// Protocol Buffers - Google's data interchange format // Copyright 2008 Google Inc. All rights reserved. // https://developers.google.com/protocol-buffers/ // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following disclaimer // in the documentation and/or other materials provided with the // distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // Author: kenton@google.com (Kenton Varda) // Based on original Protocol Buffers design by // Sanjay Ghemawat, Jeff Dean, and others. #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // clang-format off #include // clang-format on namespace google { namespace protobuf { namespace internal { namespace { TEST(WireFormatTest, EnumsInSync) { // Verify that WireFormatLite::FieldType and WireFormatLite::CppType match // FieldDescriptor::Type and FieldDescriptor::CppType. EXPECT_EQ(implicit_cast(FieldDescriptor::MAX_TYPE), implicit_cast(WireFormatLite::MAX_FIELD_TYPE)); EXPECT_EQ(implicit_cast(FieldDescriptor::MAX_CPPTYPE), implicit_cast(WireFormatLite::MAX_CPPTYPE)); for (int i = 1; i <= WireFormatLite::MAX_FIELD_TYPE; i++) { EXPECT_EQ(implicit_cast(FieldDescriptor::TypeToCppType( static_cast(i))), implicit_cast(WireFormatLite::FieldTypeToCppType( static_cast(i)))); } } TEST(WireFormatTest, MaxFieldNumber) { // Make sure the max field number constant is accurate. EXPECT_EQ((1 << (32 - WireFormatLite::kTagTypeBits)) - 1, FieldDescriptor::kMaxNumber); } TEST(WireFormatTest, Parse) { UNITTEST::TestAllTypes source, dest; std::string data; // Serialize using the generated code. TestUtil::SetAllFields(&source); source.SerializeToString(&data); // Parse using WireFormat. io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); WireFormat::ParseAndMergePartial(&input, &dest); // Check. TestUtil::ExpectAllFieldsSet(dest); } TEST(WireFormatTest, ParseExtensions) { UNITTEST::TestAllExtensions source, dest; std::string data; // Serialize using the generated code. TestUtil::SetAllExtensions(&source); source.SerializeToString(&data); // Parse using WireFormat. io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); WireFormat::ParseAndMergePartial(&input, &dest); // Check. TestUtil::ExpectAllExtensionsSet(dest); } TEST(WireFormatTest, ParsePacked) { UNITTEST::TestPackedTypes source, dest; std::string data; // Serialize using the generated code. TestUtil::SetPackedFields(&source); source.SerializeToString(&data); // Parse using WireFormat. io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); WireFormat::ParseAndMergePartial(&input, &dest); // Check. TestUtil::ExpectPackedFieldsSet(dest); } TEST(WireFormatTest, ParsePackedFromUnpacked) { // Serialize using the generated code. UNITTEST::TestUnpackedTypes source; TestUtil::SetUnpackedFields(&source); std::string data = source.SerializeAsString(); // Parse using WireFormat. UNITTEST::TestPackedTypes dest; io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); WireFormat::ParseAndMergePartial(&input, &dest); // Check. TestUtil::ExpectPackedFieldsSet(dest); } TEST(WireFormatTest, ParseUnpackedFromPacked) { // Serialize using the generated code. UNITTEST::TestPackedTypes source; TestUtil::SetPackedFields(&source); std::string data = source.SerializeAsString(); // Parse using WireFormat. UNITTEST::TestUnpackedTypes dest; io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); WireFormat::ParseAndMergePartial(&input, &dest); // Check. TestUtil::ExpectUnpackedFieldsSet(dest); } TEST(WireFormatTest, ParsePackedExtensions) { UNITTEST::TestPackedExtensions source, dest; std::string data; // Serialize using the generated code. TestUtil::SetPackedExtensions(&source); source.SerializeToString(&data); // Parse using WireFormat. io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); WireFormat::ParseAndMergePartial(&input, &dest); // Check. TestUtil::ExpectPackedExtensionsSet(dest); } TEST(WireFormatTest, ParseOneof) { UNITTEST::TestOneof2 source, dest; std::string data; // Serialize using the generated code. TestUtil::SetOneof1(&source); source.SerializeToString(&data); // Parse using WireFormat. io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); WireFormat::ParseAndMergePartial(&input, &dest); // Check. TestUtil::ExpectOneofSet1(dest); } TEST(WireFormatTest, OneofOnlySetLast) { UNITTEST::TestOneofBackwardsCompatible source; UNITTEST::TestOneof oneof_dest; std::string data; // Set two fields source.set_foo_int(100); source.set_foo_string("101"); // Serialize and parse to oneof message. Generated serializer may not order // fields in tag order. Use WireFormat::SerializeWithCachedSizes instead as // it sorts fields beforehand. { io::StringOutputStream raw_output(&data); io::CodedOutputStream output(&raw_output); WireFormat::SerializeWithCachedSizes(source, source.ByteSizeLong(), &output); ASSERT_FALSE(output.HadError()); } io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); WireFormat::ParseAndMergePartial(&input, &oneof_dest); // Only the last field is set. EXPECT_FALSE(oneof_dest.has_foo_int()); EXPECT_TRUE(oneof_dest.has_foo_string()); } TEST(WireFormatTest, ByteSize) { UNITTEST::TestAllTypes message; TestUtil::SetAllFields(&message); EXPECT_EQ(message.ByteSizeLong(), WireFormat::ByteSize(message)); message.Clear(); EXPECT_EQ(0, message.ByteSizeLong()); EXPECT_EQ(0, WireFormat::ByteSize(message)); } TEST(WireFormatTest, ByteSizeExtensions) { UNITTEST::TestAllExtensions message; TestUtil::SetAllExtensions(&message); EXPECT_EQ(message.ByteSizeLong(), WireFormat::ByteSize(message)); message.Clear(); EXPECT_EQ(0, message.ByteSizeLong()); EXPECT_EQ(0, WireFormat::ByteSize(message)); } TEST(WireFormatTest, ByteSizePacked) { UNITTEST::TestPackedTypes message; TestUtil::SetPackedFields(&message); EXPECT_EQ(message.ByteSizeLong(), WireFormat::ByteSize(message)); message.Clear(); EXPECT_EQ(0, message.ByteSizeLong()); EXPECT_EQ(0, WireFormat::ByteSize(message)); } TEST(WireFormatTest, ByteSizePackedExtensions) { UNITTEST::TestPackedExtensions message; TestUtil::SetPackedExtensions(&message); EXPECT_EQ(message.ByteSizeLong(), WireFormat::ByteSize(message)); message.Clear(); EXPECT_EQ(0, message.ByteSizeLong()); EXPECT_EQ(0, WireFormat::ByteSize(message)); } TEST(WireFormatTest, ByteSizeOneof) { UNITTEST::TestOneof2 