boost_1_45_0/libs/utility/compressed_pair_test.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //  boost::compressed_pair test program

 //  (C) Copyright John Maddock 2000.
 //  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).

 // standalone test program for <boost/compressed_pair.hpp>
 // Revised 03 Oct 2000:
 //    Enabled tests for VC6.

 #include <iostream>
 #include <typeinfo>
 #include <cassert>

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

 using namespace boost;

 struct empty_UDT
 {
    ~empty_UDT(){};
    empty_UDT& operator=(const empty_UDT&){ return *this; }
    bool operator==(const empty_UDT&)const
    { return true; }
 };
 struct empty_POD_UDT
 {
    empty_POD_UDT& operator=(const empty_POD_UDT&){ return *this; }
    bool operator==(const empty_POD_UDT&)const
    { return true; }
 };

 struct non_empty1
 {
    int i;
    non_empty1() : i(1){}
    non_empty1(int v) : i(v){}
    friend bool operator==(const non_empty1& a, const non_empty1& b)
    { return a.i == b.i; }
 };

 struct non_empty2
 {
    int i;
    non_empty2() : i(3){}
    non_empty2(int v) : i(v){}
    friend bool operator==(const non_empty2& a, const non_empty2& b)
    { return a.i == b.i; }
 };

 #ifdef __GNUC__
 using std::swap;
 #endif

 template <class T1, class T2>
 struct compressed_pair_tester
 {
    // define the types we need:
    typedef T1                                                 first_type;
    typedef T2                                                 second_type;
    typedef typename call_traits<first_type>::param_type       first_param_type;
    typedef typename call_traits<second_type>::param_type      second_param_type;
    // define our test proc:
    static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
 };

 template <class T1, class T2>
 void compressed_pair_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4)
 {
 #ifndef __GNUC__
    // gcc 2.90 can't cope with function scope using
    // declarations, and generates an internal compiler error...
    using std::swap;
 #endif
    // default construct:
    boost::compressed_pair<T1,T2> cp1;
    // first param construct:
    boost::compressed_pair<T1,T2> cp2(p1);
    cp2.second() = p2;
    BOOST_CHECK(cp2.first() == p1);
    BOOST_CHECK(cp2.second() == p2);
    // second param construct:
    boost::compressed_pair<T1,T2> cp3(p2);
    cp3.first() = p1;
    BOOST_CHECK(cp3.second() == p2);
    BOOST_CHECK(cp3.first() == p1);
    // both param construct:
    boost::compressed_pair<T1,T2> cp4(p1, p2);
    BOOST_CHECK(cp4.first() == p1);
    BOOST_CHECK(cp4.second() == p2);
    boost::compressed_pair<T1,T2> cp5(p3, p4);
    BOOST_CHECK(cp5.first() == p3);
    BOOST_CHECK(cp5.second() == p4);
    // check const members:
    const boost::compressed_pair<T1,T2>& cpr1 = cp4;
    BOOST_CHECK(cpr1.first() == p1);
    BOOST_CHECK(cpr1.second() == p2);

    // copy construct:
    boost::compressed_pair<T1,T2> cp6(cp4);
    BOOST_CHECK(cp6.first() == p1);
    BOOST_CHECK(cp6.second() == p2);
    // assignment:
    cp1 = cp4;
    BOOST_CHECK(cp1.first() == p1);
    BOOST_CHECK(cp1.second() == p2);
    cp1 = cp5;
    BOOST_CHECK(cp1.first() == p3);
    BOOST_CHECK(cp1.second() == p4);
    // swap:
    cp4.swap(cp5);
    BOOST_CHECK(cp4.first() == p3);
    BOOST_CHECK(cp4.second() == p4);
    BOOST_CHECK(cp5.first() == p1);
    BOOST_CHECK(cp5.second() == p2);
    swap(cp4,cp5);
    BOOST_CHECK(cp4.first() == p1);
    BOOST_CHECK(cp4.second() == p2);
    BOOST_CHECK(cp5.first() == p3);
    BOOST_CHECK(cp5.second() == p4);
 }

