llvm-gcc-4.0/libstdc++-v3/include/tr1/boost_shared_ptr.h - llvm-archive - Git at Google

 // <tr1/boost_shared_ptr.h> -*- C++ -*-

 // Copyright (C) 2005 Free Software Foundation, Inc.
 //
 // This file is part of the GNU ISO C++ Library.  This library is free
 // software; you can redistribute it and/or modify it under the
 // terms of the GNU General Public License as published by the
 // Free Software Foundation; either version 2, or (at your option)
 // any later version.

 // This library is distributed in the hope that it will be useful,
 // but WITHOUT ANY WARRANTY; without even the implied warranty of
 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 // GNU General Public License for more details.

 // You should have received a copy of the GNU General Public License along
 // with this library; see the file COPYING.  If not, write to the Free
 // Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307,
 // USA.

 // As a special exception, you may use this file as part of a free software
 // library without restriction.  Specifically, if other files instantiate
 // templates or use macros or inline functions from this file, or you compile
 // this file and link it with other files to produce an executable, this
 // file does not by itself cause the resulting executable to be covered by
 // the GNU General Public License.  This exception does not however
 // invalidate any other reasons why the executable file might be covered by
 // the GNU General Public License.

 //  shared_count.hpp
 //  Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.

 //  shared_ptr.hpp
 //  Copyright (C) 1998, 1999 Greg Colvin and Beman Dawes.
 //  Copyright (C) 2001, 2002, 2003 Peter Dimov

 //  weak_ptr.hpp
 //  Copyright (C) 2001, 2002, 2003 Peter Dimov

 //  enable_shared_from_this.hpp
 //  Copyright (C) 2002 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)

 // GCC Note:  based on version 1.32.0 of the Boost library.

 /** @file boost_memory.h
  *  This is an internal header file, included by other library headers.
  *  You should not attempt to use it directly.
  */

 #ifndef _BOOST_SHARED_PTR_H
 #define _BOOST_SHARED_PTR_H 1

 // namespace std::tr1
 namespace std
 {
 namespace tr1
 {

 class bad_weak_ptr : public std::exception
 {
 public:

   virtual char const* what() const throw()
   {
     return "tr1::bad_weak_ptr";
   }
 };

 // Helper for exception objects in <tr1/memory>
 // TODO this should be defined in a different file.
 inline void
 __throw_bad_weak_ptr()
 {
 #if __EXCEPTIONS
   throw bad_weak_ptr();
 #else
   std::abort();
 #endif
 }


 template <typename _Tp>
   struct _Sp_deleter
   {
     typedef void result_type;
     typedef _Tp* argument_type;

     void
     operator()(_Tp* p) const
     { delete p; }
   };


 class _Sp_counted_base
 {
 public:

   _Sp_counted_base()
   : _M_use_count(1), _M_weak_count(1)
   { }

   virtual
   ~_Sp_counted_base() // nothrow
   { }

   // dispose() is called when _M_use_count drops to zero, to release
   // the resources managed by *this.
   virtual void
   dispose() = 0; // nothrow

   // destroy() is called when _M_weak_count drops to zero.
   virtual void
   destroy() // nothrow
   {
     delete this;
   }

   virtual void*
   get_deleter(const std::type_info&) = 0;

   void
   add_ref_copy()
   {
     __gnu_cxx::__atomic_add(&_M_use_count, 1);
   }

   void
   add_ref_lock()
   {
     __gnu_cxx::lock lock(_M_mutex);
     if (__gnu_cxx::__exchange_and_add(&_M_use_count, 1) == 0)
     {
       _M_use_count = 0;
       __throw_bad_weak_ptr();
     }
   }

   void
   release() // nothrow
   {
     if (__gnu_cxx::__exchange_and_add(&_M_use_count, -1) == 1)
     {
       dispose();
       __glibcxx_mutex_lock(_M_mutex);
       __glibcxx_mutex_unlock(_M_mutex);
       weak_release();
     }
   }

   void
   weak_add_ref() // nothrow
   {
     __gnu_cxx::__atomic_add(&_M_weak_count, 1);
   }

   void
   weak_release() // nothrow
   {
     if (__gnu_cxx::__exchange_and_add(&_M_weak_count, -1) == 1)
     {
       __glibcxx_mutex_lock(_M_mutex);
       __glibcxx_mutex_unlock(_M_mutex);
       destroy();
     }
   }

   long
   use_count() const // nothrow
   {
     return _M_use_count;  // XXX is this MT safe?
   }

 private:

   _Sp_counted_base(_Sp_counted_base const&);
   _Sp_counted_base& operator= (_Sp_counted_base const&);

   _Atomic_word _M_use_count;        // #shared
   _Atomic_word _M_weak_count;       // #weak + (#shared != 0)
   __gnu_cxx::mutex_type _M_mutex;
 };

 template <typename _Ptr, typename _Deleter>
 class _Sp_counted_base_impl : public _Sp_counted_base
 {
 public:

   /**
    *  @brief
    *  @pre     d(p) must not throw.
    */
   _Sp_counted_base_impl(_Ptr __p, _Deleter __d)
   : _M_ptr(__p), _M_del(__d)
   { }

   virtual void
   dispose() // nothrow
   {
     _M_del(_M_ptr);
   }

   virtual void*
   get_deleter(const std::type_info& __ti)
   {
     return __ti == typeid(_Deleter) ? &_M_del : 0;
   }

 private:
   _Sp_counted_base_impl(const _Sp_counted_base_impl&);
   _Sp_counted_base_impl& operator=(const _Sp_counted_base_impl&);

   _Ptr     _M_ptr; // copy constructor must not throw
   _Deleter _M_del; // copy constructor must not throw
 };

 class weak_count;

 class shared_count
 {
 private:

   _Sp_counted_base* _M_pi;

   friend class weak_count;

 public:

   shared_count()
   : _M_pi(0) // nothrow
   { }

   template <typename _Ptr, typename _Deleter>
     shared_count(_Ptr __p, _Deleter __d)
     : _M_pi(0)
     {
       try
       {
         _M_pi = new _Sp_counted_base_impl<_Ptr, _Deleter>(__p, __d);
       }
       catch(...)
       {
         __d(__p); // delete __p
         __throw_exception_again;
       }
     }

   // auto_ptr<_Tp> is special cased to provide the strong guarantee

   template <typename _Tp>
     explicit shared_count(std::auto_ptr<_Tp>& __r)
     : _M_pi(new _Sp_counted_base_impl<_Tp*,_Sp_deleter<_Tp> >(
             __r.get(), _Sp_deleter<_Tp>()
             ))
     { __r.release(); }

   // throws bad_weak_ptr when __r.use_count() == 0
   explicit shared_count(const weak_count& __r);

