boost_1_45_0/libs/optional/test/optional_test.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 // Copyright (C) 2003, Fernando Luis Cacciola Carballal.
 //
 // 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)
 //
 // See http://www.boost.org/lib/optional for documentation.
 //
 // You are welcome to contact the author at:
 //  fernando_cacciola@hotmail.com
 //
 #include<iostream>
 #include<stdexcept>
 #include<string>

 #define BOOST_ENABLE_ASSERT_HANDLER

 #include "boost/bind/apply.hpp" // Included just to test proper interaction with boost::apply<> as reported by Daniel Wallin

 #include "boost/optional/optional.hpp"

 #ifdef __BORLANDC__
 #pragma hdrstop
 #endif

 #include "boost/none.hpp"

 #include "boost/test/minimal.hpp"

 #include "optional_test_common.cpp"

 void test_implicit_construction ( optional<double> opt, double v, double z )
 {
   check_value(opt,v,z);
 }

 void test_implicit_construction ( optional<X> opt, X const& v, X const& z )
 {
   check_value(opt,v,z);
 }

 void test_default_implicit_construction ( double, optional<double> opt )
 {
   BOOST_CHECK(!opt);
 }

 void test_default_implicit_construction ( X const&, optional<X> opt )
 {
   BOOST_CHECK(!opt);
 }

 //
 // Basic test.
 // Check ordinary functionality:
 //   Initialization, assignment, comparison and value-accessing.
 //
 template<class T>
 void test_basics( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION  );

   T z(0);

   T a(1);

   // Default construction.
   // 'def' state is Uninitialized.
   // T::T() is not called (and it is not even defined)
   optional<T> def ;
   check_uninitialized(def);

   // Implicit construction
   // The first parameter is implicitely converted to optional<T>(a);
   test_implicit_construction(a,a,z);

   // Direct initialization.
   // 'oa' state is Initialized with 'a'
   // T::T( T const& x ) is used.
   set_pending_copy( ARG(T) ) ;
   optional<T> oa ( a ) ;
   check_is_not_pending_copy( ARG(T) );
   check_initialized(oa);
   check_value(oa,a,z);

   T b(2);

   optional<T> ob ;

   // Value-Assignment upon Uninitialized optional.
   // T::T( T const& x ) is used.
   set_pending_copy( ARG(T) ) ;
   ob = a ;
   check_is_not_pending_copy( ARG(T) ) ;
   check_initialized(ob);
   check_value(ob,a,z);

   // Value-Assignment upon Initialized optional.
   // T::operator=( T const& x ) is used
   set_pending_assign( ARG(T) ) ;
   set_pending_copy  ( ARG(T) ) ;
   set_pending_dtor  ( ARG(T) ) ;
   ob = b ;
   check_is_not_pending_assign( ARG(T) ) ;
   check_is_pending_copy      ( ARG(T) ) ;
   check_is_pending_dtor      ( ARG(T) ) ;
   check_initialized(ob);
   check_value(ob,b,z);

   // Assignment initialization.
   // T::T ( T const& x ) is used to copy new value.
   set_pending_copy( ARG(T) ) ;
   optional<T> const oa2 ( oa ) ;
   check_is_not_pending_copy( ARG(T) ) ;
   check_initialized_const(oa2);
   check_value_const(oa2,a,z);

   // Assignment
   // T::operator= ( T const& x ) is used to copy new value.
   set_pending_assign( ARG(T) ) ;
   oa = ob ;
   check_is_not_pending_assign( ARG(T) ) ;
   check_initialized(oa);
   check_value(oa,b,z);

   // Uninitializing Assignment upon Initialized Optional
   // T::~T() is used to destroy previous value in oa.
   set_pending_dtor( ARG(T) ) ;
   set_pending_copy( ARG(T) ) ;
   oa = def ;
   check_is_not_pending_dtor( ARG(T) ) ;
   check_is_pending_copy    ( ARG(T) ) ;
   check_uninitialized(oa);

   // Uninitializing Assignment upon Uninitialized Optional
   // (Dtor is not called this time)
   set_pending_dtor( ARG(T) ) ;
   set_pending_copy( ARG(T) ) ;
   oa = def ;
   check_is_pending_dtor( ARG(T) ) ;
   check_is_pending_copy( ARG(T) ) ;
   check_uninitialized(oa);

   // Deinitialization of Initialized Optional
   // T::~T() is used to destroy previous value in ob.
   set_pending_dtor( ARG(T) ) ;
   ob.reset();
   check_is_not_pending_dtor( ARG(T) ) ;
   check_uninitialized(ob);

   // Deinitialization of Uninitialized Optional
   // (Dtor is not called this time)
   set_pending_dtor( ARG(T) ) ;
   ob.reset();
   check_is_pending_dtor( ARG(T) ) ;
   check_uninitialized(ob);

 }

 template<class T>
 void test_conditional_ctor_and_get_valur_or ( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION  );

   T a(321);

   T z(123);

   optional<T> const cdef0(false,a);

   optional<T> def0(false,a);
   optional<T> def1 = boost::make_optional(false,a); //  T is not within boost so ADL won't find make_optional unqualified
   check_uninitialized(def0);
   check_uninitialized(def1);

   optional<T> const co0(true,a);

   optional<T> o0(true,a);
   optional<T> o1 = boost::make_optional(true,a); //  T is not within boost so ADL won't find make_optional unqualified

   check_initialized(o0);
   check_initialized(o1);
   check_value(o0,a,z);
   check_value(o1,a,z);

   T b = def0.get_value_or(z);
   BOOST_CHECK( b == z ) ;

   b = get_optional_value_or(def0,z);
   BOOST_CHECK( b == z ) ;

   b = o0.get_value_or(z);
   BOOST_CHECK( b == a ) ;

   b = get_optional_value_or(o0,z);
   BOOST_CHECK( b == a ) ;


   T const& crz = z ;
   T&        rz = z ;

   T const& crzz = def0.get_value_or(crz);
   BOOST_CHECK( crzz == crz ) ;

   T& rzz = def0.get_value_or(rz);
   BOOST_CHECK( rzz == rz ) ;

   T const& crzzz = get_optional_value_or(cdef0,crz);
   BOOST_CHECK( crzzz == crz ) ;

   T& rzzz = get_optional_value_or(def0,rz);
   BOOST_CHECK( rzzz == rz ) ;

   T const& crb = o0.get_value_or(crz);
   BOOST_CHECK( crb == a ) ;

   T& rb = o0.get_value_or(rz);
   BOOST_CHECK( rb == b ) ;

   T const& crbb = get_optional_value_or(co0,crz);
   BOOST_CHECK( crbb == b ) ;

