boost_1_45_0/libs/tuple/test/tuple_test_bench.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 // Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
 //
 // 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)

 // For more information, see http://www.boost.org

 //  tuple_test_bench.cpp  --------------------------------

 #define BOOST_INCLUDE_MAIN  // for testing, include rather than link
 #include <boost/test/test_tools.hpp>    // see "Header Implementation Option"

 #include "boost/tuple/tuple.hpp"

 #include "boost/tuple/tuple_comparison.hpp"

 #include "boost/type_traits/is_const.hpp"

 #include "boost/ref.hpp"
 #include <string>
 #include <utility>

 using namespace boost;

 // ----------------------------------------------------------------------------
 // helpers
 // ----------------------------------------------------------------------------

 class A {};
 class B {};
 class C {};

 // classes with different kinds of conversions
 class AA {};
 class BB : public AA {};
 struct CC { CC() {} CC(const BB&) {} };
 struct DD { operator CC() const { return CC(); }; };

 // something to prevent warnings for unused variables
 template<class T> void dummy(const T&) {}

 // no public default constructor
 class foo {
 public:
   explicit foo(int v) : val(v) {}

   bool operator==(const foo& other) const  {
     return val == other.val;
   }

 private:
   foo() {}
   int val;
 };

 // another class without a public default constructor
 class no_def_constructor {
   no_def_constructor() {}
 public:
   no_def_constructor(std::string) {}
 };

 // A non-copyable class
 class no_copy {
   no_copy(const no_copy&) {}
 public:
   no_copy() {};
 };


 // ----------------------------------------------------------------------------
 // Testing different element types --------------------------------------------
 // ----------------------------------------------------------------------------


 typedef tuple<int> t1;

 typedef tuple<double&, const double&, const double, double*, const double*> t2;
 typedef tuple<A, int(*)(char, int), C> t3;
 typedef tuple<std::string, std::pair<A, B> > t4;
 typedef tuple<A*, tuple<const A*, const B&, C>, bool, void*> t5;
 typedef tuple<volatile int, const volatile char&, int(&)(float) > t6;

 # if !defined(__BORLANDC__) || __BORLAND__ > 0x0551
 typedef tuple<B(A::*)(C&), A&> t7;
 #endif

 // -----------------------------------------------------------------------
 // -tuple construction tests ---------------------------------------------
 // -----------------------------------------------------------------------


 no_copy y;
 tuple<no_copy&> x = tuple<no_copy&>(y); // ok

 char cs[10];
 tuple<char(&)[10]> v2(cs);  // ok

 void
 construction_test()
 {

   // Note, the get function can be called without the tuples:: qualifier,
   // as it is lifted to namespace boost with a "using tuples::get" but
   // MSVC 6.0 just cannot find get without the namespace qualifier

   tuple<int> t1;
   BOOST_CHECK(get<0>(t1) == int());

   tuple<float> t2(5.5f);
   BOOST_CHECK(get<0>(t2) > 5.4f && get<0>(t2) < 5.6f);

   tuple<foo> t3(foo(12));
   BOOST_CHECK(get<0>(t3) == foo(12));

   tuple<double> t4(t2);
   BOOST_CHECK(get<0>(t4) > 5.4 && get<0>(t4) < 5.6);

   tuple<int, float> t5;
   BOOST_CHECK(get<0>(t5) == int());
   BOOST_CHECK(get<1>(t5) == float());

   tuple<int, float> t6(12, 5.5f);
   BOOST_CHECK(get<0>(t6) == 12);
   BOOST_CHECK(get<1>(t6) > 5.4f && get<1>(t6) < 5.6f);

   tuple<int, float> t7(t6);
   BOOST_CHECK(get<0>(t7) == 12);
   BOOST_CHECK(get<1>(t7) > 5.4f && get<1>(t7) < 5.6f);

   tuple<long, double> t8(t6);
   BOOST_CHECK(get<0>(t8) == 12);
   BOOST_CHECK(get<1>(t8) > 5.4f && get<1>(t8) < 5.6f);

   dummy(
     tuple<no_def_constructor, no_def_constructor, no_def_constructor>(
        std::string("Jaba"),   // ok, since the default
        std::string("Daba"),   // constructor is not used
        std::string("Doo")
     )
   );