   ~shared_count() // nothrow
   {
     if (_M_pi != 0)
       _M_pi->release();
   }

   shared_count(const shared_count& __r)
   : _M_pi(__r._M_pi) // nothrow
   {
     if (_M_pi != 0)
       _M_pi->add_ref_copy();
   }

   shared_count&
   operator=(const shared_count& __r) // nothrow
   {
     _Sp_counted_base* __tmp = __r._M_pi;

     if(__tmp != _M_pi)
     {
       if(__tmp != 0)
         __tmp->add_ref_copy();
       if(_M_pi != 0)
         _M_pi->release();
       _M_pi = __tmp;
     }
     return *this;
   }

   void swap(shared_count& __r) // nothrow
   {
     _Sp_counted_base* __tmp = __r._M_pi;
     __r._M_pi = _M_pi;
     _M_pi = __tmp;
   }

   long
   use_count() const // nothrow
   { return _M_pi != 0 ? _M_pi->use_count() : 0; }

   bool
   unique() const // nothrow
   { return this->use_count() == 1; }

   friend inline bool
   operator==(const shared_count& __a, const shared_count& __b)
   { return __a._M_pi == __b._M_pi; }

   friend inline bool
   operator<(const shared_count& __a, const shared_count& __b)
   { return std::less<_Sp_counted_base*>()(__a._M_pi, __b._M_pi); }

   void*
   get_deleter(const std::type_info& __ti) const
   { return _M_pi ? _M_pi->get_deleter(__ti) : 0; }
 };


 class weak_count
 {
 private:

   _Sp_counted_base * _M_pi;

   friend class shared_count;

 public:

   weak_count()
   : _M_pi(0) // nothrow
   { }

   weak_count(const shared_count& __r)
   : _M_pi(__r._M_pi) // nothrow
   {
     if (_M_pi != 0)
       _M_pi->weak_add_ref();
   }

   weak_count(const weak_count& __r)
   : _M_pi(__r._M_pi) // nothrow
   {
     if (_M_pi != 0)
       _M_pi->weak_add_ref();
   }

   ~weak_count() // nothrow
   {
     if (_M_pi != 0)
       _M_pi->weak_release();
   }

   weak_count&
   operator=(const shared_count& __r) // nothrow
   {
     _Sp_counted_base* __tmp = __r._M_pi;
     if (__tmp != 0)
       __tmp->weak_add_ref();
     if (_M_pi != 0)
       _M_pi->weak_release();
     _M_pi = __tmp;

     return *this;
   }

   weak_count&
   operator=(const weak_count& __r) // nothrow
   {
     _Sp_counted_base * __tmp = __r._M_pi;
     if (__tmp != 0)
       __tmp->weak_add_ref();
     if (_M_pi != 0)
       _M_pi->weak_release();
     _M_pi = __tmp;

     return *this;
   }

   void
   swap(weak_count& __r) // nothrow
   {
     _Sp_counted_base * __tmp = __r._M_pi;
     __r._M_pi = _M_pi;
     _M_pi = __tmp;
   }

   long
   use_count() const // nothrow
   { return _M_pi != 0 ? _M_pi->use_count() : 0; }

   friend inline bool
   operator==(const weak_count& __a, const weak_count& __b)
   { return __a._M_pi == __b._M_pi; }

   friend inline bool
   operator<(const weak_count& __a, const weak_count& __b)
   { return std::less<_Sp_counted_base*>()(__a._M_pi, __b._M_pi); }
 };

 inline
 shared_count::shared_count(const weak_count& __r)
 : _M_pi(__r._M_pi)
 {
   if (_M_pi != 0)
   {
     _M_pi->add_ref_lock();
   }
   else
   {
     __throw_bad_weak_ptr();
   }
 }

 // fwd decls
 template <typename _Tp> class weak_ptr;
 template <typename _Tp> class enable_shared_from_this;

 struct __static_cast_tag {};
 struct __const_cast_tag {};
 struct __dynamic_cast_tag {};
 struct __polymorphic_cast_tag {};

 template<class _Tp> struct shared_ptr_traits
 {
     typedef _Tp & reference;
 };

 template<> struct shared_ptr_traits<void>
 {
     typedef void reference;
 };

 template<> struct shared_ptr_traits<void const>
 {
     typedef void reference;
 };

 template<> struct shared_ptr_traits<void volatile>
 {
     typedef void reference;
 };

 template<> struct shared_ptr_traits<void const volatile>
 {
     typedef void reference;
 };


 // enable_shared_from_this support

 // friend of enable_shared_from_this
 template <typename _Tp1, typename _Tp2>
   void
   __enable_shared_from_this( const shared_count& __pn,
                              const enable_shared_from_this<_Tp1>* __pe,
                              const _Tp2* __px );

 inline void
 __enable_shared_from_this(const shared_count&, ...)
 { }

 /**
  *  @class shared_ptr <tr1/memory>
  *
  *  A smart pointer with reference-counted copy semantics.
  *  The object pointed to is deleted when the last shared_ptr pointing to it
  *  is destroyed or reset.
  */

 template <typename _Tp>
   class shared_ptr
   {
     typedef typename shared_ptr_traits<_Tp>::reference _Reference;

   public:

     typedef _Tp   element_type;

     /** @brief  Construct an empty %shared_ptr.
      *  @post   use_count()==0 && get()==0
      */
     shared_ptr() : _M_ptr(0), _M_refcount() // never throws
     { }

     /** @brief  Construct a %shared_ptr that owns the pointer @a p.
      *  @param  p  A pointer that is convertible to element_type*.
      *  @post   use_count()==1 && get()==p
      *  @throw  std::bad_alloc, in which case @c delete @a p is called.
      */
     template <typename _Tp1>
       explicit shared_ptr(_Tp1* __p)
       : _M_ptr(__p), _M_refcount(__p, _Sp_deleter<_Tp1>())
       {
         __glibcxx_function_requires(_ConvertibleConcept<_Tp1*, _Tp*>)
         // __glibcxx_function_requires(_CompleteConcept<_Tp1*>)

         __enable_shared_from_this( _M_refcount, __p, __p );
       }

     //
     // Requirements: D's copy constructor and destructor must not throw
     //
     // shared_ptr will release p by calling d(p)
     //
     /** @brief  Construct a %shared_ptr that owns the pointer @a p
      *          and the deleter @a d.
      *  @param  p  A pointer.
      *  @param  d  A deleter.
      *  @post   use_count()==1 && get()==p
      *  @throw  std::bad_alloc, in which case @a d(p) is called.
      */
     template <typename _Tp1, typename _Deleter>
       shared_ptr(_Tp1* __p, _Deleter __d)
       : _M_ptr(__p), _M_refcount(__p, __d)
       {
         __glibcxx_function_requires(_ConvertibleConcept<_Tp1*, _Tp*>)
         // TODO requires D is CopyConstructible and d(p) well-formed

         __enable_shared_from_this( _M_refcount, __p, __p );
       }

     //  generated copy constructor, assignment, destructor are fine.