message; TestUtil::SetOneof1(&message); EXPECT_EQ(message.ByteSizeLong(), WireFormat::ByteSize(message)); message.Clear(); EXPECT_EQ(0, message.ByteSizeLong()); EXPECT_EQ(0, WireFormat::ByteSize(message)); } TEST(WireFormatTest, Serialize) { UNITTEST::TestAllTypes message; std::string generated_data; std::string dynamic_data; TestUtil::SetAllFields(&message); size_t size = message.ByteSizeLong(); // Serialize using the generated code. { io::StringOutputStream raw_output(&generated_data); io::CodedOutputStream output(&raw_output); message.SerializeWithCachedSizes(&output); ASSERT_FALSE(output.HadError()); } // Serialize using WireFormat. { io::StringOutputStream raw_output(&dynamic_data); io::CodedOutputStream output(&raw_output); WireFormat::SerializeWithCachedSizes(message, size, &output); ASSERT_FALSE(output.HadError()); } // Should parse to the same message. EXPECT_TRUE(TestUtil::EqualsToSerialized(message, generated_data)); EXPECT_TRUE(TestUtil::EqualsToSerialized(message, dynamic_data)); } TEST(WireFormatTest, SerializeExtensions) { UNITTEST::TestAllExtensions message; std::string generated_data; std::string dynamic_data; TestUtil::SetAllExtensions(&message); size_t size = message.ByteSizeLong(); // Serialize using the generated code. { io::StringOutputStream raw_output(&generated_data); io::CodedOutputStream output(&raw_output); message.SerializeWithCachedSizes(&output); ASSERT_FALSE(output.HadError()); } // Serialize using WireFormat. { io::StringOutputStream raw_output(&dynamic_data); io::CodedOutputStream output(&raw_output); WireFormat::SerializeWithCachedSizes(message, size, &output); ASSERT_FALSE(output.HadError()); } // Should parse to the same message. EXPECT_TRUE(TestUtil::EqualsToSerialized(message, generated_data)); EXPECT_TRUE(TestUtil::EqualsToSerialized(message, dynamic_data)); } TEST(WireFormatTest, SerializeFieldsAndExtensions) { UNITTEST::TestFieldOrderings message; std::string generated_data; std::string dynamic_data; TestUtil::SetAllFieldsAndExtensions(&message); size_t size = message.ByteSizeLong(); // Serialize using the generated code. { io::StringOutputStream raw_output(&generated_data); io::CodedOutputStream output(&raw_output); message.SerializeWithCachedSizes(&output); ASSERT_FALSE(output.HadError()); } // Serialize using WireFormat. { io::StringOutputStream raw_output(&dynamic_data); io::CodedOutputStream output(&raw_output); WireFormat::SerializeWithCachedSizes(message, size, &output); ASSERT_FALSE(output.HadError()); } // Should parse to the same message. EXPECT_TRUE(TestUtil::EqualsToSerialized(message, generated_data)); EXPECT_TRUE(TestUtil::EqualsToSerialized(message, dynamic_data)); } TEST(WireFormatTest, SerializeOneof) { UNITTEST::TestOneof2 message; std::string generated_data; std::string dynamic_data; TestUtil::SetOneof1(&message); size_t size = message.ByteSizeLong(); // Serialize using the generated code. { io::StringOutputStream raw_output(&generated_data); io::CodedOutputStream output(&raw_output); message.SerializeWithCachedSizes(&output); ASSERT_FALSE(output.HadError()); } // Serialize using WireFormat. { io::StringOutputStream raw_output(&dynamic_data); io::CodedOutputStream output(&raw_output); WireFormat::SerializeWithCachedSizes(message, size, &output); ASSERT_FALSE(output.HadError()); } // Should parse to the same message. EXPECT_TRUE(TestUtil::EqualsToSerialized(message, generated_data)); EXPECT_TRUE(TestUtil::EqualsToSerialized(message, dynamic_data)); } TEST(WireFormatTest, ParseMultipleExtensionRanges) { // Make sure we can parse a message that contains multiple extensions ranges. UNITTEST::TestFieldOrderings source; std::string data; TestUtil::SetAllFieldsAndExtensions(&source); source.SerializeToString(&data); { UNITTEST::TestFieldOrderings dest; EXPECT_TRUE(dest.ParseFromString(data)); EXPECT_EQ(source.DebugString(), dest.DebugString()); } // Also test using reflection-based parsing. { UNITTEST::TestFieldOrderings dest; io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream coded_input(&raw_input); EXPECT_TRUE(WireFormat::ParseAndMergePartial(&coded_input, &dest)); EXPECT_EQ(source.DebugString(), dest.DebugString()); } } const int kUnknownTypeId = 1550055; TEST(WireFormatTest, SerializeMessageSet) { // Set up a TestMessageSet with two known messages and an unknown one. PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; message_set .MutableExtension( UNITTEST::TestMessageSetExtension1::message_set_extension) ->set_i(123); message_set .MutableExtension( UNITTEST::TestMessageSetExtension2::message_set_extension) ->set_str("foo"); message_set.mutable_unknown_fields()->AddLengthDelimited(kUnknownTypeId, "bar"); std::string data; ASSERT_TRUE(message_set.SerializeToString(&data)); // Parse back using RawMessageSet and check the contents. UNITTEST::RawMessageSet raw; ASSERT_TRUE(raw.ParseFromString(data)); EXPECT_EQ(0, raw.unknown_fields().field_count()); ASSERT_EQ(3, raw.item_size()); EXPECT_EQ( UNITTEST::TestMessageSetExtension1::descriptor()->extension(0)->number(), raw.item(0).type_id()); EXPECT_EQ( UNITTEST::TestMessageSetExtension2::descriptor()->extension(0)->number(), raw.item(1).type_id()); EXPECT_EQ(kUnknownTypeId, raw.item(2).type_id()); UNITTEST::TestMessageSetExtension1 message1; EXPECT_TRUE(message1.ParseFromString(raw.item(0).message())); EXPECT_EQ(123, message1.i()); UNITTEST::TestMessageSetExtension2 message2; EXPECT_TRUE(message2.ParseFromString(raw.item(1).message())); EXPECT_EQ("foo", message2.str()); EXPECT_EQ("bar", raw.item(2).message()); } TEST(WireFormatTest, SerializeMessageSetVariousWaysAreEqual) { // Serialize a MessageSet to a stream and to a flat array using generated // code, and also using WireFormat, and check that the results are equal. // Set up a TestMessageSet with two known messages and an unknown one, as // above. PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; message_set .MutableExtension( UNITTEST::TestMessageSetExtension1::message_set_extension) ->set_i(123); message_set .MutableExtension( UNITTEST::TestMessageSetExtension2::message_set_extension) ->set_str("foo"); message_set.mutable_unknown_fields()->AddLengthDelimited(kUnknownTypeId, "bar"); size_t size = message_set.ByteSizeLong(); EXPECT_EQ(size, message_set.GetCachedSize()); ASSERT_EQ(size, WireFormat::ByteSize(message_set)); std::string flat_data; std::string stream_data; std::string dynamic_data; flat_data.resize(size); stream_data.resize(size); // Serialize to flat array { uint8_t* target = reinterpret_cast(::google::protobuf::string_as_array(&flat_data)); uint8_t* end = message_set.SerializeWithCachedSizesToArray(target); EXPECT_EQ(size, end - target); } // Serialize to buffer { io::ArrayOutputStream array_stream(::google::protobuf::string_as_array(&stream_data), size, 1); io::CodedOutputStream output_stream(&array_stream); message_set.SerializeWithCachedSizes(&output_stream); ASSERT_FALSE(output_stream.HadError()); } // Serialize to buffer with WireFormat. { io::StringOutputStream string_stream(&dynamic_data); io::CodedOutputStream output_stream(&string_stream); WireFormat::SerializeWithCachedSizes(message_set, size, &output_stream); ASSERT_FALSE(output_stream.HadError()); } EXPECT_TRUE(flat_data == stream_data); EXPECT_TRUE(flat_data == dynamic_data); } TEST(WireFormatTest, ParseMessageSet) { // Set up a RawMessageSet with two known messages and an unknown one. UNITTEST::RawMessageSet raw; { UNITTEST::RawMessageSet::Item* item = raw.add_item(); item->set_type_id(UNITTEST::TestMessageSetExtension1::descriptor() ->extension(0) ->number()); UNITTEST::TestMessageSetExtension1 message; message.set_i(123); message.SerializeToString(item->mutable_message()); } { UNITTEST::RawMessageSet::Item* item = raw.add_item(); item->set_type_id(UNITTEST::TestMessageSetExtension2::descriptor() ->extension(0) ->number()); UNITTEST::TestMessageSetExtension2 message; message.set_str("foo"); message.SerializeToString(item->mutable_message()); } { UNITTEST::RawMessageSet::Item* item = raw.add_item(); item->set_type_id(kUnknownTypeId); item->set_message("bar"); } std::string data; ASSERT_TRUE(raw.SerializeToString(&data)); // Parse as a TestMessageSet and check the contents. PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; ASSERT_TRUE(message_set.ParseFromString(data)); EXPECT_EQ(123, message_set .GetExtension( UNITTEST::TestMessageSetExtension1::message_set_extension) .i()); EXPECT_EQ("foo", message_set .GetExtension( UNITTEST::TestMessageSetExtension2::message_set_extension) .str()); ASSERT_EQ(1, message_set.unknown_fields().field_count()); ASSERT_EQ(UnknownField::TYPE_LENGTH_DELIMITED, message_set.unknown_fields().field(0).type()); EXPECT_EQ("bar", message_set.unknown_fields().field(0).length_delimited()); // Also parse using WireFormat. PROTO2_WIREFORMAT_UNITTEST::TestMessageSet dynamic_message_set; io::CodedInputStream input(reinterpret_cast(data.data()), data.size()); ASSERT_TRUE(WireFormat::ParseAndMergePartial(&input, &dynamic_message_set)); EXPECT_EQ(message_set.DebugString(), dynamic_message_set.DebugString()); } namespace { std::string BuildMessageSetItemStart() { std::string data; { io::StringOutputStream output_stream(&data); io::CodedOutputStream coded_output(&output_stream); coded_output.WriteTag(WireFormatLite::kMessageSetItemStartTag); } return data; } std::string BuildMessageSetItemEnd() { std::string data; { io::StringOutputStream output_stream(&data); io::CodedOutputStream coded_output(&output_stream); coded_output.WriteTag(WireFormatLite::kMessageSetItemEndTag); } return data; } std::string BuildMessageSetTestExtension1(int value = 123) { std::string data; { UNITTEST::TestMessageSetExtension1 message; message.set_i(value); io::StringOutputStream output_stream(&data); io::CodedOutputStream coded_output(&output_stream); // Write the message content first. WireFormatLite::WriteTag(WireFormatLite::kMessageSetMessageNumber, WireFormatLite::WIRETYPE_LENGTH_DELIMITED, &coded_output); coded_output.WriteVarint32(message.ByteSizeLong()); message.SerializeWithCachedSizes(&coded_output); } return data; } std::string BuildMessageSetItemTypeId(int extension_number) { std::string data; { io::StringOutputStream output_stream(&data); io::CodedOutputStream coded_output(&output_stream); WireFormatLite::WriteUInt32(WireFormatLite::kMessageSetTypeIdNumber, extension_number, &coded_output); } return data; } void ValidateTestMessageSet(const std::string& test_case, const std::string& data) { SCOPED_TRACE(test_case); { PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; ASSERT_TRUE(message_set.ParseFromString(data)); EXPECT_EQ(123, message_set .GetExtension( UNITTEST::TestMessageSetExtension1::message_set_extension) .i()); // Make sure it does not contain anything else. message_set.ClearExtension( UNITTEST::TestMessageSetExtension1::message_set_extension); EXPECT_EQ(message_set.SerializeAsString(), ""); } { // Test parse the message via Reflection. PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; io::CodedInputStream input(reinterpret_cast(data.data()), data.size()); EXPECT_TRUE(WireFormat::ParseAndMergePartial(&input, &message_set)); EXPECT_TRUE(input.ConsumedEntireMessage()); EXPECT_EQ(123, message_set .GetExtension( UNITTEST::TestMessageSetExtension1::message_set_extension) .i()); } { // Test parse the message via DynamicMessage. DynamicMessageFactory factory; std::unique_ptr msg( factory .GetPrototype( PROTO2_WIREFORMAT_UNITTEST::TestMessageSet::descriptor()) ->New()); msg->ParseFromString(data); auto* reflection = msg->GetReflection(); std::vector fields; reflection->ListFields(*msg, &fields); ASSERT_EQ(fields.size(), 1); const auto& sub = reflection->GetMessage(*msg, fields[0]); reflection = sub.GetReflection(); EXPECT_EQ(123, reflection->GetInt32( sub, sub.GetDescriptor()->FindFieldByName("i"))); } } } // namespace TEST(WireFormatTest, ParseMessageSetWithAnyTagOrder) { std::string start = BuildMessageSetItemStart(); std::string end = BuildMessageSetItemEnd(); std::string id = BuildMessageSetItemTypeId( UNITTEST::TestMessageSetExtension1::descriptor()->extension(0)->number()); std::string