 // testing default values
   dummy(tuple<int, double>());
   dummy(tuple<int, double>(1));
   dummy(tuple<int, double>(1,3.14));


   //  dummy(tuple<double&>()); // should fail, not defaults for references
   //  dummy(tuple<const double&>()); // likewise

   double dd = 5;
   dummy(tuple<double&>(dd)); // ok

   dummy(tuple<const double&>(dd+3.14)); // ok, but dangerous

   //  dummy(tuple<double&>(dd+3.14)); // should fail,
   //                                  // temporary to non-const reference
 }


 // ----------------------------------------------------------------------------
 // - testing element access ---------------------------------------------------
 // ----------------------------------------------------------------------------

 void element_access_test()
 {
   double d = 2.7;
   A a;
   tuple<int, double&, const A&, int> t(1, d, a, 2);
   const tuple<int, double&, const A, int> ct = t;

   int i  = get<0>(t);
   int i2 = get<3>(t);

   BOOST_CHECK(i == 1 && i2 == 2);

   int j  = get<0>(ct);
   BOOST_CHECK(j == 1);

   get<0>(t) = 5;
   BOOST_CHECK(t.head == 5);

   //  get<0>(ct) = 5; // can't assign to const

   double e = get<1>(t);
   BOOST_CHECK(e > 2.69 && e < 2.71);

   get<1>(t) = 3.14+i;
   BOOST_CHECK(get<1>(t) > 4.13 && get<1>(t) < 4.15);

   //  get<4>(t) = A(); // can't assign to const
   //  dummy(get<5>(ct)); // illegal index

   ++get<0>(t);
   BOOST_CHECK(get<0>(t) == 6);

   BOOST_STATIC_ASSERT((boost::is_const<boost::tuples::element<0, tuple<int, float> >::type>::value != true));
 #ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
   BOOST_STATIC_ASSERT((boost::is_const<boost::tuples::element<0, const tuple<int, float> >::type>::value));
 #endif

   BOOST_STATIC_ASSERT((boost::is_const<boost::tuples::element<1, tuple<int, float> >::type>::value != true));
 #ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
   BOOST_STATIC_ASSERT((boost::is_const<boost::tuples::element<1, const tuple<int, float> >::type>::value));
 #endif


   dummy(i); dummy(i2); dummy(j); dummy(e); // avoid warns for unused variables
 }


 // ----------------------------------------------------------------------------
 // - copying tuples -----------------------------------------------------------
 // ----------------------------------------------------------------------------


 void
 copy_test()
 {
   tuple<int, char> t1(4, 'a');
   tuple<int, char> t2(5, 'b');
   t2 = t1;
   BOOST_CHECK(get<0>(t1) == get<0>(t2));
   BOOST_CHECK(get<1>(t1) == get<1>(t2));

   tuple<long, std::string> t3(2, "a");
   t3 = t1;
   BOOST_CHECK((double)get<0>(t1) == get<0>(t3));
   BOOST_CHECK(get<1>(t1) == get<1>(t3)[0]);

 // testing copy and assignment with implicit conversions between elements
 // testing tie

   tuple<char, BB*, BB, DD> t;
   tuple<int, AA*, CC, CC> a(t);
   a = t;

   int i; char c; double d;
   tie(i, c, d) = make_tuple(1, 'a', 5.5);

   BOOST_CHECK(i==1);
   BOOST_CHECK(c=='a');
   BOOST_CHECK(d>5.4 && d<5.6);
 }

 void
 mutate_test()
 {
   tuple<int, float, bool, foo> t1(5, 12.2f, true, foo(4));
   get<0>(t1) = 6;
   get<1>(t1) = 2.2f;
   get<2>(t1) = false;
   get<3>(t1) = foo(5);

   BOOST_CHECK(get<0>(t1) == 6);
   BOOST_CHECK(get<1>(t1) > 2.1f && get<1>(t1) < 2.3f);
   BOOST_CHECK(get<2>(t1) == false);
   BOOST_CHECK(get<3>(t1) == foo(5));
 }