   T const& crbbb = get_optional_value_or(o0,crz);
   BOOST_CHECK( crbbb == b ) ;

   T& rbb = get_optional_value_or(o0,rz);
   BOOST_CHECK( rbb == b ) ;

   T& ra = a ;

   optional<T&> defref(false,ra);
   BOOST_CHECK(!defref);

   optional<T&> ref(true,ra);
   BOOST_CHECK(!!ref);

   a = T(432);

   BOOST_CHECK( *ref == a ) ;

   T& r1 = defref.get_value_or(z);
   BOOST_CHECK( r1 == z ) ;

   T& r2 = ref.get_value_or(z);
   BOOST_CHECK( r2 == a ) ;
 }

 //
 // Test Direct Value Manipulation
 //
 template<class T>
 void test_direct_value_manip( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   T x(3);

   optional<T> const c_opt0(x) ;
   optional<T>         opt0(x);

   BOOST_CHECK( c_opt0.get().V() == x.V() ) ;
   BOOST_CHECK(   opt0.get().V() == x.V() ) ;

   BOOST_CHECK( c_opt0->V() == x.V() ) ;
   BOOST_CHECK(   opt0->V() == x.V() ) ;

   BOOST_CHECK( (*c_opt0).V() == x.V() ) ;
   BOOST_CHECK( (*  opt0).V() == x.V() ) ;

   T y(4);
   opt0 = y ;
   BOOST_CHECK( get(opt0).V() == y.V() ) ;
 }

 //
 // Test Uninitialized access assert
 //
 template<class T>
 void test_uninitialized_access( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   optional<T> def ;

   bool passed = false ;
   try
   {
     // This should throw because 'def' is uninitialized
     T const& n = def.get() ;
     unused_variable(n);
     passed = true ;
   }
   catch (...) {}
   BOOST_CHECK(!passed);

   passed = false ;
   try
   {
     // This should throw because 'def' is uninitialized
     T const& n = *def ;
     unused_variable(n);
     passed = true ;
   }
   catch (...) {}
   BOOST_CHECK(!passed);

   passed = false ;
   try
   {
     T v(5) ;
     unused_variable(v);
     // This should throw because 'def' is uninitialized
     *def = v ;
     passed = true ;
   }
   catch (...) {}
   BOOST_CHECK(!passed);

   passed = false ;
   try
   {
     // This should throw because 'def' is uninitialized
     T v = *(def.operator->()) ;
     unused_variable(v);
     passed = true ;
   }
   catch (...) {}
   BOOST_CHECK(!passed);
 }

 #if BOOST_WORKAROUND( BOOST_INTEL_CXX_VERSION, <= 700) // Intel C++ 7.0
 void prevent_buggy_optimization( bool v ) {}
 #endif

 //
 // Test Direct Initialization of optional for a T with throwing copy-ctor.
 //
 template<class T>
 void test_throwing_direct_init( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   T a(6);

   int count = get_instance_count( ARG(T) ) ;

   set_throw_on_copy( ARG(T) ) ;

   bool passed = false ;
   try
   {
     // This should:
     //   Attempt to copy construct 'a' and throw.
     // 'opt' won't be constructed.
     set_pending_copy( ARG(T) ) ;

 #if BOOST_WORKAROUND( BOOST_INTEL_CXX_VERSION, <= 700) // Intel C++ 7.0
     // Intel C++ 7.0 specific:
     //    For some reason, when "check_is_not_pending_copy",
     //    after the exception block is reached,
     //    X::pending_copy==true even though X's copy ctor set it to false.
     //    I guessed there is some sort of optimization bug,
     //    and it seems to be the since the following additional line just
     //    solves the problem (!?)
     prevent_buggy_optimization(X::pending_copy);
 #endif

     optional<T> opt(a) ;
     passed = true ;
   }
   catch ( ... ){}

   BOOST_CHECK(!passed);
   check_is_not_pending_copy( ARG(T) );
   check_instance_count(count, ARG(T) );

   reset_throw_on_copy( ARG(T) ) ;

 }

 //
 // Test Value Assignment to an Uninitialized optional for a T with a throwing copy-ctor
 //
 template<class T>
 void test_throwing_val_assign_on_uninitialized( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   T a(7);

   int count = get_instance_count( ARG(T) ) ;

   set_throw_on_copy( ARG(T) ) ;

   optional<T> opt ;

   bool passed = false ;
   try
   {
     // This should:
     //   Attempt to copy construct 'a' and throw.
     //   opt should be left uninitialized.
     set_pending_copy( ARG(T) ) ;
     opt.reset( a );
     passed = true ;
   }
   catch ( ... ) {}

   BOOST_CHECK(!passed);

   check_is_not_pending_copy( ARG(T) );
   check_instance_count(count, ARG(T) );
   check_uninitialized(opt);

   reset_throw_on_copy( ARG(T) ) ;
 }

 //
 // Test Value Reset on an Initialized optional for a T with a throwing copy-ctor
 //
 template<class T>
 void test_throwing_val_assign_on_initialized( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   T z(0);
   T a(8);
   T b(9);
   T x(-1);

   int count = get_instance_count( ARG(T) ) ;

   optional<T> opt ( b ) ;
   ++ count ;

   check_instance_count(count, ARG(T) );

   check_value(opt,b,z);

   set_throw_on_assign( ARG(T) ) ;

   bool passed = false ;
   try
   {
     // This should:
     //   Attempt to assign 'a' and throw.
     //   opt is kept initialized but its value not neccesarily fully assigned
     //   (in this test, incompletely assigned is flaged with the value -1 being set)
     set_pending_assign( ARG(T) ) ;
     opt.reset ( a ) ;
     passed = true ;
   }
   catch ( ... ) {}

   BOOST_CHECK(!passed);

   check_is_not_pending_assign( ARG(T) );
   check_instance_count(count, ARG(T) );
   check_initialized(opt);
   check_value(opt,x,z);

   reset_throw_on_assign ( ARG(T) ) ;
 }

 //
 // Test Copy Initialization from an Initialized optional for a T with a throwing copy-ctor
 //
 template<class T>
 void test_throwing_copy_initialization( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   T z(0);
   T a(10);

   optional<T> opt (a);

   int count = get_instance_count( ARG(T) ) ;

   set_throw_on_copy( ARG(T) ) ;

   bool passed = false ;
   try
   {
     // This should:
     //   Attempt to copy construct 'opt' and throw.
     //   opt1 won't be constructed.
     set_pending_copy( ARG(T) ) ;
     optional<T> opt1 = opt ;
     passed = true ;
   }
   catch ( ... ) {}