     /** @brief  If @a r is empty, constructs an empty %shared_ptr; otherwise
      *          construct a %shared_ptr that shares ownership with @a r.
      *  @param  r  A %shared_ptr.
      *  @post   get()==r.get() && use_count()==r.use_count()
      *  @throw  std::bad_alloc, in which case
      */
     template <typename _Tp1>
       shared_ptr(const shared_ptr<_Tp1>& __r)
       : _M_ptr(__r._M_ptr), _M_refcount(__r._M_refcount) // never throws
       {
         __glibcxx_function_requires(_ConvertibleConcept<_Tp1*, _Tp*>)
       }

     /** @brief  Constructs a %shared_ptr that shares ownership with @a r
      *          and stores a copy of the pointer stored in @a r.
      *  @param  r  A weak_ptr.
      *  @post   use_count()==r.use_count()
      *  @throw  bad_weak_ptr when r.expired(),
      *          in which case the constructor has no effect.
      */
     template <typename _Tp1>
       explicit shared_ptr(const weak_ptr<_Tp1>& __r)
       : _M_refcount(__r._M_refcount) // may throw
       {
         __glibcxx_function_requires(_ConvertibleConcept<_Tp1*, _Tp*>)
         // it is now safe to copy r__._M_ptr, as _M_refcount(__r._M_refcount)
         // did not throw
         _M_ptr = __r._M_ptr;
       }

     /**
      * @post use_count()==1 and r.get()==0
      */
     template <typename _Tp1>
       explicit shared_ptr(std::auto_ptr<_Tp1>& __r)
       : _M_ptr(__r.get()), _M_refcount()
       {
         // TODO requires r.release() convertible to _Tp*, Tp1 is complete,
         // delete r.release() well-formed
         _Tp1 * __tmp = __r.get();
         _M_refcount = shared_count(__r);

         __enable_shared_from_this( _M_refcount, __tmp, __tmp );
       }

     template <typename _Tp1>
       shared_ptr(const shared_ptr<_Tp1>& __r, __static_cast_tag)
       : _M_ptr(static_cast<element_type*>(__r._M_ptr))
       , _M_refcount(__r._M_refcount)
       { }

     template <typename _Tp1>
       shared_ptr(const shared_ptr<_Tp1>& __r, __const_cast_tag)
       : _M_ptr(const_cast<element_type*>(__r._M_ptr))
       , _M_refcount(__r._M_refcount)
       { }

     template <typename _Tp1>
       shared_ptr(const shared_ptr<_Tp1>& __r, __dynamic_cast_tag)
       : _M_ptr(dynamic_cast<element_type*>(__r._M_ptr))
       , _M_refcount(__r._M_refcount)
       {
         if (_M_ptr == 0) // need to allocate new counter -- the cast failed
         {
           _M_refcount = shared_count();
         }
       }

     template <typename _Tp1>
       shared_ptr&
       operator=(const shared_ptr<_Tp1>& __r) // never throws
       {
         _M_ptr = __r._M_ptr;
         _M_refcount = __r._M_refcount; // shared_count::op= doesn't throw
         return *this;
       }

     template <typename _Tp1>
       shared_ptr&
       operator=(std::auto_ptr<_Tp1>& __r)
       {
         shared_ptr(__r).swap(*this);
         return *this;
       }

     void
     reset() // never throws
     { shared_ptr().swap(*this); }

     template <typename _Tp1>
       void
       reset(_Tp1* __p) // _Tp1 must be complete
       {
         _GLIBCXX_DEBUG_ASSERT(__p == 0 || __p != _M_ptr); // catch self-reset errors
         shared_ptr(__p).swap(*this);
       }

     template <typename _Tp1, typename _Deleter>
       void
       reset(_Tp1 * __p, _Deleter __d)
       { shared_ptr(__p, __d).swap(*this); }

     // error to instantiate if _Tp is [cv-qual] void
     _Reference
     operator*() const // never throws
     {
       _GLIBCXX_DEBUG_ASSERT(_M_ptr != 0);
       return *_M_ptr;
     }

     _Tp*
     operator->() const // never throws
     {
       _GLIBCXX_DEBUG_ASSERT(_M_ptr != 0);
       return _M_ptr;
     }

     _Tp*
     get() const // never throws
     { return _M_ptr; }

     // implicit conversion to "bool"
   private:
     typedef _Tp* shared_ptr::*__unspecified_bool_type;

   public:
     operator __unspecified_bool_type() const // never throws
     { return _M_ptr == 0 ? 0 : &shared_ptr::_M_ptr; }

     bool
     unique() const // never throws
     { return _M_refcount.unique(); }

     long
     use_count() const // never throws
     { return _M_refcount.use_count(); }

     void
     swap(shared_ptr<_Tp>& __other) // never throws
     {
       std::swap(_M_ptr, __other._M_ptr);
       _M_refcount.swap(__other._M_refcount);
     }

   private:
     template <typename _Tp1>
       bool
       _M_less(const shared_ptr<_Tp1>& __rhs) const
       { return _M_refcount < __rhs._M_refcount; }

     void*
     _M_get_deleter(const std::type_info& __ti) const
     { return _M_refcount.get_deleter(__ti); }

     template <typename _Tp1> friend class shared_ptr;
     template <typename _Tp1> friend class weak_ptr;

     // friends injected into enclosing namespace and found by ADL:

     // get_deleter (experimental)
     template <typename _Del>
       friend inline _Del*
       get_deleter(const shared_ptr& __p)
       { return static_cast<_Del*>(__p._M_get_deleter(typeid(_Del))); }

     template <typename _Tp1>
       friend inline bool
       operator==(const shared_ptr& __a, const shared_ptr<_Tp1>& __b)
       { return __a.get() == __b.get(); }

     template <typename _Tp1>
       friend inline bool
       operator!=(const shared_ptr& __a, const shared_ptr<_Tp1>& __b)
       { return __a.get() != __b.get(); }

     template <typename _Tp1>
       friend inline bool
       operator<(const shared_ptr& __a, const shared_ptr<_Tp1>& __b)
       { return __a._M_less(__b); }

     _Tp*         _M_ptr;         // contained pointer
     shared_count _M_refcount;    // reference counter
   };  // shared_ptr

 // 2.2.3.9 shared_ptr casts

 /** @warning The seemingly equivalent
  *           <code>shared_ptr<T>(static_cast<T*>(r.get()))</code>
  *           will eventually result in undefined behaviour,
  *           attempting to delete the same object twice.
  */
 template <typename _Tp, typename _Tp1>
   shared_ptr<_Tp>
   static_pointer_cast(const shared_ptr<_Tp1>& __r)
   {
     return shared_ptr<_Tp>(__r, __static_cast_tag());
   }

