// 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. // // To test the code generator, we actually use it to generate code for // net/proto2/internal/unittest.proto, then test that. This means that we // are actually testing the parser and other parts of the system at the same // time, and that problems in the generator may show up as compile-time errors // rather than unittest failures, which may be surprising. However, testing // the output of the C++ generator directly would be very hard. We can't very // well just check it against golden files since those files would have to be // updated for any small change; such a test would be very brittle and probably // not very helpful. What we really want to test is that the code compiles // correctly and produces the interfaces we expect, which is why this test // is written this way. #include #include #include #include #include #include #if !defined(GOOGLE_PROTOBUF_CMAKE_BUILD) && !defined(_MSC_VER) // We exclude this large proto from cmake build because it's too large for // visual studio to compile (report internal errors). #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // Must be included last. #include namespace google { namespace protobuf { namespace compiler { namespace cpp { // Can't use an anonymous namespace here due to brokenness of Tru64 compiler. namespace cpp_unittest { void DoNothing() {} class MockErrorCollector : public MultiFileErrorCollector { public: MockErrorCollector() {} ~MockErrorCollector() {} std::string text_; // implements ErrorCollector --------------------------------------- void AddError(const std::string& filename, int line, int column, const std::string& message) override { strings::SubstituteAndAppend(&text_, "$0:$1:$2: $3\n", filename, line, column, message); } }; #ifndef PROTOBUF_TEST_NO_DESCRIPTORS // Test that generated code has proper descriptors: // Parse a descriptor directly (using google::protobuf::compiler::Importer) and // compare it to the one that was produced by generated code. TEST(GENERATED_DESCRIPTOR_TEST_NAME, IdenticalDescriptors) { const FileDescriptor* generated_descriptor = UNITTEST::TestAllTypes::descriptor()->file(); // Set up the Importer. MockErrorCollector error_collector; DiskSourceTree source_tree; source_tree.MapPath("", TestUtil::TestSourceDir()); Importer importer(&source_tree, &error_collector); // Import (parse) unittest.proto. const FileDescriptor* parsed_descriptor = importer.Import(TestUtil::MaybeTranslatePath(UNITTEST_PROTO_PATH)); EXPECT_EQ("", error_collector.text_); ASSERT_TRUE(parsed_descriptor != NULL); // Test that descriptors are generated correctly by converting them to // FileDescriptorProtos and comparing. FileDescriptorProto generated_descriptor_proto, parsed_descriptor_proto; generated_descriptor->CopyTo(&generated_descriptor_proto); parsed_descriptor->CopyTo(&parsed_descriptor_proto); EXPECT_EQ(parsed_descriptor_proto.DebugString(), generated_descriptor_proto.DebugString()); } #if !defined(GOOGLE_PROTOBUF_CMAKE_BUILD) && !defined(_MSC_VER) // Test that generated code has proper descriptors: // Touch a descriptor generated from an enormous message to validate special // handling for descriptors exceeding the C++ standard's recommended minimum // limit for string literal size TEST(GENERATED_DESCRIPTOR_TEST_NAME, EnormousDescriptor) { const Descriptor* generated_descriptor = ::protobuf_unittest::TestEnormousDescriptor::descriptor(); EXPECT_TRUE(generated_descriptor != NULL); } #endif #endif // !PROTOBUF_TEST_NO_DESCRIPTORS // =================================================================== TEST(GENERATED_MESSAGE_TEST_NAME, Defaults) { // Check that all default values are set correctly in the initial message. UNITTEST::TestAllTypes message; TestUtil::ExpectClear(message); // Messages should return pointers to default instances until first use. // (This is not checked by ExpectClear() since it is not actually true after // the fields have been set and then cleared.) EXPECT_EQ(&UNITTEST::TestAllTypes::OptionalGroup::default_instance(), &message.optionalgroup()); EXPECT_EQ(&UNITTEST::TestAllTypes::NestedMessage::default_instance(), &message.optional_nested_message()); EXPECT_EQ(&UNITTEST::ForeignMessage::default_instance(), &message.optional_foreign_message()); EXPECT_EQ(&UNITTEST_IMPORT::ImportMessage::default_instance(), &message.optional_import_message()); } TEST(GENERATED_MESSAGE_TEST_NAME, FloatingPointDefaults) { const UNITTEST::TestExtremeDefaultValues& extreme_default = UNITTEST::TestExtremeDefaultValues::default_instance(); EXPECT_EQ(0.0f, extreme_default.zero_float()); EXPECT_EQ(1.0f, extreme_default.one_float()); EXPECT_EQ(1.5f, extreme_default.small_float()); EXPECT_EQ(-1.0f, extreme_default.negative_one_float()); EXPECT_EQ(-1.5f, extreme_default.negative_float()); EXPECT_EQ(2.0e8f, extreme_default.large_float()); EXPECT_EQ(-8e-28f, extreme_default.small_negative_float()); EXPECT_EQ(std::numeric_limits::infinity(), extreme_default.inf_double()); EXPECT_EQ(-std::numeric_limits::infinity(), extreme_default.neg_inf_double()); EXPECT_TRUE(extreme_default.nan_double() != extreme_default.nan_double()); EXPECT_EQ(std::numeric_limits::infinity(), extreme_default.inf_float()); EXPECT_EQ(-std::numeric_limits::infinity(), extreme_default.neg_inf_float()); EXPECT_TRUE(extreme_default.nan_float() != extreme_default.nan_float()); } TEST(GENERATED_MESSAGE_TEST_NAME, Trigraph) { const UNITTEST::TestExtremeDefaultValues& extreme_default = UNITTEST::TestExtremeDefaultValues::default_instance(); EXPECT_EQ("? ? ?? ?? ??? ?\?/ ?\?-", extreme_default.cpp_trigraph()); } TEST(GENERATED_MESSAGE_TEST_NAME, ExtremeSmallIntegerDefault) { const UNITTEST::TestExtremeDefaultValues& extreme_default = UNITTEST::TestExtremeDefaultValues::default_instance(); EXPECT_EQ(std::numeric_limits::min(), extreme_default.really_small_int32()); EXPECT_EQ(std::numeric_limits::min(), extreme_default.really_small_int64()); } TEST(GENERATED_MESSAGE_TEST_NAME, Accessors) { // Set every field to a unique value then go back and check all those // values. UNITTEST::TestAllTypes message; TestUtil::SetAllFields(&message); TestUtil::ExpectAllFieldsSet(message); TestUtil::ModifyRepeatedFields(&message); TestUtil::ExpectRepeatedFieldsModified(message); } TEST(GENERATED_MESSAGE_TEST_NAME, MutableStringDefault) { // mutable_foo() for a string should return a string initialized to its // default value. UNITTEST::TestAllTypes message; EXPECT_EQ("hello", *message.mutable_default_string()); // Note that the first time we call mutable_foo(), we get a newly-allocated // string, but if we clear it and call it again, we get the same object again. // We should verify that it has its default value in both cases. message.set_default_string("blah"); message.Clear(); EXPECT_EQ("hello", *message.mutable_default_string()); } TEST(GENERATED_MESSAGE_TEST_NAME, StringDefaults) { UNITTEST::TestExtremeDefaultValues message; // Check if '\000' can be used in default string value. EXPECT_EQ(std::string("hel\000lo", 6), message.string_with_zero()); EXPECT_EQ(std::string("wor\000ld", 6), message.bytes_with_zero()); } TEST(GENERATED_MESSAGE_TEST_NAME, ReleaseString) { // Check that release_foo() starts out NULL, and gives us a value // that we can delete after it's been set. UNITTEST::TestAllTypes message; EXPECT_EQ(NULL, message.release_default_string()); EXPECT_FALSE(message.has_default_string()); EXPECT_EQ("hello", message.default_string()); message.set_default_string("blah"); EXPECT_TRUE(message.has_default_string()); std::unique_ptr str(message.release_default_string()); EXPECT_FALSE(message.has_default_string()); ASSERT_TRUE(str != NULL); EXPECT_EQ("blah", *str); EXPECT_EQ(NULL, message.release_default_string()); EXPECT_FALSE(message.has_default_string()); EXPECT_EQ("hello", message.default_string()); } TEST(GENERATED_MESSAGE_TEST_NAME, ReleaseMessage) { // Check that release_foo() starts out NULL, and gives us a value // that we can delete after it's been set. UNITTEST::TestAllTypes message; EXPECT_EQ(NULL, message.release_optional_nested_message()); EXPECT_FALSE(message.has_optional_nested_message()); message.mutable_optional_nested_message()->set_bb(1); std::unique_ptr nest( message.release_optional_nested_message()); EXPECT_FALSE(message.has_optional_nested_message()); ASSERT_TRUE(nest != NULL); EXPECT_EQ(1, nest->bb()); EXPECT_EQ(NULL, message.release_optional_nested_message()); EXPECT_FALSE(message.has_optional_nested_message()); } TEST(GENERATED_MESSAGE_TEST_NAME, SetAllocatedString) { // Check that set_allocated_foo() works for strings. UNITTEST::TestAllTypes message; EXPECT_FALSE(message.has_optional_string()); const std::string