boost_1_45_0/libs/range/test/algorithm_test/find_end.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 // Boost.Range library
 //
 //  Copyright Neil Groves 2009. Use, modification and
 //  distribution is 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)
 //
 //
 // For more information, see http://www.boost.org/libs/range/
 //
 #include <boost/range/algorithm/find_end.hpp>

 #include <boost/test/test_tools.hpp>
 #include <boost/test/unit_test.hpp>

 #include <boost/assign.hpp>
 #include "../test_driver/range_return_test_driver.hpp"
 #include <algorithm>
 #include <functional>
 #include <vector>
 #include <set>
 #include <list>

 namespace boost
 {
     namespace
     {
         template<class Container2>
         class find_end_test_policy
         {
             typedef Container2 container2_t;
         public:
             explicit find_end_test_policy(const Container2& cont)
                 :   m_cont(cont)
             {
             }

             container2_t cont() { return m_cont; }

             template<class Container>
             BOOST_DEDUCED_TYPENAME range_iterator<Container>::type
             test_iter(Container& cont)
             {
                 typedef BOOST_DEDUCED_TYPENAME range_iterator<Container>::type iter_t;
                 iter_t result = boost::find_end(cont, m_cont);
                 BOOST_CHECK( result == boost::find_end(boost::make_iterator_range(cont), m_cont) );
                 BOOST_CHECK( result == boost::find_end(cont, boost::make_iterator_range(m_cont)) );
                 BOOST_CHECK( result == boost::find_end(boost::make_iterator_range(cont), boost::make_iterator_range(m_cont)) );
                 return result;
             }

             template<range_return_value return_type>
             struct test_range
             {
                 template<class Container, class Policy>
                 BOOST_DEDUCED_TYPENAME range_return<Container,return_type>::type
                 operator()(Policy& policy, Container& cont)
                 {
                     typedef BOOST_DEDUCED_TYPENAME range_return<Container,return_type>::type result_t;
                     result_t result = boost::find_end<return_type>(cont, policy.cont());
                     BOOST_CHECK( result == boost::find_end<return_type>(boost::make_iterator_range(cont), policy.cont()) );
                     BOOST_CHECK( result == boost::find_end<return_type>(cont, boost::make_iterator_range(policy.cont())) );
                     BOOST_CHECK( result == boost::find_end<return_type>(boost::make_iterator_range(cont),
                                                                         boost::make_iterator_range(policy.cont())) );
                     return result;
                 }
             };

             template<class Container>
             BOOST_DEDUCED_TYPENAME range_iterator<Container>::type
             reference(Container& cont)
             {
                 return std::find_end(cont.begin(), cont.end(),
                                      m_cont.begin(), m_cont.end());
             }

         private:
             Container2 m_cont;
         };

         template<class Container2, class BinaryPredicate>
         class find_end_pred_test_policy
         {
             typedef Container2 container2_t;
         public:
             explicit find_end_pred_test_policy(const Container2& cont)
                 :   m_cont(cont)
             {
             }

             container2_t& cont() { return m_cont; }
             BinaryPredicate& pred() { return m_pred; }

             template<class Container>
             BOOST_DEDUCED_TYPENAME range_iterator<Container>::type
             test_iter(Container& cont)
             {
                 typedef BOOST_DEDUCED_TYPENAME range_iterator<Container>::type iter_t;
                 iter_t it = boost::find_end(cont, m_cont, m_pred);
                 BOOST_CHECK( it == boost::find_end(boost::make_iterator_range(cont), m_cont, m_pred) );
                 BOOST_CHECK( it == boost::find_end(cont, boost::make_iterator_range(m_cont), m_pred) );
                 BOOST_CHECK( it == boost::find_end(boost::make_iterator_range(cont), boost::make_iterator_range(m_cont), m_pred) );
                 return it;
             }

             template<range_return_value return_type>
             struct test_range
             {
                 template<class Container, class Policy>
                 BOOST_DEDUCED_TYPENAME range_return<Container,return_type>::type
                 operator()(Policy& policy, Container& cont)
                 {
                     typedef BOOST_DEDUCED_TYPENAME range_return<Container,return_type>::type result_t;
                     result_t result = boost::find_end<return_type>(cont, policy.cont(), policy.pred());
                     BOOST_CHECK( result == boost::find_end<return_type>(boost::make_iterator_range(cont), policy.cont(), policy.pred()) );
                     BOOST_CHECK( result == boost::find_end<return_type>(cont, boost::make_iterator_range(policy.cont()), policy.pred()) );
                     BOOST_CHECK( result == boost::find_end<return_type>(boost::make_iterator_range(cont),
                                                                         boost::make_iterator_range(policy.cont()), policy.pred()) );
                     return boost::find_end<return_type>(cont, policy.cont(), policy.pred());
                 }
             };

             template<class Container>
             BOOST_DEDUCED_TYPENAME range_iterator<Container>::type
             reference(Container& cont)
             {
                 return std::find_end(cont.begin(), cont.end(),
                                      m_cont.begin(), m_cont.end(),
                                      m_pred);
             }

