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Release 1.41.0

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[SVN r57747]
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Beman Dawes
2009-11-18 14:58:26 +00:00
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<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.01 Transitional//EN">
<html>
<head>
<title>Smart Pointer Changes</title>
<meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1">
</head>
<body bgcolor="#ffffff" text="#000000">
<h1><A href="../../index.htm"><img src="../../boost.png" alt="boost.png (6897 bytes)" align="middle" width="277" height="86"
border="0"></A>Smart Pointer Changes</h1>
<p>The February 2002 change to the Boost smart pointers introduced a number of
changes. Since the previous version of the smart pointers was in use for a long
time, it's useful to have a detailed list of what changed from a library user's
point of view.</p>
<p>Note that for compilers that don't support member templates well enough, a
separate implementation is used that lacks many of the new features and is more
like the old version.</p>
<h2>Features Requiring Code Changes to Take Advantage</h2>
<ul>
<li>
The smart pointer class templates now each have their own header file. For
compatibility, the <a href="../../boost/smart_ptr.hpp">&lt;boost/smart_ptr.hpp&gt;</a>
header now includes the headers for the four classic smart pointer class
templates.
<li>
The <b>weak_ptr</b>
template was added.
<li>
The new <b>shared_ptr</b> and <b>shared_array</b> relax the requirement that
the pointed-to object's destructor must be visible when instantiating the <b>shared_ptr</b>
destructor. This makes it easier to have shared_ptr members in classes without
explicit destructors.
<li>
A custom deallocator can be passed in when creating a <b>shared_ptr</b> or <b>shared_array</b>.
<li>
<b>shared_static_cast</b> and <b>shared_dynamic_cast</b> function templates are
provided which work for <b>shared_ptr</b> and <b>weak_ptr</b> as <b>static_cast</b>
and <b>dynamic_cast</b>
do for pointers.
<li>
The self-assignment misfeature has been removed from <b>shared_ptr::reset</b>,
although it is still present in <b>scoped_ptr</b>, and in <b>std::auto_ptr</b>.
Calling <b>reset</b> with a pointer to the object that's already owned by the <b>shared_ptr</b>
results in undefined behavior (an assertion, or eventually a double-delete if
assertions are off).
<li>
The <b>BOOST_SMART_PTR_CONVERSION</b>
feature has been removed.
<li>
<b>shared_ptr&lt;void&gt;</b> is now allowed.</li>
</ul>
<h2>Features That Improve Robustness</h2>
<ul>
<li>
The manipulation of use counts is now <a name="threadsafe">thread safe</a> on
Windows, Linux, and platforms that support pthreads. See the <a href="../../boost/detail/atomic_count.hpp">
&lt;boost/detail/atomic_count.hpp&gt;</a>
file for details
<li>
The new shared_ptr will always delete the object using the pointer it was
originally constructed with. This prevents subtle problems that could happen if
the last <b>shared_ptr</b> was a pointer to a sub-object of a class that did
not have a virtual destructor.</li>
</ul>
<h2>Implementation Details</h2>
<ul>
<li>
Some bugs in the assignment operator implementations and in <b>reset</b>
have been fixed by using the "copy and swap" idiom.
<li>
Assertions have been added to check preconditions of various functions;
however, since these use the new <a href="../../boost/assert.hpp">&lt;boost/assert.hpp&gt;</a>
header, the assertions are disabled by default.
<li>
The partial specialization of <b>std::less</b> has been replaced by <b>operator&lt;</b>
overloads which accomplish the same thing without relying on undefined
behavior.
<li>
The incorrect overload of <b>std::swap</b> has been replaced by <b>boost::swap</b>,
which has many of the same advantages for generic programming but does not
violate the C++ standard.</li>
</ul>
<hr>
<p>Revised 1 February 2002</p>
<p><small>Copyright 2002 Darin Adler. Distributed under the Boost Software License, Version
1.0. See accompanying file <A href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</A> or
copy at <A href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</A>.</small></p>
</body>
</html>

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<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Transitional//EN">
<html>
<head>
<title>Boost: enable_shared_from_this.hpp documentation</title>
<meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1">
</head>
<body bgcolor="white" style="MARGIN-LEFT: 5%; MARGIN-RIGHT: 5%">
<table border="0" width="100%">
<tr>
<td width="277"><A href="../../index.htm"> <img src="../../boost.png" alt="boost.png (6897 bytes)" width="277" height="86" border="0"></A>
</td>
<td align="center">
<h1>enable_shared_from_this.hpp</h1>
</td>
</tr>
<tr>
<td colspan="2" height="64">&nbsp;</td>
</tr>
</table>
<h3><a name="Purpose">Purpose</a></h3>
<p>
The header <STRONG>&lt;boost/enable_shared_from_this.hpp&gt;</STRONG> defines
the class template <STRONG>enable_shared_from_this</STRONG>. It is used as a
base class that allows a <A href="shared_ptr.htm">shared_ptr</A> to the current
object to be obtained from within a member function.
</p>
<P><STRONG>enable_shared_from_this&lt;T&gt;</STRONG> defines two member functions
called <STRONG>shared_from_this</STRONG> that return a <STRONG>shared_ptr&lt;T&gt;</STRONG>
and <STRONG>shared_ptr&lt;T const&gt;</STRONG>, depending on constness, to <STRONG>this</STRONG>.</P>
<h3><a name="Example">Example</a></h3>
<pre>
class Y: public enable_shared_from_this&lt;Y&gt;
{
public:
shared_ptr&lt;Y&gt; f()
{
return shared_from_this();
}
}
int main()
{
shared_ptr&lt;Y&gt; p(new Y);
shared_ptr&lt;Y&gt; q = p-&gt;f();
assert(p == q);
assert(!(p &lt; q || q &lt; p)); // p and q must share ownership
}
</pre>
<h3><a name="Synopsis">Synopsis</a></h3>
<pre>
namespace boost
{
template&lt;class T&gt; class enable_shared_from_this
{
public:
shared_ptr&lt;T&gt; shared_from_this();
shared_ptr&lt;T const&gt; shared_from_this() const;
}
}
</pre>
<h4>template&lt;class T&gt; shared_ptr&lt;T&gt;
enable_shared_from_this&lt;T&gt;::shared_from_this();</h4>
<h4>template&lt;class T&gt; shared_ptr&lt;T const&gt;
enable_shared_from_this&lt;T&gt;::shared_from_this() const;</h4>
<blockquote>
<p>
<b>Requires:</b> <STRONG>enable_shared_from_this&lt;T&gt;</STRONG> must be an
accessible base class of <b>T</b>. <STRONG>*this</STRONG> must be a subobject
of an instance <STRONG>t</STRONG> of type <STRONG>T</STRONG> . There must exist
at least one <STRONG>shared_ptr</STRONG> instance <STRONG>p</STRONG> that <EM>owns</EM>
<STRONG>t</STRONG>.
</p>
<p>
<b>Returns:</b> A <b>shared_ptr&lt;T&gt;</b> instance <b>r</b> that shares
ownership with <b>p</b>.
</p>
<p>
<b>Postconditions:</b> <tt>r.get() == this</tt>.
</p>
</blockquote>
<p>
<br>
<small>Copyright <20> 2002, 2003 by Peter Dimov. Distributed under the Boost Software License, Version
1.0. See accompanying file <A href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</A> or
copy at <A href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</A>.</small></p>
</body>
</html>

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// Boost scoped_ptr_example implementation file -----------------------------//
// Copyright Beman Dawes 2001. 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)
// See http://www.boost.org/libs/smart_ptr for documentation.
#include "scoped_ptr_example.hpp"
#include <iostream>
class example::implementation
{
public:
~implementation() { std::cout << "destroying implementation\n"; }
};
example::example() : _imp( new implementation ) {}
void example::do_something() { std::cout << "did something\n"; }
example::~example() {}

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// Boost scoped_ptr_example header file ------------------------------------//
// Copyright Beman Dawes 2001. 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)
// See http://www.boost.org/libs/smart_ptr for documentation.
#include <boost/utility.hpp>
#include <boost/scoped_ptr.hpp>
// The point of this example is to prove that even though
// example::implementation is an incomplete type in translation units using
// this header, scoped_ptr< implementation > is still valid because the type
// is complete where it counts - in the inplementation translation unit where
// destruction is actually instantiated.
class example : private boost::noncopyable
{
public:
example();
~example();
void do_something();
private:
class implementation;
boost::scoped_ptr< implementation > _imp; // hide implementation details
};

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// Boost scoped_ptr_example_test main program -------------------------------//
// Copyright Beman Dawes 2001. 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)
// See http://www.boost.org/libs/smart_ptr for documentation.
#include "scoped_ptr_example.hpp"
int main()
{
example my_example;
my_example.do_something();
return 0;
}

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// Boost shared_ptr_example.cpp --------------------------------------------//
// Copyright Beman Dawes 2001. 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)
// See http://www.boost.org/libs/smart_ptr for documentation.
// Revision History
// 21 May 01 Initial complete version (Beman Dawes)
// The original code for this example appeared in the shared_ptr documentation.
// Ray Gallimore pointed out that foo_set was missing a Compare template
// argument, so would not work as intended. At that point the code was
// turned into an actual .cpp file so it could be compiled and tested.
#include <vector>
#include <set>
#include <iostream>
#include <algorithm>
#include <boost/shared_ptr.hpp>
// The application will produce a series of
// objects of type Foo which later must be
// accessed both by occurrence (std::vector)
// and by ordering relationship (std::set).
struct Foo
{
Foo( int _x ) : x(_x) {}
~Foo() { std::cout << "Destructing a Foo with x=" << x << "\n"; }
int x;
/* ... */
};
typedef boost::shared_ptr<Foo> FooPtr;
struct FooPtrOps
{
bool operator()( const FooPtr & a, const FooPtr & b )
{ return a->x > b->x; }
void operator()( const FooPtr & a )
{ std::cout << a->x << "\n"; }
};
int main()
{
std::vector<FooPtr> foo_vector;
std::set<FooPtr,FooPtrOps> foo_set; // NOT multiset!
FooPtr foo_ptr( new Foo( 2 ) );
foo_vector.push_back( foo_ptr );
foo_set.insert( foo_ptr );
foo_ptr.reset( new Foo( 1 ) );
foo_vector.push_back( foo_ptr );
foo_set.insert( foo_ptr );
foo_ptr.reset( new Foo( 3 ) );
foo_vector.push_back( foo_ptr );
foo_set.insert( foo_ptr );
foo_ptr.reset ( new Foo( 2 ) );
foo_vector.push_back( foo_ptr );
foo_set.insert( foo_ptr );
std::cout << "foo_vector:\n";
std::for_each( foo_vector.begin(), foo_vector.end(), FooPtrOps() );
std::cout << "\nfoo_set:\n";
std::for_each( foo_set.begin(), foo_set.end(), FooPtrOps() );
std::cout << "\n";
// Expected output:
//
// foo_vector:
// 2
// 1
// 3
// 2
//
// foo_set:
// 3
// 2
// 1
//
// Destructing a Foo with x=2
// Destructing a Foo with x=1
// Destructing a Foo with x=3
// Destructing a Foo with x=2
return 0;
}

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// Boost shared_ptr_example2 implementation file -----------------------------//
// Copyright Beman Dawes 2001. 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)
// See http://www.boost.org/libs/smart_ptr for documentation.
#include "shared_ptr_example2.hpp"
#include <iostream>
class example::implementation
{
public:
~implementation() { std::cout << "destroying implementation\n"; }
};
example::example() : _imp( new implementation ) {}
void example::do_something()
{ std::cout << "use_count() is " << _imp.use_count() << "\n"; }

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// Boost shared_ptr_example2 header file -----------------------------------//
// Copyright Beman Dawes 2001. 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)
// See http://www.boost.org/libs/smart_ptr for documentation.
#include <boost/shared_ptr.hpp>
// This example demonstrates the handle/body idiom (also called pimpl and
// several other names). It separates the interface (in this header file)
// from the implementation (in shared_ptr_example2.cpp).
// Note that even though example::implementation is an incomplete type in
// some translation units using this header, shared_ptr< implementation >
// is still valid because the type is complete where it counts - in the
// shared_ptr_example2.cpp translation unit where functions requiring a
// complete type are actually instantiated.
class example
{
public:
example();
void do_something();
private:
class implementation;
boost::shared_ptr< implementation > _imp; // hide implementation details
};

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// Boost shared_ptr_example2_test main program ------------------------------//
// Copyright Beman Dawes 2001. 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)
// See http://www.boost.org/libs/smart_ptr for documentation.
#include "shared_ptr_example2.hpp"
int main()
{
example a;
a.do_something();
example b(a);
b.do_something();
example c;
c = a;
c.do_something();
return 0;
}

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#ifndef BOOST_DETAIL_ATOMIC_COUNT_HPP_INCLUDED
#define BOOST_DETAIL_ATOMIC_COUNT_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/detail/atomic_count.hpp - thread/SMP safe reference counter
//
// Copyright (c) 2001, 2002 Peter Dimov and Multi Media Ltd.
//
// 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/smart_ptr/detail/atomic_count.hpp>
#endif // #ifndef BOOST_DETAIL_ATOMIC_COUNT_HPP_INCLUDED

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#ifndef BOOST_DETAIL_LIGHTWEIGHT_MUTEX_HPP_INCLUDED
#define BOOST_DETAIL_LIGHTWEIGHT_MUTEX_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/detail/lightweight_mutex.hpp - lightweight mutex
//
// Copyright (c) 2002, 2003 Peter Dimov and Multi Media Ltd.
//
// 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/smart_ptr/detail/lightweight_mutex.hpp>
#endif // #ifndef BOOST_DETAIL_LIGHTWEIGHT_MUTEX_HPP_INCLUDED

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#ifndef BOOST_DETAIL_SP_TYPEINFO_HPP_INCLUDED
#define BOOST_DETAIL_SP_TYPEINFO_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
// detail/sp_typeinfo.hpp
//
// Copyright 2007 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/config.hpp>
#if defined( BOOST_NO_TYPEID )
namespace boost
{
namespace detail
{
typedef void* sp_typeinfo;
template<class T> struct sp_typeid_
{
static char v_;
};
template<class T> char sp_typeid_< T >::v_;
template<class T> struct sp_typeid_< T const >: sp_typeid_< T >
{
};
template<class T> struct sp_typeid_< T volatile >: sp_typeid_< T >
{
};
template<class T> struct sp_typeid_< T const volatile >: sp_typeid_< T >
{
};
} // namespace detail
} // namespace boost
#define BOOST_SP_TYPEID(T) (&boost::detail::sp_typeid_<T>::v_)
#else
#include <typeinfo>
namespace boost
{
namespace detail
{
#if defined( BOOST_NO_STD_TYPEINFO )
typedef ::type_info sp_typeinfo;
#else
typedef std::type_info sp_typeinfo;
#endif
} // namespace detail
} // namespace boost
#define BOOST_SP_TYPEID(T) typeid(T)
#endif
#endif // #ifndef BOOST_DETAIL_SP_TYPEINFO_HPP_INCLUDED

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#ifndef BOOST_ENABLE_SHARED_FROM_THIS_HPP_INCLUDED
#define BOOST_ENABLE_SHARED_FROM_THIS_HPP_INCLUDED
//
// 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
//
// http://www.boost.org/libs/smart_ptr/enable_shared_from_this.html
//
#include <boost/smart_ptr/enable_shared_from_this.hpp>
#endif // #ifndef BOOST_ENABLE_SHARED_FROM_THIS_HPP_INCLUDED

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// Copyright Peter Dimov and David Abrahams 2002.
// 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)
#ifndef GET_POINTER_DWA20021219_HPP
# define GET_POINTER_DWA20021219_HPP
// In order to avoid circular dependencies with Boost.TR1
// we make sure that our include of <memory> doesn't try to
// pull in the TR1 headers: that's why we use this header
// rather than including <memory> directly:
# include <boost/config/no_tr1/memory.hpp> // std::auto_ptr
namespace boost {
// get_pointer(p) extracts a ->* capable pointer from p
template<class T> T * get_pointer(T * p)
{
return p;
}
// get_pointer(shared_ptr<T> const & p) has been moved to shared_ptr.hpp
template<class T> T * get_pointer(std::auto_ptr<T> const& p)
{
return p.get();
}
} // namespace boost
#endif // GET_POINTER_DWA20021219_HPP

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#ifndef BOOST_INTRUSIVE_PTR_HPP_INCLUDED
#define BOOST_INTRUSIVE_PTR_HPP_INCLUDED
//
// intrusive_ptr.hpp
//
// Copyright (c) 2001, 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
//
// See http://www.boost.org/libs/smart_ptr/intrusive_ptr.html for documentation.
//
#include <boost/smart_ptr/intrusive_ptr.hpp>
#endif // #ifndef BOOST_INTRUSIVE_PTR_HPP_INCLUDED

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#ifndef BOOST_MAKE_SHARED_HPP_INCLUDED
#define BOOST_MAKE_SHARED_HPP_INCLUDED
// make_shared.hpp
//
// Copyright (c) 2007, 2008 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
//
// See http://www.boost.org/libs/smart_ptr/make_shared.html
// for documentation.
#include <boost/smart_ptr/make_shared.hpp>
#endif // #ifndef BOOST_MAKE_SHARED_HPP_INCLUDED

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#ifndef BOOST_MEMORY_ORDER_HPP_INCLUDED
#define BOOST_MEMORY_ORDER_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
// boost/memory_order.hpp
//
// Defines enum boost::memory_order per the C++0x working draft
//
// Copyright (c) 2008 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)
namespace boost
{
enum memory_order
{
memory_order_relaxed = 0,
memory_order_acquire = 1,
memory_order_release = 2,
memory_order_acq_rel = 3, // acquire | release
memory_order_seq_cst = 7 // acq_rel | 4
};
} // namespace boost
#endif // #ifndef BOOST_MEMORY_ORDER_HPP_INCLUDED

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//////////////////////////////////////////////////////////////////////////////
//
// (C) Copyright Ion Gaztanaga 2005.
// 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)
//
//////////////////////////////////////////////////////////////////////////////
#ifndef BOOST_POINTER_CAST_HPP
#define BOOST_POINTER_CAST_HPP
namespace boost {
//static_pointer_cast overload for raw pointers
template<class T, class U>
inline T* static_pointer_cast(U *ptr)
{
return static_cast<T*>(ptr);
}
//dynamic_pointer_cast overload for raw pointers
template<class T, class U>
inline T* dynamic_pointer_cast(U *ptr)
{
return dynamic_cast<T*>(ptr);
}
//const_pointer_cast overload for raw pointers
template<class T, class U>
inline T* const_pointer_cast(U *ptr)
{
return const_cast<T*>(ptr);
}
//reinterpret_pointer_cast overload for raw pointers
template<class T, class U>
inline T* reinterpret_pointer_cast(U *ptr)
{
return reinterpret_cast<T*>(ptr);
}
} // namespace boost
#endif //BOOST_POINTER_CAST_HPP

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#ifndef BOOST_POINTER_TO_OTHER_HPP_INCLUDED
#define BOOST_POINTER_TO_OTHER_HPP_INCLUDED
//
// pointer_to_other.hpp
//
// (C) Copyright Ion Gaztanaga 2005.
// Copyright (c) 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)
//
// See http://www.boost.org/libs/smart_ptr/pointer_to_other.html
//
namespace boost
{
// Defines the same pointer type (raw or smart) to another pointee type
template<class T, class U>
struct pointer_to_other;
template<class T, class U,
template<class> class Sp>
struct pointer_to_other< Sp<T>, U >
{
typedef Sp<U> type;
};
template<class T, class T2, class U,
template<class, class> class Sp>
struct pointer_to_other< Sp<T, T2>, U >
{
typedef Sp<U, T2> type;
};
template<class T, class T2, class T3, class U,
template<class, class, class> class Sp>
struct pointer_to_other< Sp<T, T2, T3>, U >
{
typedef Sp<U, T2, T3> type;
};
template<class T, class U>
struct pointer_to_other< T*, U >
{
typedef U* type;
};
} // namespace boost
#endif // #ifndef BOOST_POINTER_TO_OTHER_HPP_INCLUDED

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#ifndef BOOST_SCOPED_ARRAY_HPP_INCLUDED
#define BOOST_SCOPED_ARRAY_HPP_INCLUDED
// (C) Copyright Greg Colvin and Beman Dawes 1998, 1999.
// Copyright (c) 2001, 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)
//
// http://www.boost.org/libs/smart_ptr/scoped_array.htm
//
#include <boost/smart_ptr/scoped_array.hpp>
#endif // #ifndef BOOST_SCOPED_ARRAY_HPP_INCLUDED

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#ifndef BOOST_SCOPED_PTR_HPP_INCLUDED
#define BOOST_SCOPED_PTR_HPP_INCLUDED
// (C) Copyright Greg Colvin and Beman Dawes 1998, 1999.
// Copyright (c) 2001, 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)
//
// http://www.boost.org/libs/smart_ptr/scoped_ptr.htm
//
#include <boost/smart_ptr/scoped_ptr.hpp>
#endif // #ifndef BOOST_SCOPED_PTR_HPP_INCLUDED

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#ifndef BOOST_SHARED_ARRAY_HPP_INCLUDED
#define BOOST_SHARED_ARRAY_HPP_INCLUDED
//
// shared_array.hpp
//
// (C) Copyright Greg Colvin and Beman Dawes 1998, 1999.
// Copyright (c) 2001, 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)
//
// See http://www.boost.org/libs/smart_ptr/shared_array.htm for documentation.
//
#include <boost/smart_ptr/shared_array.hpp>
#endif // #ifndef BOOST_SHARED_ARRAY_HPP_INCLUDED

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#ifndef BOOST_SHARED_PTR_HPP_INCLUDED
#define BOOST_SHARED_PTR_HPP_INCLUDED
//
// shared_ptr.hpp
//
// (C) Copyright Greg Colvin and Beman Dawes 1998, 1999.
// Copyright (c) 2001-2008 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)
//
// See http://www.boost.org/libs/smart_ptr/shared_ptr.htm for documentation.
//
#include <boost/smart_ptr/shared_ptr.hpp>
#endif // #ifndef BOOST_SHARED_PTR_HPP_INCLUDED

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//
// smart_ptr.hpp
//
// For convenience, this header includes the rest of the smart
// pointer library headers.
//
// Copyright (c) 2003 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)
//
// http://www.boost.org/libs/smart_ptr/smart_ptr.htm
//
#include <boost/config.hpp>
#include <boost/scoped_ptr.hpp>
#include <boost/scoped_array.hpp>
#include <boost/shared_ptr.hpp>
#include <boost/shared_array.hpp>
#if !defined(BOOST_NO_MEMBER_TEMPLATES) || defined(BOOST_MSVC6_MEMBER_TEMPLATES)
# include <boost/weak_ptr.hpp>
# include <boost/intrusive_ptr.hpp>
# include <boost/enable_shared_from_this.hpp>
#endif

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#ifndef BOOST_SMART_PTR_BAD_WEAK_PTR_HPP_INCLUDED
#define BOOST_SMART_PTR_BAD_WEAK_PTR_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/smart_ptr/bad_weak_ptr.hpp
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
//
// 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 <exception>
#ifdef __BORLANDC__
# pragma warn -8026 // Functions with excep. spec. are not expanded inline
#endif
namespace boost
{
// The standard library that comes with Borland C++ 5.5.1, 5.6.4
// defines std::exception and its members as having C calling
// convention (-pc). When the definition of bad_weak_ptr
// is compiled with -ps, the compiler issues an error.
// Hence, the temporary #pragma option -pc below.
#if defined(__BORLANDC__) && __BORLANDC__ <= 0x564
# pragma option push -pc
#endif
class bad_weak_ptr: public std::exception
{
public:
virtual char const * what() const throw()
{
return "tr1::bad_weak_ptr";
}
};
#if defined(__BORLANDC__) && __BORLANDC__ <= 0x564
# pragma option pop
#endif
} // namespace boost
#ifdef __BORLANDC__
# pragma warn .8026 // Functions with excep. spec. are not expanded inline
#endif
#endif // #ifndef BOOST_SMART_PTR_BAD_WEAK_PTR_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/detail/atomic_count.hpp - thread/SMP safe reference counter
//
// Copyright (c) 2001, 2002 Peter Dimov and Multi Media Ltd.
//
// 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)
//
// typedef <implementation-defined> boost::detail::atomic_count;
//
// atomic_count a(n);
//
// (n is convertible to long)
//
// Effects: Constructs an atomic_count with an initial value of n
//
// a;
//
// Returns: (long) the current value of a
//
// ++a;
//
// Effects: Atomically increments the value of a
// Returns: (long) the new value of a
//
// --a;
//
// Effects: Atomically decrements the value of a
// Returns: (long) the new value of a
//
// Important note: when --a returns zero, it must act as a
// read memory barrier (RMB); i.e. the calling thread must
// have a synchronized view of the memory
//
// On Intel IA-32 (x86) memory is always synchronized, so this
// is not a problem.
//
// On many architectures the atomic instructions already act as
// a memory barrier.
//
// This property is necessary for proper reference counting, since
// a thread can update the contents of a shared object, then
// release its reference, and another thread may immediately
// release the last reference causing object destruction.
//
// The destructor needs to have a synchronized view of the
// object to perform proper cleanup.
//
// Original example by Alexander Terekhov:
//
// Given:
//
// - a mutable shared object OBJ;
// - two threads THREAD1 and THREAD2 each holding
// a private smart_ptr object pointing to that OBJ.
//
// t1: THREAD1 updates OBJ (thread-safe via some synchronization)
// and a few cycles later (after "unlock") destroys smart_ptr;
//
// t2: THREAD2 destroys smart_ptr WITHOUT doing any synchronization
// with respect to shared mutable object OBJ; OBJ destructors
// are called driven by smart_ptr interface...
//
#include <boost/config.hpp>
#include <boost/smart_ptr/detail/sp_has_sync.hpp>
#ifndef BOOST_HAS_THREADS
namespace boost
{
namespace detail
{
typedef long atomic_count;
}
}
#elif defined(BOOST_AC_USE_PTHREADS)
# include <boost/smart_ptr/detail/atomic_count_pthreads.hpp>
#elif defined( __GNUC__ ) && ( defined( __i386__ ) || defined( __x86_64__ ) )
# include <boost/smart_ptr/detail/atomic_count_gcc_x86.hpp>
#elif defined(WIN32) || defined(_WIN32) || defined(__WIN32__) || defined(__CYGWIN__)
# include <boost/smart_ptr/detail/atomic_count_win32.hpp>
#elif defined( BOOST_SP_HAS_SYNC )
# include <boost/smart_ptr/detail/atomic_count_sync.hpp>
#elif defined(__GLIBCPP__) || defined(__GLIBCXX__)
# include <boost/smart_ptr/detail/atomic_count_gcc.hpp>
#elif defined(BOOST_HAS_PTHREADS)
# define BOOST_AC_USE_PTHREADS
# include <boost/smart_ptr/detail/atomic_count_pthreads.hpp>
#else
// Use #define BOOST_DISABLE_THREADS to avoid the error
#error Unrecognized threading platform
#endif
#endif // #ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_GCC_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_GCC_HPP_INCLUDED
//
// boost/detail/atomic_count_gcc.hpp
//
// atomic_count for GNU libstdc++ v3
//
// http://gcc.gnu.org/onlinedocs/porting/Thread-safety.html
//
// Copyright (c) 2001, 2002 Peter Dimov and Multi Media Ltd.
// Copyright (c) 2002 Lars Gullik Bj<42>nnes <larsbj@lyx.org>
// Copyright 2003-2005 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)
//
#if __GNUC__ * 100 + __GNUC_MINOR__ >= 402
# include <ext/atomicity.h>
#else
# include <bits/atomicity.h>
#endif
namespace boost
{
namespace detail
{
#if defined(__GLIBCXX__) // g++ 3.4+
using __gnu_cxx::__atomic_add;
using __gnu_cxx::__exchange_and_add;
#endif
class atomic_count
{
public:
explicit atomic_count( long v ) : value_( v ) {}
long operator++()
{
return __exchange_and_add( &value_, +1 ) + 1;
}
long operator--()
{
return __exchange_and_add( &value_, -1 ) - 1;
}
operator long() const
{
return __exchange_and_add( &value_, 0 );
}
private:
atomic_count(atomic_count const &);
atomic_count & operator=(atomic_count const &);
mutable _Atomic_word value_;
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_GCC_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_GCC_X86_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_GCC_X86_HPP_INCLUDED
//
// boost/detail/atomic_count_gcc_x86.hpp
//
// atomic_count for g++ on 486+/AMD64
//
// Copyright 2007 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)
//
namespace boost
{
namespace detail
{
class atomic_count
{
public:
explicit atomic_count( long v ) : value_( static_cast< int >( v ) ) {}
long operator++()
{
return atomic_exchange_and_add( &value_, +1 ) + 1;
}
long operator--()
{
return atomic_exchange_and_add( &value_, -1 ) - 1;
}
operator long() const
{
return atomic_exchange_and_add( &value_, 0 );
}
private:
atomic_count(atomic_count const &);
atomic_count & operator=(atomic_count const &);
mutable int value_;
private:
static int atomic_exchange_and_add( int * pw, int dv )
{
// int r = *pw;
// *pw += dv;
// return r;
int r;
__asm__ __volatile__
(
"lock\n\t"
"xadd %1, %0":
"+m"( *pw ), "=r"( r ): // outputs (%0, %1)
"1"( dv ): // inputs (%2 == %1)
"memory", "cc" // clobbers
);
return r;
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_GCC_X86_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_PTHREADS_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_PTHREADS_HPP_INCLUDED
//
// boost/detail/atomic_count_pthreads.hpp
//
// Copyright (c) 2001, 2002 Peter Dimov and Multi Media Ltd.
//
// 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 <pthread.h>
//
// The generic pthread_mutex-based implementation sometimes leads to
// inefficiencies. Example: a class with two atomic_count members
// can get away with a single mutex.
//
// Users can detect this situation by checking BOOST_AC_USE_PTHREADS.
//
namespace boost
{
namespace detail
{
class atomic_count
{
private:
class scoped_lock
{
public:
scoped_lock(pthread_mutex_t & m): m_(m)
{
pthread_mutex_lock(&m_);
}
~scoped_lock()
{
pthread_mutex_unlock(&m_);
}
private:
pthread_mutex_t & m_;
};
public:
explicit atomic_count(long v): value_(v)
{
pthread_mutex_init(&mutex_, 0);
}
~atomic_count()
{
pthread_mutex_destroy(&mutex_);
}
long operator++()
{
scoped_lock lock(mutex_);
return ++value_;
}
long operator--()
{
scoped_lock lock(mutex_);
return --value_;
}
operator long() const
{
scoped_lock lock(mutex_);
return value_;
}
private:
atomic_count(atomic_count const &);
atomic_count & operator=(atomic_count const &);
mutable pthread_mutex_t mutex_;
long value_;
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_PTHREADS_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_SOLARIS_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_SOLARIS_HPP_INCLUDED
//
// boost/detail/atomic_count_solaris.hpp
// based on: boost/detail/atomic_count_win32.hpp
//
// Copyright (c) 2001-2005 Peter Dimov
// Copyright (c) 2006 Michael van der Westhuizen
//
// 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 <atomic.h>
namespace boost
{
namespace detail
{
class atomic_count
{
public:
explicit atomic_count( uint32_t v ): value_( v )
{
}
long operator++()
{
return atomic_inc_32_nv( &value_ );
}
long operator--()
{
return atomic_dec_32_nv( &value_ );
}
operator uint32_t() const
{
return static_cast<uint32_t const volatile &>( value_ );
}
private:
atomic_count( atomic_count const & );
atomic_count & operator=( atomic_count const & );
uint32_t value_;
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_SOLARIS_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_SYNC_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_SYNC_HPP_INCLUDED
//
// boost/detail/atomic_count_sync.hpp
//
// atomic_count for g++ 4.1+
//
// http://gcc.gnu.org/onlinedocs/gcc-4.1.1/gcc/Atomic-Builtins.html
//
// Copyright 2007 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)
//
#if defined( __ia64__ ) && defined( __INTEL_COMPILER )
# include <ia64intrin.h>
#endif
namespace boost
{
namespace detail
{
class atomic_count
{
public:
explicit atomic_count( long v ) : value_( v ) {}
long operator++()
{
return __sync_add_and_fetch( &value_, 1 );
}
long operator--()
{
return __sync_add_and_fetch( &value_, -1 );
}
operator long() const
{
return __sync_fetch_and_add( &value_, 0 );
}
private:
atomic_count(atomic_count const &);
atomic_count & operator=(atomic_count const &);
mutable long value_;
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_SYNC_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_WIN32_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_WIN32_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/detail/atomic_count_win32.hpp
//
// Copyright (c) 2001-2005 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/interlocked.hpp>
namespace boost
{
namespace detail
{
class atomic_count
{
public:
explicit atomic_count( long v ): value_( v )
{
}
long operator++()
{
return BOOST_INTERLOCKED_INCREMENT( &value_ );
}
long operator--()
{
return BOOST_INTERLOCKED_DECREMENT( &value_ );
}
operator long() const
{
return static_cast<long const volatile &>( value_ );
}
private:
atomic_count( atomic_count const & );
atomic_count & operator=( atomic_count const & );
long value_;
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_ATOMIC_COUNT_WIN32_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_LIGHTWEIGHT_MUTEX_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_LIGHTWEIGHT_MUTEX_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/detail/lightweight_mutex.hpp - lightweight mutex
//
// Copyright (c) 2002, 2003 Peter Dimov and Multi Media Ltd.
//
// 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)
//
// typedef <unspecified> boost::detail::lightweight_mutex;
//
// boost::detail::lightweight_mutex is a header-only implementation of
// a subset of the Mutex concept requirements:
//
// http://www.boost.org/doc/html/threads/concepts.html#threads.concepts.Mutex
//
// It maps to a CRITICAL_SECTION on Windows or a pthread_mutex on POSIX.
//
#include <boost/config.hpp>
#if !defined(BOOST_HAS_THREADS)
# include <boost/smart_ptr/detail/lwm_nop.hpp>
#elif defined(BOOST_HAS_PTHREADS)
# include <boost/smart_ptr/detail/lwm_pthreads.hpp>
#elif defined(BOOST_HAS_WINTHREADS) || defined(WIN32) || defined(_WIN32) || defined(__WIN32__) || defined(__CYGWIN__)
# include <boost/smart_ptr/detail/lwm_win32_cs.hpp>
#else
// Use #define BOOST_DISABLE_THREADS to avoid the error
# error Unrecognized threading platform
#endif
#endif // #ifndef BOOST_SMART_PTR_DETAIL_LIGHTWEIGHT_MUTEX_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_LWM_NOP_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_LWM_NOP_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/detail/lwm_nop.hpp
//
// Copyright (c) 2002 Peter Dimov and Multi Media Ltd.
//
// 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)
//
namespace boost
{
namespace detail
{
class lightweight_mutex
{
public:
typedef lightweight_mutex scoped_lock;
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_LWM_NOP_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_LWM_PTHREADS_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_LWM_PTHREADS_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/detail/lwm_pthreads.hpp
//
// Copyright (c) 2002 Peter Dimov and Multi Media Ltd.
//
// 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 <pthread.h>
namespace boost
{
namespace detail
{
class lightweight_mutex
{
private:
pthread_mutex_t m_;
lightweight_mutex(lightweight_mutex const &);
lightweight_mutex & operator=(lightweight_mutex const &);
public:
lightweight_mutex()
{
// HPUX 10.20 / DCE has a nonstandard pthread_mutex_init
#if defined(__hpux) && defined(_DECTHREADS_)
pthread_mutex_init(&m_, pthread_mutexattr_default);
#else
pthread_mutex_init(&m_, 0);
#endif
}
~lightweight_mutex()
{
pthread_mutex_destroy(&m_);
}
class scoped_lock;
friend class scoped_lock;
class scoped_lock
{
private:
pthread_mutex_t & m_;
scoped_lock(scoped_lock const &);
scoped_lock & operator=(scoped_lock const &);
public:
scoped_lock(lightweight_mutex & m): m_(m.m_)
{
pthread_mutex_lock(&m_);
}
~scoped_lock()
{
pthread_mutex_unlock(&m_);
}
};
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_LWM_PTHREADS_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_LWM_WIN32_CS_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_LWM_WIN32_CS_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/detail/lwm_win32_cs.hpp
//
// Copyright (c) 2002, 2003 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)
//
#ifdef BOOST_USE_WINDOWS_H
# include <windows.h>
#endif
namespace boost
{
namespace detail
{
#ifndef BOOST_USE_WINDOWS_H
struct critical_section
{
struct critical_section_debug * DebugInfo;
long LockCount;
long RecursionCount;
void * OwningThread;
void * LockSemaphore;
#if defined(_WIN64)
unsigned __int64 SpinCount;
#else
unsigned long SpinCount;
#endif
};
extern "C" __declspec(dllimport) void __stdcall InitializeCriticalSection(critical_section *);
extern "C" __declspec(dllimport) void __stdcall EnterCriticalSection(critical_section *);
extern "C" __declspec(dllimport) void __stdcall LeaveCriticalSection(critical_section *);
extern "C" __declspec(dllimport) void __stdcall DeleteCriticalSection(critical_section *);
#else
typedef ::CRITICAL_SECTION critical_section;
#endif // #ifndef BOOST_USE_WINDOWS_H
class lightweight_mutex
{
private:
critical_section cs_;
lightweight_mutex(lightweight_mutex const &);
lightweight_mutex & operator=(lightweight_mutex const &);
public:
lightweight_mutex()
{
InitializeCriticalSection(&cs_);
}
~lightweight_mutex()
{
DeleteCriticalSection(&cs_);
}
class scoped_lock;
friend class scoped_lock;
class scoped_lock
{
private:
lightweight_mutex & m_;
scoped_lock(scoped_lock const &);
scoped_lock & operator=(scoped_lock const &);
public:
explicit scoped_lock(lightweight_mutex & m): m_(m)
{
EnterCriticalSection(&m_.cs_);
}
~scoped_lock()
{
LeaveCriticalSection(&m_.cs_);
}
};
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_LWM_WIN32_CS_HPP_INCLUDED

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// This header intentionally has no include guards.
//
// Copyright (c) 2001-2009 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
#if ( defined(__SUNPRO_CC) && BOOST_WORKAROUND(__SUNPRO_CC, < 0x570) ) || defined(__CINT__)
operator bool () const
{
return px != 0;
}
#elif defined( _MANAGED )
static void unspecified_bool( this_type*** )
{
}
typedef void (*unspecified_bool_type)( this_type*** );
operator unspecified_bool_type() const // never throws
{
return px == 0? 0: unspecified_bool;
}
#elif \
( defined(__MWERKS__) && BOOST_WORKAROUND(__MWERKS__, < 0x3200) ) || \
( defined(__GNUC__) && (__GNUC__ * 100 + __GNUC_MINOR__ < 304) ) || \
( defined(__SUNPRO_CC) && BOOST_WORKAROUND(__SUNPRO_CC, <= 0x590) )
typedef T * (this_type::*unspecified_bool_type)() const;
operator unspecified_bool_type() const // never throws
{
return px == 0? 0: &this_type::get;
}
#else
typedef T * this_type::*unspecified_bool_type;
operator unspecified_bool_type() const // never throws
{
return px == 0? 0: &this_type::px;
}
#endif
// operator! is redundant, but some compilers need it
bool operator! () const // never throws
{
return px == 0;
}