message = BuildMessageSetTestExtension1(); ValidateTestMessageSet("id + message", start + id + message + end); ValidateTestMessageSet("message + id", start + message + id + end); } TEST(WireFormatTest, ParseMessageSetWithDuplicateTags) { std::string start = BuildMessageSetItemStart(); std::string end = BuildMessageSetItemEnd(); std::string id = BuildMessageSetItemTypeId( UNITTEST::TestMessageSetExtension1::descriptor()->extension(0)->number()); std::string other_id = BuildMessageSetItemTypeId(123456); std::string message = BuildMessageSetTestExtension1(); std::string other_message = BuildMessageSetTestExtension1(321); // Double id ValidateTestMessageSet("id + other_id + message", start + id + other_id + message + end); ValidateTestMessageSet("id + message + other_id", start + id + message + other_id + end); ValidateTestMessageSet("message + id + other_id", start + message + id + other_id + end); // Double message ValidateTestMessageSet("id + message + other_message", start + id + message + other_message + end); ValidateTestMessageSet("message + id + other_message", start + message + id + other_message + end); ValidateTestMessageSet("message + other_message + id", start + message + other_message + id + end); } void SerializeReverseOrder( const PROTO2_WIREFORMAT_UNITTEST::TestMessageSet& mset, io::CodedOutputStream* coded_output); void SerializeReverseOrder(const UNITTEST::TestMessageSetExtension1& message, io::CodedOutputStream* coded_output) { WireFormatLite::WriteTag(15, // i WireFormatLite::WIRETYPE_VARINT, coded_output); coded_output->WriteVarint64(message.i()); WireFormatLite::WriteTag(16, // recursive WireFormatLite::WIRETYPE_LENGTH_DELIMITED, coded_output); coded_output->WriteVarint32(message.recursive().GetCachedSize()); SerializeReverseOrder(message.recursive(), coded_output); } void SerializeReverseOrder( const PROTO2_WIREFORMAT_UNITTEST::TestMessageSet& mset, io::CodedOutputStream* coded_output) { if (!mset.HasExtension( UNITTEST::TestMessageSetExtension1::message_set_extension)) return; coded_output->WriteTag(WireFormatLite::kMessageSetItemStartTag); // Write the message content first. WireFormatLite::WriteTag(WireFormatLite::kMessageSetMessageNumber, WireFormatLite::WIRETYPE_LENGTH_DELIMITED, coded_output); auto& message = mset.GetExtension( UNITTEST::TestMessageSetExtension1::message_set_extension); coded_output->WriteVarint32(message.GetCachedSize()); SerializeReverseOrder(message, coded_output); // Write the type id. uint32_t type_id = message.GetDescriptor()->extension(0)->number(); WireFormatLite::WriteUInt32(WireFormatLite::kMessageSetTypeIdNumber, type_id, coded_output); coded_output->WriteTag(WireFormatLite::kMessageSetItemEndTag); } TEST(WireFormatTest, ParseMessageSetWithDeepRecReverseOrder) { std::string data; { PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; PROTO2_WIREFORMAT_UNITTEST::TestMessageSet* mset = &message_set; for (int i = 0; i < 200; i++) { auto m = mset->MutableExtension( UNITTEST::TestMessageSetExtension1::message_set_extension); m->set_i(i); mset = m->mutable_recursive(); } message_set.ByteSizeLong(); // Serialize with reverse payload tag order io::StringOutputStream output_stream(&data); io::CodedOutputStream coded_output(&output_stream); SerializeReverseOrder(message_set, &coded_output); } PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; EXPECT_FALSE(message_set.ParseFromString(data)); } TEST(WireFormatTest, ParseFailMalformedMessageSet) { constexpr int kDepth = 5; std::string data; { PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; PROTO2_WIREFORMAT_UNITTEST::TestMessageSet* mset = &message_set; for (int i = 0; i < kDepth; i++) { auto m = mset->MutableExtension( UNITTEST::TestMessageSetExtension1::message_set_extension); m->set_i(i); mset = m->mutable_recursive(); } auto m = mset->MutableExtension( UNITTEST::TestMessageSetExtension1::message_set_extension); // -1 becomes \xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\x1 m->set_i(-1); EXPECT_TRUE(message_set.SerializeToString(&data)); // Make the proto mal-formed. data[data.size() - 2 - kDepth] = 0xFF; } PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; EXPECT_FALSE(message_set.ParseFromString(data)); } TEST(WireFormatTest, ParseFailMalformedMessageSetReverseOrder) { constexpr int kDepth = 5; std::string data; { PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; PROTO2_WIREFORMAT_UNITTEST::TestMessageSet* mset = &message_set; for (int i = 0; i < kDepth; i++) { auto m = mset->MutableExtension( UNITTEST::TestMessageSetExtension1::message_set_extension); m->set_i(i); mset = m->mutable_recursive(); } auto m = mset->MutableExtension( UNITTEST::TestMessageSetExtension1::message_set_extension); // -1 becomes \xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\x1 m->set_i(-1); // SerializeReverseOrder() assumes "recursive" is always present. m->mutable_recursive(); message_set.ByteSizeLong(); // Serialize with reverse payload tag order io::StringOutputStream output_stream(&data); io::CodedOutputStream coded_output(&output_stream); SerializeReverseOrder(message_set, &coded_output); } // Make varint for -1 malformed. data[data.size() - 5 * (kDepth + 1) - 4] = 0xFF; PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; EXPECT_FALSE(message_set.ParseFromString(data)); } TEST(WireFormatTest, ParseBrokenMessageSet) { PROTO2_WIREFORMAT_UNITTEST::TestMessageSet message_set; std::string input("goodbye"); // Invalid wire format data. EXPECT_FALSE(message_set.ParseFromString(input)); } TEST(WireFormatTest, RecursionLimit) { UNITTEST::TestRecursiveMessage message; message.mutable_a()->mutable_a()->mutable_a()->mutable_a()->set_i(1); std::string data; message.SerializeToString(&data); { io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); input.SetRecursionLimit(4); UNITTEST::TestRecursiveMessage message2; EXPECT_TRUE(message2.ParseFromCodedStream(&input)); } { io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); input.SetRecursionLimit(3); UNITTEST::TestRecursiveMessage message2; EXPECT_FALSE(message2.ParseFromCodedStream(&input)); } } TEST(WireFormatTest, LargeRecursionLimit) { const