   BOOST_CHECK(!passed);

   check_is_not_pending_copy( ARG(T) );
   check_instance_count(count, ARG(T) );

   // Nothing should have happened to the source optional.
   check_initialized(opt);
   check_value(opt,a,z);

   reset_throw_on_copy( ARG(T) ) ;
 }

 //
 // Test Assignment to an Uninitialized optional from an Initialized optional
 // for a T with a throwing copy-ctor
 //
 template<class T>
 void test_throwing_assign_to_uninitialized( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   T z(0);
   T a(11);

   optional<T> opt0 ;
   optional<T> opt1(a) ;

   int count = get_instance_count( ARG(T) ) ;

   set_throw_on_copy( ARG(T) ) ;

   bool passed = false ;
   try
   {
     // This should:
     //   Attempt to copy construct 'opt1.value()' into opt0 and throw.
     //   opt0 should be left uninitialized.
     set_pending_copy( ARG(T) ) ;
     opt0 = opt1 ;
     passed = true ;
   }
   catch ( ... ) {}

   BOOST_CHECK(!passed);

   check_is_not_pending_copy( ARG(T) );
   check_instance_count(count, ARG(T) );
   check_uninitialized(opt0);

   reset_throw_on_copy( ARG(T) ) ;
 }

 //
 // Test Assignment to an Initialized optional from an Initialized optional
 // for a T with a throwing copy-ctor
 //
 template<class T>
 void test_throwing_assign_to_initialized( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   T z(0);
   T a(12);
   T b(13);
   T x(-1);

   optional<T> opt0(a) ;
   optional<T> opt1(b) ;

   int count = get_instance_count( ARG(T) ) ;

   set_throw_on_assign( ARG(T) ) ;

   bool passed = false ;
   try
   {
     // This should:
     //   Attempt to copy construct 'opt1.value()' into opt0 and throw.
     //   opt0 is kept initialized but its value not neccesarily fully assigned
     //   (in this test, incompletely assigned is flaged with the value -1 being set)
     set_pending_assign( ARG(T) ) ;
     opt0 = opt1 ;
     passed = true ;
   }
   catch ( ... ) {}

   BOOST_CHECK(!passed);

   // opt0 was left uninitialized
   check_is_not_pending_assign( ARG(T) );
   check_instance_count(count, ARG(T) );
   check_initialized(opt0);
   check_value(opt0,x,z);

   reset_throw_on_assign( ARG(T) ) ;
 }

 //
 // Test swap in a no-throwing case
 //
 template<class T>
 void test_no_throwing_swap( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   T z(0);
   T a(14);
   T b(15);

   optional<T> def0 ;
   optional<T> def1 ;
   optional<T> opt0(a) ;
   optional<T> opt1(b) ;

   int count = get_instance_count( ARG(T) ) ;

   swap(def0,def1);
   check_uninitialized(def0);
   check_uninitialized(def1);

   swap(def0,opt0);
   check_uninitialized(opt0);
   check_initialized(def0);
   check_value(def0,a,z);

   // restore def0 and opt0
   swap(def0,opt0);

   swap(opt0,opt1);
   check_instance_count(count, ARG(T) );
   check_initialized(opt0);
   check_initialized(opt1);
   check_value(opt0,b,z);
   check_value(opt1,a,z);
 }

 //
 // Test swap in a throwing case
 //
 template<class T>
 void test_throwing_swap( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   T a(16);
   T b(17);
   T x(-1);

   optional<T> opt0(a) ;
   optional<T> opt1(b) ;

   set_throw_on_assign( ARG(T) ) ;

   //
   // Case 1: Both Initialized.
   //
   bool passed = false ;
   try
   {
     // This should attempt to swap optionals and fail at swap(X&,X&).
     swap(opt0,opt1);

     passed = true ;
   }
   catch ( ... ) {}

   BOOST_CHECK(!passed);

   // optional's swap doesn't affect the initialized states of the arguments. Therefore,
   // the following must hold:
   check_initialized(opt0);
   check_initialized(opt1);
   check_value(opt0,x,a);
   check_value(opt1,b,x);


   //
   // Case 2: Only one Initialized.
   //
   reset_throw_on_assign( ARG(T) ) ;

   opt0.reset();
   opt1.reset(a);

   set_throw_on_copy( ARG(T) ) ;

   passed = false ;
   try
   {
     // This should attempt to swap optionals and fail at opt0.reset(*opt1)
     // Both opt0 and op1 are left unchanged (unswaped)
     swap(opt0,opt1);

     passed = true ;
   }
   catch ( ... ) {}

   BOOST_CHECK(!passed);

   check_uninitialized(opt0);
   check_initialized(opt1);
   check_value(opt1,a,x);

   reset_throw_on_copy( ARG(T) ) ;
 }

 //
 // This verifies relational operators.
 //
 template<class T>
 void test_relops( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   T v0(0);
   T v1(1);
   T v2(1);

   optional<T> def0 ;
   optional<T> def1 ;
   optional<T> opt0(v0);
   optional<T> opt1(v1);
   optional<T> opt2(v2);

   // Check identity
   BOOST_CHECK ( def0 == def0 ) ;
   BOOST_CHECK ( opt0 == opt0 ) ;
   BOOST_CHECK ( !(def0 != def0) ) ;
   BOOST_CHECK ( !(opt0 != opt0) ) ;

   // Check when both are uininitalized.
   BOOST_CHECK (   def0 == def1  ) ; // both uninitialized compare equal
   BOOST_CHECK ( !(def0 <  def1) ) ; // uninitialized is never less    than uninitialized
   BOOST_CHECK ( !(def0 >  def1) ) ; // uninitialized is never greater than uninitialized
   BOOST_CHECK ( !(def0 != def1) ) ;
   BOOST_CHECK (   def0 <= def1  ) ;
   BOOST_CHECK (   def0 >= def1  ) ;

   // Check when only lhs is uninitialized.
   BOOST_CHECK (   def0 != opt0  ) ; // uninitialized is never equal to initialized
   BOOST_CHECK ( !(def0 == opt0) ) ;
   BOOST_CHECK (   def0 <  opt0  ) ; // uninitialized is always less than initialized
   BOOST_CHECK ( !(def0 >  opt0) ) ;
   BOOST_CHECK (   def0 <= opt0  ) ;
   BOOST_CHECK ( !(def0 >= opt0) ) ;

   // Check when only rhs is uninitialized.
   BOOST_CHECK (   opt0 != def0  ) ; // initialized is never equal to uninitialized
   BOOST_CHECK ( !(opt0 == def0) ) ;
   BOOST_CHECK ( !(opt0 <  def0) ) ; // initialized is never less than uninitialized
   BOOST_CHECK (   opt0 >  def0  ) ;
   BOOST_CHECK ( !(opt0 <= def0) ) ;
   BOOST_CHECK (   opt0 >= opt0  ) ;