 //
 // tests for case where one or both
 // parameters are reference types:
 //
 template <class T1, class T2>
 struct compressed_pair_reference_tester
 {
    // define the types we need:
    typedef T1                                                 first_type;
    typedef T2                                                 second_type;
    typedef typename call_traits<first_type>::param_type       first_param_type;
    typedef typename call_traits<second_type>::param_type      second_param_type;
    // define our test proc:
    static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
 };

 template <class T1, class T2>
 void compressed_pair_reference_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4)
 {
 #ifndef __GNUC__
    // gcc 2.90 can't cope with function scope using
    // declarations, and generates an internal compiler error...
    using std::swap;
 #endif
    // both param construct:
    boost::compressed_pair<T1,T2> cp4(p1, p2);
    BOOST_CHECK(cp4.first() == p1);
    BOOST_CHECK(cp4.second() == p2);
    boost::compressed_pair<T1,T2> cp5(p3, p4);
    BOOST_CHECK(cp5.first() == p3);
    BOOST_CHECK(cp5.second() == p4);
    // check const members:
    const boost::compressed_pair<T1,T2>& cpr1 = cp4;
    BOOST_CHECK(cpr1.first() == p1);
    BOOST_CHECK(cpr1.second() == p2);

    // copy construct:
    boost::compressed_pair<T1,T2> cp6(cp4);
    BOOST_CHECK(cp6.first() == p1);
    BOOST_CHECK(cp6.second() == p2);
    // assignment:
    // VC6 bug:
    // When second() is an empty class, VC6 performs the
    // assignment by doing a memcpy - even though the empty
    // class is really a zero sized base class, the result
    // is that the memory of first() gets trampled over.
    // Similar arguments apply to the case that first() is
    // an empty base class.
    // Strangely the problem is dependent upon the compiler
    // settings - some generate the problem others do not.
    cp4.first() = p3;
    cp4.second() = p4;
    BOOST_CHECK(cp4.first() == p3);
    BOOST_CHECK(cp4.second() == p4);
 }
 //
 // supplimentary tests for case where first arg only is a reference type:
 //
 template <class T1, class T2>
 struct compressed_pair_reference1_tester
 {
    // define the types we need:
    typedef T1                                                 first_type;
    typedef T2                                                 second_type;
    typedef typename call_traits<first_type>::param_type       first_param_type;
    typedef typename call_traits<second_type>::param_type      second_param_type;
    // define our test proc:
    static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
 };

 template <class T1, class T2>
 void compressed_pair_reference1_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
 {
 #ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
    // first param construct:
    boost::compressed_pair<T1,T2> cp2(p1);
    cp2.second() = p2;
    BOOST_CHECK(cp2.first() == p1);
    BOOST_CHECK(cp2.second() == p2);
 #endif
 }
 //
 // supplimentary tests for case where second arg only is a reference type:
 //
 template <class T1, class T2>
 struct compressed_pair_reference2_tester
 {
    // define the types we need:
    typedef T1                                                 first_type;
    typedef T2                                                 second_type;
    typedef typename call_traits<first_type>::param_type       first_param_type;
    typedef typename call_traits<second_type>::param_type      second_param_type;
    // define our test proc:
    static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
 };

 template <class T1, class T2>
 void compressed_pair_reference2_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
 {
 #ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
    // second param construct:
    boost::compressed_pair<T1,T2> cp3(p2);
    cp3.first() = p1;
    BOOST_CHECK(cp3.second() == p2);
    BOOST_CHECK(cp3.first() == p1);
 #endif
 }

 //
 // tests for where one or the other parameter is an array:
 //
 template <class T1, class T2>
 struct compressed_pair_array1_tester
 {
    // define the types we need:
    typedef T1                                                 first_type;
    typedef T2                                                 second_type;
    typedef typename call_traits<first_type>::param_type       first_param_type;
    typedef typename call_traits<second_type>::param_type      second_param_type;
    // define our test proc:
    static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
 };

 template <class T1, class T2>
 void compressed_pair_array1_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
 {
   // default construct:
    boost::compressed_pair<T1,T2> cp1;
    // second param construct:
    boost::compressed_pair<T1,T2> cp3(p2);
    cp3.first()[0] = p1[0];
    BOOST_CHECK(cp3.second() == p2);
    BOOST_CHECK(cp3.first()[0] == p1[0]);
    // check const members:
    const boost::compressed_pair<T1,T2>& cpr1 = cp3;
    BOOST_CHECK(cpr1.first()[0] == p1[0]);
    BOOST_CHECK(cpr1.second() == p2);