int kLargeLimit = io::CodedInputStream::GetDefaultRecursionLimit() + 50; UNITTEST::TestRecursiveMessage src, dst, *a; a = src.mutable_a(); for (int i = 0; i < kLargeLimit - 1; i++) { a = a->mutable_a(); } a->set_i(1); std::string data = src.SerializeAsString(); { // Parse with default recursion limit. Should fail. io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); ASSERT_FALSE(dst.ParseFromCodedStream(&input)); } { // Parse with custom recursion limit. Should pass. io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); input.SetRecursionLimit(kLargeLimit); ASSERT_TRUE(dst.ParseFromCodedStream(&input)); } // Verifies the recursion depth. int depth = 1; a = dst.mutable_a(); while (a->has_a()) { a = a->mutable_a(); depth++; } EXPECT_EQ(a->i(), 1); EXPECT_EQ(depth, kLargeLimit); } TEST(WireFormatTest, UnknownFieldRecursionLimit) { UNITTEST::TestEmptyMessage message; message.mutable_unknown_fields() ->AddGroup(1234) ->AddGroup(1234) ->AddGroup(1234) ->AddGroup(1234) ->AddVarint(1234, 123); std::string data; message.SerializeToString(&data); { io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); input.SetRecursionLimit(4); UNITTEST::TestEmptyMessage message2; EXPECT_TRUE(message2.ParseFromCodedStream(&input)); } { io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream input(&raw_input); input.SetRecursionLimit(3); UNITTEST::TestEmptyMessage message2; EXPECT_FALSE(message2.ParseFromCodedStream(&input)); } } TEST(WireFormatTest, ZigZag) { // avoid line-wrapping #define LL(x) static_cast(ULL(x)) #define ULL(x) uint64_t{x##u} #define ZigZagEncode32(x) WireFormatLite::ZigZagEncode32(x) #define ZigZagDecode32(x) WireFormatLite::ZigZagDecode32(x) #define ZigZagEncode64(x) WireFormatLite::ZigZagEncode64(x) #define ZigZagDecode64(x) WireFormatLite::ZigZagDecode64(x) EXPECT_EQ(0u, ZigZagEncode32(0)); EXPECT_EQ(1u, ZigZagEncode32(-1)); EXPECT_EQ(2u, ZigZagEncode32(1)); EXPECT_EQ(3u, ZigZagEncode32(-2)); EXPECT_EQ(0x7FFFFFFEu, ZigZagEncode32(0x3FFFFFFF)); EXPECT_EQ(0x7FFFFFFFu, ZigZagEncode32(0xC0000000)); EXPECT_EQ(0xFFFFFFFEu, ZigZagEncode32(0x7FFFFFFF)); EXPECT_EQ(0xFFFFFFFFu, ZigZagEncode32(0x80000000)); EXPECT_EQ(0, ZigZagDecode32(0u)); EXPECT_EQ(-1, ZigZagDecode32(1u)); EXPECT_EQ(1, ZigZagDecode32(2u)); EXPECT_EQ(-2, ZigZagDecode32(3u)); EXPECT_EQ(0x3FFFFFFF, ZigZagDecode32(0x7FFFFFFEu)); EXPECT_EQ(0xC0000000, ZigZagDecode32(0x7FFFFFFFu)); EXPECT_EQ(0x7FFFFFFF, ZigZagDecode32(0xFFFFFFFEu)); EXPECT_EQ(0x80000000, ZigZagDecode32(0xFFFFFFFFu)); EXPECT_EQ(0u, ZigZagEncode64(0)); EXPECT_EQ(1u, ZigZagEncode64(-1)); EXPECT_EQ(2u, ZigZagEncode64(1)); EXPECT_EQ(3u, ZigZagEncode64(-2)); EXPECT_EQ(ULL(0x000000007FFFFFFE), ZigZagEncode64(LL(0x000000003FFFFFFF))); EXPECT_EQ(ULL(0x000000007FFFFFFF), ZigZagEncode64(LL(0xFFFFFFFFC0000000))); EXPECT_EQ(ULL(0x00000000FFFFFFFE), ZigZagEncode64(LL(0x000000007FFFFFFF))); EXPECT_EQ(ULL(0x00000000FFFFFFFF), ZigZagEncode64(LL(0xFFFFFFFF80000000))); EXPECT_EQ(ULL(0xFFFFFFFFFFFFFFFE), ZigZagEncode64(LL(0x7FFFFFFFFFFFFFFF))); EXPECT_EQ(ULL(0xFFFFFFFFFFFFFFFF), ZigZagEncode64(LL(0x8000000000000000))); EXPECT_EQ(0, ZigZagDecode64(0u)); EXPECT_EQ(-1, ZigZagDecode64(1u)); EXPECT_EQ(1, ZigZagDecode64(2u)); EXPECT_EQ(-2, ZigZagDecode64(3u)); EXPECT_EQ(LL(0x000000003FFFFFFF), ZigZagDecode64(ULL(0x000000007FFFFFFE))); EXPECT_EQ(LL(0xFFFFFFFFC0000000), ZigZagDecode64(ULL(0x000000007FFFFFFF))); EXPECT_EQ(LL(0x000000007FFFFFFF), ZigZagDecode64(ULL(0x00000000FFFFFFFE))); EXPECT_EQ(LL(0xFFFFFFFF80000000), ZigZagDecode64(ULL(0x00000000FFFFFFFF))); EXPECT_EQ(LL(0x7FFFFFFFFFFFFFFF), ZigZagDecode64(ULL(0xFFFFFFFFFFFFFFFE))); EXPECT_EQ(LL(0x8000000000000000), ZigZagDecode64(ULL(0xFFFFFFFFFFFFFFFF))); // Some easier-to-verify round-trip tests. The inputs (other than 0, 1, -1) // were chosen semi-randomly via keyboard bashing. EXPECT_EQ(0, ZigZagDecode32(ZigZagEncode32(0))); EXPECT_EQ(1, ZigZagDecode32(ZigZagEncode32(1))); EXPECT_EQ(-1, ZigZagDecode32(ZigZagEncode32(-1))); EXPECT_EQ(14927, ZigZagDecode32(ZigZagEncode32(14927))); EXPECT_EQ(-3612, ZigZagDecode32(ZigZagEncode32(-3612))); EXPECT_EQ(0, ZigZagDecode64(ZigZagEncode64(0))); EXPECT_EQ(1, ZigZagDecode64(ZigZagEncode64(1))); EXPECT_EQ(-1, ZigZagDecode64(ZigZagEncode64(-1))); EXPECT_EQ(14927, ZigZagDecode64(ZigZagEncode64(14927))); EXPECT_EQ(-3612, ZigZagDecode64(ZigZagEncode64(-3612))); EXPECT_EQ(LL(856912304801416), ZigZagDecode64(ZigZagEncode64(LL(856912304801416)))); EXPECT_EQ(LL(-75123905439571256), ZigZagDecode64(ZigZagEncode64(LL(-75123905439571256)))); } TEST(WireFormatTest, RepeatedScalarsDifferentTagSizes) { // At one point checks would trigger when parsing repeated fixed scalar // fields. UNITTEST::TestRepeatedScalarDifferentTagSizes msg1, msg2; for (int i = 0; i < 100; ++i) { msg1.add_repeated_fixed32(i); msg1.add_repeated_int32(i); msg1.add_repeated_fixed64(i); msg1.add_repeated_int64(i); msg1.add_repeated_float(i); msg1.add_repeated_uint64(i); } // Make sure that we have a variety of tag sizes. const Descriptor* desc = msg1.GetDescriptor(); const FieldDescriptor* field; field = desc->FindFieldByName("repeated_fixed32"); ASSERT_TRUE(field != nullptr); ASSERT_EQ(1, WireFormat::TagSize(field->number(), field->type())); field = desc->FindFieldByName("repeated_int32"); ASSERT_TRUE(field != nullptr); ASSERT_EQ(1, WireFormat::TagSize(field->number(), field->type())); field = desc->FindFieldByName("repeated_fixed64"); ASSERT_TRUE(field != nullptr); ASSERT_EQ(2, WireFormat::TagSize(field->number(), field->type())); field = desc->FindFieldByName("repeated_int64"); ASSERT_TRUE(field != nullptr); ASSERT_EQ(2, WireFormat::TagSize(field->number(), field->type())); field = desc->FindFieldByName("repeated_float"); ASSERT_TRUE(field != nullptr); ASSERT_EQ(3, WireFormat::TagSize(field->number(), field->type())); field = desc->FindFieldByName("repeated_uint64"); ASSERT_TRUE(field != nullptr); ASSERT_EQ(3, WireFormat::TagSize(field->number(), field->type())); EXPECT_TRUE(msg2.ParseFromString(msg1.SerializeAsString())); EXPECT_EQ(msg1.DebugString(), msg2.DebugString()); } TEST(WireFormatTest, CompatibleTypes) { const