boost_1_45_0/libs/smart_ptr/test/intrusive_ptr_test.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 #include <boost/config.hpp>

 #if defined(BOOST_MSVC)

 #pragma warning(disable: 4786)  // identifier truncated in debug info
 #pragma warning(disable: 4710)  // function not inlined
 #pragma warning(disable: 4711)  // function selected for automatic inline expansion
 #pragma warning(disable: 4514)  // unreferenced inline removed
 #pragma warning(disable: 4355)  // 'this' : used in base member initializer list
 #pragma warning(disable: 4511)  // copy constructor could not be generated
 #pragma warning(disable: 4512)  // assignment operator could not be generated

 #if (BOOST_MSVC >= 1310)
 #pragma warning(disable: 4675)  // resolved overload found with Koenig lookup
 #endif

 #endif

 //
 //  intrusive_ptr_test.cpp
 //
 //  Copyright (c) 2002-2005 Peter Dimov
 //
 // 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)
 //

 #include <boost/detail/lightweight_test.hpp>
 #include <boost/intrusive_ptr.hpp>
 #include <boost/detail/atomic_count.hpp>
 #include <boost/config.hpp>
 #include <algorithm>
 #include <functional>

 //

 namespace N
 {

 class base
 {
 private:

     boost::detail::atomic_count use_count_;

     base(base const &);
     base & operator=(base const &);

 protected:

     base(): use_count_(0)
     {
     }

     virtual ~base()
     {
     }

 public:

     long use_count() const
     {
         return use_count_;
     }

 #if !defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)

     inline friend void intrusive_ptr_add_ref(base * p)
     {
         ++p->use_count_;
     }

     inline friend void intrusive_ptr_release(base * p)
     {
         if(--p->use_count_ == 0) delete p;
     }

 #else

     void add_ref()
     {
         ++use_count_;
     }

     void release()
     {
         if(--use_count_ == 0) delete this;
     }

 #endif
 };

 } // namespace N

 #if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)

 namespace boost
 {

 inline void intrusive_ptr_add_ref(N::base * p)
 {
     p->add_ref();
 }

 inline void intrusive_ptr_release(N::base * p)
 {
     p->release();
 }

 } // namespace boost

 #endif

 //

 struct X: public virtual N::base
 {
 };

 struct Y: public X
 {
 };

 //

 namespace n_element_type
 {

 void f(X &)
 {
 }

 void test()
 {
     typedef boost::intrusive_ptr<X>::element_type T;
     T t;
     f(t);
 }

 } // namespace n_element_type

 namespace n_constructors
 {

 void default_constructor()
 {
     boost::intrusive_ptr<X> px;
     BOOST_TEST(px.get() == 0);
 }

 void pointer_constructor()
 {
     {
         boost::intrusive_ptr<X> px(0);
         BOOST_TEST(px.get() == 0);
     }

     {
         boost::intrusive_ptr<X> px(0, false);
         BOOST_TEST(px.get() == 0);
     }

     {
         X * p = new X;
         BOOST_TEST(p->use_count() == 0);

         boost::intrusive_ptr<X> px(p);
         BOOST_TEST(px.get() == p);
         BOOST_TEST(px->use_count() == 1);
     }

     {
         X * p = new X;
         BOOST_TEST(p->use_count() == 0);

 #if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
         using boost::intrusive_ptr_add_ref;
 #endif
         intrusive_ptr_add_ref(p);
         BOOST_TEST(p->use_count() == 1);

         boost::intrusive_ptr<X> px(p, false);
         BOOST_TEST(px.get() == p);
         BOOST_TEST(px->use_count() == 1);
     }
 }

 void copy_constructor()
 {
     {
         boost::intrusive_ptr<X> px;
         boost::intrusive_ptr<X> px2(px);
         BOOST_TEST(px2.get() == px.get());
     }

     {
         boost::intrusive_ptr<Y> py;
         boost::intrusive_ptr<X> px(py);
         BOOST_TEST(px.get() == py.get());
     }