   // If both are initialized, values are compared
   BOOST_CHECK ( opt0 != opt1 ) ;
   BOOST_CHECK ( opt1 == opt2 ) ;
   BOOST_CHECK ( opt0 <  opt1 ) ;
   BOOST_CHECK ( opt1 >  opt0 ) ;
   BOOST_CHECK ( opt1 <= opt2 ) ;
   BOOST_CHECK ( opt1 >= opt0 ) ;

   // Compare against a value directly
   BOOST_CHECK ( opt0 == v0 ) ;
   BOOST_CHECK ( opt0 != v1 ) ;
   BOOST_CHECK ( opt1 == v2 ) ;
   BOOST_CHECK ( opt0 <  v1 ) ;
   BOOST_CHECK ( opt1 >  v0 ) ;
   BOOST_CHECK ( opt1 <= v2 ) ;
   BOOST_CHECK ( opt1 >= v0 ) ;
   BOOST_CHECK ( v0 != opt1 ) ;
   BOOST_CHECK ( v1 == opt2 ) ;
   BOOST_CHECK ( v0 <  opt1 ) ;
   BOOST_CHECK ( v1 >  opt0 ) ;
   BOOST_CHECK ( v1 <= opt2 ) ;
   BOOST_CHECK ( v1 >= opt0 ) ;
   BOOST_CHECK (   def0 != v0  ) ;
   BOOST_CHECK ( !(def0 == v0) ) ;
   BOOST_CHECK (   def0 <  v0  ) ;
   BOOST_CHECK ( !(def0 >  v0) ) ;
   BOOST_CHECK (   def0 <= v0  ) ;
   BOOST_CHECK ( !(def0 >= v0) ) ;
   BOOST_CHECK (   v0 != def0  ) ;
   BOOST_CHECK ( !(v0 == def0) ) ;
   BOOST_CHECK ( !(v0 <  def0) ) ;
   BOOST_CHECK (   v0 >  def0  ) ;
   BOOST_CHECK ( !(v0 <= def0) ) ;
   BOOST_CHECK (   v0 >= opt0  ) ;
 }

 template<class T>
 void test_none( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   using boost::none ;

   optional<T> def0 ;
   optional<T> def1(none) ;
   optional<T> non_def( T(1234) ) ;

   BOOST_CHECK ( def0    == none ) ;
   BOOST_CHECK ( non_def != none ) ;
   BOOST_CHECK ( !def1           ) ;
   BOOST_CHECK ( !(non_def <  none) ) ;
   BOOST_CHECK (   non_def >  none  ) ;
   BOOST_CHECK ( !(non_def <= none) ) ;
   BOOST_CHECK (   non_def >= none  ) ;

   non_def = none ;
   BOOST_CHECK ( !non_def ) ;

   test_default_implicit_construction(T(1),none);
 }

 template<class T>
 void test_arrow( T const* )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   T a(1234);

   optional<T>        oa(a) ;
   optional<T> const coa(a) ;

   BOOST_CHECK ( coa->V() == 1234 ) ;

   oa->V() = 4321 ;

   BOOST_CHECK (     a.V() = 1234 ) ;
   BOOST_CHECK ( (*oa).V() = 4321 ) ;
 }

 void test_with_builtin_types()
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   test_basics( ARG(double) );
   test_conditional_ctor_and_get_valur_or( ARG(double) );
   test_uninitialized_access( ARG(double) );
   test_no_throwing_swap( ARG(double) );
   test_relops( ARG(double) ) ;
   test_none( ARG(double) ) ;
 }

 void test_with_class_type()
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   test_basics( ARG(X) );
   test_conditional_ctor_and_get_valur_or( ARG(X) );
   test_direct_value_manip( ARG(X) );
   test_uninitialized_access( ARG(X) );
   test_throwing_direct_init( ARG(X) );
   test_throwing_val_assign_on_uninitialized( ARG(X) );
   test_throwing_val_assign_on_initialized( ARG(X) );
   test_throwing_copy_initialization( ARG(X) );
   test_throwing_assign_to_uninitialized( ARG(X) );
   test_throwing_assign_to_initialized( ARG(X) );
   test_no_throwing_swap( ARG(X) );
   test_throwing_swap( ARG(X) );
   test_relops( ARG(X) ) ;
   test_none( ARG(X) ) ;
   test_arrow( ARG(X) ) ;
   BOOST_CHECK ( X::count == 0 ) ;
 }

 int eat ( bool ) { return 1 ; }
 int eat ( char ) { return 1 ; }
 int eat ( int  ) { return 1 ; }
 int eat ( void const* ) { return 1 ; }

 template<class T> int eat ( T ) { return 0 ; }

 //
 // This verifies that operator safe_bool() behaves properly.
 //
 template<class T>
 void test_no_implicit_conversions_impl( T const& )
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   optional<T> def ;
   BOOST_CHECK ( eat(def) == 0 ) ;
 }

 void test_no_implicit_conversions()
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION   );

   bool b = false ;
   char c = 0 ;
   int i = 0 ;
   void const* p = 0 ;

   test_no_implicit_conversions_impl(b);
   test_no_implicit_conversions_impl(c);
   test_no_implicit_conversions_impl(i);
   test_no_implicit_conversions_impl(p);
 }

 struct A {} ;
 void test_conversions1()
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION );

 #ifndef BOOST_OPTIONAL_NO_CONVERTING_COPY_CTOR
   char c = 20 ;
   optional<char> opt0(c);
   optional<int> opt1(opt0);
   BOOST_CHECK(*opt1 == static_cast<int>(c));
 #endif

 #ifndef BOOST_OPTIONAL_NO_CONVERTING_ASSIGNMENT
   float f = 21.22f ;
   double d = f ;
   optional<float> opt2(f) ;
   optional<double> opt3 ;
   opt3 = opt2 ;
   BOOST_CHECK(*opt3 == d);
 #endif
 }

 void test_conversions2()
 {
   TRACE( std::endl << BOOST_CURRENT_FUNCTION );

   char c = 20 ;
   optional<int> opt(c);
   BOOST_CHECK( get(opt) == static_cast<int>(c));

   float f = 21.22f ;
   optional<double> opt1;
   opt1 = f ;
   BOOST_CHECK(*get(&opt1) == static_cast<double>(f));
 }

 int test_main( int, char* [] )
 {
   try
   {
     test_with_class_type();
     test_with_builtin_types();
     test_no_implicit_conversions();
     test_conversions1();
     test_conversions2();
   }
   catch ( ... )
   {
     BOOST_ERROR("Unexpected Exception caught!");
   }

   return 0;
 }
	// Copyright (C) 2003, Fernando Luis Cacciola Carballal.
	//
	// 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)
	//
	// See http://www.boost.org/lib/optional for documentation.
	//
	// You are welcome to contact the author at:
	// fernando_cacciola@hotmail.com
	//
	#include<iostream>
	#include<stdexcept>
	#include<string>

