#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace { using testing::DoAll; using testing::Return; using testing::StrEq; ACTION_TEMPLATE(AssignReadVal, HAS_1_TEMPLATE_PARAMS(typename, T), AND_1_VALUE_PARAMS(val)) { *static_cast(arg2) = val; } class ReadTest : public testing::Test { protected: testing::StrictMock mock; void SetUp() override { EXPECT_CALL(mock, sd_bus_message_new_method_call(testing::_, testing::_, nullptr, nullptr, nullptr, nullptr)) .WillRepeatedly(Return(0)); }; sdbusplus::message_t new_message() { return sdbusplus::get_mocked_new(&mock).new_method_call( nullptr, nullptr, nullptr, nullptr); } void expect_basic_error(char type, int ret) { EXPECT_CALL(mock, sd_bus_message_read_basic(nullptr, type, testing::_)) .WillOnce(Return(ret)); } template void expect_basic(char type, T val) { EXPECT_CALL(mock, sd_bus_message_read_basic(nullptr, type, testing::_)) .WillOnce(DoAll(AssignReadVal(val), Return(0))); } void expect_verify_type(char type, const char* contents, int ret) { EXPECT_CALL(mock, sd_bus_message_verify_type(nullptr, type, StrEq(contents))) .WillOnce(Return(ret)); } void expect_at_end(bool complete, int ret) { EXPECT_CALL(mock, sd_bus_message_at_end(nullptr, complete)) .WillOnce(Return(ret)); } void expect_skip(const char* contents, int ret = 0) { EXPECT_CALL(mock, sd_bus_message_skip(nullptr, StrEq(contents))) .WillOnce(Return(ret)); } void expect_enter_container(char type, const char* contents, int ret = 0) { EXPECT_CALL(mock, sd_bus_message_enter_container(nullptr, type, StrEq(contents))) .WillOnce(Return(ret)); } void expect_exit_container(int ret = 0) { EXPECT_CALL(mock, sd_bus_message_exit_container(nullptr)) .WillOnce(Return(ret)); } }; TEST_F(ReadTest, Int) { const int i = 1; expect_basic(SD_BUS_TYPE_INT32, i); int ret; new_message().read(ret); EXPECT_EQ(i, ret); } TEST_F(ReadTest, Bool) { const bool b = true; expect_basic(SD_BUS_TYPE_BOOLEAN, b); bool ret; new_message().read(ret); EXPECT_EQ(b, ret); } TEST_F(ReadTest, Double) { const double d = 1.1; expect_basic(SD_BUS_TYPE_DOUBLE, d); double ret; new_message().read(ret); EXPECT_EQ(d, ret); } TEST_F(ReadTest, CString) { const char* const s = "asdf"; expect_basic(SD_BUS_TYPE_STRING, s); const char* ret; new_message().read(ret); EXPECT_EQ(s, ret); } TEST_F(ReadTest, String) { const char* const s = "fsda"; expect_basic(SD_BUS_TYPE_STRING, s); std::string ret; new_message().read(ret); // Pointer comparison here is intentional as we don't expect a copy EXPECT_EQ(s, ret); } TEST_F(ReadTest, ObjectPath) { const char* const s = "/fsda"; expect_basic(SD_BUS_TYPE_OBJECT_PATH, s); sdbusplus::message::object_path ret; new_message().read(ret); EXPECT_EQ(s, ret.str); } TEST_F(ReadTest, Signature) { const char* const s = "{ii}"; expect_basic(SD_BUS_TYPE_SIGNATURE, s); sdbusplus::message::signature ret; new_message().read(ret); EXPECT_EQ(s, ret.str); } TEST_F(ReadTest, CombinedBasic) { const double a = 2.2; const char* const b = "ijkd"; const bool c = false; const int d = 18; { testing::InSequence seq; expect_basic(SD_BUS_TYPE_DOUBLE, a); expect_basic(SD_BUS_TYPE_STRING, b); expect_basic(SD_BUS_TYPE_BOOLEAN, c); expect_basic(SD_BUS_TYPE_INT32, d); } double ret_a; const char* ret_b; bool ret_c; int