     {
         boost::intrusive_ptr<X> px(0);
         boost::intrusive_ptr<X> px2(px);
         BOOST_TEST(px2.get() == px.get());
     }

     {
         boost::intrusive_ptr<Y> py(0);
         boost::intrusive_ptr<X> px(py);
         BOOST_TEST(px.get() == py.get());
     }

     {
         boost::intrusive_ptr<X> px(0, false);
         boost::intrusive_ptr<X> px2(px);
         BOOST_TEST(px2.get() == px.get());
     }

     {
         boost::intrusive_ptr<Y> py(0, false);
         boost::intrusive_ptr<X> px(py);
         BOOST_TEST(px.get() == py.get());
     }

     {
         boost::intrusive_ptr<X> px(new X);
         boost::intrusive_ptr<X> px2(px);
         BOOST_TEST(px2.get() == px.get());
     }

     {
         boost::intrusive_ptr<Y> py(new Y);
         boost::intrusive_ptr<X> px(py);
         BOOST_TEST(px.get() == py.get());
     }
 }

 void test()
 {
     default_constructor();
     pointer_constructor();
     copy_constructor();
 }

 } // namespace n_constructors

 namespace n_destructor
 {

 void test()
 {
     boost::intrusive_ptr<X> px(new X);
     BOOST_TEST(px->use_count() == 1);

     {
         boost::intrusive_ptr<X> px2(px);
         BOOST_TEST(px->use_count() == 2);
     }

     BOOST_TEST(px->use_count() == 1);
 }

 } // namespace n_destructor

 namespace n_assignment
 {

 void copy_assignment()
 {
 }

 void conversion_assignment()
 {
 }

 void pointer_assignment()
 {
 }

 void test()
 {
     copy_assignment();
     conversion_assignment();
     pointer_assignment();
 }

 } // namespace n_assignment

 namespace n_access
 {

 void test()
 {
     {
         boost::intrusive_ptr<X> px;
         BOOST_TEST(px? false: true);
         BOOST_TEST(!px);

 #if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
         using boost::get_pointer;
 #endif

         BOOST_TEST(get_pointer(px) == px.get());
     }

     {
         boost::intrusive_ptr<X> px(0);
         BOOST_TEST(px? false: true);
         BOOST_TEST(!px);

 #if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
         using boost::get_pointer;
 #endif

         BOOST_TEST(get_pointer(px) == px.get());
     }

     {
         boost::intrusive_ptr<X> px(new X);
         BOOST_TEST(px? true: false);
         BOOST_TEST(!!px);
         BOOST_TEST(&*px == px.get());
         BOOST_TEST(px.operator ->() == px.get());

 #if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
         using boost::get_pointer;
 #endif

         BOOST_TEST(get_pointer(px) == px.get());
     }
 }

 } // namespace n_access

 namespace n_swap
 {

 void test()
 {
     {
         boost::intrusive_ptr<X> px;
         boost::intrusive_ptr<X> px2;

         px.swap(px2);

         BOOST_TEST(px.get() == 0);
         BOOST_TEST(px2.get() == 0);

         using std::swap;
         swap(px, px2);

         BOOST_TEST(px.get() == 0);
         BOOST_TEST(px2.get() == 0);
     }

     {
         X * p = new X;
         boost::intrusive_ptr<X> px;
         boost::intrusive_ptr<X> px2(p);
         boost::intrusive_ptr<X> px3(px2);

         px.swap(px2);

         BOOST_TEST(px.get() == p);
         BOOST_TEST(px->use_count() == 2);
         BOOST_TEST(px2.get() == 0);
         BOOST_TEST(px3.get() == p);
         BOOST_TEST(px3->use_count() == 2);

         using std::swap;
         swap(px, px2);

         BOOST_TEST(px.get() == 0);
         BOOST_TEST(px2.get() == p);
         BOOST_TEST(px2->use_count() == 2);
         BOOST_TEST(px3.get() == p);
         BOOST_TEST(px3->use_count() == 2);
     }

     {
         X * p1 = new X;
         X * p2 = new X;
         boost::intrusive_ptr<X> px(p1);
         boost::intrusive_ptr<X> px2(p2);
         boost::intrusive_ptr<X> px3(px2);

         px.swap(px2);