	#define BOOST_ENABLE_ASSERT_HANDLER

	#include "boost/bind/apply.hpp" // Included just to test proper interaction with boost::apply<> as reported by Daniel Wallin

	#include "boost/optional/optional.hpp"

	#ifdef __BORLANDC__
	#pragma hdrstop
	#endif

	#include "boost/none.hpp"

	#include "boost/test/minimal.hpp"

	#include "optional_test_common.cpp"

	void test_implicit_construction ( optional<double> opt, double v, double z )
	{
	check_value(opt,v,z);
	}

	void test_implicit_construction ( optional<X> opt, X const& v, X const& z )
	{
	check_value(opt,v,z);
	}

	void test_default_implicit_construction ( double, optional<double> opt )
	{
	BOOST_CHECK(!opt);
	}

	void test_default_implicit_construction ( X const&, optional<X> opt )
	{
	BOOST_CHECK(!opt);
	}

	//
	// Basic test.
	// Check ordinary functionality:
	// Initialization, assignment, comparison and value-accessing.
	//
	template<class T>
	void test_basics( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T z(0);

	T a(1);

	// Default construction.
	// 'def' state is Uninitialized.
	// T::T() is not called (and it is not even defined)
	optional<T> def ;
	check_uninitialized(def);

	// Implicit construction
	// The first parameter is implicitely converted to optional<T>(a);
	test_implicit_construction(a,a,z);

	// Direct initialization.
	// 'oa' state is Initialized with 'a'
	// T::T( T const& x ) is used.
	set_pending_copy( ARG(T) ) ;
	optional<T> oa ( a ) ;
	check_is_not_pending_copy( ARG(T) );
	check_initialized(oa);
	check_value(oa,a,z);

	T b(2);

	optional<T> ob ;

	// Value-Assignment upon Uninitialized optional.
	// T::T( T const& x ) is used.
	set_pending_copy( ARG(T) ) ;
	ob = a ;
	check_is_not_pending_copy( ARG(T) ) ;
	check_initialized(ob);
	check_value(ob,a,z);

	// Value-Assignment upon Initialized optional.
	// T::operator=( T const& x ) is used
	set_pending_assign( ARG(T) ) ;
	set_pending_copy ( ARG(T) ) ;
	set_pending_dtor ( ARG(T) ) ;
	ob = b ;
	check_is_not_pending_assign( ARG(T) ) ;
	check_is_pending_copy ( ARG(T) ) ;
	check_is_pending_dtor ( ARG(T) ) ;
	check_initialized(ob);
	check_value(ob,b,z);

	// Assignment initialization.
	// T::T ( T const& x ) is used to copy new value.
	set_pending_copy( ARG(T) ) ;
	optional<T> const oa2 ( oa ) ;
	check_is_not_pending_copy( ARG(T) ) ;
	check_initialized_const(oa2);
	check_value_const(oa2,a,z);

	// Assignment
	// T::operator= ( T const& x ) is used to copy new value.
	set_pending_assign( ARG(T) ) ;
	oa = ob ;
	check_is_not_pending_assign( ARG(T) ) ;
	check_initialized(oa);
	check_value(oa,b,z);

	// Uninitializing Assignment upon Initialized Optional
	// T::~T() is used to destroy previous value in oa.
	set_pending_dtor( ARG(T) ) ;
	set_pending_copy( ARG(T) ) ;
	oa = def ;
	check_is_not_pending_dtor( ARG(T) ) ;
	check_is_pending_copy ( ARG(T) ) ;
	check_uninitialized(oa);

	// Uninitializing Assignment upon Uninitialized Optional
	// (Dtor is not called this time)
	set_pending_dtor( ARG(T) ) ;
	set_pending_copy( ARG(T) ) ;
	oa = def ;
	check_is_pending_dtor( ARG(T) ) ;
	check_is_pending_copy( ARG(T) ) ;
	check_uninitialized(oa);

	// Deinitialization of Initialized Optional
	// T::~T() is used to destroy previous value in ob.
	set_pending_dtor( ARG(T) ) ;
	ob.reset();
	check_is_not_pending_dtor( ARG(T) ) ;
	check_uninitialized(ob);

	// Deinitialization of Uninitialized Optional
	// (Dtor is not called this time)
	set_pending_dtor( ARG(T) ) ;
	ob.reset();
	check_is_pending_dtor( ARG(T) ) ;
	check_uninitialized(ob);

	}

	template<class T>
	void test_conditional_ctor_and_get_valur_or ( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T a(321);

	T z(123);

	optional<T> const cdef0(false,a);

	optional<T> def0(false,a);
	optional<T> def1 = boost::make_optional(false,a); // T is not within boost so ADL won't find make_optional unqualified
	check_uninitialized(def0);
	check_uninitialized(def1);

	optional<T> const co0(true,a);

	optional<T> o0(true,a);
	optional<T> o1 = boost::make_optional(true,a); // T is not within boost so ADL won't find make_optional unqualified

	check_initialized(o0);
	check_initialized(o1);
	check_value(o0,a,z);
	check_value(o1,a,z);

	T b = def0.get_value_or(z);
	BOOST_CHECK( b == z ) ;

	b = get_optional_value_or(def0,z);
	BOOST_CHECK( b == z ) ;

	b = o0.get_value_or(z);
	BOOST_CHECK( b == a ) ;

	b = get_optional_value_or(o0,z);
	BOOST_CHECK( b == a ) ;


	T const& crz = z ;
	T& rz = z ;

	T const& crzz = def0.get_value_or(crz);
	BOOST_CHECK( crzz == crz ) ;

	T& rzz = def0.get_value_or(rz);
	BOOST_CHECK( rzz == rz ) ;

	T const& crzzz = get_optional_value_or(cdef0,crz);
	BOOST_CHECK( crzzz == crz ) ;

	T& rzzz = get_optional_value_or(def0,rz);
	BOOST_CHECK( rzzz == rz ) ;

	T const& crb = o0.get_value_or(crz);
	BOOST_CHECK( crb == a ) ;

	T& rb = o0.get_value_or(rz);
	BOOST_CHECK( rb == b ) ;

	T const& crbb = get_optional_value_or(co0,crz);
	BOOST_CHECK( crbb == b ) ;