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#ifndef BOOST_SMART_PTR_DETAIL_QUICK_ALLOCATOR_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_QUICK_ALLOCATOR_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/quick_allocator.hpp
//
// Copyright (c) 2003 David Abrahams
// Copyright (c) 2003 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/config.hpp>
#include <boost/smart_ptr/detail/lightweight_mutex.hpp>
#include <boost/type_traits/type_with_alignment.hpp>
#include <boost/type_traits/alignment_of.hpp>
#include <new> // ::operator new, ::operator delete
#include <cstddef> // std::size_t
namespace boost
{
namespace detail
{
template<unsigned size, unsigned align_> union freeblock
{
typedef typename boost::type_with_alignment<align_>::type aligner_type;
aligner_type aligner;
char bytes[size];
freeblock * next;
};
template<unsigned size, unsigned align_> struct allocator_impl
{
typedef freeblock<size, align_> block;
// It may seem odd to use such small pages.
//
// However, on a typical Windows implementation that uses
// the OS allocator, "normal size" pages interact with the
// "ordinary" operator new, slowing it down dramatically.
//
// 512 byte pages are handled by the small object allocator,
// and don't interfere with ::new.
//
// The other alternative is to use much bigger pages (1M.)
//
// It is surprisingly easy to hit pathological behavior by
// varying the page size. g++ 2.96 on Red Hat Linux 7.2,
// for example, passionately dislikes 496. 512 seems OK.
#if defined(BOOST_QA_PAGE_SIZE)
enum { items_per_page = BOOST_QA_PAGE_SIZE / size };
#else
enum { items_per_page = 512 / size }; // 1048560 / size
#endif
#ifdef BOOST_HAS_THREADS
static lightweight_mutex & mutex()
{
static lightweight_mutex m;
return m;
}
static lightweight_mutex * mutex_init;
#endif
static block * free;
static block * page;
static unsigned last;
static inline void * alloc()
{
#ifdef BOOST_HAS_THREADS
lightweight_mutex::scoped_lock lock( mutex() );
#endif
if(block * x = free)
{
free = x->next;
return x;
}
else
{
if(last == items_per_page)
{
// "Listen to me carefully: there is no memory leak"
// -- Scott Meyers, Eff C++ 2nd Ed Item 10
page = ::new block[items_per_page];
last = 0;
}
return &page[last++];
}
}
static inline void * alloc(std::size_t n)
{
if(n != size) // class-specific new called for a derived object
{
return ::operator new(n);
}
else
{
#ifdef BOOST_HAS_THREADS
lightweight_mutex::scoped_lock lock( mutex() );
#endif
if(block * x = free)
{
free = x->next;
return x;
}
else
{
if(last == items_per_page)
{
page = ::new block[items_per_page];
last = 0;
}
return &page[last++];
}
}
}
static inline void dealloc(void * pv)
{
if(pv != 0) // 18.4.1.1/13
{
#ifdef BOOST_HAS_THREADS
lightweight_mutex::scoped_lock lock( mutex() );
#endif
block * pb = static_cast<block *>(pv);
pb->next = free;
free = pb;
}
}
static inline void dealloc(void * pv, std::size_t n)
{
if(n != size) // class-specific delete called for a derived object
{
::operator delete(pv);
}
else if(pv != 0) // 18.4.1.1/13
{
#ifdef BOOST_HAS_THREADS
lightweight_mutex::scoped_lock lock( mutex() );
#endif
block * pb = static_cast<block *>(pv);
pb->next = free;
free = pb;
}
}
};
#ifdef BOOST_HAS_THREADS
template<unsigned size, unsigned align_>
lightweight_mutex * allocator_impl<size, align_>::mutex_init = &allocator_impl<size, align_>::mutex();
#endif
template<unsigned size, unsigned align_>
freeblock<size, align_> * allocator_impl<size, align_>::free = 0;
template<unsigned size, unsigned align_>
freeblock<size, align_> * allocator_impl<size, align_>::page = 0;
template<unsigned size, unsigned align_>
unsigned allocator_impl<size, align_>::last = allocator_impl<size, align_>::items_per_page;
template<class T>
struct quick_allocator: public allocator_impl< sizeof(T), boost::alignment_of<T>::value >
{
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_QUICK_ALLOCATOR_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SHARED_ARRAY_NMT_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SHARED_ARRAY_NMT_HPP_INCLUDED
//
// detail/shared_array_nmt.hpp - shared_array.hpp without member templates
//
// (C) Copyright Greg Colvin and Beman Dawes 1998, 1999.
// Copyright (c) 2001, 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)
//
// See http://www.boost.org/libs/smart_ptr/shared_array.htm for documentation.
//
#include <boost/assert.hpp>
#include <boost/checked_delete.hpp>
#include <boost/throw_exception.hpp>
#include <boost/smart_ptr/detail/atomic_count.hpp>
#include <cstddef> // for std::ptrdiff_t
#include <algorithm> // for std::swap
#include <functional> // for std::less
#include <new> // for std::bad_alloc
namespace boost
{
template<class T> class shared_array
{
private:
typedef detail::atomic_count count_type;
public:
typedef T element_type;
explicit shared_array(T * p = 0): px(p)
{
#ifndef BOOST_NO_EXCEPTIONS
try // prevent leak if new throws
{
pn = new count_type(1);
}
catch(...)
{
boost::checked_array_delete(p);
throw;
}
#else
pn = new count_type(1);
if(pn == 0)
{
boost::checked_array_delete(p);
boost::throw_exception(std::bad_alloc());
}
#endif
}
~shared_array()
{
if(--*pn == 0)
{
boost::checked_array_delete(px);
delete pn;
}
}
shared_array(shared_array const & r) : px(r.px) // never throws
{
pn = r.pn;
++*pn;
}
shared_array & operator=(shared_array const & r)
{
shared_array(r).swap(*this);
return *this;
}
void reset(T * p = 0)
{
BOOST_ASSERT(p == 0 || p != px);
shared_array(p).swap(*this);
}
T * get() const // never throws
{
return px;
}
T & operator[](std::ptrdiff_t i) const // never throws
{
BOOST_ASSERT(px != 0);
BOOST_ASSERT(i >= 0);
return px[i];
}
long use_count() const // never throws
{
return *pn;
}
bool unique() const // never throws
{
return *pn == 1;
}
void swap(shared_array<T> & other) // never throws
{
std::swap(px, other.px);
std::swap(pn, other.pn);
}
private:
T * px; // contained pointer
count_type * pn; // ptr to reference counter
}; // shared_array
template<class T, class U> inline bool operator==(shared_array<T> const & a, shared_array<U> const & b)
{
return a.get() == b.get();
}
template<class T, class U> inline bool operator!=(shared_array<T> const & a, shared_array<U> const & b)
{
return a.get() != b.get();
}
template<class T> inline bool operator<(shared_array<T> const & a, shared_array<T> const & b)
{
return std::less<T*>()(a.get(), b.get());
}
template<class T> void swap(shared_array<T> & a, shared_array<T> & b)
{
a.swap(b);
}
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SHARED_ARRAY_NMT_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SHARED_COUNT_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SHARED_COUNT_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/shared_count.hpp
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2005 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)
//
#ifdef __BORLANDC__
# pragma warn -8027 // Functions containing try are not expanded inline
#endif
#include <boost/config.hpp>
#include <boost/checked_delete.hpp>
#include <boost/throw_exception.hpp>
#include <boost/smart_ptr/bad_weak_ptr.hpp>
#include <boost/smart_ptr/detail/sp_counted_base.hpp>
#include <boost/smart_ptr/detail/sp_counted_impl.hpp>
#include <boost/detail/workaround.hpp>
// In order to avoid circular dependencies with Boost.TR1
// we make sure that our include of <memory> doesn't try to
// pull in the TR1 headers: that's why we use this header
// rather than including <memory> directly:
#include <boost/config/no_tr1/memory.hpp> // std::auto_ptr
#include <functional> // std::less
#include <new> // std::bad_alloc
namespace boost
{
namespace detail
{
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
int const shared_count_id = 0x2C35F101;
int const weak_count_id = 0x298C38A4;
#endif
struct sp_nothrow_tag {};
class weak_count;
class shared_count
{
private:
sp_counted_base * pi_;
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
int id_;
#endif
friend class weak_count;
public:
shared_count(): pi_(0) // nothrow
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(shared_count_id)
#endif
{
}
template<class Y> explicit shared_count( Y * p ): pi_( 0 )
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(shared_count_id)
#endif
{
#ifndef BOOST_NO_EXCEPTIONS
try
{
pi_ = new sp_counted_impl_p<Y>( p );
}
catch(...)
{
boost::checked_delete( p );
throw;
}
#else
pi_ = new sp_counted_impl_p<Y>( p );
if( pi_ == 0 )
{
boost::checked_delete( p );
boost::throw_exception( std::bad_alloc() );
}
#endif
}
#if defined( BOOST_MSVC ) && BOOST_WORKAROUND( BOOST_MSVC, <= 1200 )
template<class Y, class D> shared_count( Y * p, D d ): pi_(0)
#else
template<class P, class D> shared_count( P p, D d ): pi_(0)
#endif
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(shared_count_id)
#endif
{
#if defined( BOOST_MSVC ) && BOOST_WORKAROUND( BOOST_MSVC, <= 1200 )
typedef Y* P;
#endif
#ifndef BOOST_NO_EXCEPTIONS
try
{
pi_ = new sp_counted_impl_pd<P, D>(p, d);
}
catch(...)
{
d(p); // delete p
throw;
}
#else
pi_ = new sp_counted_impl_pd<P, D>(p, d);
if(pi_ == 0)
{
d(p); // delete p
boost::throw_exception(std::bad_alloc());
}
#endif
}
template<class P, class D, class A> shared_count( P p, D d, A a ): pi_( 0 )
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(shared_count_id)
#endif
{
typedef sp_counted_impl_pda<P, D, A> impl_type;
typedef typename A::template rebind< impl_type >::other A2;
A2 a2( a );
#ifndef BOOST_NO_EXCEPTIONS
try
{
pi_ = a2.allocate( 1, static_cast< impl_type* >( 0 ) );
new( static_cast< void* >( pi_ ) ) impl_type( p, d, a );
}
catch(...)
{
d( p );
if( pi_ != 0 )
{
a2.deallocate( static_cast< impl_type* >( pi_ ), 1 );
}
throw;
}
#else
pi_ = a2.allocate( 1, static_cast< impl_type* >( 0 ) );
if( pi_ != 0 )
{
new( static_cast< void* >( pi_ ) ) impl_type( p, d, a );
}
else
{
d( p );
boost::throw_exception( std::bad_alloc() );
}
#endif
}
#ifndef BOOST_NO_AUTO_PTR
// auto_ptr<Y> is special cased to provide the strong guarantee
template<class Y>
explicit shared_count( std::auto_ptr<Y> & r ): pi_( new sp_counted_impl_p<Y>( r.get() ) )
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(shared_count_id)
#endif
{
#ifdef BOOST_NO_EXCEPTIONS
if( pi_ == 0 )
{
boost::throw_exception(std::bad_alloc());
}
#endif
r.release();
}
#endif
~shared_count() // nothrow
{
if( pi_ != 0 ) pi_->release();
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
id_ = 0;
#endif
}
shared_count(shared_count const & r): pi_(r.pi_) // nothrow
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(shared_count_id)
#endif
{
if( pi_ != 0 ) pi_->add_ref_copy();
}
#if defined( BOOST_HAS_RVALUE_REFS )
shared_count(shared_count && r): pi_(r.pi_) // nothrow
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(shared_count_id)
#endif
{
r.pi_ = 0;
}
#endif
explicit shared_count(weak_count const & r); // throws bad_weak_ptr when r.use_count() == 0
shared_count( weak_count const & r, sp_nothrow_tag ); // constructs an empty *this when r.use_count() == 0
shared_count & operator= (shared_count const & r) // nothrow
{
sp_counted_base * tmp = r.pi_;
if( tmp != pi_ )
{
if( tmp != 0 ) tmp->add_ref_copy();
if( pi_ != 0 ) pi_->release();
pi_ = tmp;
}
return *this;
}
void swap(shared_count & r) // nothrow
{
sp_counted_base * tmp = r.pi_;
r.pi_ = pi_;
pi_ = tmp;
}
long use_count() const // nothrow
{
return pi_ != 0? pi_->use_count(): 0;
}
bool unique() const // nothrow
{
return use_count() == 1;
}
bool empty() const // nothrow
{
return pi_ == 0;
}
friend inline bool operator==(shared_count const & a, shared_count const & b)
{
return a.pi_ == b.pi_;
}
friend inline bool operator<(shared_count const & a, shared_count const & b)
{
return std::less<sp_counted_base *>()( a.pi_, b.pi_ );
}
void * get_deleter( sp_typeinfo const & ti ) const
{
return pi_? pi_->get_deleter( ti ): 0;
}
};
class weak_count
{
private:
sp_counted_base * pi_;
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
int id_;
#endif
friend class shared_count;
public:
weak_count(): pi_(0) // nothrow
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(weak_count_id)
#endif
{
}
weak_count(shared_count const & r): pi_(r.pi_) // nothrow
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(weak_count_id)
#endif
{
if(pi_ != 0) pi_->weak_add_ref();
}
weak_count(weak_count const & r): pi_(r.pi_) // nothrow
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(weak_count_id)
#endif
{
if(pi_ != 0) pi_->weak_add_ref();
}
// Move support
#if defined( BOOST_HAS_RVALUE_REFS )
weak_count(weak_count && r): pi_(r.pi_) // nothrow
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(weak_count_id)
#endif
{
r.pi_ = 0;
}
#endif
~weak_count() // nothrow
{
if(pi_ != 0) pi_->weak_release();
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
id_ = 0;
#endif
}
weak_count & operator= (shared_count const & r) // nothrow
{
sp_counted_base * tmp = r.pi_;
if( tmp != pi_ )
{
if(tmp != 0) tmp->weak_add_ref();
if(pi_ != 0) pi_->weak_release();
pi_ = tmp;
}
return *this;
}
weak_count & operator= (weak_count const & r) // nothrow
{
sp_counted_base * tmp = r.pi_;
if( tmp != pi_ )
{
if(tmp != 0) tmp->weak_add_ref();
if(pi_ != 0) pi_->weak_release();
pi_ = tmp;
}
return *this;
}
void swap(weak_count & r) // nothrow
{
sp_counted_base * tmp = r.pi_;
r.pi_ = pi_;
pi_ = tmp;
}
long use_count() const // nothrow
{
return pi_ != 0? pi_->use_count(): 0;
}
bool empty() const // nothrow
{
return pi_ == 0;
}
friend inline bool operator==(weak_count const & a, weak_count const & b)
{
return a.pi_ == b.pi_;
}
friend inline bool operator<(weak_count const & a, weak_count const & b)
{
return std::less<sp_counted_base *>()(a.pi_, b.pi_);
}
};
inline shared_count::shared_count( weak_count const & r ): pi_( r.pi_ )
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(shared_count_id)
#endif
{
if( pi_ == 0 || !pi_->add_ref_lock() )
{
boost::throw_exception( boost::bad_weak_ptr() );
}
}
inline shared_count::shared_count( weak_count const & r, sp_nothrow_tag ): pi_( r.pi_ )
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
, id_(shared_count_id)
#endif
{
if( pi_ != 0 && !pi_->add_ref_lock() )
{
pi_ = 0;
}
}
} // namespace detail
} // namespace boost
#ifdef __BORLANDC__
# pragma warn .8027 // Functions containing try are not expanded inline
#endif
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SHARED_COUNT_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SHARED_PTR_NMT_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SHARED_PTR_NMT_HPP_INCLUDED
//
// detail/shared_ptr_nmt.hpp - shared_ptr.hpp without member templates
//
// (C) Copyright Greg Colvin and Beman Dawes 1998, 1999.
// Copyright (c) 2001, 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)
//
// See http://www.boost.org/libs/smart_ptr/shared_ptr.htm for documentation.
//
#include <boost/assert.hpp>
#include <boost/checked_delete.hpp>
#include <boost/throw_exception.hpp>
#include <boost/smart_ptr/detail/atomic_count.hpp>
#ifndef BOOST_NO_AUTO_PTR
# include <memory> // for std::auto_ptr
#endif
#include <algorithm> // for std::swap
#include <functional> // for std::less
#include <new> // for std::bad_alloc
namespace boost
{
template<class T> class shared_ptr
{
private:
typedef detail::atomic_count count_type;
public:
typedef T element_type;
typedef T value_type;
explicit shared_ptr(T * p = 0): px(p)
{
#ifndef BOOST_NO_EXCEPTIONS
try // prevent leak if new throws
{
pn = new count_type(1);
}
catch(...)
{
boost::checked_delete(p);
throw;
}
#else
pn = new count_type(1);
if(pn == 0)
{
boost::checked_delete(p);
boost::throw_exception(std::bad_alloc());
}
#endif
}
~shared_ptr()
{
if(--*pn == 0)
{
boost::checked_delete(px);
delete pn;
}
}
shared_ptr(shared_ptr const & r): px(r.px) // never throws
{
pn = r.pn;
++*pn;
}
shared_ptr & operator=(shared_ptr const & r)
{
shared_ptr(r).swap(*this);
return *this;
}
#ifndef BOOST_NO_AUTO_PTR
explicit shared_ptr(std::auto_ptr<T> & r)
{
pn = new count_type(1); // may throw
px = r.release(); // fix: moved here to stop leak if new throws
}
shared_ptr & operator=(std::auto_ptr<T> & r)
{
shared_ptr(r).swap(*this);
return *this;
}
#endif
void reset(T * p = 0)
{
BOOST_ASSERT(p == 0 || p != px);
shared_ptr(p).swap(*this);
}
T & operator*() const // never throws
{
BOOST_ASSERT(px != 0);
return *px;
}
T * operator->() const // never throws
{
BOOST_ASSERT(px != 0);
return px;
}
T * get() const // never throws
{
return px;
}
long use_count() const // never throws
{
return *pn;
}
bool unique() const // never throws
{
return *pn == 1;
}
void swap(shared_ptr<T> & other) // never throws
{
std::swap(px, other.px);
std::swap(pn, other.pn);
}
private:
T * px; // contained pointer
count_type * pn; // ptr to reference counter
};
template<class T, class U> inline bool operator==(shared_ptr<T> const & a, shared_ptr<U> const & b)
{
return a.get() == b.get();
}
template<class T, class U> inline bool operator!=(shared_ptr<T> const & a, shared_ptr<U> const & b)
{
return a.get() != b.get();
}
template<class T> inline bool operator<(shared_ptr<T> const & a, shared_ptr<T> const & b)
{
return std::less<T*>()(a.get(), b.get());
}
template<class T> void swap(shared_ptr<T> & a, shared_ptr<T> & b)
{
a.swap(b);
}
// get_pointer() enables boost::mem_fn to recognize shared_ptr
template<class T> inline T * get_pointer(shared_ptr<T> const & p)
{
return p.get();
}
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SHARED_PTR_NMT_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_CONVERTIBLE_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_CONVERTIBLE_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
// detail/sp_convertible.hpp
//
// Copyright 2008 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/config.hpp>
#if !defined( BOOST_SP_NO_SP_CONVERTIBLE ) && defined( BOOST_NO_SFINAE )
# define BOOST_SP_NO_SP_CONVERTIBLE
#endif
#if !defined( BOOST_SP_NO_SP_CONVERTIBLE ) && defined( __GNUC__ ) && ( __GNUC__ * 100 + __GNUC_MINOR__ < 303 )
# define BOOST_SP_NO_SP_CONVERTIBLE
#endif
#if !defined( BOOST_SP_NO_SP_CONVERTIBLE ) && defined( __BORLANDC__ ) && ( __BORLANDC__ <= 0x610 )
# define BOOST_SP_NO_SP_CONVERTIBLE
#endif
#if !defined( BOOST_SP_NO_SP_CONVERTIBLE )
namespace boost
{
namespace detail
{
template< class Y, class T > struct sp_convertible
{
typedef char (&yes) [1];
typedef char (&no) [2];
static yes f( T* );
static no f( ... );
enum _vt { value = sizeof( f( static_cast<Y*>(0) ) ) == sizeof(yes) };
};
struct sp_empty
{
};
template< bool > struct sp_enable_if_convertible_impl;
template<> struct sp_enable_if_convertible_impl<true>
{
typedef sp_empty type;
};
template<> struct sp_enable_if_convertible_impl<false>
{
};
template< class Y, class T > struct sp_enable_if_convertible: public sp_enable_if_convertible_impl< sp_convertible< Y, T >::value >
{
};
} // namespace detail
} // namespace boost
#endif // !defined( BOOST_SP_NO_SP_CONVERTIBLE )
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_CONVERTIBLE_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/sp_counted_base.hpp
//
// Copyright 2005, 2006 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/config.hpp>
#include <boost/smart_ptr/detail/sp_has_sync.hpp>
#if defined( BOOST_SP_DISABLE_THREADS )
# include <boost/smart_ptr/detail/sp_counted_base_nt.hpp>
#elif defined( BOOST_SP_USE_SPINLOCK )
# include <boost/smart_ptr/detail/sp_counted_base_spin.hpp>
#elif defined( BOOST_SP_USE_PTHREADS )
# include <boost/smart_ptr/detail/sp_counted_base_pt.hpp>
#elif defined( BOOST_DISABLE_THREADS ) && !defined( BOOST_SP_ENABLE_THREADS ) && !defined( BOOST_DISABLE_WIN32 )
# include <boost/smart_ptr/detail/sp_counted_base_nt.hpp>
#elif defined( __GNUC__ ) && ( defined( __i386__ ) || defined( __x86_64__ ) )
# include <boost/smart_ptr/detail/sp_counted_base_gcc_x86.hpp>
#elif defined( __GNUC__ ) && defined( __ia64__ ) && !defined( __INTEL_COMPILER )
# include <boost/smart_ptr/detail/sp_counted_base_gcc_ia64.hpp>
#elif defined(__HP_aCC) && defined(__ia64)
# include <boost/smart_ptr/detail/sp_counted_base_acc_ia64.hpp>
#elif defined( __MWERKS__ ) && defined( __POWERPC__ )
# include <boost/smart_ptr/detail/sp_counted_base_cw_ppc.hpp>
#elif defined( __GNUC__ ) && ( defined( __powerpc__ ) || defined( __ppc__ ) || defined( __ppc ) )
# include <boost/smart_ptr/detail/sp_counted_base_gcc_ppc.hpp>
#elif defined( __GNUC__ ) && ( defined( __mips__ ) || defined( _mips ) )
# include <boost/smart_ptr/detail/sp_counted_base_gcc_mips.hpp>
#elif defined( BOOST_SP_HAS_SYNC )
# include <boost/smart_ptr/detail/sp_counted_base_sync.hpp>
#elif defined(__GNUC__) && ( defined( __sparcv9 ) || ( defined( __sparcv8 ) && ( __GNUC__ * 100 + __GNUC_MINOR__ >= 402 ) ) )
# include <boost/smart_ptr/detail/sp_counted_base_gcc_sparc.hpp>
#elif defined( WIN32 ) || defined( _WIN32 ) || defined( __WIN32__ ) || defined(__CYGWIN__)
# include <boost/smart_ptr/detail/sp_counted_base_w32.hpp>
#elif !defined( BOOST_HAS_THREADS )
# include <boost/smart_ptr/detail/sp_counted_base_nt.hpp>
#else
# include <boost/smart_ptr/detail/sp_counted_base_spin.hpp>
#endif
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_ACC_IA64_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_ACC_IA64_HPP_INCLUDED
//
// detail/sp_counted_base_acc_ia64.hpp - aC++ on HP-UX IA64
//
// Copyright 2007 Baruch Zilber
// Copyright 2007 Boris Gubenko
//
// 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)
//
//
// Lock-free algorithm by Alexander Terekhov
//
#include <boost/detail/sp_typeinfo.hpp>
#include <machine/sys/inline.h>
namespace boost
{
namespace detail
{
inline void atomic_increment( int * pw )
{
// ++*pw;
_Asm_fetchadd(_FASZ_W, _SEM_REL, pw, +1, _LDHINT_NONE);
}
inline int atomic_decrement( int * pw )
{
// return --*pw;
int r = static_cast<int>(_Asm_fetchadd(_FASZ_W, _SEM_REL, pw, -1, _LDHINT_NONE));
if (1 == r)
{
_Asm_mf();
}
return r - 1;
}
inline int atomic_conditional_increment( int * pw )
{
// if( *pw != 0 ) ++*pw;
// return *pw;
int v = *pw;
for (;;)
{
if (0 == v)
{
return 0;
}
_Asm_mov_to_ar(_AREG_CCV,
v,
(_UP_CALL_FENCE | _UP_SYS_FENCE | _DOWN_CALL_FENCE | _DOWN_SYS_FENCE));
int r = static_cast<int>(_Asm_cmpxchg(_SZ_W, _SEM_ACQ, pw, v + 1, _LDHINT_NONE));
if (r == v)
{
return r + 1;
}
v = r;
}
}
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
int use_count_; // #shared
int weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
atomic_increment( &use_count_ );
}
bool add_ref_lock() // true on success
{
return atomic_conditional_increment( &use_count_ ) != 0;
}
void release() // nothrow
{
if( atomic_decrement( &use_count_ ) == 0 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
atomic_increment( &weak_count_ );
}
void weak_release() // nothrow
{
if( atomic_decrement( &weak_count_ ) == 0 )
{
destroy();
}
}
long use_count() const // nothrow
{
return static_cast<int const volatile &>( use_count_ ); // TODO use ld.acq here
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_ACC_IA64_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_CW_PPC_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_CW_PPC_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/sp_counted_base_cw_ppc.hpp - CodeWarrior on PowerPC
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2005 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)
//
//
// Lock-free algorithm by Alexander Terekhov
//
// Thanks to Ben Hitchings for the #weak + (#shared != 0)
// formulation
//
#include <boost/detail/sp_typeinfo.hpp>
namespace boost
{
namespace detail
{
inline void atomic_increment( register long * pw )
{
register int a;
asm
{
loop:
lwarx a, 0, pw
addi a, a, 1
stwcx. a, 0, pw
bne- loop
}
}
inline long atomic_decrement( register long * pw )
{
register int a;
asm
{
sync
loop:
lwarx a, 0, pw
addi a, a, -1
stwcx. a, 0, pw
bne- loop
isync
}
return a;
}
inline long atomic_conditional_increment( register long * pw )
{
register int a;
asm
{
loop:
lwarx a, 0, pw
cmpwi a, 0
beq store
addi a, a, 1
store:
stwcx. a, 0, pw
bne- loop
}
return a;
}
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
long use_count_; // #shared
long weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
atomic_increment( &use_count_ );
}
bool add_ref_lock() // true on success
{
return atomic_conditional_increment( &use_count_ ) != 0;
}
void release() // nothrow
{
if( atomic_decrement( &use_count_ ) == 0 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
atomic_increment( &weak_count_ );
}
void weak_release() // nothrow
{
if( atomic_decrement( &weak_count_ ) == 0 )
{
destroy();
}
}
long use_count() const // nothrow
{
return static_cast<long const volatile &>( use_count_ );
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_CW_PPC_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_CW_X86_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_CW_X86_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/sp_counted_base_cw_x86.hpp - CodeWarrion on 486+
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2005 Peter Dimov
// Copyright 2005 Rene Rivera
//
// 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)
//
//
// Lock-free algorithm by Alexander Terekhov
//
// Thanks to Ben Hitchings for the #weak + (#shared != 0)
// formulation
//
#include <boost/detail/sp_typeinfo.hpp>
namespace boost
{
namespace detail
{
inline int atomic_exchange_and_add( int * pw, int dv )
{
// int r = *pw;
// *pw += dv;
// return r;
asm
{
mov esi, [pw]
mov eax, dv
lock xadd dword ptr [esi], eax
}
}
inline void atomic_increment( int * pw )
{
//atomic_exchange_and_add( pw, 1 );
asm
{
mov esi, [pw]
lock inc dword ptr [esi]
}
}
inline int atomic_conditional_increment( int * pw )
{
// int rv = *pw;
// if( rv != 0 ) ++*pw;
// return rv;
asm
{
mov esi, [pw]
mov eax, dword ptr [esi]
L0:
test eax, eax
je L1
mov ebx, eax
inc ebx
lock cmpxchg dword ptr [esi], ebx
jne L0
L1:
}
}
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
int use_count_; // #shared
int weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
atomic_increment( &use_count_ );
}
bool add_ref_lock() // true on success
{
return atomic_conditional_increment( &use_count_ ) != 0;
}
void release() // nothrow
{
if( atomic_exchange_and_add( &use_count_, -1 ) == 1 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
atomic_increment( &weak_count_ );
}
void weak_release() // nothrow
{
if( atomic_exchange_and_add( &weak_count_, -1 ) == 1 )
{
destroy();
}
}
long use_count() const // nothrow
{
return static_cast<int const volatile &>( use_count_ );
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_CW_X86_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_IA64_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_IA64_HPP_INCLUDED
//
// detail/sp_counted_base_gcc_ia64.hpp - g++ on IA64
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2006 Peter Dimov
// Copyright 2005 Ben Hutchings
//
// 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)
//
//
// Lock-free algorithm by Alexander Terekhov
//
#include <boost/detail/sp_typeinfo.hpp>
namespace boost
{
namespace detail
{
inline void atomic_increment( int * pw )
{
// ++*pw;
int tmp;
// No barrier is required here but fetchadd always has an acquire or
// release barrier associated with it. We choose release as it should be
// cheaper.
__asm__ ("fetchadd4.rel %0=%1,1" :
"=r"(tmp), "=m"(*pw) :
"m"( *pw ));
}
inline int atomic_decrement( int * pw )
{
// return --*pw;
int rv;
__asm__ (" fetchadd4.rel %0=%1,-1 ;; \n"
" cmp.eq p7,p0=1,%0 ;; \n"
"(p7) ld4.acq %0=%1 " :
"=&r"(rv), "=m"(*pw) :
"m"( *pw ) :
"p7");
return rv;
}
inline int atomic_conditional_increment( int * pw )
{
// if( *pw != 0 ) ++*pw;
// return *pw;
int rv, tmp, tmp2;
__asm__ ("0: ld4 %0=%3 ;; \n"
" cmp.eq p7,p0=0,%0 ;; \n"
"(p7) br.cond.spnt 1f \n"
" mov ar.ccv=%0 \n"
" add %1=1,%0 ;; \n"
" cmpxchg4.acq %2=%3,%1,ar.ccv ;; \n"
" cmp.ne p7,p0=%0,%2 ;; \n"
"(p7) br.cond.spnt 0b \n"
" mov %0=%1 ;; \n"
"1:" :
"=&r"(rv), "=&r"(tmp), "=&r"(tmp2), "=m"(*pw) :
"m"( *pw ) :
"ar.ccv", "p7");
return rv;
}
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
int use_count_; // #shared
int weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
atomic_increment( &use_count_ );
}
bool add_ref_lock() // true on success
{
return atomic_conditional_increment( &use_count_ ) != 0;
}
void release() // nothrow
{
if( atomic_decrement( &use_count_ ) == 0 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
atomic_increment( &weak_count_ );
}
void weak_release() // nothrow
{
if( atomic_decrement( &weak_count_ ) == 0 )
{
destroy();
}
}
long use_count() const // nothrow
{
return static_cast<int const volatile &>( use_count_ ); // TODO use ld.acq here
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_IA64_HPP_INCLUDED