         BOOST_TEST(px.get() == p2);
         BOOST_TEST(px->use_count() == 2);
         BOOST_TEST(px2.get() == p1);
         BOOST_TEST(px2->use_count() == 1);
         BOOST_TEST(px3.get() == p2);
         BOOST_TEST(px3->use_count() == 2);

         using std::swap;
         swap(px, px2);

         BOOST_TEST(px.get() == p1);
         BOOST_TEST(px->use_count() == 1);
         BOOST_TEST(px2.get() == p2);
         BOOST_TEST(px2->use_count() == 2);
         BOOST_TEST(px3.get() == p2);
         BOOST_TEST(px3->use_count() == 2);
     }
 }

 } // namespace n_swap

 namespace n_comparison
 {

 template<class T, class U> void test2(boost::intrusive_ptr<T> const & p, boost::intrusive_ptr<U> const & q)
 {
     BOOST_TEST((p == q) == (p.get() == q.get()));
     BOOST_TEST((p != q) == (p.get() != q.get()));
 }

 template<class T> void test3(boost::intrusive_ptr<T> const & p, boost::intrusive_ptr<T> const & q)
 {
     BOOST_TEST((p == q) == (p.get() == q.get()));
     BOOST_TEST((p.get() == q) == (p.get() == q.get()));
     BOOST_TEST((p == q.get()) == (p.get() == q.get()));
     BOOST_TEST((p != q) == (p.get() != q.get()));
     BOOST_TEST((p.get() != q) == (p.get() != q.get()));
     BOOST_TEST((p != q.get()) == (p.get() != q.get()));

     // 'less' moved here as a g++ 2.9x parse error workaround
     std::less<T*> less;
     BOOST_TEST((p < q) == less(p.get(), q.get()));
 }

 void test()
 {
     {
         boost::intrusive_ptr<X> px;
         test3(px, px);

         boost::intrusive_ptr<X> px2;
         test3(px, px2);

         boost::intrusive_ptr<X> px3(px);
         test3(px3, px3);
         test3(px, px3);
     }

     {
         boost::intrusive_ptr<X> px;

         boost::intrusive_ptr<X> px2(new X);
         test3(px, px2);
         test3(px2, px2);

         boost::intrusive_ptr<X> px3(new X);
         test3(px2, px3);

         boost::intrusive_ptr<X> px4(px2);
         test3(px2, px4);
         test3(px4, px4);
     }

     {
         boost::intrusive_ptr<X> px(new X);

         boost::intrusive_ptr<Y> py(new Y);
         test2(px, py);

         boost::intrusive_ptr<X> px2(py);
         test2(px2, py);
         test3(px, px2);
         test3(px2, px2);
     }
 }

 } // namespace n_comparison

 namespace n_static_cast
 {

 void test()
 {
 }

 } // namespace n_static_cast

 namespace n_dynamic_cast
 {

 void test()
 {
 }

 } // namespace n_dynamic_cast

 namespace n_transitive
 {

 struct X: public N::base
 {
     boost::intrusive_ptr<X> next;
 };

 void test()
 {
     boost::intrusive_ptr<X> p(new X);
     p->next = boost::intrusive_ptr<X>(new X);
     BOOST_TEST(!p->next->next);
     p = p->next;
     BOOST_TEST(!p->next);
 }

 } // namespace n_transitive

 namespace n_report_1
 {

 class foo: public N::base
 {
 public:

     foo(): m_self(this)
     {
     }

     void suicide()
     {
         m_self = 0;
     }

 private:

     boost::intrusive_ptr<foo> m_self;
 };

 void test()
 {
     foo * foo_ptr = new foo;
     foo_ptr->suicide();
 }

 } // namespace n_report_1

 int main()
 {
     n_element_type::test();
     n_constructors::test();
     n_destructor::test();
     n_assignment::test();
     n_access::test();
     n_swap::test();
     n_comparison::test();
     n_static_cast::test();
     n_dynamic_cast::test();

     n_transitive::test();
     n_report_1::test();

     return boost::report_errors();
 }
	#include <boost/config.hpp>

	#if defined(BOOST_MSVC)