int64_t data = 0x100000000LL; UNITTEST::Int64Message msg1; msg1.set_data(data); std::string serialized; msg1.SerializeToString(&serialized); // Test int64 is compatible with bool UNITTEST::BoolMessage msg2; ASSERT_TRUE(msg2.ParseFromString(serialized)); ASSERT_EQ(static_cast(data), msg2.data()); // Test int64 is compatible with uint64 UNITTEST::Uint64Message msg3; ASSERT_TRUE(msg3.ParseFromString(serialized)); ASSERT_EQ(static_cast(data), msg3.data()); // Test int64 is compatible with int32 UNITTEST::Int32Message msg4; ASSERT_TRUE(msg4.ParseFromString(serialized)); ASSERT_EQ(static_cast(data), msg4.data()); // Test int64 is compatible with uint32 UNITTEST::Uint32Message msg5; ASSERT_TRUE(msg5.ParseFromString(serialized)); ASSERT_EQ(static_cast(data), msg5.data()); } class Proto3PrimitiveRepeatedWireFormatTest : public ::testing::Test { protected: Proto3PrimitiveRepeatedWireFormatTest() : packedTestAllTypes_( "\xFA\x01\x01\x01" "\x82\x02\x01\x01" "\x8A\x02\x01\x01" "\x92\x02\x01\x01" "\x9A\x02\x01\x02" "\xA2\x02\x01\x02" "\xAA\x02\x04\x01\x00\x00\x00" "\xB2\x02\x08\x01\x00\x00\x00\x00\x00\x00\x00" "\xBA\x02\x04\x01\x00\x00\x00" "\xC2\x02\x08\x01\x00\x00\x00\x00\x00\x00\x00" "\xCA\x02\x04\x00\x00\x80\x3f" "\xD2\x02\x08\x00\x00\x00\x00\x00\x00\xf0\x3f" "\xDA\x02\x01\x01" "\x9A\x03\x01\x01", 86), packedTestUnpackedTypes_( "\x0A\x01\x01" "\x12\x01\x01" "\x1A\x01\x01" "\x22\x01\x01" "\x2A\x01\x02" "\x32\x01\x02" "\x3A\x04\x01\x00\x00\x00" "\x42\x08\x01\x00\x00\x00\x00\x00\x00\x00" "\x4A\x04\x01\x00\x00\x00" "\x52\x08\x01\x00\x00\x00\x00\x00\x00\x00" "\x5A\x04\x00\x00\x80\x3f" "\x62\x08\x00\x00\x00\x00\x00\x00\xf0\x3f" "\x6A\x01\x01" "\x72\x01\x01", 72), unpackedTestAllTypes_( "\xF8\x01\x01" "\x80\x02\x01" "\x88\x02\x01" "\x90\x02\x01" "\x98\x02\x02" "\xA0\x02\x02" "\xAD\x02\x01\x00\x00\x00" "\xB1\x02\x01\x00\x00\x00\x00\x00\x00\x00" "\xBD\x02\x01\x00\x00\x00" "\xC1\x02\x01\x00\x00\x00\x00\x00\x00\x00" "\xCD\x02\x00\x00\x80\x3f" "\xD1\x02\x00\x00\x00\x00\x00\x00\xf0\x3f" "\xD8\x02\x01" "\x98\x03\x01", 72), unpackedTestUnpackedTypes_( "\x08\x01" "\x10\x01" "\x18\x01" "\x20\x01" "\x28\x02" "\x30\x02" "\x3D\x01\x00\x00\x00" "\x41\x01\x00\x00\x00\x00\x00\x00\x00" "\x4D\x01\x00\x00\x00" "\x51\x01\x00\x00\x00\x00\x00\x00\x00" "\x5D\x00\x00\x80\x3f" "\x61\x00\x00\x00\x00\x00\x00\xf0\x3f" "\x68\x01" "\x70\x01", 58) {} template void SetProto3PrimitiveRepeatedFields(Proto* message) { message->add_repeated_int32(1); message->add_repeated_int64(1); message->add_repeated_uint32(1); message->add_repeated_uint64(1); message->add_repeated_sint32(1); message->add_repeated_sint64(1); message->add_repeated_fixed32(1); message->add_repeated_fixed64(1); message->add_repeated_sfixed32(1); message->add_repeated_sfixed64(1); message->add_repeated_float(1.0); message->add_repeated_double(1.0); message->add_repeated_bool(true); message->add_repeated_nested_enum(PROTO3_ARENA_UNITTEST::TestAllTypes::FOO); } template void ExpectProto3PrimitiveRepeatedFieldsSet(const Proto& message) { EXPECT_EQ(1, message.repeated_int32(0)); EXPECT_EQ(1, message.repeated_int64(0)); EXPECT_EQ(1, message.repeated_uint32(0)); EXPECT_EQ(1, message.repeated_uint64(0)); EXPECT_EQ(1, message.repeated_sint32(0)); EXPECT_EQ(1, message.repeated_sint64(0)); EXPECT_EQ(1, message.repeated_fixed32(0)); EXPECT_EQ(1, message.repeated_fixed64(0)); EXPECT_EQ(1, message.repeated_sfixed32(0)); EXPECT_EQ(1, message.repeated_sfixed64(0)); EXPECT_EQ(1.0, message.repeated_float(0)); EXPECT_EQ(1.0, message.repeated_double(0)); EXPECT_EQ(true, message.repeated_bool(0)); EXPECT_EQ(PROTO3_ARENA_UNITTEST::TestAllTypes::FOO, message.repeated_nested_enum(0)); } template void TestSerialization(Proto* message, const std::string& expected) { SetProto3PrimitiveRepeatedFields(message); size_t size = message->ByteSizeLong(); // Serialize using the generated code. std::string generated_data; { io::StringOutputStream raw_output(&generated_data); io::CodedOutputStream output(&raw_output); message->SerializeWithCachedSizes(&output); ASSERT_FALSE(output.HadError()); } EXPECT_TRUE(TestUtil::EqualsToSerialized(*message, generated_data)); // Serialize using the dynamic code. std::string dynamic_data; { io::StringOutputStream raw_output(&dynamic_data); io::CodedOutputStream output(&raw_output); WireFormat::SerializeWithCachedSizes(*message, size, &output); ASSERT_FALSE(output.HadError()); } EXPECT_TRUE(expected == dynamic_data); } template void TestParsing(Proto* message, const std::string& compatible_data) { message->Clear(); message->ParseFromString(compatible_data); ExpectProto3PrimitiveRepeatedFieldsSet(*message); message->Clear(); io::CodedInputStream input( reinterpret_cast(compatible_data.data()), compatible_data.size()); WireFormat::ParseAndMergePartial(&input, message); ExpectProto3PrimitiveRepeatedFieldsSet(*message); } const std::string packedTestAllTypes_; const std::string packedTestUnpackedTypes_; const std::string unpackedTestAllTypes_; const std::string unpackedTestUnpackedTypes_; }; TEST_F(Proto3PrimitiveRepeatedWireFormatTest, Proto3PrimitiveRepeated) { PROTO3_ARENA_UNITTEST::TestAllTypes packed_message; PROTO3_ARENA_UNITTEST::TestUnpackedTypes unpacked_message; TestSerialization(&packed_message, packedTestAllTypes_); TestParsing(&packed_message, packedTestAllTypes_); TestParsing(&packed_message, unpackedTestAllTypes_); TestSerialization(&unpacked_message, unpackedTestUnpackedTypes_); TestParsing(&unpacked_message, packedTestUnpackedTypes_); TestParsing(&unpacked_message, unpackedTestUnpackedTypes_); } class WireFormatInvalidInputTest : public testing::Test { protected: // Make a serialized TestAllTypes in which the field optional_nested_message // contains exactly the given bytes, which may be invalid. std::string MakeInvalidEmbeddedMessage(const char* bytes, int size) { const FieldDescriptor* field = UNITTEST::TestAllTypes::descriptor()->FindFieldByName( "optional_nested_message"); GOOGLE_CHECK(field != nullptr); std::string result; { io::StringOutputStream raw_output(&result); io::CodedOutputStream