#include #include #include #include using namespace c10::guts; // NOLINTBEGIN(modernize*) namespace { namespace test_function_traits { static_assert( std::is_same< void, typename function_traits::return_type>::value, ""); static_assert( std::is_same::return_type>:: value, ""); static_assert( std::is_same< typelist::typelist, typename function_traits::parameter_types>::value, ""); static_assert( std::is_same< typelist::typelist, typename function_traits::parameter_types>::value, ""); static_assert( std::is_same< bool, typename make_function_traits_t>:: return_type>::value, ""); static_assert( std::is_same< void, typename make_function_traits_t>:: return_type>::value, ""); static_assert( std::is_same< typelist::typelist, typename make_function_traits_t>:: parameter_types>::value, ""); static_assert( std::is_same< typelist::typelist, typename make_function_traits_t>:: parameter_types>::value, ""); static_assert( std::is_same< bool(int, float), typename make_function_traits_t>:: func_type>::value, ""); static_assert( std::is_same< void(int, float), typename make_function_traits_t>:: func_type>::value, ""); } // namespace test_function_traits struct MovableOnly { constexpr MovableOnly(int val_) : val(val_) { /* no default constructor */ } MovableOnly(const MovableOnly&) = delete; MovableOnly(MovableOnly&&) = default; MovableOnly& operator=(const MovableOnly&) = delete; MovableOnly& operator=(MovableOnly&&) = default; friend bool operator==(const MovableOnly& lhs, const MovableOnly& rhs) { return lhs.val == rhs.val; } private: int val; }; template using is_my_movable_only_class = std::is_same>>; struct CopyCounting { int move_count; int copy_count; CopyCounting() : move_count(0), copy_count(0) {} CopyCounting(const CopyCounting& rhs) : move_count(rhs.move_count), copy_count(rhs.copy_count + 1) {} CopyCounting(CopyCounting&& rhs) noexcept : move_count(rhs.move_count + 1), copy_count(rhs.copy_count) {} CopyCounting& operator=(const CopyCounting& rhs) { move_count = rhs.move_count; copy_count = rhs.copy_count + 1; return *this; } CopyCounting& operator=(CopyCounting&& rhs) noexcept { move_count = rhs.move_count + 1; copy_count = rhs.copy_count; return *this; } }; template using is_my_copy_counting_class = std::is_same>>; namespace test_tuple_elements { // note: not testing empty selection, as some compilers will raise // "parameter set but not used" in tuple_elements(). a good example // of the friction that comes with using these tools TEST(MetaprogrammingTest, TupleElements_subsetSelection) { auto x = std::make_tuple(0, "HEY", 2.0); auto y = tuple_elements(x, std::index_sequence<0, 2>()); auto z = std::make_tuple(0, 2.0); EXPECT_EQ(y, z); } TEST(MetaprogrammingTest, TupleElements_reorderSelection) { auto x = std::make_tuple(0, "HEY", 2.0); auto y = tuple_elements(x, std::index_sequence<0, 2, 1>()); auto z = std::make_tuple(0, 2.0, "HEY"); EXPECT_EQ(y, z); } } // namespace test_tuple_elements namespace test_tuple_take { // note: not testing empty prefix, see note on empty selection above. TEST(MetaprogrammingTest, TupleTake_nonemptyPrefix) { auto x = std::make_tuple(0, "HEY", 2.0); auto y = tuple_take(x); auto z = std::make_tuple(0, "HEY"); EXPECT_EQ(y, z); } TEST(MetaprogrammingTest, TupleTake_fullPrefix) { auto x = std::make_tuple(0, "HEY", 2.0); auto y = tuple_take(x); EXPECT_EQ(x, y); } TEST(MetaprogrammingTest, TupleTake_negative) { auto x = std::make_tuple(0, "HEY", 2.0); auto y = tuple_take(x); auto z = std::make_tuple("HEY", 2.0); EXPECT_EQ(y, z); } } // namespace test_tuple_take namespace test_tuple_slice { TEST(MetaprogrammingTest, TupleSlice_middle) { auto