kHello("hello"); message.set_optional_string(kHello); EXPECT_TRUE(message.has_optional_string()); message.set_allocated_optional_string(NULL); EXPECT_FALSE(message.has_optional_string()); EXPECT_EQ("", message.optional_string()); message.set_allocated_optional_string(new std::string(kHello)); EXPECT_TRUE(message.has_optional_string()); EXPECT_EQ(kHello, message.optional_string()); } TEST(GENERATED_MESSAGE_TEST_NAME, SetAllocatedMessage) { // Check that set_allocated_foo() can be called in all cases. UNITTEST::TestAllTypes message; EXPECT_FALSE(message.has_optional_nested_message()); message.mutable_optional_nested_message()->set_bb(1); EXPECT_TRUE(message.has_optional_nested_message()); message.set_allocated_optional_nested_message(NULL); EXPECT_FALSE(message.has_optional_nested_message()); EXPECT_EQ(&UNITTEST::TestAllTypes::NestedMessage::default_instance(), &message.optional_nested_message()); message.mutable_optional_nested_message()->set_bb(1); UNITTEST::TestAllTypes::NestedMessage* nest = message.release_optional_nested_message(); ASSERT_TRUE(nest != NULL); EXPECT_FALSE(message.has_optional_nested_message()); message.set_allocated_optional_nested_message(nest); EXPECT_TRUE(message.has_optional_nested_message()); EXPECT_EQ(1, message.optional_nested_message().bb()); } TEST(GENERATED_MESSAGE_TEST_NAME, Clear) { // Set every field to a unique value, clear the message, then check that // it is cleared. UNITTEST::TestAllTypes message; TestUtil::SetAllFields(&message); message.Clear(); TestUtil::ExpectClear(message); // Unlike with the defaults test, we do NOT expect that requesting embedded // messages will return a pointer to the default instance. Instead, they // should return the objects that were created when mutable_blah() was // called. EXPECT_NE(&UNITTEST::TestAllTypes::OptionalGroup::default_instance(), &message.optionalgroup()); EXPECT_NE(&UNITTEST::TestAllTypes::NestedMessage::default_instance(), &message.optional_nested_message()); EXPECT_NE(&UNITTEST::ForeignMessage::default_instance(), &message.optional_foreign_message()); EXPECT_NE(&UNITTEST_IMPORT::ImportMessage::default_instance(), &message.optional_import_message()); } TEST(GENERATED_MESSAGE_TEST_NAME, EmbeddedNullsInBytesCharStar) { UNITTEST::TestAllTypes message; const char* value = "\0lalala\0\0"; message.set_optional_bytes(value, 9); ASSERT_EQ(9, message.optional_bytes().size()); EXPECT_EQ(0, memcmp(value, message.optional_bytes().data(), 9)); message.add_repeated_bytes(value, 9); ASSERT_EQ(9, message.repeated_bytes(0).size()); EXPECT_EQ(0, memcmp(value, message.repeated_bytes(0).data(), 9)); } TEST(GENERATED_MESSAGE_TEST_NAME, ClearOneField) { // Set every field to a unique value, then clear one value and insure that // only that one value is cleared. UNITTEST::TestAllTypes message; TestUtil::SetAllFields(&message); int64_t original_value = message.optional_int64(); // Clear the field and make sure it shows up as cleared. message.clear_optional_int64(); EXPECT_FALSE(message.has_optional_int64()); EXPECT_EQ(0, message.optional_int64()); // Other adjacent fields should not be cleared. EXPECT_TRUE(message.has_optional_int32()); EXPECT_TRUE(message.has_optional_uint32()); // Make sure if we set it again, then all fields are set. message.set_optional_int64(original_value); TestUtil::ExpectAllFieldsSet(message); } TEST(GENERATED_MESSAGE_TEST_NAME, StringCharStarLength) { // Verify that we can use a char*,length to set one of the string fields. UNITTEST::TestAllTypes message; message.set_optional_string("abcdef", 3); EXPECT_EQ("abc", message.optional_string()); // Verify that we can use a char*,length to add to a repeated string field. message.add_repeated_string("abcdef", 3); EXPECT_EQ(1, message.repeated_string_size()); EXPECT_EQ("abc", message.repeated_string(0)); // Verify that we can use a char*,length to set a repeated string field. message.set_repeated_string(0, "wxyz", 2); EXPECT_EQ("wx", message.repeated_string(0)); } TEST(GENERATED_MESSAGE_TEST_NAME, CopyFrom) { UNITTEST::TestAllTypes message1, message2; TestUtil::SetAllFields(&message1); message2.CopyFrom(message1); TestUtil::ExpectAllFieldsSet(message2); // Copying from self should be a no-op. message2.CopyFrom(message2); TestUtil::ExpectAllFieldsSet(message2); } TEST(GENERATED_MESSAGE_TEST_NAME, SwapWithEmpty) { UNITTEST::TestAllTypes message1, message2; TestUtil::SetAllFields(&message1); TestUtil::ExpectAllFieldsSet(message1); TestUtil::ExpectClear(message2); message1.Swap(&message2); TestUtil::ExpectAllFieldsSet(message2); TestUtil::ExpectClear(message1); } TEST(GENERATED_MESSAGE_TEST_NAME, SwapWithSelf) { UNITTEST::TestAllTypes message; TestUtil::SetAllFields(&message); TestUtil::ExpectAllFieldsSet(message); message.Swap(&message); TestUtil::ExpectAllFieldsSet(message); } TEST(GENERATED_MESSAGE_TEST_NAME, SwapWithOther) { UNITTEST::TestAllTypes message1, message2; message1.set_optional_int32(123); message1.set_optional_string("abc"); message1.mutable_optional_nested_message()->set_bb(1); message1.set_optional_nested_enum(UNITTEST::TestAllTypes::FOO); message1.add_repeated_int32(1); message1.add_repeated_int32(2); message1.add_repeated_string("a"); message1.add_repeated_string("b"); message1.add_repeated_nested_message()->set_bb(7); message1.add_repeated_nested_message()->set_bb(8); message1.add_repeated_nested_enum(UNITTEST::TestAllTypes::FOO); message1.add_repeated_nested_enum(UNITTEST::TestAllTypes::BAR); message2.set_optional_int32(456); message2.set_optional_string("def"); message2.mutable_optional_nested_message()->set_bb(2); message2.set_optional_nested_enum(UNITTEST::TestAllTypes::BAR); message2.add_repeated_int32(3); message2.add_repeated_string("c"); message2.add_repeated_nested_message()->set_bb(9); message2.add_repeated_nested_enum(UNITTEST::TestAllTypes::BAZ); message1.Swap(&message2); EXPECT_EQ(456, message1.optional_int32()); EXPECT_EQ("def", message1.optional_string()); EXPECT_EQ(2, message1.optional_nested_message().bb()); EXPECT_EQ(UNITTEST::TestAllTypes::BAR, message1.optional_nested_enum()); ASSERT_EQ(1, message1.repeated_int32_size()); EXPECT_EQ(3, message1.repeated_int32(0)); ASSERT_EQ(1, message1.repeated_string_size()); EXPECT_EQ("c", message1.repeated_string(0)); ASSERT_EQ(1, message1.repeated_nested_message_size()); EXPECT_EQ(9, message1.repeated_nested_message(0).bb()); ASSERT_EQ(1, message1.repeated_nested_enum_size()); EXPECT_EQ(UNITTEST::TestAllTypes::BAZ, message1.repeated_nested_enum(0)); EXPECT_EQ(123, message2.optional_int32()); EXPECT_EQ("abc", message2.optional_string()); EXPECT_EQ(1, message2.optional_nested_message().bb()); EXPECT_EQ(UNITTEST::TestAllTypes::FOO, message2.optional_nested_enum()); ASSERT_EQ(2, message2.repeated_int32_size()); EXPECT_EQ(1, message2.repeated_int32(0)); EXPECT_EQ(2, message2.repeated_int32(1)); ASSERT_EQ(2, message2.repeated_string_size()); EXPECT_EQ("a", message2.repeated_string(0)); EXPECT_EQ("b", message2.repeated_string(1)); ASSERT_EQ(2, message2.repeated_nested_message_size()); EXPECT_EQ(7, message2.repeated_nested_message(0).bb()); EXPECT_EQ(8, message2.repeated_nested_message(1).bb()); ASSERT_EQ(2, message2.repeated_nested_enum_size()); EXPECT_EQ(UNITTEST::TestAllTypes::FOO, message2.repeated_nested_enum(0)); EXPECT_EQ(UNITTEST::TestAllTypes::BAR, message2.repeated_nested_enum(1)); } TEST(GENERATED_MESSAGE_TEST_NAME, ADLSwap) { UNITTEST::TestAllTypes message1, message2; TestUtil::SetAllFields(&message1); // Note the address of one of the repeated fields, to verify it was swapped // rather than copied. const int32_t* addr = &message1.repeated_int32().Get(0); using std::swap; swap(message1, message2); TestUtil::ExpectAllFieldsSet(message2); TestUtil::ExpectClear(message1); #ifdef PROTOBUF_FORCE_COPY_IN_SWAP EXPECT_NE(addr, &message2.repeated_int32().Get(0)); EXPECT_EQ(*addr, message2.repeated_int32().Get(0)); #else EXPECT_EQ(addr, &message2.repeated_int32().Get(0)); #endif } TEST(GENERATED_MESSAGE_TEST_NAME, CopyConstructor) { // All set. { UNITTEST::TestAllTypes message1; TestUtil::SetAllFields(&message1); UNITTEST::TestAllTypes message2(message1); TestUtil::ExpectAllFieldsSet(message2); } // None set. { UNITTEST::TestAllTypes message1; UNITTEST::TestAllTypes