 // ----------------------------------------------------------------------------
 // make_tuple tests -----------------------------------------------------------
 // ----------------------------------------------------------------------------

 void
 make_tuple_test()
 {
   tuple<int, char> t1 = make_tuple(5, 'a');
   BOOST_CHECK(get<0>(t1) == 5);
   BOOST_CHECK(get<1>(t1) == 'a');

   tuple<int, std::string> t2;
   t2 = boost::make_tuple((short int)2, std::string("Hi"));
   BOOST_CHECK(get<0>(t2) == 2);
   BOOST_CHECK(get<1>(t2) == "Hi");


     A a = A(); B b;
     const A ca = a;
     make_tuple(boost::cref(a), b);
     make_tuple(boost::ref(a), b);
     make_tuple(boost::ref(a), boost::cref(b));

     make_tuple(boost::ref(ca));

 // the result of make_tuple is assignable:
    BOOST_CHECK(make_tuple(2, 4, 6) ==
              (make_tuple(1, 2, 3) = make_tuple(2, 4, 6)));

 #ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
     make_tuple("Donald", "Daisy"); // should work;
 #endif
     //    std::make_pair("Doesn't","Work"); // fails

 // You can store a reference to a function in a tuple
     tuple<void(&)()> adf(make_tuple_test);

     dummy(adf); // avoid warning for unused variable

 // But make_tuple doesn't work
 // with function references, since it creates a const qualified function type

 //   make_tuple(make_tuple_test);

 // With function pointers, make_tuple works just fine

 #if !defined(__BORLANDC__) || __BORLAND__ > 0x0551
    make_tuple(&make_tuple_test);
 #endif

 // NOTE:
 //
 // wrapping it the function reference with ref helps on gcc 2.95.2.
 // on edg 2.43. it results in a catastrophic error?

 // make_tuple(ref(foo3));

 // It seems that edg can't use implicitly the ref's conversion operator, e.g.:
 // typedef void (&func_t) (void);
 // func_t fref = static_cast<func_t>(ref(make_tuple_test)); // works fine
 // func_t fref = ref(make_tuple_test);                        // error

 // This is probably not a very common situation, so currently
 // I don't know how which compiler is right (JJ)
 }

 void
 tie_test()
 {
   int a;
   char b;
   foo c(5);

   tie(a, b, c) = make_tuple(2, 'a', foo(3));
   BOOST_CHECK(a == 2);
   BOOST_CHECK(b == 'a');
   BOOST_CHECK(c == foo(3));

   tie(a, tuples::ignore, c) = make_tuple((short int)5, false, foo(5));
   BOOST_CHECK(a == 5);
   BOOST_CHECK(b == 'a');
   BOOST_CHECK(c == foo(5));

 // testing assignment from std::pair
    int i, j;
    tie (i, j) = std::make_pair(1, 2);
    BOOST_CHECK(i == 1 && j == 2);

    tuple<int, int, float> ta;
 #ifdef E11
    ta = std::make_pair(1, 2); // should fail, tuple is of length 3, not 2
 #endif

    dummy(ta);
 }


 // ----------------------------------------------------------------------------
 // - testing tuple equality   -------------------------------------------------
 // ----------------------------------------------------------------------------

 void
 equality_test()
 {
   tuple<int, char> t1(5, 'a');
   tuple<int, char> t2(5, 'a');
   BOOST_CHECK(t1 == t2);

   tuple<int, char> t3(5, 'b');
   tuple<int, char> t4(2, 'a');
   BOOST_CHECK(t1 != t3);
   BOOST_CHECK(t1 != t4);
   BOOST_CHECK(!(t1 != t2));
 }


 // ----------------------------------------------------------------------------
 // - testing tuple comparisons  -----------------------------------------------
 // ----------------------------------------------------------------------------

 void
 ordering_test()
 {
   tuple<int, float> t1(4, 3.3f);
   tuple<short, float> t2(5, 3.3f);
   tuple<long, double> t3(5, 4.4);
   BOOST_CHECK(t1 < t2);
   BOOST_CHECK(t1 <= t2);
   BOOST_CHECK(t2 > t1);
   BOOST_CHECK(t2 >= t1);
   BOOST_CHECK(t2 < t3);
   BOOST_CHECK(t2 <= t3);
   BOOST_CHECK(t3 > t2);
   BOOST_CHECK(t3 >= t2);

