projects/SelfTest/TrickyTests.cpp - platform/external/catch2 - Gitiles

 /*
  *  Created by Phil on 09/11/2010.
  *  Copyright 2010 Two Blue Cubes Ltd. All rights reserved.
  *
  *  Distributed under the Boost Software License, Version 1.0. (See accompanying
  *  file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
  */

 #ifdef __clang__
 #pragma clang diagnostic ignored "-Wpadded"
 #endif

 #include <stdio.h>

 #include "catch.hpp"

 namespace Catch
 {
     template<>
     std::string toString<std::pair<int, int> >( const std::pair<int, int>& value )
     {
         std::ostringstream oss;
         oss << "std::pair( " << value.first << ", " << value.second << " )";
         return oss.str();

     }
 }

 ///////////////////////////////////////////////////////////////////////////////
 TEST_CASE
 (
     "Parsing a std::pair",
     "[Tricky][std::pair]"
 )
 {
     std::pair<int, int> aNicePair( 1, 2 );

     REQUIRE( (std::pair<int, int>( 1, 2 )) == aNicePair );
 }

 ///////////////////////////////////////////////////////////////////////////////
 TEST_CASE
 (
     "Where there is more to the expression after the RHS",
     "[Tricky][failing][.]"
 )
 {
 //    int a = 1, b = 2;
 //    REQUIRE( a == 2 || b == 2 );
     WARN( "Uncomment the code in this test to check that it gives a sensible compiler error" );
 }
 ///////////////////////////////////////////////////////////////////////////////
 TEST_CASE
 (
     "Where the LHS is not a simple value",
     "[Tricky][failing][.]"
 )
 {
     /*
     int a = 1;
     int b = 2;

     // This only captures part of the expression, but issues a warning about the rest
     REQUIRE( a+1 == b-1 );
     */
     WARN( "Uncomment the code in this test to check that it gives a sensible compiler error" );
 }

 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
 (
     "string literals of different sizes can be compared",
     "[Tricky][failing][.]"
 )
 {
     REQUIRE( std::string( "first" ) == "second" );

 }

 ///////////////////////////////////////////////////////////////////////////////
 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() {return 0xc0000000;}
     };

     ///////////////////////////////////////////////////////////////////////////////
     TEST_CASE
     (
         "Operators at different namespace levels not hijacked by Koenig lookup",
         "[Tricky]"
     )
     {
         Object o;
         REQUIRE(0xc0000000 == o );
     }
 }

 namespace ObjectWithNonConstEqualityOperator
 {
     struct Test
     {
         Test( unsigned int v )
         : m_value(v)
         {}

         bool operator==( const Test&rhs )
         {
             return (m_value == rhs.m_value);
         }
         bool operator==( const Test&rhs ) const
         {
             return (m_value != rhs.m_value);
         }
         unsigned int m_value;
     };

     TEST_CASE("Demonstrate that a non-const == is not used", "[Tricky]" )
     {
         Test t( 1 );
         REQUIRE( t == 1u );
     }
 }

 namespace EnumBitFieldTests
 {
     enum Bits {bit0 = 0x0001, bit1 = 0x0002, bit2 = 0x0004, bit3 = 0x0008, bit1and2 = 0x0006,
         bit30 = 0x40000000, bit31 = 0x80000000,
         bit30and31 = 0xc0000000};

     TEST_CASE( "Test enum bit values", "[Tricky]" )
     {
         REQUIRE( 0xc0000000 == bit30and31 );
     }
 }

 struct Obj
 {
     Obj():prop(&p){}

     int p;
     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 <bool B>
 struct is_true
 {
     static const bool value = B;
 };

 TEST_CASE( "(unimplemented) static bools can be evaluated", "[Tricky]" )
 {
     SECTION("compare to true","")
     {
         REQUIRE( is_true<true>::value == true );
         REQUIRE( true == is_true<true>::value );
     }
     SECTION("compare to false","")
     {
         REQUIRE( is_true<false>::value == false );
         REQUIRE( false == is_true<false>::value );
     }