	#pragma warning(disable: 4786) // identifier truncated in debug info
	#pragma warning(disable: 4710) // function not inlined
	#pragma warning(disable: 4711) // function selected for automatic inline expansion
	#pragma warning(disable: 4514) // unreferenced inline removed
	#pragma warning(disable: 4355) // 'this' : used in base member initializer list
	#pragma warning(disable: 4511) // copy constructor could not be generated
	#pragma warning(disable: 4512) // assignment operator could not be generated

	#if (BOOST_MSVC >= 1310)
	#pragma warning(disable: 4675) // resolved overload found with Koenig lookup
	#endif

	#endif

	//
	// intrusive_ptr_test.cpp
	//
	// Copyright (c) 2002-2005 Peter Dimov
	//
	// 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)
	//

	#include <boost/detail/lightweight_test.hpp>
	#include <boost/intrusive_ptr.hpp>
	#include <boost/detail/atomic_count.hpp>
	#include <boost/config.hpp>
	#include <algorithm>
	#include <functional>

	//

	namespace N
	{

	class base
	{
	private:

	boost::detail::atomic_count use_count_;

	base(base const &);
	base & operator=(base const &);

	protected:

	base(): use_count_(0)
	{
	}

	virtual ~base()
	{
	}

	public:

	long use_count() const
	{
	return use_count_;
	}

	#if !defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)

	inline friend void intrusive_ptr_add_ref(base * p)
	{
	++p->use_count_;
	}

	inline friend void intrusive_ptr_release(base * p)
	{
	if(--p->use_count_ == 0) delete p;
	}

	#else

	void add_ref()
	{
	++use_count_;
	}

	void release()
	{
	if(--use_count_ == 0) delete this;
	}

	#endif
	};

	} // namespace N

	#if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)

	namespace boost
	{

	inline void intrusive_ptr_add_ref(N::base * p)
	{
	p->add_ref();
	}

	inline void intrusive_ptr_release(N::base * p)
	{
	p->release();
	}

	} // namespace boost

	#endif

	//

	struct X: public virtual N::base
	{
	};

	struct Y: public X
	{
	};

	//

	namespace n_element_type
	{

	void f(X &)
	{
	}

	void test()
	{
	typedef boost::intrusive_ptr<X>::element_type T;
	T t;
	f(t);
	}

	} // namespace n_element_type

	namespace n_constructors
	{

	void default_constructor()
	{
	boost::intrusive_ptr<X> px;
	BOOST_TEST(px.get() == 0);
	}

	void pointer_constructor()
	{
	{
	boost::intrusive_ptr<X> px(0);
	BOOST_TEST(px.get() == 0);
	}

	{
	boost::intrusive_ptr<X> px(0, false);
	BOOST_TEST(px.get() == 0);
	}

	{
	X * p = new X;
	BOOST_TEST(p->use_count() == 0);

	boost::intrusive_ptr<X> px(p);
	BOOST_TEST(px.get() == p);
	BOOST_TEST(px->use_count() == 1);
	}

	{
	X * p = new X;
	BOOST_TEST(p->use_count() == 0);

	#if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
	using boost::intrusive_ptr_add_ref;
	#endif
	intrusive_ptr_add_ref(p);
	BOOST_TEST(p->use_count() == 1);

	boost::intrusive_ptr<X> px(p, false);
	BOOST_TEST(px.get() == p);
	BOOST_TEST(px->use_count() == 1);
	}
	}

	void copy_constructor()
	{
	{
	boost::intrusive_ptr<X> px;
	boost::intrusive_ptr<X> px2(px);
	BOOST_TEST(px2.get() == px.get());
	}

	{
	boost::intrusive_ptr<Y> py;
	boost::intrusive_ptr<X> px(py);
	BOOST_TEST(px.get() == py.get());
	}

	{
	boost::intrusive_ptr<X> px(0);
	boost::intrusive_ptr<X> px2(px);
	BOOST_TEST(px2.get() == px.get());
	}