 /** @warning The seemingly equivalent
  *           <code>shared_ptr<T>(const_cast<T*>(r.get()))</code>
  *           will eventually result in undefined behaviour,
  *           attempting to delete the same object twice.
  */
 template <typename _Tp, typename _Tp1>
   shared_ptr<_Tp>
   const_pointer_cast(const shared_ptr<_Tp1>& __r)
   {
     return shared_ptr<_Tp>(__r, __const_cast_tag());
   }

 /** @warning The seemingly equivalent
  *           <code>shared_ptr<T>(dynamic_cast<T*>(r.get()))</code>
  *           will eventually result in undefined behaviour,
  *           attempting to delete the same object twice.
  */
 template <typename _Tp, typename _Tp1>
   shared_ptr<_Tp>
   dynamic_pointer_cast(const shared_ptr<_Tp1>& __r)
   {
     return shared_ptr<_Tp>(__r, __dynamic_cast_tag());
   }

 // operator<<
 template <typename _Ch, typename _Tr, typename _Tp>
   std::basic_ostream<_Ch,_Tr>&
   operator<<(std::basic_ostream<_Ch,_Tr>& __os, const shared_ptr<_Tp>& __p)
   {
     __os << __p.get();
     return __os;
   }


 template <typename _Tp>
   class weak_ptr
   {
   public:

     typedef _Tp element_type;

     weak_ptr()
     : _M_ptr(0), _M_refcount() // never throws
     { }

   //  generated copy constructor, assignment, destructor are fine

   //
   //  The "obvious" converting constructor implementation:
   //
   //  template<class Y>
   //  weak_ptr(weak_ptr<Y> const & r): _M_ptr(r._M_ptr), _M_refcount(r._M_refcount) // never throws
   //  {
   //  }
   //
   //  has a serious problem.
   //
   //  r._M_ptr may already have been invalidated. The _M_ptr(r._M_ptr)
   //  conversion may require access to *r._M_ptr (virtual inheritance).
   //
   //  It is not possible to avoid spurious access violations since
   //  in multithreaded programs r._M_ptr may be invalidated at any point.
   //

     template <typename _Tp1>
       weak_ptr(const weak_ptr<_Tp1>& r)
       : _M_refcount(r._M_refcount) // never throws
       {
         __glibcxx_function_requires(_ConvertibleConcept<_Tp1*, _Tp*>)
         _M_ptr = r.lock().get();
       }

     template <typename _Tp1>
       weak_ptr(const shared_ptr<_Tp1>& r)
       : _M_ptr(r._M_ptr), _M_refcount(r._M_refcount) // never throws
       {
         __glibcxx_function_requires(_ConvertibleConcept<_Tp1*, _Tp*>)
       }

     template <typename _Tp1>
       weak_ptr&
       operator=(const weak_ptr<_Tp1>& r) // never throws
       {
         _M_ptr = r.lock().get();
         _M_refcount = r._M_refcount;
         return *this;
       }

     template <typename _Tp1>
       weak_ptr&
       operator=(const shared_ptr<_Tp1>& r) // never throws
       {
         _M_ptr = r._M_ptr;
         _M_refcount = r._M_refcount;
         return *this;
       }

     shared_ptr<_Tp>
     lock() const // never throws
     {
 #ifdef __GTHREADS

       // optimization: avoid throw overhead
       if (expired())
       {
         return shared_ptr<element_type>();
       }

       try
       {
         return shared_ptr<element_type>(*this);
       }
       catch (const bad_weak_ptr&)
       {
         // Q: how can we get here?
         // A: another thread may have invalidated r after the use_count test above.
         return shared_ptr<element_type>();
       }

 #else

       // optimization: avoid try/catch overhead when single threaded
       return expired() ? shared_ptr<element_type>() : shared_ptr<element_type>(*this);

 #endif
     } // XXX MT


     long
     use_count() const // never throws
     { return _M_refcount.use_count(); }

     bool
     expired() const // never throws
     { return _M_refcount.use_count() == 0; }

     void
     reset() // never throws
     { weak_ptr().swap(*this); }

     void
     swap(weak_ptr& __s) // never throws
     {
       std::swap(_M_ptr, __s._M_ptr);
       _M_refcount.swap(__s._M_refcount);
     }

   private:

     template <typename _Tp1>
       bool
       _M_less(const weak_ptr<_Tp1>& __rhs) const
       { return _M_refcount < __rhs._M_refcount; }

     // used by __enable_shared_from_this
     void
     _M_assign(_Tp* __ptr, const shared_count& __refcount)
     {
       _M_ptr = __ptr;
       _M_refcount = __refcount;
     }

     // friend injected into namespace and found by ADL

     template <typename _Tp1>
       friend inline bool
       operator<(const weak_ptr& __lhs, const weak_ptr<_Tp1>& __rhs)
       { return __lhs._M_less(__rhs); }

     template <typename _Tp1> friend class weak_ptr;
     template <typename _Tp1> friend class shared_ptr;
     friend class enable_shared_from_this<_Tp>;

     _Tp*       _M_ptr;           // contained pointer
     weak_count _M_refcount;      // reference counter

   };  // weak_ptr


 template <typename _Tp>
   class enable_shared_from_this
   {
   protected:

     enable_shared_from_this()
     { }

     enable_shared_from_this(const enable_shared_from_this&)
     { }

     enable_shared_from_this&
     operator=(const enable_shared_from_this&)
     { return *this; }

     ~enable_shared_from_this()
     { }

   public:

     shared_ptr<_Tp>
     shared_from_this()
     {
       shared_ptr<_Tp> p(this->_M_weak_this);
       return p;
     }

     shared_ptr<const _Tp>
     shared_from_this() const
     {
       shared_ptr<const _Tp> p(this->_M_weak_this);
       return p;
     }

   private:
     template <typename _Tp1>
       void
       _M_weak_assign(_Tp1* __p, const shared_count& __n) const
       { _M_weak_this._M_assign(__p, __n); }

     template <typename _Tp1>
       friend void
       __enable_shared_from_this( const shared_count& __pn, const enable_shared_from_this* __pe, const _Tp1* __px)
       {
         if(__pe != 0)
           __pe->_M_weak_assign(const_cast<_Tp1*>(__px), __pn);
       }

     mutable weak_ptr<_Tp> _M_weak_this;
   };

 } // namespace tr1

 /**
  *  @brief   std::swap() specialisation for shared_ptr.
  *  @relates shared_ptr.
  */
 template <typename _Tp>
   inline void
   swap(tr1::shared_ptr<_Tp>& __a, tr1::shared_ptr<_Tp>& __b)
   {
     __a.swap(__b);
   }

 /**
  *  @brief   std::swap() specialisation for weak_ptr.
  *  @relates weak_ptr.
  */
 template <typename _Tp>
   void
   swap(tr1::weak_ptr<_Tp>& __a, tr1::weak_ptr<_Tp>& __b)
   {
     __a.swap(__b);
   }

 } // namespace std

 #endif
	// <tr1/boost_shared_ptr.h> -- C++ --

	// Copyright (C) 2005 Free Software Foundation, Inc.
	//
	// This file is part of the GNU ISO C++ Library. This library is free
	// software; you can redistribute it and/or modify it under the
	// terms of the GNU General Public License as published by the
	// Free Software Foundation; either version 2, or (at your option)
	// any later version.