    BOOST_CHECK(sizeof(T1) == sizeof(cp1.first()));
 }

 template <class T1, class T2>
 struct compressed_pair_array2_tester
 {
    // define the types we need:
    typedef T1                                                 first_type;
    typedef T2                                                 second_type;
    typedef typename call_traits<first_type>::param_type       first_param_type;
    typedef typename call_traits<second_type>::param_type      second_param_type;
    // define our test proc:
    static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
 };

 template <class T1, class T2>
 void compressed_pair_array2_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
 {
    // default construct:
    boost::compressed_pair<T1,T2> cp1;
    // first param construct:
    boost::compressed_pair<T1,T2> cp2(p1);
    cp2.second()[0] = p2[0];
    BOOST_CHECK(cp2.first() == p1);
    BOOST_CHECK(cp2.second()[0] == p2[0]);
    // check const members:
    const boost::compressed_pair<T1,T2>& cpr1 = cp2;
    BOOST_CHECK(cpr1.first() == p1);
    BOOST_CHECK(cpr1.second()[0] == p2[0]);

    BOOST_CHECK(sizeof(T2) == sizeof(cp1.second()));
 }

 template <class T1, class T2>
 struct compressed_pair_array_tester
 {
    // define the types we need:
    typedef T1                                                 first_type;
    typedef T2                                                 second_type;
    typedef typename call_traits<first_type>::param_type       first_param_type;
    typedef typename call_traits<second_type>::param_type      second_param_type;
    // define our test proc:
    static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
 };

 template <class T1, class T2>
 void compressed_pair_array_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
 {
    // default construct:
    boost::compressed_pair<T1,T2> cp1;
    cp1.first()[0] = p1[0];
    cp1.second()[0] = p2[0];
    BOOST_CHECK(cp1.first()[0] == p1[0]);
    BOOST_CHECK(cp1.second()[0] == p2[0]);
    // check const members:
    const boost::compressed_pair<T1,T2>& cpr1 = cp1;
    BOOST_CHECK(cpr1.first()[0] == p1[0]);
    BOOST_CHECK(cpr1.second()[0] == p2[0]);

    BOOST_CHECK(sizeof(T1) == sizeof(cp1.first()));
    BOOST_CHECK(sizeof(T2) == sizeof(cp1.second()));
 }

 int test_main(int, char *[])
 {
    // declare some variables to pass to the tester:
    non_empty1 ne1(2);
    non_empty1 ne2(3);
    non_empty2 ne3(4);
    non_empty2 ne4(5);
    empty_POD_UDT  e1;
    empty_UDT      e2;

    // T1 != T2, both non-empty
    compressed_pair_tester<non_empty1,non_empty2>::test(ne1, ne3, ne2, ne4);
    // T1 != T2, T2 empty
    compressed_pair_tester<non_empty1,empty_POD_UDT>::test(ne1, e1, ne2, e1);
    // T1 != T2, T1 empty
    compressed_pair_tester<empty_POD_UDT,non_empty2>::test(e1, ne3, e1, ne4);
    // T1 != T2, both empty
    compressed_pair_tester<empty_POD_UDT,empty_UDT>::test(e1, e2, e1, e2);
    // T1 == T2, both non-empty
    compressed_pair_tester<non_empty1,non_empty1>::test(ne1, ne1, ne2, ne2);
    // T1 == T2, both empty
    compressed_pair_tester<empty_UDT,empty_UDT>::test(e2, e2, e2, e2);


    // test references:

