGE_28 = 28;
SEQ_LARGE_29 = 29;
SEQ_LARGE_30 = 30;
SEQ_LARGE_31 = 31;
SEQ_LARGE_32 = 32;
SEQ_LARGE_33 = 33;
}
SeqLarge optional_seq_large_lowfield = 7;
SeqLarge optional_seq_large_midfield = 1007;
SeqLarge optional_seq_large_hifield = 1000007;
repeated SeqLarge repeated_seq_large_lowfield = 8;
repeated SeqLarge repeated_seq_large_midfield = 1008;
repeated SeqLarge repeated_seq_large_hifield = 1000008;
repeated SeqLarge packed_seq_large_lowfield = 9 [
features.repeated_field_encoding = PACKED
];
repeated SeqLarge packed_seq_large_midfield = 1009 [
features.repeated_field_encoding = PACKED
];
repeated SeqLarge packed_seq_large_hifield = 1000009 [
features.repeated_field_encoding = PACKED
];
enum Arbitrary {
ARBITRARY_DEFAULT = -123123;
ARBITRARY_1 = -123;
ARBITRARY_2 = 213;
ARBITRARY_3 = 213213;
ARBITRARY_MIN = -2147483648;
ARBITRARY_MAX = 2147483647;
}
Arbitrary optional_arbitrary_lowfield = 10;
Arbitrary optional_arbitrary_midfield = 1010;
Arbitrary optional_arbitrary_hifield = 1000010;
repeated Arbitrary repeated_arbitrary_lowfield = 11;
repeated Arbitrary repeated_arbitrary_midfield = 1011;
repeated Arbitrary repeated_arbitrary_hifield = 1000011;
repeated Arbitrary packed_arbitrary_lowfield = 12 [
features.repeated_field_encoding = PACKED
];
repeated Arbitrary packed_arbitrary_midfield = 1012 [
features.repeated_field_encoding = PACKED
];
repeated Arbitrary packed_arbitrary_hifield = 1000012 [
features.repeated_field_encoding = PACKED
];
extensions 2000000 to max;
extend EnumParseTester {
Arbitrary optional_arbitrary_ext = 2000000;
repeated Arbitrary repeated_arbitrary_ext = 2000001;
repeated Arbitrary packed_arbitrary_ext = 2000002 [
features.repeated_field_encoding = PACKED
];
}
// An arbitrary field we can append to to break the runs of repeated fields.
int32 other_field = 99;
}
// This message contains different kind of bool fields to exercise the different
// parsers in table-drived.
message BoolParseTester {
bool optional_bool_lowfield = 1;
bool optional_bool_midfield = 1001;
bool optional_bool_hifield = 1000001;
repeated bool repeated_bool_lowfield = 2;
repeated bool repeated_bool_midfield = 1002;
repeated bool repeated_bool_hifield = 1000002;
repeated bool packed_bool_lowfield = 3 [
features.repeated_field_encoding = PACKED
];
repeated bool packed_bool_midfield = 1003 [
features.repeated_field_encoding = PACKED
];
repeated bool packed_bool_hifield = 1000003 [
features.repeated_field_encoding = PACKED
];
extensions 2000000 to max;
extend BoolParseTester {
bool optional_bool_ext = 2000000;
repeated bool repeated_bool_ext = 2000001;
repeated bool packed_bool_ext = 2000002 [
features.repeated_field_encoding = PACKED
];
}
// An arbitrary field we can append to to break the runs of repeated fields.
int32 other_field = 99;
}
message Int32ParseTester {
int32 optional_int32_lowfield = 1;
int32 optional_int32_midfield = 1001;
int32 optional_int32_hifield = 1000001;
repeated int32 repeated_int32_lowfield = 2;
repeated int32 repeated_int32_midfield = 1002;
repeated int32 repeated_int32_hifield = 1000002;
repeated int32 packed_int32_lowfield = 3 [
features.repeated_field_encoding = PACKED
];
repeated int32 packed_int32_midfield = 1003 [
features.repeated_field_encoding = PACKED
];
repeated int32 packed_int32_hifield = 1000003 [
features.repeated_field_encoding = PACKED
];
extensions 2000000 to max;
extend Int32ParseTester {
int32 optional_int32_ext = 2000000;
repeated int32 repeated_int32_ext = 2000001;
repeated int32 packed_int32_ext = 2000002 [
features.repeated_field_encoding = PACKED
];
}
// An arbitrary field we can append to to break the runs of repeated fields.
int32 other_field = 99;
}
message Int64ParseTester {
int64 optional_int64_lowfield = 1;
int64 optional_int64_midfield = 1001;
int64 optional_int64_hifield = 1000001;
repeated int64 repeated_int64_lowfield = 2;
repeated int64 repeated_int64_midfield = 1002;
repeated int64 repeated_int64_hifield = 1000002;
repeated int64 packed_int64_lowfield = 3 [
features.repeated_field_encoding = PACKED
];
repeated int64 packed_int64_midfield = 1003 [
features.repeated_field_encoding = PACKED
];
repeated int64 packed_int64_hifield = 1000003 [
features.repeated_field_encoding = PACKED
];
extensions 2000000 to max;
extend Int64ParseTester {
int64 optional_int64_ext = 2000000;
repeated int64 repeated_int64_ext = 2000001;
repeated int64 packed_int64_ext = 2000002 [
features.repeated_field_encoding = PACKED
];
}
// An arbitrary field we can append to to break the runs of repeated fields.
int32 other_field = 99;
}
message InlinedStringIdxRegressionProto {
// We mix data to make sure aux ids and inlined string idx do not match.
