// 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. // // This file needs to be included as .inc as it depends on certain macros being // defined prior to its inclusion. #include #include #include #include #ifndef _MSC_VER #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace google { namespace protobuf { #if defined(_WIN32) // DO NOT include , instead create functions in io_win32.{h,cc} and import // them like we do below. using google::protobuf::internal::win32::close; using google::protobuf::internal::win32::open; #endif #ifndef O_BINARY #ifdef _O_BINARY #define O_BINARY _O_BINARY #else #define O_BINARY 0 // If this isn't defined, the platform doesn't need it. #endif #endif TEST(MESSAGE_TEST_NAME, SerializeHelpers) { // TODO(kenton): Test more helpers? They're all two-liners so it seems // like a waste of time. UNITTEST::TestAllTypes message; TestUtil::SetAllFields(&message); std::stringstream stream; string str1("foo"); string str2("bar"); EXPECT_TRUE(message.SerializeToString(&str1)); EXPECT_TRUE(message.AppendToString(&str2)); EXPECT_TRUE(message.SerializeToOstream(&stream)); EXPECT_EQ(str1.size() + 3, str2.size()); EXPECT_EQ("bar", str2.substr(0, 3)); // Don't use EXPECT_EQ because we don't want to dump raw binary data to // stdout. EXPECT_TRUE(str2.substr(3) == str1); // GCC gives some sort of error if we try to just do stream.str() == str1. string temp = stream.str(); EXPECT_TRUE(temp == str1); EXPECT_TRUE(message.SerializeAsString() == str1); } TEST(MESSAGE_TEST_NAME, SerializeToBrokenOstream) { std::ofstream out; UNITTEST::TestAllTypes message; message.set_optional_int32(123); EXPECT_FALSE(message.SerializeToOstream(&out)); } TEST(MESSAGE_TEST_NAME, ParseFromFileDescriptor) { string filename = TestSourceDir() + "/google/protobuf/testdata/golden_message"; int file = open(filename.c_str(), O_RDONLY | O_BINARY); ASSERT_GE(file, 0); UNITTEST::TestAllTypes message; EXPECT_TRUE(message.ParseFromFileDescriptor(file)); TestUtil::ExpectAllFieldsSet(message); EXPECT_GE(close(file), 0); } TEST(MESSAGE_TEST_NAME, ParsePackedFromFileDescriptor) { string filename = TestSourceDir() + "/google/protobuf/testdata/golden_packed_fields_message"; int file = open(filename.c_str(), O_RDONLY | O_BINARY); ASSERT_GE(file, 0); UNITTEST::TestPackedTypes message; EXPECT_TRUE(message.ParseFromFileDescriptor(file)); TestUtil::ExpectPackedFieldsSet(message); EXPECT_GE(close(file), 0); } TEST(MESSAGE_TEST_NAME, ParseHelpers) { // TODO(kenton): Test more helpers? They're all two-liners so it seems // like a waste of time. string data; { // Set up. UNITTEST::TestAllTypes message; TestUtil::SetAllFields(&message); message.SerializeToString(&data); } { // Test ParseFromString. UNITTEST::TestAllTypes message; EXPECT_TRUE(message.ParseFromString(data)); TestUtil::ExpectAllFieldsSet(message); } { // Test ParseFromIstream. UNITTEST::TestAllTypes message; std::stringstream stream(data); EXPECT_TRUE(message.ParseFromIstream(&stream)); EXPECT_TRUE(stream.eof()); TestUtil::ExpectAllFieldsSet(message); } { // Test ParseFromBoundedZeroCopyStream. string data_with_junk(data); data_with_junk.append("some junk on the end"); io::ArrayInputStream stream(data_with_junk.data(), data_with_junk.size()); UNITTEST::TestAllTypes message; EXPECT_TRUE(message.ParseFromBoundedZeroCopyStream(&stream, data.size())); TestUtil::ExpectAllFieldsSet(message); } { // Test that ParseFromBoundedZeroCopyStream fails (but doesn't crash) if // EOF is reached before the expected number of bytes. io::ArrayInputStream stream(data.data(), data.size()); UNITTEST::TestAllTypes message; EXPECT_FALSE( message.ParseFromBoundedZeroCopyStream(&stream, data.size() + 1)); } } TEST(MESSAGE_TEST_NAME, ParseFailsIfNotInitialized) { UNITTEST::TestRequired message; std::vector errors; { ScopedMemoryLog