message2(message1); EXPECT_FALSE(message1.has_optional_string()); EXPECT_FALSE(message2.has_optional_string()); EXPECT_EQ(message1.optional_string(), message2.optional_string()); EXPECT_FALSE(message1.has_optional_bytes()); EXPECT_FALSE(message2.has_optional_bytes()); EXPECT_EQ(message1.optional_bytes(), message2.optional_bytes()); EXPECT_FALSE(message1.has_optional_nested_message()); EXPECT_FALSE(message2.has_optional_nested_message()); EXPECT_EQ(&message1.optional_nested_message(), &message2.optional_nested_message()); EXPECT_FALSE(message1.has_optional_foreign_message()); EXPECT_FALSE(message2.has_optional_foreign_message()); EXPECT_EQ(&message1.optional_foreign_message(), &message2.optional_foreign_message()); EXPECT_FALSE(message1.has_optional_import_message()); EXPECT_FALSE(message2.has_optional_import_message()); EXPECT_EQ(&message1.optional_import_message(), &message2.optional_import_message()); EXPECT_FALSE(message1.has_optional_public_import_message()); EXPECT_FALSE(message2.has_optional_public_import_message()); EXPECT_EQ(&message1.optional_public_import_message(), &message2.optional_public_import_message()); EXPECT_FALSE(message1.has_optional_lazy_message()); EXPECT_FALSE(message2.has_optional_lazy_message()); EXPECT_EQ(&message1.optional_lazy_message(), &message2.optional_lazy_message()); } } TEST(GENERATED_MESSAGE_TEST_NAME, CopyConstructorWithArenas) { Arena arena; UNITTEST::TestAllTypes* message1 = Arena::CreateMessage(&arena); TestUtil::SetAllFields(message1); UNITTEST::TestAllTypes message2_stack(*message1); TestUtil::ExpectAllFieldsSet(message2_stack); std::unique_ptr message2_heap( new UNITTEST::TestAllTypes(*message1)); TestUtil::ExpectAllFieldsSet(*message2_heap); arena.Reset(); // Verify that the copies are still intact. TestUtil::ExpectAllFieldsSet(message2_stack); TestUtil::ExpectAllFieldsSet(*message2_heap); } TEST(GENERATED_MESSAGE_TEST_NAME, CopyAssignmentOperator) { UNITTEST::TestAllTypes message1; TestUtil::SetAllFields(&message1); UNITTEST::TestAllTypes message2; message2 = message1; TestUtil::ExpectAllFieldsSet(message2); // Make sure that self-assignment does something sane. message2.operator=(message2); TestUtil::ExpectAllFieldsSet(message2); } #if !defined(PROTOBUF_TEST_NO_DESCRIPTORS) || PROTOBUF_RTTI TEST(GENERATED_MESSAGE_TEST_NAME, UpcastCopyFrom) { // Test the CopyFrom method that takes in the generic const Message& // parameter. UNITTEST::TestAllTypes message1, message2; TestUtil::SetAllFields(&message1); const Message* source = implicit_cast(&message1); message2.CopyFrom(*source); TestUtil::ExpectAllFieldsSet(message2); } #endif #ifndef PROTOBUF_TEST_NO_DESCRIPTORS TEST(GENERATED_MESSAGE_TEST_NAME, DynamicMessageCopyFrom) { // Test copying from a DynamicMessage, which must fall back to using // reflection. UNITTEST::TestAllTypes message2; // Construct a new version of the dynamic message via the factory. DynamicMessageFactory factory; std::unique_ptr message1; message1.reset(factory.GetPrototype( UNITTEST::TestAllTypes::descriptor())->New()); TestUtil::ReflectionTester reflection_tester( UNITTEST::TestAllTypes::descriptor()); reflection_tester.SetAllFieldsViaReflection(message1.get()); message2.CopyFrom(*message1); TestUtil::ExpectAllFieldsSet(message2); } #endif // !PROTOBUF_TEST_NO_DESCRIPTORS TEST(GENERATED_MESSAGE_TEST_NAME, NonEmptyMergeFrom) { // Test merging with a non-empty message. Code is a modified form // of that found in net/proto2/internal/reflection_ops_unittest.cc. UNITTEST::TestAllTypes message1, message2; TestUtil::SetAllFields(&message1); // This field will test merging into an empty spot. message2.set_optional_int32(message1.optional_int32()); message1.clear_optional_int32(); // This tests overwriting. message2.set_optional_string(message1.optional_string()); message1.set_optional_string("something else"); // This tests concatenating. message2.add_repeated_int32(message1.repeated_int32(1)); int32_t i = message1.repeated_int32(0); message1.clear_repeated_int32(); message1.add_repeated_int32(i); message1.MergeFrom(message2); TestUtil::ExpectAllFieldsSet(message1); } // Test the generated SerializeWithCachedSizesToArray(), TEST(GENERATED_MESSAGE_TEST_NAME, SerializationToArray) { UNITTEST::TestAllTypes message1, message2; std::string data; TestUtil::SetAllFields(&message1); int size = message1.ByteSizeLong(); data.resize(size); uint8_t* start = reinterpret_cast(::google::protobuf::string_as_array(&data)); uint8_t* end = message1.SerializeWithCachedSizesToArray(start); EXPECT_EQ(size, end - start); EXPECT_TRUE(message2.ParseFromString(data)); TestUtil::ExpectAllFieldsSet(message2); } TEST(GENERATED_MESSAGE_TEST_NAME, PackedFieldsSerializationToArray) { UNITTEST::TestPackedTypes packed_message1, packed_message2; std::string packed_data; TestUtil::SetPackedFields(&packed_message1); int packed_size = packed_message1.ByteSizeLong(); packed_data.resize(packed_size); uint8_t* start = reinterpret_cast(::google::protobuf::string_as_array(&packed_data)); uint8_t* end = packed_message1.SerializeWithCachedSizesToArray(start); EXPECT_EQ(packed_size, end - start); EXPECT_TRUE(packed_message2.ParseFromString(packed_data)); TestUtil::ExpectPackedFieldsSet(packed_message2); } // Test the generated SerializeWithCachedSizes() by forcing the buffer to write // one byte at a time. TEST(GENERATED_MESSAGE_TEST_NAME, SerializationToStream) { UNITTEST::TestAllTypes message1, message2; TestUtil::SetAllFields(&message1); int size = message1.ByteSizeLong(); std::string data; data.resize(size); { // Allow the output stream to buffer only one byte at a time. io::ArrayOutputStream array_stream(::google::protobuf::string_as_array(&data), size, 1); io::CodedOutputStream output_stream(&array_stream); message1.SerializeWithCachedSizes(&output_stream); EXPECT_FALSE(output_stream.HadError()); EXPECT_EQ(size, output_stream.ByteCount()); } EXPECT_TRUE(message2.ParseFromString(data)); TestUtil::ExpectAllFieldsSet(message2); } TEST(GENERATED_MESSAGE_TEST_NAME, PackedFieldsSerializationToStream) { UNITTEST::TestPackedTypes message1, message2; TestUtil::SetPackedFields(&message1); int size = message1.ByteSizeLong(); std::string data; data.resize(size); { // Allow the output stream to buffer only one byte at a time. io::ArrayOutputStream array_stream(::google::protobuf::string_as_array(&data), size, 1); io::CodedOutputStream output_stream(&array_stream); message1.SerializeWithCachedSizes(&output_stream); EXPECT_FALSE(output_stream.HadError()); EXPECT_EQ(size, output_stream.ByteCount()); } EXPECT_TRUE(message2.ParseFromString(data)); TestUtil::ExpectPackedFieldsSet(message2); } TEST(GENERATED_MESSAGE_TEST_NAME, Required) { // Test that IsInitialized() returns false if required fields are missing. UNITTEST::TestRequired message; EXPECT_FALSE(message.IsInitialized()); message.set_a(1); EXPECT_FALSE(message.IsInitialized()); message.set_b(2); EXPECT_FALSE(message.IsInitialized()); message.set_c(3); EXPECT_TRUE(message.IsInitialized()); } TEST(GENERATED_MESSAGE_TEST_NAME, RequiredForeign) { // Test that IsInitialized() returns false if required fields in nested // messages are missing. UNITTEST::TestRequiredForeign message; EXPECT_TRUE(message.IsInitialized()); message.mutable_optional_message(); EXPECT_FALSE(message.IsInitialized()); message.mutable_optional_message()->set_a(1); message.mutable_optional_message()->set_b(2); message.mutable_optional_message()->set_c(3); EXPECT_TRUE(message.IsInitialized()); message.add_repeated_message(); EXPECT_FALSE(message.IsInitialized()); message.mutable_repeated_message(0)->set_a(1); message.mutable_repeated_message(0)->set_b(2); message.mutable_repeated_message(0)->set_c(3); EXPECT_TRUE(message.IsInitialized()); } TEST(GENERATED_MESSAGE_TEST_NAME, ForeignNested) { // Test that TestAllTypes::NestedMessage can be embedded directly into // another message. UNITTEST::TestForeignNested message; // If this compiles and runs without crashing, it must work. We have // nothing more to test. UNITTEST::TestAllTypes::NestedMessage* nested = message.mutable_foreign_nested(); nested->set_bb(1); } TEST(GENERATED_MESSAGE_TEST_NAME, ReallyLargeTagNumber) { // Test that really large tag numbers don't break anything. UNITTEST::TestReallyLargeTagNumber message1, message2; std::string data; // For the most part, if this compiles and runs then we're probably good. // (The most likely cause for failure would be if something were attempting // to allocate a lookup table of some sort using tag numbers as the index.) // We'll try serializing just for fun. message1.set_a(1234); message1.set_bb(5678); message1.SerializeToString(&data); EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(1234, message2.a()); EXPECT_EQ(5678, message2.bb()); } TEST(GENERATED_MESSAGE_TEST_NAME, MutualRecursion) { // Test that mutually-recursive message types work. UNITTEST::TestMutualRecursionA message; UNITTEST::TestMutualRecursionA* nested = message.mutable_bb()->mutable_a(); UNITTEST::TestMutualRecursionA* nested2 = nested->mutable_bb()->mutable_a(); // Again, if the above compiles and runs, that's all we really have to // test, but just for run we'll check that the system didn't somehow come // up with a pointer