	T const& crbbb = get_optional_value_or(o0,crz);
	BOOST_CHECK( crbbb == b ) ;

	T& rbb = get_optional_value_or(o0,rz);
	BOOST_CHECK( rbb == b ) ;

	T& ra = a ;

	optional<T&> defref(false,ra);
	BOOST_CHECK(!defref);

	optional<T&> ref(true,ra);
	BOOST_CHECK(!!ref);

	a = T(432);

	BOOST_CHECK( *ref == a ) ;

	T& r1 = defref.get_value_or(z);
	BOOST_CHECK( r1 == z ) ;

	T& r2 = ref.get_value_or(z);
	BOOST_CHECK( r2 == a ) ;
	}

	//
	// Test Direct Value Manipulation
	//
	template<class T>
	void test_direct_value_manip( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T x(3);

	optional<T> const c_opt0(x) ;
	optional<T> opt0(x);

	BOOST_CHECK( c_opt0.get().V() == x.V() ) ;
	BOOST_CHECK( opt0.get().V() == x.V() ) ;

	BOOST_CHECK( c_opt0->V() == x.V() ) ;
	BOOST_CHECK( opt0->V() == x.V() ) ;

	BOOST_CHECK( (*c_opt0).V() == x.V() ) ;
	BOOST_CHECK( (* opt0).V() == x.V() ) ;

	T y(4);
	opt0 = y ;
	BOOST_CHECK( get(opt0).V() == y.V() ) ;
	}

	//
	// Test Uninitialized access assert
	//
	template<class T>
	void test_uninitialized_access( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	optional<T> def ;

	bool passed = false ;
	try
	{
	// This should throw because 'def' is uninitialized
	T const& n = def.get() ;
	unused_variable(n);
	passed = true ;
	}
	catch (...) {}
	BOOST_CHECK(!passed);

	passed = false ;
	try
	{
	// This should throw because 'def' is uninitialized
	T const& n = *def ;
	unused_variable(n);
	passed = true ;
	}
	catch (...) {}
	BOOST_CHECK(!passed);

	passed = false ;
	try
	{
	T v(5) ;
	unused_variable(v);
	// This should throw because 'def' is uninitialized
	*def = v ;
	passed = true ;
	}
	catch (...) {}
	BOOST_CHECK(!passed);

	passed = false ;
	try
	{
	// This should throw because 'def' is uninitialized
	T v = *(def.operator->()) ;
	unused_variable(v);
	passed = true ;
	}
	catch (...) {}
	BOOST_CHECK(!passed);
	}

	#if BOOST_WORKAROUND( BOOST_INTEL_CXX_VERSION, <= 700) // Intel C++ 7.0
	void prevent_buggy_optimization( bool v ) {}
	#endif

	//
	// Test Direct Initialization of optional for a T with throwing copy-ctor.
	//
	template<class T>
	void test_throwing_direct_init( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T a(6);

	int count = get_instance_count( ARG(T) ) ;

	set_throw_on_copy( ARG(T) ) ;

	bool passed = false ;
	try
	{
	// This should:
	// Attempt to copy construct 'a' and throw.
	// 'opt' won't be constructed.
	set_pending_copy( ARG(T) ) ;

	#if BOOST_WORKAROUND( BOOST_INTEL_CXX_VERSION, <= 700) // Intel C++ 7.0
	// Intel C++ 7.0 specific:
	// For some reason, when "check_is_not_pending_copy",
	// after the exception block is reached,
	// X::pending_copy==true even though X's copy ctor set it to false.
	// I guessed there is some sort of optimization bug,
	// and it seems to be the since the following additional line just
	// solves the problem (!?)
	prevent_buggy_optimization(X::pending_copy);
	#endif

	optional<T> opt(a) ;
	passed = true ;
	}
	catch ( ... ){}

	BOOST_CHECK(!passed);
	check_is_not_pending_copy( ARG(T) );
	check_instance_count(count, ARG(T) );

	reset_throw_on_copy( ARG(T) ) ;

	}

	//
	// Test Value Assignment to an Uninitialized optional for a T with a throwing copy-ctor
	//
	template<class T>
	void test_throwing_val_assign_on_uninitialized( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T a(7);

	int count = get_instance_count( ARG(T) ) ;

	set_throw_on_copy( ARG(T) ) ;

	optional<T> opt ;

	bool passed = false ;
	try
	{
	// This should:
	// Attempt to copy construct 'a' and throw.
	// opt should be left uninitialized.
	set_pending_copy( ARG(T) ) ;
	opt.reset( a );
	passed = true ;
	}
	catch ( ... ) {}

	BOOST_CHECK(!passed);

	check_is_not_pending_copy( ARG(T) );
	check_instance_count(count, ARG(T) );
	check_uninitialized(opt);

	reset_throw_on_copy( ARG(T) ) ;
	}

	//
	// Test Value Reset on an Initialized optional for a T with a throwing copy-ctor
	//
	template<class T>
	void test_throwing_val_assign_on_initialized( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T z(0);
	T a(8);
	T b(9);
	T x(-1);

	int count = get_instance_count( ARG(T) ) ;

	optional<T> opt ( b ) ;
	++ count ;

	check_instance_count(count, ARG(T) );

	check_value(opt,b,z);

	set_throw_on_assign( ARG(T) ) ;

	bool passed = false ;
	try
	{
	// This should:
	// Attempt to assign 'a' and throw.
	// opt is kept initialized but its value not neccesarily fully assigned
	// (in this test, incompletely assigned is flaged with the value -1 being set)
	set_pending_assign( ARG(T) ) ;
	opt.reset ( a ) ;
	passed = true ;
	}
	catch ( ... ) {}

	BOOST_CHECK(!passed);

	check_is_not_pending_assign( ARG(T) );
	check_instance_count(count, ARG(T) );
	check_initialized(opt);
	check_value(opt,x,z);

	reset_throw_on_assign ( ARG(T) ) ;
	}

	//
	// Test Copy Initialization from an Initialized optional for a T with a throwing copy-ctor
	//
	template<class T>
	void test_throwing_copy_initialization( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T z(0);
	T a(10);

	optional<T> opt (a);

	int count = get_instance_count( ARG(T) ) ;

	set_throw_on_copy( ARG(T) ) ;

	bool passed = false ;
	try
	{
	// This should:
	// Attempt to copy construct 'opt' and throw.
	// opt1 won't be constructed.
	set_pending_copy( ARG(T) ) ;
	optional<T> opt1 = opt ;
	passed = true ;
	}
	catch ( ... ) {}

	BOOST_CHECK(!passed);

	check_is_not_pending_copy( ARG(T) );
	check_instance_count(count, ARG(T) );