    // T1 != T2, both non-empty
    compressed_pair_reference_tester<non_empty1&,non_empty2>::test(ne1, ne3, ne2, ne4);
    compressed_pair_reference_tester<non_empty1,non_empty2&>::test(ne1, ne3, ne2, ne4);
    compressed_pair_reference1_tester<non_empty1&,non_empty2>::test(ne1, ne3, ne2, ne4);
    compressed_pair_reference2_tester<non_empty1,non_empty2&>::test(ne1, ne3, ne2, ne4);
    // T1 != T2, T2 empty
    compressed_pair_reference_tester<non_empty1&,empty_POD_UDT>::test(ne1, e1, ne2, e1);
    compressed_pair_reference1_tester<non_empty1&,empty_POD_UDT>::test(ne1, e1, ne2, e1);
    // T1 != T2, T1 empty
    compressed_pair_reference_tester<empty_POD_UDT,non_empty2&>::test(e1, ne3, e1, ne4);
    compressed_pair_reference2_tester<empty_POD_UDT,non_empty2&>::test(e1, ne3, e1, ne4);
    // T1 == T2, both non-empty
    compressed_pair_reference_tester<non_empty1&,non_empty1&>::test(ne1, ne1, ne2, ne2);

    // tests arrays:
    non_empty1 nea1[2];
    non_empty1 nea2[2];
    non_empty2 nea3[2];
    non_empty2 nea4[2];
    nea1[0] = non_empty1(5);
    nea2[0] = non_empty1(6);
    nea3[0] = non_empty2(7);
    nea4[0] = non_empty2(8);

    // T1 != T2, both non-empty
    compressed_pair_array1_tester<non_empty1[2],non_empty2>::test(nea1, ne3, nea2, ne4);
    compressed_pair_array2_tester<non_empty1,non_empty2[2]>::test(ne1, nea3, ne2, nea4);
    compressed_pair_array_tester<non_empty1[2],non_empty2[2]>::test(nea1, nea3, nea2, nea4);
    // T1 != T2, T2 empty
    compressed_pair_array1_tester<non_empty1[2],empty_POD_UDT>::test(nea1, e1, nea2, e1);
    // T1 != T2, T1 empty
    compressed_pair_array2_tester<empty_POD_UDT,non_empty2[2]>::test(e1, nea3, e1, nea4);
    // T1 == T2, both non-empty
    compressed_pair_array_tester<non_empty1[2],non_empty1[2]>::test(nea1, nea1, nea2, nea2);
    return 0;
 }


 unsigned int expected_failures = 0;
	// boost::compressed_pair test program

	// (C) Copyright John Maddock 2000.
	// 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).

	// standalone test program for <boost/compressed_pair.hpp>
	// Revised 03 Oct 2000:
	// Enabled tests for VC6.

	#include <iostream>
	#include <typeinfo>
	#include <cassert>

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

	using namespace boost;

	struct empty_UDT
	{
	~empty_UDT(){};
	empty_UDT& operator=(const empty_UDT&){ return *this; }
	bool operator==(const empty_UDT&)const
	{ return true; }
	};
	struct empty_POD_UDT
	{
	empty_POD_UDT& operator=(const empty_POD_UDT&){ return *this; }
	bool operator==(const empty_POD_UDT&)const
	{ return true; }
	};

	struct non_empty1
	{
	int i;
	non_empty1() : i(1){}
	non_empty1(int v) : i(v){}
	friend bool operator==(const non_empty1& a, const non_empty1& b)
	{ return a.i == b.i; }
	};

	struct non_empty2
	{
	int i;
	non_empty2() : i(3){}
	non_empty2(int v) : i(v){}
	friend bool operator==(const non_empty2& a, const non_empty2& b)
	{ return a.i == b.i; }
	};

	#ifdef __GNUC__
	using std::swap;
	#endif

	template <class T1, class T2>
	struct compressed_pair_tester
	{
	// define the types we need:
	typedef T1 first_type;
	typedef T2 second_type;
	typedef typename call_traits<first_type>::param_type first_param_type;
	typedef typename call_traits<second_type>::param_type second_param_type;
	// define our test proc:
	static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
	};