loop... EXPECT_NE(&message, nested); EXPECT_NE(&message, nested2); EXPECT_NE(nested, nested2); } TEST(GENERATED_MESSAGE_TEST_NAME, CamelCaseFieldNames) { // This test is mainly checking that the following compiles, which verifies // that the field names were coerced to lower-case. // // Protocol buffers standard style is to use lowercase-with-underscores for // field names. Some old proto1 .protos unfortunately used camel-case field // names. In proto1, these names were forced to lower-case. So, we do the // same thing in proto2. UNITTEST::TestCamelCaseFieldNames message; message.set_primitivefield(2); message.set_stringfield("foo"); message.set_enumfield(UNITTEST::FOREIGN_FOO); message.mutable_messagefield()->set_c(6); message.add_repeatedprimitivefield(8); message.add_repeatedstringfield("qux"); message.add_repeatedenumfield(UNITTEST::FOREIGN_BAR); message.add_repeatedmessagefield()->set_c(15); EXPECT_EQ(2, message.primitivefield()); EXPECT_EQ("foo", message.stringfield()); EXPECT_EQ(UNITTEST::FOREIGN_FOO, message.enumfield()); EXPECT_EQ(6, message.messagefield().c()); EXPECT_EQ(8, message.repeatedprimitivefield(0)); EXPECT_EQ("qux", message.repeatedstringfield(0)); EXPECT_EQ(UNITTEST::FOREIGN_BAR, message.repeatedenumfield(0)); EXPECT_EQ(15, message.repeatedmessagefield(0).c()); } #ifndef PROTOBUF_TEST_NO_DESCRIPTORS TEST(GENERATED_MESSAGE_TEST_NAME, TestOptimizedForSize) { // We rely on the tests in reflection_ops_unittest and wire_format_unittest // to really test that reflection-based methods work. Here we are mostly // just making sure that TestOptimizedForSize actually builds and seems to // function. UNITTEST::TestOptimizedForSize message, message2; message.set_i(1); message.mutable_msg()->set_c(2); message2.CopyFrom(message); EXPECT_EQ(1, message2.i()); EXPECT_EQ(2, message2.msg().c()); } TEST(GENERATED_MESSAGE_TEST_NAME, TestEmbedOptimizedForSize) { // Verifies that something optimized for speed can contain something optimized // for size. UNITTEST::TestEmbedOptimizedForSize message, message2; message.mutable_optional_message()->set_i(1); message.add_repeated_message()->mutable_msg()->set_c(2); std::string data; message.SerializeToString(&data); ASSERT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(1, message2.optional_message().i()); EXPECT_EQ(2, message2.repeated_message(0).msg().c()); } TEST(GENERATED_MESSAGE_TEST_NAME, TestSpaceUsed) { UNITTEST::TestAllTypes message1; // sizeof provides a lower bound on SpaceUsedLong(). EXPECT_LE(sizeof(UNITTEST::TestAllTypes), message1.SpaceUsedLong()); const size_t empty_message_size = message1.SpaceUsedLong(); // Setting primitive types shouldn't affect the space used. message1.set_optional_int32(123); message1.set_optional_int64(12345); message1.set_optional_uint32(123); message1.set_optional_uint64(12345); EXPECT_EQ(empty_message_size, message1.SpaceUsedLong()); // On some STL implementations, setting the string to a small value should // only increase SpaceUsedLong() by the size of a string object, though this // is not true everywhere. message1.set_optional_string("abc"); EXPECT_LE(empty_message_size + message1.optional_string().size(), message1.SpaceUsedLong()); // Setting a string to a value larger than the string object itself should // increase SpaceUsedLong(), because it cannot store the value internally. message1.set_optional_string(std::string(sizeof(std::string) + 1, 'x')); int min_expected_increase = message1.optional_string().capacity(); EXPECT_LE(empty_message_size + min_expected_increase, message1.SpaceUsedLong()); size_t previous_size = message1.SpaceUsedLong(); // Adding an optional message should increase the size by the size of the // nested message type. NestedMessage is simple enough (1 int field) that it // is equal to sizeof(NestedMessage) message1.mutable_optional_nested_message(); ASSERT_EQ(sizeof(UNITTEST::TestAllTypes::NestedMessage), message1.optional_nested_message().SpaceUsedLong()); EXPECT_EQ(previous_size + sizeof(UNITTEST::TestAllTypes::NestedMessage), message1.SpaceUsedLong()); } TEST(GENERATED_MESSAGE_TEST_NAME, TestOneofSpaceUsed) { UNITTEST::TestOneof2 message1; EXPECT_LE(sizeof(UNITTEST::TestOneof2), message1.SpaceUsedLong()); const size_t empty_message_size = message1.SpaceUsedLong(); // Setting primitive types shouldn't affect the space used. message1.set_foo_int(123); message1.set_bar_int(12345); EXPECT_EQ(empty_message_size, message1.SpaceUsedLong()); // Setting a string in oneof to a small value should only increase // SpaceUsedLong() by the size of a string object. message1.set_foo_string("abc"); EXPECT_LE(empty_message_size + sizeof(std::string), message1.SpaceUsedLong()); // Setting a string in oneof to a value larger than the string object itself // should increase SpaceUsedLong(), because it cannot store the value // internally. message1.set_foo_string(std::string(sizeof(std::string) + 1, 'x')); int min_expected_increase = message1.foo_string().capacity() + sizeof(std::string); EXPECT_LE(empty_message_size + min_expected_increase, message1.SpaceUsedLong()); // Setting a message in oneof should delete the other fields and increase the // size by the size of the nested message type. NestedMessage is simple enough // that it is equal to sizeof(NestedMessage). It may be backed by LazyField, // increasing space used by LazyField and backing Cord. message1.mutable_foo_message(); ASSERT_EQ(sizeof(UNITTEST::TestOneof2::NestedMessage), message1.foo_message().SpaceUsedLong()); EXPECT_LE(empty_message_size + sizeof(UNITTEST::TestOneof2::NestedMessage), message1.SpaceUsedLong()); } #endif // !PROTOBUF_TEST_NO_DESCRIPTORS TEST(GENERATED_MESSAGE_TEST_NAME, FieldConstantValues) { UNITTEST::TestRequired message; EXPECT_EQ(UNITTEST::TestAllTypes_NestedMessage::kBbFieldNumber, 1); EXPECT_EQ(UNITTEST::TestAllTypes::kOptionalInt32FieldNumber, 1); EXPECT_EQ(UNITTEST::TestAllTypes::kOptionalgroupFieldNumber, 16); EXPECT_EQ(UNITTEST::TestAllTypes::kOptionalNestedMessageFieldNumber, 18); EXPECT_EQ(UNITTEST::TestAllTypes::kOptionalNestedEnumFieldNumber, 21); EXPECT_EQ(UNITTEST::TestAllTypes::kRepeatedInt32FieldNumber, 31); EXPECT_EQ(UNITTEST::TestAllTypes::kRepeatedgroupFieldNumber, 46); EXPECT_EQ(UNITTEST::TestAllTypes::kRepeatedNestedMessageFieldNumber, 48); EXPECT_EQ(UNITTEST::TestAllTypes::kRepeatedNestedEnumFieldNumber, 51); } TEST(GENERATED_MESSAGE_TEST_NAME, ExtensionConstantValues) { EXPECT_EQ(UNITTEST::TestRequired::kSingleFieldNumber, 1000); EXPECT_EQ(UNITTEST::TestRequired::kMultiFieldNumber, 1001); EXPECT_EQ(UNITTEST::kOptionalInt32ExtensionFieldNumber, 1); EXPECT_EQ(UNITTEST::kOptionalgroupExtensionFieldNumber, 16); EXPECT_EQ(UNITTEST::kOptionalNestedMessageExtensionFieldNumber, 18); EXPECT_EQ(UNITTEST::kOptionalNestedEnumExtensionFieldNumber, 21); EXPECT_EQ(UNITTEST::kRepeatedInt32ExtensionFieldNumber, 31); EXPECT_EQ(UNITTEST::kRepeatedgroupExtensionFieldNumber, 46); EXPECT_EQ(UNITTEST::kRepeatedNestedMessageExtensionFieldNumber, 48); EXPECT_EQ(UNITTEST::kRepeatedNestedEnumExtensionFieldNumber, 51); } TEST(GENERATED_MESSAGE_TEST_NAME, ParseFromTruncated) { const std::string long_string = std::string(128, 'q'); FileDescriptorProto p; p.add_extension()->set_name(long_string); const std::string msg = p.SerializeAsString(); int successful_count = 0; for (int i = 0; i <= msg.size(); i++) { if (p.ParseFromArray(msg.c_str(), i)) { ++successful_count; } } // We don't really care about how often we succeeded. // As long as we didn't crash, we're happy. EXPECT_GE(successful_count, 1); } // =================================================================== TEST(GENERATED_ENUM_TEST_NAME, EnumValuesAsSwitchCases) { // Test that our nested enum values can be used as switch cases. This test // doesn't actually do anything, the proof that it works is that it // compiles. int i =0; UNITTEST::TestAllTypes::NestedEnum a = UNITTEST::TestAllTypes::BAR; switch (a) { case UNITTEST::TestAllTypes::FOO: i = 1; break; case UNITTEST::TestAllTypes::BAR: i = 2; break; case UNITTEST::TestAllTypes::BAZ: i = 3; break; case UNITTEST::TestAllTypes::NEG: i = -1; break; // no default case: We want to make sure the compiler recognizes that // all cases are covered. (GCC warns if you do not cover all cases of // an enum in a switch.) } // Token check just for fun. EXPECT_EQ(2, i); } TEST(GENERATED_ENUM_TEST_NAME, IsValidValue) { // Test enum IsValidValue. EXPECT_TRUE(UNITTEST::TestAllTypes::NestedEnum_IsValid(1)); EXPECT_TRUE(UNITTEST::TestAllTypes::NestedEnum_IsValid(2)); EXPECT_TRUE(UNITTEST::TestAllTypes::NestedEnum_IsValid(3)); EXPECT_FALSE(UNITTEST::TestAllTypes::NestedEnum_IsValid(0)); EXPECT_FALSE(UNITTEST::TestAllTypes::NestedEnum_IsValid(4)); // Make sure it also works when