// Copyright Catch2 Authors // Distributed under the Boost Software License, Version 1.0. // (See accompanying file LICENSE.txt or copy at // https://www.boost.org/LICENSE_1_0.txt) // SPDX-License-Identifier: BSL-1.0 #ifdef __clang__ #pragma clang diagnostic ignored "-Wpadded" #endif #ifdef _MSC_VER #pragma warning (disable : 4702) // Disable unreachable code warning for the last test // that is triggered when compiling as Win32|Release #endif #include #include #include #include #include #include struct Opaque { int val; bool operator ==( const Opaque& o ) const { return val == o.val; } }; /////////////////////////////////////////////////////////////////////////////// TEST_CASE ( "A failing expression with a non streamable type is still captured", "[Tricky][failing][.]" ) { Opaque o1, o2; o1.val = 7; o2.val = 8; CHECK( &o1 == &o2 ); CHECK( o1 == o2 ); } /////////////////////////////////////////////////////////////////////////////// TEST_CASE ( "An expression with side-effects should only be evaluated once", "[Tricky]" ) { int i = 7; REQUIRE( i++ == 7 ); REQUIRE( i++ == 8 ); } namespace A { struct X { X() : a(4), b(2), c(7) {} X(int v) : a(v), b(2), c(7) {} int a; int b; int c; }; } namespace B { struct Y { Y() : a(4), b(2), c(7) {} Y(int v) : a(v), b(2), c(7) {} int a; int b; int c; }; } inline bool operator==(const A::X& lhs, const B::Y& rhs) { return (lhs.a == rhs.a); } inline bool operator==(const B::Y& lhs, const A::X& rhs) { return (lhs.a == rhs.a); } /////////////////////////////////////////////////////////////////////////////// /* This, currently, does not compile with LLVM TEST_CASE ( "Operators at different namespace levels not hijacked by Koenig lookup" "[Tricky]" ) { A::X x; B::Y y; REQUIRE( x == y ); } */ namespace ObjectWithConversions { struct Object { operator unsigned int() const {return 0xc0000000;} }; /////////////////////////////////////////////////////////////////////////////// TEST_CASE ( "Implicit conversions are supported inside assertion macros", "[Tricky][approvals]" ) { Object o; REQUIRE(0xc0000000 == o ); } } namespace EnumBitFieldTests { enum Bits : uint32_t { bit0 = 0x0001, bit1 = 0x0002, bit2 = 0x0004, bit3 = 0x0008, bit1and2 = bit1 | bit2, bit30 = 0x40000000, bit31 = 0x80000000, bit30and31 = bit30 | bit31 }; TEST_CASE( "Test enum bit values", "[Tricky]" ) { REQUIRE( 0xc0000000 == bit30and31 ); } } struct Obj { Obj():prop(&p){} int p = 0; int* prop; }; TEST_CASE("boolean member", "[Tricky]") { Obj obj; REQUIRE( obj.prop != nullptr ); } // Tests for a problem submitted by Ralph McArdell // // The static bool value should not need to be defined outside the // struct it is declared in - but when evaluating it in a deduced // context it appears to require the extra definition. // The issue was fixed by adding bool overloads to bypass the // templates that were there to deduce it. template struct is_true { static const bool value = B; }; TEST_CASE( "(unimplemented) static bools can be evaluated", "[Tricky]" ) { SECTION("compare to true") { REQUIRE( is_true::value == true ); REQUIRE( true == is_true::value ); } SECTION("compare to false") { REQUIRE( is_true::value == false ); REQUIRE( false == is_true::value ); } SECTION("negation") { REQUIRE( !is_true::value ); } SECTION("double negation") { REQUIRE( !!is_true::value ); } SECTION("direct") { REQUIRE( is_true::value ); REQUIRE_FALSE( is_true::value ); } } struct Boolable { explicit Boolable( bool value ) : m_value( value ) {} explicit operator bool() const { return m_value; } bool m_value; }; TEST_CASE( "Objects that evaluated in boolean contexts can be checked", "[Tricky][SafeBool]" ) { Boolable True( true ); Boolable False( false ); CHECK( True ); CHECK( !False ); CHECK_FALSE( False ); } TEST_CASE( "Assertions then sections", "[Tricky]" ) { // This was causing a failure due to the way the console reporter was handling // the current section REQUIRE( true ); SECTION( "A section" ) { REQUIRE( true ); SECTION( "Another section" ) { REQUIRE( true ); } SECTION( "Another other section" ) { REQUIRE( true ); } } } struct Awkward { operator int() const { return 7; } }; TEST_CASE( "non streamable - with conv. op", "[Tricky]" ) { Awkward awkward; std::string s = ::Catch::Detail::stringify( awkward ); REQUIRE( s == "7" ); } inline void foo() {} using fooptr_t = void (*)(); TEST_CASE( "Comparing function pointers", "[Tricky][function pointer]" ) { // This was giving a warning in VS2010 // #179 fooptr_t a = foo; REQUIRE( a ); REQUIRE( a == &foo ); } struct S { void f() {} }; TEST_CASE( "Comparing member function pointers", "[Tricky][member function pointer][approvals]" ) { using MF = void (S::*)(); MF m = &S::f; CHECK( m == &S::f ); } class ClassName {}; TEST_CASE( "pointer to class", "[Tricky]" ) { ClassName *p = 0; REQUIRE( p == 0 ); } #include TEST_CASE( "null_ptr", "[Tricky]" ) { std::unique_ptr ptr; REQUIRE(ptr.get() == nullptr); } TEST_CASE( "X/level/0/a", "[Tricky]" ) { SUCCEED(""); } TEST_CASE( "X/level/0/b", "[Tricky][fizz]" ){ SUCCEED(""); } TEST_CASE( "X/level/1/a", "[Tricky]" ) { SUCCEED(""); } TEST_CASE( "X/level/1/b", "[Tricky]" ) { SUCCEED(""); } #include #include TEST_CASE( "has printf" ) { // This can cause problems as, currently, stdout itself is not redirected - only the cout (and cerr) buffer printf( "loose text artifact\n" ); fflush( stdout ); std::this_thread::sleep_for( std::chrono::seconds( 1 ) ); } namespace { struct constructor_throws { [[noreturn]] constructor_throws() { throw 1; } }; } TEST_CASE("Commas in various macros are allowed") { REQUIRE_THROWS( std::vector{constructor_throws{}, constructor_throws{}} ); CHECK_THROWS( std::vector{constructor_throws{}, constructor_throws{}} ); REQUIRE_NOTHROW( std::vector{1, 2, 3} == std::vector{1, 2, 3} ); CHECK_NOTHROW( std::vector{1, 2, 3} == std::vector{1, 2, 3} ); REQUIRE(std::vector{1, 2} == std::vector{1, 2}); CHECK( std::vector{1, 2} == std::vector{1, 2} ); REQUIRE_FALSE(std::vector{1, 2} == std::vector{1, 2, 3}); CHECK_FALSE( std::vector{1, 2} == std::vector{1, 2, 3} ); CHECK_NOFAIL( std::vector{1, 2} == std::vector{1, 2} ); CHECKED_IF( std::vector{1, 2} == std::vector{1, 2} ) { REQUIRE(true); } CHECKED_ELSE( std::vector{1, 2} == std::vector{1, 2} ) { CHECK(true); } } TEST_CASE( "non-copyable objects", "[.][failing]" ) { // Thanks to Agustin Bergé (@k-ballo on the cpplang Slack) for raising this std::type_info const& ti = typeid(int); CHECK( ti == typeid(int) ); } TEST_CASE("#1514: stderr/stdout is not captured in tests aborted by an exception", "[output-capture][regression][.]") { std::cout << "This would not be caught previously\n" << std::flush; std::clog << "Nor would this\n" << std::flush; // FAIL aborts the test by throwing a Catch exception FAIL("1514"); } TEST_CASE( "#2025: -c shouldn't cause infinite loop", "[sections][generators][regression][.approvals]" ) { SECTION( "Check cursor from buffer offset" ) { auto bufPos = GENERATE_REF( range( 0, 44 ) ); WHEN( "Buffer position is " << bufPos ) { REQUIRE( 1 == 1 ); } } } TEST_CASE("#2025: original repro", "[sections][generators][regression][.approvals]") { auto fov = GENERATE(true, false); DYNAMIC_SECTION("fov_" << fov) { std::cout << "inside with fov: " << fov << '\n'; } } TEST_CASE("#2025: same-level sections", "[sections][generators][regression][.approvals]") { SECTION("A") { SUCCEED(); } auto i = GENERATE(1, 2, 3); SECTION("B") { REQUIRE(i < 4); } }