boost_1_45_0/libs/fusion/test/functional/invoke_function_object.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 /*=============================================================================
     Copyright (c) 2005-2006 Joao Abecasis
     Copyright (c) 2006-2007 Tobias Schwinger

     Use modification and distribution are subject to 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).
 ==============================================================================*/

 #include <boost/fusion/functional/invocation/invoke_function_object.hpp>
 #include <boost/detail/lightweight_test.hpp>

 #include <boost/type_traits/is_same.hpp>

 #include <memory>
 #include <boost/noncopyable.hpp>

 #include <boost/mpl/int.hpp>

 #include <boost/fusion/container/vector.hpp>
 #include <boost/fusion/container/list.hpp>
 #include <boost/fusion/sequence/intrinsic/size.hpp>
 #include <boost/fusion/sequence/intrinsic/begin.hpp>
 #include <boost/fusion/view/single_view.hpp>
 #include <boost/fusion/view/iterator_range.hpp>
 #include <boost/fusion/iterator/advance.hpp>
 #include <boost/fusion/algorithm/transformation/join.hpp>

 namespace mpl = boost::mpl;
 namespace fusion = boost::fusion;

 template <typename T>
 inline T const & const_(T const & t)
 {
     return t;
 }

 struct object {};
 struct object_nc : boost::noncopyable {};

 struct fobj
 {
     // Handle nullary separately to exercise result_of support
     template <typename Sig>
     struct result;

     template <class Self, typename T0>
     struct result< Self(T0) >
     {
         typedef int type;
     };

     template <class Self, typename T0, typename T1>
     struct result< Self(T0, T1) >
     {
         typedef int type;
     };

     template <class Self, typename T0, typename T1, typename T2>
     struct result< Self(T0, T1, T2) >
     {
         typedef int type;
     };

     int operator()()       { return 0; }
     int operator()() const { return 1; }

     int operator()(int i)       { return 2 + i; }
     int operator()(int i) const { return 3 + i; }

     int operator()(int i, object &)             { return 4 + i; }
     int operator()(int i, object &) const       { return 5 + i; }
     int operator()(int i, object const &)       { return 6 + i; }
     int operator()(int i, object const &) const { return 7 + i; }

     int operator()(int i, object &, object_nc &)       { return 10 + i; }
     int operator()(int i, object &, object_nc &) const { return 11 + i; }
 };

 struct nullary_fobj
 {
     typedef int result_type;

     int operator()()       { return 0; }
     int operator()() const { return 1; }
 };

 struct fobj_nc
       : boost::noncopyable
 {
     // Handle nullary separately to exercise result_of support
     template <typename T>
     struct result;

     template <class Self, typename T0>
     struct result< Self(T0) >
     {
         typedef int type;
     };

     int operator()(int i)       { return 14 + i; }
     int operator()(int i) const { return 15 + i; }
 };

 struct nullary_fobj_nc
       : boost::noncopyable
 {
     typedef int result_type;

     int operator()()       { return 12; }
     int operator()() const { return 13; }
 };


 typedef int         element1_type;
 typedef object      element2_type;
 typedef object_nc & element3_type;

 int         element1 = 100;
 object      element2 = object();
 object_nc   element3;

 template <class Sequence>
 void test_sequence_n(Sequence & seq, mpl::int_<0>)
 {
     // Function Objects

     nullary_fobj f;
     BOOST_TEST(f () == fusion::invoke_function_object(f ,        seq ));
     BOOST_TEST(f () == fusion::invoke_function_object(f , const_(seq)));

     // Note: The function object is taken by value, so we request the copy
     // to be const with an explicit template argument. We can also request
     // the function object to be pased by reference...
     BOOST_TEST(const_(f)() == fusion::invoke_function_object<nullary_fobj const  >(const_(f),        seq ));
     BOOST_TEST(const_(f)() == fusion::invoke_function_object<nullary_fobj const &>(const_(f), const_(seq)));