log; EXPECT_FALSE(message.ParseFromString("")); errors = log.GetMessages(ERROR); } ASSERT_EQ(1, errors.size()); EXPECT_EQ( "Can't parse message of type \"" + string(UNITTEST_PACKAGE_NAME) + ".TestRequired\" because it is missing required fields: a, b, c", errors[0]); } TEST(MESSAGE_TEST_NAME, BypassInitializationCheckOnParse) { UNITTEST::TestRequired message; io::ArrayInputStream raw_input(nullptr, 0); io::CodedInputStream input(&raw_input); EXPECT_TRUE(message.MergePartialFromCodedStream(&input)); } TEST(MESSAGE_TEST_NAME, InitializationErrorString) { UNITTEST::TestRequired message; EXPECT_EQ("a, b, c", message.InitializationErrorString()); } TEST(MESSAGE_TEST_NAME, DynamicCastToGenerated) { UNITTEST::TestAllTypes test_all_types; google::protobuf::Message* test_all_types_pointer = &test_all_types; EXPECT_EQ(&test_all_types, google::protobuf::internal::DynamicCastToGenerated( test_all_types_pointer)); EXPECT_EQ(nullptr, google::protobuf::internal::DynamicCastToGenerated( test_all_types_pointer)); const google::protobuf::Message* test_all_types_pointer_const = &test_all_types; EXPECT_EQ( &test_all_types, google::protobuf::internal::DynamicCastToGenerated( test_all_types_pointer_const)); EXPECT_EQ( nullptr, google::protobuf::internal::DynamicCastToGenerated( test_all_types_pointer_const)); } #ifdef PROTOBUF_HAS_DEATH_TEST // death tests do not work on Windows yet. TEST(MESSAGE_TEST_NAME, SerializeFailsIfNotInitialized) { UNITTEST::TestRequired message; string data; EXPECT_DEBUG_DEATH(EXPECT_TRUE(message.SerializeToString(&data)), "Can't serialize message of type \"" + string(UNITTEST_PACKAGE_NAME) + ".TestRequired\" because " "it is missing required fields: a, b, c"); } TEST(MESSAGE_TEST_NAME, CheckInitialized) { UNITTEST::TestRequired message; EXPECT_DEATH(message.CheckInitialized(), "Message of type \"" + string(UNITTEST_PACKAGE_NAME) + ".TestRequired\" is missing required " "fields: a, b, c"); } #endif // PROTOBUF_HAS_DEATH_TEST namespace { // An input stream that repeats a string's content for a number of times. It // helps us create a really large input without consuming too much memory. Used // to test the parsing behavior when the input size exceeds 2G or close to it. class RepeatedInputStream : public io::ZeroCopyInputStream { public: RepeatedInputStream(const string& data, size_t count) : data_(data), count_(count), position_(0), total_byte_count_(0) {} virtual bool Next(const void** data, int* size) { if (position_ == data_.size()) { if (--count_ == 0) { return false; } position_ = 0; } *data = &data_[position_]; *size = static_cast(data_.size() - position_); position_ = data_.size(); total_byte_count_ += *size; return true; } virtual void BackUp(int count) { position_ -= static_cast(count); total_byte_count_ -= count; } virtual bool Skip(int count) { while (count > 0) { const void* data; int size; if (!Next(&data, &size)) { break; } if (size >= count) { BackUp(size - count); return true; } else { count -= size; } } return false; } virtual int64 ByteCount() const { return total_byte_count_; } private: string data_; size_t count_; // The number of strings that haven't been consuemd. size_t position_; // Position in the string for the next read. int64 total_byte_count_; }; } // namespace TEST(MESSAGE_TEST_NAME, TestParseMessagesCloseTo2G) { // Create a message with a large string field. string value = string(64 * 1024 * 1024, 'x'); UNITTEST::TestAllTypes message; message.set_optional_string(value); // Repeat this message in the input stream to make the total input size // close to 2G. string data = message.SerializeAsString(); size_t count = static_cast(kint32max) / data.size(); RepeatedInputStream input(data, count); // The parsing should succeed. UNITTEST::TestAllTypes result; EXPECT_TRUE(result.ParseFromZeroCopyStream(&input)); // When