	{
	boost::intrusive_ptr<Y> py(0);
	boost::intrusive_ptr<X> px(py);
	BOOST_TEST(px.get() == py.get());
	}

	{
	boost::intrusive_ptr<X> px(0, false);
	boost::intrusive_ptr<X> px2(px);
	BOOST_TEST(px2.get() == px.get());
	}

	{
	boost::intrusive_ptr<Y> py(0, false);
	boost::intrusive_ptr<X> px(py);
	BOOST_TEST(px.get() == py.get());
	}

	{
	boost::intrusive_ptr<X> px(new X);
	boost::intrusive_ptr<X> px2(px);
	BOOST_TEST(px2.get() == px.get());
	}

	{
	boost::intrusive_ptr<Y> py(new Y);
	boost::intrusive_ptr<X> px(py);
	BOOST_TEST(px.get() == py.get());
	}
	}

	void test()
	{
	default_constructor();
	pointer_constructor();
	copy_constructor();
	}

	} // namespace n_constructors

	namespace n_destructor
	{

	void test()
	{
	boost::intrusive_ptr<X> px(new X);
	BOOST_TEST(px->use_count() == 1);

	{
	boost::intrusive_ptr<X> px2(px);
	BOOST_TEST(px->use_count() == 2);
	}

	BOOST_TEST(px->use_count() == 1);
	}

	} // namespace n_destructor

	namespace n_assignment
	{

	void copy_assignment()
	{
	}

	void conversion_assignment()
	{
	}

	void pointer_assignment()
	{
	}

	void test()
	{
	copy_assignment();
	conversion_assignment();
	pointer_assignment();
	}

	} // namespace n_assignment

	namespace n_access
	{

	void test()
	{
	{
	boost::intrusive_ptr<X> px;
	BOOST_TEST(px? false: true);
	BOOST_TEST(!px);

	#if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
	using boost::get_pointer;
	#endif

	BOOST_TEST(get_pointer(px) == px.get());
	}

	{
	boost::intrusive_ptr<X> px(0);
	BOOST_TEST(px? false: true);
	BOOST_TEST(!px);

	#if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
	using boost::get_pointer;
	#endif

	BOOST_TEST(get_pointer(px) == px.get());
	}

	{
	boost::intrusive_ptr<X> px(new X);
	BOOST_TEST(px? true: false);
	BOOST_TEST(!!px);
	BOOST_TEST(&*px == px.get());
	BOOST_TEST(px.operator ->() == px.get());

	#if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
	using boost::get_pointer;
	#endif

	BOOST_TEST(get_pointer(px) == px.get());
	}
	}

	} // namespace n_access

	namespace n_swap
	{

	void test()
	{
	{
	boost::intrusive_ptr<X> px;
	boost::intrusive_ptr<X> px2;

	px.swap(px2);

	BOOST_TEST(px.get() == 0);
	BOOST_TEST(px2.get() == 0);

	using std::swap;
	swap(px, px2);

	BOOST_TEST(px.get() == 0);
	BOOST_TEST(px2.get() == 0);
	}

	{
	X * p = new X;
	boost::intrusive_ptr<X> px;
	boost::intrusive_ptr<X> px2(p);
	boost::intrusive_ptr<X> px3(px2);

	px.swap(px2);

	BOOST_TEST(px.get() == p);
	BOOST_TEST(px->use_count() == 2);
	BOOST_TEST(px2.get() == 0);
	BOOST_TEST(px3.get() == p);
	BOOST_TEST(px3->use_count() == 2);

	using std::swap;
	swap(px, px2);

	BOOST_TEST(px.get() == 0);
	BOOST_TEST(px2.get() == p);
	BOOST_TEST(px2->use_count() == 2);
	BOOST_TEST(px3.get() == p);
	BOOST_TEST(px3->use_count() == 2);
	}

	{
	X * p1 = new X;
	X * p2 = new X;
	boost::intrusive_ptr<X> px(p1);
	boost::intrusive_ptr<X> px2(p2);
	boost::intrusive_ptr<X> px3(px2);

	px.swap(px2);