     nullary_fobj_nc nc_f;
     // ...and we further ensure there is no copying in this case, using a
     // noncopyable function object.
     BOOST_TEST(nc_f () == fusion::invoke_function_object<nullary_fobj_nc &>(nc_f ,        seq ));
     BOOST_TEST(nc_f () == fusion::invoke_function_object<nullary_fobj_nc &>(nc_f , const_(seq)));
     BOOST_TEST(const_(nc_f)() == fusion::invoke_function_object<nullary_fobj_nc const &>(const_(nc_f),        seq ));
     BOOST_TEST(const_(nc_f)() == fusion::invoke_function_object<nullary_fobj_nc const &>(const_(nc_f), const_(seq)));
 }

 template <class Sequence>
 void test_sequence_n(Sequence & seq, mpl::int_<1>)
 {
     fobj f;
     BOOST_TEST(f(element1) == fusion::invoke_function_object(f , seq ));
     BOOST_TEST(f(element1) == fusion::invoke_function_object(f , const_(seq)));
     BOOST_TEST(const_(f)(element1) == fusion::invoke_function_object<fobj const  >(const_(f), seq ));
     BOOST_TEST(const_(f)(element1) == fusion::invoke_function_object<fobj const &>(const_(f), const_(seq)));

     fobj_nc nc_f;
     BOOST_TEST(nc_f(element1) == fusion::invoke_function_object<fobj_nc &>(nc_f, seq ));
     BOOST_TEST(nc_f(element1) == fusion::invoke_function_object<fobj_nc &>(nc_f, const_(seq)));
     BOOST_TEST(const_(nc_f)(element1) == fusion::invoke_function_object<fobj_nc const &>(const_(nc_f), seq ));
     BOOST_TEST(const_(nc_f)(element1) == fusion::invoke_function_object<fobj_nc const &>(const_(nc_f), const_(seq)));
 }

 template <class Sequence>
 void test_sequence_n(Sequence & seq, mpl::int_<2>)
 {
     fobj f;
     BOOST_TEST(f (element1, element2) == fusion::invoke_function_object(f , seq));
     BOOST_TEST(f (element1, const_(element2)) == fusion::invoke_function_object(f , const_(seq)));
     BOOST_TEST(const_(f)(element1, element2) == fusion::invoke_function_object<fobj const>(const_(f), seq));
     BOOST_TEST(const_(f)(element1, const_(element2)) == fusion::invoke_function_object<fobj const>(const_(f), const_(seq)));
 }

 template <class Sequence>
 void test_sequence_n(Sequence & seq, mpl::int_<3>)
 {
     fobj f;

     BOOST_TEST(f(element1, element2, element3) == fusion::invoke_function_object(f, seq));
     BOOST_TEST(const_(f)(element1, element2, element3) == fusion::invoke_function_object<fobj const>(const_(f), seq));
 }

 template <class Sequence>
 void test_sequence(Sequence & seq)
 {
     test_sequence_n(seq, mpl::int_<fusion::result_of::size<Sequence>::value>());
 }

 void result_type_tests()
 {
     using boost::is_same;

     BOOST_TEST(( is_same< fusion::result_of::invoke_function_object< nullary_fobj, fusion::vector<> >::type, int >::value ));
     BOOST_TEST(( is_same< fusion::result_of::invoke_function_object< fobj, fusion::vector<element1_type> >::type, int >::value ));
     BOOST_TEST(( is_same< fusion::result_of::invoke_function_object< fobj, fusion::vector<element1_type,element2_type> >::type, int >::value ));
 }


 int main()
 {
     result_type_tests();

     typedef fusion::vector<> vector0;
     typedef fusion::vector<element1_type> vector1;
     typedef fusion::vector<element1_type, element2_type> vector2;
     typedef fusion::vector<element1_type, element2_type, element3_type> vector3;

     vector0 v0;
     vector1 v1(element1);
     vector2 v2(element1, element2);
     vector3 v3(element1, element2, element3);

     test_sequence(v0);
     test_sequence(v1);
     test_sequence(v2);
     test_sequence(v3);

     typedef fusion::list<> list0;
     typedef fusion::list<element1_type> list1;
     typedef fusion::list<element1_type, element2_type> list2;
     typedef fusion::list<element1_type, element2_type, element3_type> list3;

     list0 l0;
     list1 l1(element1);
     list2 l2(element1, element2);
     list3 l3(element1, element2, element3);

     test_sequence(l0);
     test_sequence(l1);
     test_sequence(l2);
     test_sequence(l3);

     return boost::report_errors();
 }
	/*=============================================================================
	Copyright (c) 2005-2006 Joao Abecasis
	Copyright (c) 2006-2007 Tobias Schwinger