     SECTION("negation", "")
     {
         REQUIRE( !is_true<false>::value );
     }

     SECTION("double negation","")
     {
         REQUIRE( !!is_true<true>::value );
     }

     SECTION("direct","")
     {
         REQUIRE( is_true<true>::value );
         REQUIRE_FALSE( is_true<false>::value );
     }
 }

 // Uncomment these tests to produce an error at test registration time
 /*
 TEST_CASE( "Tests with the same name are not allowed", "[Tricky]" )
 {

 }
 TEST_CASE( "Tests with the same name are not allowed", "[Tricky]" )
 {

 }
 */

 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( Catch::alwaysTrue() );

     SECTION( "A section", "" )
     {
         REQUIRE( Catch::alwaysTrue() );

         SECTION( "Another section", "" )
         {
             REQUIRE( Catch::alwaysTrue() );
         }
         SECTION( "Another other section", "" )
         {
             REQUIRE( Catch::alwaysTrue() );
         }
     }
 }

 struct Awkward
 {
     operator int() const { return 7; }
 };

 TEST_CASE( "non streamable - with conv. op", "[Tricky]" )
 {
     Awkward awkward;
     std::string s = Catch::toString( awkward );
     REQUIRE( s == "7" );
 }

 inline void foo() {}

 typedef void (*fooptr_t)();

 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]" )
 {
     typedef void (S::*MF)();
     MF m = &S::f;

     CHECK( m == &S::f );
 }

 class ClassName {};

 TEST_CASE( "pointer to class", "[Tricky]" )
 {
    ClassName *p = 0;
    REQUIRE( p == 0 );
 }

 #include <memory>

 TEST_CASE( "null_ptr", "[Tricky][c++11][.]" )
 {
     std::unique_ptr<int> 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(""); }

 TEST_CASE( "has printf", "" ) {

     // This can cause problems as, currently, stdout itself is not redirect - only the cout (and cerr) buffer
     printf( "spanner" );
 }
	/*
	* Created by Phil on 09/11/2010.
	* Copyright 2010 Two Blue Cubes Ltd. All rights reserved.
	*
	* Distributed under the Boost Software License, Version 1.0. (See accompanying
	* file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
	*/

	#ifdef __clang__
	#pragma clang diagnostic ignored "-Wpadded"
	#endif

	#include <stdio.h>

	#include "catch.hpp"

	namespace Catch
	{
	template<>
	std::string toString<std::pair<int, int> >( const std::pair<int, int>& value )
	{
	std::ostringstream oss;
	oss << "std::pair( " << value.first << ", " << value.second << " )";
	return oss.str();

	}
	}

	///////////////////////////////////////////////////////////////////////////////
	TEST_CASE
	(
	"Parsing a std::pair",
	"[Tricky][std::pair]"
	)
	{
	std::pair<int, int> aNicePair( 1, 2 );

	REQUIRE( (std::pair<int, int>( 1, 2 )) == aNicePair );
	}

	///////////////////////////////////////////////////////////////////////////////
	TEST_CASE
	(
	"Where there is more to the expression after the RHS",
	"[Tricky][failing][.]"
	)
	{
	// int a = 1, b = 2;
	// REQUIRE( a == 2 \|\| b == 2 );
	WARN( "Uncomment the code in this test to check that it gives a sensible compiler error" );
	}
	///////////////////////////////////////////////////////////////////////////////
	TEST_CASE
	(
	"Where the LHS is not a simple value",
	"[Tricky][failing][.]"
	)
	{
	/*
	int a = 1;
	int b = 2;

	// This only captures part of the expression, but issues a warning about the rest
	REQUIRE( a+1 == b-1 );
	*/
	WARN( "Uncomment the code in this test to check that it gives a sensible compiler error" );
	}

	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
	(
	"string literals of different sizes can be compared",
	"[Tricky][failing][.]"
	)
	{
	REQUIRE( std::string( "first" ) == "second" );