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#ifndef BOOST_DETAIL_SP_COUNTED_BASE_GCC_MIPS_HPP_INCLUDED
#define BOOST_DETAIL_SP_COUNTED_BASE_GCC_MIPS_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/sp_counted_base_gcc_mips.hpp - g++ on MIPS
//
// Copyright (c) 2009, Spirent Communications, Inc.
//
// 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)
//
//
// Lock-free algorithm by Alexander Terekhov
//
#include <boost/detail/sp_typeinfo.hpp>
namespace boost
{
namespace detail
{
inline void atomic_increment( int * pw )
{
// ++*pw;
int tmp;
__asm__ __volatile__
(
"0:\n\t"
"ll %0, %1\n\t"
"addiu %0, 1\n\t"
"sc %0, %1\n\t"
"beqz %0, 0b":
"=&r"( tmp ), "=m"( *pw ):
"m"( *pw )
);
}
inline int atomic_decrement( int * pw )
{
// return --*pw;
int rv, tmp;
__asm__ __volatile__
(
"0:\n\t"
"ll %1, %2\n\t"
"addiu %0, %1, -1\n\t"
"sc %0, %2\n\t"
"beqz %0, 0b\n\t"
"addiu %0, %1, -1":
"=&r"( rv ), "=&r"( tmp ), "=m"( *pw ):
"m"( *pw ):
"memory"
);
return rv;
}
inline int atomic_conditional_increment( int * pw )
{
// if( *pw != 0 ) ++*pw;
// return *pw;
int rv, tmp;
__asm__ __volatile__
(
"0:\n\t"
"ll %0, %2\n\t"
"beqz %0, 1f\n\t"
"addiu %1, %0, 1\n\t"
"sc %1, %2\n\t"
"beqz %1, 0b\n\t"
"addiu %0, %0, 1\n\t"
"1:":
"=&r"( rv ), "=&r"( tmp ), "=m"( *pw ):
"m"( *pw ):
"memory"
);
return rv;
}
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
int use_count_; // #shared
int weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
atomic_increment( &use_count_ );
}
bool add_ref_lock() // true on success
{
return atomic_conditional_increment( &use_count_ ) != 0;
}
void release() // nothrow
{
if( atomic_decrement( &use_count_ ) == 0 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
atomic_increment( &weak_count_ );
}
void weak_release() // nothrow
{
if( atomic_decrement( &weak_count_ ) == 0 )
{
destroy();
}
}
long use_count() const // nothrow
{
return static_cast<int const volatile &>( use_count_ );
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_DETAIL_SP_COUNTED_BASE_GCC_MIPS_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_PPC_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_PPC_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/sp_counted_base_gcc_ppc.hpp - g++ on PowerPC
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2005 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)
//
//
// Lock-free algorithm by Alexander Terekhov
//
// Thanks to Ben Hitchings for the #weak + (#shared != 0)
// formulation
//
#include <boost/detail/sp_typeinfo.hpp>
namespace boost
{
namespace detail
{
inline void atomic_increment( int * pw )
{
// ++*pw;
int tmp;
__asm__
(
"0:\n\t"
"lwarx %1, 0, %2\n\t"
"addi %1, %1, 1\n\t"
"stwcx. %1, 0, %2\n\t"
"bne- 0b":
"=m"( *pw ), "=&b"( tmp ):
"r"( pw ), "m"( *pw ):
"cc"
);
}
inline int atomic_decrement( int * pw )
{
// return --*pw;
int rv;
__asm__ __volatile__
(
"sync\n\t"
"0:\n\t"
"lwarx %1, 0, %2\n\t"
"addi %1, %1, -1\n\t"
"stwcx. %1, 0, %2\n\t"
"bne- 0b\n\t"
"isync":
"=m"( *pw ), "=&b"( rv ):
"r"( pw ), "m"( *pw ):
"memory", "cc"
);
return rv;
}
inline int atomic_conditional_increment( int * pw )
{
// if( *pw != 0 ) ++*pw;
// return *pw;
int rv;
__asm__
(
"0:\n\t"
"lwarx %1, 0, %2\n\t"
"cmpwi %1, 0\n\t"
"beq 1f\n\t"
"addi %1, %1, 1\n\t"
"1:\n\t"
"stwcx. %1, 0, %2\n\t"
"bne- 0b":
"=m"( *pw ), "=&b"( rv ):
"r"( pw ), "m"( *pw ):
"cc"
);
return rv;
}
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
int use_count_; // #shared
int weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
atomic_increment( &use_count_ );
}
bool add_ref_lock() // true on success
{
return atomic_conditional_increment( &use_count_ ) != 0;
}
void release() // nothrow
{
if( atomic_decrement( &use_count_ ) == 0 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
atomic_increment( &weak_count_ );
}
void weak_release() // nothrow
{
if( atomic_decrement( &weak_count_ ) == 0 )
{
destroy();
}
}
long use_count() const // nothrow
{
return static_cast<int const volatile &>( use_count_ );
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_PPC_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_SPARC_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_SPARC_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
// detail/sp_counted_base_gcc_sparc.hpp - g++ on Sparc V8+
//
// Copyright (c) 2006 Piotr Wyderski
// Copyright (c) 2006 Tomas Puverle
// Copyright (c) 2006 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
//
// Thanks to Michael van der Westhuizen
#include <boost/detail/sp_typeinfo.hpp>
#include <inttypes.h> // int32_t
namespace boost
{
namespace detail
{
inline int32_t compare_and_swap( int32_t * dest_, int32_t compare_, int32_t swap_ )
{
__asm__ __volatile__( "cas %0, %2, %1"
: "+m" (*dest_), "+r" (swap_)
: "r" (compare_)
: "memory" );
return swap_;
}
inline int32_t atomic_fetch_and_add( int32_t * pw, int32_t dv )
{
// long r = *pw;
// *pw += dv;
// return r;
for( ;; )
{
int32_t r = *pw;
if( __builtin_expect((compare_and_swap(pw, r, r + dv) == r), 1) )
{
return r;
}
}
}
inline void atomic_increment( int32_t * pw )
{
atomic_fetch_and_add( pw, 1 );
}
inline int32_t atomic_decrement( int32_t * pw )
{
return atomic_fetch_and_add( pw, -1 );
}
inline int32_t atomic_conditional_increment( int32_t * pw )
{
// long r = *pw;
// if( r != 0 ) ++*pw;
// return r;
for( ;; )
{
int32_t r = *pw;
if( r == 0 )
{
return r;
}
if( __builtin_expect( ( compare_and_swap( pw, r, r + 1 ) == r ), 1 ) )
{
return r;
}
}
}
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
int32_t use_count_; // #shared
int32_t weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
atomic_increment( &use_count_ );
}
bool add_ref_lock() // true on success
{
return atomic_conditional_increment( &use_count_ ) != 0;
}
void release() // nothrow
{
if( atomic_decrement( &use_count_ ) == 1 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
atomic_increment( &weak_count_ );
}
void weak_release() // nothrow
{
if( atomic_decrement( &weak_count_ ) == 1 )
{
destroy();
}
}
long use_count() const // nothrow
{
return const_cast< int32_t const volatile & >( use_count_ );
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_SPARC_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_X86_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_X86_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/sp_counted_base_gcc_x86.hpp - g++ on 486+ or AMD64
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2005 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)
//
//
// Lock-free algorithm by Alexander Terekhov
//
// Thanks to Ben Hitchings for the #weak + (#shared != 0)
// formulation
//
#include <boost/detail/sp_typeinfo.hpp>
namespace boost
{
namespace detail
{
inline int atomic_exchange_and_add( int * pw, int dv )
{
// int r = *pw;
// *pw += dv;
// return r;
int r;
__asm__ __volatile__
(
"lock\n\t"
"xadd %1, %0":
"=m"( *pw ), "=r"( r ): // outputs (%0, %1)
"m"( *pw ), "1"( dv ): // inputs (%2, %3 == %1)
"memory", "cc" // clobbers
);
return r;
}
inline void atomic_increment( int * pw )
{
//atomic_exchange_and_add( pw, 1 );
__asm__
(
"lock\n\t"
"incl %0":
"=m"( *pw ): // output (%0)
"m"( *pw ): // input (%1)
"cc" // clobbers
);
}
inline int atomic_conditional_increment( int * pw )
{
// int rv = *pw;
// if( rv != 0 ) ++*pw;
// return rv;
int rv, tmp;
__asm__
(
"movl %0, %%eax\n\t"
"0:\n\t"
"test %%eax, %%eax\n\t"
"je 1f\n\t"
"movl %%eax, %2\n\t"
"incl %2\n\t"
"lock\n\t"
"cmpxchgl %2, %0\n\t"
"jne 0b\n\t"
"1:":
"=m"( *pw ), "=&a"( rv ), "=&r"( tmp ): // outputs (%0, %1, %2)
"m"( *pw ): // input (%3)
"cc" // clobbers
);
return rv;
}
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
int use_count_; // #shared
int weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
atomic_increment( &use_count_ );
}
bool add_ref_lock() // true on success
{
return atomic_conditional_increment( &use_count_ ) != 0;
}
void release() // nothrow
{
if( atomic_exchange_and_add( &use_count_, -1 ) == 1 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
atomic_increment( &weak_count_ );
}
void weak_release() // nothrow
{
if( atomic_exchange_and_add( &weak_count_, -1 ) == 1 )
{
destroy();
}
}
long use_count() const // nothrow
{
return static_cast<int const volatile &>( use_count_ );
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_GCC_X86_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_NT_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_NT_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/sp_counted_base_nt.hpp
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2005 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/sp_typeinfo.hpp>
namespace boost
{
namespace detail
{
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
long use_count_; // #shared
long weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
++use_count_;
}
bool add_ref_lock() // true on success
{
if( use_count_ == 0 ) return false;
++use_count_;
return true;
}
void release() // nothrow
{
if( --use_count_ == 0 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
++weak_count_;
}
void weak_release() // nothrow
{
if( --weak_count_ == 0 )
{
destroy();
}
}
long use_count() const // nothrow
{
return use_count_;
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_NT_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_PT_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_PT_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/sp_counted_base_pt.hpp
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2005 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/sp_typeinfo.hpp>
#include <pthread.h>
namespace boost
{
namespace detail
{
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
long use_count_; // #shared
long weak_count_; // #weak + (#shared != 0)
mutable pthread_mutex_t m_;
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
// HPUX 10.20 / DCE has a nonstandard pthread_mutex_init
#if defined(__hpux) && defined(_DECTHREADS_)
pthread_mutex_init( &m_, pthread_mutexattr_default );
#else
pthread_mutex_init( &m_, 0 );
#endif
}
virtual ~sp_counted_base() // nothrow
{
pthread_mutex_destroy( &m_ );
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
pthread_mutex_lock( &m_ );
++use_count_;
pthread_mutex_unlock( &m_ );
}
bool add_ref_lock() // true on success
{
pthread_mutex_lock( &m_ );
bool r = use_count_ == 0? false: ( ++use_count_, true );
pthread_mutex_unlock( &m_ );
return r;
}
void release() // nothrow
{
pthread_mutex_lock( &m_ );
long new_use_count = --use_count_;
pthread_mutex_unlock( &m_ );
if( new_use_count == 0 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
pthread_mutex_lock( &m_ );
++weak_count_;
pthread_mutex_unlock( &m_ );
}
void weak_release() // nothrow
{
pthread_mutex_lock( &m_ );
long new_weak_count = --weak_count_;
pthread_mutex_unlock( &m_ );
if( new_weak_count == 0 )
{
destroy();
}
}
long use_count() const // nothrow
{
pthread_mutex_lock( &m_ );
long r = use_count_;
pthread_mutex_unlock( &m_ );
return r;
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_PT_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_SOLARIS_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_SOLARIS_HPP_INCLUDED
//
// detail/sp_counted_base_solaris.hpp
// based on: detail/sp_counted_base_w32.hpp
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2005 Peter Dimov
// Copyright 2006 Michael van der Westhuizen
//
// 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)
//
//
// Lock-free algorithm by Alexander Terekhov
//
// Thanks to Ben Hitchings for the #weak + (#shared != 0)
// formulation
//
#include <boost/detail/sp_typeinfo.hpp>
#include <atomic.h>
namespace boost
{
namespace detail
{
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
uint32_t use_count_; // #shared
uint32_t weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
atomic_inc_32( &use_count_ );
}
bool add_ref_lock() // true on success
{
for( ;; )
{
uint32_t tmp = static_cast< uint32_t const volatile& >( use_count_ );
if( tmp == 0 ) return false;
if( atomic_cas_32( &use_count_, tmp, tmp + 1 ) == tmp ) return true;
}
}
void release() // nothrow
{
if( atomic_dec_32_nv( &use_count_ ) == 0 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
atomic_inc_32( &weak_count_ );
}
void weak_release() // nothrow
{
if( atomic_dec_32_nv( &weak_count_ ) == 0 )
{
destroy();
}
}
long use_count() const // nothrow
{
return static_cast<long const volatile &>( use_count_ );
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_SOLARIS_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_SPIN_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_SPIN_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/sp_counted_base_spin.hpp - spinlock pool atomic emulation
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2008 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/sp_typeinfo.hpp>
#include <boost/smart_ptr/detail/spinlock_pool.hpp>
namespace boost
{
namespace detail
{
inline int atomic_exchange_and_add( int * pw, int dv )
{
spinlock_pool<1>::scoped_lock lock( pw );
int r = *pw;
*pw += dv;
return r;
}
inline void atomic_increment( int * pw )
{
spinlock_pool<1>::scoped_lock lock( pw );
++*pw;
}
inline int atomic_conditional_increment( int * pw )
{
spinlock_pool<1>::scoped_lock lock( pw );
int rv = *pw;
if( rv != 0 ) ++*pw;
return rv;
}
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
int use_count_; // #shared
int weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
atomic_increment( &use_count_ );
}
bool add_ref_lock() // true on success
{
return atomic_conditional_increment( &use_count_ ) != 0;
}
void release() // nothrow
{
if( atomic_exchange_and_add( &use_count_, -1 ) == 1 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
atomic_increment( &weak_count_ );
}
void weak_release() // nothrow
{
if( atomic_exchange_and_add( &weak_count_, -1 ) == 1 )
{
destroy();
}
}
long use_count() const // nothrow
{
spinlock_pool<1>::scoped_lock lock( &use_count_ );
return use_count_;
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_SPIN_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_SYNC_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_SYNC_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
// detail/sp_counted_base_sync.hpp - g++ 4.1+ __sync intrinsics
//
// Copyright (c) 2007 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/sp_typeinfo.hpp>
#include <limits.h>
#if defined( __ia64__ ) && defined( __INTEL_COMPILER )
# include <ia64intrin.h>
#endif
namespace boost
{
namespace detail
{
#if INT_MAX >= 2147483647
typedef int sp_int32_t;
#else
typedef long sp_int32_t;
#endif
inline void atomic_increment( sp_int32_t * pw )
{
__sync_fetch_and_add( pw, 1 );
}
inline sp_int32_t atomic_decrement( sp_int32_t * pw )
{
return __sync_fetch_and_add( pw, -1 );
}
inline sp_int32_t atomic_conditional_increment( sp_int32_t * pw )
{
// long r = *pw;
// if( r != 0 ) ++*pw;
// return r;
sp_int32_t r = *pw;
for( ;; )
{
if( r == 0 )
{
return r;
}
sp_int32_t r2 = __sync_val_compare_and_swap( pw, r, r + 1 );
if( r2 == r )
{
return r;
}
else
{
r = r2;
}
}
}
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
sp_int32_t use_count_; // #shared
sp_int32_t weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
atomic_increment( &use_count_ );
}
bool add_ref_lock() // true on success
{
return atomic_conditional_increment( &use_count_ ) != 0;
}
void release() // nothrow
{
if( atomic_decrement( &use_count_ ) == 1 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
atomic_increment( &weak_count_ );
}
void weak_release() // nothrow
{
if( atomic_decrement( &weak_count_ ) == 1 )
{
destroy();
}
}
long use_count() const // nothrow
{
return const_cast< sp_int32_t const volatile & >( use_count_ );
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_SYNC_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_W32_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_W32_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/sp_counted_base_w32.hpp
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2005 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)
//
//
// Lock-free algorithm by Alexander Terekhov
//
// Thanks to Ben Hitchings for the #weak + (#shared != 0)
// formulation
//
#include <boost/detail/interlocked.hpp>
#include <boost/detail/workaround.hpp>
#include <boost/detail/sp_typeinfo.hpp>
namespace boost
{
namespace detail
{
class sp_counted_base
{
private:
sp_counted_base( sp_counted_base const & );
sp_counted_base & operator= ( sp_counted_base const & );
long use_count_; // #shared
long weak_count_; // #weak + (#shared != 0)
public:
sp_counted_base(): use_count_( 1 ), weak_count_( 1 )
{
}
virtual ~sp_counted_base() // nothrow
{
}
// dispose() is called when use_count_ drops to zero, to release
// the resources managed by *this.
virtual void dispose() = 0; // nothrow
// destroy() is called when weak_count_ drops to zero.
virtual void destroy() // nothrow
{
delete this;
}
virtual void * get_deleter( sp_typeinfo const & ti ) = 0;
void add_ref_copy()
{
BOOST_INTERLOCKED_INCREMENT( &use_count_ );
}
bool add_ref_lock() // true on success
{
for( ;; )
{
long tmp = static_cast< long const volatile& >( use_count_ );
if( tmp == 0 ) return false;
#if defined( BOOST_MSVC ) && BOOST_WORKAROUND( BOOST_MSVC, == 1200 )
// work around a code generation bug
long tmp2 = tmp + 1;
if( BOOST_INTERLOCKED_COMPARE_EXCHANGE( &use_count_, tmp2, tmp ) == tmp2 - 1 ) return true;
#else
if( BOOST_INTERLOCKED_COMPARE_EXCHANGE( &use_count_, tmp + 1, tmp ) == tmp ) return true;
#endif
}
}
void release() // nothrow
{
if( BOOST_INTERLOCKED_DECREMENT( &use_count_ ) == 0 )
{
dispose();
weak_release();
}
}
void weak_add_ref() // nothrow
{
BOOST_INTERLOCKED_INCREMENT( &weak_count_ );
}
void weak_release() // nothrow
{
if( BOOST_INTERLOCKED_DECREMENT( &weak_count_ ) == 0 )
{
destroy();
}
}
long use_count() const // nothrow
{
return static_cast<long const volatile &>( use_count_ );
}
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_BASE_W32_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_IMPL_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_COUNTED_IMPL_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// detail/sp_counted_impl.hpp
//
// Copyright (c) 2001, 2002, 2003 Peter Dimov and Multi Media Ltd.
// Copyright 2004-2005 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/config.hpp>
#if defined(BOOST_SP_USE_STD_ALLOCATOR) && defined(BOOST_SP_USE_QUICK_ALLOCATOR)
# error BOOST_SP_USE_STD_ALLOCATOR and BOOST_SP_USE_QUICK_ALLOCATOR are incompatible.
#endif
#include <boost/checked_delete.hpp>
#include <boost/smart_ptr/detail/sp_counted_base.hpp>
#if defined(BOOST_SP_USE_QUICK_ALLOCATOR)
#include <boost/smart_ptr/detail/quick_allocator.hpp>
#endif
#if defined(BOOST_SP_USE_STD_ALLOCATOR)
#include <memory> // std::allocator
#endif
#include <cstddef> // std::size_t
namespace boost
{
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
void sp_scalar_constructor_hook( void * px, std::size_t size, void * pn );
void sp_scalar_destructor_hook( void * px, std::size_t size, void * pn );
#endif
namespace detail
{
template<class X> class sp_counted_impl_p: public sp_counted_base
{
private:
X * px_;
sp_counted_impl_p( sp_counted_impl_p const & );
sp_counted_impl_p & operator= ( sp_counted_impl_p const & );
typedef sp_counted_impl_p<X> this_type;
public:
explicit sp_counted_impl_p( X * px ): px_( px )
{
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
boost::sp_scalar_constructor_hook( px, sizeof(X), this );
#endif
}
virtual void dispose() // nothrow
{
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
boost::sp_scalar_destructor_hook( px_, sizeof(X), this );
#endif
boost::checked_delete( px_ );
}
virtual void * get_deleter( detail::sp_typeinfo const & )
{
return 0;
}
#if defined(BOOST_SP_USE_STD_ALLOCATOR)
void * operator new( std::size_t )
{
return std::allocator<this_type>().allocate( 1, static_cast<this_type *>(0) );
}
void operator delete( void * p )
{
std::allocator<this_type>().deallocate( static_cast<this_type *>(p), 1 );
}
#endif
#if defined(BOOST_SP_USE_QUICK_ALLOCATOR)
void * operator new( std::size_t )
{
return quick_allocator<this_type>::alloc();
}
void operator delete( void * p )
{
quick_allocator<this_type>::dealloc( p );
}
#endif
};
//
// Borland's Codeguard trips up over the -Vx- option here:
//
#ifdef __CODEGUARD__
# pragma option push -Vx-
#endif
template<class P, class D> class sp_counted_impl_pd: public sp_counted_base
{
private:
P ptr; // copy constructor must not throw
D del; // copy constructor must not throw
sp_counted_impl_pd( sp_counted_impl_pd const & );
sp_counted_impl_pd & operator= ( sp_counted_impl_pd const & );
typedef sp_counted_impl_pd<P, D> this_type;
public:
// pre: d(p) must not throw
sp_counted_impl_pd( P p, D d ): ptr(p), del(d)
{
}
virtual void dispose() // nothrow
{
del( ptr );
}
virtual void * get_deleter( detail::sp_typeinfo const & ti )
{
return ti == BOOST_SP_TYPEID(D)? &reinterpret_cast<char&>( del ): 0;
}
#if defined(BOOST_SP_USE_STD_ALLOCATOR)
void * operator new( std::size_t )
{
return std::allocator<this_type>().allocate( 1, static_cast<this_type *>(0) );
}
void operator delete( void * p )
{
std::allocator<this_type>().deallocate( static_cast<this_type *>(p), 1 );
}
#endif
#if defined(BOOST_SP_USE_QUICK_ALLOCATOR)
void * operator new( std::size_t )
{
return quick_allocator<this_type>::alloc();
}
void operator delete( void * p )
{
quick_allocator<this_type>::dealloc( p );
}
#endif
};
template<class P, class D, class A> class sp_counted_impl_pda: public sp_counted_base
{
private:
P p_; // copy constructor must not throw
D d_; // copy constructor must not throw
A a_; // copy constructor must not throw
sp_counted_impl_pda( sp_counted_impl_pda const & );
sp_counted_impl_pda & operator= ( sp_counted_impl_pda const & );
typedef sp_counted_impl_pda<P, D, A> this_type;
public:
// pre: d( p ) must not throw
sp_counted_impl_pda( P p, D d, A a ): p_( p ), d_( d ), a_( a )
{
}
virtual void dispose() // nothrow
{
d_( p_ );
}
virtual void destroy() // nothrow
{
typedef typename A::template rebind< this_type >::other A2;
A2 a2( a_ );
this->~this_type();
a2.deallocate( this, 1 );
}
virtual void * get_deleter( detail::sp_typeinfo const & ti )
{
return ti == BOOST_SP_TYPEID( D )? &reinterpret_cast<char&>( d_ ): 0;
}
};
#ifdef __CODEGUARD__
# pragma option pop
#endif
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_COUNTED_IMPL_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SP_HAS_SYNC_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SP_HAS_SYNC_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/smart_ptr/detail/sp_has_sync.hpp
//
// Copyright (c) 2008, 2009 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)
//
// Defines the BOOST_SP_HAS_SYNC macro if the __sync_* intrinsics
// are available.
//
#if defined(__GNUC__) && ( __GNUC__ * 100 + __GNUC_MINOR__ >= 401 )
#define BOOST_SP_HAS_SYNC
#if defined( __arm__ ) || defined( __armel__ )
#undef BOOST_SP_HAS_SYNC
#endif
#if defined( __hppa ) || defined( __hppa__ )
#undef BOOST_SP_HAS_SYNC
#endif
#if defined( __m68k__ )
#undef BOOST_SP_HAS_SYNC
#endif
#if defined( __sparc__ )
#undef BOOST_SP_HAS_SYNC
#endif
#if defined( __INTEL_COMPILER ) && !defined( __ia64__ )
#undef BOOST_SP_HAS_SYNC
#endif
#endif // __GNUC__ * 100 + __GNUC_MINOR__ >= 401
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SP_HAS_SYNC_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SPINLOCK_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/detail/spinlock.hpp
//
// Copyright (c) 2008 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)
//
// struct spinlock
// {
// void lock();
// bool try_lock();
// void unlock();
//
// class scoped_lock;
// };
//
// #define BOOST_DETAIL_SPINLOCK_INIT <unspecified>
//
#include <boost/config.hpp>
#include <boost/smart_ptr/detail/sp_has_sync.hpp>
#if defined(__GNUC__) && defined( __arm__ ) && !defined( __thumb__ )
# include <boost/smart_ptr/detail/spinlock_gcc_arm.hpp>
#elif defined( BOOST_SP_HAS_SYNC )
# include <boost/smart_ptr/detail/spinlock_sync.hpp>
#elif defined(WIN32) || defined(_WIN32) || defined(__WIN32__) || defined(__CYGWIN__)
# include <boost/smart_ptr/detail/spinlock_w32.hpp>
#elif defined(BOOST_HAS_PTHREADS)
# include <boost/smart_ptr/detail/spinlock_pt.hpp>
#elif !defined(BOOST_HAS_THREADS)
# include <boost/smart_ptr/detail/spinlock_nt.hpp>
#else
# error Unrecognized threading platform
#endif
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_GCC_ARM_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SPINLOCK_GCC_ARM_HPP_INCLUDED
//
// Copyright (c) 2008 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/smart_ptr/detail/yield_k.hpp>
namespace boost
{
namespace detail
{
class spinlock
{
public:
int v_;
public:
bool try_lock()
{
int r;
__asm__ __volatile__(
"swp %0, %1, [%2]":
"=&r"( r ): // outputs
"r"( 1 ), "r"( &v_ ): // inputs
"memory", "cc" );
return r == 0;
}
void lock()
{
for( unsigned k = 0; !try_lock(); ++k )
{
boost::detail::yield( k );
}
}
void unlock()
{
__asm__ __volatile__( "" ::: "memory" );
*const_cast< int volatile* >( &v_ ) = 0;
}
public:
class scoped_lock
{
private:
spinlock & sp_;
scoped_lock( scoped_lock const & );
scoped_lock & operator=( scoped_lock const & );
public:
explicit scoped_lock( spinlock & sp ): sp_( sp )
{
sp.lock();
}
~scoped_lock()
{
sp_.unlock();
}
};
};
} // namespace detail
} // namespace boost
#define BOOST_DETAIL_SPINLOCK_INIT {0}
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_GCC_ARM_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_NT_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SPINLOCK_NT_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// Copyright (c) 2008 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/assert.hpp>
namespace boost
{
namespace detail
{
class spinlock
{
public:
bool locked_;
public:
inline bool try_lock()
{
if( locked_ )
{
return false;
}
else
{
locked_ = true;
return true;
}
}
inline void lock()
{
BOOST_ASSERT( !locked_ );
locked_ = true;
}
inline void unlock()
{
BOOST_ASSERT( locked_ );
locked_ = false;
}
public:
class scoped_lock
{
private:
spinlock & sp_;
scoped_lock( scoped_lock const & );
scoped_lock & operator=( scoped_lock const & );
public:
explicit scoped_lock( spinlock & sp ): sp_( sp )
{
sp.lock();
}
~scoped_lock()
{
sp_.unlock();
}
};
};
} // namespace detail
} // namespace boost
#define BOOST_DETAIL_SPINLOCK_INIT { false }
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_NT_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_POOL_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SPINLOCK_POOL_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// boost/detail/spinlock_pool.hpp
//
// Copyright (c) 2008 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)
//
// spinlock_pool<0> is reserved for atomic<>, when/if it arrives
// spinlock_pool<1> is reserved for shared_ptr reference counts
// spinlock_pool<2> is reserved for shared_ptr atomic access
//
#include <boost/config.hpp>
#include <boost/smart_ptr/detail/spinlock.hpp>
#include <cstddef>
namespace boost
{
namespace detail
{
template< int I > class spinlock_pool
{
private:
static spinlock pool_[ 41 ];
public:
static spinlock & spinlock_for( void const * pv )
{
std::size_t i = reinterpret_cast< std::size_t >( pv ) % 41;
return pool_[ i ];
}
class scoped_lock
{
private:
spinlock & sp_;
scoped_lock( scoped_lock const & );
scoped_lock & operator=( scoped_lock const & );
public:
explicit scoped_lock( void const * pv ): sp_( spinlock_for( pv ) )
{
sp_.lock();
}
~scoped_lock()
{
sp_.unlock();
}
};
};
template< int I > spinlock spinlock_pool< I >::pool_[ 41 ] =
{
BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT,
BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT,
BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT,
BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT,
BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT,
BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT,
BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT,
BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT, BOOST_DETAIL_SPINLOCK_INIT,
BOOST_DETAIL_SPINLOCK_INIT
};
} // namespace detail
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_POOL_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_PT_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SPINLOCK_PT_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// Copyright (c) 2008 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 <pthread.h>
namespace boost
{
namespace detail
{
class spinlock
{
public:
pthread_mutex_t v_;
public:
bool try_lock()
{
return pthread_mutex_trylock( &v_ ) == 0;
}
void lock()
{
pthread_mutex_lock( &v_ );
}
void unlock()
{
pthread_mutex_unlock( &v_ );
}
public:
class scoped_lock
{
private:
spinlock & sp_;
scoped_lock( scoped_lock const & );
scoped_lock & operator=( scoped_lock const & );
public:
explicit scoped_lock( spinlock & sp ): sp_( sp )
{
sp.lock();
}
~scoped_lock()
{
sp_.unlock();
}
};
};
} // namespace detail
} // namespace boost
#define BOOST_DETAIL_SPINLOCK_INIT { PTHREAD_MUTEX_INITIALIZER }
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_PT_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_SYNC_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SPINLOCK_SYNC_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// Copyright (c) 2008 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/smart_ptr/detail/yield_k.hpp>
#if defined( __ia64__ ) && defined( __INTEL_COMPILER )
# include <ia64intrin.h>
#endif
namespace boost
{
namespace detail
{
class spinlock
{
public:
int v_;
public:
bool try_lock()
{
int r = __sync_lock_test_and_set( &v_, 1 );
return r == 0;
}
void lock()
{
for( unsigned k = 0; !try_lock(); ++k )
{
boost::detail::yield( k );
}
}
void unlock()
{
__sync_lock_release( &v_ );
}
public:
class scoped_lock
{
private:
spinlock & sp_;
scoped_lock( scoped_lock const & );
scoped_lock & operator=( scoped_lock const & );
public:
explicit scoped_lock( spinlock & sp ): sp_( sp )
{
sp.lock();
}
~scoped_lock()
{
sp_.unlock();
}
};
};
} // namespace detail
} // namespace boost
#define BOOST_DETAIL_SPINLOCK_INIT {0}
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_SYNC_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_W32_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_SPINLOCK_W32_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// Copyright (c) 2008 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/interlocked.hpp>
#include <boost/smart_ptr/detail/yield_k.hpp>
// BOOST_COMPILER_FENCE
#if defined(__INTEL_COMPILER)
#define BOOST_COMPILER_FENCE __memory_barrier();
#elif defined( _MSC_VER ) && _MSC_VER >= 1310
extern "C" void _ReadWriteBarrier();
#pragma intrinsic( _ReadWriteBarrier )
#define BOOST_COMPILER_FENCE _ReadWriteBarrier();
#elif defined(__GNUC__)
#define BOOST_COMPILER_FENCE __asm__ __volatile__( "" : : : "memory" );
#else
#define BOOST_COMPILER_FENCE
#endif
//
namespace boost
{
namespace detail
{
class spinlock
{
public:
long v_;
public:
bool try_lock()
{
long r = BOOST_INTERLOCKED_EXCHANGE( &v_, 1 );
BOOST_COMPILER_FENCE
return r == 0;
}
void lock()
{
for( unsigned k = 0; !try_lock(); ++k )
{
boost::detail::yield( k );
}
}
void unlock()
{
BOOST_COMPILER_FENCE
*const_cast< long volatile* >( &v_ ) = 0;
}
public:
class scoped_lock
{
private:
spinlock & sp_;
scoped_lock( scoped_lock const & );
scoped_lock & operator=( scoped_lock const & );
public:
explicit scoped_lock( spinlock & sp ): sp_( sp )
{
sp.lock();
}
~scoped_lock()
{
sp_.unlock();
}
};
};
} // namespace detail
} // namespace boost
#define BOOST_DETAIL_SPINLOCK_INIT {0}
#endif // #ifndef BOOST_SMART_PTR_DETAIL_SPINLOCK_W32_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_DETAIL_YIELD_K_HPP_INCLUDED
#define BOOST_SMART_PTR_DETAIL_YIELD_K_HPP_INCLUDED
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
//
// yield_k.hpp
//
// Copyright (c) 2008 Peter Dimov
//
// void yield( unsigned k );
//
// Typical use:
//
// for( unsigned k = 0; !try_lock(); ++k ) yield( k );
//
// 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/config.hpp>
// BOOST_SMT_PAUSE
#if defined(_MSC_VER) && _MSC_VER >= 1310 && ( defined(_M_IX86) || defined(_M_X64) )
extern "C" void _mm_pause();
#pragma intrinsic( _mm_pause )
#define BOOST_SMT_PAUSE _mm_pause();
#elif defined(__GNUC__) && ( defined(__i386__) || defined(__x86_64__) )
#define BOOST_SMT_PAUSE __asm__ __volatile__( "rep; nop" : : : "memory" );
#endif
//
#if defined( WIN32 ) || defined( _WIN32 ) || defined( __WIN32__ ) || defined( __CYGWIN__ )
#if defined( BOOST_USE_WINDOWS_H )
# include <windows.h>
#endif
namespace boost
{
namespace detail
{
#if !defined( BOOST_USE_WINDOWS_H )
extern "C" void __stdcall Sleep( unsigned ms );
#endif
inline void yield( unsigned k )
{
if( k < 4 )
{
}
#if defined( BOOST_SMT_PAUSE )
else if( k < 16 )
{
BOOST_SMT_PAUSE
}
#endif
else if( k < 32 )
{
Sleep( 0 );
}
else
{
Sleep( 1 );
}
}
} // namespace detail
} // namespace boost
#elif defined( BOOST_HAS_PTHREADS )
#include <sched.h>
#include <time.h>
namespace boost
{
namespace detail
{
inline void yield( unsigned k )
{
if( k < 4 )
{
}
#if defined( BOOST_SMT_PAUSE )
else if( k < 16 )
{
BOOST_SMT_PAUSE
}
#endif
else if( k < 32 || k & 1 )
{
sched_yield();
}
else
{
// g++ -Wextra warns on {} or {0}
struct timespec rqtp = { 0, 0 };
// POSIX says that timespec has tv_sec and tv_nsec
// But it doesn't guarantee order or placement
rqtp.tv_sec = 0;
rqtp.tv_nsec = 1000;
nanosleep( &rqtp, 0 );
}
}
} // namespace detail
} // namespace boost
#else
namespace boost
{
namespace detail
{
inline void yield( unsigned )
{
}
} // namespace detail
} // namespace boost
#endif
#endif // #ifndef BOOST_SMART_PTR_DETAIL_YIELD_K_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_ENABLE_SHARED_FROM_THIS_HPP_INCLUDED
#define BOOST_SMART_PTR_ENABLE_SHARED_FROM_THIS_HPP_INCLUDED
//
// enable_shared_from_this.hpp
//
// Copyright 2002, 2009 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
//
// http://www.boost.org/libs/smart_ptr/enable_shared_from_this.html
//
#include <boost/smart_ptr/weak_ptr.hpp>
#include <boost/smart_ptr/shared_ptr.hpp>
#include <boost/assert.hpp>
#include <boost/config.hpp>
namespace boost
{
template<class T> class enable_shared_from_this
{
protected:
enable_shared_from_this()
{
}
enable_shared_from_this(enable_shared_from_this const &)
{
}
enable_shared_from_this & operator=(enable_shared_from_this const &)
{
return *this;
}
~enable_shared_from_this()
{
}
public:
shared_ptr<T> shared_from_this()
{
shared_ptr<T> p( weak_this_ );
BOOST_ASSERT( p.get() == this );
return p;
}
shared_ptr<T const> shared_from_this() const
{
shared_ptr<T const> p( weak_this_ );
BOOST_ASSERT( p.get() == this );
return p;
}
public: // actually private, but avoids compiler template friendship issues
// Note: invoked automatically by shared_ptr; do not call
template<class X, class Y> void _internal_accept_owner( shared_ptr<X> const * ppx, Y * py ) const
{
if( weak_this_.expired() )
{
weak_this_ = shared_ptr<T>( *ppx, py );
}
}
private:
mutable weak_ptr<T> weak_this_;
};
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_ENABLE_SHARED_FROM_THIS_HPP_INCLUDED