	// This library is distributed in the hope that it will be useful,
	// but WITHOUT ANY WARRANTY; without even the implied warranty of
	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	// GNU General Public License for more details.

	// You should have received a copy of the GNU General Public License along
	// with this library; see the file COPYING. If not, write to the Free
	// Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307,
	// USA.

	// As a special exception, you may use this file as part of a free software
	// library without restriction. Specifically, if other files instantiate
	// templates or use macros or inline functions from this file, or you compile
	// this file and link it with other files to produce an executable, this
	// file does not by itself cause the resulting executable to be covered by
	// the GNU General Public License. This exception does not however
	// invalidate any other reasons why the executable file might be covered by
	// the GNU General Public License.

	// shared_count.hpp
	// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.

	// shared_ptr.hpp
	// Copyright (C) 1998, 1999 Greg Colvin and Beman Dawes.
	// Copyright (C) 2001, 2002, 2003 Peter Dimov

	// weak_ptr.hpp
	// Copyright (C) 2001, 2002, 2003 Peter Dimov

	// enable_shared_from_this.hpp
	// Copyright (C) 2002 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)

	// GCC Note: based on version 1.32.0 of the Boost library.

	/** @file boost_memory.h
	* This is an internal header file, included by other library headers.
	* You should not attempt to use it directly.
	*/

	#ifndef _BOOST_SHARED_PTR_H
	#define _BOOST_SHARED_PTR_H 1

	// namespace std::tr1
	namespace std
	{
	namespace tr1
	{

	class bad_weak_ptr : public std::exception
	{
	public:

	virtual char const* what() const throw()
	{
	return "tr1::bad_weak_ptr";
	}
	};

	// Helper for exception objects in <tr1/memory>
	// TODO this should be defined in a different file.
	inline void
	__throw_bad_weak_ptr()
	{
	#if __EXCEPTIONS
	throw bad_weak_ptr();
	#else
	std::abort();
	#endif
	}


	template <typename _Tp>
	struct _Sp_deleter
	{
	typedef void result_type;
	typedef _Tp* argument_type;

	void
	operator()(_Tp* p) const
	{ delete p; }
	};


	class _Sp_counted_base
	{
	public:

	_Sp_counted_base()
	: _M_use_count(1), _M_weak_count(1)
	{ }

	virtual
	~_Sp_counted_base() // nothrow
	{ }

	// dispose() is called when _M_use_count drops to zero, to release
	// the resources managed by *this.
	virtual void
	dispose() = 0; // nothrow

	// destroy() is called when _M_weak_count drops to zero.
	virtual void
	destroy() // nothrow
	{
	delete this;
	}

	virtual void*
	get_deleter(const std::type_info&) = 0;

	void
	add_ref_copy()
	{
	__gnu_cxx::__atomic_add(&_M_use_count, 1);
	}

	void
	add_ref_lock()
	{
	__gnu_cxx::lock lock(_M_mutex);
	if (__gnu_cxx::__exchange_and_add(&_M_use_count, 1) == 0)
	{
	_M_use_count = 0;
	__throw_bad_weak_ptr();
	}
	}

	void
	release() // nothrow
	{
	if (__gnu_cxx::__exchange_and_add(&_M_use_count, -1) == 1)
	{
	dispose();
	__glibcxx_mutex_lock(_M_mutex);
	__glibcxx_mutex_unlock(_M_mutex);
	weak_release();
	}
	}

	void
	weak_add_ref() // nothrow
	{
	__gnu_cxx::__atomic_add(&_M_weak_count, 1);
	}

	void
	weak_release() // nothrow
	{
	if (__gnu_cxx::__exchange_and_add(&_M_weak_count, -1) == 1)
	{
	__glibcxx_mutex_lock(_M_mutex);
	__glibcxx_mutex_unlock(_M_mutex);
	destroy();
	}
	}

	long
	use_count() const // nothrow
	{
	return _M_use_count; // XXX is this MT safe?
	}

	private:

	_Sp_counted_base(_Sp_counted_base const&);
	_Sp_counted_base& operator= (_Sp_counted_base const&);

	_Atomic_word _M_use_count; // #shared
	_Atomic_word _M_weak_count; // #weak + (#shared != 0)
	__gnu_cxx::mutex_type _M_mutex;
	};

	template <typename _Ptr, typename _Deleter>
	class _Sp_counted_base_impl : public _Sp_counted_base
	{
	public:

	/**
	* @brief
	* @pre d(p) must not throw.
	*/
	_Sp_counted_base_impl(_Ptr __p, _Deleter __d)
	: _M_ptr(__p), _M_del(__d)
	{ }

	virtual void
	dispose() // nothrow
	{
	_M_del(_M_ptr);
	}

	virtual void*
	get_deleter(const std::type_info& __ti)
	{
	return __ti == typeid(_Deleter) ? &_M_del : 0;
	}

	private:
	_Sp_counted_base_impl(const _Sp_counted_base_impl&);
	_Sp_counted_base_impl& operator=(const _Sp_counted_base_impl&);

	_Ptr _M_ptr; // copy constructor must not throw
	_Deleter _M_del; // copy constructor must not throw
	};

	class weak_count;

	class shared_count
	{
	private:

	_Sp_counted_base* _M_pi;

	friend class weak_count;

	public:

	shared_count()
	: _M_pi(0) // nothrow
	{ }

	template <typename _Ptr, typename _Deleter>
	shared_count(_Ptr __p, _Deleter __d)
	: _M_pi(0)
	{
	try
	{
	_M_pi = new _Sp_counted_base_impl<_Ptr, _Deleter>(__p, __d);
	}
	catch(...)
	{
	__d(__p); // delete __p
	__throw_exception_again;
	}
	}

	// auto_ptr<_Tp> is special cased to provide the strong guarantee

	template <typename _Tp>
	explicit shared_count(std::auto_ptr<_Tp>& __r)
	: _M_pi(new _Sp_counted_base_impl<_Tp*,_Sp_deleter<_Tp> >(
	__r.get(), _Sp_deleter<_Tp>()
	))
	{ __r.release(); }

	// throws bad_weak_ptr when __r.use_count() == 0
	explicit shared_count(const weak_count& __r);