there are dups. EXPECT_TRUE(UNITTEST::TestEnumWithDupValue_IsValid(1)); EXPECT_TRUE(UNITTEST::TestEnumWithDupValue_IsValid(2)); EXPECT_TRUE(UNITTEST::TestEnumWithDupValue_IsValid(3)); EXPECT_FALSE(UNITTEST::TestEnumWithDupValue_IsValid(0)); EXPECT_FALSE(UNITTEST::TestEnumWithDupValue_IsValid(4)); } TEST(GENERATED_ENUM_TEST_NAME, MinAndMax) { EXPECT_EQ(UNITTEST::TestAllTypes::NEG, UNITTEST::TestAllTypes::NestedEnum_MIN); EXPECT_EQ(UNITTEST::TestAllTypes::BAZ, UNITTEST::TestAllTypes::NestedEnum_MAX); EXPECT_EQ(4, UNITTEST::TestAllTypes::NestedEnum_ARRAYSIZE); EXPECT_EQ(UNITTEST::FOREIGN_FOO, UNITTEST::ForeignEnum_MIN); EXPECT_EQ(UNITTEST::FOREIGN_BAZ, UNITTEST::ForeignEnum_MAX); EXPECT_EQ(7, UNITTEST::ForeignEnum_ARRAYSIZE); EXPECT_EQ(1, UNITTEST::TestEnumWithDupValue_MIN); EXPECT_EQ(3, UNITTEST::TestEnumWithDupValue_MAX); EXPECT_EQ(4, UNITTEST::TestEnumWithDupValue_ARRAYSIZE); EXPECT_EQ(UNITTEST::SPARSE_E, UNITTEST::TestSparseEnum_MIN); EXPECT_EQ(UNITTEST::SPARSE_C, UNITTEST::TestSparseEnum_MAX); EXPECT_EQ(12589235, UNITTEST::TestSparseEnum_ARRAYSIZE); // Make sure we can take the address of _MIN, _MAX and _ARRAYSIZE. void* null_pointer = 0; // NULL may be integer-type, not pointer-type. EXPECT_NE(null_pointer, &UNITTEST::TestAllTypes::NestedEnum_MIN); EXPECT_NE(null_pointer, &UNITTEST::TestAllTypes::NestedEnum_MAX); EXPECT_NE(null_pointer, &UNITTEST::TestAllTypes::NestedEnum_ARRAYSIZE); EXPECT_NE(null_pointer, &UNITTEST::ForeignEnum_MIN); EXPECT_NE(null_pointer, &UNITTEST::ForeignEnum_MAX); EXPECT_NE(null_pointer, &UNITTEST::ForeignEnum_ARRAYSIZE); // Make sure we can use _MIN and _MAX as switch cases. switch (UNITTEST::SPARSE_A) { case UNITTEST::TestSparseEnum_MIN: case UNITTEST::TestSparseEnum_MAX: break; default: break; } } #ifndef PROTOBUF_TEST_NO_DESCRIPTORS TEST(GENERATED_ENUM_TEST_NAME, Name) { // "Names" in the presence of dup values map to the first alias. EXPECT_EQ("FOO1", UNITTEST::TestEnumWithDupValue_Name(UNITTEST::FOO1)); EXPECT_EQ("FOO1", UNITTEST::TestEnumWithDupValue_Name(UNITTEST::FOO2)); EXPECT_EQ("SPARSE_A", UNITTEST::TestSparseEnum_Name(UNITTEST::SPARSE_A)); EXPECT_EQ("SPARSE_B", UNITTEST::TestSparseEnum_Name(UNITTEST::SPARSE_B)); EXPECT_EQ("SPARSE_C", UNITTEST::TestSparseEnum_Name(UNITTEST::SPARSE_C)); EXPECT_EQ("SPARSE_D", UNITTEST::TestSparseEnum_Name(UNITTEST::SPARSE_D)); EXPECT_EQ("SPARSE_E", UNITTEST::TestSparseEnum_Name(UNITTEST::SPARSE_E)); EXPECT_EQ("SPARSE_F", UNITTEST::TestSparseEnum_Name(UNITTEST::SPARSE_F)); EXPECT_EQ("SPARSE_G", UNITTEST::TestSparseEnum_Name(UNITTEST::SPARSE_G)); } TEST(GENERATED_ENUM_TEST_NAME, Parse) { UNITTEST::TestEnumWithDupValue dup_value = UNITTEST::FOO1; EXPECT_TRUE(UNITTEST::TestEnumWithDupValue_Parse("FOO1", &dup_value)); EXPECT_EQ(UNITTEST::FOO1, dup_value); EXPECT_TRUE(UNITTEST::TestEnumWithDupValue_Parse("FOO2", &dup_value)); EXPECT_EQ(UNITTEST::FOO2, dup_value); EXPECT_FALSE(UNITTEST::TestEnumWithDupValue_Parse("FOO", &dup_value)); } TEST(GENERATED_ENUM_TEST_NAME, GetEnumDescriptor) { EXPECT_EQ(UNITTEST::TestAllTypes::NestedEnum_descriptor(), GetEnumDescriptor()); EXPECT_EQ(UNITTEST::ForeignEnum_descriptor(), GetEnumDescriptor()); EXPECT_EQ(UNITTEST::TestEnumWithDupValue_descriptor(), GetEnumDescriptor()); EXPECT_EQ(UNITTEST::TestSparseEnum_descriptor(), GetEnumDescriptor()); } enum NonProtoEnum { kFoo = 1, }; TEST(GENERATED_ENUM_TEST_NAME, IsProtoEnumTypeTrait) { EXPECT_TRUE(is_proto_enum::value); EXPECT_TRUE(is_proto_enum::value); EXPECT_TRUE(is_proto_enum::value); EXPECT_TRUE(is_proto_enum::value); EXPECT_FALSE(is_proto_enum::value); EXPECT_FALSE(is_proto_enum::value); } #endif // PROTOBUF_TEST_NO_DESCRIPTORS // =================================================================== #ifndef PROTOBUF_TEST_NO_DESCRIPTORS // Support code for testing services. class GENERATED_SERVICE_TEST_NAME : public testing::Test { protected: class MockTestService : public UNITTEST::TestService { public: MockTestService() : called_(false), method_(""), controller_(NULL), request_(NULL), response_(NULL), done_(NULL) {} ~MockTestService() {} void Reset() { called_ = false; } // implements TestService ---------------------------------------- void Foo(RpcController* controller, const UNITTEST::FooRequest* request, UNITTEST::FooResponse* response, Closure* done) override { ASSERT_FALSE(called_); called_ = true; method_ = "Foo"; controller_ = controller; request_ = request; response_ = response; done_ = done; } void Bar(RpcController* controller, const UNITTEST::BarRequest* request, UNITTEST::BarResponse* response, Closure* done) override { ASSERT_FALSE(called_); called_ = true; method_ = "Bar"; controller_ = controller; request_ = request; response_ = response; done_ = done; } // --------------------------------------------------------------- bool called_; std::string method_; RpcController* controller_; const Message* request_; Message* response_; Closure* done_; }; class MockRpcChannel : public RpcChannel { public: MockRpcChannel() : called_(false), method_(NULL), controller_(NULL), request_(NULL), response_(NULL), done_(NULL), destroyed_(NULL) {} ~MockRpcChannel() { if (destroyed_ != NULL) *destroyed_ = true; } void Reset() { called_ = false; } // implements TestService ---------------------------------------- void CallMethod(const MethodDescriptor* method, RpcController* controller, const Message* request, Message* response, Closure* done) override { ASSERT_FALSE(called_); called_ = true; method_ = method; controller_ = controller; request_ = request; response_ = response; done_ = done; } // --------------------------------------------------------------- bool called_; const MethodDescriptor* method_; RpcController* controller_; const Message* request_; Message* response_; Closure* done_; bool* destroyed_; }; class MockController : public RpcController { public: void Reset() override { ADD_FAILURE() << "Reset() not expected during this test."; } bool Failed() const override { ADD_FAILURE() << "Failed() not expected during this test."; return false; } std::string ErrorText() const override { ADD_FAILURE() << "ErrorText() not expected during this test."; return ""; } void StartCancel() override { ADD_FAILURE() << "StartCancel() not expected during this test."; } void SetFailed(const std::string& reason) override { ADD_FAILURE() << "SetFailed() not expected during this test."; } bool IsCanceled() const override { ADD_FAILURE() << "IsCanceled() not expected during this test."; return false; } void NotifyOnCancel(Closure* callback) override { ADD_FAILURE() << "NotifyOnCancel() not expected during this test."; } }; GENERATED_SERVICE_TEST_NAME() : descriptor_(UNITTEST::TestService::descriptor()), foo_(descriptor_->FindMethodByName("Foo")), bar_(descriptor_->FindMethodByName("Bar")), stub_(&mock_channel_), done_(::google::protobuf::NewPermanentCallback(&DoNothing)) {} void SetUp() override { ASSERT_TRUE(foo_ != NULL); ASSERT_TRUE(bar_ != NULL); } const ServiceDescriptor* descriptor_; const MethodDescriptor* foo_; const MethodDescriptor* bar_; MockTestService mock_service_; MockController mock_controller_; MockRpcChannel mock_channel_; UNITTEST::TestService::Stub stub_; // Just so we don't have to re-define these with every test. UNITTEST::FooRequest foo_request_; UNITTEST::FooResponse foo_response_; UNITTEST::BarRequest bar_request_; UNITTEST::BarResponse bar_response_; std::unique_ptr done_; }; TEST_F(GENERATED_SERVICE_TEST_NAME, GetDescriptor) { // Test that GetDescriptor() works. EXPECT_EQ(descriptor_, mock_service_.GetDescriptor()); } TEST_F(GENERATED_SERVICE_TEST_NAME, GetChannel) { EXPECT_EQ(&mock_channel_, stub_.channel()); } TEST_F(GENERATED_SERVICE_TEST_NAME, OwnsChannel) { MockRpcChannel* channel = new MockRpcChannel; bool destroyed = false; channel->destroyed_ = &destroyed; { UNITTEST::TestService::Stub owning_stub(channel, Service::STUB_OWNS_CHANNEL); EXPECT_FALSE(destroyed); } EXPECT_TRUE(destroyed); } TEST_F(GENERATED_SERVICE_TEST_NAME, CallMethod) { // Test that CallMethod() works. // Call Foo() via CallMethod(). mock_service_.CallMethod(foo_, &mock_controller_, &foo_request_, &foo_response_, done_.get()); ASSERT_TRUE(mock_service_.called_); EXPECT_EQ("Foo" , mock_service_.method_ ); EXPECT_EQ(&mock_controller_, mock_service_.controller_); EXPECT_EQ(&foo_request_ , mock_service_.request_ ); EXPECT_EQ(&foo_response_ , mock_service_.response_ ); EXPECT_EQ(done_.get() , mock_service_.done_ ); // Try again, but call Bar() instead. mock_service_.Reset(); mock_service_.CallMethod(bar_, &mock_controller_, &bar_request_, &bar_response_, done_.get()); ASSERT_TRUE(mock_service_.called_); EXPECT_EQ("Bar", mock_service_.method_); } TEST_F(GENERATED_SERVICE_TEST_NAME, CallMethodTypeFailure) { // Verify