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#ifndef BOOST_ENABLE_SHARED_FROM_THIS2_HPP_INCLUDED
#define BOOST_ENABLE_SHARED_FROM_THIS2_HPP_INCLUDED
//
// enable_shared_from_this2.hpp
//
// Copyright 2002, 2009 Peter Dimov
// Copyright 2008 Frank Mori Hess
//
// 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/config.hpp>
#include <boost/shared_ptr.hpp>
#include <boost/assert.hpp>
#include <boost/detail/workaround.hpp>
namespace boost
{
namespace detail
{
class esft2_deleter_wrapper
{
private:
shared_ptr<void> deleter_;
public:
esft2_deleter_wrapper()
{
}
template< class T > void set_deleter( shared_ptr<T> const & deleter )
{
deleter_ = deleter;
}
template< class T> void operator()( T* )
{
BOOST_ASSERT( deleter_.use_count() <= 1 );
deleter_.reset();
}
};
} // namespace detail
template< class T > class enable_shared_from_this2
{
protected:
enable_shared_from_this2()
{
}
enable_shared_from_this2( enable_shared_from_this2 const & )
{
}
enable_shared_from_this2 & operator=( enable_shared_from_this2 const & )
{
return *this;
}
~enable_shared_from_this2()
{
BOOST_ASSERT( shared_this_.use_count() <= 1 ); // make sure no dangling shared_ptr objects exist
}
private:
mutable weak_ptr<T> weak_this_;
mutable shared_ptr<T> shared_this_;
public:
shared_ptr<T> shared_from_this()
{
init_weak_once();
return shared_ptr<T>( weak_this_ );
}
shared_ptr<T const> shared_from_this() const
{
init_weak_once();
return shared_ptr<T>( weak_this_ );
}
private:
void init_weak_once() const
{
if( weak_this_._empty() )
{
shared_this_.reset( static_cast< T* >( 0 ), detail::esft2_deleter_wrapper() );
weak_this_ = shared_this_;
}
}
public: // actually private, but avoids compiler template friendship issues
// Note: invoked automatically by shared_ptr; do not call
template<class X, class Y> void _internal_accept_owner( shared_ptr<X> * ppx, Y * py ) const
{
BOOST_ASSERT( ppx != 0 );
if( weak_this_.use_count() == 0 )
{
weak_this_ = shared_ptr<T>( *ppx, py );
}
else if( shared_this_.use_count() != 0 )
{
BOOST_ASSERT( ppx->unique() ); // no weak_ptrs should exist either, but there's no way to check that
detail::esft2_deleter_wrapper * pd = boost::get_deleter<detail::esft2_deleter_wrapper>( shared_this_ );
BOOST_ASSERT( pd != 0 );
pd->set_deleter( *ppx );
ppx->reset( shared_this_, ppx->get() );
shared_this_.reset();
}
}
};
} // namespace boost
#endif // #ifndef BOOST_ENABLE_SHARED_FROM_THIS2_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_INTRUSIVE_PTR_HPP_INCLUDED
#define BOOST_SMART_PTR_INTRUSIVE_PTR_HPP_INCLUDED
//
// intrusive_ptr.hpp
//
// Copyright (c) 2001, 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)
//
// See http://www.boost.org/libs/smart_ptr/intrusive_ptr.html for documentation.
//
#include <boost/config.hpp>
#ifdef BOOST_MSVC // moved here to work around VC++ compiler crash
# pragma warning(push)
# pragma warning(disable:4284) // odd return type for operator->
#endif
#include <boost/assert.hpp>
#include <boost/detail/workaround.hpp>
#include <boost/smart_ptr/detail/sp_convertible.hpp>
#include <boost/config/no_tr1/functional.hpp> // for std::less
#if !defined(BOOST_NO_IOSTREAM)
#if !defined(BOOST_NO_IOSFWD)
#include <iosfwd> // for std::basic_ostream
#else
#include <ostream>
#endif
#endif
namespace boost
{
//
// intrusive_ptr
//
// A smart pointer that uses intrusive reference counting.
//
// Relies on unqualified calls to
//
// void intrusive_ptr_add_ref(T * p);
// void intrusive_ptr_release(T * p);
//
// (p != 0)
//
// The object is responsible for destroying itself.
//
template<class T> class intrusive_ptr
{
private:
typedef intrusive_ptr this_type;
public:
typedef T element_type;
intrusive_ptr(): px( 0 )
{
}
intrusive_ptr( T * p, bool add_ref = true ): px( p )
{
if( px != 0 && add_ref ) intrusive_ptr_add_ref( px );
}
#if !defined(BOOST_NO_MEMBER_TEMPLATES) || defined(BOOST_MSVC6_MEMBER_TEMPLATES)
template<class U>
#if !defined( BOOST_SP_NO_SP_CONVERTIBLE )
intrusive_ptr( intrusive_ptr<U> const & rhs, typename detail::sp_enable_if_convertible<U,T>::type = detail::sp_empty() )
#else
intrusive_ptr( intrusive_ptr<U> const & rhs )
#endif
: px( rhs.get() )
{
if( px != 0 ) intrusive_ptr_add_ref( px );
}
#endif
intrusive_ptr(intrusive_ptr const & rhs): px( rhs.px )
{
if( px != 0 ) intrusive_ptr_add_ref( px );
}
~intrusive_ptr()
{
if( px != 0 ) intrusive_ptr_release( px );
}
#if !defined(BOOST_NO_MEMBER_TEMPLATES) || defined(BOOST_MSVC6_MEMBER_TEMPLATES)
template<class U> intrusive_ptr & operator=(intrusive_ptr<U> const & rhs)
{
this_type(rhs).swap(*this);
return *this;
}
#endif
// Move support
#if defined( BOOST_HAS_RVALUE_REFS )
intrusive_ptr(intrusive_ptr && rhs): px( rhs.px )
{
rhs.px = 0;
}
intrusive_ptr & operator=(intrusive_ptr && rhs)
{
this_type(std::move(rhs)).swap(*this);
return *this;
}
#endif
intrusive_ptr & operator=(intrusive_ptr const & rhs)
{
this_type(rhs).swap(*this);
return *this;
}
intrusive_ptr & operator=(T * rhs)
{
this_type(rhs).swap(*this);
return *this;
}
void reset()
{
this_type().swap( *this );
}
void reset( T * rhs )
{
this_type( rhs ).swap( *this );
}
T * get() const
{
return px;
}
T & operator*() const
{
BOOST_ASSERT( px != 0 );
return *px;
}
T * operator->() const
{
BOOST_ASSERT( px != 0 );
return px;
}
// implicit conversion to "bool"
#include <boost/smart_ptr/detail/operator_bool.hpp>
void swap(intrusive_ptr & rhs)
{
T * tmp = px;
px = rhs.px;
rhs.px = tmp;
}
private:
T * px;
};
template<class T, class U> inline bool operator==(intrusive_ptr<T> const & a, intrusive_ptr<U> const & b)
{
return a.get() == b.get();
}
template<class T, class U> inline bool operator!=(intrusive_ptr<T> const & a, intrusive_ptr<U> const & b)
{
return a.get() != b.get();
}
template<class T, class U> inline bool operator==(intrusive_ptr<T> const & a, U * b)
{
return a.get() == b;
}
template<class T, class U> inline bool operator!=(intrusive_ptr<T> const & a, U * b)
{
return a.get() != b;
}
template<class T, class U> inline bool operator==(T * a, intrusive_ptr<U> const & b)
{
return a == b.get();
}
template<class T, class U> inline bool operator!=(T * a, intrusive_ptr<U> const & b)
{
return a != b.get();
}
#if __GNUC__ == 2 && __GNUC_MINOR__ <= 96
// Resolve the ambiguity between our op!= and the one in rel_ops
template<class T> inline bool operator!=(intrusive_ptr<T> const & a, intrusive_ptr<T> const & b)
{
return a.get() != b.get();
}
#endif
template<class T> inline bool operator<(intrusive_ptr<T> const & a, intrusive_ptr<T> const & b)
{
return std::less<T *>()(a.get(), b.get());
}
template<class T> void swap(intrusive_ptr<T> & lhs, intrusive_ptr<T> & rhs)
{
lhs.swap(rhs);
}
// mem_fn support
template<class T> T * get_pointer(intrusive_ptr<T> const & p)
{
return p.get();
}
template<class T, class U> intrusive_ptr<T> static_pointer_cast(intrusive_ptr<U> const & p)
{
return static_cast<T *>(p.get());
}
template<class T, class U> intrusive_ptr<T> const_pointer_cast(intrusive_ptr<U> const & p)
{
return const_cast<T *>(p.get());
}
template<class T, class U> intrusive_ptr<T> dynamic_pointer_cast(intrusive_ptr<U> const & p)
{
return dynamic_cast<T *>(p.get());
}
// operator<<
#if !defined(BOOST_NO_IOSTREAM)
#if defined(BOOST_NO_TEMPLATED_IOSTREAMS) || ( defined(__GNUC__) && (__GNUC__ < 3) )
template<class Y> std::ostream & operator<< (std::ostream & os, intrusive_ptr<Y> const & p)
{
os << p.get();
return os;
}
#else
// in STLport's no-iostreams mode no iostream symbols can be used
#ifndef _STLP_NO_IOSTREAMS
# if defined(BOOST_MSVC) && BOOST_WORKAROUND(BOOST_MSVC, < 1300 && __SGI_STL_PORT)
// MSVC6 has problems finding std::basic_ostream through the using declaration in namespace _STL
using std::basic_ostream;
template<class E, class T, class Y> basic_ostream<E, T> & operator<< (basic_ostream<E, T> & os, intrusive_ptr<Y> const & p)
# else
template<class E, class T, class Y> std::basic_ostream<E, T> & operator<< (std::basic_ostream<E, T> & os, intrusive_ptr<Y> const & p)
# endif
{
os << p.get();
return os;
}
#endif // _STLP_NO_IOSTREAMS
#endif // __GNUC__ < 3
#endif // !defined(BOOST_NO_IOSTREAM)
} // namespace boost
#ifdef BOOST_MSVC
# pragma warning(pop)
#endif
#endif // #ifndef BOOST_SMART_PTR_INTRUSIVE_PTR_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_MAKE_SHARED_HPP_INCLUDED
#define BOOST_SMART_PTR_MAKE_SHARED_HPP_INCLUDED
// make_shared.hpp
//
// Copyright (c) 2007, 2008 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
//
// See http://www.boost.org/libs/smart_ptr/make_shared.html
// for documentation.
#include <boost/config.hpp>
#include <boost/smart_ptr/shared_ptr.hpp>
#include <boost/type_traits/type_with_alignment.hpp>
#include <boost/type_traits/alignment_of.hpp>
#include <cstddef>
#include <new>
namespace boost
{
namespace detail
{
template< std::size_t N, std::size_t A > struct sp_aligned_storage
{
union type
{
char data_[ N ];
typename boost::type_with_alignment< A >::type align_;
};
};
template< class T > class sp_ms_deleter
{
private:
typedef typename sp_aligned_storage< sizeof( T ), ::boost::alignment_of< T >::value >::type storage_type;
bool initialized_;
storage_type storage_;
private:
void destroy()
{
if( initialized_ )
{
reinterpret_cast< T* >( storage_.data_ )->~T();
initialized_ = false;
}
}
public:
sp_ms_deleter(): initialized_( false )
{
}
// optimization: do not copy storage_
sp_ms_deleter( sp_ms_deleter const & ): initialized_( false )
{
}
~sp_ms_deleter()
{
destroy();
}
void operator()( T * )
{
destroy();
}
void * address()
{
return storage_.data_;
}
void set_initialized()
{
initialized_ = true;
}
};
template< class T > T forward( T t )
{
return t;
}
} // namespace detail
// Zero-argument versions
//
// Used even when variadic templates are available because of the new T() vs new T issue
template< class T > boost::shared_ptr< T > make_shared()
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >() );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T();
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A > boost::shared_ptr< T > allocate_shared( A const & a )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >(), a );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T();
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
#if defined( BOOST_HAS_VARIADIC_TMPL ) && defined( BOOST_HAS_RVALUE_REFS )
// Variadic templates, rvalue reference
template< class T, class... Args > boost::shared_ptr< T > make_shared( Args && ... args )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >() );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( detail::forward<Args>( args )... );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A, class... Args > boost::shared_ptr< T > allocate_shared( A const & a, Args && ... args )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >(), a );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( detail::forward<Args>( args )... );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
#else
// C++03 version
template< class T, class A1 >
boost::shared_ptr< T > make_shared( A1 const & a1 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >() );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A, class A1 >
boost::shared_ptr< T > allocate_shared( A const & a, A1 const & a1 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >(), a );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A1, class A2 >
boost::shared_ptr< T > make_shared( A1 const & a1, A2 const & a2 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >() );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A, class A1, class A2 >
boost::shared_ptr< T > allocate_shared( A const & a, A1 const & a1, A2 const & a2 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >(), a );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A1, class A2, class A3 >
boost::shared_ptr< T > make_shared( A1 const & a1, A2 const & a2, A3 const & a3 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >() );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A, class A1, class A2, class A3 >
boost::shared_ptr< T > allocate_shared( A const & a, A1 const & a1, A2 const & a2, A3 const & a3 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >(), a );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A1, class A2, class A3, class A4 >
boost::shared_ptr< T > make_shared( A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >() );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A, class A1, class A2, class A3, class A4 >
boost::shared_ptr< T > allocate_shared( A const & a, A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >(), a );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A1, class A2, class A3, class A4, class A5 >
boost::shared_ptr< T > make_shared( A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4, A5 const & a5 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >() );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4, a5 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A, class A1, class A2, class A3, class A4, class A5 >
boost::shared_ptr< T > allocate_shared( A const & a, A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4, A5 const & a5 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >(), a );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4, a5 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A1, class A2, class A3, class A4, class A5, class A6 >
boost::shared_ptr< T > make_shared( A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4, A5 const & a5, A6 const & a6 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >() );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4, a5, a6 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A, class A1, class A2, class A3, class A4, class A5, class A6 >
boost::shared_ptr< T > allocate_shared( A const & a, A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4, A5 const & a5, A6 const & a6 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >(), a );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4, a5, a6 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A1, class A2, class A3, class A4, class A5, class A6, class A7 >
boost::shared_ptr< T > make_shared( A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4, A5 const & a5, A6 const & a6, A7 const & a7 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >() );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4, a5, a6, a7 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A, class A1, class A2, class A3, class A4, class A5, class A6, class A7 >
boost::shared_ptr< T > allocate_shared( A const & a, A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4, A5 const & a5, A6 const & a6, A7 const & a7 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >(), a );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4, a5, a6, a7 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8 >
boost::shared_ptr< T > make_shared( A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4, A5 const & a5, A6 const & a6, A7 const & a7, A8 const & a8 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >() );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4, a5, a6, a7, a8 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8 >
boost::shared_ptr< T > allocate_shared( A const & a, A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4, A5 const & a5, A6 const & a6, A7 const & a7, A8 const & a8 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >(), a );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4, a5, a6, a7, a8 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9 >
boost::shared_ptr< T > make_shared( A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4, A5 const & a5, A6 const & a6, A7 const & a7, A8 const & a8, A9 const & a9 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >() );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4, a5, a6, a7, a8, a9 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
template< class T, class A, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9 >
boost::shared_ptr< T > allocate_shared( A const & a, A1 const & a1, A2 const & a2, A3 const & a3, A4 const & a4, A5 const & a5, A6 const & a6, A7 const & a7, A8 const & a8, A9 const & a9 )
{
boost::shared_ptr< T > pt( static_cast< T* >( 0 ), detail::sp_ms_deleter< T >(), a );
detail::sp_ms_deleter< T > * pd = boost::get_deleter< detail::sp_ms_deleter< T > >( pt );
void * pv = pd->address();
::new( pv ) T( a1, a2, a3, a4, a5, a6, a7, a8, a9 );
pd->set_initialized();
T * pt2 = static_cast< T* >( pv );
boost::detail::sp_enable_shared_from_this( &pt, pt2, pt2 );
return boost::shared_ptr< T >( pt, pt2 );
}
#endif
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_MAKE_SHARED_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_SCOPED_ARRAY_HPP_INCLUDED
#define BOOST_SMART_PTR_SCOPED_ARRAY_HPP_INCLUDED
// (C) Copyright Greg Colvin and Beman Dawes 1998, 1999.
// Copyright (c) 2001, 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)
//
// http://www.boost.org/libs/smart_ptr/scoped_array.htm
//
#include <boost/assert.hpp>
#include <boost/checked_delete.hpp>
#include <boost/config.hpp> // in case ptrdiff_t not in std
#include <boost/detail/workaround.hpp>
#include <cstddef> // for std::ptrdiff_t
namespace boost
{
// Debug hooks
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
void sp_array_constructor_hook(void * p);
void sp_array_destructor_hook(void * p);
#endif
// scoped_array extends scoped_ptr to arrays. Deletion of the array pointed to
// is guaranteed, either on destruction of the scoped_array or via an explicit
// reset(). Use shared_array or std::vector if your needs are more complex.
template<class T> class scoped_array // noncopyable
{
private:
T * px;
scoped_array(scoped_array const &);
scoped_array & operator=(scoped_array const &);
typedef scoped_array<T> this_type;
void operator==( scoped_array const& ) const;
void operator!=( scoped_array const& ) const;
public:
typedef T element_type;
explicit scoped_array( T * p = 0 ) : px( p ) // never throws
{
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
boost::sp_array_constructor_hook( px );
#endif
}
~scoped_array() // never throws
{
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
boost::sp_array_destructor_hook( px );
#endif
boost::checked_array_delete( px );
}
void reset(T * p = 0) // never throws
{
BOOST_ASSERT( p == 0 || p != px ); // catch self-reset errors
this_type(p).swap(*this);
}
T & operator[](std::ptrdiff_t i) const // never throws
{
BOOST_ASSERT( px != 0 );
BOOST_ASSERT( i >= 0 );
return px[i];
}
T * get() const // never throws
{
return px;
}
// implicit conversion to "bool"
#include <boost/smart_ptr/detail/operator_bool.hpp>
void swap(scoped_array & b) // never throws
{
T * tmp = b.px;
b.px = px;
px = tmp;
}
};
template<class T> inline void swap(scoped_array<T> & a, scoped_array<T> & b) // never throws
{
a.swap(b);
}
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_SCOPED_ARRAY_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_SCOPED_PTR_HPP_INCLUDED
#define BOOST_SMART_PTR_SCOPED_PTR_HPP_INCLUDED
// (C) Copyright Greg Colvin and Beman Dawes 1998, 1999.
// Copyright (c) 2001, 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)
//
// http://www.boost.org/libs/smart_ptr/scoped_ptr.htm
//
#include <boost/assert.hpp>
#include <boost/checked_delete.hpp>
#include <boost/detail/workaround.hpp>
#ifndef BOOST_NO_AUTO_PTR
# include <memory> // for std::auto_ptr
#endif
namespace boost
{
// Debug hooks
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
void sp_scalar_constructor_hook(void * p);
void sp_scalar_destructor_hook(void * p);
#endif
// scoped_ptr mimics a built-in pointer except that it guarantees deletion
// of the object pointed to, either on destruction of the scoped_ptr or via
// an explicit reset(). scoped_ptr is a simple solution for simple needs;
// use shared_ptr or std::auto_ptr if your needs are more complex.
template<class T> class scoped_ptr // noncopyable
{
private:
T * px;
scoped_ptr(scoped_ptr const &);
scoped_ptr & operator=(scoped_ptr const &);
typedef scoped_ptr<T> this_type;
void operator==( scoped_ptr const& ) const;
void operator!=( scoped_ptr const& ) const;
public:
typedef T element_type;
explicit scoped_ptr( T * p = 0 ): px( p ) // never throws
{
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
boost::sp_scalar_constructor_hook( px );
#endif
}
#ifndef BOOST_NO_AUTO_PTR
explicit scoped_ptr( std::auto_ptr<T> p ): px( p.release() ) // never throws
{
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
boost::sp_scalar_constructor_hook( px );
#endif
}
#endif
~scoped_ptr() // never throws
{
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
boost::sp_scalar_destructor_hook( px );
#endif
boost::checked_delete( px );
}
void reset(T * p = 0) // never throws
{
BOOST_ASSERT( p == 0 || p != px ); // catch self-reset errors
this_type(p).swap(*this);
}
T & operator*() const // never throws
{
BOOST_ASSERT( px != 0 );
return *px;
}
T * operator->() const // never throws
{
BOOST_ASSERT( px != 0 );
return px;
}
T * get() const // never throws
{
return px;
}
// implicit conversion to "bool"
#include <boost/smart_ptr/detail/operator_bool.hpp>
void swap(scoped_ptr & b) // never throws
{
T * tmp = b.px;
b.px = px;
px = tmp;
}
};
template<class T> inline void swap(scoped_ptr<T> & a, scoped_ptr<T> & b) // never throws
{
a.swap(b);
}
// get_pointer(p) is a generic way to say p.get()
template<class T> inline T * get_pointer(scoped_ptr<T> const & p)
{
return p.get();
}
} // namespace boost
#endif // #ifndef BOOST_SMART_PTR_SCOPED_PTR_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_SHARED_ARRAY_HPP_INCLUDED
#define BOOST_SMART_PTR_SHARED_ARRAY_HPP_INCLUDED
//
// shared_array.hpp
//
// (C) Copyright Greg Colvin and Beman Dawes 1998, 1999.
// Copyright (c) 2001, 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)
//
// See http://www.boost.org/libs/smart_ptr/shared_array.htm for documentation.
//
#include <boost/config.hpp> // for broken compiler workarounds
#if defined(BOOST_NO_MEMBER_TEMPLATES) && !defined(BOOST_MSVC6_MEMBER_TEMPLATES)
#include <boost/smart_ptr/detail/shared_array_nmt.hpp>
#else
#include <memory> // TR1 cyclic inclusion fix
#include <boost/assert.hpp>
#include <boost/checked_delete.hpp>
#include <boost/smart_ptr/detail/shared_count.hpp>
#include <boost/detail/workaround.hpp>
#include <cstddef> // for std::ptrdiff_t
#include <algorithm> // for std::swap
#include <functional> // for std::less
namespace boost
{
//
// shared_array
//
// shared_array extends shared_ptr to arrays.
// The array pointed to is deleted when the last shared_array pointing to it
// is destroyed or reset.
//
template<class T> class shared_array
{
private:
// Borland 5.5.1 specific workarounds
typedef checked_array_deleter<T> deleter;
typedef shared_array<T> this_type;
public:
typedef T element_type;
explicit shared_array(T * p = 0): px(p), pn(p, deleter())
{
}
//
// Requirements: D's copy constructor must not throw
//
// shared_array will release p by calling d(p)
//
template<class D> shared_array(T * p, D d): px(p), pn(p, d)
{
}
// generated copy constructor, assignment, destructor are fine
void reset(T * p = 0)
{
BOOST_ASSERT(p == 0 || p != px);
this_type(p).swap(*this);
}
template <class D> void reset(T * p, D d)
{
this_type(p, d).swap(*this);
}
T & operator[] (std::ptrdiff_t i) const // never throws
{
BOOST_ASSERT(px != 0);
BOOST_ASSERT(i >= 0);
return px[i];
}
T * get() const // never throws
{
return px;
}
// implicit conversion to "bool"
#include <boost/smart_ptr/detail/operator_bool.hpp>
bool unique() const // never throws
{
return pn.unique();
}
long use_count() const // never throws
{
return pn.use_count();
}
void swap(shared_array<T> & other) // never throws
{
std::swap(px, other.px);
pn.swap(other.pn);
}
private:
T * px; // contained pointer
detail::shared_count pn; // reference counter
}; // shared_array
template<class T> inline bool operator==(shared_array<T> const & a, shared_array<T> const & b) // never throws
{
return a.get() == b.get();
}
template<class T> inline bool operator!=(shared_array<T> const & a, shared_array<T> const & b) // never throws
{
return a.get() != b.get();
}
template<class T> inline bool operator<(shared_array<T> const & a, shared_array<T> const & b) // never throws
{
return std::less<T*>()(a.get(), b.get());
}
template<class T> void swap(shared_array<T> & a, shared_array<T> & b) // never throws
{
a.swap(b);
}
} // namespace boost
#endif // #if defined(BOOST_NO_MEMBER_TEMPLATES) && !defined(BOOST_MSVC6_MEMBER_TEMPLATES)
#endif // #ifndef BOOST_SMART_PTR_SHARED_ARRAY_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_SHARED_PTR_HPP_INCLUDED
#define BOOST_SMART_PTR_SHARED_PTR_HPP_INCLUDED
//
// shared_ptr.hpp
//
// (C) Copyright Greg Colvin and Beman Dawes 1998, 1999.
// Copyright (c) 2001-2008 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)
//
// See http://www.boost.org/libs/smart_ptr/shared_ptr.htm for documentation.
//
#include <boost/config.hpp> // for broken compiler workarounds
#if defined(BOOST_NO_MEMBER_TEMPLATES) && !defined(BOOST_MSVC6_MEMBER_TEMPLATES)
#include <boost/smart_ptr/detail/shared_ptr_nmt.hpp>
#else
// In order to avoid circular dependencies with Boost.TR1
// we make sure that our include of <memory> doesn't try to
// pull in the TR1 headers: that's why we use this header
// rather than including <memory> directly:
#include <boost/config/no_tr1/memory.hpp> // std::auto_ptr
#include <boost/assert.hpp>
#include <boost/checked_delete.hpp>
#include <boost/throw_exception.hpp>
#include <boost/smart_ptr/detail/shared_count.hpp>
#include <boost/detail/workaround.hpp>
#include <boost/smart_ptr/detail/sp_convertible.hpp>
#if !defined(BOOST_SP_NO_ATOMIC_ACCESS)
#include <boost/smart_ptr/detail/spinlock_pool.hpp>
#include <boost/memory_order.hpp>
#endif
#include <algorithm> // for std::swap
#include <functional> // for std::less
#include <typeinfo> // for std::bad_cast
#if !defined(BOOST_NO_IOSTREAM)
#if !defined(BOOST_NO_IOSFWD)
#include <iosfwd> // for std::basic_ostream
#else
#include <ostream>
#endif
#endif
#ifdef BOOST_MSVC // moved here to work around VC++ compiler crash
# pragma warning(push)
# pragma warning(disable:4284) // odd return type for operator->
#endif
namespace boost
{
template<class T> class shared_ptr;
template<class T> class weak_ptr;
template<class T> class enable_shared_from_this;
template<class T> class enable_shared_from_this2;
namespace detail
{
struct static_cast_tag {};
struct const_cast_tag {};
struct dynamic_cast_tag {};
struct polymorphic_cast_tag {};
template<class T> struct shared_ptr_traits
{
typedef T & reference;
};
template<> struct shared_ptr_traits<void>
{
typedef void reference;
};
#if !defined(BOOST_NO_CV_VOID_SPECIALIZATIONS)
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;
};
#endif
// enable_shared_from_this support
template< class X, class Y, class T > inline void sp_enable_shared_from_this( boost::shared_ptr<X> const * ppx, Y const * py, boost::enable_shared_from_this< T > const * pe )
{
if( pe != 0 )
{
pe->_internal_accept_owner( ppx, const_cast< Y* >( py ) );
}
}
template< class X, class Y, class T > inline void sp_enable_shared_from_this( boost::shared_ptr<X> * ppx, Y const * py, boost::enable_shared_from_this2< T > const * pe )
{
if( pe != 0 )
{
pe->_internal_accept_owner( ppx, const_cast< Y* >( py ) );
}
}
#ifdef _MANAGED
// Avoid C4793, ... causes native code generation
struct sp_any_pointer
{
template<class T> sp_any_pointer( T* ) {}
};
inline void sp_enable_shared_from_this( sp_any_pointer, sp_any_pointer, sp_any_pointer )
{
}
#else // _MANAGED
inline void sp_enable_shared_from_this( ... )
{
}
#endif // _MANAGED
#if !defined( BOOST_NO_SFINAE ) && !defined( BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION ) && !defined( BOOST_NO_AUTO_PTR )
// rvalue auto_ptr support based on a technique by Dave Abrahams
template< class T, class R > struct sp_enable_if_auto_ptr
{
};
template< class T, class R > struct sp_enable_if_auto_ptr< std::auto_ptr< T >, R >
{
typedef R type;
};
#endif
} // namespace detail
//
// shared_ptr
//
// An enhanced relative of scoped_ptr with reference counted copy semantics.
// The object pointed to is deleted when the last shared_ptr pointing to it
// is destroyed or reset.
//
template<class T> class shared_ptr
{
private:
// Borland 5.5.1 specific workaround
typedef shared_ptr<T> this_type;
public:
typedef T element_type;
typedef T value_type;
typedef T * pointer;
typedef typename boost::detail::shared_ptr_traits<T>::reference reference;
shared_ptr(): px(0), pn() // never throws in 1.30+
{
}
template<class Y>
explicit shared_ptr( Y * p ): px( p ), pn( p ) // Y must be complete
{
boost::detail::sp_enable_shared_from_this( this, p, p );
}
//
// Requirements: D's copy constructor must not throw
//
// shared_ptr will release p by calling d(p)
//
template<class Y, class D> shared_ptr(Y * p, D d): px(p), pn(p, d)
{
boost::detail::sp_enable_shared_from_this( this, p, p );
}
// As above, but with allocator. A's copy constructor shall not throw.
template<class Y, class D, class A> shared_ptr( Y * p, D d, A a ): px( p ), pn( p, d, a )
{
boost::detail::sp_enable_shared_from_this( this, p, p );
}
// generated copy constructor, destructor are fine
template<class Y>
explicit shared_ptr(weak_ptr<Y> const & r): pn(r.pn) // may throw
{
// it is now safe to copy r.px, as pn(r.pn) did not throw
px = r.px;
}
template<class Y>
shared_ptr( weak_ptr<Y> const & r, boost::detail::sp_nothrow_tag ): px( 0 ), pn( r.pn, boost::detail::sp_nothrow_tag() ) // never throws
{
if( !pn.empty() )
{
px = r.px;
}
}
template<class Y>
#if !defined( BOOST_SP_NO_SP_CONVERTIBLE )
shared_ptr( shared_ptr<Y> const & r, typename detail::sp_enable_if_convertible<Y,T>::type = detail::sp_empty() )
#else
shared_ptr( shared_ptr<Y> const & r )
#endif
: px( r.px ), pn( r.pn ) // never throws
{
}
// aliasing
template< class Y >
shared_ptr( shared_ptr<Y> const & r, T * p ): px( p ), pn( r.pn ) // never throws
{
}
template<class Y>
shared_ptr(shared_ptr<Y> const & r, boost::detail::static_cast_tag): px(static_cast<element_type *>(r.px)), pn(r.pn)
{
}
template<class Y>
shared_ptr(shared_ptr<Y> const & r, boost::detail::const_cast_tag): px(const_cast<element_type *>(r.px)), pn(r.pn)
{
}
template<class Y>
shared_ptr(shared_ptr<Y> const & r, boost::detail::dynamic_cast_tag): px(dynamic_cast<element_type *>(r.px)), pn(r.pn)
{
if(px == 0) // need to allocate new counter -- the cast failed
{
pn = boost::detail::shared_count();
}
}
template<class Y>
shared_ptr(shared_ptr<Y> const & r, boost::detail::polymorphic_cast_tag): px(dynamic_cast<element_type *>(r.px)), pn(r.pn)
{
if(px == 0)
{
boost::throw_exception(std::bad_cast());
}
}
#ifndef BOOST_NO_AUTO_PTR
template<class Y>
explicit shared_ptr(std::auto_ptr<Y> & r): px(r.get()), pn()
{
Y * tmp = r.get();
pn = boost::detail::shared_count(r);
boost::detail::sp_enable_shared_from_this( this, tmp, tmp );
}
#if !defined( BOOST_NO_SFINAE ) && !defined( BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION )
template<class Ap>
explicit shared_ptr( Ap r, typename boost::detail::sp_enable_if_auto_ptr<Ap, int>::type = 0 ): px( r.get() ), pn()
{
typename Ap::element_type * tmp = r.get();
pn = boost::detail::shared_count( r );
boost::detail::sp_enable_shared_from_this( this, tmp, tmp );
}
#endif // BOOST_NO_SFINAE, BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
#endif // BOOST_NO_AUTO_PTR
// assignment
shared_ptr & operator=( shared_ptr const & r ) // never throws
{
this_type(r).swap(*this);
return *this;
}
#if !defined(BOOST_MSVC) || (BOOST_MSVC >= 1400)
template<class Y>
shared_ptr & operator=(shared_ptr<Y> const & r) // never throws
{
this_type(r).swap(*this);
return *this;
}
#endif
#ifndef BOOST_NO_AUTO_PTR
template<class Y>
shared_ptr & operator=( std::auto_ptr<Y> & r )
{
this_type(r).swap(*this);
return *this;
}
#if !defined( BOOST_NO_SFINAE ) && !defined( BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION )
template<class Ap>
typename boost::detail::sp_enable_if_auto_ptr< Ap, shared_ptr & >::type operator=( Ap r )
{
this_type( r ).swap( *this );
return *this;
}
#endif // BOOST_NO_SFINAE, BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
#endif // BOOST_NO_AUTO_PTR
// Move support
#if defined( BOOST_HAS_RVALUE_REFS )
shared_ptr( shared_ptr && r ): px( r.px ), pn() // never throws
{
pn.swap( r.pn );
r.px = 0;
}
template<class Y>
#if !defined( BOOST_SP_NO_SP_CONVERTIBLE )
shared_ptr( shared_ptr<Y> && r, typename detail::sp_enable_if_convertible<Y,T>::type = detail::sp_empty() )
#else
shared_ptr( shared_ptr<Y> && r )
#endif
: px( r.px ), pn() // never throws
{
pn.swap( r.pn );
r.px = 0;
}
shared_ptr & operator=( shared_ptr && r ) // never throws
{
this_type( std::move( r ) ).swap( *this );
return *this;
}
template<class Y>
shared_ptr & operator=( shared_ptr<Y> && r ) // never throws
{
this_type( std::move( r ) ).swap( *this );
return *this;
}
#endif
void reset() // never throws in 1.30+
{
this_type().swap(*this);
}
template<class Y> void reset(Y * p) // Y must be complete
{
BOOST_ASSERT(p == 0 || p != px); // catch self-reset errors
this_type(p).swap(*this);
}
template<class Y, class D> void reset( Y * p, D d )
{
this_type( p, d ).swap( *this );
}
template<class Y, class D, class A> void reset( Y * p, D d, A a )
{
this_type( p, d, a ).swap( *this );
}
template<class Y> void reset( shared_ptr<Y> const & r, T * p )
{
this_type( r, p ).swap( *this );
}
reference operator* () const // never throws
{
BOOST_ASSERT(px != 0);
return *px;
}
T * operator-> () const // never throws
{
BOOST_ASSERT(px != 0);
return px;
}
T * get() const // never throws
{
return px;
}
// implicit conversion to "bool"
#include <boost/smart_ptr/detail/operator_bool.hpp>
bool unique() const // never throws
{
return pn.unique();
}
long use_count() const // never throws
{
return pn.use_count();
}
void swap(shared_ptr<T> & other) // never throws
{
std::swap(px, other.px);
pn.swap(other.pn);
}
template<class Y> bool _internal_less(shared_ptr<Y> const & rhs) const
{
return pn < rhs.pn;
}
void * _internal_get_deleter( detail::sp_typeinfo const & ti ) const
{
return pn.get_deleter( ti );
}
bool _internal_equiv( shared_ptr const & r ) const
{
return px == r.px && pn == r.pn;
}
// Tasteless as this may seem, making all members public allows member templates
// to work in the absence of member template friends. (Matthew Langston)
#ifndef BOOST_NO_MEMBER_TEMPLATE_FRIENDS
private:
template<class Y> friend class shared_ptr;
template<class Y> friend class weak_ptr;
#endif
T * px; // contained pointer
boost::detail::shared_count pn; // reference counter
}; // shared_ptr
template<class T, class U> inline bool operator==(shared_ptr<T> const & a, shared_ptr<U> const & b)
{
return a.get() == b.get();
}
template<class T, class U> inline bool operator!=(shared_ptr<T> const & a, shared_ptr<U> const & b)
{
return a.get() != b.get();
}
#if __GNUC__ == 2 && __GNUC_MINOR__ <= 96
// Resolve the ambiguity between our op!= and the one in rel_ops
template<class T> inline bool operator!=(shared_ptr<T> const & a, shared_ptr<T> const & b)
{
return a.get() != b.get();
}
#endif
template<class T, class U> inline bool operator<(shared_ptr<T> const & a, shared_ptr<U> const & b)
{
return a._internal_less(b);
}
template<class T> inline void swap(shared_ptr<T> & a, shared_ptr<T> & b)
{
a.swap(b);
}
template<class T, class U> shared_ptr<T> static_pointer_cast(shared_ptr<U> const & r)
{
return shared_ptr<T>(r, boost::detail::static_cast_tag());
}
template<class T, class U> shared_ptr<T> const_pointer_cast(shared_ptr<U> const & r)
{
return shared_ptr<T>(r, boost::detail::const_cast_tag());
}
template<class T, class U> shared_ptr<T> dynamic_pointer_cast(shared_ptr<U> const & r)
{
return shared_ptr<T>(r, boost::detail::dynamic_cast_tag());
}
// shared_*_cast names are deprecated. Use *_pointer_cast instead.
template<class T, class U> shared_ptr<T> shared_static_cast(shared_ptr<U> const & r)
{
return shared_ptr<T>(r, boost::detail::static_cast_tag());
}
template<class T, class U> shared_ptr<T> shared_dynamic_cast(shared_ptr<U> const & r)
{
return shared_ptr<T>(r, boost::detail::dynamic_cast_tag());
}
template<class T, class U> shared_ptr<T> shared_polymorphic_cast(shared_ptr<U> const & r)
{
return shared_ptr<T>(r, boost::detail::polymorphic_cast_tag());
}
template<class T, class U> shared_ptr<T> shared_polymorphic_downcast(shared_ptr<U> const & r)
{
BOOST_ASSERT(dynamic_cast<T *>(r.get()) == r.get());
return shared_static_cast<T>(r);
}
// get_pointer() enables boost::mem_fn to recognize shared_ptr
template<class T> inline T * get_pointer(shared_ptr<T> const & p)
{
return p.get();
}
// operator<<
#if !defined(BOOST_NO_IOSTREAM)
#if defined(BOOST_NO_TEMPLATED_IOSTREAMS) || ( defined(__GNUC__) && (__GNUC__ < 3) )
template<class Y> std::ostream & operator<< (std::ostream & os, shared_ptr<Y> const & p)
{
os << p.get();
return os;
}
#else
// in STLport's no-iostreams mode no iostream symbols can be used
#ifndef _STLP_NO_IOSTREAMS
# if defined(BOOST_MSVC) && BOOST_WORKAROUND(BOOST_MSVC, < 1300 && __SGI_STL_PORT)
// MSVC6 has problems finding std::basic_ostream through the using declaration in namespace _STL
using std::basic_ostream;
template<class E, class T, class Y> basic_ostream<E, T> & operator<< (basic_ostream<E, T> & os, shared_ptr<Y> const & p)
# else
template<class E, class T, class Y> std::basic_ostream<E, T> & operator<< (std::basic_ostream<E, T> & os, shared_ptr<Y> const & p)
# endif
{
os << p.get();
return os;
}
#endif // _STLP_NO_IOSTREAMS
#endif // __GNUC__ < 3
#endif // !defined(BOOST_NO_IOSTREAM)
// get_deleter
#if ( defined(__GNUC__) && BOOST_WORKAROUND(__GNUC__, < 3) ) || \
( defined(__EDG_VERSION__) && BOOST_WORKAROUND(__EDG_VERSION__, <= 238) ) || \
( defined(__HP_aCC) && BOOST_WORKAROUND(__HP_aCC, <= 33500) )
// g++ 2.9x doesn't allow static_cast<X const *>(void *)
// apparently EDG 2.38 and HP aCC A.03.35 also don't accept it
template<class D, class T> D * get_deleter(shared_ptr<T> const & p)
{
void const * q = p._internal_get_deleter(BOOST_SP_TYPEID(D));
return const_cast<D *>(static_cast<D const *>(q));
}
#else
template<class D, class T> D * get_deleter(shared_ptr<T> const & p)
{
return static_cast<D *>(p._internal_get_deleter(BOOST_SP_TYPEID(D)));
}
#endif
// atomic access
#if !defined(BOOST_SP_NO_ATOMIC_ACCESS)
template<class T> inline bool atomic_is_lock_free( shared_ptr<T> const * /*p*/ )
{
return false;
}
template<class T> shared_ptr<T> atomic_load( shared_ptr<T> const * p )
{
boost::detail::spinlock_pool<2>::scoped_lock lock( p );
return *p;
}
template<class T> inline shared_ptr<T> atomic_load_explicit( shared_ptr<T> const * p, memory_order /*mo*/ )
{
return atomic_load( p );
}
template<class T> void atomic_store( shared_ptr<T> * p, shared_ptr<T> r )
{
boost::detail::spinlock_pool<2>::scoped_lock lock( p );
p->swap( r );
}
template<class T> inline void atomic_store_explicit( shared_ptr<T> * p, shared_ptr<T> r, memory_order /*mo*/ )
{
atomic_store( p, r ); // std::move( r )
}
template<class T> shared_ptr<T> atomic_exchange( shared_ptr<T> * p, shared_ptr<T> r )
{
boost::detail::spinlock & sp = boost::detail::spinlock_pool<2>::spinlock_for( p );
sp.lock();
p->swap( r );
sp.unlock();
return r; // return std::move( r )
}
template<class T> shared_ptr<T> atomic_exchange_explicit( shared_ptr<T> * p, shared_ptr<T> r, memory_order /*mo*/ )
{
return atomic_exchange( p, r ); // std::move( r )
}
template<class T> bool atomic_compare_exchange( shared_ptr<T> * p, shared_ptr<T> * v, shared_ptr<T> w )
{
boost::detail::spinlock & sp = boost::detail::spinlock_pool<2>::spinlock_for( p );
sp.lock();
if( p->_internal_equiv( *v ) )
{
p->swap( w );
sp.unlock();
return true;
}
else
{
shared_ptr<T> tmp( *p );
sp.unlock();
tmp.swap( *v );
return false;
}
}
template<class T> inline bool atomic_compare_exchange_explicit( shared_ptr<T> * p, shared_ptr<T> * v, shared_ptr<T> w, memory_order /*success*/, memory_order /*failure*/ )
{
return atomic_compare_exchange( p, v, w ); // std::move( w )
}
#endif
} // namespace boost
#ifdef BOOST_MSVC
# pragma warning(pop)
#endif
#endif // #if defined(BOOST_NO_MEMBER_TEMPLATES) && !defined(BOOST_MSVC6_MEMBER_TEMPLATES)
#endif // #ifndef BOOST_SMART_PTR_SHARED_PTR_HPP_INCLUDED

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#ifndef BOOST_SMART_PTR_WEAK_PTR_HPP_INCLUDED
#define BOOST_SMART_PTR_WEAK_PTR_HPP_INCLUDED
//
// weak_ptr.hpp
//
// Copyright (c) 2001, 2002, 2003 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)
//
// See http://www.boost.org/libs/smart_ptr/weak_ptr.htm for documentation.
//
#include <memory> // boost.TR1 include order fix
#include <boost/smart_ptr/detail/shared_count.hpp>
#include <boost/smart_ptr/shared_ptr.hpp>
#ifdef BOOST_MSVC // moved here to work around VC++ compiler crash
# pragma warning(push)
# pragma warning(disable:4284) // odd return type for operator->
#endif
namespace boost
{
template<class T> class weak_ptr
{
private:
// Borland 5.5.1 specific workarounds
typedef weak_ptr<T> this_type;
public:
typedef T element_type;
weak_ptr(): px(0), pn() // never throws in 1.30+
{
}
// generated copy constructor, assignment, destructor are fine
//
// The "obvious" converting constructor implementation:
//
// template<class Y>
// weak_ptr(weak_ptr<Y> const & r): px(r.px), pn(r.pn) // never throws
// {
// }
//
// has a serious problem.
//
// r.px may already have been invalidated. The px(r.px)
// conversion may require access to *r.px (virtual inheritance).
//
// It is not possible to avoid spurious access violations since
// in multithreaded programs r.px may be invalidated at any point.
//
template<class Y>
#if !defined( BOOST_SP_NO_SP_CONVERTIBLE )
weak_ptr( weak_ptr<Y> const & r, typename detail::sp_enable_if_convertible<Y,T>::type = detail::sp_empty() )
#else
weak_ptr( weak_ptr<Y> const & r )
#endif
: px(r.lock().get()), pn(r.pn) // never throws
{
}
#if defined( BOOST_HAS_RVALUE_REFS )
template<class Y>
#if !defined( BOOST_SP_NO_SP_CONVERTIBLE )
weak_ptr( weak_ptr<Y> && r, typename detail::sp_enable_if_convertible<Y,T>::type = detail::sp_empty() )
#else
weak_ptr( weak_ptr<Y> && r )
#endif
: px(r.lock().get()), pn(std::move(r.pn)) // never throws
{
r.px = 0;
}
// for better efficiency in the T == Y case
weak_ptr( weak_ptr && r ): px( r.px ), pn(std::move(r.pn)) // never throws
{
r.px = 0;
}
// for better efficiency in the T == Y case
weak_ptr & operator=( weak_ptr && r ) // never throws
{
this_type( std::move( r ) ).swap( *this );
return *this;
}
#endif
template<class Y>
#if !defined( BOOST_SP_NO_SP_CONVERTIBLE )
weak_ptr( shared_ptr<Y> const & r, typename detail::sp_enable_if_convertible<Y,T>::type = detail::sp_empty() )
#else
weak_ptr( shared_ptr<Y> const & r )
#endif
: px( r.px ), pn( r.pn ) // never throws
{
}
#if !defined(BOOST_MSVC) || (BOOST_MSVC >= 1300)
template<class Y>
weak_ptr & operator=(weak_ptr<Y> const & r) // never throws
{
px = r.lock().get();
pn = r.pn;
return *this;
}
#if defined( BOOST_HAS_RVALUE_REFS )
template<class Y>
weak_ptr & operator=(weak_ptr<Y> && r)
{
this_type( std::move( r ) ).swap( *this );
return *this;
}
#endif
template<class Y>
weak_ptr & operator=(shared_ptr<Y> const & r) // never throws
{
px = r.px;
pn = r.pn;
return *this;
}
#endif
shared_ptr<T> lock() const // never throws
{
return shared_ptr<element_type>( *this, boost::detail::sp_nothrow_tag() );
}
long use_count() const // never throws
{
return pn.use_count();
}
bool expired() const // never throws
{
return pn.use_count() == 0;
}
bool _empty() const // extension, not in std::weak_ptr
{
return pn.empty();
}
void reset() // never throws in 1.30+
{
this_type().swap(*this);
}
void swap(this_type & other) // never throws
{
std::swap(px, other.px);
pn.swap(other.pn);
}
void _internal_assign(T * px2, boost::detail::shared_count const & pn2)
{
px = px2;
pn = pn2;
}
template<class Y> bool _internal_less(weak_ptr<Y> const & rhs) const
{
return pn < rhs.pn;
}
// Tasteless as this may seem, making all members public allows member templates
// to work in the absence of member template friends. (Matthew Langston)
#ifndef BOOST_NO_MEMBER_TEMPLATE_FRIENDS
private:
template<class Y> friend class weak_ptr;
template<class Y> friend class shared_ptr;
#endif
T * px; // contained pointer
boost::detail::weak_count pn; // reference counter
}; // weak_ptr
template<class T, class U> inline bool operator<(weak_ptr<T> const & a, weak_ptr<U> const & b)
{
return a._internal_less(b);
}
template<class T> void swap(weak_ptr<T> & a, weak_ptr<T> & b)
{
a.swap(b);
}
} // namespace boost
#ifdef BOOST_MSVC
# pragma warning(pop)
#endif
#endif // #ifndef BOOST_SMART_PTR_WEAK_PTR_HPP_INCLUDED

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#ifndef BOOST_WEAK_PTR_HPP_INCLUDED
#define BOOST_WEAK_PTR_HPP_INCLUDED
//
// weak_ptr.hpp
//
// Copyright (c) 2001, 2002, 2003 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
//
// See http://www.boost.org/libs/smart_ptr/weak_ptr.htm for documentation.
//
#include <boost/smart_ptr/weak_ptr.hpp>
#endif // #ifndef BOOST_WEAK_PTR_HPP_INCLUDED