	~shared_count() // nothrow
	{
	if (_M_pi != 0)
	_M_pi->release();
	}

	shared_count(const shared_count& __r)
	: _M_pi(__r._M_pi) // nothrow
	{
	if (_M_pi != 0)
	_M_pi->add_ref_copy();
	}

	shared_count&
	operator=(const shared_count& __r) // nothrow
	{
	_Sp_counted_base* __tmp = __r._M_pi;

	if(__tmp != _M_pi)
	{
	if(__tmp != 0)
	__tmp->add_ref_copy();
	if(_M_pi != 0)
	_M_pi->release();
	_M_pi = __tmp;
	}
	return *this;
	}

	void swap(shared_count& __r) // nothrow
	{
	_Sp_counted_base* __tmp = __r._M_pi;
	__r._M_pi = _M_pi;
	_M_pi = __tmp;
	}

	long
	use_count() const // nothrow
	{ return _M_pi != 0 ? _M_pi->use_count() : 0; }

	bool
	unique() const // nothrow
	{ return this->use_count() == 1; }

	friend inline bool
	operator==(const shared_count& __a, const shared_count& __b)
	{ return __a._M_pi == __b._M_pi; }

	friend inline bool
	operator<(const shared_count& __a, const shared_count& __b)
	{ return std::less<_Sp_counted_base*>()(__a._M_pi, __b._M_pi); }

	void*
	get_deleter(const std::type_info& __ti) const
	{ return _M_pi ? _M_pi->get_deleter(__ti) : 0; }
	};


	class weak_count
	{
	private:

	_Sp_counted_base * _M_pi;

	friend class shared_count;

	public:

	weak_count()
	: _M_pi(0) // nothrow
	{ }

	weak_count(const shared_count& __r)
	: _M_pi(__r._M_pi) // nothrow
	{
	if (_M_pi != 0)
	_M_pi->weak_add_ref();
	}

	weak_count(const weak_count& __r)
	: _M_pi(__r._M_pi) // nothrow
	{
	if (_M_pi != 0)
	_M_pi->weak_add_ref();
	}

	~weak_count() // nothrow
	{
	if (_M_pi != 0)
	_M_pi->weak_release();
	}

	weak_count&
	operator=(const shared_count& __r) // nothrow
	{
	_Sp_counted_base* __tmp = __r._M_pi;
	if (__tmp != 0)
	__tmp->weak_add_ref();
	if (_M_pi != 0)
	_M_pi->weak_release();
	_M_pi = __tmp;

	return *this;
	}

	weak_count&
	operator=(const weak_count& __r) // nothrow
	{
	_Sp_counted_base * __tmp = __r._M_pi;
	if (__tmp != 0)
	__tmp->weak_add_ref();
	if (_M_pi != 0)
	_M_pi->weak_release();
	_M_pi = __tmp;

	return *this;
	}

	void
	swap(weak_count& __r) // nothrow
	{
	_Sp_counted_base * __tmp = __r._M_pi;
	__r._M_pi = _M_pi;
	_M_pi = __tmp;
	}

	long
	use_count() const // nothrow
	{ return _M_pi != 0 ? _M_pi->use_count() : 0; }

	friend inline bool
	operator==(const weak_count& __a, const weak_count& __b)
	{ return __a._M_pi == __b._M_pi; }

	friend inline bool
	operator<(const weak_count& __a, const weak_count& __b)
	{ return std::less<_Sp_counted_base*>()(__a._M_pi, __b._M_pi); }
	};

	inline
	shared_count::shared_count(const weak_count& __r)
	: _M_pi(__r._M_pi)
	{
	if (_M_pi != 0)
	{
	_M_pi->add_ref_lock();
	}
	else
	{
	__throw_bad_weak_ptr();
	}
	}

	// fwd decls
	template <typename _Tp> class weak_ptr;
	template <typename _Tp> class enable_shared_from_this;

	struct __static_cast_tag {};
	struct __const_cast_tag {};
	struct __dynamic_cast_tag {};
	struct __polymorphic_cast_tag {};

	template<class _Tp> struct shared_ptr_traits
	{
	typedef _Tp & reference;
	};

	template<> struct shared_ptr_traits<void>
	{
	typedef void reference;
	};

	template<> struct shared_ptr_traits<void const>
	{
	typedef void reference;
	};

	template<> struct shared_ptr_traits<void volatile>
	{
	typedef void reference;
	};

	template<> struct shared_ptr_traits<void const volatile>
	{
	typedef void reference;
	};


	// enable_shared_from_this support

	// friend of enable_shared_from_this
	template <typename _Tp1, typename _Tp2>
	void
	__enable_shared_from_this( const shared_count& __pn,
	const enable_shared_from_this<_Tp1>* __pe,
	const _Tp2* __px );

	inline void
	__enable_shared_from_this(const shared_count&, ...)
	{ }

	/**
	* @class shared_ptr <tr1/memory>
	*
	* A smart pointer with reference-counted copy semantics.
	* The object pointed to is deleted when the last shared_ptr pointing to it
	* is destroyed or reset.
	*/

	template <typename _Tp>
	class shared_ptr
	{
	typedef typename shared_ptr_traits<_Tp>::reference _Reference;

	public:

	typedef _Tp element_type;

	/** @brief Construct an empty %shared_ptr.
	* @post use_count()==0 && get()==0
	*/
	shared_ptr() : _M_ptr(0), _M_refcount() // never throws
	{ }

	/** @brief Construct a %shared_ptr that owns the pointer @a p.
	* @param p A pointer that is convertible to element_type*.
	* @post use_count()==1 && get()==p
	* @throw std::bad_alloc, in which case @c delete @a p is called.
	*/
	template <typename _Tp1>
	explicit shared_ptr(_Tp1* __p)
	: _M_ptr(__p), _M_refcount(__p, _Sp_deleter<_Tp1>())
	{
	__glibcxx_function_requires(_ConvertibleConcept<_Tp1, _Tp>)
	// __glibcxx_function_requires(_CompleteConcept<_Tp1*>)

	__enable_shared_from_this( _M_refcount, __p, __p );
	}

	//
	// Requirements: D's copy constructor and destructor must not throw
	//
	// shared_ptr will release p by calling d(p)
	//
	/** @brief Construct a %shared_ptr that owns the pointer @a p
	* and the deleter @a d.
	* @param p A pointer.
	* @param d A deleter.
	* @post use_count()==1 && get()==p
	* @throw std::bad_alloc, in which case @a d(p) is called.
	*/
	template <typename _Tp1, typename _Deleter>
	shared_ptr(_Tp1* __p, _Deleter __d)
	: _M_ptr(__p), _M_refcount(__p, __d)
	{
	__glibcxx_function_requires(_ConvertibleConcept<_Tp1, _Tp>)
	// TODO requires D is CopyConstructible and d(p) well-formed

	__enable_shared_from_this( _M_refcount, __p, __p );
	}

	// generated copy constructor, assignment, destructor are fine.