death if we call Foo() with Bar's message types. #ifdef PROTOBUF_HAS_DEATH_TEST // death tests do not work on Windows yet EXPECT_DEBUG_DEATH( mock_service_.CallMethod(foo_, &mock_controller_, &foo_request_, &bar_response_, done_.get()), "dynamic_cast"); mock_service_.Reset(); EXPECT_DEBUG_DEATH( mock_service_.CallMethod(foo_, &mock_controller_, &bar_request_, &foo_response_, done_.get()), "dynamic_cast"); #endif // PROTOBUF_HAS_DEATH_TEST } TEST_F(GENERATED_SERVICE_TEST_NAME, GetPrototypes) { // Test Get{Request,Response}Prototype() methods. EXPECT_EQ(&UNITTEST::FooRequest::default_instance(), &mock_service_.GetRequestPrototype(foo_)); EXPECT_EQ(&UNITTEST::BarRequest::default_instance(), &mock_service_.GetRequestPrototype(bar_)); EXPECT_EQ(&UNITTEST::FooResponse::default_instance(), &mock_service_.GetResponsePrototype(foo_)); EXPECT_EQ(&UNITTEST::BarResponse::default_instance(), &mock_service_.GetResponsePrototype(bar_)); } TEST_F(GENERATED_SERVICE_TEST_NAME, Stub) { // Test that the stub class works. // Call Foo() via the stub. stub_.Foo(&mock_controller_, &foo_request_, &foo_response_, done_.get()); ASSERT_TRUE(mock_channel_.called_); EXPECT_EQ(foo_ , mock_channel_.method_ ); EXPECT_EQ(&mock_controller_, mock_channel_.controller_); EXPECT_EQ(&foo_request_ , mock_channel_.request_ ); EXPECT_EQ(&foo_response_ , mock_channel_.response_ ); EXPECT_EQ(done_.get() , mock_channel_.done_ ); // Call Bar() via the stub. mock_channel_.Reset(); stub_.Bar(&mock_controller_, &bar_request_, &bar_response_, done_.get()); ASSERT_TRUE(mock_channel_.called_); EXPECT_EQ(bar_, mock_channel_.method_); } TEST_F(GENERATED_SERVICE_TEST_NAME, NotImplemented) { // Test that failing to implement a method of a service causes it to fail // with a "not implemented" error message. // A service which doesn't implement any methods. class UnimplementedService : public UNITTEST::TestService { public: UnimplementedService() {} }; UnimplementedService unimplemented_service; // And a controller which expects to get a "not implemented" error. class ExpectUnimplementedController : public MockController { public: ExpectUnimplementedController() : called_(false) {} void SetFailed(const std::string& reason) override { EXPECT_FALSE(called_); called_ = true; EXPECT_EQ("Method Foo() not implemented.", reason); } bool called_; }; ExpectUnimplementedController controller; // Call Foo. unimplemented_service.Foo(&controller, &foo_request_, &foo_response_, done_.get()); EXPECT_TRUE(controller.called_); } // =================================================================== class OneofTest : public testing::Test { protected: void SetUp() override {} void ExpectEnumCasesWork(const UNITTEST::TestOneof2 &message) { switch (message.foo_case()) { case UNITTEST::TestOneof2::kFooInt: EXPECT_TRUE(message.has_foo_int()); break; case UNITTEST::TestOneof2::kFooString: EXPECT_TRUE(message.has_foo_string()); break; case UNITTEST::TestOneof2::kFooCord: EXPECT_TRUE(message.has_foo_cord()); break; case UNITTEST::TestOneof2::kFooStringPiece: EXPECT_TRUE(message.has_foo_string_piece()); break; case UNITTEST::TestOneof2::kFooBytes: EXPECT_TRUE(message.has_foo_bytes()); break; case UNITTEST::TestOneof2::kFooEnum: EXPECT_TRUE(message.has_foo_enum()); break; case UNITTEST::TestOneof2::kFooMessage: EXPECT_TRUE(message.has_foo_message()); break; case UNITTEST::TestOneof2::kFoogroup: EXPECT_TRUE(message.has_foogroup()); break; case UNITTEST::TestOneof2::kFooLazyMessage: EXPECT_TRUE(message.has_foo_lazy_message()); break; case UNITTEST::TestOneof2::FOO_NOT_SET: break; } } }; TEST_F(OneofTest, SettingOneFieldClearsOthers) { UNITTEST::TestOneof2 message; message.set_foo_int(123); EXPECT_TRUE(message.has_foo_int()); TestUtil::ExpectAtMostOneFieldSetInOneof(message); message.set_foo_string("foo"); EXPECT_TRUE(message.has_foo_string()); TestUtil::ExpectAtMostOneFieldSetInOneof(message); message.set_foo_bytes("qux"); EXPECT_TRUE(message.has_foo_bytes()); TestUtil::ExpectAtMostOneFieldSetInOneof(message); message.set_foo_enum(UNITTEST::TestOneof2::FOO); EXPECT_TRUE(message.has_foo_enum()); TestUtil::ExpectAtMostOneFieldSetInOneof(message); message.mutable_foo_message()->set_qux_int(234); EXPECT_TRUE(message.has_foo_message()); TestUtil::ExpectAtMostOneFieldSetInOneof(message); message.mutable_foogroup()->set_a(345); EXPECT_TRUE(message.has_foogroup()); TestUtil::ExpectAtMostOneFieldSetInOneof(message); // we repeat this because we didn't test if this properly clears other fields // at the beginning. message.set_foo_int(123); EXPECT_TRUE(message.has_foo_int()); TestUtil::ExpectAtMostOneFieldSetInOneof(message); } TEST_F(OneofTest, EnumCases) { UNITTEST::TestOneof2 message; message.set_foo_int(123); ExpectEnumCasesWork(message); message.set_foo_string("foo"); ExpectEnumCasesWork(message); message.set_foo_bytes("qux"); ExpectEnumCasesWork(message); message.set_foo_enum(UNITTEST::TestOneof2::FOO); ExpectEnumCasesWork(message); message.mutable_foo_message()->set_qux_int(234); ExpectEnumCasesWork(message); message.mutable_foogroup()->set_a(345); ExpectEnumCasesWork(message); } TEST_F(OneofTest, PrimitiveType) { UNITTEST::TestOneof2 message; // Unset field returns default value EXPECT_EQ(message.foo_int(), 0); message.set_foo_int(123); EXPECT_TRUE(message.has_foo_int()); EXPECT_EQ(message.foo_int(), 123); message.clear_foo_int(); EXPECT_FALSE(message.has_foo_int()); } TEST_F(OneofTest, EnumType) { UNITTEST::TestOneof2 message; // Unset field returns default value EXPECT_EQ(message.foo_enum(), 1); message.set_foo_enum(UNITTEST::TestOneof2::FOO); EXPECT_TRUE(message.has_foo_enum()); EXPECT_EQ(message.foo_enum(), UNITTEST::TestOneof2::FOO); message.clear_foo_enum(); EXPECT_FALSE(message.has_foo_enum()); } TEST_F(OneofTest, SetString) { // Check that setting a string field in various ways works UNITTEST::TestOneof2 message; // Unset field returns default value EXPECT_EQ(message.foo_string(), ""); message.set_foo_string("foo"); EXPECT_TRUE(message.has_foo_string()); EXPECT_EQ(message.foo_string(), "foo"); message.clear_foo_string(); EXPECT_FALSE(message.has_foo_string()); message.set_foo_string(std::string("bar")); EXPECT_TRUE(message.has_foo_string()); EXPECT_EQ(message.foo_string(), "bar"); message.clear_foo_string(); EXPECT_FALSE(message.has_foo_string()); message.set_foo_string("qux", 3); EXPECT_TRUE(message.has_foo_string()); EXPECT_EQ(message.foo_string(), "qux"); message.clear_foo_string(); EXPECT_FALSE(message.has_foo_string()); message.mutable_foo_string()->assign("quux"); EXPECT_TRUE(message.has_foo_string()); EXPECT_EQ(message.foo_string(), "quux"); message.clear_foo_string(); EXPECT_FALSE(message.has_foo_string()); message.set_foo_string("corge"); EXPECT_TRUE(message.has_foo_string()); EXPECT_EQ(message.foo_string(), "corge"); message.clear_foo_string(); EXPECT_FALSE(message.has_foo_string()); } TEST_F(OneofTest, ReleaseString) { // Check that release_foo() starts out NULL, and gives us a value // that we can delete after it's been set. UNITTEST::TestOneof2 message; EXPECT_EQ(NULL, message.release_foo_string()); EXPECT_FALSE(message.has_foo_string()); message.set_foo_string("blah"); EXPECT_TRUE(message.has_foo_string()); std::unique_ptr str(message.release_foo_string()); EXPECT_FALSE(message.has_foo_string()); ASSERT_TRUE(str != NULL); EXPECT_EQ("blah", *str); EXPECT_EQ(NULL, message.release_foo_string()); EXPECT_FALSE(message.has_foo_string()); } TEST_F(OneofTest, SetAllocatedString) { // Check that set_allocated_foo() works for strings. UNITTEST::TestOneof2 message; EXPECT_FALSE(message.has_foo_string()); const std::string kHello("hello"); message.set_foo_string(kHello); EXPECT_TRUE(message.has_foo_string()); message.set_allocated_foo_string(NULL); EXPECT_FALSE(message.has_foo_string()); EXPECT_EQ("", message.foo_string()); message.set_allocated_foo_string(new std::string(kHello)); EXPECT_TRUE(message.has_foo_string()); EXPECT_EQ(kHello, message.foo_string()); } TEST_F(OneofTest, ArenaSetAllocatedString) { // Check that set_allocated_foo() works for strings. Arena arena; UNITTEST::TestOneof2* message = Arena::CreateMessage(&arena); EXPECT_FALSE(message->has_foo_string()); const std::string kHello("hello"); message->set_foo_string(kHello); EXPECT_TRUE(message->has_foo_string()); message->set_allocated_foo_string(NULL); EXPECT_FALSE(message->has_foo_string()); EXPECT_EQ("", message->foo_string()); message->set_allocated_foo_string(new std::string(kHello)); EXPECT_TRUE(message->has_foo_string()); EXPECT_EQ(kHello, message->foo_string()); } TEST_F(OneofTest, SetMessage) { // Check that setting a message field works UNITTEST::TestOneof2 message; // Unset field returns default instance