output(&raw_output); WireFormatLite::WriteBytes(field->number(), std::string(bytes, size), &output); } return result; } // Make a serialized TestAllTypes in which the field optionalgroup // contains exactly the given bytes -- which may be invalid -- and // possibly no end tag. std::string MakeInvalidGroup(const char* bytes, int size, bool include_end_tag) { const FieldDescriptor* field = UNITTEST::TestAllTypes::descriptor()->FindFieldByName("optionalgroup"); GOOGLE_CHECK(field != nullptr); std::string result; { io::StringOutputStream raw_output(&result); io::CodedOutputStream output(&raw_output); output.WriteVarint32(WireFormat::MakeTag(field)); output.WriteString(std::string(bytes, size)); if (include_end_tag) { output.WriteVarint32(WireFormatLite::MakeTag( field->number(), WireFormatLite::WIRETYPE_END_GROUP)); } } return result; } }; TEST_F(WireFormatInvalidInputTest, InvalidSubMessage) { UNITTEST::TestAllTypes message; // Control case. EXPECT_TRUE(message.ParseFromString(MakeInvalidEmbeddedMessage("", 0))); // The byte is a valid varint, but not a valid tag (zero). EXPECT_FALSE(message.ParseFromString(MakeInvalidEmbeddedMessage("\0", 1))); // The byte is a malformed varint. EXPECT_FALSE(message.ParseFromString(MakeInvalidEmbeddedMessage("\200", 1))); // The byte is an endgroup tag, but we aren't parsing a group. EXPECT_FALSE(message.ParseFromString(MakeInvalidEmbeddedMessage("\014", 1))); // The byte is a valid varint but not a valid tag (bad wire type). EXPECT_FALSE(message.ParseFromString(MakeInvalidEmbeddedMessage("\017", 1))); } TEST_F(WireFormatInvalidInputTest, InvalidMessageWithExtraZero) { std::string data; { // Serialize a valid proto UNITTEST::TestAllTypes message; message.set_optional_int32(1); message.SerializeToString(&data); data.push_back(0); // Append invalid zero tag } // Control case. { io::ArrayInputStream ais(data.data(), data.size()); io::CodedInputStream is(&ais); UNITTEST::TestAllTypes message; // It should fail but currently passes. EXPECT_TRUE(message.MergePartialFromCodedStream(&is)); // Parsing from the string should fail. EXPECT_FALSE(message.ParseFromString(data)); } } TEST_F(WireFormatInvalidInputTest, InvalidGroup) { UNITTEST::TestAllTypes message; // Control case. EXPECT_TRUE(message.ParseFromString(MakeInvalidGroup("", 0, true))); // Missing end tag. Groups cannot end at EOF. EXPECT_FALSE(message.ParseFromString(MakeInvalidGroup("", 0, false))); // The byte is a valid varint, but not a valid tag (zero). EXPECT_FALSE(message.ParseFromString(MakeInvalidGroup("\0", 1, false))); // The byte is a malformed varint. EXPECT_FALSE(message.ParseFromString(MakeInvalidGroup("\200", 1, false))); // The byte is an endgroup tag, but not the right one for this group. EXPECT_FALSE(message.ParseFromString(MakeInvalidGroup("\014", 1, false))); // The byte is a valid varint but not a valid tag (bad wire type). EXPECT_FALSE(message.ParseFromString(MakeInvalidGroup("\017", 1, true))); } TEST_F(WireFormatInvalidInputTest, InvalidUnknownGroup) { // Use TestEmptyMessage so that the group made by MakeInvalidGroup will not // be a known tag number. UNITTEST::TestEmptyMessage message; // Control case. EXPECT_TRUE(message.ParseFromString(MakeInvalidGroup("", 0, true))); // Missing end tag. Groups cannot end at EOF. EXPECT_FALSE(message.ParseFromString(MakeInvalidGroup("", 0, false))); // The byte is a valid varint, but not a valid tag (zero). EXPECT_FALSE(message.ParseFromString(MakeInvalidGroup("\0", 1, false))); // The byte is a malformed varint. EXPECT_FALSE(message.ParseFromString(MakeInvalidGroup("\200", 1, false))); // The byte is an endgroup tag, but not the right one for this group. EXPECT_FALSE(message.ParseFromString(MakeInvalidGroup("\014", 1, false))); // The byte is a valid varint but not a valid tag (bad wire type). EXPECT_FALSE(message.ParseFromString(MakeInvalidGroup("\017", 1, true))); } TEST_F(WireFormatInvalidInputTest, InvalidStringInUnknownGroup) { // Test a bug fix: SkipMessage should fail if the message contains a // string whose length would extend beyond the message end. UNITTEST::TestAllTypes message; message.set_optional_string("foo foo foo foo"); std::string data; message.SerializeToString(&data); // Chop some bytes off the end. data.resize(data.size() - 4); // Try to skip it. Note that the bug was only present when parsing to an // UnknownFieldSet. io::ArrayInputStream raw_input(data.data(), data.size()); io::CodedInputStream coded_input(&raw_input); UnknownFieldSet unknown_fields; EXPECT_FALSE(WireFormat::SkipMessage(&coded_input, &unknown_fields)); } // Test differences between string and bytes. // Value of a string type must be valid UTF-8 string. When UTF-8 // validation is enabled (GOOGLE_PROTOBUF_UTF8_VALIDATION_ENABLED): // WriteInvalidUTF8String: see error message. // ReadInvalidUTF8String: see error message. // WriteValidUTF8String: fine. // ReadValidUTF8String: fine. // WriteAnyBytes: fine. // ReadAnyBytes: fine. const char* kInvalidUTF8String = "Invalid UTF-8: \xA0\xB0\xC0\xD0"; // This used to be "Valid UTF-8: \x01\x02\u8C37\u6B4C", but MSVC seems to // interpret \u differently from GCC. const char* kValidUTF8String = "Valid UTF-8: \x01\x02\350\260\267\346\255\214"; template bool WriteMessage(const char* value, T* message, std::string* wire_buffer) { message->set_data(value); wire_buffer->clear(); message->AppendToString(wire_buffer); return (wire_buffer->size() > 0); } template bool ReadMessage(const std::string& wire_buffer, T* message) { return message->ParseFromArray(wire_buffer.data(), wire_buffer.size()); } class Utf8ValidationTest : public ::testing::Test { protected: Utf8ValidationTest() {} ~Utf8ValidationTest() override {} void SetUp() override { } }; TEST_F(Utf8ValidationTest, WriteInvalidUTF8String) { std::string wire_buffer; UNITTEST::OneString input; std::vector errors; { ScopedMemoryLog log; WriteMessage(kInvalidUTF8String, &input, &wire_buffer); errors = log.GetMessages(ERROR); } #ifdef GOOGLE_PROTOBUF_UTF8_VALIDATION_ENABLED EXPECT_THAT(errors, testing::ElementsAre( "String field '" + std::string(UNITTEST_PACKAGE_NAME) + ".OneString.data' " "contains