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<html>
<head>
<title>intrusive_ptr</title>
<meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1">
</head>
<body text="#000000" bgColor="#ffffff">
<h1><A href="../../index.htm"><IMG height="86" alt="boost.png (6897 bytes)" src="../../boost.png" width="277" align="middle"
border="0"></A>intrusive_ptr class template</h1>
<p>
<A href="#Introduction">Introduction</A><br>
<A href="#Synopsis">Synopsis</A><br>
<A href="#Members">Members</A><br>
<A href="#functions">Free Functions</A><br>
</p>
<h2><a name="Introduction">Introduction</a></h2>
<p>The <b>intrusive_ptr</b> class template stores a pointer to an object with an
embedded reference count. Every new <b>intrusive_ptr</b> instance increments
the reference count by using an unqualified call to the function <STRONG>intrusive_ptr_add_ref</STRONG>,
passing it the pointer as an argument. Similarly, when an <STRONG>intrusive_ptr</STRONG>
is destroyed, it calls <STRONG>intrusive_ptr_release</STRONG>; this function is
responsible for destroying the object when its reference count drops to zero.
The user is expected to provide suitable definitions of these two functions. On
compilers that support argument-dependent lookup, <STRONG>intrusive_ptr_add_ref</STRONG>
and <STRONG>intrusive_ptr_release</STRONG> should be defined in the namespace
that corresponds to their parameter; otherwise, the definitions need to go in
namespace <STRONG>boost</STRONG>.</p>
<p>The class template is parameterized on <b>T</b>, the type of the object pointed
to. <STRONG>intrusive_ptr&lt;T&gt;</STRONG> can be implicitly converted to <STRONG>intrusive_ptr&lt;U&gt;</STRONG>
whenever <STRONG>T*</STRONG> can be implicitly converted to <STRONG>U*</STRONG>.</p>
<P>The main reasons to use <STRONG>intrusive_ptr</STRONG> are:</P>
<UL>
<LI>
Some existing frameworks or OSes provide objects with embedded reference
counts;
<LI>
The memory footprint of <STRONG>intrusive_ptr</STRONG>
is the same as the corresponding raw pointer;
<LI>
<STRONG>intrusive_ptr&lt;T&gt;</STRONG> can be constructed from an arbitrary
raw pointer of type <STRONG>T *</STRONG>.</LI></UL>
<P>As a general rule, if it isn't obvious whether <STRONG>intrusive_ptr</STRONG> better
fits your needs than <STRONG>shared_ptr</STRONG>, try a <STRONG>shared_ptr</STRONG>-based
design first.</P>
<h2><a name="Synopsis">Synopsis</a></h2>
<pre>namespace boost {
template&lt;class T&gt; class intrusive_ptr {
public:
typedef T <A href="#element_type" >element_type</A>;
<A href="#constructors" >intrusive_ptr</A>(); // never throws
<A href="#constructors" >intrusive_ptr</A>(T * p, bool add_ref = true);
<A href="#constructors" >intrusive_ptr</A>(intrusive_ptr const &amp; r);
template&lt;class Y&gt; <A href="#constructors" >intrusive_ptr</A>(intrusive_ptr&lt;Y&gt; const &amp; r);
<A href="#destructor" >~intrusive_ptr</A>();
intrusive_ptr &amp; <A href="#assignment" >operator=</A>(intrusive_ptr const &amp; r);
template&lt;class Y&gt; intrusive_ptr &amp; <A href="#assignment" >operator=</A>(intrusive_ptr&lt;Y&gt; const &amp; r);
intrusive_ptr &amp; <A href="#assignment" >operator=</A>(T * r);
void <a href="#reset" >reset</a>();
void <a href="#reset" >reset</a>(T * r);
T &amp; <A href="#indirection" >operator*</A>() const; // never throws
T * <A href="#indirection" >operator-&gt;</A>() const; // never throws
T * <A href="#get" >get</A>() const; // never throws
operator <A href="#conversions" ><i>unspecified-bool-type</i></A>() const; // never throws
void <A href="#swap" >swap</A>(intrusive_ptr &amp; b); // never throws
};
template&lt;class T, class U&gt;
bool <A href="#comparison" >operator==</A>(intrusive_ptr&lt;T&gt; const &amp; a, intrusive_ptr&lt;U&gt; const &amp; b); // never throws
template&lt;class T, class U&gt;
bool <A href="#comparison" >operator!=</A>(intrusive_ptr&lt;T&gt; const &amp; a, intrusive_ptr&lt;U&gt; const &amp; b); // never throws
template&lt;class T&gt;
bool <A href="#comparison" >operator==</A>(intrusive_ptr&lt;T&gt; const &amp; a, T * b); // never throws
template&lt;class T&gt;
bool <A href="#comparison" >operator!=</A>(intrusive_ptr&lt;T&gt; const &amp; a, T * b); // never throws
template&lt;class T&gt;
bool <A href="#comparison" >operator==</A>(T * a, intrusive_ptr&lt;T&gt; const &amp; b); // never throws
template&lt;class T&gt;
bool <A href="#comparison" >operator!=</A>(T * a, intrusive_ptr&lt;T&gt; const &amp; b); // never throws
template&lt;class T, class U&gt;
bool <A href="#comparison" >operator&lt;</A>(intrusive_ptr&lt;T&gt; const &amp; a, intrusive_ptr&lt;U&gt; const &amp; b); // never throws
template&lt;class T&gt; void <A href="#free-swap" >swap</A>(intrusive_ptr&lt;T&gt; &amp; a, intrusive_ptr&lt;T&gt; &amp; b); // never throws
template&lt;class T&gt; T * <A href="#get_pointer" >get_pointer</A>(intrusive_ptr&lt;T&gt; const &amp; p); // never throws
template&lt;class T, class U&gt;
intrusive_ptr&lt;T&gt; <A href="#static_pointer_cast" >static_pointer_cast</A>(intrusive_ptr&lt;U&gt; const &amp; r); // never throws
template&lt;class T, class U&gt;
intrusive_ptr&lt;T&gt; <A href="#const_pointer_cast" >const_pointer_cast</A>(intrusive_ptr&lt;U&gt; const &amp; r); // never throws
template&lt;class T, class U&gt;
intrusive_ptr&lt;T&gt; <A href="#dynamic_pointer_cast" >dynamic_pointer_cast</A>(intrusive_ptr&lt;U&gt; const &amp; r); // never throws
template&lt;class E, class T, class Y&gt;
std::basic_ostream&lt;E, T&gt; &amp; <A href="#insertion-operator" >operator&lt;&lt;</A> (std::basic_ostream&lt;E, T&gt; &amp; os, intrusive_ptr&lt;Y&gt; const &amp; p);
}</pre>
<h2><a name="Members">Members</a></h2>
<h3><a name="element_type">element_type</a></h3>
<pre>typedef T element_type;</pre>
<blockquote>
<p>Provides the type of the template parameter T.</p>
</blockquote>
<h3><a name="constructors">constructors</a></h3>
<pre>intrusive_ptr(); // never throws</pre>
<blockquote>
<p><b>Postconditions:</b> <code>get() == 0</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>intrusive_ptr(T * p, bool add_ref = true);</pre>
<blockquote>
<p><b>Effects:</b> <code>if(p != 0 &amp;&amp; add_ref) intrusive_ptr_add_ref(p);</code>.</p>
<p><b>Postconditions:</b> <code>get() == p</code>.</p>
</blockquote>
<pre>intrusive_ptr(intrusive_ptr const &amp; r);
template&lt;class Y&gt; intrusive_ptr(intrusive_ptr&lt;Y&gt; const &amp; r);</pre>
<blockquote>
<p><b>Effects:</b> <code>if(r.get() != 0) intrusive_ptr_add_ref(r.get());</code>.</p>
<p><b>Postconditions:</b> <code>get() == r.get()</code>.</p>
</blockquote>
<h3><a name="destructor">destructor</a></h3>
<pre>~intrusive_ptr();</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> <code>if(get() != 0) intrusive_ptr_release(get());</code>.</P>
</BLOCKQUOTE>
<H3><a name="assignment">assignment</a></H3>
<pre>intrusive_ptr &amp; operator=(intrusive_ptr const &amp; r);
template&lt;class Y&gt; intrusive_ptr &amp; operator=(intrusive_ptr&lt;Y&gt; const &amp; r);
intrusive_ptr &amp; operator=(T * r);</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Equivalent to <code>intrusive_ptr(r).swap(*this)</code>.</P>
<P><B>Returns:</B> <code>*this</code>.</P>
</BLOCKQUOTE>
<H3><a name="reset">reset</a></H3>
<pre>void reset();</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Equivalent to <code>intrusive_ptr().swap(*this)</code>.</P>
</BLOCKQUOTE>
<pre>void reset(T * r);</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Equivalent to <code>intrusive_ptr(r).swap(*this)</code>.</P>
</BLOCKQUOTE>
<h3><a name="indirection">indirection</a></h3>
<pre>T &amp; operator*() const; // never throws</pre>
<blockquote>
<p><b>Requirements:</b> <code>get() != 0</code>.</p>
<p><b>Returns:</b> <code>*get()</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>T * operator-&gt;() const; // never throws</pre>
<blockquote>
<p><b>Requirements:</b> <code>get() != 0</code>.</p>
<p><b>Returns:</b> <code>get()</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<h3><a name="get">get</a></h3>
<pre>T * get() const; // never throws</pre>
<blockquote>
<p><b>Returns:</b> the stored pointer.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<h3><a name="conversions">conversions</a></h3>
<pre>operator <i>unspecified-bool-type</i> () const; // never throws</pre>
<blockquote>
<p><b>Returns:</b> an unspecified value that, when used in boolean contexts, is
equivalent to <code>get() != 0</code>.</p>
<p><b>Throws:</b> nothing.</p>
<P><B>Notes:</B> This conversion operator allows <b>intrusive_ptr</b> objects to be
used in boolean contexts, like <code>if (p &amp;&amp; p-&gt;valid()) {}</code>.
The actual target type is typically a pointer to a member function, avoiding
many of the implicit conversion pitfalls.</P>
</blockquote>
<h3><a name="swap">swap</a></h3>
<pre>void swap(intrusive_ptr &amp; b); // never throws</pre>
<blockquote>
<p><b>Effects:</b> Exchanges the contents of the two smart pointers.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<h2><a name="functions">Free Functions</a></h2>
<h3><a name="comparison">comparison</a></h3>
<pre>template&lt;class T, class U&gt;
bool operator==(intrusive_ptr&lt;T&gt; const &amp; a, intrusive_ptr&lt;U&gt; const &amp; b); // never throws</pre>
<blockquote>
<p><b>Returns:</b> <code>a.get() == b.get()</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>template&lt;class T, class U&gt;
bool operator!=(intrusive_ptr&lt;T&gt; const &amp; a, intrusive_ptr&lt;U&gt; const &amp; b); // never throws</pre>
<blockquote>
<p><b>Returns:</b> <code>a.get() != b.get()</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>template&lt;class T, class U&gt;
bool operator==(intrusive_ptr&lt;T&gt; const &amp; a, U * b); // never throws</pre>
<blockquote>
<p><b>Returns:</b> <code>a.get() == b</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>template&lt;class T, class U&gt;
bool operator!=(intrusive_ptr&lt;T&gt; const &amp; a, U * b); // never throws</pre>
<blockquote>
<p><b>Returns:</b> <code>a.get() != b</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>template&lt;class T, class U&gt;
bool operator==(T * a, intrusive_ptr&lt;U&gt; const &amp; b); // never throws</pre>
<blockquote>
<p><b>Returns:</b> <code>a == b.get()</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>template&lt;class T, class U&gt;
bool operator!=(T * a, intrusive_ptr&lt;U&gt; const &amp; b); // never throws</pre>
<blockquote>
<p><b>Returns:</b> <code>a != b.get()</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>template&lt;class T, class U&gt;
bool operator&lt;(intrusive_ptr&lt;T&gt; const &amp; a, intrusive_ptr&lt;U&gt; const &amp; b); // never throws</pre>
<blockquote>
<p><b>Returns:</b> <code>std::less&lt;T *&gt;()(a.get(), b.get())</code>.</p>
<p><b>Throws:</b> nothing.</p>
<P><B>Notes:</B> Allows <STRONG>intrusive_ptr</STRONG> objects to be used as keys
in associative containers.</P>
</blockquote>
<h3><a name="free-swap">swap</a></h3>
<pre>template&lt;class T&gt;
void swap(intrusive_ptr&lt;T&gt; &amp; a, intrusive_ptr&lt;T&gt; &amp; b); // never throws</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Equivalent to <code>a.swap(b)</code>.</P>
<P><B>Throws:</B> nothing.</P>
<P><B>Notes:</B> Matches the interface of <B>std::swap</B>. Provided as an aid to
generic programming.</P>
</BLOCKQUOTE>
<h3><a name="get_pointer">get_pointer</a></h3>
<pre>template&lt;class T&gt;
T * get_pointer(intrusive_ptr&lt;T&gt; const &amp; p); // never throws</pre>
<BLOCKQUOTE>
<P><B>Returns:</B> <code>p.get()</code>.</P>
<P><B>Throws:</B> nothing.</P>
<P><B>Notes:</B> Provided as an aid to generic programming. Used by <A href="../bind/mem_fn.html">
mem_fn</A>.</P>
</BLOCKQUOTE>
<h3><a name="static_pointer_cast">static_pointer_cast</a></h3>
<pre>template&lt;class T, class U&gt;
intrusive_ptr&lt;T&gt; static_pointer_cast(intrusive_ptr&lt;U&gt; const &amp; r); // never throws</pre>
<BLOCKQUOTE>
<P><B>Returns:</B> <code>intrusive_ptr&lt;T&gt;(static_cast&lt;T*&gt;(r.get()))</code>.</P>
<P><B>Throws:</B> nothing.</P>
</BLOCKQUOTE>
<h3><a name="const_pointer_cast">const_pointer_cast</a></h3>
<pre>template&lt;class T, class U&gt;
intrusive_ptr&lt;T&gt; const_pointer_cast(intrusive_ptr&lt;U&gt; const &amp; r); // never throws</pre>
<BLOCKQUOTE>
<P><B>Returns:</B> <code>intrusive_ptr&lt;T&gt;(const_cast&lt;T*&gt;(r.get()))</code>.</P>
<P><B>Throws:</B> nothing.</P>
</BLOCKQUOTE>
<h3><a name="dynamic_pointer_cast">dynamic_pointer_cast</a></h3>
<pre>template&lt;class T, class U&gt;
intrusive_ptr&lt;T&gt; dynamic_pointer_cast(intrusive_ptr&lt;U&gt; const &amp; r);</pre>
<BLOCKQUOTE>
<P><B>Returns:</B> <code>intrusive_ptr&lt;T&gt;(dynamic_cast&lt;T*&gt;(r.get()))</code>.</P>
<P><B>Throws:</B> nothing.</P>
</BLOCKQUOTE>
<h3><a name="insertion-operator">operator&lt;&lt;</a></h3>
<pre>template&lt;class E, class T, class Y&gt;
std::basic_ostream&lt;E, T&gt; &amp; operator&lt;&lt; (std::basic_ostream&lt;E, T&gt; &amp; os, intrusive_ptr&lt;Y&gt; const &amp; p);</pre>
<BLOCKQUOTE>
<p><STRONG>Effects:</STRONG> <code>os &lt;&lt; p.get();</code>.</p>
<P><B>Returns:</B> <code>os</code>.</P>
</BLOCKQUOTE>
<hr>
<p>
$Date$</p>
<p>
<small>Copyright <20> 2003-2005 Peter Dimov. Distributed under the Boost Software License, Version
1.0. See accompanying file <A href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</A> or
copy at <A href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</A>.</small></p>
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<h1><A href="../../index.htm"><IMG height="86" alt="boost.png (6897 bytes)" src="../../boost.png" width="277" align="middle"
border="0"></A>make_shared and allocate_shared function templates</h1>
<p><A href="#Introduction">Introduction</A><br>
<A href="#Synopsis">Synopsis</A><br>
<A href="#functions">Free Functions</A><br>
<A href="#example">Example</A><br>
<h2><a name="Introduction">Introduction</a></h2>
<p>Consistent use of <a href="shared_ptr.htm"><code>shared_ptr</code></a>
can eliminate the need to use an explicit <code>delete</code>,
but alone it provides no support in avoiding explicit <code>new</code>.
There have been repeated requests from users for a factory function that creates
an object of a given type and returns a <code>shared_ptr</code> to it.
Besides convenience and style, such a function is also exception safe and
considerably faster because it can use a single allocation for both the object
and its corresponding control block, eliminating a significant portion of
<code>shared_ptr</code>'s construction overhead.
This eliminates one of the major efficiency complaints about <code>shared_ptr</code>.
</p>
<p>The header file &lt;boost/make_shared.hpp&gt; provides a family of overloaded function templates,
<code>make_shared</code> and <code>allocate_shared</code>, to address this need.
<code>make_shared</code> uses the global operator <code>new</code> to allocate memory,
whereas <code>allocate_shared</code> uses an user-supplied allocator, allowing finer control.</p>
<p>
The rationale for choosing the name <code>make_shared</code> is that the expression
<code>make_shared&lt;Widget&gt;()</code> can be read aloud and conveys the intended meaning.</p>
<h2><a name="Synopsis">Synopsis</a></h2>
<pre>namespace boost {
template&lt;typename T&gt; class shared_ptr;
template&lt;typename T&gt;
shared_ptr&lt;T&gt; <a href="#functions">make_shared</a>();
template&lt;typename T, typename A&gt;
shared_ptr&lt;T&gt; <a href="#functions">allocate_shared</a>( A const &amp; );
#if defined( BOOST_HAS_VARIADIC_TMPL ) && defined( BOOST_HAS_RVALUE_REFS ) // C++0x prototypes
template&lt;typename T, typename... Args&gt;
shared_ptr&lt;T&gt; <a href="#functions">make_shared</a>( Args &amp;&amp; ... args );
template&lt;typename T, typename A, typename... Args&gt;
shared_ptr&lt;T&gt; <a href="#functions">allocate_shared</a>( A const &amp; a, Args &amp;&amp; ... args );
#else // no C++0X support
template&lt;typename T, typename Arg1 &gt;
shared_ptr&lt;T&gt; <a href="#functions">make_shared</a>( Arg1 const &amp; arg1 );
template&lt;typename T, typename Arg1, typename Arg2 &gt;
shared_ptr&lt;T&gt; <a href="#functions">make_shared</a>( Arg1 const &amp; arg1, Arg2 const &amp; arg2 );
// ...
template&lt;typename T, typename Arg1, typename Arg2, ..., typename ArgN &gt;
shared_ptr&lt;T&gt; <a href="#functions">make_shared</a>( Arg1 const &amp; arg1, Arg2 const &amp; arg2, ..., ArgN const &amp; argN );
template&lt;typename T, typename A, typename Arg1 &gt;
shared_ptr&lt;T&gt; <a href="#functions">allocate_shared</a>( A const &amp; a, Arg1 const &amp; arg1 );
template&lt;typename T, typename A, typename Arg1, typename Arg2 &gt;
shared_ptr&lt;T&gt; <a href="#functions">allocate_shared</a>( Arg1 const &amp; arg1, Arg2 const &amp; arg2 );
// ...
template&lt;typename T, typename A, typename Arg1, typename Arg2, ..., typename ArgN &gt;
shared_ptr&lt;T&gt; <a href="#functions">allocate_shared</a>( A const &amp; a, Arg1 const &amp; arg1, Arg2 const &amp; arg2, ..., ArgN const &amp; argN );
#endif
}</pre>
<h2><a name="functions">Free Functions</a></h2>
<pre>template&lt;class T, class... Args&gt;
shared_ptr&lt;T&gt; make_shared( Args &amp;&amp; ... args );
template&lt;class T, class A, class... Args&gt;
shared_ptr&lt;T&gt; allocate_shared( A const &amp; a, Args &amp;&amp; ... args );</pre>
<blockquote>
<p><b>Requires:</b> The expression <code>new( pv ) T( std::forward&lt;Args&gt;(args)... )</code>,
where <code>pv</code> is a <code>void*</code> pointing to storage suitable
to hold an object of type <code>T</code>,
shall be well-formed. <code>A</code> shall be an <em>Allocator</em>,
as described in section 20.1.5 (<stong>Allocator requirements</strong>) of the C++ Standard.
The copy constructor and destructor of <code>A</code> shall not throw.</p>
<p><b>Effects:</b> Allocates memory suitable for an object of type <code>T</code>
and constructs an object in it via the placement new expression <code>new( pv ) T()</code>
or <code>new( pv ) T( std::forward&lt;Args&gt;(args)... )</code>.
<code>allocate_shared</code> uses a copy of <code>a</code> to allocate memory.
If an exception is thrown, has no effect.</p>
<p><b>Returns:</b> A <code>shared_ptr</code> instance that stores and owns the address
of the newly constructed object of type <code>T</code>.</p>
<p><b>Postconditions:</b> <code>get() != 0 &amp;&amp; use_count() == 1</code>.</p>
<p><b>Throws:</b> <code>bad_alloc</code>, or an exception thrown from <code>A::allocate</code>
or the constructor of <code>T</code>.</p>
<p><b>Notes:</b> This implementation allocates the memory required for the
returned <code>shared_ptr</code> and an object of type <code>T</code> in a single
allocation. This provides efficiency equivalent to an intrusive smart pointer.</p>
<p>The prototypes shown above are used if your compiler supports rvalue references
and variadic templates. They perfectly forward the <code>args</code> parameters to
the constructors of <code>T</code>.</p>
<p>Otherwise, the implementation will fall back on
forwarding the arguments to the constructors of <code>T</code> as const references.
If you need to pass a non-const reference to a constructor of <code>T</code>,
you may do so by wrapping the parameter in a call to <code>boost::ref</code>.
In addition, you will be
limited to a maximum of 9 arguments (not counting the allocator argument of
allocate_shared).</p>
</blockquote>
<h2><a name="example">Example</a></h2>
<pre>boost::shared_ptr&lt;std::string&gt; x = boost::make_shared&lt;std::string&gt;("hello, world!");
std::cout << *x;</pre>
<hr>
<p>
$Date: 2008-05-19 15:42:39 -0400 (Mon, 19 May 2008) $</p>
<p><small>Copyright 2008 Peter Dimov. Copyright 2008 Frank Mori Hess.
Distributed under the Boost Software License,
Version 1.0. See accompanying file <A href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</A>
or copy at <A href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</A>.</small></p>
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<title>pointer_cast.hpp</title>
</head>
<body>
<h1><IMG height="86" alt="C++ Boost" src="../../boost.png" width="277" align="middle" border="0">Pointer
cast functions</h1>
<p>The pointer cast functions (<code>boost::static_pointer_cast</code> <code>boost::dynamic_pointer_cast</code>
<code>boost::reinterpret_pointer_cast</code> <code>boost::const_pointer_cast</code>)
provide a way to write generic pointer castings for raw pointers. The functions
are defined in <CITE><A href="../../boost/pointer_cast.hpp">boost/pointer_cast.hpp</A>.</CITE></p>
<P>There is test/example code in <CITE><A href="test/pointer_cast_test.cpp">pointer_cast_test.cpp</A></CITE>.</p>
<h2><a name="rationale">Rationale</a></h2>
<P>Boost smart pointers usually overload those functions to provide a mechanism to
emulate pointers casts. For example, <code>boost::shared_ptr&lt;...&gt;</code> implements
a static pointer cast this way:</P>
<pre>
template&lt;class T, class U&gt;
shared_ptr&lt;T&gt; static_pointer_cast(shared_ptr&lt;U&gt; const &amp;r);
</pre>
<P>Pointer cast functions from <CITE><A href="../../boost/pointer_cast.hpp">boost/pointer_cast.hpp</A></CITE>
are overloads of <code>boost::static_pointer_cast</code>, <code>boost::dynamic_pointer_cast</code>,
<code>boost::reinterpret_pointer_cast</code> and <code>boost::const_pointer_cast</code>
for raw pointers. This way when developing pointer type independent classes,
for example, memory managers or shared memory compatible classes, the same code
can be used for raw and smart pointers.</p>
<H2><A name="synopsis">Synopsis</A></H2>
<BLOCKQUOTE>
<PRE>
namespace boost {
template&lt;class T, class U&gt;
inline T* static_pointer_cast(U *ptr)
{ return static_cast&lt;T*&gt;(ptr); }
template&lt;class T, class U&gt;
inline T* dynamic_pointer_cast(U *ptr)
{ return dynamic_cast&lt;T*&gt;(ptr); }
template&lt;class T, class U&gt;
inline T* const_pointer_cast(U *ptr)
{ return const_cast&lt;T*&gt;(ptr); }
template&lt;class T, class U&gt;
inline T* reinterpret_pointer_cast(U *ptr)
{ return reinterpret_cast&lt;T*&gt;(ptr); }
} // namespace boost
</PRE>
</BLOCKQUOTE>
<P>As you can see from the above synopsis, the pointer cast functions are just
wrappers around standard C++ cast operators.</P>
<H2><A name="example">Example</A></H2>
<BLOCKQUOTE>
<PRE>
#include &lt;boost/pointer_cast.hpp&gt;
#include &lt;boost/shared_ptr.hpp&gt;
class base
{
public:
virtual ~base()
{
}
};
class derived: public base
{
};
template &lt;class BasePtr&gt;
void check_if_it_is_derived(const BasePtr &amp;ptr)
{
assert(boost::dynamic_pointer_cast&lt;derived&gt;(ptr) != 0);
}
int main()
{
<I>// Create a raw and a shared_ptr</I>
base *ptr = new derived;
boost::shared_ptr&lt;base&gt; sptr(new derived);
<I>// Check that base pointer points actually to derived class</I>
check_if_it_is_derived(ptr);
check_if_it_is_derived(sptr);
// <EM>Ok!</EM>
delete ptr;
return 0;
}</PRE>
</BLOCKQUOTE>
<P>The example demonstrates how the generic pointer casts help us create pointer
independent code.</P>
<hr>
<p>Revised: $Date$</p>
<p>Copyright 2005 Ion Gazta<74>aga. Use, modification, and distribution are subject to
the Boost Software License, Version 1.0. (See accompanying file <A href="../../LICENSE_1_0.txt">
LICENSE_1_0.txt</A> or a copy at &lt;<A href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</A>&gt;.)</p>
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<h1><img src="../../boost.png" alt="boost.png (6897 bytes)" align="middle" WIDTH="277" HEIGHT="86">Header
<a href="../../boost/pointer_to_other.hpp">boost/pointer_to_other.hpp</a></h1>
<p>
The pointer to other utility provides a way, given a source pointer type,
to obtain a pointer of the same type to another pointee type. The utility is
defined in <cite><a href="../../boost/pointer_to_other.hpp">boost/pointer_to_other.hpp</a>.</cite></p>
<p>There is test/example code in <cite><a href="test/pointer_to_other_test.cpp">pointer_to_other_test.cpp</a></cite>.</p>
<h2><a name="contents">Contents</a></h2>
<ul>
<li>
<a href="#rationale">Rationale</a>
<li>
<a href="#synopsis">Synopsis</a>
<li>
<a href="#example">Example</a></li>
</ul>
<h2><a name="rationale">Rationale</a></h2>
<p>When building pointer independent classes, like memory managers, allocators, or
containers, there is often a need to define pointers generically, so that if a
template parameter represents a pointer (for example, a raw or smart pointer to
an int), we can define another pointer of the same type to another pointee (a
raw or smart pointer to a float.)</p>
<pre>template &lt;class IntPtr&gt;
class FloatPointerHolder
{
<em>// Let's define a pointer to a float</em>
typedef typename boost::pointer_to_other
&lt;IntPtr, float&gt;::type float_ptr_t;
float_ptr_t float_ptr;
};</pre>
<h2><a name="synopsis">Synopsis</a></h2>
<pre>
namespace boost {
template&lt;class T, class U&gt;
struct pointer_to_other;
template&lt;class T, class U, template &lt;class&gt; class Sp&gt;
struct pointer_to_other&lt; Sp&lt;T&gt;, U &gt;
{
typedef Sp&lt;U&gt; type;
};
template&lt;class T, class T2, class U,
template &lt;class, class&gt; class Sp&gt;
struct pointer_to_other&lt; Sp&lt;T, T2&gt;, U &gt;
{
typedef Sp&lt;U, T2&gt; type;
};
template&lt;class T, class T2, class T3, class U,
template &lt;class, class, class&gt; class Sp&gt;
struct pointer_to_other&lt; Sp&lt;T, T2, T3&gt;, U &gt;
{
typedef Sp&lt;U, T2, T3&gt; type;
};
template&lt;class T, class U&gt;
struct pointer_to_other&lt; T*, U &gt;
{
typedef U* type;
};
} <em>// namespace boost</em></pre>
<p>If these definitions are not correct for a specific smart pointer, we can define
a specialization of pointer_to_other.</p>
<h2><a name="example">Example</a></h2>
<pre><em>// Let's define a memory allocator that can
// work with raw and smart pointers</em>
#include &lt;boost/pointer_to_other.hpp&gt;
template &lt;class VoidPtr&gt;
class memory_allocator
{<em>
// Predefine a memory_block </em>
struct block;<em>
// Define a pointer to a memory_block from a void pointer
// If VoidPtr is void *, block_ptr_t is block*
// If VoidPtr is smart_ptr&lt;void&gt;, block_ptr_t is smart_ptr&lt;block&gt;</em>
typedef typename boost::pointer_to_other
&lt;VoidPtr, block&gt;::type block_ptr_t;
struct block
{
std::size_t size;
block_ptr_t next_block;
};
block_ptr_t free_blocks;
};</pre>
<p>As we can see, using pointer_to_other we can create pointer independent code.</p>
<hr>
<p>Last revised: $Date$</p>
<p><small>Copyright 2005, 2006 Ion Gazta<74>aga and Peter Dimov. Use, modification,
and distribution are subject to the Boost Software License, Version 1.0.<br>
(See accompanying file <a href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</a> or a
copy at &lt; <a href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</a>&gt;.)</small></p>
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<h1><A href="../../index.htm"><img src="../../boost.png" alt="boost.png (6897 bytes)" align="middle" width="277" height="86"
border="0"></A>scoped_array class template</h1>
<p>The <b>scoped_array</b> class template stores a pointer to a dynamically
allocated array. (Dynamically allocated arrays are allocated with the C++ <b>new[]</b>
expression.) The array pointed to is guaranteed to be deleted, either on
destruction of the <b>scoped_array</b>, or via an explicit <b>reset</b>.</p>
<p>The <b>scoped_array</b> template is a simple solution for simple needs. It
supplies a basic "resource acquisition is initialization" facility, without
shared-ownership or transfer-of-ownership semantics. Both its name and
enforcement of semantics (by being <a href="../utility/utility.htm#Class_noncopyable">
noncopyable</a>) signal its intent to retain ownership solely within the
current scope. Because it is <a href="../utility/utility.htm#Class_noncopyable">noncopyable</a>,
it is safer than <b>shared_array</b> for pointers which should not be copied.</p>
<p>Because <b>scoped_array</b> is so simple, in its usual implementation every
operation is as fast as a built-in array pointer and it has no more space
overhead that a built-in array pointer.</p>
<p>It cannot be used in C++ standard library containers. See <a href="shared_array.htm">
<b>shared_array</b></a> if <b>scoped_array</b> does not meet your needs.</p>
<p>It cannot correctly hold a pointer to a single object. See <a href="scoped_ptr.htm"><b>scoped_ptr</b></a>
for that usage.</p>
<p>A <b>std::vector</b> is an alternative to a <b>scoped_array</b> that is a bit
heavier duty but far more flexible. A <b>boost::array</b> is an alternative
that does not use dynamic allocation.</p>
<p>The class template is parameterized on <b>T</b>, the type of the object pointed
to. <b>T</b> must meet the smart pointer <a href="smart_ptr.htm#common_requirements">
common requirements</a>.</p>
<h2>Synopsis</h2>
<pre>namespace boost {
template&lt;class T&gt; class scoped_array : <a href="../utility/utility.htm#Class_noncopyable">noncopyable</a> {
public:
typedef T <a href="#element_type">element_type</a>;
explicit <a href="#ctor">scoped_array</a>(T * p = 0); // never throws
<a href="#destructor">~scoped_array</a>(); // never throws
void <a href="#reset">reset</a>(T * p = 0); // never throws
T &amp; <a href="#operator[]">operator[]</a>(std::ptrdiff_t i) const; // never throws
T * <a href="#get">get</a>() const; // never throws
operator <A href="#conversions" ><i>unspecified-bool-type</i></A>() const; // never throws
void <a href="#swap">swap</a>(scoped_array &amp; b); // never throws
};
template&lt;class T&gt; void <a href="#free-swap">swap</a>(scoped_array&lt;T&gt; &amp; a, scoped_array&lt;T&gt; &amp; b); // never throws
}</pre>
<h2>Members</h2>
<h3>
<a name="element_type">element_type</a></h3>
<pre>typedef T element_type;</pre>
<p>Provides the type of the stored pointer.</p>
<h3><a name="ctor">constructors</a></h3>
<pre>explicit scoped_array(T * p = 0); // never throws</pre>
<p>Constructs a <b>scoped_array</b>, storing a copy of <b>p</b>, which must have
been allocated via a C++ <b>new</b>[] expression or be 0. <b>T</b> is not
required be a complete type. See the smart pointer <a href="smart_ptr.htm#common_requirements">
common requirements</a>.</p>
<h3><a name="destructor">destructor</a></h3>
<pre>~scoped_array(); // never throws</pre>
<p>Deletes the array pointed to by the stored pointer. Note that <b>delete[]</b> on
a pointer with a value of 0 is harmless. The guarantee that this does not throw
exceptions depends on the requirement that the deleted array's objects'
destructors do not throw exceptions. See the smart pointer <a href="smart_ptr.htm#common_requirements">
common requirements</a>.</p>
<h3><a name="reset">reset</a></h3>
<pre>void reset(T * p = 0); // never throws</pre>
<p>
Deletes the array pointed to by the stored pointer and then stores a copy of p,
which must have been allocated via a C++ <b>new[]</b> expression or be 0. The
guarantee that this does not throw exceptions depends on the requirement that
the deleted array's objects' destructors do not throw exceptions. See the smart
pointer <a href="smart_ptr.htm#common_requirements">common requirements</a>.</p>
<h3><a name="operator[]">subscripting</a></h3>
<pre>T &amp; operator[](std::ptrdiff_t i) const; // never throws</pre>
<p>Returns a reference to element <b>i</b> of the array pointed to by the stored
pointer. Behavior is undefined and almost certainly undesirable if the stored
pointer is 0, or if <b>i</b> is less than 0 or is greater than or equal to the
number of elements in the array.</p>
<h3><a name="get">get</a></h3>
<pre>T * get() const; // never throws</pre>
<p>Returns the stored pointer. <b>T</b> need not be a complete type. See the smart
pointer <a href="smart_ptr.htm#common_requirements">common requirements</a>.</p>
<h3><a name="conversions">conversions</a></h3>
<pre>operator <i>unspecified-bool-type</i> () const; // never throws</pre>
<p>Returns an unspecified value that, when used in boolean contexts, is equivalent
to <code>get() != 0</code>.</p>
<h3><a name="swap">swap</a></h3>
<pre>void swap(scoped_array &amp; b); // never throws</pre>
<p>Exchanges the contents of the two smart pointers. <b>T</b> need not be a
complete type. See the smart pointer <a href="smart_ptr.htm#common_requirements">common
requirements</a>.</p>
<h2><a name="functions">Free Functions</a></h2>
<h3><a name="free-swap">swap</a></h3>
<pre>template&lt;class T&gt; void swap(scoped_array&lt;T&gt; &amp; a, scoped_array&lt;T&gt; &amp; b); // never throws</pre>
<p>Equivalent to <b>a.swap(b)</b>. Matches the interface of <b>std::swap</b>.
Provided as an aid to generic programming.</p>
<hr>
<p>Revised <!--webbot bot="Timestamp" S-Type="EDITED" S-Format="%d %B %Y" startspan-->
09 January 2003<!--webbot bot="Timestamp" endspan i-checksum="32310"--></p>
<p><small>Copyright 1999 Greg Colvin and Beman Dawes. Copyright 2002 Darin Adler.
Copyright 2002-2005 Peter Dimov. Distributed under the Boost Software License, Version
1.0. See accompanying file <A href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</A> or
copy at <A href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</A>.</small></p>
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<meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1">
</head>
<body bgcolor="#ffffff" text="#000000">
<h1><A href="../../index.htm"><img src="../../boost.png" alt="boost.png (6897 bytes)" align="middle" width="277" height="86"
border="0"></A>scoped_ptr class template</h1>
<p>The <b>scoped_ptr</b> class template stores a pointer to a dynamically allocated
object. (Dynamically allocated objects are allocated with the C++ <b>new</b> expression.)
The object pointed to is guaranteed to be deleted, either on destruction of the <b>scoped_ptr</b>,
or via an explicit <b>reset</b>. See the <a href="#example">example</a>.</p>
<p>The <b>scoped_ptr</b> template is a simple solution for simple needs. It
supplies a basic "resource acquisition is initialization" facility, without
shared-ownership or transfer-of-ownership semantics. Both its name and
enforcement of semantics (by being <a href="../utility/utility.htm#Class_noncopyable">
noncopyable</a>) signal its intent to retain ownership solely within the
current scope. Because it is <a href="../utility/utility.htm#Class_noncopyable">noncopyable</a>,
it is safer than <b>shared_ptr</b> or <b>std::auto_ptr</b> for pointers which
should not be copied.</p>
<p>Because <b>scoped_ptr</b> is simple, in its usual implementation every operation
is as fast as for a built-in pointer and it has no more space overhead that a
built-in pointer.</p>
<p><STRONG>scoped_ptr</STRONG> cannot be used in C++ Standard Library containers.
Use <a href="shared_ptr.htm"><b>shared_ptr</b></a> if you need a smart pointer
that can.</p>
<p><STRONG>scoped_ptr</STRONG> cannot correctly hold a pointer to a dynamically
allocated array. See <a href="scoped_array.htm"><b>scoped_array</b></a> for
that usage.</p>
<p>The class template is parameterized on <b>T</b>, the type of the object pointed
to. <b>T</b> must meet the smart pointer <a href="smart_ptr.htm#common_requirements">
common requirements</a>.</p>
<h2>Synopsis</h2>
<pre>namespace boost {
template&lt;class T&gt; class scoped_ptr : <a href="../utility/utility.htm#Class_noncopyable">noncopyable</a> {
public:
typedef T <a href="#element_type">element_type</a>;
explicit <a href="#constructors">scoped_ptr</a>(T * p = 0); // never throws
<a href="#destructor">~scoped_ptr</a>(); // never throws
void <a href="#reset">reset</a>(T * p = 0); // never throws
T &amp; <a href="#indirection">operator*</a>() const; // never throws
T * <a href="#indirection">operator-&gt;</a>() const; // never throws
T * <a href="#get">get</a>() const; // never throws
operator <A href="#conversions" ><i>unspecified-bool-type</i></A>() const; // never throws
void <a href="#swap">swap</a>(scoped_ptr &amp; b); // never throws
};
template&lt;class T&gt; void <a href="#free-swap">swap</a>(scoped_ptr&lt;T&gt; &amp; a, scoped_ptr&lt;T&gt; &amp; b); // never throws
}</pre>
<h2>Members</h2>
<h3><a name="element_type">element_type</a></h3>
<pre>typedef T element_type;</pre>
<p>Provides the type of the stored pointer.</p>
<h3><a name="constructors">constructors</a></h3>
<pre>explicit scoped_ptr(T * p = 0); // never throws</pre>
<p>Constructs a <b>scoped_ptr</b>, storing a copy of <b>p</b>, which must have been
allocated via a C++ <b>new</b> expression or be 0. <b>T</b> is not required be
a complete type. See the smart pointer <a href="smart_ptr.htm#common_requirements">common
requirements</a>.</p>
<h3><a name="destructor">destructor</a></h3>
<pre>~scoped_ptr(); // never throws</pre>
<p>Destroys the object pointed to by the stored pointer, if any, as if by using <tt>delete
this-&gt;get()</tt>.</p>
<P>
The guarantee that this does not throw exceptions depends on the requirement
that the deleted object's destructor does not throw exceptions. See the smart
pointer <a href="smart_ptr.htm#common_requirements">common requirements</a>.</P>
<h3><a name="reset">reset</a></h3>
<pre>void reset(T * p = 0); // never throws</pre>
<p>
Deletes the object pointed to by the stored pointer and then stores a copy of
p, which must have been allocated via a C++ <b>new</b> expression or be 0. The
guarantee that this does not throw exceptions depends on the requirement that
the deleted object's destructor does not throw exceptions. See the smart
pointer <a href="smart_ptr.htm#common_requirements">common requirements</a>.</p>
<h3><a name="indirection">indirection</a></h3>
<pre>T &amp; operator*() const; // never throws</pre>
<p>Returns a reference to the object pointed to by the stored pointer. Behavior is
undefined if the stored pointer is 0.</p>
<pre>T * operator-&gt;() const; // never throws</pre>
<p>Returns the stored pointer. Behavior is undefined if the stored pointer is 0.</p>
<h3><a name="get">get</a></h3>
<pre>T * get() const; // never throws</pre>
<p>Returns the stored pointer. <b>T</b> need not be a complete type. See the smart
pointer <a href="smart_ptr.htm#common_requirements">common requirements</a>.</p>
<h3><a name="conversions">conversions</a></h3>
<pre>operator <i>unspecified-bool-type</i> () const; // never throws</pre>
<p>Returns an unspecified value that, when used in boolean contexts, is equivalent
to <code>get() != 0</code>.</p>
<h3><a name="swap">swap</a></h3>
<pre>void swap(scoped_ptr &amp; b); // never throws</pre>
<p>Exchanges the contents of the two smart pointers. <b>T</b> need not be a
complete type. See the smart pointer <a href="smart_ptr.htm#common_requirements">common
requirements</a>.</p>
<h2><a name="functions">Free Functions</a></h2>
<h3><a name="free-swap">swap</a></h3>
<pre>template&lt;class T&gt; void swap(scoped_ptr&lt;T&gt; &amp; a, scoped_ptr&lt;T&gt; &amp; b); // never throws</pre>
<p>Equivalent to <b>a.swap(b)</b>. Matches the interface of <b>std::swap</b>.
Provided as an aid to generic programming.</p>
<h2><a name="example">Example</a></h2>
<p>Here's an example that uses <b>scoped_ptr</b>.</p>
<blockquote>
<pre>#include &lt;boost/scoped_ptr.hpp&gt;
#include &lt;iostream&gt;
struct Shoe { ~Shoe() { std::cout &lt;&lt; "Buckle my shoe\n"; } };
class MyClass {
boost::scoped_ptr&lt;int&gt; ptr;
public:
MyClass() : ptr(new int) { *ptr = 0; }
int add_one() { return ++*ptr; }
};
int main()
{
boost::scoped_ptr&lt;Shoe&gt; x(new Shoe);
MyClass my_instance;
std::cout &lt;&lt; my_instance.add_one() &lt;&lt; '\n';
std::cout &lt;&lt; my_instance.add_one() &lt;&lt; '\n';
}</pre>
</blockquote>
<p>The example program produces the beginning of a child's nursery rhyme:</p>
<blockquote>
<pre>1
2
Buckle my shoe</pre>
</blockquote>
<h2>Rationale</h2>
<p>The primary reason to use <b>scoped_ptr</b> rather than <b>auto_ptr</b> is to
let readers of your code know that you intend "resource acquisition is
initialization" to be applied only for the current scope, and have no intent to
transfer ownership.</p>
<p>A secondary reason to use <b>scoped_ptr</b> is to prevent a later maintenance
programmer from adding a function that transfers ownership by returning the <b>auto_ptr</b>,
because the maintenance programmer saw <b>auto_ptr</b>, and assumed ownership
could safely be transferred.</p>
<p>Think of <b>bool</b> vs <b>int</b>. We all know that under the covers <b>bool</b>
is usually just an <b>int</b>. Indeed, some argued against including <b>bool</b>
in the C++ standard because of that. But by coding <b>bool</b> rather than <b>int</b>,
you tell your readers what your intent is. Same with <b>scoped_ptr</b>; by
using it you are signaling intent.</p>
<p>It has been suggested that <b>scoped_ptr&lt;T&gt;</b> is equivalent to <b>std::auto_ptr&lt;T&gt;
const</b>. Ed Brey pointed out, however, that <b>reset</b> will not work on
a <b>std::auto_ptr&lt;T&gt; const.</b></p>
<h2><a name="Handle/Body">Handle/Body</a> Idiom</h2>
<p>One common usage of <b>scoped_ptr</b> is to implement a handle/body (also called
pimpl) idiom which avoids exposing the body (implementation) in the header
file.</p>
<p>The <a href="example/scoped_ptr_example_test.cpp">scoped_ptr_example_test.cpp</a>
sample program includes a header file, <a href="example/scoped_ptr_example.hpp">scoped_ptr_example.hpp</a>,
which uses a <b>scoped_ptr&lt;&gt;</b> to an incomplete type to hide the
implementation. The instantiation of member functions which require a complete
type occurs in the <a href="example/scoped_ptr_example.cpp">scoped_ptr_example.cpp</a>
implementation file.</p>
<h2>Frequently Asked Questions</h2>
<p><b>Q</b>. Why doesn't <b>scoped_ptr</b> have a release() member?<br>
<b>A</b>. When reading source code, it is valuable to be able to draw
conclusions about program behavior based on the types being used. If <STRONG>scoped_ptr</STRONG>
had a release() member, it would become possible to transfer ownership of the
held pointer, weakening its role as a way of limiting resource lifetime to a
given context. Use <STRONG>std::auto_ptr</STRONG> where transfer of ownership
is required. (supplied by Dave Abrahams)</p>
<hr>
<p>Revised <!--webbot bot="Timestamp" s-type="EDITED" s-format="%d %B %Y" startspan -->
09 January 2003<!--webbot bot="Timestamp" endspan i-checksum="32310" --></p>
<p><small>Copyright 1999 Greg Colvin and Beman Dawes. Copyright 2002 Darin Adler.
Copyright 2002-2005 Peter Dimov. Distributed under the Boost Software License, Version
1.0. See accompanying file <A href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</A> or
copy at <A href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</A>.</small></p>
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<body bgcolor="#ffffff" text="#000000">
<h1><A href="../../index.htm"><img src="../../boost.png" alt="boost.png (6897 bytes)" align="middle" width="277" height="86"
border="0"></A>shared_array class template</h1>
<p>The <b>shared_array</b> class template stores a pointer to a dynamically
allocated array. (Dynamically allocated array are allocated with the C++ <b>new[]</b>
expression.) The object pointed to is guaranteed to be deleted when the last <b>shared_array</b>
pointing to it is destroyed or reset.</p>
<p>Every <b>shared_array</b> meets the <b>CopyConstructible</b> and <b>Assignable</b>
requirements of the C++ Standard Library, and so can be used in standard
library containers. Comparison operators are supplied so that <b>shared_array</b>
works with the standard library's associative containers.</p>
<p>Normally, a <b>shared_array</b> cannot correctly hold a pointer to an object
that has been allocated with the non-array form of <STRONG>new</STRONG>. See <a href="shared_ptr.htm">
<b>shared_ptr</b></a> for that usage.</p>
<p>Because the implementation uses reference counting, cycles of <b>shared_array</b>
instances will not be reclaimed. For example, if <b>main()</b> holds a <b>shared_array</b>
to <b>A</b>, which directly or indirectly holds a <b>shared_array</b> back to <b>A</b>,
<b>A</b>'s use count will be 2. Destruction of the original <b>shared_array</b>
will leave <b>A</b> dangling with a use count of 1.</p>
<p>A <b>shared_ptr</b> to a <b>std::vector</b> is an alternative to a <b>shared_array</b>
that is a bit heavier duty but far more flexible.</p>
<p>The class template is parameterized on <b>T</b>, the type of the object pointed
to. <b>T</b> must meet the smart pointer <a href="smart_ptr.htm#common_requirements">
common requirements</a>.</p>
<h2>Synopsis</h2>
<pre>namespace boost {
template&lt;class T&gt; class shared_array {
public:
typedef T <a href="#element_type">element_type</a>;
explicit <a href="#constructors">shared_array</a>(T * p = 0);
template&lt;class D&gt; <a href="#constructors">shared_array</a>(T * p, D d);
<a href="#destructor">~shared_array</a>(); // never throws
<a href="#constructors">shared_array</a>(shared_array const &amp; r); // never throws
shared_array &amp; <a href="#assignment">operator=</a>(shared_array const &amp; r); // never throws
void <a href="#reset">reset</a>(T * p = 0);
template&lt;class D&gt; void <a href="#reset">reset</a>(T * p, D d);
T &amp; <a href="#indexing">operator[]</a>(std::ptrdiff_t i) const; // never throws
T * <a href="#get">get</a>() const; // never throws
bool <a href="#unique">unique</a>() const; // never throws
long <a href="#use_count">use_count</a>() const; // never throws
operator <A href="#conversions" ><i>unspecified-bool-type</i></A>() const; // never throws
void <a href="#swap">swap</a>(shared_array&lt;T&gt; &amp; b); // never throws
};
template&lt;class T&gt;
bool <a href="#comparison">operator==</a>(shared_array&lt;T&gt; const &amp; a, shared_array&lt;T&gt; const &amp; b); // never throws
template&lt;class T&gt;
bool <a href="#comparison">operator!=</a>(shared_array&lt;T&gt; const &amp; a, shared_array&lt;T&gt; const &amp; b); // never throws
template&lt;class T&gt;
bool <a href="#comparison">operator&lt;</a>(shared_array&lt;T&gt; const &amp; a, shared_array&lt;T&gt; const &amp; b); // never throws
template&lt;class T&gt; void <a href="#free-swap">swap</a>(shared_array&lt;T&gt; &amp; a, shared_array&lt;T&gt; &amp; b); // never throws
}</pre>
<h2>Members</h2>
<h3><a name="element_type">element_type</a></h3>
<pre>typedef T element_type;</pre>
<p>Provides the type of the stored pointer.</p>
<h3><a name="constructors">constructors</a></h3>
<pre>explicit shared_array(T * p = 0);</pre>
<p>Constructs a <b>shared_array</b>, storing a copy of <b>p</b>, which must be a
pointer to an array that was allocated via a C++ <b>new[]</b> expression or be
0. Afterwards, the <a href="#use_count">use count</a> is 1 (even if p == 0; see <a href="#destructor">
~shared_array</a>). The only exception which may be thrown by this
constructor is <b>std::bad_alloc</b>. If an exception is thrown, <b>delete[] p</b>
is called.</p>
<pre>template&lt;class D&gt; shared_array(T * p, D d);</pre>
<p>Constructs a <b>shared_array</b>, storing a copy of <b>p</b> and of <b>d</b>.
Afterwards, the <a href="#use_count">use count</a> is 1. <b>D</b>'s copy
constructor and destructor must not throw. When the the time comes to delete
the array pointed to by <b>p</b>, the object <b>d</b> is used in the statement <b>d(p)</b>.
Invoking the object <b>d</b> with parameter <b>p</b> in this way must not
throw. The only exception which may be thrown by this constructor is <b>std::bad_alloc</b>.
If an exception is thrown, <b>d(p)</b> is called.</p>
<pre>shared_array(shared_array const &amp; r); // never throws</pre>
<p>Constructs a <b>shared_array</b>, as if by storing a copy of the pointer stored
in <b>r</b>. Afterwards, the <a href="#use_count">use count</a> for all copies
is 1 more than the initial use count.</p>
<h3><a name="destructor">destructor</a></h3>
<pre>~shared_array(); // never throws</pre>
<p>Decrements the <a href="#use_count">use count</a>. Then, if the use count is 0,
deletes the array pointed to by the stored pointer. Note that <b>delete[]</b> on
a pointer with a value of 0 is harmless. <b>T</b> need not be a complete type.
The guarantee that this does not throw exceptions depends on the requirement
that the deleted object's destructor does not throw exceptions. See the smart
pointer <a href="smart_ptr.htm#common_requirements">common requirements</a>.</p>
<h3><a name="assignment">assignment</a></h3>
<pre>shared_array &amp; operator=(shared_array const &amp; r); // never throws</pre>
<p>Constructs a new <b>shared_array</b> as described <a href="#constructors">above</a>,
then replaces this <b>shared_array</b> with the new one, destroying the
replaced object.</p>
<h3><a name="reset">reset</a></h3>
<pre>void reset(T * p = 0);</pre>
<p>Constructs a new <b>shared_array</b> as described <a href="#constructors">above</a>,
then replaces this <b>shared_array</b> with the new one, destroying the
replaced object. The only exception which may be thrown is <b>std::bad_alloc</b>.
If an exception is thrown, <b>delete[] p</b> is called.</p>
<pre>template&lt;class D&gt; void reset(T * p, D d);</pre>
<p>Constructs a new <b>shared_array</b> as described <a href="#constructors">above</a>,
then replaces this <b>shared_array</b> with the new one, destroying the
replaced object. <b>D</b>'s copy constructor must not throw. The only exception
which may be thrown is <b>std::bad_alloc</b>. If an exception is thrown, <b>d(p)</b>
is called.</p>
<h3><a name="indexing">indexing</a></h3>
<pre>T &amp; operator[](std::ptrdiff_t i) const; // never throws</pre>
<p>Returns a reference to element <b>i</b> of the array pointed to by the stored
pointer. Behavior is undefined and almost certainly undesirable if the stored
pointer is 0, or if <b>i</b> is less than 0 or is greater than or equal to the
number of elements in the array.</p>
<h3><a name="get">get</a></h3>
<pre>T * get() const; // never throws</pre>
<p>Returns the stored pointer. <b>T</b> need not be a complete type. See the smart
pointer <a href="smart_ptr.htm#common_requirements">common requirements</a>.</p>
<h3><a name="unique">unique</a></h3>
<pre>bool unique() const; // never throws</pre>
<p>Returns true if no other <b>shared_array</b> is sharing ownership of the stored
pointer, false otherwise. <b>T</b> need not be a complete type. See the smart
pointer <a href="smart_ptr.htm#common_requirements">common requirements</a>.</p>
<h3><a name="use_count">use_count</a></h3>
<pre>long use_count() const; // never throws</pre>
<p>Returns the number of <b>shared_array</b> objects sharing ownership of the
stored pointer. <b>T</b> need not be a complete type. See the smart pointer <a href="smart_ptr.htm#common_requirements">
common requirements</a>.</p>
<p>Because <b>use_count</b> is not necessarily efficient to implement for
implementations of <b>shared_array</b> that do not use an explicit reference
count, it might be removed from some future version. Thus it should be used for
debugging purposes only, and not production code.</p>
<h3><a name="conversions">conversions</a></h3>
<pre>operator <i>unspecified-bool-type</i> () const; // never throws</pre>
<p>Returns an unspecified value that, when used in boolean contexts, is equivalent
to <code>get() != 0</code>.</p>
<h3><a name="swap">swap</a></h3>
<pre>void swap(shared_ptr &amp; b); // never throws</pre>
<p>Exchanges the contents of the two smart pointers. <b>T</b> need not be a
complete type. See the smart pointer <a href="smart_ptr.htm#common_requirements">common
requirements</a>.</p>
<h2><a name="functions">Free Functions</a></h2>
<h3><a name="comparison">comparison</a></h3>
<pre>template&lt;class T&gt;
bool operator==(shared_array&lt;T&gt; const &amp; a, shared_array&lt;T&gt; const &amp; b); // never throws
template&lt;class T&gt;
bool operator!=(shared_array&lt;T&gt; const &amp; a, shared_array&lt;T&gt; const &amp; b); // never throws
template&lt;class T&gt;
bool operator&lt;(shared_array&lt;T&gt; const &amp; a, shared_array&lt;T&gt; const &amp; b); // never throws</pre>
<p>Compares the stored pointers of the two smart pointers. <b>T</b> need not be a
complete type. See the smart pointer <a href="smart_ptr.htm#common_requirements">common
requirements</a>.</p>
<p>The <b>operator&lt;</b> overload is provided to define an ordering so that <b>shared_array</b>
objects can be used in associative containers such as <b>std::map</b>. The
implementation uses <b>std::less&lt;T *&gt;</b> to perform the comparison. This
ensures that the comparison is handled correctly, since the standard mandates
that relational operations on pointers are unspecified (5.9 [expr.rel]
paragraph 2) but <b>std::less&lt;&gt;</b> on pointers is well-defined (20.3.3
[lib.comparisons] paragraph 8).</p>
<h3><a name="free-swap">swap</a></h3>
<pre>template&lt;class T&gt;
void swap(shared_array&lt;T&gt; &amp; a, shared_array&lt;T&gt; &amp; b) // never throws</pre>
<p>Equivalent to <b>a.swap(b)</b>. Matches the interface of <b>std::swap</b>.
Provided as an aid to generic programming.</p>
<hr>
<p>Revised
<!--webbot bot="Timestamp" S-Type="EDITED" S-Format="%d %B %Y" startspan -->
09 January 2003<!--webbot bot="Timestamp" endspan i-checksum="32310" --></p>
<p><small>Copyright 1999 Greg Colvin and Beman Dawes. Copyright 2002 Darin Adler.
Copyright 2002-2005 Peter Dimov. Distributed under the Boost Software License, Version
1.0. See accompanying file <A href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</A> or
copy at <A href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</A>.</small></p>
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<h1><A href="../../index.htm"><IMG height="86" alt="boost.png (6897 bytes)" src="../../boost.png" width="277" align="middle"
border="0"></A>shared_ptr class template</h1>
<p><A href="#Introduction">Introduction</A><br>
<A href="#BestPractices">Best Practices</A><br>
<A href="#Synopsis">Synopsis</A><br>
<A href="#Members">Members</A><br>
<A href="#functions">Free Functions</A><br>
<A href="#example">Example</A><br>
<A href="#Handle/Body">Handle/Body Idiom</A><br>
<A href="#ThreadSafety">Thread Safety</A><br>
<A href="#FAQ">Frequently Asked Questions</A><br>
<A href="smarttests.htm">Smart Pointer Timings</A><br>
<A href="sp_techniques.html">Programming Techniques</A></p>
<h2><a name="Introduction">Introduction</a></h2>
<p>The <b>shared_ptr</b> class template stores a pointer to a dynamically allocated
object, typically with a C++ <EM>new-expression</EM>. The object pointed to is
guaranteed to be deleted when the last <b>shared_ptr</b> pointing to it is
destroyed or reset. See the <A href="#example">example</A>.</p>
<p>Every <b>shared_ptr</b> meets the <b>CopyConstructible</b> and <b>Assignable</b>
requirements of the C++ Standard Library, and so can be used in standard
library containers. Comparison operators are supplied so that <b>shared_ptr</b>
works with the standard library's associative containers.</p>
<p>Normally, a <b>shared_ptr</b> cannot correctly hold a pointer to a dynamically
allocated array. See <A href="shared_array.htm"><b>shared_array</b></A> for
that usage.</p>
<p>Because the implementation uses reference counting, cycles of <b>shared_ptr</b> instances
will not be reclaimed. For example, if <b>main()</b> holds a <b>shared_ptr</b> to
<b>A</b>, which directly or indirectly holds a <b>shared_ptr</b> back to <b>A</b>,
<b>A</b>'s use count will be 2. Destruction of the original <b>shared_ptr</b> will
leave <b>A</b> dangling with a use count of 1. Use <A href="weak_ptr.htm">weak_ptr</A>
to "break cycles."</p>
<p>The class template is parameterized on <b>T</b>, the type of the object pointed
to. <STRONG>shared_ptr</STRONG> and most of its member functions place no
requirements on <STRONG>T</STRONG>; it is allowed to be an incomplete type, or <STRONG>
void</STRONG>. Member functions that do place additional requirements (<A href="#constructors">constructors</A>,
<A href="#reset">reset</A>) are explicitly documented below.</p>
<P><STRONG>shared_ptr&lt;T&gt;</STRONG> can be implicitly converted to <STRONG>shared_ptr&lt;U&gt;</STRONG>
whenever <STRONG>T*</STRONG> can be implicitly converted to <STRONG>U*</STRONG>.
In particular, <STRONG>shared_ptr&lt;T&gt;</STRONG> is implicitly convertible
to <STRONG>shared_ptr&lt;T const&gt;</STRONG>, to <STRONG>shared_ptr&lt;U&gt;</STRONG>
where <STRONG>U</STRONG> is an accessible base of <STRONG>T</STRONG>, and to <STRONG>
shared_ptr&lt;void&gt;</STRONG>.</P>
<P><STRONG>shared_ptr</STRONG> is now part of <STRONG>TR1</STRONG>, the first C++
Library Technical Report. The latest draft of <STRONG>TR1</STRONG> is available
at the following location:</P>
<P><A href="http://www.open-std.org/JTC1/SC22/WG21/docs/papers/2005/n1745.pdf">http://www.open-std.org/JTC1/SC22/WG21/docs/papers/2005/n1745.pdf</A>
(1.36Mb PDF)</P>
<P>This implementation conforms to the TR1 specification, with the only exception
that it resides in namespace <code>boost</code> instead of <code>std::tr1</code>.</P>
<h2><a name="BestPractices">Best Practices</a></h2>
<P>A simple guideline that nearly eliminates the possibility of memory leaks is:
always use a named smart pointer variable to hold the result of <STRONG>new. </STRONG>
Every occurence of the <STRONG>new</STRONG> keyword in the code should have the
form:</P>
<PRE>shared_ptr&lt;T&gt; p(new Y);</PRE>
<P>It is, of course, acceptable to use another smart pointer in place of <STRONG>shared_ptr</STRONG>
above; having <STRONG>T</STRONG> and <STRONG>Y</STRONG> be the same type, or
passing arguments to <STRONG>Y</STRONG>'s constructor is also OK.</P>
<P>If you observe this guideline, it naturally follows that you will have no
explicit <STRONG>delete</STRONG>s; <STRONG>try/catch</STRONG> constructs will
be rare.</P>
<P>Avoid using unnamed <STRONG>shared_ptr</STRONG> temporaries to save typing; to
see why this is dangerous, consider this example:</P>
<PRE>void f(shared_ptr&lt;int&gt;, int);
int g();
void ok()
{
shared_ptr&lt;int&gt; p(new int(2));
f(p, g());
}
void bad()
{
f(shared_ptr&lt;int&gt;(new int(2)), g());
}
</PRE>
<P>The function <STRONG>ok</STRONG> follows the guideline to the letter, whereas <STRONG>
bad</STRONG> constructs the temporary <STRONG>shared_ptr</STRONG> in place,
admitting the possibility of a memory leak. Since function arguments are
evaluated in unspecified order, it is possible for <STRONG>new int(2)</STRONG> to
be evaluated first, <STRONG>g()</STRONG> second, and we may never get to the <STRONG>
shared_ptr </STRONG>constructor if <STRONG>g</STRONG> throws an exception.
See <A href="http://www.gotw.ca/gotw/056.htm">Herb Sutter's treatment</A> (also <A href="http://www.cuj.com/reference/articles/2002/0212/0212_sutter.htm">
here</A>) of the issue for more information.</P>
<P>The exception safety problem described above may also be eliminated by using
the <a href="make_shared.html"><code>make_shared</code></a>
or <a href="make_shared.html"><code>allocate_shared</code></a>
factory functions defined in boost/make_shared.hpp. These factory functions also provide
an efficiency benefit by consolidating allocations.<P>
<h2><a name="Synopsis">Synopsis</a></h2>
<pre>namespace boost {
class bad_weak_ptr: public std::exception;
template&lt;class T&gt; class <A href="weak_ptr.htm" >weak_ptr</A>;
template&lt;class T&gt; class shared_ptr {
public:
typedef T <A href="#element_type" >element_type</A>;
<A href="#constructors" >shared_ptr</A>(); // never throws
template&lt;class Y&gt; explicit <A href="#constructors" >shared_ptr</A>(Y * p);
template&lt;class Y, class D&gt; <A href="#constructors" >shared_ptr</A>(Y * p, D d);
template&lt;class Y, class D, class A&gt; <A href="#allocator_constructor" >shared_ptr</A>(Y * p, D d, A a);
<A href="#destructor" >~shared_ptr</A>(); // never throws
<A href="#constructors" >shared_ptr</A>(shared_ptr const &amp; r); // never throws
template&lt;class Y&gt; <A href="#constructors" >shared_ptr</A>(shared_ptr&lt;Y&gt; const &amp; r); // never throws
template&lt;class Y&gt; <A href="#constructors" >shared_ptr</A>(shared_ptr&lt;Y&gt; const &amp; r, T * p); // never throws
template&lt;class Y&gt; explicit <A href="#constructors" >shared_ptr</A>(<A href="weak_ptr.htm" >weak_ptr</A>&lt;Y&gt; const &amp; r);
template&lt;class Y&gt; explicit <A href="#constructors" >shared_ptr</A>(std::auto_ptr&lt;Y&gt; &amp; r);
shared_ptr &amp; <A href="#assignment" >operator=</A>(shared_ptr const &amp; r); // never throws
template&lt;class Y&gt; shared_ptr &amp; <A href="#assignment" >operator=</A>(shared_ptr&lt;Y&gt; const &amp; r); // never throws
template&lt;class Y&gt; shared_ptr &amp; <A href="#assignment" >operator=</A>(std::auto_ptr&lt;Y&gt; &amp; r);
void <A href="#reset" >reset</A>(); // never throws
template&lt;class Y&gt; void <A href="#reset" >reset</A>(Y * p);
template&lt;class Y, class D&gt; void <A href="#reset" >reset</A>(Y * p, D d);
template&lt;class Y, class D, class A&gt; void <A href="#reset" >reset</A>(Y * p, D d, A a);
template&lt;class Y&gt; void <A href="#reset" >reset</A>(shared_ptr&lt;Y&gt; const &amp; r, T * p); // never throws
T &amp; <A href="#indirection" >operator*</A>() const; // never throws
T * <A href="#indirection" >operator-&gt;</A>() const; // never throws
T * <A href="#get" >get</A>() const; // never throws
bool <A href="#unique" >unique</A>() const; // never throws
long <A href="#use_count" >use_count</A>() const; // never throws
operator <A href="#conversions" ><i>unspecified-bool-type</i></A>() const; // never throws
void <A href="#swap" >swap</A>(shared_ptr &amp; b); // never throws
};
template&lt;class T, class U&gt;
bool <A href="#comparison" >operator==</A>(shared_ptr&lt;T&gt; const &amp; a, shared_ptr&lt;U&gt; const &amp; b); // never throws
template&lt;class T, class U&gt;
bool <A href="#comparison" >operator!=</A>(shared_ptr&lt;T&gt; const &amp; a, shared_ptr&lt;U&gt; const &amp; b); // never throws
template&lt;class T, class U&gt;
bool <A href="#comparison" >operator&lt;</A>(shared_ptr&lt;T&gt; const &amp; a, shared_ptr&lt;U&gt; const &amp; b); // never throws
template&lt;class T&gt; void <A href="#free-swap" >swap</A>(shared_ptr&lt;T&gt; &amp; a, shared_ptr&lt;T&gt; &amp; b); // never throws
template&lt;class T&gt; T * <A href="#get_pointer" >get_pointer</A>(shared_ptr&lt;T&gt; const &amp; p); // never throws
template&lt;class T, class U&gt;
shared_ptr&lt;T&gt; <A href="#static_pointer_cast" >static_pointer_cast</A>(shared_ptr&lt;U&gt; const &amp; r); // never throws
template&lt;class T, class U&gt;
shared_ptr&lt;T&gt; <A href="#const_pointer_cast" >const_pointer_cast</A>(shared_ptr&lt;U&gt; const &amp; r); // never throws
template&lt;class T, class U&gt;
shared_ptr&lt;T&gt; <A href="#dynamic_pointer_cast" >dynamic_pointer_cast</A>(shared_ptr&lt;U&gt; const &amp; r); // never throws
template&lt;class E, class T, class Y&gt;
std::basic_ostream&lt;E, T&gt; &amp; <A href="#insertion-operator" >operator&lt;&lt;</A> (std::basic_ostream&lt;E, T&gt; &amp; os, shared_ptr&lt;Y&gt; const &amp; p);
template&lt;class D, class T&gt;
D * <A href="#get_deleter">get_deleter</A>(shared_ptr&lt;T&gt; const &amp; p);
}</pre>
<h2><a name="Members">Members</a></h2>
<h3><a name="element_type">element_type</a></h3>
<pre>typedef T element_type;</pre>
<blockquote>
<p>Provides the type of the template parameter T.</p>
</blockquote>
<h3><a name="constructors">constructors</a></h3>
<pre>shared_ptr(); // never throws</pre>
<blockquote>
<p><b>Effects:</b> Constructs an <EM>empty</EM> <b>shared_ptr</b>.</p>
<p><b>Postconditions:</b> <code>use_count() == 0 &amp;&amp; get() == 0</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<P><EM>[The nothrow guarantee is important, since <STRONG>reset()</STRONG> is specified
in terms of the default constructor; this implies that the constructor must not
allocate memory.]</EM></P>
<pre>template&lt;class Y&gt; explicit shared_ptr(Y * p);</pre>
<blockquote>
<p><b>Requirements:</b> <b>p</b> must be convertible to <b>T *</b>. <STRONG>Y</STRONG>
must be a complete type. The expression <code>delete p</code> must be
well-formed, must not invoke undefined behavior, and must not throw exceptions.
</p>
<p><b>Effects:</b> Constructs a <b>shared_ptr</b> that <EM>owns</EM> the pointer <b>p</b>.</p>
<p><b>Postconditions:</b> <code>use_count() == 1 &amp;&amp; get() == p</code>.</p>
<p><b>Throws:</b> <STRONG>std::bad_alloc</STRONG>, or an implementation-defined
exception when a resource other than memory could not be obtained.</p>
<p><b>Exception safety:</b> If an exception is thrown, <code>delete p</code> is
called.</p>
<P><STRONG>Notes:</STRONG> <B>p</B> must be a pointer to an object that was
allocated via a C++ <B>new</B> expression or be 0. The postcondition that <A href="#use_count">
use count</A> is 1 holds even if <b>p</b> is 0; invoking <STRONG>delete</STRONG>
on a pointer that has a value of 0 is harmless.</P>
</blockquote>
<P><EM>[This constructor has been changed to a template in order to remember the actual
pointer type passed. The destructor will call <STRONG>delete</STRONG> with the
same pointer, complete with its original type, even when <STRONG>T</STRONG> does
not have a virtual destructor, or is <STRONG>void</STRONG>.</EM></P>
<P><EM>The optional intrusive counting support has been dropped as it exposes too much
implementation details and doesn't interact well with <STRONG>weak_ptr</STRONG>.
The current implementation uses a different mechanism, <A href="enable_shared_from_this.html">
enable_shared_from_this</A>, to solve the "<STRONG>shared_ptr</STRONG> from <STRONG>
this</STRONG>" problem.</EM><EM>]</EM></P>
<a name="allocator_constructor"></a>
<pre>template&lt;class Y, class D&gt; shared_ptr(Y * p, D d);
template&lt;class Y, class D, class A&gt; shared_ptr(Y * p, D d, A a);</pre>
<blockquote>
<p><b>Requirements:</b> <B>p</B> must be convertible to <B>T *</B>. <STRONG>D</STRONG>
must be <STRONG>CopyConstructible</STRONG>. The copy constructor and destructor
of <b>D</b> must not throw. The expression <code>d(p)</code> must be
well-formed, must not invoke undefined behavior, and must not throw exceptions. <STRONG>
A</STRONG> must be an <EM>Allocator</EM>, as described in section 20.1.5 (<STRONG>Allocator
requirements</STRONG>) of the C++ Standard.
</p>
<p><b>Effects:</b> Constructs a <b>shared_ptr</b> that <EM>owns</EM> the pointer <STRONG>
p</STRONG> and the deleter <b>d</b>. The second constructor allocates
memory using a copy of <STRONG>a</STRONG>.</p>
<p><b>Postconditions:</b> <code>use_count() == 1 &amp;&amp; get() == p</code>.</p>
<p><b>Throws:</b> <STRONG>std::bad_alloc</STRONG>, or an implementation-defined
exception when a resource other than memory could not be obtained.</p>
<p><b>Exception safety:</b> If an exception is thrown, <code>d(p)</code> is called.</p>
<p><b>Notes:</b> When the the time comes to delete the object pointed to by <b>p</b>,
the stored copy of <STRONG>d</STRONG> is invoked with the stored copy of <STRONG>p</STRONG>
as an argument.</p>
</blockquote>
<P><EM>[Custom deallocators allow a factory function returning a <STRONG>shared_ptr</STRONG>
to insulate the user from its memory allocation strategy. Since the deallocator
is not part of the type, changing the allocation strategy does not break source
or binary compatibility, and does not require a client recompilation. For
example, a "no-op" deallocator is useful when returning a <STRONG>shared_ptr</STRONG>
to a statically allocated object, and other variations allow a <STRONG>shared_ptr</STRONG>
to be used as a wrapper for another smart pointer, easing interoperability.</EM></P>
<P><EM>The support for custom deallocators does not impose significant overhead. Other <STRONG>
shared_ptr</STRONG> features still require a deallocator to be kept.</EM></P>
<P><EM>The requirement that the copy constructor of <b>D</b> does not throw comes from
the pass by value. If the copy constructor throws, the pointer is leaked.
Removing the requirement requires a pass by (const) reference.</EM></P>
<P><EM>The main problem with pass by reference lies in its interaction with rvalues. A
const reference may still cause a copy, and will require a const operator(). A
non-const reference won't bind to an rvalue at all. A good solution to this
problem is the rvalue reference proposed in <A href="http://std.dkuug.dk/jtc1/sc22/wg21/docs/papers/2002/n1377.htm">
N1377</A>/<A href="http://std.dkuug.dk/jtc1/sc22/wg21/docs/papers/2002/n1385.htm">N1385</A>.]</EM></P>
<pre>shared_ptr(shared_ptr const &amp; r); // never throws
template&lt;class Y&gt; shared_ptr(shared_ptr&lt;Y&gt; const &amp; r); // never throws</pre>
<blockquote>
<p><b>Effects:</b> If <b>r</b> is <EM>empty</EM>, constructs an <EM>empty</EM> <b>shared_ptr</b>;
otherwise, constructs a <b>shared_ptr</b> that <EM>shares ownership</EM> with <b>r</b>.</p>
<p><b>Postconditions:</b> <code>get() == r.get() &amp;&amp; use_count() ==
r.use_count()</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>template&lt;class Y&gt; shared_ptr(shared_ptr&lt;Y&gt; const &amp; r, T * p); // never throws</pre>
<blockquote>
<p><b>Effects:</b> constructs a <b>shared_ptr</b> that <EM>shares ownership</EM> with
<b>r</b> and stores <b>p</b>.</p>
<p><b>Postconditions:</b> <code>get() == p &amp;&amp; use_count() == r.use_count()</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>template&lt;class Y&gt; explicit shared_ptr(<A href="weak_ptr.htm" >weak_ptr</A>&lt;Y&gt; const &amp; r);</pre>
<blockquote>
<p><b>Effects:</b> Constructs a <b>shared_ptr</b> that <EM>shares ownership</EM> with
<b>r</b> and stores a copy of the pointer stored in <STRONG>r</STRONG>.</p>
<p><b>Postconditions:</b> <code>use_count() == r.use_count()</code>.</p>
<p><b>Throws:</b> <b>bad_weak_ptr</b> when <code>r.use_count() == 0</code>.</p>
<p><b>Exception safety:</b> If an exception is thrown, the constructor has no
effect.</p>
</blockquote>
<pre>template&lt;class Y&gt; shared_ptr(std::auto_ptr&lt;Y&gt; &amp; r);</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Constructs a <B>shared_ptr</B>, as if by storing a copy of <STRONG>r.release()</STRONG>.</P>
<p><b>Postconditions:</b> <code>use_count() == 1</code>.</p>
<p><b>Throws:</b> <STRONG>std::bad_alloc</STRONG>, or an implementation-defined
exception when a resource other than memory could not be obtained.</p>
<P><B>Exception safety:</B> If an exception is thrown, the constructor has no
effect.</P>
</BLOCKQUOTE>
<P><EM>[This constructor takes a the source <STRONG>auto_ptr</STRONG> by reference and
not by value, and cannot accept <STRONG>auto_ptr</STRONG> temporaries. This is
by design, as the constructor offers the strong guarantee; an rvalue reference
would solve this problem, too.]</EM></P>
<h3><a name="destructor">destructor</a></h3>
<pre>~shared_ptr(); // never throws</pre>
<BLOCKQUOTE>
<P><B>Effects:</B></P>
<UL>
<LI>
If <STRONG>*this</STRONG> is <EM>empty</EM>, or <EM>shares ownership</EM> with
another <STRONG>shared_ptr</STRONG> instance (<code>use_count() &gt; 1</code>),
there are no side effects.
<LI>
Otherwise, if <STRONG>*this</STRONG> <EM>owns</EM> a pointer <STRONG>p</STRONG>
and a deleter <STRONG>d</STRONG>, <code>d(p)</code>
is called.
<LI>
Otherwise, <STRONG>*this</STRONG> <EM>owns</EM> a pointer <STRONG>p</STRONG>,
and <code>delete p</code> is called.</LI></UL>
<P><B>Throws:</B> nothing.</P>
</BLOCKQUOTE>
<H3><a name="assignment">assignment</a></H3>
<pre>shared_ptr &amp; operator=(shared_ptr const &amp; r); // never throws
template&lt;class Y&gt; shared_ptr &amp; operator=(shared_ptr&lt;Y&gt; const &amp; r); // never throws
template&lt;class Y&gt; shared_ptr &amp; operator=(std::auto_ptr&lt;Y&gt; &amp; r);</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Equivalent to <code>shared_ptr(r).swap(*this)</code>.</P>
<P><B>Returns:</B> <code>*this</code>.</P>
<P><B>Notes:</B> The use count updates caused by the temporary object construction
and destruction are not considered observable side effects, and the
implementation is free to meet the effects (and the implied guarantees) via
different means, without creating a temporary. In particular, in the example:</P>
<pre>shared_ptr&lt;int&gt; p(new int);
shared_ptr&lt;void&gt; q(p);
p = p;
q = p;
</pre>
<p>both assignments may be no-ops.</p>
</BLOCKQUOTE>
<h3><a name="reset">reset</a></h3>
<pre>void reset(); // never throws</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Equivalent to <code>shared_ptr().swap(*this)</code>.</P>
</BLOCKQUOTE>
<pre>template&lt;class Y&gt; void reset(Y * p);</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Equivalent to <code>shared_ptr(p).swap(*this)</code>.</P>
</BLOCKQUOTE>
<pre>template&lt;class Y, class D&gt; void reset(Y * p, D d);</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Equivalent to <code>shared_ptr(p, d).swap(*this)</code>.</P>
</BLOCKQUOTE>
<pre>template&lt;class Y, class D, class A&gt; void reset(Y * p, D d, A a);</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Equivalent to <code>shared_ptr(p, d, a).swap(*this)</code>.</P>
</BLOCKQUOTE>