EXPECT_EQ(&message.foo_message(), &UNITTEST::TestOneof2_NestedMessage::default_instance()); EXPECT_EQ(message.foo_message().qux_int(), 0); message.mutable_foo_message()->set_qux_int(234); EXPECT_TRUE(message.has_foo_message()); EXPECT_EQ(message.foo_message().qux_int(), 234); message.clear_foo_message(); EXPECT_FALSE(message.has_foo_message()); } TEST_F(OneofTest, ReleaseMessage) { // Check that release_foo() starts out NULL, and gives us a value // that we can delete after it's been set. UNITTEST::TestOneof2 message; EXPECT_EQ(NULL, message.release_foo_message()); EXPECT_FALSE(message.has_foo_message()); message.mutable_foo_message()->set_qux_int(1); EXPECT_TRUE(message.has_foo_message()); std::unique_ptr mes( message.release_foo_message()); EXPECT_FALSE(message.has_foo_message()); ASSERT_TRUE(mes != NULL); EXPECT_EQ(1, mes->qux_int()); EXPECT_EQ(NULL, message.release_foo_message()); EXPECT_FALSE(message.has_foo_message()); } TEST_F(OneofTest, SetAllocatedMessage) { // Check that set_allocated_foo() works for messages. UNITTEST::TestOneof2 message; EXPECT_FALSE(message.has_foo_message()); message.mutable_foo_message()->set_qux_int(1); EXPECT_TRUE(message.has_foo_message()); message.set_allocated_foo_message(NULL); EXPECT_FALSE(message.has_foo_message()); EXPECT_EQ(&message.foo_message(), &UNITTEST::TestOneof2_NestedMessage::default_instance()); message.mutable_foo_message()->set_qux_int(1); UNITTEST::TestOneof2_NestedMessage* mes = message.release_foo_message(); ASSERT_TRUE(mes != NULL); EXPECT_FALSE(message.has_foo_message()); message.set_allocated_foo_message(mes); EXPECT_TRUE(message.has_foo_message()); EXPECT_EQ(1, message.foo_message().qux_int()); } TEST_F(OneofTest, Clear) { UNITTEST::TestOneof2 message; message.set_foo_int(1); EXPECT_TRUE(message.has_foo_int()); message.clear_foo_int(); EXPECT_FALSE(message.has_foo_int()); } TEST_F(OneofTest, Defaults) { UNITTEST::TestOneof2 message; EXPECT_FALSE(message.has_foo_int()); EXPECT_EQ(message.foo_int(), 0); EXPECT_FALSE(message.has_foo_string()); EXPECT_EQ(message.foo_string(), ""); EXPECT_FALSE(message.has_foo_bytes()); EXPECT_EQ(message.foo_bytes(), ""); EXPECT_FALSE(message.has_foo_enum()); EXPECT_EQ(message.foo_enum(), 1); EXPECT_FALSE(message.has_foo_message()); EXPECT_EQ(message.foo_message().qux_int(), 0); EXPECT_FALSE(message.has_foogroup()); EXPECT_EQ(message.foogroup().a(), 0); EXPECT_FALSE(message.has_bar_int()); EXPECT_EQ(message.bar_int(), 5); EXPECT_FALSE(message.has_bar_string()); EXPECT_EQ(message.bar_string(), "STRING"); EXPECT_FALSE(message.has_bar_bytes()); EXPECT_EQ(message.bar_bytes(), "BYTES"); EXPECT_FALSE(message.has_bar_enum()); EXPECT_EQ(message.bar_enum(), 2); } TEST_F(OneofTest, SwapWithEmpty) { UNITTEST::TestOneof2 message1, message2; message1.set_foo_string("FOO"); EXPECT_TRUE(message1.has_foo_string()); message1.Swap(&message2); EXPECT_FALSE(message1.has_foo_string()); EXPECT_TRUE(message2.has_foo_string()); EXPECT_EQ(message2.foo_string(), "FOO"); } TEST_F(OneofTest, SwapWithSelf) { UNITTEST::TestOneof2 message; message.set_foo_string("FOO"); EXPECT_TRUE(message.has_foo_string()); message.Swap(&message); EXPECT_TRUE(message.has_foo_string()); EXPECT_EQ(message.foo_string(), "FOO"); } TEST_F(OneofTest, SwapBothHasFields) { UNITTEST::TestOneof2 message1, message2; message1.set_foo_string("FOO"); EXPECT_TRUE(message1.has_foo_string()); message2.mutable_foo_message()->set_qux_int(1); EXPECT_TRUE(message2.has_foo_message()); message1.Swap(&message2); EXPECT_FALSE(message1.has_foo_string()); EXPECT_FALSE(message2.has_foo_message()); EXPECT_TRUE(message1.has_foo_message()); EXPECT_EQ(message1.foo_message().qux_int(), 1); EXPECT_TRUE(message2.has_foo_string()); EXPECT_EQ(message2.foo_string(), "FOO"); } TEST_F(OneofTest, CopyConstructor) { UNITTEST::TestOneof2 message1; message1.set_foo_bytes("FOO"); UNITTEST::TestOneof2 message2(message1); EXPECT_TRUE(message2.has_foo_bytes()); EXPECT_EQ(message2.foo_bytes(), "FOO"); } TEST_F(OneofTest, CopyFrom) { UNITTEST::TestOneof2 message1, message2; message1.set_foo_enum(UNITTEST::TestOneof2::BAR); EXPECT_TRUE(message1.has_foo_enum()); message2.CopyFrom(message1); EXPECT_TRUE(message2.has_foo_enum()); EXPECT_EQ(message2.foo_enum(), UNITTEST::TestOneof2::BAR); // Copying from self should be a no-op. message2.CopyFrom(message2); EXPECT_TRUE(message2.has_foo_enum()); EXPECT_EQ(message2.foo_enum(), UNITTEST::TestOneof2::BAR); } TEST_F(OneofTest, CopyAssignmentOperator) { UNITTEST::TestOneof2 message1; message1.mutable_foo_message()->set_qux_int(123); EXPECT_TRUE(message1.has_foo_message()); UNITTEST::TestOneof2 message2; message2 = message1; EXPECT_EQ(message2.foo_message().qux_int(), 123); // Make sure that self-assignment does something sane. message2 = *&message2; // Avoid -Wself-assign. EXPECT_EQ(message2.foo_message().qux_int(), 123); } TEST_F(OneofTest, UpcastCopyFrom) { // Test the CopyFrom method that takes in the generic const Message& // parameter. UNITTEST::TestOneof2 message1, message2; message1.mutable_foogroup()->set_a(123); EXPECT_TRUE(message1.has_foogroup()); const Message* source = implicit_cast(&message1); message2.CopyFrom(*source); EXPECT_TRUE(message2.has_foogroup()); EXPECT_EQ(message2.foogroup().a(), 123); } // Test the generated SerializeWithCachedSizesToArray(), // This indirectly tests MergePartialFromCodedStream() // We have to test each field type separately because we cannot set them at the // same time TEST_F(OneofTest, SerializationToArray) { // Primitive type { UNITTEST::TestOneof2 message1, message2; std::string data; message1.set_foo_int(123); int size = message1.ByteSizeLong(); data.resize(size); uint8_t* start = reinterpret_cast(::google::protobuf::string_as_array(&data)); uint8_t* end = message1.SerializeWithCachedSizesToArray(start); EXPECT_EQ(size, end - start); EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foo_int(), 123); } // String { UNITTEST::TestOneof2 message1, message2; std::string data; message1.set_foo_string("foo"); int size = message1.ByteSizeLong(); data.resize(size); uint8_t* start = reinterpret_cast(::google::protobuf::string_as_array(&data)); uint8_t* end = message1.SerializeWithCachedSizesToArray(start); EXPECT_EQ(size, end - start); EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foo_string(), "foo"); } // Bytes { UNITTEST::TestOneof2 message1, message2; std::string data; message1.set_foo_bytes("qux"); int size = message1.ByteSizeLong(); data.resize(size); uint8_t* start = reinterpret_cast(::google::protobuf::string_as_array(&data)); uint8_t* end = message1.SerializeWithCachedSizesToArray(start); EXPECT_EQ(size, end - start); EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foo_bytes(), "qux"); } // Enum { UNITTEST::TestOneof2 message1, message2; std::string data; message1.set_foo_enum(UNITTEST::TestOneof2::FOO); int size = message1.ByteSizeLong(); data.resize(size); uint8_t* start = reinterpret_cast(::google::protobuf::string_as_array(&data)); uint8_t* end = message1.SerializeWithCachedSizesToArray(start); EXPECT_EQ(size, end - start); EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foo_enum(), UNITTEST::TestOneof2::FOO); } // Message { UNITTEST::TestOneof2 message1, message2; std::string data; message1.mutable_foo_message()->set_qux_int(234); int size = message1.ByteSizeLong(); data.resize(size); uint8_t* start = reinterpret_cast(::google::protobuf::string_as_array(&data)); uint8_t* end = message1.SerializeWithCachedSizesToArray(start); EXPECT_EQ(size, end - start); EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foo_message().qux_int(), 234); } // Group { UNITTEST::TestOneof2 message1, message2; std::string data; message1.mutable_foogroup()->set_a(345); int size = message1.ByteSizeLong(); data.resize(size); uint8_t* start = reinterpret_cast(::google::protobuf::string_as_array(&data)); uint8_t* end = message1.SerializeWithCachedSizesToArray(start); EXPECT_EQ(size, end - start); EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foogroup().a(), 345); } } // Test the generated SerializeWithCachedSizes() by forcing the buffer to write // one byte at a time. // This indirectly tests MergePartialFromCodedStream() // We have to test each field type separately because we cannot set them at the // same time TEST_F(OneofTest, SerializationToStream) { // Primitive type { UNITTEST::TestOneof2 message1, message2; std::string data; message1.set_foo_int(123); int size = message1.ByteSizeLong(); data.resize(size); { // Allow the output stream to buffer only one byte at a time. io::ArrayOutputStream array_stream(::google::protobuf::string_as_array(&data), size, 1); io::CodedOutputStream