	Use modification and distribution are subject to 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).
	==============================================================================*/

	#include <boost/fusion/functional/invocation/invoke_function_object.hpp>
	#include <boost/detail/lightweight_test.hpp>

	#include <boost/type_traits/is_same.hpp>

	#include <memory>
	#include <boost/noncopyable.hpp>

	#include <boost/mpl/int.hpp>

	#include <boost/fusion/container/vector.hpp>
	#include <boost/fusion/container/list.hpp>
	#include <boost/fusion/sequence/intrinsic/size.hpp>
	#include <boost/fusion/sequence/intrinsic/begin.hpp>
	#include <boost/fusion/view/single_view.hpp>
	#include <boost/fusion/view/iterator_range.hpp>
	#include <boost/fusion/iterator/advance.hpp>
	#include <boost/fusion/algorithm/transformation/join.hpp>

	namespace mpl = boost::mpl;
	namespace fusion = boost::fusion;

	template <typename T>
	inline T const & const_(T const & t)
	{
	return t;
	}

	struct object {};
	struct object_nc : boost::noncopyable {};

	struct fobj
	{
	// Handle nullary separately to exercise result_of support
	template <typename Sig>
	struct result;

	template <class Self, typename T0>
	struct result< Self(T0) >
	{
	typedef int type;
	};

	template <class Self, typename T0, typename T1>
	struct result< Self(T0, T1) >
	{
	typedef int type;
	};

	template <class Self, typename T0, typename T1, typename T2>
	struct result< Self(T0, T1, T2) >
	{
	typedef int type;
	};

	int operator()() { return 0; }
	int operator()() const { return 1; }

	int operator()(int i) { return 2 + i; }
	int operator()(int i) const { return 3 + i; }

	int operator()(int i, object &) { return 4 + i; }
	int operator()(int i, object &) const { return 5 + i; }
	int operator()(int i, object const &) { return 6 + i; }
	int operator()(int i, object const &) const { return 7 + i; }

	int operator()(int i, object &, object_nc &) { return 10 + i; }
	int operator()(int i, object &, object_nc &) const { return 11 + i; }
	};

	struct nullary_fobj
	{
	typedef int result_type;

	int operator()() { return 0; }
	int operator()() const { return 1; }
	};

	struct fobj_nc
	: boost::noncopyable
	{
	// Handle nullary separately to exercise result_of support
	template <typename T>
	struct result;

	template <class Self, typename T0>
	struct result< Self(T0) >
	{
	typedef int type;
	};

	int operator()(int i) { return 14 + i; }
	int operator()(int i) const { return 15 + i; }
	};

	struct nullary_fobj_nc
	: boost::noncopyable
	{
	typedef int result_type;

	int operator()() { return 12; }
	int operator()() const { return 13; }
	};


	typedef int element1_type;
	typedef object element2_type;
	typedef object_nc & element3_type;

	int element1 = 100;
	object element2 = object();
	object_nc element3;

	template <class Sequence>
	void test_sequence_n(Sequence & seq, mpl::int_<0>)
	{
	// Function Objects

	nullary_fobj f;
	BOOST_TEST(f () == fusion::invoke_function_object(f , seq ));
	BOOST_TEST(f () == fusion::invoke_function_object(f , const_(seq)));

	// Note: The function object is taken by value, so we request the copy
	// to be const with an explicit template argument. We can also request
	// the function object to be pased by reference...
	BOOST_TEST(const_(f)() == fusion::invoke_function_object<nullary_fobj const >(const_(f), seq ));
	BOOST_TEST(const_(f)() == fusion::invoke_function_object<nullary_fobj const &>(const_(f), const_(seq)));