 }


 // ----------------------------------------------------------------------------
 // - testing cons lists -------------------------------------------------------
 // ----------------------------------------------------------------------------
 void cons_test()
 {
   using tuples::cons;
   using tuples::null_type;

   cons<volatile float, null_type> a(1, null_type());
   cons<const int, cons<volatile float, null_type> > b(2,a);
   int i = 3;
   cons<int&, cons<const int, cons<volatile float, null_type> > > c(i, b);
   BOOST_CHECK(make_tuple(3,2,1)==c);

   cons<char, cons<int, cons<float, null_type> > > x;
   dummy(x);
 }

 // ----------------------------------------------------------------------------
 // - testing const tuples -----------------------------------------------------
 // ----------------------------------------------------------------------------
 void const_tuple_test()
 {
   const tuple<int, float> t1(5, 3.3f);
   BOOST_CHECK(get<0>(t1) == 5);
   BOOST_CHECK(get<1>(t1) == 3.3f);
 }

 // ----------------------------------------------------------------------------
 // - testing length -----------------------------------------------------------
 // ----------------------------------------------------------------------------
 void tuple_length_test()
 {
   typedef tuple<int, float, double> t1;
   using tuples::cons;
   typedef cons<int, cons< float, cons <double, tuples::null_type> > > t1_cons;
   typedef tuple<> t2;
   typedef tuples::null_type t3;

   BOOST_STATIC_ASSERT(tuples::length<t1>::value == 3);
   BOOST_STATIC_ASSERT(tuples::length<t1_cons>::value == 3);
   BOOST_STATIC_ASSERT(tuples::length<t2>::value == 0);
   BOOST_STATIC_ASSERT(tuples::length<t3>::value == 0);

 }


 // ----------------------------------------------------------------------------
 // - main ---------------------------------------------------------------------
 // ----------------------------------------------------------------------------

 int test_main(int, char *[]) {

   construction_test();
   element_access_test();
   copy_test();
   mutate_test();
   make_tuple_test();
   tie_test();
   equality_test();
   ordering_test();
   cons_test();
   const_tuple_test();
   tuple_length_test();
   return 0;
 }
	// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
	//
	// 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)

	// For more information, see http://www.boost.org

	// tuple_test_bench.cpp --------------------------------

	#define BOOST_INCLUDE_MAIN // for testing, include rather than link
	#include <boost/test/test_tools.hpp> // see "Header Implementation Option"

	#include "boost/tuple/tuple.hpp"

	#include "boost/tuple/tuple_comparison.hpp"

	#include "boost/type_traits/is_const.hpp"

	#include "boost/ref.hpp"
	#include <string>
	#include <utility>

	using namespace boost;

	// ----------------------------------------------------------------------------
	// helpers
	// ----------------------------------------------------------------------------

	class A {};
	class B {};
	class C {};

	// classes with different kinds of conversions
	class AA {};
	class BB : public AA {};
	struct CC { CC() {} CC(const BB&) {} };
	struct DD { operator CC() const { return CC(); }; };

	// something to prevent warnings for unused variables
	template<class T> void dummy(const T&) {}

	// no public default constructor
	class foo {
	public:
	explicit foo(int v) : val(v) {}

	bool operator==(const foo& other) const {
	return val == other.val;
	}

	private:
	foo() {}
	int val;
	};

	// another class without a public default constructor
	class no_def_constructor {
	no_def_constructor() {}
	public:
	no_def_constructor(std::string) {}
	};

	// A non-copyable class
	class no_copy {
	no_copy(const no_copy&) {}
	public:
	no_copy() {};
	};


	// ----------------------------------------------------------------------------
	// Testing different element types --------------------------------------------
	// ----------------------------------------------------------------------------


	typedef tuple<int> t1;

	typedef tuple<double&, const double&, const double, double, const double> t2;
	typedef tuple<A, int(*)(char, int), C> t3;
	typedef tuple<std::string, std::pair<A, B> > t4;
	typedef tuple<A, tuple<const A, const B&, C>, bool, void*> t5;
	typedef tuple<volatile int, const volatile char&, int(&)(float) > t6;