output_stream(&array_stream); message1.SerializeWithCachedSizes(&output_stream); EXPECT_FALSE(output_stream.HadError()); EXPECT_EQ(size, output_stream.ByteCount()); } EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foo_int(), 123); } // String { UNITTEST::TestOneof2 message1, message2; std::string data; message1.set_foo_string("foo"); int size = message1.ByteSizeLong(); data.resize(size); { // Allow the output stream to buffer only one byte at a time. io::ArrayOutputStream array_stream(::google::protobuf::string_as_array(&data), size, 1); io::CodedOutputStream output_stream(&array_stream); message1.SerializeWithCachedSizes(&output_stream); EXPECT_FALSE(output_stream.HadError()); EXPECT_EQ(size, output_stream.ByteCount()); } EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foo_string(), "foo"); } // Bytes { UNITTEST::TestOneof2 message1, message2; std::string data; message1.set_foo_bytes("qux"); int size = message1.ByteSizeLong(); data.resize(size); { // Allow the output stream to buffer only one byte at a time. io::ArrayOutputStream array_stream(::google::protobuf::string_as_array(&data), size, 1); io::CodedOutputStream output_stream(&array_stream); message1.SerializeWithCachedSizes(&output_stream); EXPECT_FALSE(output_stream.HadError()); EXPECT_EQ(size, output_stream.ByteCount()); } EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foo_bytes(), "qux"); } // Enum { UNITTEST::TestOneof2 message1, message2; std::string data; message1.set_foo_enum(UNITTEST::TestOneof2::FOO); int size = message1.ByteSizeLong(); data.resize(size); { // Allow the output stream to buffer only one byte at a time. io::ArrayOutputStream array_stream(::google::protobuf::string_as_array(&data), size, 1); io::CodedOutputStream output_stream(&array_stream); message1.SerializeWithCachedSizes(&output_stream); EXPECT_FALSE(output_stream.HadError()); EXPECT_EQ(size, output_stream.ByteCount()); } EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foo_enum(), UNITTEST::TestOneof2::FOO); } // Message { UNITTEST::TestOneof2 message1, message2; std::string data; message1.mutable_foo_message()->set_qux_int(234); int size = message1.ByteSizeLong(); data.resize(size); { // Allow the output stream to buffer only one byte at a time. io::ArrayOutputStream array_stream(::google::protobuf::string_as_array(&data), size, 1); io::CodedOutputStream output_stream(&array_stream); message1.SerializeWithCachedSizes(&output_stream); EXPECT_FALSE(output_stream.HadError()); EXPECT_EQ(size, output_stream.ByteCount()); } EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foo_message().qux_int(), 234); } // Group { UNITTEST::TestOneof2 message1, message2; std::string data; message1.mutable_foogroup()->set_a(345); int size = message1.ByteSizeLong(); data.resize(size); { // Allow the output stream to buffer only one byte at a time. io::ArrayOutputStream array_stream(::google::protobuf::string_as_array(&data), size, 1); io::CodedOutputStream output_stream(&array_stream); message1.SerializeWithCachedSizes(&output_stream); EXPECT_FALSE(output_stream.HadError()); EXPECT_EQ(size, output_stream.ByteCount()); } EXPECT_TRUE(message2.ParseFromString(data)); EXPECT_EQ(message2.foogroup().a(), 345); } } TEST_F(OneofTest, MergeFrom) { UNITTEST::TestOneof2 message1, message2; message1.set_foo_int(123); message2.MergeFrom(message1); TestUtil::ExpectAtMostOneFieldSetInOneof(message2); EXPECT_TRUE(message2.has_foo_int()); EXPECT_EQ(message2.foo_int(), 123); message1.set_foo_string("foo"); message2.MergeFrom(message1); TestUtil::ExpectAtMostOneFieldSetInOneof(message2); EXPECT_TRUE(message2.has_foo_string()); EXPECT_EQ(message2.foo_string(), "foo"); message1.set_foo_bytes("qux"); message2.MergeFrom(message1); TestUtil::ExpectAtMostOneFieldSetInOneof(message2); EXPECT_TRUE(message2.has_foo_bytes()); EXPECT_EQ(message2.foo_bytes(), "qux"); message1.set_foo_enum(UNITTEST::TestOneof2::FOO); message2.MergeFrom(message1); TestUtil::ExpectAtMostOneFieldSetInOneof(message2); EXPECT_TRUE(message2.has_foo_enum()); EXPECT_EQ(message2.foo_enum(), UNITTEST::TestOneof2::FOO); message1.mutable_foo_message()->set_qux_int(234); message2.MergeFrom(message1); TestUtil::ExpectAtMostOneFieldSetInOneof(message2); EXPECT_TRUE(message2.has_foo_message()); EXPECT_EQ(message2.foo_message().qux_int(), 234); message1.mutable_foogroup()->set_a(345); message2.MergeFrom(message1); TestUtil::ExpectAtMostOneFieldSetInOneof(message2); EXPECT_TRUE(message2.has_foogroup()); EXPECT_EQ(message2.foogroup().a(), 345); } TEST(HELPERS_TEST_NAME, TestSCC) { UNITTEST::TestMutualRecursionA a; MessageSCCAnalyzer scc_analyzer((Options())); const SCC* scc = scc_analyzer.GetSCC(a.GetDescriptor()); std::vector names; names.reserve(scc->descriptors.size()); for (int i = 0; i < scc->descriptors.size(); i++) { names.push_back(scc->descriptors[i]->full_name()); } std::string package = a.GetDescriptor()->file()->package(); ASSERT_EQ(names.size(), 4); std::sort(names.begin(), names.end()); EXPECT_EQ(names[0], package + ".TestMutualRecursionA"); EXPECT_EQ(names[1], package + ".TestMutualRecursionA.SubGroup"); EXPECT_EQ(names[2], package + ".TestMutualRecursionA.SubMessage"); EXPECT_EQ(names[3], package + ".TestMutualRecursionB"); MessageAnalysis result = scc_analyzer.GetSCCAnalysis(scc); EXPECT_EQ(result.is_recursive, true); EXPECT_EQ(result.contains_required, false); EXPECT_EQ(result.contains_cord, true); // TestAllTypes EXPECT_EQ(result.contains_extension, false); // TestAllTypes } TEST(HELPERS_TEST_NAME, TestSCCAnalysis) { { UNITTEST::TestRecursiveMessage msg; MessageSCCAnalyzer scc_analyzer((Options())); const SCC* scc = scc_analyzer.GetSCC(msg.GetDescriptor()); MessageAnalysis result = scc_analyzer.GetSCCAnalysis(scc); EXPECT_EQ(result.is_recursive, true); EXPECT_EQ(result.contains_required, false); EXPECT_EQ(result.contains_cord, false); EXPECT_EQ(result.contains_extension, false); } { UNITTEST::TestAllExtensions msg; MessageSCCAnalyzer scc_analyzer((Options())); const SCC* scc = scc_analyzer.GetSCC(msg.GetDescriptor()); MessageAnalysis result = scc_analyzer.GetSCCAnalysis(scc); EXPECT_EQ(result.is_recursive, false); EXPECT_EQ(result.contains_required, false); EXPECT_EQ(result.contains_cord, false); EXPECT_EQ(result.contains_extension, true); } { UNITTEST::TestRequired msg; MessageSCCAnalyzer scc_analyzer((Options())); const SCC* scc = scc_analyzer.GetSCC(msg.GetDescriptor()); MessageAnalysis result = scc_analyzer.GetSCCAnalysis(scc); EXPECT_EQ(result.is_recursive, false); EXPECT_EQ(result.contains_required, true); EXPECT_EQ(result.contains_cord, false); EXPECT_EQ(result.contains_extension, false); } } } // namespace cpp_unittest } // namespace cpp } // namespace compiler namespace no_generic_services_test { // Verify that no class called "TestService" was defined in // unittest_no_generic_services.pb.h by defining a different type by the same // name. If such a service was generated, this will not compile. struct TestService { int i; }; } namespace compiler { namespace cpp { namespace cpp_unittest { TEST_F(GENERATED_SERVICE_TEST_NAME, NoGenericServices) { // Verify that non-services in unittest_no_generic_services.proto were // generated. ::protobuf_unittest::no_generic_services_test::TestMessage message; message.set_a(1); message.SetExtension( ::protobuf_unittest::no_generic_services_test::test_extension, 123); ::protobuf_unittest::no_generic_services_test::TestEnum e = ::protobuf_unittest::no_generic_services_test::FOO; EXPECT_EQ(e, 1); // Verify that a ServiceDescriptor is generated for the service even if the // class itself is not. const FileDescriptor* file = ::google::protobuf::unittest::no_generic_services_test::TestMessage::descriptor() ->file(); ASSERT_EQ(1, file->service_count()); EXPECT_EQ("TestService", file->service(0)->name()); ASSERT_EQ(1, file->service(0)->method_count()); EXPECT_EQ("Foo", file->service(0)->method(0)->name()); } #endif // !PROTOBUF_TEST_NO_DESCRIPTORS // =================================================================== // This test must run last. It verifies that descriptors were or were not // initialized depending on whether PROTOBUF_TEST_NO_DESCRIPTORS was defined. // When this is defined, we skip all tests which are expected to trigger // descriptor initialization. This verifies that everything else still works // if descriptors are not initialized. TEST(DESCRIPTOR_INIT_TEST_NAME, Initialized) { #ifdef PROTOBUF_TEST_NO_DESCRIPTORS bool should_have_descriptors = false; #else bool should_have_descriptors = true; #endif EXPECT_EQ(should_have_descriptors, DescriptorPool::generated_pool()->InternalIsFileLoaded( TestUtil::MaybeTranslatePath(UNITTEST_PROTO_PATH))); } } // namespace cpp_unittest } // namespace cpp } // namespace compiler } // namespace protobuf } // namespace google #include