ret_d; new_message().read(ret_a, ret_b, ret_c, ret_d); EXPECT_EQ(a, ret_a); EXPECT_EQ(b, ret_b); EXPECT_EQ(c, ret_c); EXPECT_EQ(d, ret_d); } TEST_F(ReadTest, BasicError) { expect_basic_error(SD_BUS_TYPE_INT32, -EINVAL); int ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, BasicStringError) { expect_basic_error(SD_BUS_TYPE_STRING, -EINVAL); std::string ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, BasicStringWrapperError) { expect_basic_error(SD_BUS_TYPE_SIGNATURE, -EINVAL); sdbusplus::message::signature ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, BasicBoolError) { expect_basic_error(SD_BUS_TYPE_BOOLEAN, -EINVAL); bool ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, Vector) { const std::vector vi{1, 2, 3, 4}; { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "i"); for (const auto& i : vi) { expect_at_end(false, 0); expect_basic(SD_BUS_TYPE_INT32, i); } expect_at_end(false, 1); expect_exit_container(); } std::vector ret_vi; new_message().read(ret_vi); EXPECT_EQ(vi, ret_vi); } TEST_F(ReadTest, VectorEnterError) { { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "i", -EINVAL); } std::vector ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, VectorIterError) { { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "i"); expect_at_end(false, 0); expect_basic(SD_BUS_TYPE_INT32, 1); expect_at_end(false, -EINVAL); } std::vector ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, VectorExitError) { { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "i"); expect_at_end(false, 0); expect_basic(SD_BUS_TYPE_INT32, 1); expect_at_end(false, 0); expect_basic(SD_BUS_TYPE_INT32, 2); expect_at_end(false, 1); expect_exit_container(-EINVAL); } std::vector ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, Set) { const std::set ss{"one", "two", "eight"}; { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "s"); for (const auto& s : ss) { expect_at_end(false, 0); expect_basic(SD_BUS_TYPE_STRING, s.c_str()); } expect_at_end(false, 1); expect_exit_container(); } std::set ret_ss; new_message().read(ret_ss); EXPECT_EQ(ss, ret_ss); } TEST_F(ReadTest, UnorderedSet) { const std::unordered_set ss{"one", "two", "eight"}; { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "s"); for (const auto& s : ss) { expect_at_end(false, 0); expect_basic(SD_BUS_TYPE_STRING, s.c_str()); } expect_at_end(false, 1); expect_exit_container(); } std::unordered_set ret_ss; new_message().read(ret_ss); EXPECT_EQ(ss, ret_ss); } TEST_F(ReadTest, Map) { const std::map mis{ {1, "a"}, {2, "bc"}, {3, "def"}, {4, "ghij"}, }; { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "{is}"); for (const auto& is : mis) { expect_at_end(false, 0); expect_enter_container(SD_BUS_TYPE_DICT_ENTRY, "is"); expect_basic(SD_BUS_TYPE_INT32, is.first); expect_basic(SD_BUS_TYPE_STRING, is.second.c_str()); expect_exit_container(); } expect_at_end(false, 1); expect_exit_container(); } std::map ret_mis; new_message().read(ret_mis); EXPECT_EQ(mis, ret_mis); } TEST_F(ReadTest, MapEnterError) { { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "{si}", -EINVAL); } std::map ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, MapEntryEnterError) { { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "{si}"); expect_at_end(false, 0); expect_enter_container(SD_BUS_TYPE_DICT_ENTRY, "si", -EINVAL); } std::map ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, MapEntryExitError) { { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "{si}"); expect_at_end(false, 