	/** @brief If @a r is empty, constructs an empty %shared_ptr; otherwise
	* construct a %shared_ptr that shares ownership with @a r.
	* @param r A %shared_ptr.
	* @post get()==r.get() && use_count()==r.use_count()
	* @throw std::bad_alloc, in which case
	*/
	template <typename _Tp1>
	shared_ptr(const shared_ptr<_Tp1>& __r)
	: _M_ptr(__r._M_ptr), _M_refcount(__r._M_refcount) // never throws
	{
	__glibcxx_function_requires(_ConvertibleConcept<_Tp1, _Tp>)
	}

	/** @brief Constructs a %shared_ptr that shares ownership with @a r
	* and stores a copy of the pointer stored in @a r.
	* @param r A weak_ptr.
	* @post use_count()==r.use_count()
	* @throw bad_weak_ptr when r.expired(),
	* in which case the constructor has no effect.
	*/
	template <typename _Tp1>
	explicit shared_ptr(const weak_ptr<_Tp1>& __r)
	: _M_refcount(__r._M_refcount) // may throw
	{
	__glibcxx_function_requires(_ConvertibleConcept<_Tp1, _Tp>)
	// it is now safe to copy r__._M_ptr, as _M_refcount(__r._M_refcount)
	// did not throw
	_M_ptr = __r._M_ptr;
	}

	/**
	* @post use_count()==1 and r.get()==0
	*/
	template <typename _Tp1>
	explicit shared_ptr(std::auto_ptr<_Tp1>& __r)
	: _M_ptr(__r.get()), _M_refcount()
	{
	// TODO requires r.release() convertible to _Tp*, Tp1 is complete,
	// delete r.release() well-formed
	_Tp1 * __tmp = __r.get();
	_M_refcount = shared_count(__r);

	__enable_shared_from_this( _M_refcount, __tmp, __tmp );
	}

	template <typename _Tp1>
	shared_ptr(const shared_ptr<_Tp1>& __r, __static_cast_tag)
	: _M_ptr(static_cast<element_type*>(__r._M_ptr))
	, _M_refcount(__r._M_refcount)
	{ }

	template <typename _Tp1>
	shared_ptr(const shared_ptr<_Tp1>& __r, __const_cast_tag)
	: _M_ptr(const_cast<element_type*>(__r._M_ptr))
	, _M_refcount(__r._M_refcount)
	{ }

	template <typename _Tp1>
	shared_ptr(const shared_ptr<_Tp1>& __r, __dynamic_cast_tag)
	: _M_ptr(dynamic_cast<element_type*>(__r._M_ptr))
	, _M_refcount(__r._M_refcount)
	{
	if (_M_ptr == 0) // need to allocate new counter -- the cast failed
	{
	_M_refcount = shared_count();
	}
	}

	template <typename _Tp1>
	shared_ptr&
	operator=(const shared_ptr<_Tp1>& __r) // never throws
	{
	_M_ptr = __r._M_ptr;
	_M_refcount = __r._M_refcount; // shared_count::op= doesn't throw
	return *this;
	}

	template <typename _Tp1>
	shared_ptr&
	operator=(std::auto_ptr<_Tp1>& __r)
	{
	shared_ptr(__r).swap(*this);
	return *this;
	}

	void
	reset() // never throws
	{ shared_ptr().swap(*this); }

	template <typename _Tp1>
	void
	reset(_Tp1* __p) // _Tp1 must be complete
	{
	_GLIBCXX_DEBUG_ASSERT(__p == 0 \|\| __p != _M_ptr); // catch self-reset errors
	shared_ptr(__p).swap(*this);
	}

	template <typename _Tp1, typename _Deleter>
	void
	reset(_Tp1 * __p, _Deleter __d)
	{ shared_ptr(__p, __d).swap(*this); }

	// error to instantiate if _Tp is [cv-qual] void
	_Reference
	operator*() const // never throws
	{
	_GLIBCXX_DEBUG_ASSERT(_M_ptr != 0);
	return *_M_ptr;
	}

	_Tp*
	operator->() const // never throws
	{
	_GLIBCXX_DEBUG_ASSERT(_M_ptr != 0);
	return _M_ptr;
	}

	_Tp*
	get() const // never throws
	{ return _M_ptr; }

	// implicit conversion to "bool"
	private:
	typedef _Tp* shared_ptr::*__unspecified_bool_type;

	public:
	operator __unspecified_bool_type() const // never throws
	{ return _M_ptr == 0 ? 0 : &shared_ptr::_M_ptr; }

	bool
	unique() const // never throws
	{ return _M_refcount.unique(); }

	long
	use_count() const // never throws
	{ return _M_refcount.use_count(); }

	void
	swap(shared_ptr<_Tp>& __other) // never throws
	{
	std::swap(_M_ptr, __other._M_ptr);
	_M_refcount.swap(__other._M_refcount);
	}

	private:
	template <typename _Tp1>
	bool
	_M_less(const shared_ptr<_Tp1>& __rhs) const
	{ return _M_refcount < __rhs._M_refcount; }

	void*
	_M_get_deleter(const std::type_info& __ti) const
	{ return _M_refcount.get_deleter(__ti); }

	template <typename _Tp1> friend class shared_ptr;
	template <typename _Tp1> friend class weak_ptr;

	// friends injected into enclosing namespace and found by ADL:

	// get_deleter (experimental)
	template <typename _Del>
	friend inline _Del*
	get_deleter(const shared_ptr& __p)
	{ return static_cast<_Del*>(__p._M_get_deleter(typeid(_Del))); }

	template <typename _Tp1>
	friend inline bool
	operator==(const shared_ptr& __a, const shared_ptr<_Tp1>& __b)
	{ return __a.get() == __b.get(); }

	template <typename _Tp1>
	friend inline bool
	operator!=(const shared_ptr& __a, const shared_ptr<_Tp1>& __b)
	{ return __a.get() != __b.get(); }

	template <typename _Tp1>
	friend inline bool
	operator<(const shared_ptr& __a, const shared_ptr<_Tp1>& __b)
	{ return __a._M_less(__b); }

	_Tp* _M_ptr; // contained pointer
	shared_count _M_refcount; // reference counter
	}; // shared_ptr

	// 2.2.3.9 shared_ptr casts

	/** @warning The seemingly equivalent
	* <code>shared_ptr<T>(static_cast<T*>(r.get()))</code>
	* will eventually result in undefined behaviour,
	* attempting to delete the same object twice.
	*/
	template <typename _Tp, typename _Tp1>
	shared_ptr<_Tp>
	static_pointer_cast(const shared_ptr<_Tp1>& __r)
	{
	return shared_ptr<_Tp>(__r, __static_cast_tag());
	}