         private:
             Container2      m_cont;
             BinaryPredicate m_pred;
         };

         template<class Container1, class Container2>
         void run_tests(Container1& cont1, Container2& cont2)
         {
             range_test::range_return_test_driver test_driver;
             test_driver(cont1, find_end_test_policy<Container2>(cont2));
             test_driver(cont1, find_end_pred_test_policy<Container2, std::less<int> >(cont2));
             test_driver(cont2, find_end_pred_test_policy<Container2, std::greater<int> >(cont2));
         }

         template<class Container1, class Container2>
         void test_find_end_impl()
         {
             using namespace boost::assign;

             typedef BOOST_DEDUCED_TYPENAME remove_const<Container1>::type container1_t;
             typedef BOOST_DEDUCED_TYPENAME remove_const<Container2>::type container2_t;

             container1_t mcont1;
             Container1& cont1 = mcont1;
             container2_t mcont2;
             Container2& cont2 = mcont2;

             run_tests(cont1, cont2);

             mcont1 += 1;
             run_tests(cont1, cont2);

             mcont2 += 1;
             run_tests(cont1, cont2);

             mcont1 += 2,3,4,5,6,7,8,9;
             mcont2 += 2,3,4;
             run_tests(cont1, cont2);

             mcont2.clear();
             mcont2 += 7,8,9;
             run_tests(cont1, cont2);
         }

         void test_find_end()
         {
             test_find_end_impl< std::vector<int>, std::vector<int> >();
             test_find_end_impl< std::list<int>, std::list<int> >();
             test_find_end_impl< std::deque<int>, std::deque<int> >();
             test_find_end_impl< const std::vector<int>, const std::vector<int> >();
             test_find_end_impl< const std::list<int>, const std::list<int> >();
             test_find_end_impl< const std::deque<int>, const std::deque<int> >();
             test_find_end_impl< const std::vector<int>, const std::list<int> >();
             test_find_end_impl< const std::list<int>, const std::vector<int> >();
             test_find_end_impl< const std::vector<int>, std::list<int> >();
             test_find_end_impl< const std::list<int>, std::vector<int> >();
             test_find_end_impl< std::vector<int>, std::list<int> >();
             test_find_end_impl< std::list<int>, std::vector<int> >();
         }
     }
 }

 boost::unit_test::test_suite*
 init_unit_test_suite(int argc, char* argv[])
 {
     boost::unit_test::test_suite* test
         = BOOST_TEST_SUITE( "RangeTestSuite.algorithm.find_end" );

     test->add( BOOST_TEST_CASE( &boost::test_find_end ) );

     return test;
 }
	// Boost.Range library
	//
	// Copyright Neil Groves 2009. Use, modification and
	// distribution is 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)
	//
	//
	// For more information, see http://www.boost.org/libs/range/
	//
	#include <boost/range/algorithm/find_end.hpp>

	#include <boost/test/test_tools.hpp>
	#include <boost/test/unit_test.hpp>

	#include <boost/assign.hpp>
	#include "../test_driver/range_return_test_driver.hpp"
	#include <algorithm>
	#include <functional>
	#include <vector>
	#include <set>
	#include <list>

	namespace boost
	{
	namespace
	{
	template<class Container2>
	class find_end_test_policy
	{
	typedef Container2 container2_t;
	public:
	explicit find_end_test_policy(const Container2& cont)
	: m_cont(cont)
	{
	}

	container2_t cont() { return m_cont; }

	template<class Container>
	BOOST_DEDUCED_TYPENAME range_iterator<Container>::type
	test_iter(Container& cont)
	{
	typedef BOOST_DEDUCED_TYPENAME range_iterator<Container>::type iter_t;
	iter_t result = boost::find_end(cont, m_cont);
	BOOST_CHECK( result == boost::find_end(boost::make_iterator_range(cont), m_cont) );
	BOOST_CHECK( result == boost::find_end(cont, boost::make_iterator_range(m_cont)) );
	BOOST_CHECK( result == boost::find_end(boost::make_iterator_range(cont), boost::make_iterator_range(m_cont)) );
	return result;
	}

	template<range_return_value return_type>
	struct test_range
	{
	template<class Container, class Policy>
	BOOST_DEDUCED_TYPENAME range_return<Container,return_type>::type
	operator()(Policy& policy, Container& cont)
	{
	typedef BOOST_DEDUCED_TYPENAME range_return<Container,return_type>::type result_t;
	result_t result = boost::find_end<return_type>(cont, policy.cont());
	BOOST_CHECK( result == boost::find_end<return_type>(boost::make_iterator_range(cont), policy.cont()) );
	BOOST_CHECK( result == boost::find_end<return_type>(cont, boost::make_iterator_range(policy.cont())) );
	BOOST_CHECK( result == boost::find_end<return_type>(boost::make_iterator_range(cont),
	boost::make_iterator_range(policy.cont())) );
	return result;
	}
	};