	}

	///////////////////////////////////////////////////////////////////////////////
	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() {return 0xc0000000;}
	};

	///////////////////////////////////////////////////////////////////////////////
	TEST_CASE
	(
	"Operators at different namespace levels not hijacked by Koenig lookup",
	"[Tricky]"
	)
	{
	Object o;
	REQUIRE(0xc0000000 == o );
	}
	}

	namespace ObjectWithNonConstEqualityOperator
	{
	struct Test
	{
	Test( unsigned int v )
	: m_value(v)
	{}

	bool operator==( const Test&rhs )
	{
	return (m_value == rhs.m_value);
	}
	bool operator==( const Test&rhs ) const
	{
	return (m_value != rhs.m_value);
	}
	unsigned int m_value;
	};

	TEST_CASE("Demonstrate that a non-const == is not used", "[Tricky]" )
	{
	Test t( 1 );
	REQUIRE( t == 1u );
	}
	}

	namespace EnumBitFieldTests
	{
	enum Bits {bit0 = 0x0001, bit1 = 0x0002, bit2 = 0x0004, bit3 = 0x0008, bit1and2 = 0x0006,
	bit30 = 0x40000000, bit31 = 0x80000000,
	bit30and31 = 0xc0000000};

	TEST_CASE( "Test enum bit values", "[Tricky]" )
	{
	REQUIRE( 0xc0000000 == bit30and31 );
	}
	}

	struct Obj
	{
	Obj():prop(&p){}

	int p;
	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 <bool B>
	struct is_true
	{
	static const bool value = B;
	};

	TEST_CASE( "(unimplemented) static bools can be evaluated", "[Tricky]" )
	{
	SECTION("compare to true","")
	{
	REQUIRE( is_true<true>::value == true );
	REQUIRE( true == is_true<true>::value );
	}
	SECTION("compare to false","")
	{
	REQUIRE( is_true<false>::value == false );
	REQUIRE( false == is_true<false>::value );
	}

	SECTION("negation", "")
	{
	REQUIRE( !is_true<false>::value );
	}

	SECTION("double negation","")
	{
	REQUIRE( !!is_true<true>::value );
	}

	SECTION("direct","")
	{
	REQUIRE( is_true<true>::value );
	REQUIRE_FALSE( is_true<false>::value );
	}
	}

	// Uncomment these tests to produce an error at test registration time
	/*
	TEST_CASE( "Tests with the same name are not allowed", "[Tricky]" )
	{

	}
	TEST_CASE( "Tests with the same name are not allowed", "[Tricky]" )
	{

	}
	*/

	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( Catch::alwaysTrue() );

	SECTION( "A section", "" )
	{
	REQUIRE( Catch::alwaysTrue() );

	SECTION( "Another section", "" )
	{
	REQUIRE( Catch::alwaysTrue() );
	}
	SECTION( "Another other section", "" )
	{
	REQUIRE( Catch::alwaysTrue() );
	}
	}
	}

	struct Awkward
	{
	operator int() const { return 7; }
	};

	TEST_CASE( "non streamable - with conv. op", "[Tricky]" )
	{
	Awkward awkward;
	std::string s = Catch::toString( awkward );
	REQUIRE( s == "7" );
	}

	inline void foo() {}

	typedef void (*fooptr_t)();

	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]" )
	{
	typedef void (S::*MF)();
	MF m = &S::f;

	CHECK( m == &S::f );
	}

	class ClassName {};

	TEST_CASE( "pointer to class", "[Tricky]" )
	{
	ClassName *p = 0;
	REQUIRE( p == 0 );
	}

	#include <memory>

	TEST_CASE( "null_ptr", "[Tricky][c++11][.]" )
	{
	std::unique_ptr<int> 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(""); }

	TEST_CASE( "has printf", "" ) {

	// This can cause problems as, currently, stdout itself is not redirect - only the cout (and cerr) buffer
	printf( "spanner" );
	}