	// Nothing should have happened to the source optional.
	check_initialized(opt);
	check_value(opt,a,z);

	reset_throw_on_copy( ARG(T) ) ;
	}

	//
	// Test Assignment to an Uninitialized optional from an Initialized optional
	// for a T with a throwing copy-ctor
	//
	template<class T>
	void test_throwing_assign_to_uninitialized( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T z(0);
	T a(11);

	optional<T> opt0 ;
	optional<T> opt1(a) ;

	int count = get_instance_count( ARG(T) ) ;

	set_throw_on_copy( ARG(T) ) ;

	bool passed = false ;
	try
	{
	// This should:
	// Attempt to copy construct 'opt1.value()' into opt0 and throw.
	// opt0 should be left uninitialized.
	set_pending_copy( ARG(T) ) ;
	opt0 = opt1 ;
	passed = true ;
	}
	catch ( ... ) {}

	BOOST_CHECK(!passed);

	check_is_not_pending_copy( ARG(T) );
	check_instance_count(count, ARG(T) );
	check_uninitialized(opt0);

	reset_throw_on_copy( ARG(T) ) ;
	}

	//
	// Test Assignment to an Initialized optional from an Initialized optional
	// for a T with a throwing copy-ctor
	//
	template<class T>
	void test_throwing_assign_to_initialized( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T z(0);
	T a(12);
	T b(13);
	T x(-1);

	optional<T> opt0(a) ;
	optional<T> opt1(b) ;

	int count = get_instance_count( ARG(T) ) ;

	set_throw_on_assign( ARG(T) ) ;

	bool passed = false ;
	try
	{
	// This should:
	// Attempt to copy construct 'opt1.value()' into opt0 and throw.
	// opt0 is kept initialized but its value not neccesarily fully assigned
	// (in this test, incompletely assigned is flaged with the value -1 being set)
	set_pending_assign( ARG(T) ) ;
	opt0 = opt1 ;
	passed = true ;
	}
	catch ( ... ) {}

	BOOST_CHECK(!passed);

	// opt0 was left uninitialized
	check_is_not_pending_assign( ARG(T) );
	check_instance_count(count, ARG(T) );
	check_initialized(opt0);
	check_value(opt0,x,z);

	reset_throw_on_assign( ARG(T) ) ;
	}

	//
	// Test swap in a no-throwing case
	//
	template<class T>
	void test_no_throwing_swap( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T z(0);
	T a(14);
	T b(15);

	optional<T> def0 ;
	optional<T> def1 ;
	optional<T> opt0(a) ;
	optional<T> opt1(b) ;

	int count = get_instance_count( ARG(T) ) ;

	swap(def0,def1);
	check_uninitialized(def0);
	check_uninitialized(def1);

	swap(def0,opt0);
	check_uninitialized(opt0);
	check_initialized(def0);
	check_value(def0,a,z);

	// restore def0 and opt0
	swap(def0,opt0);

	swap(opt0,opt1);
	check_instance_count(count, ARG(T) );
	check_initialized(opt0);
	check_initialized(opt1);
	check_value(opt0,b,z);
	check_value(opt1,a,z);
	}

	//
	// Test swap in a throwing case
	//
	template<class T>
	void test_throwing_swap( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T a(16);
	T b(17);
	T x(-1);

	optional<T> opt0(a) ;
	optional<T> opt1(b) ;

	set_throw_on_assign( ARG(T) ) ;

	//
	// Case 1: Both Initialized.
	//
	bool passed = false ;
	try
	{
	// This should attempt to swap optionals and fail at swap(X&,X&).
	swap(opt0,opt1);

	passed = true ;
	}
	catch ( ... ) {}

	BOOST_CHECK(!passed);

	// optional's swap doesn't affect the initialized states of the arguments. Therefore,
	// the following must hold:
	check_initialized(opt0);
	check_initialized(opt1);
	check_value(opt0,x,a);
	check_value(opt1,b,x);


	//
	// Case 2: Only one Initialized.
	//
	reset_throw_on_assign( ARG(T) ) ;

	opt0.reset();
	opt1.reset(a);

	set_throw_on_copy( ARG(T) ) ;

	passed = false ;
	try
	{
	// This should attempt to swap optionals and fail at opt0.reset(*opt1)
	// Both opt0 and op1 are left unchanged (unswaped)
	swap(opt0,opt1);

	passed = true ;
	}
	catch ( ... ) {}

	BOOST_CHECK(!passed);

	check_uninitialized(opt0);
	check_initialized(opt1);
	check_value(opt1,a,x);

	reset_throw_on_copy( ARG(T) ) ;
	}

	//
	// This verifies relational operators.
	//
	template<class T>
	void test_relops( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T v0(0);
	T v1(1);
	T v2(1);

	optional<T> def0 ;
	optional<T> def1 ;
	optional<T> opt0(v0);
	optional<T> opt1(v1);
	optional<T> opt2(v2);

	// Check identity
	BOOST_CHECK ( def0 == def0 ) ;
	BOOST_CHECK ( opt0 == opt0 ) ;
	BOOST_CHECK ( !(def0 != def0) ) ;
	BOOST_CHECK ( !(opt0 != opt0) ) ;

	// Check when both are uininitalized.
	BOOST_CHECK ( def0 == def1 ) ; // both uninitialized compare equal
	BOOST_CHECK ( !(def0 < def1) ) ; // uninitialized is never less than uninitialized
	BOOST_CHECK ( !(def0 > def1) ) ; // uninitialized is never greater than uninitialized
	BOOST_CHECK ( !(def0 != def1) ) ;
	BOOST_CHECK ( def0 <= def1 ) ;
	BOOST_CHECK ( def0 >= def1 ) ;

	// Check when only lhs is uninitialized.
	BOOST_CHECK ( def0 != opt0 ) ; // uninitialized is never equal to initialized
	BOOST_CHECK ( !(def0 == opt0) ) ;
	BOOST_CHECK ( def0 < opt0 ) ; // uninitialized is always less than initialized
	BOOST_CHECK ( !(def0 > opt0) ) ;
	BOOST_CHECK ( def0 <= opt0 ) ;
	BOOST_CHECK ( !(def0 >= opt0) ) ;

	// Check when only rhs is uninitialized.
	BOOST_CHECK ( opt0 != def0 ) ; // initialized is never equal to uninitialized
	BOOST_CHECK ( !(opt0 == def0) ) ;
	BOOST_CHECK ( !(opt0 < def0) ) ; // initialized is never less than uninitialized
	BOOST_CHECK ( opt0 > def0 ) ;
	BOOST_CHECK ( !(opt0 <= def0) ) ;
	BOOST_CHECK ( opt0 >= opt0 ) ;