<pre>template&lt;class Y&gt; void reset(shared_ptr&lt;Y&gt; const &amp; r, T * p); // never throws</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Equivalent to <code>shared_ptr(r, p).swap(*this)</code>.</P>
</BLOCKQUOTE>
<h3><a name="indirection">indirection</a></h3>
<pre>T &amp; operator*() const; // never throws</pre>
<blockquote>
<p><b>Requirements:</b> The stored pointer must not be 0.</p>
<p><b>Returns:</b> a reference to the object pointed to by the stored pointer.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>T * operator-&gt;() const; // never throws</pre>
<blockquote>
<p><b>Requirements:</b> The stored pointer must not be 0.</p>
<p><b>Returns:</b> the stored pointer.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<h3><a name="get">get</a></h3>
<pre>T * get() const; // never throws</pre>
<blockquote>
<p><b>Returns:</b> the stored pointer.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<h3><a name="unique">unique</a></h3>
<pre>bool unique() const; // never throws</pre>
<blockquote>
<p><b>Returns:</b> <code>use_count() == 1</code>.</p>
<p><b>Throws:</b> nothing.</p>
<P><B>Notes:</B> <code>unique()</code> may be faster than <code>use_count()</code>.
If you are using <code>unique()</code> to implement copy on write, do not rely
on a specific value when the stored pointer is zero.</P>
</blockquote>
<h3><a name="use_count">use_count</a></h3>
<pre>long use_count() const; // never throws</pre>
<blockquote>
<p><b>Returns:</b> the number of <b>shared_ptr</b> objects, <STRONG>*this</STRONG> included,
that <i>share ownership</i> with <b>*this</b>, or 0 when <STRONG>*this</STRONG>
is <EM>empty</EM>.</p>
<p><b>Throws:</b> nothing.</p>
<P><B>Notes:</B> <code>use_count()</code> is not necessarily efficient. Use only
for debugging and testing purposes, not for production code.</P>
</blockquote>
<h3><a name="conversions">conversions</a></h3>
<pre>operator <i>unspecified-bool-type</i> () const; // never throws</pre>
<blockquote>
<p><b>Returns:</b> an unspecified value that, when used in boolean contexts, is
equivalent to <code>get() != 0</code>.</p>
<p><b>Throws:</b> nothing.</p>
<P><B>Notes:</B> This conversion operator allows <b>shared_ptr</b> objects to be
used in boolean contexts, like <code>if (p &amp;&amp; p-&gt;valid()) {}</code>.
The actual target type is typically a pointer to a member function, avoiding
many of the implicit conversion pitfalls.</P>
</blockquote>
<P><EM>[The conversion to bool is not merely syntactic sugar. It allows <STRONG>shared_ptr</STRONG>s
to be declared in conditions when using <A href="#dynamic_pointer_cast">dynamic_pointer_cast</A>
or <A href="weak_ptr.htm#lock">weak_ptr::lock</A>.]</EM></P>
<h3><a name="swap">swap</a></h3>
<pre>void swap(shared_ptr &amp; b); // never throws</pre>
<blockquote>
<p><b>Effects:</b> Exchanges the contents of the two smart pointers.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<h2><a name="functions">Free Functions</a></h2>
<h3><a name="comparison">comparison</a></h3>
<pre>template&lt;class T, class U&gt;
bool operator==(shared_ptr&lt;T&gt; const &amp; a, shared_ptr&lt;U&gt; const &amp; b); // never throws</pre>
<blockquote>
<p><b>Returns:</b> <code>a.get() == b.get()</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>template&lt;class T, class U&gt;
bool operator!=(shared_ptr&lt;T&gt; const &amp; a, shared_ptr&lt;U&gt; const &amp; b); // never throws</pre>
<blockquote>
<p><b>Returns:</b> <code>a.get() != b.get()</code>.</p>
<p><b>Throws:</b> nothing.</p>
</blockquote>
<pre>template&lt;class T, class U&gt;
bool operator&lt;(shared_ptr&lt;T&gt; const &amp; a, shared_ptr&lt;U&gt; const &amp; b); // never throws</pre>
<blockquote>
<p><b>Returns:</b> an unspecified value such that</p>
<UL>
<LI>
<b>operator&lt;</b> is a strict weak ordering as described in section 25.3 <code>[lib.alg.sorting]</code>
of the C++ standard;
<LI>
under the equivalence relation defined by <STRONG>operator&lt;</STRONG>, <code>!(a
&lt; b) &amp;&amp; !(b &lt; a)</code>, two <STRONG>shared_ptr</STRONG> instances
are equivalent if and only if they <EM>share ownership</EM> or are both <EM>empty</EM>.</LI></UL>
<p><b>Throws:</b> nothing.</p>
<P><B>Notes:</B> Allows <STRONG>shared_ptr</STRONG> objects to be used as keys in
associative containers.</P>
</blockquote>
<P><EM>[<STRONG>Operator&lt;</STRONG> has been preferred over a <STRONG>std::less </STRONG>
specialization for consistency and legality reasons, as <STRONG>std::less</STRONG>
is required to return the results of <STRONG>operator&lt;</STRONG>, and many
standard algorithms use <STRONG>operator&lt;</STRONG> instead of <STRONG>std::less</STRONG>
for comparisons when a predicate is not supplied. Composite objects, like <STRONG>std::pair</STRONG>,
also implement their <STRONG>operator&lt;</STRONG> in terms of their contained
subobjects' <STRONG>operator&lt;</STRONG>.</EM></P>
<P><EM>The rest of the comparison operators are omitted by design.]</EM></P>
<h3><a name="free-swap">swap</a></h3>
<pre>template&lt;class T&gt;
void swap(shared_ptr&lt;T&gt; &amp; a, shared_ptr&lt;T&gt; &amp; b); // never throws</pre>
<BLOCKQUOTE>
<P><B>Effects:</B> Equivalent to <code>a.swap(b)</code>.</P>
<P><B>Throws:</B> nothing.</P>
<P><B>Notes:</B> Matches the interface of <B>std::swap</B>. Provided as an aid to
generic programming.</P>
</BLOCKQUOTE>
<P><EM>[<STRONG>swap</STRONG> is defined in the same namespace as <STRONG>shared_ptr</STRONG>
as this is currently the only legal way to supply a <STRONG>swap</STRONG> function
that has a chance to be used by the standard library.]</EM></P>
<h3><a name="get_pointer">get_pointer</a></h3>
<pre>template&lt;class T&gt;
T * get_pointer(shared_ptr&lt;T&gt; const &amp; p); // never throws</pre>
<BLOCKQUOTE>
<P><B>Returns:</B> <code>p.get()</code>.</P>
<P><B>Throws:</B> nothing.</P>
<P><B>Notes:</B> Provided as an aid to generic programming. Used by <A href="../bind/mem_fn.html">
mem_fn</A>.</P>
</BLOCKQUOTE>
<h3><a name="static_pointer_cast">static_pointer_cast</a></h3>
<pre>template&lt;class T, class U&gt;
shared_ptr&lt;T&gt; static_pointer_cast(shared_ptr&lt;U&gt; const &amp; r); // never throws</pre>
<BLOCKQUOTE>
<P><STRONG>Requires:</STRONG> The expression <code>static_cast&lt;T*&gt;(r.get())</code>
must be well-formed.</P>
<P><B>Returns:</B> If <b>r</b> is <i>empty</i>, an <i>empty</i> <b>shared_ptr&lt;T&gt;</b>;
otherwise, a <STRONG>shared_ptr&lt;T&gt;</STRONG> object that stores a copy of <code>
static_cast&lt;T*&gt;(r.get())</code> and <i>shares ownership</i> with <b>r</b>.</P>
<P><B>Throws:</B> nothing.</P>
<P><B>Notes:</B> the seemingly equivalent expression</P>
<p><code>shared_ptr&lt;T&gt;(static_cast&lt;T*&gt;(r.get()))</code></p>
<p>will eventually result in undefined behavior, attempting to delete the same
object twice.</p>
</BLOCKQUOTE>
<h3><a name="const_pointer_cast">const_pointer_cast</a></h3>
<pre>template&lt;class T, class U&gt;
shared_ptr&lt;T&gt; const_pointer_cast(shared_ptr&lt;U&gt; const &amp; r); // never throws</pre>
<BLOCKQUOTE>
<P><STRONG>Requires:</STRONG> The expression <code>const_cast&lt;T*&gt;(r.get())</code>
must be well-formed.</P>
<P><B>Returns:</B> If <b>r</b> is <i>empty</i>, an <i>empty</i> <b>shared_ptr&lt;T&gt;</b>;
otherwise, a <STRONG>shared_ptr&lt;T&gt;</STRONG> object that stores a copy of <code>
const_cast&lt;T*&gt;(r.get())</code> and <i>shares ownership</i> with <b>r</b>.</P>
<P><B>Throws:</B> nothing.</P>
<P><B>Notes:</B> the seemingly equivalent expression</P>
<p><code>shared_ptr&lt;T&gt;(const_cast&lt;T*&gt;(r.get()))</code></p>
<p>will eventually result in undefined behavior, attempting to delete the same
object twice.</p>
</BLOCKQUOTE>
<h3><a name="dynamic_pointer_cast">dynamic_pointer_cast</a></h3>
<pre>template&lt;class T, class U&gt;
shared_ptr&lt;T&gt; dynamic_pointer_cast(shared_ptr&lt;U&gt; const &amp; r);</pre>
<BLOCKQUOTE>
<P><STRONG>Requires:</STRONG> The expression <CODE>dynamic_cast&lt;T*&gt;(r.get())</CODE>
must be well-formed and its behavior defined.</P>
<P><B>Returns:</B></P>
<UL>
<LI>
When <CODE>dynamic_cast&lt;T*&gt;(r.get())</CODE> returns a nonzero value, a <STRONG>
shared_ptr&lt;T&gt;</STRONG> object that stores a copy of it and <i>shares
ownership</i> with <STRONG>r</STRONG>;
<LI>
Otherwise, an <i>empty</i> <STRONG>shared_ptr&lt;T&gt;</STRONG> object.</LI></UL>
<P><B>Throws:</B> nothing.</P>
<P><B>Notes:</B> the seemingly equivalent expression</P>
<P><CODE>shared_ptr&lt;T&gt;(dynamic_cast&lt;T*&gt;(r.get()))</CODE></P>
<P>will eventually result in undefined behavior, attempting to delete the same
object twice.</P>
</BLOCKQUOTE>
<h3><a name="insertion-operator">operator&lt;&lt;</a></h3>
<pre>template&lt;class E, class T, class Y&gt;
std::basic_ostream&lt;E, T&gt; &amp; operator&lt;&lt; (std::basic_ostream&lt;E, T&gt; &amp; os, shared_ptr&lt;Y&gt; const &amp; p);</pre>
<BLOCKQUOTE>
<p><STRONG>Effects:</STRONG> <code>os &lt;&lt; p.get();</code>.</p>
<P><B>Returns:</B> <b>os</b>.</P>
</BLOCKQUOTE>
<h3><a name="get_deleter">get_deleter</a></h3>
<pre>template&lt;class D, class T&gt;
D * get_deleter(shared_ptr&lt;T&gt; const &amp; p);</pre>
<BLOCKQUOTE>
<P><B>Returns:</B> If <STRONG>*this</STRONG> <EM>owns</EM> a deleter <STRONG>d</STRONG>
of type (cv-unqualified) <STRONG>D</STRONG>, returns <code>&amp;d</code>;
otherwise returns 0.</P>
<P><B>Throws:</B> nothing.</P>
</BLOCKQUOTE>
<h2><a name="example">Example</a></h2>
<p>See <A href="example/shared_ptr_example.cpp">shared_ptr_example.cpp</A> for a
complete example program. The program builds a <b>std::vector</b> and <b>std::set</b>
of <b>shared_ptr</b> objects.</p>
<p>Note that after the containers have been populated, some of the <b>shared_ptr</b>
objects will have a use count of 1 rather than a use count of 2, since the set
is a <b>std::set</b> rather than a <b>std::multiset</b>, and thus does not
contain duplicate entries. Furthermore, the use count may be even higher at
various times while <b>push_back</b> and <b>insert</b> container operations are
performed. More complicated yet, the container operations may throw exceptions
under a variety of circumstances. Getting the memory management and exception
handling in this example right without a smart pointer would be a nightmare.</p>
<h2><a name="Handle/Body">Handle/Body</a> Idiom</h2>
<p>One common usage of <b>shared_ptr</b> is to implement a handle/body (also called
pimpl) idiom which avoids exposing the body (implementation) in the header
file.</p>
<p>The <A href="example/shared_ptr_example2_test.cpp">shared_ptr_example2_test.cpp</A>
sample program includes a header file, <A href="example/shared_ptr_example2.hpp">shared_ptr_example2.hpp</A>,
which uses a <b>shared_ptr&lt;&gt;</b> to an incomplete type to hide the
implementation. The instantiation of member functions which require a complete
type occurs in the <A href="example/shared_ptr_example2.cpp">shared_ptr_example2.cpp</A>
implementation file. Note that there is no need for an explicit destructor.
Unlike ~scoped_ptr, ~shared_ptr does not require that <b>T</b> be a complete
type.</p>
<h2><a name="ThreadSafety">Thread Safety</a></h2>
<p><STRONG>shared_ptr</STRONG> objects offer the same level of thread safety as
built-in types. A <STRONG>shared_ptr</STRONG> instance can be "read" (accessed
using only const operations) simultaneously by multiple threads. Different <STRONG>shared_ptr</STRONG>
instances can be "written to" (accessed using mutable operations such as <STRONG>operator=
</STRONG>or <STRONG>reset</STRONG>) simultaneosly by multiple threads (even
when these instances are copies, and share the same reference count
underneath.)</p>
<P>Any other simultaneous accesses result in undefined behavior.</P>
<P>Examples:</P>
<pre>shared_ptr&lt;int&gt; p(new int(42));
//--- Example 1 ---
// thread A
shared_ptr&lt;int&gt; p2(p); // reads p
// thread B
shared_ptr&lt;int&gt; p3(p); // OK, multiple reads are safe
//--- Example 2 ---
// thread A
p.reset(new int(1912)); // writes p
// thread B
p2.reset(); // OK, writes p2
//--- Example 3 ---
// thread A
p = p3; // reads p3, writes p
// thread B
p3.reset(); // writes p3; undefined, simultaneous read/write
//--- Example 4 ---
// thread A
p3 = p2; // reads p2, writes p3
// thread B
// p2 goes out of scope: undefined, the destructor is considered a "write access"
//--- Example 5 ---
// thread A
p3.reset(new int(1));
// thread B
p3.reset(new int(2)); // undefined, multiple writes
</pre>
<p>&nbsp;</p>
<P>Starting with Boost release 1.33.0, <STRONG>shared_ptr</STRONG> uses a lock-free
implementation on the following platforms:</P>
<UL>
<LI>
GNU GCC on x86 or x86-64;
<LI>
GNU GCC on IA64;
<LI>
Metrowerks CodeWarrior on PowerPC;
<LI>
GNU GCC on PowerPC;
<LI>
Windows.</LI></UL>
<P>If your program is single-threaded and does not link to any libraries that might
have used <STRONG>shared_ptr</STRONG> in its default configuration, you can <STRONG>
#define</STRONG> the macro <STRONG>BOOST_SP_DISABLE_THREADS</STRONG> on a
project-wide basis to switch to ordinary non-atomic reference count updates.</P>
<P>(Defining <STRONG>BOOST_SP_DISABLE_THREADS</STRONG> in some, but not all,
translation units is technically a violation of the One Definition Rule and
undefined behavior. Nevertheless, the implementation attempts to do its best to
accommodate the request to use non-atomic updates in those translation units.
No guarantees, though.)</P>
<P>You can define the macro <STRONG>BOOST_SP_USE_PTHREADS</STRONG> to turn off the
lock-free platform-specific implementation and fall back to the generic <STRONG>pthread_mutex_t</STRONG>-based
code.</P>
<h2><a name="FAQ">Frequently Asked Questions</a></h2>
<P><B>Q.</B> There are several variations of shared pointers, with different
tradeoffs; why does the smart pointer library supply only a single
implementation? It would be useful to be able to experiment with each type so
as to find the most suitable for the job at hand?</P>
<P>
<b>A.</b> An important goal of <STRONG>shared_ptr</STRONG> is to provide a
standard shared-ownership pointer. Having a single pointer type is important
for stable library interfaces, since different shared pointers typically cannot
interoperate, i.e. a reference counted pointer (used by library A) cannot share
ownership with a linked pointer (used by library B.)<BR>
</P>
<P><B>Q.</B> Why doesn't <B>shared_ptr</B> have template parameters supplying
traits or policies to allow extensive user customization?</P>
<P>
<B>A.</B> Parameterization discourages users. The <B>shared_ptr</B> template is
carefully crafted to meet common needs without extensive parameterization. Some
day a highly configurable smart pointer may be invented that is also very easy
to use and very hard to misuse. Until then, <B>shared_ptr</B> is the smart
pointer of choice for a wide range of applications. (Those interested in policy
based smart pointers should read <A href="http://www.awprofessional.com/bookstore/product.asp?isbn=0201704315&amp;rl=1">
Modern C++ Design</A> by Andrei Alexandrescu.)<BR>
</P>
<P><B>Q.</B> I am not convinced. Default parameters can be used where appropriate
to hide the complexity. Again, why not policies?</P>
<P>
<B>A.</B> Template parameters affect the type. See the answer to the first
question above.<BR>
</P>
<P><B>Q.</B> Why doesn't <b>shared_ptr</b> use a linked list implementation?</P>
<P>
<b>A.</b> A linked list implementation does not offer enough advantages to
offset the added cost of an extra pointer. See <A href="smarttests.htm">timings</A>
page. In addition, it is expensive to make a linked list implementation thread
safe.<BR>
</P>
<P><b>Q.</b> Why doesn't <b>shared_ptr</b> (or any of the other Boost smart
pointers) supply an automatic conversion to <b>T*</b>?</P>
<P>
<b>A.</b> Automatic conversion is believed to be too error prone.<BR>
</P>
<P><B>Q.</B> Why does <b>shared_ptr</b> supply use_count()?</P>
<P>
<b>A.</b> As an aid to writing test cases and debugging displays. One of the
progenitors had use_count(), and it was useful in tracking down bugs in a
complex project that turned out to have cyclic-dependencies.<BR>
</P>
<P><B>Q.</B> Why doesn't <b>shared_ptr</b> specify complexity requirements?</P>
<P>
<b>A.</b> Because complexity requirements limit implementors and complicate the
specification without apparent benefit to <b>shared_ptr</b> users. For example,
error-checking implementations might become non-conforming if they had to meet
stringent complexity requirements.<BR>
</P>
<P><b>Q.</b> Why doesn't <b>shared_ptr</b> provide a release() function?</P>
<P>
<b>A.</b> <b>shared_ptr</b> cannot give away ownership unless it's unique()
because the other copy will still destroy the object.</P>
<p>Consider:</p>
<blockquote><pre>shared_ptr&lt;int&gt; a(new int);
shared_ptr&lt;int&gt; b(a); // a.use_count() == b.use_count() == 2
int * p = a.release();
// Who owns p now? b will still call delete on it in its destructor.</pre>
</blockquote>
<p>Furthermore, the pointer returned by <code>release()</code> would be difficult
to deallocate reliably, as the source <b>shared_ptr</b> could have been created
with a custom deleter.<BR>
</p>
<P><b>Q.</b> Why is <code>operator-&gt;()</code> const, but its return value is a
non-const pointer to the element type?</P>
<P>
<b>A.</b> Shallow copy pointers, including raw pointers, typically don't
propagate constness. It makes little sense for them to do so, as you can always
obtain a non-const pointer from a const one and then proceed to modify the
object through it.<b>shared_ptr</b> is "as close to raw pointers as possible
but no closer".<BR>
<BR>
</P>
<hr>
<p>
$Date$</p>
<p><small>Copyright 1999 Greg Colvin and Beman Dawes. Copyright 2002 Darin Adler.
Copyright 2002-2005 Peter Dimov. Distributed under the Boost Software License,
Version 1.0. See accompanying file <A href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</A>
or copy at <A href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</A>.</small></p>
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<h1><A href="../../index.htm"><img src="../../boost.png" alt="boost.png (6897 bytes)" align="middle" width="277" height="86"
border="0"></A>Smart Pointers</h1>
<p><a href="#Introduction">Introduction</a><br>
<a href="#common_requirements">Common Requirements</a><br>
<a href="#Exception_Safety">Exception Safety</a><br>
<a href="#Exception-specifications">Exception-specifications</a><br>
<a href="#History">History and Acknowledgements</a><br>
<a href="#References">References</a></p>
<h2><a name="Introduction">Introduction</a></h2>
<p>Smart pointers are objects which store pointers to dynamically allocated (heap)
objects. They behave much like built-in C++ pointers except that they
automatically delete the object pointed to at the appropriate time. Smart
pointers are particularly useful in the face of exceptions as they ensure
proper destruction of dynamically allocated objects. They can also be used to
keep track of dynamically allocated objects shared by multiple owners.</p>
<p>Conceptually, smart pointers are seen as owning the object pointed to, and thus
responsible for deletion of the object when it is no longer needed.</p>
<p>The smart pointer library provides six smart pointer class templates:</p>
<div align="left">
<table border="1" cellpadding="4" cellspacing="0">
<tr>
<td><a href="scoped_ptr.htm"><b>scoped_ptr</b></a></td>
<td><a href="../../boost/scoped_ptr.hpp">&lt;boost/scoped_ptr.hpp&gt;</a></td>
<td>Simple sole ownership of single objects. Noncopyable.</td>
</tr>
<tr>
<td><a href="scoped_array.htm"><b>scoped_array</b></a></td>
<td><a href="../../boost/scoped_array.hpp">&lt;boost/scoped_array.hpp&gt;</a></td>
<td>Simple sole ownership of arrays. Noncopyable.</td>
</tr>
<tr>
<td><a href="shared_ptr.htm"><b>shared_ptr</b></a></td>
<td><a href="../../boost/shared_ptr.hpp">&lt;boost/shared_ptr.hpp&gt;</a></td>
<td>Object ownership shared among multiple pointers.</td>
</tr>
<tr>
<td><a href="shared_array.htm"><b>shared_array</b></a></td>
<td><a href="../../boost/shared_array.hpp">&lt;boost/shared_array.hpp&gt;</a></td>
<td>Array ownership shared among multiple pointers.</td>
</tr>
<tr>
<td><a href="weak_ptr.htm"><b>weak_ptr</b></a></td>
<td><a href="../../boost/weak_ptr.hpp">&lt;boost/weak_ptr.hpp&gt;</a></td>
<td>Non-owning observers of an object owned by <b>shared_ptr</b>.</td>
</tr>
<tr>
<td><a href="intrusive_ptr.html"><b>intrusive_ptr</b></a></td>
<td><a href="../../boost/intrusive_ptr.hpp">&lt;boost/intrusive_ptr.hpp&gt;</a></td>
<td>Shared ownership of objects with an embedded reference count.</td>
</tr>
</table>
</div>
<p>These templates are designed to complement the <b>std::auto_ptr</b> template.</p>
<p>They are examples of the "resource acquisition is initialization" idiom
described in Bjarne Stroustrup's "The C++ Programming Language", 3rd edition,
Section 14.4, Resource Management.</p>
<p>Additionally, the smart pointer library provides efficient factory functions
for creating <code>shared_ptr</code> objects:</p>
<div align="left">
<table border="1" cellpadding="4" cellspacing="0">
<tr>
<td><a href="make_shared.html"><b>make_shared and allocate_shared</b></a></td>
<td><a href="../../boost/make_shared.hpp">&lt;boost/make_shared.hpp&gt;</a></td>
<td>Efficient creation of <code>shared_ptr</code> objects.</td>
</tr>
</table>
</div>
<p>A test program, <a href="test/smart_ptr_test.cpp">smart_ptr_test.cpp</a>, is
provided to verify correct operation.</p>
<p>A page on <a href="compatibility.htm">compatibility</a> with older versions of
the Boost smart pointer library describes some of the changes since earlier
versions of the smart pointer implementation.</p>
<p>A page on <a href="smarttests.htm">smart pointer timings</a> will be of interest
to those curious about performance issues.</p>
<P>A page on <A href="sp_techniques.html">smart pointer programming techniques</A> lists
some advanced applications of <code>shared_ptr</code> and <code>weak_ptr</code>.</P>
<h2><a name="common_requirements">Common Requirements</a></h2>
<p>These smart pointer class templates have a template parameter, <b>T</b>, which
specifies the type of the object pointed to by the smart pointer. The behavior
of the smart pointer templates is undefined if the destructor or <b>operator delete</b>
for objects of type <b>T</b> throw exceptions.</p>
<p><b>T</b> may be an incomplete type at the point of smart pointer declaration.
Unless otherwise specified, it is required that <b>T</b> be a complete type at
points of smart pointer instantiation. Implementations are required to diagnose
(treat as an error) all violations of this requirement, including deletion of
an incomplete type. See the description of the <a href="../utility/utility.htm#checked_delete">
<b>checked_delete</b></a> function template.</p>
<P>Note that <STRONG>shared_ptr</STRONG> does not have this restriction, as most of
its member functions do not require <STRONG>T</STRONG> to be a complete type.</P>
<h3>Rationale</h3>
<p>The requirements on <b>T</b> are carefully crafted to maximize safety yet allow
handle-body (also called pimpl) and similar idioms. In these idioms a smart
pointer may appear in translation units where <b>T</b> is an incomplete type.
This separates interface from implementation and hides implementation from
translation units which merely use the interface. Examples described in the
documentation for specific smart pointers illustrate use of smart pointers in
these idioms.</p>
<p>Note that <b>scoped_ptr</b> requires that <b>T</b> be a complete type at
destruction time, but <b>shared_ptr</b> does not.</p>
<h2><a name="Exception_Safety">Exception Safety</a></h2>
<p>Several functions in these smart pointer classes are specified as having "no
effect" or "no effect except such-and-such" if an exception is thrown. This
means that when an exception is thrown by an object of one of these classes,
the entire program state remains the same as it was prior to the function call
which resulted in the exception being thrown. This amounts to a guarantee that
there are no detectable side effects. Other functions never throw exceptions.
The only exception ever thrown by functions which do throw (assuming <b>T</b> meets
the <a href="#common_requirements">common requirements</a>) is <b>std::bad_alloc</b>,
and that is thrown only by functions which are explicitly documented as
possibly throwing <b>std::bad_alloc</b>.</p>
<h2><a name="Exception-specifications">Exception-specifications</a></h2>
<p>Exception-specifications are not used; see <a href="http://www.boost.org/more/lib_guide.htm#Exception-specification">
exception-specification rationale</a>.</p>
<p>All the smart pointer templates contain member functions which can never throw
exceptions, because they neither throw exceptions themselves nor call other
functions which may throw exceptions. These members are indicated by a comment: <code>
// never throws</code>.
</p>
<p>Functions which destroy objects of the pointed to type are prohibited from
throwing exceptions by the <a href="#common_requirements">common requirements</a>.</p>
<h2><a name="History">History</a> and Acknowledgements</h2>
<p>January 2002. Peter Dimov reworked all four classes, adding features, fixing
bugs, and splitting them into four separate headers, and added <b>weak_ptr</b>.
See the <a href="compatibility.htm">compatibility</a> page for a summary of the
changes.</p>
<p>May 2001. Vladimir Prus suggested requiring a complete type on destruction.
Refinement evolved in discussions including Dave Abrahams, Greg Colvin, Beman
Dawes, Rainer Deyke, Peter Dimov, John Maddock, Vladimir Prus, Shankar Sai, and
others.</p>
<p>November 1999. Darin Adler provided <b>operator ==</b>, <b>operator !=</b>, and <b>std::swap</b>
and <b>std::less</b> specializations for shared types.</p>
<p>September 1999. Luis Coelho provided <b>shared_ptr::swap</b> and <b>shared_array::swap</b></p>
<p>May 1999. In April and May, 1999, Valentin Bonnard and David Abrahams made a
number of suggestions resulting in numerous improvements.</p>
<p>October 1998. Beman Dawes proposed reviving the original semantics under the
names <b>safe_ptr</b> and <b>counted_ptr</b>, meeting of Per Andersson, Matt
Austern, Greg Colvin, Sean Corfield, Pete Becker, Nico Josuttis, Dietmar K&uuml;hl,
Nathan Myers, Chichiang Wan and Judy Ward. During the discussion, the four new
class names were finalized, it was decided that there was no need to exactly
follow the <b>std::auto_ptr</b> interface, and various function signatures and
semantics were finalized.</p>
<p>Over the next three months, several implementations were considered for <b>shared_ptr</b>,
and discussed on the <a href="http://www.boost.org">boost.org</a> mailing list.
The implementation questions revolved around the reference count which must be
kept, either attached to the pointed to object, or detached elsewhere. Each of
those variants have themselves two major variants:
<ul>
<li>
Direct detached: the shared_ptr contains a pointer to the object, and a pointer
to the count.
<li>
Indirect detached: the shared_ptr contains a pointer to a helper object, which
in turn contains a pointer to the object and the count.
<li>
Embedded attached: the count is a member of the object pointed to.
<li>
Placement attached: the count is attached via operator new manipulations.</li>
</ul>
<p>Each implementation technique has advantages and disadvantages. We went so far
as to run various timings of the direct and indirect approaches, and found that
at least on Intel Pentium chips there was very little measurable difference.
Kevlin Henney provided a paper he wrote on "Counted Body Techniques." Dietmar
K&uuml;hl suggested an elegant partial template specialization technique to allow
users to choose which implementation they preferred, and that was also
experimented with.</p>
<p>But Greg Colvin and Jerry Schwarz argued that "parameterization will discourage
users", and in the end we choose to supply only the direct implementation.</p>
<p>Summer, 1994. Greg Colvin proposed to the C++ Standards Committee classes named <b>auto_ptr</b>
and <b>counted_ptr</b> which were very similar to what we now call <b>scoped_ptr</b>
and <b>shared_ptr</b>. <a href="#Col-94">[Col-94]</a> In one of the very few
cases where the Library Working Group's recommendations were not followed by
the full committee, <b>counted_ptr</b> was rejected and surprising
transfer-of-ownership semantics were added to <b>auto_ptr</b>.</p>
<h2><a name="References">References</a></h2>
<p>[<a name="Col-94">Col-94</a>] Gregory Colvin, <a href="http://std.dkuug.dk/jtc1/sc22/wg21/docs/papers/1994/N0555.pdf">
Exception Safe Smart Pointers</a>, C++ committee document 94-168/N0555,
July, 1994.</p>
<p>[<a name="E&amp;D-94">E&amp;D-94</a>] John R. Ellis &amp; David L. Detlefs, <a href="http://www.usenix.org/publications/library/proceedings/c++94/full_papers/ellis.a">
Safe, Efficient Garbage Collection for C++</a>, Usenix Proceedings,
February, 1994. This paper includes an extensive discussion of weak pointers
and an extensive bibliography.</p>
<hr>
<p>$Date$</p>
<p><small>Copyright 1999 Greg Colvin and Beman Dawes. Copyright 2002 Darin Adler.
Distributed under the Boost Software License, Version 1.0. See accompanying
file <A href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</A> or copy at
<A href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</A>.</small></p>
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<title>Smart Pointer Timings</title>
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</head>
<body bgcolor="#FFFFFF">
<h1><img src="../../boost.png" alt="boost.png (6897 bytes)" align="middle" WIDTH="277" HEIGHT="86">Smart Pointer Timings</h1>
<p>In late January 2000, Mark Borgerding put forward a suggestion to boost for
a new design of smart pointer whereby an intrusive doubly linked list is used
to join together all instances of smart pointers sharing a given raw pointer.
This allowed avoidance of the costly heap allocation of a reference count that
occurred in the initial construction of the then current version of boost::shared_ptr.
Of course, nothing is for free and the benefit here was gained at the expense
of increased size and more costly copy operations. A debate ensued on the boost
mailing list and the tests which this page describes were performed to provide
a guide for current and future investigations into smart pointer implementation
strategies.</p>
<p>Thanks are due to <a href="http://www.boost.org/people/dave_abrahams.htm">Dave Abrahams</a>,
Gavin Collings,
<a href="http://www.boost.org/people/greg_colvin.htm">Greg Colvin</a> and
<a href="http://www.boost.org/people/beman_dawes.html">Beman Dawes</a>
for test code and trial implementations, the final version of which can be found
in .zip format <a href="smarttest.zip">here</a>.</p>
<h2>Description</h2>
<p>Two tests were run: the first aimed to obtain timings for two basic individual
operations:</p>
<ol type="i">
<li> Initial construction from raw pointer.</li>
<li> An amortized copy operation consisting of half an assignment and half a
copy construction - designed to reflect average usage.</li>
</ol>
<p>The second attempted to gain more insight into normal usage by timing the fill
and sort algorithms for vectors and lists filled with the various smart pointers.</p>
<p>Five smart pointer implementation strategies were tested:</p>
<ol type="i">
<li>Counted pointer using a heap allocated reference count, this is referred
to as <b>simple counted</b>.</li>
<li>Counted pointer using a special purpose allocator for the reference count
- <b>special counted</b>.</li>
<li>Counted pointer using an intrusive reference count - <b>intrusive</b>.</li>
<li>Linked pointer as described above - <b>linked</b>.</li>
<li>Cyclic pointer, a counted implementation using a std::deque for allocation
with provision for weak pointers and garbage collection of cycles of pointers
- <b>cyclic</b>.</li>
</ol>
<p>on two compilers:</p>
<ol type="i">
<li>MSVC 6.0 service pack 3, using default release optimization mode (/O2 -
optimized for speed, no inlining of functions defined outside a class body
unless specified as inline).</li>
<li>gcc 2.95.2 using full optimization (-O3 -DNDEBUG).</li>
</ol>
<p>Additionally, generated pointer sizes (taking into account struct alignment)
were compared, as were generated code sizes for MSVC mainly by manual inspection
of generated assembly code - a necessity due to function inlining.</p>
<p>All tests were run on a PII-200 running Windows NT version 4.0</p>
<h2>&nbsp;</h2>
<h2>Operation Timing Test Results</h2>
<p>The following graphs show the overall time in nanoseconds to acquire a pointer
(default construction) perform n amortized copy operations on it and finally
release it. The initial allocation time for the contained pointer is not included,
although the time for it's deallocation is. The contained pointer pointed to
a trivial class, but for the inclusion of an intrusive reference count for the
benefit of the intrusive counted shared pointer. A dumb pointer (i.e. a smart
pointer that simply acquires and releases its contained pointer with no extra
overhead) and a raw pointer were also included for comparison.</p>
<table border="0" align="center">
<tr>
<td width="20" height="20">&nbsp;</td>
<td>&nbsp;</td>
<td width="20">&nbsp;</td>
</tr>
<tr>
<td width="20">&nbsp; </td>
<td><img src="msvcspeed.gif" width="560" height="355" alt="MSVC speed graph"></td>
<td width="20">&nbsp;</td>
</tr>
<tr>
<td height="20">&nbsp;</td>
<td>&nbsp;</td>
<td>&nbsp;</td>
</tr>
<tr>
<td>&nbsp;</td>
<td><img src="gccspeed.gif" width="560" height="355" alt="GCC speed graph"></td>
<td>&nbsp;</td>
</tr>
<tr>
<td height="20">&nbsp;</td>
<td>&nbsp;</td>
<td>&nbsp;</td>
</tr>
</table>
<p>&nbsp;</p>
<p>Fitting straight lines to the above plots gives the following figures for initialization
and amortized copy operation for the two compilers (times in nanoseconds, errors
at two standard deviations) : -</p>
<p>&nbsp;</p>
<h4 align="center">MSVC</h4>
<table align="center" cellpadding="5" cellspacing="0" class="codetable" width="400">
<tr>
<th width="120">
<div align="right"></div>
</th>
<th class="codetabletop" width="120">
<div align="center">initialization</div>
</th>
<th class="codetabletop" width="120">copy operation</th>
</tr>
<tr>
<th class="codetableleft">
<div align="right">simple counted</div>
</th>
<td class="codetablecell" align="center">3000 +/- 170</td>
<td class="codetablecell" align="center">104 +/- 31</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">special counted</div>
</th>
<td class="codetablecell" align="center">1330 +/- 50</td>
<td class="codetablecell" align="center">85 +/- 9</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">intrusive</div>
</th>
<td class="codetablecell" align="center">1000 +/- 20</td>
<td class="codetablecell" align="center">71 +/- 3</td>
</tr>
<tr>
<th class="codetableleft" align="right">linked</th>
<td class="codetablecell" align="center">970 +/- 60</td>
<td class="codetablecell" align="center">136 +/- 10</td>
</tr>
<tr>
<th class="codetableleft" align="right">cyclic</th>
<td class="codetablecell" align="center">1290 +/- 70</td>
<td class="codetablecell" align="center">112 +/- 12</td>
</tr>
<tr>
<th class="codetableleft" align="right">dumb</th>
<td class="codetablecell" align="center">1020 +/- 20</td>
<td class="codetablecell" align="center">10 +/- 4</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">raw</div>
</th>
<td class="codetablecell" align="center">1038 +/- 30</td>
<td class="codetablecell" align="center">10 +/- 5</td>
</tr>
</table>
<h4 align="center">&nbsp;</h4>
<h4 align="center">GCC</h4>
<table align="center" cellpadding="5" cellspacing="0" class="codetable" width="400">
<tr>
<th width="120">
<div align="right"></div>
</th>
<th class="codetabletop" width="120">
<div align="center">initialization</div>
</th>
<th class="codetabletop" width="120">copy operation</th>
</tr>
<tr>
<th class="codetableleft">
<div align="right">simple counted</div>
</th>
<td class="codetablecell" align="center">4620 +/- 150</td>
<td class="codetablecell" align="center">301 +/- 28</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">special counted</div>
</th>
<td class="codetablecell" align="center">1990 +/- 40</td>
<td class="codetablecell" align="center">264 +/- 7</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">intrusive</div>
</th>
<td class="codetablecell" align="center">1590 +/- 70</td>
<td class="codetablecell" align="center">181 +/- 12</td>
</tr>
<tr>
<th class="codetableleft" align="right">linked</th>
<td class="codetablecell" align="center">1470 +/- 140</td>
<td class="codetablecell" align="center">345 +/- 26</td>
</tr>
<tr>
<th class="codetableleft" align="right">cyclic</th>
<td class="codetablecell" align="center">2180 +/- 100</td>
<td class="codetablecell" align="center">330 +/- 18</td>
</tr>
<tr>
<th class="codetableleft" align="right">dumb</th>
<td class="codetablecell" align="center">1590 +/- 70</td>
<td class="codetablecell" align="center">74 +/- 12</td>
</tr>
<tr>
<th class="codetableleft" align="right">
<div align="right">raw</div>
</th>
<td class="codetablecell" align="center">1430 +/- 60</td>
<td class="codetablecell" align="center">27 +/- 11</td>
</tr>
</table>
<p>Note that the above times include a certain amount of loop overhead etc. for
each operation. An estimate of the pure smart pointer operation time 'overhead'
can be obtained by subtracting the dumb or raw figure from the smart pointer
time of interest.</p>
<h3>Detail</h3>
<p>The test involved iterating a loop which creates raw pointers. These were then
shared among a varying number (set size) of smart pointers. A range of set sizes
was used and then a line fitted to get a linear relation with number of initializations
and copy-operations. A spreadsheet was used for the line fit, and to produce
the performance graphs above.</p>
<h2>&nbsp;</h2>
<h2>Container Test Results</h2>
<p>To gain some insight in to operation within real life programs, this test was
devised. Smart pointers were used to fill standard containers which were then
sorted.</p>
<p>In this case, the contained pointer pointed to a class which initializes a
private data member to a random value in its default constructor. This value
is used subsequently for the sort comparison test. The class also contains an
intrusive reference count for the benefit of the intrusive counted pointer.</p>
<p> All times are in seconds for 300,000 contained pointers.</p>
<h4 align="center">GCC</h4>
<table align="center" cellpadding="5" cellspacing="0" class="codetable" width="500">
<tr>
<th>&nbsp;</th>
<th class="codetabletop" colspan="2">vector</th>
<th class="codetabletop" colspan="2">list</th>
</tr>
<tr>
<th width="120">
<div align="right"></div>
</th>
<th class="codetabletop2" width="80">
<div align="center">fill</div>
</th>
<th class="codetabletop2" width="80">sort</th>
<th class="codetabletop2" width="80">fill</th>
<th class="codetabletop2" width="80">sort</th>
</tr>
<tr>
<th class="codetableleft">
<div align="right">simple counted</div>
</th>
<td class="codetablecell" align="center">46.54</td>
<td class="codetablecell" align="center">2.44</td>
<td class="codetablecell" align="center">47.09</td>
<td class="codetablecell" align="center">3.22</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">special counted</div>
</th>
<td class="codetablecell" align="center">14.02</td>
<td class="codetablecell" align="center">2.83</td>
<td class="codetablecell" align="center">7.28</td>
<td class="codetablecell" align="center">3.21</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">intrusive</div>
</th>
<td class="codetablecell" align="center">12.15</td>
<td class="codetablecell" align="center">1.91</td>
<td class="codetablecell" align="center">7.99</td>
<td class="codetablecell" align="center">3.08</td>
</tr>
<tr>
<th class="codetableleft" align="right">linked</th>
<td class="codetablecell" align="center">12.46</td>
<td class="codetablecell" align="center">2.32</td>
<td class="codetablecell" align="center">8.14</td>
<td class="codetablecell" align="center">3.27</td>
</tr>
<tr>
<th class="codetableleft" align="right">cyclic</th>
<td class="codetablecell" align="center">22.60</td>
<td class="codetablecell" align="center">3.19</td>
<td class="codetablecell" align="center">1.63</td>
<td class="codetablecell" align="center">3.18</td>
</tr>
<tr>
<th class="codetableleft" align="right">
<div align="right">raw</div>
</th>
<td class="codetablecell" align="center">11.81</td>
<td class="codetablecell" align="center">0.24</td>
<td class="codetablecell" align="center">27.51</td>
<td class="codetablecell" align="center">0.77</td>
</tr>
</table>
<p>&nbsp;</p>
<h4 align="center">MSVC</h4>
<table align="center" cellpadding="5" cellspacing="0" class="codetable" width="500">
<tr>
<th>&nbsp;</th>
<th class="codetabletop" colspan="2">vector</th>
<th class="codetabletop" colspan="2">list</th>
</tr>
<tr>
<th width="120">
<div align="right"></div>
</th>
<th class="codetabletop2" width="80">
<div align="center">fill</div>
</th>
<th class="codetabletop2" width="80">sort</th>
<th class="codetabletop2" width="80">fill</th>
<th class="codetabletop2" width="80">sort</th>
</tr>
<tr>
<th class="codetableleft">
<div align="right">simple counted</div>
</th>
<td class="codetablecell" align="center">1.83</td>
<td class="codetablecell" align="center">2.37</td>
<td class="codetablecell" align="center">1.86</td>
<td class="codetablecell" align="center">4.85</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">special counted</div>
</th>
<td class="codetablecell" align="center">1.04</td>
<td class="codetablecell" align="center">2.35</td>
<td class="codetablecell" align="center">1.38</td>
<td class="codetablecell" align="center">4.58</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">intrusive</div>
</th>
<td class="codetablecell" align="center">1.04</td>
<td class="codetablecell" align="center">1.84</td>
<td class="codetablecell" align="center">1.16</td>
<td class="codetablecell" align="center">4.29</td>
</tr>
<tr>
<th class="codetableleft" align="right">linked</th>
<td class="codetablecell" align="center">1.08</td>
<td class="codetablecell" align="center">2.00</td>
<td class="codetablecell" align="center">1.21</td>
<td class="codetablecell" align="center">4.33</td>
</tr>
<tr>
<th class="codetableleft" align="right">cyclic</th>
<td class="codetablecell" align="center">1.38</td>
<td class="codetablecell" align="center">2.84</td>
<td class="codetablecell" align="center">1.47</td>
<td class="codetablecell" align="center">4.73</td>
</tr>
<tr>
<th class="codetableleft" align="right">
<div align="right">raw</div>
</th>
<td class="codetablecell" align="center">0.67</td>
<td class="codetablecell" align="center">0.28</td>
<td class="codetablecell" align="center">1.24</td>
<td class="codetablecell" align="center">1.81</td>
</tr>
</table>
<p>&nbsp;</p>
<h2>Code Size</h2>
<p>The following code sizes were determined by inspection of generated code for
MSVC only. Sizes are given in the form N / M / I where:</p>
<ul type="circle">
<li> N is the instruction count of the operation</li>
<li>M is the size of the code in bytes</li>
<li>I determines whether generated code was inlined or not I = inline, O = &quot;outline&quot;</li>
</ul>
<p>&nbsp;</p>
<table align="center" cellpadding="5" cellspacing="0" class="codetable" width="570">
<tr>
<th height="28" width="140">
<div align="right"></div>
</th>
<th height="28" class="codetabletop" width="80">
<div align="center">ptr()</div>
</th>
<th height="28" class="codetabletop" width="80">ptr(p)</th>
<th height="28" class="codetabletop" width="80">ptr(ptr)</th>
<th height="28" class="codetabletop" width="80">op=()</th>
<th height="28" class="codetabletop" width="80">
<div align="center">~ptr()</div>
</th>
</tr>
<tr>
<th class="codetableleft">
<div align="right">simple counted</div>
</th>
<td class="codetablecell" align="center">38/110/O</td>
<td class="codetablecell" align="center">38/110/O</td>
<td class="codetablecell" align="center">9/23/I</td>
<td class="codetablecell" align="center">22/57/I</td>
<td class="codetablecell" align="center">17/40/I</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">special counted</div>
</th>
<td class="codetablecell" align="center"><font size="-1">50/141/O</font></td>
<td class="codetablecell" align="center"><font size="-1">50/141/O</font></td>
<td class="codetablecell" align="center"><font size="-1">9/23/I</font></td>
<td class="codetablecell" align="center"><font size="-1">23/64/I</font></td>
<td class="codetablecell" align="center"><font size="-1">13/38/I</font></td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">intrusive</div>
</th>
<td class="codetablecell" align="center"><font size="-1">1/2/I</font></td>
<td class="codetablecell" align="center"><font size="-1">3/6/I</font></td>
<td class="codetablecell" align="center"><font size="-1">3/6/I</font></td>
<td class="codetablecell" align="center"><font size="-1">6/11/I</font></td>
<td class="codetablecell" align="center"><font size="-1">6/11/I</font></td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">linked</div>
</th>
<td class="codetablecell" align="center"><font size="-1">5/19/I</font></td>
<td class="codetablecell" align="center"><font size="-1">5/15/I</font></td>
<td class="codetablecell" align="center"><font size="-1">10/30/I</font></td>
<td class="codetablecell" align="center"><font size="-1">27/59/I</font></td>
<td class="codetablecell" align="center"><font size="-1">14/38/I</font></td>
</tr>
</table>
<p>During the code inspection, a couple of minor points were noticed: -</p>
<ul>
<li>Function inlining was critical to performance.</li>
<li>For MSVC, at least, a &quot;delete 0&quot; caused execution of 11 assembly
instructions, including a function call. So in cases where performance is
at an absolute premium it can be worth inserting the extra manual test.</li>
</ul>
<h2>&nbsp;</h2>
<h2>Data Size</h2>
<p>The following smart pointer sizes were obtained in bytes</p>
<table align="center" cellpadding="5" cellspacing="0" class="codetable" width="270">
<tr>
<th height="28" width="150">
<div align="right"></div>
</th>
<th height="28" class="codetabletop" width="60">
<div align="center">MSVC</div>
</th>
<th height="28" class="codetabletop" width="60">
<div align="center">GCC</div>
</th>
</tr>
<tr>
<th class="codetableleft">
<div align="right">simple counted</div>
</th>
<td class="codetablecell">
<div align="center">8</div>
</td>
<td class="codetablecell">
<div align="center">8</div>
</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">special counted</div>
</th>
<td class="codetablecell">
<div align="center">8</div>
</td>
<td class="codetablecell">
<div align="center">12</div>
</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">intrusive</div>
</th>
<td class="codetablecell">
<div align="center">4</div>
</td>
<td class="codetablecell">
<div align="center">4</div>
</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">linked</div>
</th>
<td class="codetablecell">
<div align="center">12</div>
</td>
<td class="codetablecell">
<div align="center">12</div>
</td>
</tr>
<tr>
<th class="codetableleft">
<div align="right">cyclic</div>
</th>
<td class="codetablecell">
<div align="center">8</div>
</td>
<td class="codetablecell">
<div align="center">8</div>
</td>
</tr>
</table>
<h2>&nbsp;</h2>
<h2>Summary</h2>
<p>The timing results mainly speak for themselves: clearly an intrusive pointer
outperforms all others and a simple heap based counted pointer has poor performance
relative to other implementations. The selection of an optimal non-intrusive
smart pointer implementation is more application dependent, however. Where small
numbers of copies are expected, it is likely that the linked implementation
will be favoured. Conversely, for larger numbers of copies a counted pointer
with some type of special purpose allocator looks like a win. Other factors
to bear in mind are: -</p>
<ul>
<li>Deterministic individual, as opposed to amortized, operation time. This
weighs against any implementation depending on an allocator.</li>
<li>Multithreaded synchronization. This weighs against an implementation which
spreads its information as in the case of linked pointer.</li>
</ul>
<hr>
<p>Revised <!--webbot bot="Timestamp" S-Type="EDITED" S-Format="%d %B %Y" startspan -->19 August 2001<!--webbot bot="Timestamp" endspan i-checksum="14767" -->
</p>
<p><EFBFBD> Copyright Gavin Collings 2000. Permission to copy, use, modify, sell
and distribute this document is granted provided this copyright notice appears in all
copies. This document is provided &quot;as is&quot; without express or implied warranty,
and with no claim as to its suitability for any purpose.</p>
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<h1><A href="../../index.htm"><IMG height="86" alt="boost.png (6897 bytes)" src="../../boost.png" width="277" align="middle"
border="0"></A>Smart Pointer Programming Techniques</h1>
<p><A href="#incomplete">Using incomplete classes for implementation hiding</A><br>
<A href="#pimpl">The "Pimpl" idiom</A><br>
<A href="#abstract">Using abstract classes for implementation hiding</A><br>
<A href="#preventing_delete">Preventing <code>delete px.get()</code></A><br>
<A href="#array">Using a <code>shared_ptr</code> to hold a pointer to an array</A><br>
<A href="#encapsulation">Encapsulating allocation details, wrapping factory
functions</A><br>
<A href="#static">Using a <code>shared_ptr</code> to hold a pointer to a statically
allocated object</A><br>
<A href="#com">Using a <code>shared_ptr</code> to hold a pointer to a COM object</A><br>
<A href="#intrusive">Using a <code>shared_ptr</code> to hold a pointer to an object
with an embedded reference count</A><br>
<A href="#another_sp">Using a <code>shared_ptr</code> to hold another shared
ownership smart pointer</A><br>
<A href="#from_raw">Obtaining a <code>shared_ptr</code> from a raw pointer</A><br>
<A href="#in_constructor">Obtaining a <code>shared_ptr</code> (<code>weak_ptr</code>)
to <code>this</code> in a constructor</A><br>
<A href="#from_this">Obtaining a <code>shared_ptr</code> to <code>this</code></A><br>
<A href="#handle">Using <code>shared_ptr</code> as a smart counted handle</A><br>
<A href="#on_block_exit">Using <code>shared_ptr</code> to execute code on block
exit</A><br>
<A href="#pvoid">Using <code>shared_ptr&lt;void&gt;</code> to hold an arbitrary
object</A><br>
<A href="#extra_data">Associating arbitrary data with heterogeneous <code>shared_ptr</code>
instances</A><br>
<A href="#as_lock">Using <code>shared_ptr</code> as a CopyConstructible mutex lock</A><br>
<A href="#wrapper">Using <code>shared_ptr</code> to wrap member function calls</A><br>
<A href="#delayed">Delayed deallocation</A><br>
<A href="#weak_without_shared">Weak pointers to objects not managed by a <code>shared_ptr</code></A><br>
</p>
<h2><A name="incomplete">Using incomplete classes for implementation hiding</A></h2>
<p>A proven technique (that works in C, too) for separating interface from
implementation is to use a pointer to an incomplete class as an opaque handle:</p>
<pre>class FILE;
FILE * fopen(char const * name, char const * mode);
void fread(FILE * f, void * data, size_t size);
void fclose(FILE * f);
</pre>
<p>It is possible to express the above interface using <code>shared_ptr</code>,
eliminating the need to manually call <code>fclose</code>:</p>
<pre>class FILE;
shared_ptr&lt;FILE&gt; fopen(char const * name, char const * mode);
void fread(shared_ptr&lt;FILE&gt; f, void * data, size_t size);
</pre>
<p>This technique relies on <code>shared_ptr</code>'s ability to execute a custom
deleter, eliminating the explicit call to <code>fclose</code>, and on the fact
that <code>shared_ptr&lt;X&gt;</code> can be copied and destroyed when <code>X</code>
is incomplete.</p>
<h2><A name="pimpl">The "Pimpl" idiom</A></h2>
<p>A C++ specific variation of the incomplete class pattern is the "Pimpl" idiom.
The incomplete class is not exposed to the user; it is hidden behind a
forwarding facade. <code>shared_ptr</code> can be used to implement a "Pimpl":</p>
<pre>// file.hpp:
class file
{
private:
class impl;
shared_ptr&lt;impl&gt; pimpl_;
public:
file(char const * name, char const * mode);
// compiler generated members are fine and useful
void read(void * data, size_t size);
};
</pre>
<pre>// file.cpp:
#include "file.hpp"
class file::impl
{
private:
impl(impl const &amp;);
impl &amp; operator=(impl const &amp;);
// private data
public:
impl(char const * name, char const * mode) { ... }
~impl() { ... }
void read(void * data, size_t size) { ... }
};
file::file(char const * name, char const * mode): pimpl_(new impl(name, mode))
{
}
void file::read(void * data, size_t size)
{
pimpl_-&gt;read(data, size);
}
</pre>
<p>The key thing to note here is that the compiler-generated copy constructor,
assignment operator, and destructor all have a sensible meaning. As a result, <code>
file</code> is <code>CopyConstructible</code> and <code>Assignable</code>,
allowing its use in standard containers.</p>
<h2><A name="abstract">Using abstract classes for implementation hiding</A></h2>
<p>Another widely used C++ idiom for separating inteface and implementation is to
use abstract base classes and factory functions. The abstract classes are
sometimes called "interfaces" and the pattern is known as "interface-based
programming". Again, <code>shared_ptr</code> can be used as the return type of
the factory functions:</p>
<pre>// X.hpp:
class X
{
public:
virtual void f() = 0;
virtual void g() = 0;
protected:
~X() {}
};
shared_ptr&lt;X&gt; createX();
</pre>
<pre>-- X.cpp:
class X_impl: public X
{
private:
X_impl(X_impl const &amp;);
X_impl &amp; operator=(X_impl const &amp;);
public:
virtual void f()
{
// ...
}
virtual void g()
{
// ...
}
};
shared_ptr&lt;X&gt; createX()
{
shared_ptr&lt;X&gt; px(new X_impl);
return px;
}
</pre>
<p>A key property of shared_ptr is that the allocation, construction, deallocation,
and destruction details are captured at the point of construction, inside the
factory function. Note the protected and nonvirtual destructor in the example
above. The client code cannot, and does not need to, delete a pointer to <code>X</code>;
the <code>shared_ptr&lt;X&gt;</code> instance returned from <code>createX</code>
will correctly call <code>~X_impl</code>.</p>
<h2><A name="preventing_delete">Preventing <code>delete px.get()</code></A></h2>
<p>It is often desirable to prevent client code from deleting a pointer that is
being managed by <code>shared_ptr</code>. The previous technique showed one
possible approach, using a protected destructor. Another alternative is to use
a private deleter:</p>
<pre>class X
{
private:
~X();
class deleter;
friend class deleter;
class deleter
{
public:
void operator()(X * p) { delete p; }
};
public:
static shared_ptr&lt;X&gt; create()
{
shared_ptr&lt;X&gt; px(new X, X::deleter());
return px;
}
};
</pre>
<h2><A name="array">Using a <code>shared_ptr</code> to hold a pointer to an array</A></h2>
<p>A <code>shared_ptr</code> can be used to hold a pointer to an array allocated
with <code>new[]</code>:</p>
<pre>shared_ptr&lt;X&gt; px(new X[1], <A href="../utility/checked_delete.html" >checked_array_deleter</A>&lt;X&gt;());
</pre>
<p>Note, however, that <code><A href="shared_array.htm">shared_array</A></code> is
often preferable, if this is an option. It has an array-specific interface,
without <code>operator*</code> and <code>operator-&gt;</code>, and does not
allow pointer conversions.</p>
<h2><A name="encapsulation">Encapsulating allocation details, wrapping factory
functions</A></h2>
<p><code>shared_ptr</code> can be used in creating C++ wrappers over existing C
style library interfaces that return raw pointers from their factory functions
to encapsulate allocation details. As an example, consider this interface,
where <code>CreateX</code> might allocate <code>X</code> from its own private
heap, <code>~X</code> may be inaccessible, or <code>X</code> may be incomplete:</p>
<pre>X * CreateX();
void DestroyX(X *);
</pre>
<p>The only way to reliably destroy a pointer returned by <code>CreateX</code> is
to call <code>DestroyX</code>.</p>
<P>Here is how a <code>shared_ptr</code>-based wrapper may look like:</P>
<pre>shared_ptr&lt;X&gt; createX()
{
shared_ptr&lt;X&gt; px(CreateX(), DestroyX);
return px;
}
</pre>
<p>Client code that calls <code>createX</code> still does not need to know how the
object has been allocated, but now the destruction is automatic.</p>
<h2><A name="static">Using a <code>shared_ptr</code> to hold a pointer to a statically
allocated object</A></h2>
<p>Sometimes it is desirable to create a <code>shared_ptr</code> to an already
existing object, so that the <code>shared_ptr</code> does not attempt to
destroy the object when there are no more references left. As an example, the
factory function:</p>
<pre>shared_ptr&lt;X&gt; createX();
</pre>
<p>in certain situations may need to return a pointer to a statically allocated <code>X</code>
instance.</p>
<P>The solution is to use a custom deleter that does nothing:</P>
<pre>struct null_deleter
{
void operator()(void const *) const
{
}
};
static X x;
shared_ptr&lt;X&gt; createX()
{
shared_ptr&lt;X&gt; px(&amp;x, null_deleter());
return px;
}
</pre>
<p>The same technique works for any object known to outlive the pointer.</p>
<h2><A name="com">Using a <code>shared_ptr</code> to hold a pointer to a COM Object</A></h2>
<p>Background: COM objects have an embedded reference count and two member
functions that manipulate it. <code>AddRef()</code> increments the count. <code>Release()</code>
decrements the count and destroys itself when the count drops to zero.</p>
<P>It is possible to hold a pointer to a COM object in a <code>shared_ptr</code>:</P>
<pre>shared_ptr&lt;IWhatever&gt; make_shared_from_COM(IWhatever * p)
{
p-&gt;AddRef();
shared_ptr&lt;IWhatever&gt; pw(p, <A href="../bind/mem_fn.html" >mem_fn</A>(&amp;IWhatever::Release));
return pw;
}
</pre>
<p>Note, however, that <code>shared_ptr</code> copies created from <code>pw</code> will
not "register" in the embedded count of the COM object; they will share the
single reference created in <code>make_shared_from_COM</code>. Weak pointers
created from <code>pw</code> will be invalidated when the last <code>shared_ptr</code>
is destroyed, regardless of whether the COM object itself is still alive.</p>
<P>As <A href="../bind/mem_fn.html#Q3">explained</A> in the <code>mem_fn</code> documentation,
you need to <A href="../bind/mem_fn.html#stdcall">#define
BOOST_MEM_FN_ENABLE_STDCALL</A> first.</P>
<h2><A name="intrusive">Using a <code>shared_ptr</code> to hold a pointer to an object
with an embedded reference count</A></h2>
<p>This is a generalization of the above technique. The example assumes that the
object implements the two functions required by <code><A href="intrusive_ptr.html">intrusive_ptr</A></code>,
<code>intrusive_ptr_add_ref</code> and <code>intrusive_ptr_release</code>:</p>
<pre>template&lt;class T&gt; struct intrusive_deleter
{
void operator()(T * p)
{
if(p) intrusive_ptr_release(p);
}
};
shared_ptr&lt;X&gt; make_shared_from_intrusive(X * p)
{
if(p) intrusive_ptr_add_ref(p);
shared_ptr&lt;X&gt; px(p, intrusive_deleter&lt;X&gt;());
return px;
}
</pre>
<h2><A name="another_sp">Using a <code>shared_ptr</code> to hold another shared
ownership smart pointer</A></h2>
<p>One of the design goals of <code>shared_ptr</code> is to be used in library
interfaces. It is possible to encounter a situation where a library takes a <code>shared_ptr</code>
argument, but the object at hand is being managed by a different reference
counted or linked smart pointer.</p>
<P>It is possible to exploit <code>shared_ptr</code>'s custom deleter feature to
wrap this existing smart pointer behind a <code>shared_ptr</code> facade:</P>
<pre>template&lt;class P&gt; struct smart_pointer_deleter
{
private:
P p_;
public:
smart_pointer_deleter(P const &amp; p): p_(p)
{
}
void operator()(void const *)
{
p_.reset();
}
P const &amp; get() const
{
return p_;
}
};
shared_ptr&lt;X&gt; make_shared_from_another(another_ptr&lt;X&gt; qx)
{
shared_ptr&lt;X&gt; px(qx.get(), smart_pointer_deleter&lt; another_ptr&lt;X&gt; &gt;(qx));
return px;
}
</pre>
<p>One subtle point is that deleters are not allowed to throw exceptions, and the
above example as written assumes that <code>p_.reset()</code> doesn't throw. If
this is not the case, <code>p_.reset()</code> should be wrapped in a <code>try {}
catch(...) {}</code> block that ignores exceptions. In the (usually
unlikely) event when an exception is thrown and ignored, <code>p_</code> will
be released when the lifetime of the deleter ends. This happens when all
references, including weak pointers, are destroyed or reset.</p>
<P>Another twist is that it is possible, given the above <code>shared_ptr</code> instance,
to recover the original smart pointer, using <code><A href="shared_ptr.htm#get_deleter">
get_deleter</A></code>:</P>
<pre>void extract_another_from_shared(shared_ptr&lt;X&gt; px)
{
typedef smart_pointer_deleter&lt; another_ptr&lt;X&gt; &gt; deleter;
if(deleter const * pd = get_deleter&lt;deleter&gt;(px))
{
another_ptr&lt;X&gt; qx = pd-&gt;get();
}
else
{
// not one of ours
}
}
</pre>
<h2><A name="from_raw">Obtaining a <code>shared_ptr</code> from a raw pointer</A></h2>
<p>Sometimes it is necessary to obtain a <code>shared_ptr</code> given a raw
pointer to an object that is already managed by another <code>shared_ptr</code>
instance. Example:</p>
<pre>void f(X * p)
{
shared_ptr&lt;X&gt; px(<i>???</i>);
}
</pre>
<p>Inside <code>f</code>, we'd like to create a <code>shared_ptr</code> to <code>*p</code>.</p>
<P>In the general case, this problem has no solution. One approach is to modify <code>f</code>
to take a <code>shared_ptr</code>, if possible:</P>
<pre>void f(shared_ptr&lt;X&gt; px);
</pre>
<p>The same transformation can be used for nonvirtual member functions, to convert
the implicit <code>this</code>:</p>
<pre>void X::f(int m);
</pre>
<p>would become a free function with a <code>shared_ptr</code> first argument:</p>
<pre>void f(shared_ptr&lt;X&gt; this_, int m);
</pre>
<p>If <code>f</code> cannot be changed, but <code>X</code> uses intrusive counting,
use <code><A href="#intrusive">make_shared_from_intrusive</A></code> described
above. Or, if it's known that the <code>shared_ptr</code> created in <code>f</code>
will never outlive the object, use <A href="#static">a null deleter</A>.</p>
<h2><A name="in_constructor">Obtaining a <code>shared_ptr</code> (<code>weak_ptr</code>)
to <code>this</code> in a constructor</A></h2>
<p>Some designs require objects to register themselves on construction with a
central authority. When the registration routines take a shared_ptr, this leads
to the question how could a constructor obtain a shared_ptr to this:</p>
<pre>class X
{
public:
X()
{
shared_ptr&lt;X&gt; this_(<i>???</i>);
}
};
</pre>
<p>In the general case, the problem cannot be solved. The <code>X</code> instance
being constructed can be an automatic variable or a static variable; it can be
created on the heap:</p>
<pre>shared_ptr&lt;X&gt; px(new X);</pre>
<P>but at construction time, <code>px</code> does not exist yet, and it is
impossible to create another <code>shared_ptr</code> instance that shares
ownership with it.</P>
<P>Depending on context, if the inner <code>shared_ptr</code> <code>this_</code> doesn't
need to keep the object alive, use a <code>null_deleter</code> as explained <A href="#static">
here</A> and <A href="#weak_without_shared">here</A>. If <code>X</code> is
supposed to always live on the heap, and be managed by a <code>shared_ptr</code>,
use a static factory function:</P>
<pre>class X
{
private:
X() { ... }
public:
static shared_ptr&lt;X&gt; create()
{
shared_ptr&lt;X&gt; px(new X);
// use px as 'this_'
return px;
}
};
</pre>
<h2><A name="from_this">Obtaining a <code>shared_ptr</code> to <code>this</code></A></h2>
<p>Sometimes it is needed to obtain a <code>shared_ptr</code> from <code>this</code>
in a virtual member function under the assumption that <code>this</code> is
already managed by a <code>shared_ptr</code>. The transformations <A href="#from_raw">
described in the previous technique</A> cannot be applied.</p>
<P>A typical example:</P>
<pre>class X
{
public:
virtual void f() = 0;
protected:
~X() {}
};
class Y
{
public:
virtual shared_ptr&lt;X&gt; getX() = 0;
protected:
~Y() {}
};
// --
class impl: public X, public Y
{
public:
impl() { ... }
virtual void f() { ... }
virtual shared_ptr&lt;X&gt; getX()
{
shared_ptr&lt;X&gt; px(<i>???</i>);
return px;
}
};
</pre>
<p>The solution is to keep a weak pointer to <code>this</code> as a member in <code>impl</code>:</p>
<pre>class impl: public X, public Y
{
private:
weak_ptr&lt;impl&gt; weak_this;
impl(impl const &amp;);
impl &amp; operator=(impl const &amp;);
impl() { ... }
public:
static shared_ptr&lt;impl&gt; create()
{
shared_ptr&lt;impl&gt; pi(new impl);
pi-&gt;weak_this = pi;
return pi;
}
virtual void f() { ... }
virtual shared_ptr&lt;X&gt; getX()
{
shared_ptr&lt;X&gt; px(weak_this);
return px;
}
};
</pre>
<p>The library now includes a helper class template <code><A href="enable_shared_from_this.html">
enable_shared_from_this</A></code> that can be used to encapsulate the
solution:</p>
<pre>class impl: public X, public Y, public enable_shared_from_this&lt;impl&gt;
{
public:
impl(impl const &amp;);
impl &amp; operator=(impl const &amp;);
public:
virtual void f() { ... }
virtual shared_ptr&lt;X&gt; getX()
{
return shared_from_this();
}
}
</pre>
<p>Note that you no longer need to manually initialize the <code>weak_ptr</code> member
in <code><A href="enable_shared_from_this.html">enable_shared_from_this</A></code>.
Constructing a <code>shared_ptr</code> to <code>impl</code> takes care of that.</p>
<h2><A name="handle">Using <code>shared_ptr</code> as a smart counted handle</A></h2>
<p>Some library interfaces use opaque handles, a variation of the <A href="#incomplete">
incomplete class technique</A> described above. An example:</p>
<pre>typedef void * HANDLE;
HANDLE CreateProcess();
void CloseHandle(HANDLE);
</pre>
<p>Instead of a raw pointer, it is possible to use <code>shared_ptr</code> as the
handle and get reference counting and automatic resource management for free:</p>
<pre>typedef shared_ptr&lt;void&gt; handle;
handle createProcess()
{
shared_ptr&lt;void&gt; pv(CreateProcess(), CloseHandle);
return pv;
}
</pre>
<h2><A name="on_block_exit">Using <code>shared_ptr</code> to execute code on block exit</A></h2>
<p><code>shared_ptr&lt;void&gt;</code> can automatically execute cleanup code when
control leaves a scope.</p>
<UL>
<LI>
Executing <code>f(p)</code>, where <code>p</code> is a pointer:</LI></UL>
<pre> shared_ptr&lt;void&gt; guard(p, f);
</pre>
<UL>
<LI>
Executing arbitrary code: <code>f(x, y)</code>:</LI></UL>
<pre> shared_ptr&lt;void&gt; guard(static_cast&lt;void*&gt;(0), <A href="../bind/bind.html" >bind</A>(f, x, y));
</pre>
<P>For a more thorough treatment, see the article "Simplify Your Exception-Safe
Code" by Andrei Alexandrescu and Petru Marginean, available online at <A href="http://www.cuj.com/experts/1812/alexandr.htm?topic=experts">
http://www.cuj.com/experts/1812/alexandr.htm?topic=experts</A>.</P>
<h2><A name="pvoid">Using <code>shared_ptr&lt;void&gt;</code> to hold an arbitrary
object</A></h2>
<p><code>shared_ptr&lt;void&gt;</code> can act as a generic object pointer similar
to <code>void*</code>. When a <code>shared_ptr&lt;void&gt;</code> instance
constructed as:</p>
<pre> shared_ptr&lt;void&gt; pv(new X);
</pre>
<p>is destroyed, it will correctly dispose of the <code>X</code> object by
executing <code>~X</code>.</p>
<p>This propery can be used in much the same manner as a raw <code>void*</code> is
used to temporarily strip type information from an object pointer. A <code>shared_ptr&lt;void&gt;</code>
can later be cast back to the correct type by using <code><A href="shared_ptr.htm#static_pointer_cast">
static_pointer_cast</A></code>.</p>
<h2><A name="extra_data">Associating arbitrary data with heterogeneous <code>shared_ptr</code>
instances</A></h2>
<p><code>shared_ptr</code> and <code>weak_ptr</code> support <code>operator&lt;</code>
comparisons required by standard associative containers such as <code>std::map</code>.
This can be used to non-intrusively associate arbitrary data with objects
managed by <code>shared_ptr</code>:</p>
<pre>typedef int Data;
std::map&lt; shared_ptr&lt;void&gt;, Data &gt; userData;
// or std::map&lt; weak_ptr&lt;void&gt;, Data &gt; userData; to not affect the lifetime
shared_ptr&lt;X&gt; px(new X);
shared_ptr&lt;int&gt; pi(new int(3));
userData[px] = 42;
userData[pi] = 91;
</pre>
<h2><A name="as_lock">Using <code>shared_ptr</code> as a CopyConstructible mutex lock</A></h2>
<p>Sometimes it's necessary to return a mutex lock from a function, and a
noncopyable lock cannot be returned by value. It is possible to use <code>shared_ptr</code>
as a mutex lock:</p>
<pre>class mutex
{
public:
void lock();
void unlock();
};
shared_ptr&lt;mutex&gt; lock(mutex &amp; m)
{
m.lock();
return shared_ptr&lt;mutex&gt;(&amp;m, mem_fn(&amp;mutex::unlock));
}
</pre>
<p>Better yet, the <code>shared_ptr</code> instance acting as a lock can be
encapsulated in a dedicated <code>shared_lock</code> class:</p>
<pre>class shared_lock
{
private:
shared_ptr&lt;void&gt; pv;
public:
template&lt;class Mutex&gt; explicit shared_lock(Mutex &amp; m): pv((m.lock(), &amp;m), mem_fn(&amp;Mutex::unlock)) {}
};
</pre>
<p><code>shared_lock</code> can now be used as:</p>
<pre> shared_lock lock(m);
</pre>
<p>Note that <code>shared_lock</code> is not templated on the mutex type, thanks to <code>
shared_ptr&lt;void&gt;</code>'s ability to hide type information.</p>
<h2><A name="wrapper">Using <code>shared_ptr</code> to wrap member function calls</A></h2>
<p><code>shared_ptr</code> implements the ownership semantics required from the <code>Wrap</code>/<code>CallProxy</code>
scheme described in Bjarne Stroustrup's article "Wrapping C++ Member Function
Calls" (available online at <A href="http://www.research.att.com/~bs/wrapper.pdf">http://www.research.att.com/~bs/wrapper.pdf</A>).
An implementation is given below:</p>
<pre>template&lt;class T&gt; class pointer
{
private:
T * p_;
public:
explicit pointer(T * p): p_(p)
{
}
shared_ptr&lt;T&gt; operator-&gt;() const
{
p_-&gt;prefix();
return shared_ptr&lt;T&gt;(p_, <A href="../bind/mem_fn.html" >mem_fn</A>(&amp;T::suffix));
}
};
class X
{
private:
void prefix();
void suffix();
friend class pointer&lt;X&gt;;
public:
void f();
void g();
};
int main()
{
X x;
pointer&lt;X&gt; px(&amp;x);
px-&gt;f();
px-&gt;g();
}
</pre>
<h2><A name="delayed">Delayed deallocation</A></h2>
<p>In some situations, a single <code>px.reset()</code> can trigger an expensive
deallocation in a performance-critical region:</p>
<pre>class X; // ~X is expensive
class Y
{
shared_ptr&lt;X&gt; px;
public:
void f()
{
px.reset();
}
};
</pre>
<p>The solution is to postpone the potential deallocation by moving <code>px</code>
to a dedicated free list that can be periodically emptied when performance and
response times are not an issue:</p>
<pre>vector&lt; shared_ptr&lt;void&gt; &gt; free_list;
class Y
{
shared_ptr&lt;X&gt; px;
public:
void f()
{
free_list.push_back(px);
px.reset();
}
};
// periodically invoke free_list.clear() when convenient
</pre>
<p>Another variation is to move the free list logic to the construction point by
using a delayed deleter:</p>
<pre>struct delayed_deleter
{
template&lt;class T&gt; void operator()(T * p)
{
try
{
shared_ptr&lt;void&gt; pv(p);
free_list.push_back(pv);
}
catch(...)
{
}
}
};
</pre>
<h2><A name="weak_without_shared">Weak pointers to objects not managed by a <code>shared_ptr</code></A></h2>
<p>Make the object hold a <code>shared_ptr</code> to itself, using a <code>null_deleter</code>:</p>
<pre>class X
{
private:
shared_ptr&lt;X&gt; this_;
int i_;
public:
explicit X(int i): this_(this, null_deleter()), i_(i)
{
}
// repeat in all constructors (including the copy constructor!)
X(X const &amp; rhs): this_(this, null_deleter()), i_(rhs.i_)
{
}
// do not forget to not assign this_ in the copy assignment
X &amp; operator=(X const &amp; rhs)
{
i_ = rhs.i_;
}
weak_ptr&lt;X&gt; get_weak_ptr() const { return this_; }
};
</pre>
<p>When the object's lifetime ends, <code>X::this_</code> will be destroyed, and
all weak pointers will automatically expire.</p>
<hr>
<p>$Date$</p>
<p><small>Copyright <20> 2003 Peter Dimov. Distributed under the Boost Software License, Version
1.0. See accompanying file <A href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</A> or
copy at <A href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</A>.</small></p>
</body>
</html>