	template<class Container>
	BOOST_DEDUCED_TYPENAME range_iterator<Container>::type
	reference(Container& cont)
	{
	return std::find_end(cont.begin(), cont.end(),
	m_cont.begin(), m_cont.end());
	}

	private:
	Container2 m_cont;
	};

	template<class Container2, class BinaryPredicate>
	class find_end_pred_test_policy
	{
	typedef Container2 container2_t;
	public:
	explicit find_end_pred_test_policy(const Container2& cont)
	: m_cont(cont)
	{
	}

	container2_t& cont() { return m_cont; }
	BinaryPredicate& pred() { return m_pred; }

	template<class Container>
	BOOST_DEDUCED_TYPENAME range_iterator<Container>::type
	test_iter(Container& cont)
	{
	typedef BOOST_DEDUCED_TYPENAME range_iterator<Container>::type iter_t;
	iter_t it = boost::find_end(cont, m_cont, m_pred);
	BOOST_CHECK( it == boost::find_end(boost::make_iterator_range(cont), m_cont, m_pred) );
	BOOST_CHECK( it == boost::find_end(cont, boost::make_iterator_range(m_cont), m_pred) );
	BOOST_CHECK( it == boost::find_end(boost::make_iterator_range(cont), boost::make_iterator_range(m_cont), m_pred) );
	return it;
	}

	template<range_return_value return_type>
	struct test_range
	{
	template<class Container, class Policy>
	BOOST_DEDUCED_TYPENAME range_return<Container,return_type>::type
	operator()(Policy& policy, Container& cont)
	{
	typedef BOOST_DEDUCED_TYPENAME range_return<Container,return_type>::type result_t;
	result_t result = boost::find_end<return_type>(cont, policy.cont(), policy.pred());
	BOOST_CHECK( result == boost::find_end<return_type>(boost::make_iterator_range(cont), policy.cont(), policy.pred()) );
	BOOST_CHECK( result == boost::find_end<return_type>(cont, boost::make_iterator_range(policy.cont()), policy.pred()) );
	BOOST_CHECK( result == boost::find_end<return_type>(boost::make_iterator_range(cont),
	boost::make_iterator_range(policy.cont()), policy.pred()) );
	return boost::find_end<return_type>(cont, policy.cont(), policy.pred());
	}
	};

	template<class Container>
	BOOST_DEDUCED_TYPENAME range_iterator<Container>::type
	reference(Container& cont)
	{
	return std::find_end(cont.begin(), cont.end(),
	m_cont.begin(), m_cont.end(),
	m_pred);
	}

	private:
	Container2 m_cont;
	BinaryPredicate m_pred;
	};

	template<class Container1, class Container2>
	void run_tests(Container1& cont1, Container2& cont2)
	{
	range_test::range_return_test_driver test_driver;
	test_driver(cont1, find_end_test_policy<Container2>(cont2));
	test_driver(cont1, find_end_pred_test_policy<Container2, std::less<int> >(cont2));
	test_driver(cont2, find_end_pred_test_policy<Container2, std::greater<int> >(cont2));
	}

	template<class Container1, class Container2>
	void test_find_end_impl()
	{
	using namespace boost::assign;

	typedef BOOST_DEDUCED_TYPENAME remove_const<Container1>::type container1_t;
	typedef BOOST_DEDUCED_TYPENAME remove_const<Container2>::type container2_t;

	container1_t mcont1;
	Container1& cont1 = mcont1;
	container2_t mcont2;
	Container2& cont2 = mcont2;

	run_tests(cont1, cont2);

	mcont1 += 1;
	run_tests(cont1, cont2);

	mcont2 += 1;
	run_tests(cont1, cont2);

	mcont1 += 2,3,4,5,6,7,8,9;
	mcont2 += 2,3,4;
	run_tests(cont1, cont2);

	mcont2.clear();
	mcont2 += 7,8,9;
	run_tests(cont1, cont2);
	}

	void test_find_end()
	{
	test_find_end_impl< std::vector<int>, std::vector<int> >();
	test_find_end_impl< std::list<int>, std::list<int> >();
	test_find_end_impl< std::deque<int>, std::deque<int> >();
	test_find_end_impl< const std::vector<int>, const std::vector<int> >();
	test_find_end_impl< const std::list<int>, const std::list<int> >();
	test_find_end_impl< const std::deque<int>, const std::deque<int> >();
	test_find_end_impl< const std::vector<int>, const std::list<int> >();
	test_find_end_impl< const std::list<int>, const std::vector<int> >();
	test_find_end_impl< const std::vector<int>, std::list<int> >();
	test_find_end_impl< const std::list<int>, std::vector<int> >();
	test_find_end_impl< std::vector<int>, std::list<int> >();
	test_find_end_impl< std::list<int>, std::vector<int> >();
	}
	}
	}

	boost::unit_test::test_suite*
	init_unit_test_suite(int argc, char* argv[])
	{
	boost::unit_test::test_suite* test
	= BOOST_TEST_SUITE( "RangeTestSuite.algorithm.find_end" );

	test->add( BOOST_TEST_CASE( &boost::test_find_end ) );

	return test;
	}