	template <class T1, class T2>
	void compressed_pair_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4)
	{
	#ifndef __GNUC__
	// gcc 2.90 can't cope with function scope using
	// declarations, and generates an internal compiler error...
	using std::swap;
	#endif
	// default construct:
	boost::compressed_pair<T1,T2> cp1;
	// first param construct:
	boost::compressed_pair<T1,T2> cp2(p1);
	cp2.second() = p2;
	BOOST_CHECK(cp2.first() == p1);
	BOOST_CHECK(cp2.second() == p2);
	// second param construct:
	boost::compressed_pair<T1,T2> cp3(p2);
	cp3.first() = p1;
	BOOST_CHECK(cp3.second() == p2);
	BOOST_CHECK(cp3.first() == p1);
	// both param construct:
	boost::compressed_pair<T1,T2> cp4(p1, p2);
	BOOST_CHECK(cp4.first() == p1);
	BOOST_CHECK(cp4.second() == p2);
	boost::compressed_pair<T1,T2> cp5(p3, p4);
	BOOST_CHECK(cp5.first() == p3);
	BOOST_CHECK(cp5.second() == p4);
	// check const members:
	const boost::compressed_pair<T1,T2>& cpr1 = cp4;
	BOOST_CHECK(cpr1.first() == p1);
	BOOST_CHECK(cpr1.second() == p2);

	// copy construct:
	boost::compressed_pair<T1,T2> cp6(cp4);
	BOOST_CHECK(cp6.first() == p1);
	BOOST_CHECK(cp6.second() == p2);
	// assignment:
	cp1 = cp4;
	BOOST_CHECK(cp1.first() == p1);
	BOOST_CHECK(cp1.second() == p2);
	cp1 = cp5;
	BOOST_CHECK(cp1.first() == p3);
	BOOST_CHECK(cp1.second() == p4);
	// swap:
	cp4.swap(cp5);
	BOOST_CHECK(cp4.first() == p3);
	BOOST_CHECK(cp4.second() == p4);
	BOOST_CHECK(cp5.first() == p1);
	BOOST_CHECK(cp5.second() == p2);
	swap(cp4,cp5);
	BOOST_CHECK(cp4.first() == p1);
	BOOST_CHECK(cp4.second() == p2);
	BOOST_CHECK(cp5.first() == p3);
	BOOST_CHECK(cp5.second() == p4);
	}

	//
	// tests for case where one or both
	// parameters are reference types:
	//
	template <class T1, class T2>
	struct compressed_pair_reference_tester
	{
	// define the types we need:
	typedef T1 first_type;
	typedef T2 second_type;
	typedef typename call_traits<first_type>::param_type first_param_type;
	typedef typename call_traits<second_type>::param_type second_param_type;
	// define our test proc:
	static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
	};

	template <class T1, class T2>
	void compressed_pair_reference_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4)
	{
	#ifndef __GNUC__
	// gcc 2.90 can't cope with function scope using
	// declarations, and generates an internal compiler error...
	using std::swap;
	#endif
	// both param construct:
	boost::compressed_pair<T1,T2> cp4(p1, p2);
	BOOST_CHECK(cp4.first() == p1);
	BOOST_CHECK(cp4.second() == p2);
	boost::compressed_pair<T1,T2> cp5(p3, p4);
	BOOST_CHECK(cp5.first() == p3);
	BOOST_CHECK(cp5.second() == p4);
	// check const members:
	const boost::compressed_pair<T1,T2>& cpr1 = cp4;
	BOOST_CHECK(cpr1.first() == p1);
	BOOST_CHECK(cpr1.second() == p2);

	// copy construct:
	boost::compressed_pair<T1,T2> cp6(cp4);
	BOOST_CHECK(cp6.first() == p1);
	BOOST_CHECK(cp6.second() == p2);
	// assignment:
	// VC6 bug:
	// When second() is an empty class, VC6 performs the
	// assignment by doing a memcpy - even though the empty
	// class is really a zero sized base class, the result
	// is that the memory of first() gets trampled over.
	// Similar arguments apply to the case that first() is
	// an empty base class.
	// Strangely the problem is dependent upon the compiler
	// settings - some generate the problem others do not.
	cp4.first() = p3;
	cp4.second() = p4;
	BOOST_CHECK(cp4.first() == p3);
	BOOST_CHECK(cp4.second() == p4);
	}
	//
	// supplimentary tests for case where first arg only is a reference type:
	//
	template <class T1, class T2>
	struct compressed_pair_reference1_tester
	{
	// define the types we need:
	typedef T1 first_type;
	typedef T2 second_type;
	typedef typename call_traits<first_type>::param_type first_param_type;
	typedef typename call_traits<second_type>::param_type second_param_type;
	// define our test proc:
	static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
	};