	# if !defined(__BORLANDC__) \|\| __BORLAND__ > 0x0551
	typedef tuple<B(A::*)(C&), A&> t7;
	#endif

	// -----------------------------------------------------------------------
	// -tuple construction tests ---------------------------------------------
	// -----------------------------------------------------------------------


	no_copy y;
	tuple<no_copy&> x = tuple<no_copy&>(y); // ok

	char cs[10];
	tuple<char(&)[10]> v2(cs); // ok

	void
	construction_test()
	{

	// Note, the get function can be called without the tuples:: qualifier,
	// as it is lifted to namespace boost with a "using tuples::get" but
	// MSVC 6.0 just cannot find get without the namespace qualifier

	tuple<int> t1;
	BOOST_CHECK(get<0>(t1) == int());

	tuple<float> t2(5.5f);
	BOOST_CHECK(get<0>(t2) > 5.4f && get<0>(t2) < 5.6f);

	tuple<foo> t3(foo(12));
	BOOST_CHECK(get<0>(t3) == foo(12));

	tuple<double> t4(t2);
	BOOST_CHECK(get<0>(t4) > 5.4 && get<0>(t4) < 5.6);

	tuple<int, float> t5;
	BOOST_CHECK(get<0>(t5) == int());
	BOOST_CHECK(get<1>(t5) == float());

	tuple<int, float> t6(12, 5.5f);
	BOOST_CHECK(get<0>(t6) == 12);
	BOOST_CHECK(get<1>(t6) > 5.4f && get<1>(t6) < 5.6f);

	tuple<int, float> t7(t6);
	BOOST_CHECK(get<0>(t7) == 12);
	BOOST_CHECK(get<1>(t7) > 5.4f && get<1>(t7) < 5.6f);

	tuple<long, double> t8(t6);
	BOOST_CHECK(get<0>(t8) == 12);
	BOOST_CHECK(get<1>(t8) > 5.4f && get<1>(t8) < 5.6f);

	dummy(
	tuple<no_def_constructor, no_def_constructor, no_def_constructor>(
	std::string("Jaba"), // ok, since the default
	std::string("Daba"), // constructor is not used
	std::string("Doo")
	)
	);

	// testing default values
	dummy(tuple<int, double>());
	dummy(tuple<int, double>(1));
	dummy(tuple<int, double>(1,3.14));


	// dummy(tuple<double&>()); // should fail, not defaults for references
	// dummy(tuple<const double&>()); // likewise

	double dd = 5;
	dummy(tuple<double&>(dd)); // ok

	dummy(tuple<const double&>(dd+3.14)); // ok, but dangerous

	// dummy(tuple<double&>(dd+3.14)); // should fail,
	// // temporary to non-const reference
	}


	// ----------------------------------------------------------------------------
	// - testing element access ---------------------------------------------------
	// ----------------------------------------------------------------------------

	void element_access_test()
	{
	double d = 2.7;
	A a;
	tuple<int, double&, const A&, int> t(1, d, a, 2);
	const tuple<int, double&, const A, int> ct = t;

	int i = get<0>(t);
	int i2 = get<3>(t);

	BOOST_CHECK(i == 1 && i2 == 2);

	int j = get<0>(ct);
	BOOST_CHECK(j == 1);

	get<0>(t) = 5;
	BOOST_CHECK(t.head == 5);

	// get<0>(ct) = 5; // can't assign to const

	double e = get<1>(t);
	BOOST_CHECK(e > 2.69 && e < 2.71);

	get<1>(t) = 3.14+i;
	BOOST_CHECK(get<1>(t) > 4.13 && get<1>(t) < 4.15);

	// get<4>(t) = A(); // can't assign to const
	// dummy(get<5>(ct)); // illegal index

	++get<0>(t);
	BOOST_CHECK(get<0>(t) == 6);

	BOOST_STATIC_ASSERT((boost::is_const<boost::tuples::element<0, tuple<int, float> >::type>::value != true));
	#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
	BOOST_STATIC_ASSERT((boost::is_const<boost::tuples::element<0, const tuple<int, float> >::type>::value));
	#endif