there are multiple occurences of a singulr field, the last one // should win. EXPECT_EQ(value, result.optional_string()); } TEST(MESSAGE_TEST_NAME, TestParseMessagesOver2G) { // Create a message with a large string field. string value = string(64 * 1024 * 1024, 'x'); UNITTEST::TestAllTypes message; message.set_optional_string(value); // Repeat this message in the input stream to make the total input size // larger than 2G. string data = message.SerializeAsString(); size_t count = static_cast(kint32max) / data.size() + 1; RepeatedInputStream input(data, count); // The parsing should fail. UNITTEST::TestAllTypes result; EXPECT_FALSE(result.ParseFromZeroCopyStream(&input)); } TEST(MESSAGE_TEST_NAME, BypassInitializationCheckOnSerialize) { UNITTEST::TestRequired message; io::ArrayOutputStream raw_output(nullptr, 0); io::CodedOutputStream output(&raw_output); EXPECT_TRUE(message.SerializePartialToCodedStream(&output)); } TEST(MESSAGE_TEST_NAME, FindInitializationErrors) { UNITTEST::TestRequired message; std::vector errors; message.FindInitializationErrors(&errors); ASSERT_EQ(3, errors.size()); EXPECT_EQ("a", errors[0]); EXPECT_EQ("b", errors[1]); EXPECT_EQ("c", errors[2]); } TEST(MESSAGE_TEST_NAME, ParseFailsOnInvalidMessageEnd) { UNITTEST::TestAllTypes message; // Control case. EXPECT_TRUE(message.ParseFromArray("", 0)); // The byte is a valid varint, but not a valid tag (zero). EXPECT_FALSE(message.ParseFromArray("\0", 1)); // The byte is a malformed varint. EXPECT_FALSE(message.ParseFromArray("\200", 1)); // The byte is an endgroup tag, but we aren't parsing a group. EXPECT_FALSE(message.ParseFromArray("\014", 1)); } // Regression test for b/23630858 TEST(MESSAGE_TEST_NAME, MessageIsStillValidAfterParseFails) { UNITTEST::TestAllTypes message; // 9 0xFFs for the "optional_uint64" field. string invalid_data = "\x20\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF"; EXPECT_FALSE(message.ParseFromString(invalid_data)); message.Clear(); EXPECT_EQ(0, message.optional_uint64()); // invalid data for field "optional_string". Length prefix is 1 but no // payload. string invalid_string_data = "\x72\x01"; { google::protobuf::Arena arena; UNITTEST::TestAllTypes* arena_message = google::protobuf::Arena::CreateMessage(&arena); EXPECT_FALSE(arena_message->ParseFromString(invalid_string_data)); arena_message->Clear(); EXPECT_EQ("", arena_message->optional_string()); } } namespace { void ExpectMessageMerged(const UNITTEST::TestAllTypes& message) { EXPECT_EQ(3, message.optional_int32()); EXPECT_EQ(2, message.optional_int64()); EXPECT_EQ("hello", message.optional_string()); } void AssignParsingMergeMessages(UNITTEST::TestAllTypes* msg1, UNITTEST::TestAllTypes* msg2, UNITTEST::TestAllTypes* msg3) { msg1->set_optional_int32(1); msg2->set_optional_int64(2); msg3->set_optional_int32(3); msg3->set_optional_string("hello"); } } // namespace // Test that if an optional or required message/group field appears multiple // times in the input, they need to be merged. TEST(MESSAGE_TEST_NAME, ParsingMerge) { UNITTEST::TestParsingMerge::RepeatedFieldsGenerator generator; UNITTEST::TestAllTypes* msg1; UNITTEST::TestAllTypes* msg2; UNITTEST::TestAllTypes* msg3; #define ASSIGN_REPEATED_FIELD(FIELD) \ msg1 = generator.add_##FIELD(); \ msg2 = generator.add_##FIELD(); \ msg3 = generator.add_##FIELD(); \ AssignParsingMergeMessages(msg1, msg2, msg3) ASSIGN_REPEATED_FIELD(field1); ASSIGN_REPEATED_FIELD(field2); ASSIGN_REPEATED_FIELD(field3); ASSIGN_REPEATED_FIELD(ext1); ASSIGN_REPEATED_FIELD(ext2); #undef ASSIGN_REPEATED_FIELD #define ASSIGN_REPEATED_GROUP(FIELD) \ msg1 = generator.add_##FIELD()->mutable_field1(); \ msg2 = generator.add_##FIELD()->mutable_field1(); \ msg3 = generator.add_##FIELD()->mutable_field1(); \ AssignParsingMergeMessages(msg1, msg2, msg3) ASSIGN_REPEATED_GROUP(group1); ASSIGN_REPEATED_GROUP(group2); #undef