	template <class T1, class T2>
	void compressed_pair_reference1_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
	{
	#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
	// first param construct:
	boost::compressed_pair<T1,T2> cp2(p1);
	cp2.second() = p2;
	BOOST_CHECK(cp2.first() == p1);
	BOOST_CHECK(cp2.second() == p2);
	#endif
	}
	//
	// supplimentary tests for case where second arg only is a reference type:
	//
	template <class T1, class T2>
	struct compressed_pair_reference2_tester
	{
	// define the types we need:
	typedef T1 first_type;
	typedef T2 second_type;
	typedef typename call_traits<first_type>::param_type first_param_type;
	typedef typename call_traits<second_type>::param_type second_param_type;
	// define our test proc:
	static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
	};

	template <class T1, class T2>
	void compressed_pair_reference2_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
	{
	#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
	// second param construct:
	boost::compressed_pair<T1,T2> cp3(p2);
	cp3.first() = p1;
	BOOST_CHECK(cp3.second() == p2);
	BOOST_CHECK(cp3.first() == p1);
	#endif
	}

	//
	// tests for where one or the other parameter is an array:
	//
	template <class T1, class T2>
	struct compressed_pair_array1_tester
	{
	// define the types we need:
	typedef T1 first_type;
	typedef T2 second_type;
	typedef typename call_traits<first_type>::param_type first_param_type;
	typedef typename call_traits<second_type>::param_type second_param_type;
	// define our test proc:
	static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
	};

	template <class T1, class T2>
	void compressed_pair_array1_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
	{
	// default construct:
	boost::compressed_pair<T1,T2> cp1;
	// second param construct:
	boost::compressed_pair<T1,T2> cp3(p2);
	cp3.first()[0] = p1[0];
	BOOST_CHECK(cp3.second() == p2);
	BOOST_CHECK(cp3.first()[0] == p1[0]);
	// check const members:
	const boost::compressed_pair<T1,T2>& cpr1 = cp3;
	BOOST_CHECK(cpr1.first()[0] == p1[0]);
	BOOST_CHECK(cpr1.second() == p2);

	BOOST_CHECK(sizeof(T1) == sizeof(cp1.first()));
	}

	template <class T1, class T2>
	struct compressed_pair_array2_tester
	{
	// define the types we need:
	typedef T1 first_type;
	typedef T2 second_type;
	typedef typename call_traits<first_type>::param_type first_param_type;
	typedef typename call_traits<second_type>::param_type second_param_type;
	// define our test proc:
	static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
	};

	template <class T1, class T2>
	void compressed_pair_array2_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
	{
	// default construct:
	boost::compressed_pair<T1,T2> cp1;
	// first param construct:
	boost::compressed_pair<T1,T2> cp2(p1);
	cp2.second()[0] = p2[0];
	BOOST_CHECK(cp2.first() == p1);
	BOOST_CHECK(cp2.second()[0] == p2[0]);
	// check const members:
	const boost::compressed_pair<T1,T2>& cpr1 = cp2;
	BOOST_CHECK(cpr1.first() == p1);
	BOOST_CHECK(cpr1.second()[0] == p2[0]);

	BOOST_CHECK(sizeof(T2) == sizeof(cp1.second()));
	}

	template <class T1, class T2>
	struct compressed_pair_array_tester
	{
	// define the types we need:
	typedef T1 first_type;
	typedef T2 second_type;
	typedef typename call_traits<first_type>::param_type first_param_type;
	typedef typename call_traits<second_type>::param_type second_param_type;
	// define our test proc:
	static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
	};

	template <class T1, class T2>
	void compressed_pair_array_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
	{
	// default construct:
	boost::compressed_pair<T1,T2> cp1;
	cp1.first()[0] = p1[0];
	cp1.second()[0] = p2[0];
	BOOST_CHECK(cp1.first()[0] == p1[0]);
	BOOST_CHECK(cp1.second()[0] == p2[0]);
	// check const members:
	const boost::compressed_pair<T1,T2>& cpr1 = cp1;
	BOOST_CHECK(cpr1.first()[0] == p1[0]);
	BOOST_CHECK(cpr1.second()[0] == p2[0]);