	nullary_fobj_nc nc_f;
	// ...and we further ensure there is no copying in this case, using a
	// noncopyable function object.
	BOOST_TEST(nc_f () == fusion::invoke_function_object<nullary_fobj_nc &>(nc_f , seq ));
	BOOST_TEST(nc_f () == fusion::invoke_function_object<nullary_fobj_nc &>(nc_f , const_(seq)));
	BOOST_TEST(const_(nc_f)() == fusion::invoke_function_object<nullary_fobj_nc const &>(const_(nc_f), seq ));
	BOOST_TEST(const_(nc_f)() == fusion::invoke_function_object<nullary_fobj_nc const &>(const_(nc_f), const_(seq)));
	}

	template <class Sequence>
	void test_sequence_n(Sequence & seq, mpl::int_<1>)
	{
	fobj f;
	BOOST_TEST(f(element1) == fusion::invoke_function_object(f , seq ));
	BOOST_TEST(f(element1) == fusion::invoke_function_object(f , const_(seq)));
	BOOST_TEST(const_(f)(element1) == fusion::invoke_function_object<fobj const >(const_(f), seq ));
	BOOST_TEST(const_(f)(element1) == fusion::invoke_function_object<fobj const &>(const_(f), const_(seq)));

	fobj_nc nc_f;
	BOOST_TEST(nc_f(element1) == fusion::invoke_function_object<fobj_nc &>(nc_f, seq ));
	BOOST_TEST(nc_f(element1) == fusion::invoke_function_object<fobj_nc &>(nc_f, const_(seq)));
	BOOST_TEST(const_(nc_f)(element1) == fusion::invoke_function_object<fobj_nc const &>(const_(nc_f), seq ));
	BOOST_TEST(const_(nc_f)(element1) == fusion::invoke_function_object<fobj_nc const &>(const_(nc_f), const_(seq)));
	}

	template <class Sequence>
	void test_sequence_n(Sequence & seq, mpl::int_<2>)
	{
	fobj f;
	BOOST_TEST(f (element1, element2) == fusion::invoke_function_object(f , seq));
	BOOST_TEST(f (element1, const_(element2)) == fusion::invoke_function_object(f , const_(seq)));
	BOOST_TEST(const_(f)(element1, element2) == fusion::invoke_function_object<fobj const>(const_(f), seq));
	BOOST_TEST(const_(f)(element1, const_(element2)) == fusion::invoke_function_object<fobj const>(const_(f), const_(seq)));
	}

	template <class Sequence>
	void test_sequence_n(Sequence & seq, mpl::int_<3>)
	{
	fobj f;

	BOOST_TEST(f(element1, element2, element3) == fusion::invoke_function_object(f, seq));
	BOOST_TEST(const_(f)(element1, element2, element3) == fusion::invoke_function_object<fobj const>(const_(f), seq));
	}

	template <class Sequence>
	void test_sequence(Sequence & seq)
	{
	test_sequence_n(seq, mpl::int_<fusion::result_of::size<Sequence>::value>());
	}

	void result_type_tests()
	{
	using boost::is_same;

	BOOST_TEST(( is_same< fusion::result_of::invoke_function_object< nullary_fobj, fusion::vector<> >::type, int >::value ));
	BOOST_TEST(( is_same< fusion::result_of::invoke_function_object< fobj, fusion::vector<element1_type> >::type, int >::value ));
	BOOST_TEST(( is_same< fusion::result_of::invoke_function_object< fobj, fusion::vector<element1_type,element2_type> >::type, int >::value ));
	}


	int main()
	{
	result_type_tests();

	typedef fusion::vector<> vector0;
	typedef fusion::vector<element1_type> vector1;
	typedef fusion::vector<element1_type, element2_type> vector2;
	typedef fusion::vector<element1_type, element2_type, element3_type> vector3;

	vector0 v0;
	vector1 v1(element1);
	vector2 v2(element1, element2);
	vector3 v3(element1, element2, element3);

	test_sequence(v0);
	test_sequence(v1);
	test_sequence(v2);
	test_sequence(v3);

	typedef fusion::list<> list0;
	typedef fusion::list<element1_type> list1;
	typedef fusion::list<element1_type, element2_type> list2;
	typedef fusion::list<element1_type, element2_type, element3_type> list3;

	list0 l0;
	list1 l1(element1);
	list2 l2(element1, element2);
	list3 l3(element1, element2, element3);

	test_sequence(l0);
	test_sequence(l1);
	test_sequence(l2);
	test_sequence(l3);

	return boost::report_errors();
	}