x = std::make_tuple(0, "HEY", 2.0, false); auto y = tuple_slice(x); auto z = std::make_tuple("HEY", 2.0); EXPECT_EQ(y, z); } TEST(MetaprogrammingTest, TupleSlice_full) { auto x = std::make_tuple(0, "HEY", 2.0); auto y = tuple_slice(x); EXPECT_EQ(x, y); } } // namespace test_tuple_slice namespace test_tuple_map { TEST(MetaprogrammingTest, TupleMap_simple) { auto result = tuple_map( std::tuple(3, 4, 5), [](int32_t a) -> int16_t { return static_cast(a + 1); }); static_assert( std::is_same, decltype(result)>:: value, ""); EXPECT_EQ(4, std::get<0>(result)); EXPECT_EQ(5, std::get<1>(result)); EXPECT_EQ(6, std::get<2>(result)); } TEST(MetaprogrammingTest, TupleMap_mapperTakesDifferentButConvertibleType) { auto result = tuple_map( std::tuple(3, 4, 5), [](int64_t a) -> int16_t { return static_cast(a + 1); }); static_assert( std::is_same, decltype(result)>:: value, ""); EXPECT_EQ(4, std::get<0>(result)); EXPECT_EQ(5, std::get<1>(result)); EXPECT_EQ(6, std::get<2>(result)); } TEST(MetaprogrammingTest, TupleMap_mapperTakesConstRef) { auto result = tuple_map( std::tuple(3, 4, 5), [](const int32_t& a) -> int16_t { return static_cast(a + 1); }); static_assert( std::is_same, decltype(result)>:: value, ""); EXPECT_EQ(4, std::get<0>(result)); EXPECT_EQ(5, std::get<1>(result)); EXPECT_EQ(6, std::get<2>(result)); } TEST(MetaprogrammingTest, TupleMap_mapsToDifferentTypes) { struct Mapper { std::string operator()(int32_t a) const { return std::to_string(a); } int32_t operator()(const std::string& a) const { return atoi(a.c_str()); } }; auto result = tuple_map(std::tuple(3, "4"), Mapper()); static_assert( std::is_same, decltype(result)>::value, ""); EXPECT_EQ("3", std::get<0>(result)); EXPECT_EQ(4, std::get<1>(result)); } TEST(MetaprogrammingTest, TupleMap_differentiatesLRValueReferences) { struct Mapper { std::string operator()(std::string&& a) const { return "moved"; } std::string operator()(const std::string& a) const { return "copied"; } }; std::string str1, str2; auto result = tuple_map( std::tuple(str1, std::move(str2)), Mapper()); static_assert( std::is_same, decltype(result)>:: value, ""); EXPECT_EQ("copied", std::get<0>(result)); EXPECT_EQ("moved", std::get<1>(result)); } TEST(MetaprogrammingTest, TupleMap_canWorkWithMovableOnlyType) { auto result = tuple_map( std::tuple(MovableOnly(7)), [](MovableOnly a) { return a; }); static_assert( std::is_same, decltype(result)>::value, ""); EXPECT_EQ(MovableOnly(7), std::get<0>(result)); } TEST(MetaprogrammingTest, TupleMap_doesntUnecessarilyCopyValues) { auto result = tuple_map( std::tuple(CopyCounting()), [](CopyCounting a) { return a; }); static_assert( std::is_same, decltype(result)>::value, ""); EXPECT_EQ(4, std::get<0>(result).move_count); EXPECT_EQ(0, std::get<0>(result).copy_count); } TEST(MetaprogrammingTest, TupleMap_doesntUnecessarilyMoveValues) { CopyCounting a; auto result = tuple_map( std::tuple(std::move(a)), [](CopyCounting&& a) -> CopyCounting&& { return std::move(a); }); static_assert( std::is_same, decltype(result)>::value, ""); EXPECT_EQ(&a, &std::get<0>(result)); EXPECT_EQ(0, std::get<0>(result).move_count); EXPECT_EQ(0, std::get<0>(result).copy_count); } TEST(MetaprogrammingTest, TupleMap_canBeUsedWithAutoLambdas) { struct A final { int32_t func() { return 5; } }; struct B final { std::string func() { return "5"; } }; auto result = tuple_map(std::make_tuple(A(), B()), [](auto a) { return a.func(); }); static_assert( std::is_same, decltype(result)>::value, ""); EXPECT_EQ(5, std::get<0>(result)); EXPECT_EQ("5", std::get<1>(result)); } } // namespace test_tuple_map } // namespace // NOLINTEND(modernize*)