	BOOST_STATIC_ASSERT((boost::is_const<boost::tuples::element<1, tuple<int, float> >::type>::value != true));
	#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
	BOOST_STATIC_ASSERT((boost::is_const<boost::tuples::element<1, const tuple<int, float> >::type>::value));
	#endif


	dummy(i); dummy(i2); dummy(j); dummy(e); // avoid warns for unused variables
	}


	// ----------------------------------------------------------------------------
	// - copying tuples -----------------------------------------------------------
	// ----------------------------------------------------------------------------



	void
	copy_test()
	{
	tuple<int, char> t1(4, 'a');
	tuple<int, char> t2(5, 'b');
	t2 = t1;
	BOOST_CHECK(get<0>(t1) == get<0>(t2));
	BOOST_CHECK(get<1>(t1) == get<1>(t2));

	tuple<long, std::string> t3(2, "a");
	t3 = t1;
	BOOST_CHECK((double)get<0>(t1) == get<0>(t3));
	BOOST_CHECK(get<1>(t1) == get<1>(t3)[0]);

	// testing copy and assignment with implicit conversions between elements
	// testing tie

	tuple<char, BB*, BB, DD> t;
	tuple<int, AA*, CC, CC> a(t);
	a = t;

	int i; char c; double d;
	tie(i, c, d) = make_tuple(1, 'a', 5.5);

	BOOST_CHECK(i==1);
	BOOST_CHECK(c=='a');
	BOOST_CHECK(d>5.4 && d<5.6);
	}

	void
	mutate_test()
	{
	tuple<int, float, bool, foo> t1(5, 12.2f, true, foo(4));
	get<0>(t1) = 6;
	get<1>(t1) = 2.2f;
	get<2>(t1) = false;
	get<3>(t1) = foo(5);

	BOOST_CHECK(get<0>(t1) == 6);
	BOOST_CHECK(get<1>(t1) > 2.1f && get<1>(t1) < 2.3f);
	BOOST_CHECK(get<2>(t1) == false);
	BOOST_CHECK(get<3>(t1) == foo(5));
	}

	// ----------------------------------------------------------------------------
	// make_tuple tests -----------------------------------------------------------
	// ----------------------------------------------------------------------------

	void
	make_tuple_test()
	{
	tuple<int, char> t1 = make_tuple(5, 'a');
	BOOST_CHECK(get<0>(t1) == 5);
	BOOST_CHECK(get<1>(t1) == 'a');

	tuple<int, std::string> t2;
	t2 = boost::make_tuple((short int)2, std::string("Hi"));
	BOOST_CHECK(get<0>(t2) == 2);
	BOOST_CHECK(get<1>(t2) == "Hi");


	A a = A(); B b;
	const A ca = a;
	make_tuple(boost::cref(a), b);
	make_tuple(boost::ref(a), b);
	make_tuple(boost::ref(a), boost::cref(b));

	make_tuple(boost::ref(ca));

	// the result of make_tuple is assignable:
	BOOST_CHECK(make_tuple(2, 4, 6) ==
	(make_tuple(1, 2, 3) = make_tuple(2, 4, 6)));

	#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
	make_tuple("Donald", "Daisy"); // should work;
	#endif
	// std::make_pair("Doesn't","Work"); // fails

	// You can store a reference to a function in a tuple
	tuple<void(&)()> adf(make_tuple_test);

	dummy(adf); // avoid warning for unused variable

	// But make_tuple doesn't work
	// with function references, since it creates a const qualified function type

	// make_tuple(make_tuple_test);

	// With function pointers, make_tuple works just fine

	#if !defined(__BORLANDC__) \|\| __BORLAND__ > 0x0551
	make_tuple(&make_tuple_test);
	#endif

	// NOTE:
	//
	// wrapping it the function reference with ref helps on gcc 2.95.2.
	// on edg 2.43. it results in a catastrophic error?