	// If both are initialized, values are compared
	BOOST_CHECK ( opt0 != opt1 ) ;
	BOOST_CHECK ( opt1 == opt2 ) ;
	BOOST_CHECK ( opt0 < opt1 ) ;
	BOOST_CHECK ( opt1 > opt0 ) ;
	BOOST_CHECK ( opt1 <= opt2 ) ;
	BOOST_CHECK ( opt1 >= opt0 ) ;

	// Compare against a value directly
	BOOST_CHECK ( opt0 == v0 ) ;
	BOOST_CHECK ( opt0 != v1 ) ;
	BOOST_CHECK ( opt1 == v2 ) ;
	BOOST_CHECK ( opt0 < v1 ) ;
	BOOST_CHECK ( opt1 > v0 ) ;
	BOOST_CHECK ( opt1 <= v2 ) ;
	BOOST_CHECK ( opt1 >= v0 ) ;
	BOOST_CHECK ( v0 != opt1 ) ;
	BOOST_CHECK ( v1 == opt2 ) ;
	BOOST_CHECK ( v0 < opt1 ) ;
	BOOST_CHECK ( v1 > opt0 ) ;
	BOOST_CHECK ( v1 <= opt2 ) ;
	BOOST_CHECK ( v1 >= opt0 ) ;
	BOOST_CHECK ( def0 != v0 ) ;
	BOOST_CHECK ( !(def0 == v0) ) ;
	BOOST_CHECK ( def0 < v0 ) ;
	BOOST_CHECK ( !(def0 > v0) ) ;
	BOOST_CHECK ( def0 <= v0 ) ;
	BOOST_CHECK ( !(def0 >= v0) ) ;
	BOOST_CHECK ( v0 != def0 ) ;
	BOOST_CHECK ( !(v0 == def0) ) ;
	BOOST_CHECK ( !(v0 < def0) ) ;
	BOOST_CHECK ( v0 > def0 ) ;
	BOOST_CHECK ( !(v0 <= def0) ) ;
	BOOST_CHECK ( v0 >= opt0 ) ;
	}

	template<class T>
	void test_none( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	using boost::none ;

	optional<T> def0 ;
	optional<T> def1(none) ;
	optional<T> non_def( T(1234) ) ;

	BOOST_CHECK ( def0 == none ) ;
	BOOST_CHECK ( non_def != none ) ;
	BOOST_CHECK ( !def1 ) ;
	BOOST_CHECK ( !(non_def < none) ) ;
	BOOST_CHECK ( non_def > none ) ;
	BOOST_CHECK ( !(non_def <= none) ) ;
	BOOST_CHECK ( non_def >= none ) ;

	non_def = none ;
	BOOST_CHECK ( !non_def ) ;

	test_default_implicit_construction(T(1),none);
	}

	template<class T>
	void test_arrow( T const* )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	T a(1234);

	optional<T> oa(a) ;
	optional<T> const coa(a) ;

	BOOST_CHECK ( coa->V() == 1234 ) ;

	oa->V() = 4321 ;

	BOOST_CHECK ( a.V() = 1234 ) ;
	BOOST_CHECK ( (*oa).V() = 4321 ) ;
	}

	void test_with_builtin_types()
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	test_basics( ARG(double) );
	test_conditional_ctor_and_get_valur_or( ARG(double) );
	test_uninitialized_access( ARG(double) );
	test_no_throwing_swap( ARG(double) );
	test_relops( ARG(double) ) ;
	test_none( ARG(double) ) ;
	}

	void test_with_class_type()
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	test_basics( ARG(X) );
	test_conditional_ctor_and_get_valur_or( ARG(X) );
	test_direct_value_manip( ARG(X) );
	test_uninitialized_access( ARG(X) );
	test_throwing_direct_init( ARG(X) );
	test_throwing_val_assign_on_uninitialized( ARG(X) );
	test_throwing_val_assign_on_initialized( ARG(X) );
	test_throwing_copy_initialization( ARG(X) );
	test_throwing_assign_to_uninitialized( ARG(X) );
	test_throwing_assign_to_initialized( ARG(X) );
	test_no_throwing_swap( ARG(X) );
	test_throwing_swap( ARG(X) );
	test_relops( ARG(X) ) ;
	test_none( ARG(X) ) ;
	test_arrow( ARG(X) ) ;
	BOOST_CHECK ( X::count == 0 ) ;
	}

	int eat ( bool ) { return 1 ; }
	int eat ( char ) { return 1 ; }
	int eat ( int ) { return 1 ; }
	int eat ( void const* ) { return 1 ; }

	template<class T> int eat ( T ) { return 0 ; }

	//
	// This verifies that operator safe_bool() behaves properly.
	//
	template<class T>
	void test_no_implicit_conversions_impl( T const& )
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	optional<T> def ;
	BOOST_CHECK ( eat(def) == 0 ) ;
	}

	void test_no_implicit_conversions()
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	bool b = false ;
	char c = 0 ;
	int i = 0 ;
	void const* p = 0 ;

	test_no_implicit_conversions_impl(b);
	test_no_implicit_conversions_impl(c);
	test_no_implicit_conversions_impl(i);
	test_no_implicit_conversions_impl(p);
	}

	struct A {} ;
	void test_conversions1()
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	#ifndef BOOST_OPTIONAL_NO_CONVERTING_COPY_CTOR
	char c = 20 ;
	optional<char> opt0(c);
	optional<int> opt1(opt0);
	BOOST_CHECK(*opt1 == static_cast<int>(c));
	#endif

	#ifndef BOOST_OPTIONAL_NO_CONVERTING_ASSIGNMENT
	float f = 21.22f ;
	double d = f ;
	optional<float> opt2(f) ;
	optional<double> opt3 ;
	opt3 = opt2 ;
	BOOST_CHECK(*opt3 == d);
	#endif
	}

	void test_conversions2()
	{
	TRACE( std::endl << BOOST_CURRENT_FUNCTION );

	char c = 20 ;
	optional<int> opt(c);
	BOOST_CHECK( get(opt) == static_cast<int>(c));

	float f = 21.22f ;
	optional<double> opt1;
	opt1 = f ;
	BOOST_CHECK(*get(&opt1) == static_cast<double>(f));
	}

	int test_main( int, char* [] )
	{
	try
	{
	test_with_class_type();
	test_with_builtin_types();
	test_no_implicit_conversions();
	test_conversions1();
	test_conversions2();
	}
	catch ( ... )
	{
	BOOST_ERROR("Unexpected Exception caught!");
	}

	return 0;
	}