invalid UTF-8 data when " "serializing a protocol buffer. Use the " "'bytes' type if you intend to send raw bytes. ")); #else ASSERT_EQ(0, errors.size()); #endif // GOOGLE_PROTOBUF_UTF8_VALIDATION_ENABLED } TEST_F(Utf8ValidationTest, ReadInvalidUTF8String) { std::string wire_buffer; UNITTEST::OneString input; WriteMessage(kInvalidUTF8String, &input, &wire_buffer); UNITTEST::OneString output; std::vector errors; { ScopedMemoryLog log; ReadMessage(wire_buffer, &output); errors = log.GetMessages(ERROR); } #ifdef GOOGLE_PROTOBUF_UTF8_VALIDATION_ENABLED EXPECT_THAT(errors, testing::ElementsAre( "String field '" + std::string(UNITTEST_PACKAGE_NAME) + ".OneString.data' " "contains invalid UTF-8 data when " "parsing a protocol buffer. Use the " "'bytes' type if you intend to send raw bytes. ")); #else ASSERT_EQ(0, errors.size()); #endif // GOOGLE_PROTOBUF_UTF8_VALIDATION_ENABLED } TEST_F(Utf8ValidationTest, WriteValidUTF8String) { std::string wire_buffer; UNITTEST::OneString input; std::vector errors; { ScopedMemoryLog log; WriteMessage(kValidUTF8String, &input, &wire_buffer); errors = log.GetMessages(ERROR); } ASSERT_EQ(0, errors.size()); } TEST_F(Utf8ValidationTest, ReadValidUTF8String) { std::string wire_buffer; UNITTEST::OneString input; WriteMessage(kValidUTF8String, &input, &wire_buffer); UNITTEST::OneString output; std::vector errors; { ScopedMemoryLog log; ReadMessage(wire_buffer, &output); errors = log.GetMessages(ERROR); } ASSERT_EQ(0, errors.size()); EXPECT_EQ(input.data(), output.data()); } // Bytes: anything can pass as bytes, use invalid UTF-8 string to test TEST_F(Utf8ValidationTest, WriteArbitraryBytes) { std::string wire_buffer; UNITTEST::OneBytes input; std::vector errors; { ScopedMemoryLog log; WriteMessage(kInvalidUTF8String, &input, &wire_buffer); errors = log.GetMessages(ERROR); } ASSERT_EQ(0, errors.size()); } TEST_F(Utf8ValidationTest, ReadArbitraryBytes) { std::string wire_buffer; UNITTEST::OneBytes input; WriteMessage(kInvalidUTF8String, &input, &wire_buffer); UNITTEST::OneBytes output; std::vector errors; { ScopedMemoryLog log; ReadMessage(wire_buffer, &output); errors = log.GetMessages(ERROR); } ASSERT_EQ(0, errors.size()); EXPECT_EQ(input.data(), output.data()); } TEST_F(Utf8ValidationTest, ParseRepeatedString) { UNITTEST::MoreBytes input; input.add_data(kValidUTF8String); input.add_data(kInvalidUTF8String); input.add_data(kInvalidUTF8String); std::string wire_buffer = input.SerializeAsString(); UNITTEST::MoreString output; std::vector errors; { ScopedMemoryLog log; ReadMessage(wire_buffer, &output); errors = log.GetMessages(ERROR); } #ifdef GOOGLE_PROTOBUF_UTF8_VALIDATION_ENABLED ASSERT_EQ(2, errors.size()); #else ASSERT_EQ(0, errors.size()); #endif // GOOGLE_PROTOBUF_UTF8_VALIDATION_ENABLED EXPECT_EQ(wire_buffer, output.SerializeAsString()); } // Test the old VerifyUTF8String() function, which may still be called by old // generated code. TEST_F(Utf8ValidationTest, OldVerifyUTF8String) { std::string data(kInvalidUTF8String); std::vector errors; { ScopedMemoryLog log; WireFormat::VerifyUTF8String(data.data(), data.size(), WireFormat::SERIALIZE); errors = log.GetMessages(ERROR); } #ifdef GOOGLE_PROTOBUF_UTF8_VALIDATION_ENABLED ASSERT_EQ(1, errors.size()); EXPECT_TRUE( HasPrefixString(errors[0], "String field contains invalid UTF-8 data when " "serializing a protocol buffer. Use the " "'bytes' type if you intend to send raw bytes.")); #else ASSERT_EQ(0, errors.size()); #endif } TEST(RepeatedVarint, Int32) { RepeatedField v; // Insert -2^n, 2^n and 2^n-1. for (int n = 0; n < 10; n++) { v.Add(-(1 << n)); v.Add(1 << n); v.Add((1 << n) - 1); } // Check consistency with the scalar Int32Size. size_t expected = 0; for (int i = 0; i < v.size(); i++) { expected += WireFormatLite::Int32Size(v[i]); } EXPECT_EQ(expected, WireFormatLite::Int32Size(v)); } TEST(RepeatedVarint, Int64) { RepeatedField v; // Insert -2^n, 2^n and 2^n-1. for (int n = 0; n < 10; n++) { v.Add(-(1 << n)); v.Add(1 << n); v.Add((1 << n) - 1); } // Check consistency with the scalar Int64Size. size_t expected = 0; for (int i = 0; i < v.size(); i++) { expected += WireFormatLite::Int64Size(v[i]); } EXPECT_EQ(expected, WireFormatLite::Int64Size(v)); } TEST(RepeatedVarint, SInt32) { RepeatedField v; // Insert -2^n, 2^n and 2^n-1. for (int n = 0; n < 10; n++) { v.Add(-(1 << n)); v.Add(1 << n); v.Add((1 << n) - 1); } // Check consistency with the scalar SInt32Size. size_t expected = 0; for (int i = 0; i < v.size(); i++) { expected += WireFormatLite::SInt32Size(v[i]); } EXPECT_EQ(expected, WireFormatLite::SInt32Size(v)); } TEST(RepeatedVarint, SInt64) { RepeatedField v; // Insert -2^n, 2^n and 2^n-1. for (int n = 0; n < 10; n++) { v.Add(-(1 << n)); v.Add(1 << n); v.Add((1 << n) - 1); } // Check consistency with the scalar SInt64Size. size_t expected = 0; for (int i = 0; i < v.size(); i++) { expected += WireFormatLite::SInt64Size(v[i]); } EXPECT_EQ(expected, WireFormatLite::SInt64Size(v)); } TEST(RepeatedVarint, UInt32) { RepeatedField v; // Insert 2^n and 2^n-1. for (int n = 0; n < 10; n++) { v.Add(1 << n); v.Add((1 << n) - 1); } // Check consistency with the scalar UInt32Size. size_t expected = 0; for (int i = 0; i < v.size(); i++) { expected += WireFormatLite::UInt32Size(v[i]); } EXPECT_EQ(expected, WireFormatLite::UInt32Size(v)); } TEST(RepeatedVarint, UInt64) { RepeatedField v; // Insert 2^n and 2^n-1. for (int n = 0; n < 10; n++) { v.Add(1 << n); v.Add((1 << n) - 1); } // Check consistency with the scalar UInt64Size. size_t expected = 0; for (int i = 0; i < v.size(); i++) { expected += WireFormatLite::UInt64Size(v[i]); } EXPECT_EQ(expected, WireFormatLite::UInt64Size(v)); } TEST(RepeatedVarint, Enum) { RepeatedField v; // Insert 2^n and 2^n-1. for (int n = 0; n < 10; n++) { v.Add(1 << n); v.Add((1 << n) - 1); } // Check consistency with the scalar EnumSize. size_t expected = 0; for (int i = 0; i < v.size(); i++) { expected += WireFormatLite::EnumSize(v[i]); } EXPECT_EQ(expected, WireFormatLite::EnumSize(v)); } } // namespace } // namespace internal } // namespace protobuf } // namespace google #include