ASSIGN_REPEATED_GROUP string buffer; generator.SerializeToString(&buffer); UNITTEST::TestParsingMerge parsing_merge; parsing_merge.ParseFromString(buffer); // Required and optional fields should be merged. ExpectMessageMerged(parsing_merge.required_all_types()); ExpectMessageMerged(parsing_merge.optional_all_types()); ExpectMessageMerged(parsing_merge.optionalgroup().optional_group_all_types()); ExpectMessageMerged( parsing_merge.GetExtension(UNITTEST::TestParsingMerge::optional_ext)); // Repeated fields should not be merged. EXPECT_EQ(3, parsing_merge.repeated_all_types_size()); EXPECT_EQ(3, parsing_merge.repeatedgroup_size()); EXPECT_EQ( 3, parsing_merge.ExtensionSize(UNITTEST::TestParsingMerge::repeated_ext)); } TEST(MESSAGE_TEST_NAME, MergeFrom) { UNITTEST::TestAllTypes source, dest; // Optional fields source.set_optional_int32(1); // only source source.set_optional_int64(2); // both source and dest dest.set_optional_int64(3); dest.set_optional_uint32(4); // only dest // Optional fields with defaults source.set_default_int32(13); // only source source.set_default_int64(14); // both source and dest dest.set_default_int64(15); dest.set_default_uint32(16); // only dest // Repeated fields source.add_repeated_int32(5); // only source source.add_repeated_int32(6); source.add_repeated_int64(7); // both source and dest source.add_repeated_int64(8); dest.add_repeated_int64(9); dest.add_repeated_int64(10); dest.add_repeated_uint32(11); // only dest dest.add_repeated_uint32(12); dest.MergeFrom(source); // Optional fields: source overwrites dest if source is specified EXPECT_EQ(1, dest.optional_int32()); // only source: use source EXPECT_EQ(2, dest.optional_int64()); // source and dest: use source EXPECT_EQ(4, dest.optional_uint32()); // only dest: use dest EXPECT_EQ(0, dest.optional_uint64()); // neither: use default // Optional fields with defaults EXPECT_EQ(13, dest.default_int32()); // only source: use source EXPECT_EQ(14, dest.default_int64()); // source and dest: use source EXPECT_EQ(16, dest.default_uint32()); // only dest: use dest EXPECT_EQ(44, dest.default_uint64()); // neither: use default // Repeated fields: concatenate source onto the end of dest ASSERT_EQ(2, dest.repeated_int32_size()); EXPECT_EQ(5, dest.repeated_int32(0)); EXPECT_EQ(6, dest.repeated_int32(1)); ASSERT_EQ(4, dest.repeated_int64_size()); EXPECT_EQ(9, dest.repeated_int64(0)); EXPECT_EQ(10, dest.repeated_int64(1)); EXPECT_EQ(7, dest.repeated_int64(2)); EXPECT_EQ(8, dest.repeated_int64(3)); ASSERT_EQ(2, dest.repeated_uint32_size()); EXPECT_EQ(11, dest.repeated_uint32(0)); EXPECT_EQ(12, dest.repeated_uint32(1)); ASSERT_EQ(0, dest.repeated_uint64_size()); } TEST(MESSAGE_TEST_NAME, IsInitialized) { UNITTEST::TestIsInitialized msg; EXPECT_TRUE(msg.IsInitialized()); UNITTEST::TestIsInitialized::SubMessage* sub_message = msg.mutable_sub_message(); EXPECT_TRUE(msg.IsInitialized()); UNITTEST::TestIsInitialized::SubMessage::SubGroup* sub_group = sub_message->mutable_subgroup(); EXPECT_FALSE(msg.IsInitialized()); sub_group->set_i(1); EXPECT_TRUE(msg.IsInitialized()); } TEST(MESSAGE_FACTORY_TEST_NAME, GeneratedFactoryLookup) { EXPECT_EQ(MessageFactory::generated_factory()->GetPrototype( UNITTEST::TestAllTypes::descriptor()), &UNITTEST::TestAllTypes::default_instance()); } TEST(MESSAGE_FACTORY_TEST_NAME, GeneratedFactoryUnknownType) { // Construct a new descriptor. DescriptorPool pool; FileDescriptorProto file; file.set_name("foo.proto"); file.add_message_type()->set_name("Foo"); const Descriptor* descriptor = pool.BuildFile(file)->message_type(0); // Trying to construct it should return nullptr. EXPECT_TRUE(MessageFactory::generated_factory()->GetPrototype(descriptor) == nullptr); } } // namespace protobuf } // namespace google