	BOOST_TEST(px.get() == p2);
	BOOST_TEST(px->use_count() == 2);
	BOOST_TEST(px2.get() == p1);
	BOOST_TEST(px2->use_count() == 1);
	BOOST_TEST(px3.get() == p2);
	BOOST_TEST(px3->use_count() == 2);

	using std::swap;
	swap(px, px2);

	BOOST_TEST(px.get() == p1);
	BOOST_TEST(px->use_count() == 1);
	BOOST_TEST(px2.get() == p2);
	BOOST_TEST(px2->use_count() == 2);
	BOOST_TEST(px3.get() == p2);
	BOOST_TEST(px3->use_count() == 2);
	}
	}

	} // namespace n_swap

	namespace n_comparison
	{

	template<class T, class U> void test2(boost::intrusive_ptr<T> const & p, boost::intrusive_ptr<U> const & q)
	{
	BOOST_TEST((p == q) == (p.get() == q.get()));
	BOOST_TEST((p != q) == (p.get() != q.get()));
	}

	template<class T> void test3(boost::intrusive_ptr<T> const & p, boost::intrusive_ptr<T> const & q)
	{
	BOOST_TEST((p == q) == (p.get() == q.get()));
	BOOST_TEST((p.get() == q) == (p.get() == q.get()));
	BOOST_TEST((p == q.get()) == (p.get() == q.get()));
	BOOST_TEST((p != q) == (p.get() != q.get()));
	BOOST_TEST((p.get() != q) == (p.get() != q.get()));
	BOOST_TEST((p != q.get()) == (p.get() != q.get()));

	// 'less' moved here as a g++ 2.9x parse error workaround
	std::less<T*> less;
	BOOST_TEST((p < q) == less(p.get(), q.get()));
	}

	void test()
	{
	{
	boost::intrusive_ptr<X> px;
	test3(px, px);

	boost::intrusive_ptr<X> px2;
	test3(px, px2);

	boost::intrusive_ptr<X> px3(px);
	test3(px3, px3);
	test3(px, px3);
	}

	{
	boost::intrusive_ptr<X> px;

	boost::intrusive_ptr<X> px2(new X);
	test3(px, px2);
	test3(px2, px2);

	boost::intrusive_ptr<X> px3(new X);
	test3(px2, px3);

	boost::intrusive_ptr<X> px4(px2);
	test3(px2, px4);
	test3(px4, px4);
	}

	{
	boost::intrusive_ptr<X> px(new X);

	boost::intrusive_ptr<Y> py(new Y);
	test2(px, py);

	boost::intrusive_ptr<X> px2(py);
	test2(px2, py);
	test3(px, px2);
	test3(px2, px2);
	}
	}

	} // namespace n_comparison

	namespace n_static_cast
	{

	void test()
	{
	}

	} // namespace n_static_cast

	namespace n_dynamic_cast
	{

	void test()
	{
	}

	} // namespace n_dynamic_cast

	namespace n_transitive
	{

	struct X: public N::base
	{
	boost::intrusive_ptr<X> next;
	};

	void test()
	{
	boost::intrusive_ptr<X> p(new X);
	p->next = boost::intrusive_ptr<X>(new X);
	BOOST_TEST(!p->next->next);
	p = p->next;
	BOOST_TEST(!p->next);
	}

	} // namespace n_transitive

	namespace n_report_1
	{

	class foo: public N::base
	{
	public:

	foo(): m_self(this)
	{
	}

	void suicide()
	{
	m_self = 0;
	}

	private:

	boost::intrusive_ptr<foo> m_self;
	};

	void test()
	{
	foo * foo_ptr = new foo;
	foo_ptr->suicide();
	}

	} // namespace n_report_1

	int main()
	{
	n_element_type::test();
	n_constructors::test();
	n_destructor::test();
	n_assignment::test();
	n_access::test();
	n_swap::test();
	n_comparison::test();
	n_static_cast::test();
	n_dynamic_cast::test();

	n_transitive::test();
	n_report_1::test();

	return boost::report_errors();
	}