	/** @warning The seemingly equivalent
	* <code>shared_ptr<T>(const_cast<T*>(r.get()))</code>
	* will eventually result in undefined behaviour,
	* attempting to delete the same object twice.
	*/
	template <typename _Tp, typename _Tp1>
	shared_ptr<_Tp>
	const_pointer_cast(const shared_ptr<_Tp1>& __r)
	{
	return shared_ptr<_Tp>(__r, __const_cast_tag());
	}

	/** @warning The seemingly equivalent
	* <code>shared_ptr<T>(dynamic_cast<T*>(r.get()))</code>
	* will eventually result in undefined behaviour,
	* attempting to delete the same object twice.
	*/
	template <typename _Tp, typename _Tp1>
	shared_ptr<_Tp>
	dynamic_pointer_cast(const shared_ptr<_Tp1>& __r)
	{
	return shared_ptr<_Tp>(__r, __dynamic_cast_tag());
	}

	// operator<<
	template <typename _Ch, typename _Tr, typename _Tp>
	std::basic_ostream<_Ch,_Tr>&
	operator<<(std::basic_ostream<_Ch,_Tr>& __os, const shared_ptr<_Tp>& __p)
	{
	__os << __p.get();
	return __os;
	}


	template <typename _Tp>
	class weak_ptr
	{
	public:

	typedef _Tp element_type;

	weak_ptr()
	: _M_ptr(0), _M_refcount() // never throws
	{ }

	// generated copy constructor, assignment, destructor are fine

	//
	// The "obvious" converting constructor implementation:
	//
	// template<class Y>
	// weak_ptr(weak_ptr<Y> const & r): _M_ptr(r._M_ptr), _M_refcount(r._M_refcount) // never throws
	// {
	// }
	//
	// has a serious problem.
	//
	// r._M_ptr may already have been invalidated. The _M_ptr(r._M_ptr)
	// conversion may require access to *r._M_ptr (virtual inheritance).
	//
	// It is not possible to avoid spurious access violations since
	// in multithreaded programs r._M_ptr may be invalidated at any point.
	//

	template <typename _Tp1>
	weak_ptr(const weak_ptr<_Tp1>& r)
	: _M_refcount(r._M_refcount) // never throws
	{
	__glibcxx_function_requires(_ConvertibleConcept<_Tp1, _Tp>)
	_M_ptr = r.lock().get();
	}

	template <typename _Tp1>
	weak_ptr(const shared_ptr<_Tp1>& r)
	: _M_ptr(r._M_ptr), _M_refcount(r._M_refcount) // never throws
	{
	__glibcxx_function_requires(_ConvertibleConcept<_Tp1, _Tp>)
	}

	template <typename _Tp1>
	weak_ptr&
	operator=(const weak_ptr<_Tp1>& r) // never throws
	{
	_M_ptr = r.lock().get();
	_M_refcount = r._M_refcount;
	return *this;
	}

	template <typename _Tp1>
	weak_ptr&
	operator=(const shared_ptr<_Tp1>& r) // never throws
	{
	_M_ptr = r._M_ptr;
	_M_refcount = r._M_refcount;
	return *this;
	}

	shared_ptr<_Tp>
	lock() const // never throws
	{
	#ifdef __GTHREADS

	// optimization: avoid throw overhead
	if (expired())
	{
	return shared_ptr<element_type>();
	}

	try
	{
	return shared_ptr<element_type>(*this);
	}
	catch (const bad_weak_ptr&)
	{
	// Q: how can we get here?
	// A: another thread may have invalidated r after the use_count test above.
	return shared_ptr<element_type>();
	}

	#else

	// optimization: avoid try/catch overhead when single threaded
	return expired() ? shared_ptr<element_type>() : shared_ptr<element_type>(*this);

	#endif
	} // XXX MT


	long
	use_count() const // never throws
	{ return _M_refcount.use_count(); }

	bool
	expired() const // never throws
	{ return _M_refcount.use_count() == 0; }

	void
	reset() // never throws
	{ weak_ptr().swap(*this); }

	void
	swap(weak_ptr& __s) // never throws
	{
	std::swap(_M_ptr, __s._M_ptr);
	_M_refcount.swap(__s._M_refcount);
	}

	private:

	template <typename _Tp1>
	bool
	_M_less(const weak_ptr<_Tp1>& __rhs) const
	{ return _M_refcount < __rhs._M_refcount; }

	// used by __enable_shared_from_this
	void
	_M_assign(_Tp* __ptr, const shared_count& __refcount)
	{
	_M_ptr = __ptr;
	_M_refcount = __refcount;
	}

	// friend injected into namespace and found by ADL

	template <typename _Tp1>
	friend inline bool
	operator<(const weak_ptr& __lhs, const weak_ptr<_Tp1>& __rhs)
	{ return __lhs._M_less(__rhs); }

	template <typename _Tp1> friend class weak_ptr;
	template <typename _Tp1> friend class shared_ptr;
	friend class enable_shared_from_this<_Tp>;

	_Tp* _M_ptr; // contained pointer
	weak_count _M_refcount; // reference counter

	}; // weak_ptr



	template <typename _Tp>
	class enable_shared_from_this
	{
	protected:

	enable_shared_from_this()
	{ }

	enable_shared_from_this(const enable_shared_from_this&)
	{ }

	enable_shared_from_this&
	operator=(const enable_shared_from_this&)
	{ return *this; }

	~enable_shared_from_this()
	{ }

	public:

	shared_ptr<_Tp>
	shared_from_this()
	{
	shared_ptr<_Tp> p(this->_M_weak_this);
	return p;
	}

	shared_ptr<const _Tp>
	shared_from_this() const
	{
	shared_ptr<const _Tp> p(this->_M_weak_this);
	return p;
	}

	private:
	template <typename _Tp1>
	void
	_M_weak_assign(_Tp1* __p, const shared_count& __n) const
	{ _M_weak_this._M_assign(__p, __n); }

	template <typename _Tp1>
	friend void
	__enable_shared_from_this( const shared_count& __pn, const enable_shared_from_this* __pe, const _Tp1* __px)
	{
	if(__pe != 0)
	__pe->_M_weak_assign(const_cast<_Tp1*>(__px), __pn);
	}

	mutable weak_ptr<_Tp> _M_weak_this;
	};

	} // namespace tr1

	/**
	* @brief std::swap() specialisation for shared_ptr.
	* @relates shared_ptr.
	*/
	template <typename _Tp>
	inline void
	swap(tr1::shared_ptr<_Tp>& __a, tr1::shared_ptr<_Tp>& __b)
	{
	__a.swap(__b);
	}

	/**
	* @brief std::swap() specialisation for weak_ptr.
	* @relates weak_ptr.
	*/
	template <typename _Tp>
	void
	swap(tr1::weak_ptr<_Tp>& __a, tr1::weak_ptr<_Tp>& __b)
	{
	__a.swap(__b);
	}

	} // namespace std

	#endif