	// make_tuple(ref(foo3));

	// It seems that edg can't use implicitly the ref's conversion operator, e.g.:
	// typedef void (&func_t) (void);
	// func_t fref = static_cast<func_t>(ref(make_tuple_test)); // works fine
	// func_t fref = ref(make_tuple_test); // error

	// This is probably not a very common situation, so currently
	// I don't know how which compiler is right (JJ)
	}

	void
	tie_test()
	{
	int a;
	char b;
	foo c(5);

	tie(a, b, c) = make_tuple(2, 'a', foo(3));
	BOOST_CHECK(a == 2);
	BOOST_CHECK(b == 'a');
	BOOST_CHECK(c == foo(3));

	tie(a, tuples::ignore, c) = make_tuple((short int)5, false, foo(5));
	BOOST_CHECK(a == 5);
	BOOST_CHECK(b == 'a');
	BOOST_CHECK(c == foo(5));

	// testing assignment from std::pair
	int i, j;
	tie (i, j) = std::make_pair(1, 2);
	BOOST_CHECK(i == 1 && j == 2);

	tuple<int, int, float> ta;
	#ifdef E11
	ta = std::make_pair(1, 2); // should fail, tuple is of length 3, not 2
	#endif

	dummy(ta);
	}


	// ----------------------------------------------------------------------------
	// - testing tuple equality -------------------------------------------------
	// ----------------------------------------------------------------------------

	void
	equality_test()
	{
	tuple<int, char> t1(5, 'a');
	tuple<int, char> t2(5, 'a');
	BOOST_CHECK(t1 == t2);

	tuple<int, char> t3(5, 'b');
	tuple<int, char> t4(2, 'a');
	BOOST_CHECK(t1 != t3);
	BOOST_CHECK(t1 != t4);
	BOOST_CHECK(!(t1 != t2));
	}


	// ----------------------------------------------------------------------------
	// - testing tuple comparisons -----------------------------------------------
	// ----------------------------------------------------------------------------

	void
	ordering_test()
	{
	tuple<int, float> t1(4, 3.3f);
	tuple<short, float> t2(5, 3.3f);
	tuple<long, double> t3(5, 4.4);
	BOOST_CHECK(t1 < t2);
	BOOST_CHECK(t1 <= t2);
	BOOST_CHECK(t2 > t1);
	BOOST_CHECK(t2 >= t1);
	BOOST_CHECK(t2 < t3);
	BOOST_CHECK(t2 <= t3);
	BOOST_CHECK(t3 > t2);
	BOOST_CHECK(t3 >= t2);

	}


	// ----------------------------------------------------------------------------
	// - testing cons lists -------------------------------------------------------
	// ----------------------------------------------------------------------------
	void cons_test()
	{
	using tuples::cons;
	using tuples::null_type;

	cons<volatile float, null_type> a(1, null_type());
	cons<const int, cons<volatile float, null_type> > b(2,a);
	int i = 3;
	cons<int&, cons<const int, cons<volatile float, null_type> > > c(i, b);
	BOOST_CHECK(make_tuple(3,2,1)==c);

	cons<char, cons<int, cons<float, null_type> > > x;
	dummy(x);
	}

	// ----------------------------------------------------------------------------
	// - testing const tuples -----------------------------------------------------
	// ----------------------------------------------------------------------------
	void const_tuple_test()
	{
	const tuple<int, float> t1(5, 3.3f);
	BOOST_CHECK(get<0>(t1) == 5);
	BOOST_CHECK(get<1>(t1) == 3.3f);
	}

	// ----------------------------------------------------------------------------
	// - testing length -----------------------------------------------------------
	// ----------------------------------------------------------------------------
	void tuple_length_test()
	{
	typedef tuple<int, float, double> t1;
	using tuples::cons;
	typedef cons<int, cons< float, cons <double, tuples::null_type> > > t1_cons;
	typedef tuple<> t2;
	typedef tuples::null_type t3;

	BOOST_STATIC_ASSERT(tuples::length<t1>::value == 3);
	BOOST_STATIC_ASSERT(tuples::length<t1_cons>::value == 3);
	BOOST_STATIC_ASSERT(tuples::length<t2>::value == 0);
	BOOST_STATIC_ASSERT(tuples::length<t3>::value == 0);

	}




	// ----------------------------------------------------------------------------
	// - main ---------------------------------------------------------------------
	// ----------------------------------------------------------------------------

	int test_main(int, char *[]) {

	construction_test();
	element_access_test();
	copy_test();
	mutate_test();
	make_tuple_test();
	tie_test();
	equality_test();
	ordering_test();
	cons_test();
	const_tuple_test();
	tuple_length_test();
	return 0;
	}