0); expect_enter_container(SD_BUS_TYPE_DICT_ENTRY, "si"); expect_basic(SD_BUS_TYPE_STRING, "ab"); expect_basic(SD_BUS_TYPE_INT32, 1); expect_exit_container(-EINVAL); } std::map ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, MapIterError) { { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "{si}"); expect_at_end(false, 0); expect_enter_container(SD_BUS_TYPE_DICT_ENTRY, "si"); expect_basic(SD_BUS_TYPE_STRING, "ab"); expect_basic(SD_BUS_TYPE_INT32, 1); expect_exit_container(); expect_at_end(false, -EINVAL); } std::map ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, MapExitError) { { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "{si}"); expect_at_end(false, 0); expect_enter_container(SD_BUS_TYPE_DICT_ENTRY, "si"); expect_basic(SD_BUS_TYPE_STRING, "ab"); expect_basic(SD_BUS_TYPE_INT32, 1); expect_exit_container(); expect_at_end(false, 1); expect_exit_container(-EINVAL); } std::map ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, UnorderedMap) { const std::unordered_map mis{ {1, "a"}, {2, "bc"}, {3, "def"}, {4, "ghij"}, }; { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "{is}"); for (const auto& is : mis) { expect_at_end(false, 0); expect_enter_container(SD_BUS_TYPE_DICT_ENTRY, "is"); expect_basic(SD_BUS_TYPE_INT32, is.first); expect_basic(SD_BUS_TYPE_STRING, is.second.c_str()); expect_exit_container(); } expect_at_end(false, 1); expect_exit_container(); } std::unordered_map ret_mis; new_message().read(ret_mis); EXPECT_EQ(mis, ret_mis); } TEST_F(ReadTest, Tuple) { const std::tuple tisb{3, "hi", false}; { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_STRUCT, "isb"); expect_basic(SD_BUS_TYPE_INT32, std::get<0>(tisb)); expect_basic(SD_BUS_TYPE_STRING, std::get<1>(tisb).c_str()); expect_basic(SD_BUS_TYPE_BOOLEAN, std::get<2>(tisb)); expect_exit_container(); } std::tuple ret_tisb; new_message().read(ret_tisb); EXPECT_EQ(tisb, ret_tisb); } TEST_F(ReadTest, TupleEnterError) { { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_STRUCT, "bis", -EINVAL); } std::tuple ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, TupleExitError) { { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_STRUCT, "bis"); expect_basic(SD_BUS_TYPE_BOOLEAN, false); expect_basic(SD_BUS_TYPE_INT32, 1); expect_basic(SD_BUS_TYPE_STRING, "ab"); expect_exit_container(-EINVAL); } std::tuple ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, Variant) { const bool b1 = false; const std::string s2{"asdf"}; const std::variant v1{b1}, v2{s2}; { testing::InSequence seq; expect_verify_type(SD_BUS_TYPE_VARIANT, "i", false); expect_verify_type(SD_BUS_TYPE_VARIANT, "s", false); expect_verify_type(SD_BUS_TYPE_VARIANT, "b", true); expect_enter_container(SD_BUS_TYPE_VARIANT, "b"); expect_basic(SD_BUS_TYPE_BOOLEAN, b1); expect_exit_container(); expect_verify_type(SD_BUS_TYPE_VARIANT, "i", false); expect_verify_type(SD_BUS_TYPE_VARIANT, "s", true); expect_enter_container(SD_BUS_TYPE_VARIANT, "s"); expect_basic(SD_BUS_TYPE_STRING, s2.c_str()); expect_exit_container(); } std::variant ret_v1, ret_v2; new_message().read(ret_v1, ret_v2); EXPECT_EQ(v1, ret_v1); EXPECT_EQ(v2, ret_v2); } TEST_F(ReadTest, VariantVerifyError) { { testing::InSequence seq; expect_verify_type(SD_BUS_TYPE_VARIANT, "i", -EINVAL); } std::variant ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, VariantSkipUnmatched) { { testing::InSequence seq; expect_verify_type(SD_BUS_TYPE_VARIANT, "i", false); expect_verify_type(SD_BUS_TYPE_VARIANT, "b", false); expect_skip("v"); } std::variant ret; new_message().read(ret); } TEST_F(ReadTest, VariantSkipError) { { testing::InSequence seq; expect_verify_type(SD_BUS_TYPE_VARIANT, "i", false); expect_verify_type(SD_BUS_TYPE_VARIANT, "b", false); expect_skip("v", -EINVAL); } std::variant ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, VariantEnterError) { { testing::InSequence seq; expect_verify_type(SD_BUS_TYPE_VARIANT, "i", true); expect_enter_container(SD_BUS_TYPE_VARIANT, "i", -EINVAL); } std::variant ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, VariantExitError) { { testing::InSequence seq; expect_verify_type(SD_BUS_TYPE_VARIANT, "i", true); expect_enter_container(SD_BUS_TYPE_VARIANT, "i"); expect_basic(SD_BUS_TYPE_INT32, 10); expect_exit_container(-EINVAL); } std::variant ret; EXPECT_THROW(new_message().read(ret), sdbusplus::exception::SdBusError); } TEST_F(ReadTest, LargeCombo) { const std::vector> vas{ {"a", "b", "c"}, {"d", "", "e"}, }; const std::map> msv = { {"a", 3.3}, {"b", 1}, {"c", 4.4}}; { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "as"); for (const auto& as : vas) { expect_at_end(false, 0); expect_enter_container(SD_BUS_TYPE_ARRAY, "s"); for (const auto& s : as) { expect_at_end(false, 0); expect_basic(SD_BUS_TYPE_STRING, s.c_str()); } expect_at_end(false, 1); expect_exit_container(); } expect_at_end(false, 1); expect_exit_container(); expect_enter_container(SD_BUS_TYPE_ARRAY, "{sv}"); for (const auto& sv : msv) { expect_at_end(false, 0); expect_enter_container(SD_BUS_TYPE_DICT_ENTRY, "sv"); expect_basic(SD_BUS_TYPE_STRING, sv.first.c_str()); if (std::holds_alternative(sv.second)) { expect_verify_type(SD_BUS_TYPE_VARIANT, "i", true); expect_enter_container(SD_BUS_TYPE_VARIANT, "i"); expect_basic(SD_BUS_TYPE_INT32, std::get(sv.second)); expect_exit_container(); } else { expect_verify_type(SD_BUS_TYPE_VARIANT, "i", false); expect_verify_type(SD_BUS_TYPE_VARIANT, "d", true); expect_enter_container(SD_BUS_TYPE_VARIANT, "d"); expect_basic(SD_BUS_TYPE_DOUBLE, std::get(sv.second)); expect_exit_container(); } expect_exit_container(); } expect_at_end(false, 1); expect_exit_container(); } std::vector> ret_vas; std::map> ret_msv; new_message().read(ret_vas, ret_msv); EXPECT_EQ(vas, ret_vas); EXPECT_EQ(msv, ret_msv); } // Unpack tests. // Since unpack uses read, we're mostly just testing the compilation. // Duplicate a few tests from Read using 'unpack'. TEST_F(ReadTest, UnpackSingleVector) { const std::vector vi{1, 2, 3, 4}; { testing::InSequence seq; expect_enter_container(SD_BUS_TYPE_ARRAY, "i"); for (const auto& i : vi) { expect_at_end(false, 0); expect_basic(SD_BUS_TYPE_INT32, i); } expect_at_end(false, 1); expect_exit_container(); } auto ret_vi = new_message().unpack>(); EXPECT_EQ(vi, ret_vi); } TEST_F(ReadTest, UnpackMultiple) { const std::tuple tisb{3, "hi", false}; { testing::InSequence seq; expect_basic(SD_BUS_TYPE_INT32, std::get<0>(tisb)); expect_basic(SD_BUS_TYPE_STRING, std::get<1>(tisb).c_str()); expect_basic(SD_BUS_TYPE_BOOLEAN, std::get<2>(tisb)); } auto ret_tisb = new_message().unpack(); EXPECT_EQ(tisb, ret_tisb); } } // namespace