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//
// sp_collector.cpp
//
// Copyright (c) 2002, 2003 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)
//
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
#include <boost/assert.hpp>
#include <boost/shared_ptr.hpp>
#include <boost/detail/lightweight_mutex.hpp>
#include <cstdlib>
#include <map>
#include <deque>
#include <iostream>
typedef std::map< void const *, std::pair<void *, size_t> > map_type;
static map_type & get_map()
{
static map_type m;
return m;
}
typedef boost::detail::lightweight_mutex mutex_type;
static mutex_type & get_mutex()
{
static mutex_type m;
return m;
}
static void * init_mutex_before_main = &get_mutex();
namespace
{
class X;
struct count_layout
{
boost::detail::sp_counted_base * pi;
int id;
};
struct shared_ptr_layout
{
X * px;
count_layout pn;
};
}
// assume 4 byte alignment for pointers when scanning
size_t const pointer_align = 4;
typedef std::map<void const *, long> map2_type;
static void scan_and_count(void const * area, size_t size, map_type const & m, map2_type & m2)
{
unsigned char const * p = static_cast<unsigned char const *>(area);
for(size_t n = 0; n + sizeof(shared_ptr_layout) <= size; p += pointer_align, n += pointer_align)
{
shared_ptr_layout const * q = reinterpret_cast<shared_ptr_layout const *>(p);
if(q->pn.id == boost::detail::shared_count_id && q->pn.pi != 0 && m.count(q->pn.pi) != 0)
{
++m2[q->pn.pi];
}
}
}
typedef std::deque<void const *> open_type;
static void scan_and_mark(void const * area, size_t size, map2_type & m2, open_type & open)
{
unsigned char const * p = static_cast<unsigned char const *>(area);
for(size_t n = 0; n + sizeof(shared_ptr_layout) <= size; p += pointer_align, n += pointer_align)
{
shared_ptr_layout const * q = reinterpret_cast<shared_ptr_layout const *>(p);
if(q->pn.id == boost::detail::shared_count_id && q->pn.pi != 0 && m2.count(q->pn.pi) != 0)
{
open.push_back(q->pn.pi);
m2.erase(q->pn.pi);
}
}
}
static void find_unreachable_objects_impl(map_type const & m, map2_type & m2)
{
// scan objects for shared_ptr members, compute internal counts
{
std::cout << "... " << m.size() << " objects in m.\n";
for(map_type::const_iterator i = m.begin(); i != m.end(); ++i)
{
boost::detail::sp_counted_base const * p = static_cast<boost::detail::sp_counted_base const *>(i->first);
BOOST_ASSERT(p->use_count() != 0); // there should be no inactive counts in the map
m2[ i->first ];
scan_and_count(i->second.first, i->second.second, m, m2);
}
std::cout << "... " << m2.size() << " objects in m2.\n";
}
// mark reachable objects
{
open_type open;
for(map2_type::iterator i = m2.begin(); i != m2.end(); ++i)
{
boost::detail::sp_counted_base const * p = static_cast<boost::detail::sp_counted_base const *>(i->first);
if(p->use_count() != i->second) open.push_back(p);
}
std::cout << "... " << open.size() << " objects in open.\n";
for(open_type::iterator j = open.begin(); j != open.end(); ++j)
{
m2.erase(*j);
}
while(!open.empty())
{
void const * p = open.front();
open.pop_front();
map_type::const_iterator i = m.find(p);
BOOST_ASSERT(i != m.end());
scan_and_mark(i->second.first, i->second.second, m2, open);
}
}
// m2 now contains the unreachable objects
}
std::size_t find_unreachable_objects(bool report)
{
map2_type m2;
#ifdef BOOST_HAS_THREADS
// This will work without the #ifdef, but some compilers warn
// that lock is not referenced
mutex_type::scoped_lock lock(get_mutex());
#endif
map_type const & m = get_map();
find_unreachable_objects_impl(m, m2);
if(report)
{
for(map2_type::iterator j = m2.begin(); j != m2.end(); ++j)
{
map_type::const_iterator i = m.find(j->first);
BOOST_ASSERT(i != m.end());
std::cout << "Unreachable object at " << i->second.first << ", " << i->second.second << " bytes long.\n";
}
}
return m2.size();
}
typedef std::deque< boost::shared_ptr<X> > free_list_type;
static void scan_and_free(void * area, size_t size, map2_type const & m2, free_list_type & free)
{
unsigned char * p = static_cast<unsigned char *>(area);
for(size_t n = 0; n + sizeof(shared_ptr_layout) <= size; p += pointer_align, n += pointer_align)
{
shared_ptr_layout * q = reinterpret_cast<shared_ptr_layout *>(p);
if(q->pn.id == boost::detail::shared_count_id && q->pn.pi != 0 && m2.count(q->pn.pi) != 0 && q->px != 0)
{
boost::shared_ptr<X> * ppx = reinterpret_cast< boost::shared_ptr<X> * >(p);
free.push_back(*ppx);
ppx->reset();
}
}
}
void free_unreachable_objects()
{
free_list_type free;
{
map2_type m2;
#ifdef BOOST_HAS_THREADS
mutex_type::scoped_lock lock(get_mutex());
#endif
map_type const & m = get_map();
find_unreachable_objects_impl(m, m2);
for(map2_type::iterator j = m2.begin(); j != m2.end(); ++j)
{
map_type::const_iterator i = m.find(j->first);
BOOST_ASSERT(i != m.end());
scan_and_free(i->second.first, i->second.second, m2, free);
}
}
std::cout << "... about to free " << free.size() << " objects.\n";
}
// debug hooks
namespace boost
{
void sp_scalar_constructor_hook(void *)
{
}
void sp_scalar_constructor_hook(void * px, std::size_t size, void * pn)
{
#ifdef BOOST_HAS_THREADS
mutex_type::scoped_lock lock(get_mutex());
#endif
get_map()[pn] = std::make_pair(px, size);
}
void sp_scalar_destructor_hook(void *)
{
}
void sp_scalar_destructor_hook(void *, std::size_t, void * pn)
{
#ifdef BOOST_HAS_THREADS
mutex_type::scoped_lock lock(get_mutex());
#endif
get_map().erase(pn);
}
void sp_array_constructor_hook(void *)
{
}
void sp_array_destructor_hook(void *)
{
}
} // namespace boost
#endif // defined(BOOST_SP_ENABLE_DEBUG_HOOKS)