	BOOST_CHECK(sizeof(T1) == sizeof(cp1.first()));
	BOOST_CHECK(sizeof(T2) == sizeof(cp1.second()));
	}

	int test_main(int, char *[])
	{
	// declare some variables to pass to the tester:
	non_empty1 ne1(2);
	non_empty1 ne2(3);
	non_empty2 ne3(4);
	non_empty2 ne4(5);
	empty_POD_UDT e1;
	empty_UDT e2;

	// T1 != T2, both non-empty
	compressed_pair_tester<non_empty1,non_empty2>::test(ne1, ne3, ne2, ne4);
	// T1 != T2, T2 empty
	compressed_pair_tester<non_empty1,empty_POD_UDT>::test(ne1, e1, ne2, e1);
	// T1 != T2, T1 empty
	compressed_pair_tester<empty_POD_UDT,non_empty2>::test(e1, ne3, e1, ne4);
	// T1 != T2, both empty
	compressed_pair_tester<empty_POD_UDT,empty_UDT>::test(e1, e2, e1, e2);
	// T1 == T2, both non-empty
	compressed_pair_tester<non_empty1,non_empty1>::test(ne1, ne1, ne2, ne2);
	// T1 == T2, both empty
	compressed_pair_tester<empty_UDT,empty_UDT>::test(e2, e2, e2, e2);


	// test references:

	// T1 != T2, both non-empty
	compressed_pair_reference_tester<non_empty1&,non_empty2>::test(ne1, ne3, ne2, ne4);
	compressed_pair_reference_tester<non_empty1,non_empty2&>::test(ne1, ne3, ne2, ne4);
	compressed_pair_reference1_tester<non_empty1&,non_empty2>::test(ne1, ne3, ne2, ne4);
	compressed_pair_reference2_tester<non_empty1,non_empty2&>::test(ne1, ne3, ne2, ne4);
	// T1 != T2, T2 empty
	compressed_pair_reference_tester<non_empty1&,empty_POD_UDT>::test(ne1, e1, ne2, e1);
	compressed_pair_reference1_tester<non_empty1&,empty_POD_UDT>::test(ne1, e1, ne2, e1);
	// T1 != T2, T1 empty
	compressed_pair_reference_tester<empty_POD_UDT,non_empty2&>::test(e1, ne3, e1, ne4);
	compressed_pair_reference2_tester<empty_POD_UDT,non_empty2&>::test(e1, ne3, e1, ne4);
	// T1 == T2, both non-empty
	compressed_pair_reference_tester<non_empty1&,non_empty1&>::test(ne1, ne1, ne2, ne2);

	// tests arrays:
	non_empty1 nea1[2];
	non_empty1 nea2[2];
	non_empty2 nea3[2];
	non_empty2 nea4[2];
	nea1[0] = non_empty1(5);
	nea2[0] = non_empty1(6);
	nea3[0] = non_empty2(7);
	nea4[0] = non_empty2(8);

	// T1 != T2, both non-empty
	compressed_pair_array1_tester<non_empty1[2],non_empty2>::test(nea1, ne3, nea2, ne4);
	compressed_pair_array2_tester<non_empty1,non_empty2[2]>::test(ne1, nea3, ne2, nea4);
	compressed_pair_array_tester<non_empty1[2],non_empty2[2]>::test(nea1, nea3, nea2, nea4);
	// T1 != T2, T2 empty
	compressed_pair_array1_tester<non_empty1[2],empty_POD_UDT>::test(nea1, e1, nea2, e1);
	// T1 != T2, T1 empty
	compressed_pair_array2_tester<empty_POD_UDT,non_empty2[2]>::test(e1, nea3, e1, nea4);
	// T1 == T2, both non-empty
	compressed_pair_array_tester<non_empty1[2],non_empty1[2]>::test(nea1, nea1, nea2, nea2);
	return 0;
	}


	unsigned int expected_failures = 0;