// aux_idx == inlined_string_idx == 1
string str1 = 1;
// aux_idx == 2
InlinedStringIdxRegressionProto sub = 2;
// aux_idx == 3, inlined_string_idx == 2
string str2 = 3;
// aux_idx == 4, inlined_string_idx == 3
bytes str3 = 4;
}
message StringParseTester {
string optional_string_lowfield = 1;
string optional_string_midfield = 1001;
string optional_string_hifield = 1000001;
repeated string repeated_string_lowfield = 2;
repeated string repeated_string_midfield = 1002;
repeated string repeated_string_hifield = 1000002;
extensions 2000000 to max;
extend StringParseTester {
string optional_string_ext = 2000000;
repeated string repeated_string_ext = 2000001;
}
}
message BadFieldNames {
int32 OptionalInt32 = 1;
int32 for = 2;
}
message TestNestedMessageRedaction {
string optional_unredacted_nested_string = 1;
string optional_redacted_nested_string = 2 [
debug_redact = true
];
}
message RedactedFields {
string optional_redacted_string = 1 [
debug_redact = true
];
string optional_unredacted_string = 2;
repeated string repeated_redacted_string = 3 [
debug_redact = true
];
repeated string repeated_unredacted_string = 4;
TestNestedMessageRedaction optional_redacted_message = 5 [
debug_redact = true
];
TestNestedMessageRedaction optional_unredacted_message = 6;
repeated TestNestedMessageRedaction repeated_redacted_message = 7 [
debug_redact = true
];
repeated TestNestedMessageRedaction repeated_unredacted_message = 8;
map<string, string> map_redacted_string = 9 [
debug_redact = true
];
map<string, string> map_unredacted_string = 10;
string optional_redacted_false_string = 11 [
debug_redact = false
];
extensions 20 to 30;
}
extend RedactedFields {
string redacted_extension = 20 [
debug_redact = true
];
}
message TestString {
string optional_string = 1;
}
message TestCord {
bytes optional_bytes_cord = 1 [
ctype = CORD
];
bytes optional_bytes_cord_default = 2 [
ctype = CORD,
default = "hello"
];
}
message TestPackedEnumSmallRange {
enum NestedEnum {
UNSPECIFIED = 0;
FOO = 1;
BAR = 2;
BAZ = 3;
}
repeated NestedEnum vals = 1 [
features.repeated_field_encoding = PACKED
];
}
message EnumsForBenchmark {
enum Flat {
A0 = 0;
A1 = 1;
A2 = 2;
A3 = 3;
A4 = 4;
A5 = 5;
A6 = 6;
A7 = 7;
A8 = 8;
A9 = 9;
A10 = 10;
A11 = 11;
A12 = 12;
A13 = 13;
A14 = 14;
A15 = 15;
}
// Has a few holes, bitmap can be used.
enum AlmostFlat {
B0 = 0;
B1 = 1;
B2 = 2;
B3 = 3;
B5 = 5;
B6 = 6;
B7 = 7;
B8 = 8;
B9 = 9;
B11 = 11;
B12 = 12;
B13 = 13;
B14 = 14;
B15 = 15;
B17 = 17;
B19 = 19;
}
enum Sparse {
C536 = 536;
C8387 = 8387;
C9673 = 9673;
C10285 = 10285;
C13318 = 13318;
C15963 = 15963;
C16439 = 16439;
C18197 = 18197;
C19430 = 19430;
C20361 = 20361;
C20706 = 20706;
C21050 = 21050;
C21906 = 21906;
C27265 = 27265;
C30109 = 30109;
C31670 = 31670;
}
}
message TestMessageWithManyRepeatedPtrFields {
repeated string repeated_string_1 = 1;
repeated string repeated_string_2 = 2;
repeated string repeated_string_3 = 3;
repeated string repeated_string_4 = 4;
repeated string repeated_string_5 = 5;
repeated string repeated_string_6 = 6;
repeated string repeated_string_7 = 7;
repeated string repeated_string_8 = 8;
repeated string repeated_string_9 = 9;
repeated string repeated_string_10 = 10;
repeated string repeated_string_11 = 11;
repeated string repeated_string_12 = 12;
repeated string repeated_string_13 = 13;
repeated string repeated_string_14 = 14;
repeated string repeated_string_15 = 15;
repeated string repeated_string_16 = 16;
repeated string repeated_string_17 = 17;
repeated string repeated_string_18 = 18;
repeated string repeated_string_19 = 19;
repeated string repeated_string_20 = 20;
repeated string repeated_string_21 = 21;
repeated string repeated_string_22 = 22;
repeated string repeated_string_23 = 23;
repeated string repeated_string_24 = 24;
repeated string repeated_string_25 = 25;
repeated string repeated_string_26 = 26;
repeated string repeated_string_27 = 27;
repeated string repeated_string_28 = 28;
repeated string repeated_string_29 = 29;
repeated string repeated_string_30 = 30;
repeated string repeated_string_31 = 31;
repeated string repeated_string_32 = 32;
}
message MessageCreatorZeroInit {
int32 i = 1;
double d = 2;
MessageCreatorZeroInit m = 3;
oneof one {
string os = 10;
string oc = 11 [
ctype = CORD
];
fixed64 of = 12;
MessageCreatorZeroInit ol = 13 [
lazy = true
];
}
}
message MessageCreatorMemcpy {
string s = 1;
repeated int32 i = 2 [
features.repeated_field_encoding = PACKED
];
MessageCreatorMemcpy m = 3 [
lazy = true
];
map<int32, int32> m2 = 4;
}
message MessageCreatorFunc {
// This one is ArenaDtorNeeds::kRequired so we must run the constructor.
string c = 3 [
ctype = CORD
];
}