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//
// sp_debug_hooks.cpp
//
// Copyright (c) 2002, 2003 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)
//
#if defined(BOOST_SP_ENABLE_DEBUG_HOOKS)
#include <boost/assert.hpp>
#include <new>
#include <cstdlib>
int const m = 2; // m * sizeof(int) must be aligned appropriately
// magic values to mark heap blocks with
int const allocated_scalar = 0x1234560C;
int const allocated_array = 0x1234560A;
int const adopted_scalar = 0x0567890C;
int const adopted_array = 0x0567890A;
int const deleted = 0x498769DE;
using namespace std; // for compilers where things aren't in std
// operator new
static new_handler get_new_handler()
{
new_handler p = set_new_handler(0);
set_new_handler(p);
return p;
}
static void * allocate(size_t n, int mark)
{
int * pm;
for(;;)
{
pm = static_cast<int*>(malloc(n + m * sizeof(int)));
if(pm != 0) break;
if(new_handler pnh = get_new_handler())
{
pnh();
}
else
{
return 0;
}
}
*pm = mark;
return pm + m;
}
void * operator new(size_t n) throw(bad_alloc)
{
void * p = allocate(n, allocated_scalar);
#if !defined(BOOST_NO_EXCEPTIONS)
if(p == 0) throw bad_alloc();
#endif
return p;
}
#if !defined(__BORLANDC__) || (__BORLANDC__ > 0x551)
void * operator new(size_t n, nothrow_t const &) throw()
{
return allocate(n, allocated_scalar);
}
#endif
void * operator new[](size_t n) throw(bad_alloc)
{
void * p = allocate(n, allocated_array);
#if !defined(BOOST_NO_EXCEPTIONS)
if(p == 0) throw bad_alloc();
#endif
return p;
}
#if !defined(__BORLANDC__) || (__BORLANDC__ > 0x551)
void * operator new[](size_t n, nothrow_t const &) throw()
{
return allocate(n, allocated_array);
}
#endif
// debug hooks
namespace boost
{
void sp_scalar_constructor_hook(void * p)
{
if(p == 0) return;
int * pm = static_cast<int*>(p);
pm -= m;
BOOST_ASSERT(*pm != adopted_scalar); // second smart pointer to the same address
BOOST_ASSERT(*pm != allocated_array); // allocated with new[]
BOOST_ASSERT(*pm == allocated_scalar); // not allocated with new
*pm = adopted_scalar;
}
void sp_scalar_constructor_hook(void * px, std::size_t, void *)
{
sp_scalar_constructor_hook(px);
}
void sp_scalar_destructor_hook(void * p)
{
if(p == 0) return;
int * pm = static_cast<int*>(p);
pm -= m;
BOOST_ASSERT(*pm == adopted_scalar); // attempt to destroy nonmanaged block
*pm = allocated_scalar;
}
void sp_scalar_destructor_hook(void * px, std::size_t, void *)
{
sp_scalar_destructor_hook(px);
}
// It is not possible to handle the array hooks in a portable manner.
// The implementation typically reserves a bit of storage for the number
// of objects in the array, and the argument of the array hook isn't
// equal to the return value of operator new[].
void sp_array_constructor_hook(void * /* p */)
{
/*
if(p == 0) return;
// adjust p depending on the implementation
int * pm = static_cast<int*>(p);
pm -= m;
BOOST_ASSERT(*pm != adopted_array); // second smart array pointer to the same address
BOOST_ASSERT(*pm != allocated_scalar); // allocated with new
BOOST_ASSERT(*pm == allocated_array); // not allocated with new[]
*pm = adopted_array;
*/
}
void sp_array_destructor_hook(void * /* p */)
{
/*
if(p == 0) return;
// adjust p depending on the implementation
int * pm = static_cast<int*>(p);
pm -= m;
BOOST_ASSERT(*pm == adopted_array); // attempt to destroy nonmanaged block
*pm = allocated_array;
*/
}
} // namespace boost
// operator delete
void operator delete(void * p) throw()
{
if(p == 0) return;
int * pm = static_cast<int*>(p);
pm -= m;
BOOST_ASSERT(*pm != deleted); // double delete
BOOST_ASSERT(*pm != adopted_scalar); // delete p.get();
BOOST_ASSERT(*pm != allocated_array); // allocated with new[]
BOOST_ASSERT(*pm == allocated_scalar); // not allocated with new
*pm = deleted;
free(pm);
}
#if !defined(__BORLANDC__) || (__BORLANDC__ > 0x551)
void operator delete(void * p, nothrow_t const &) throw()
{
::operator delete(p);
}
#endif
void operator delete[](void * p) throw()
{
if(p == 0) return;
int * pm = static_cast<int*>(p);
pm -= m;
BOOST_ASSERT(*pm != deleted); // double delete
BOOST_ASSERT(*pm != adopted_scalar); // delete p.get();
BOOST_ASSERT(*pm != allocated_scalar); // allocated with new
BOOST_ASSERT(*pm == allocated_array); // not allocated with new[]
*pm = deleted;
free(pm);
}
#if !defined(__BORLANDC__) || (__BORLANDC__ > 0x551)
void operator delete[](void * p, nothrow_t const &) throw()
{
::operator delete[](p);
}
#endif
#endif // defined(BOOST_SP_ENABLE_DEBUG_HOOKS)

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# Boost.SmartPtr Library test Jamfile
#
# Copyright (c) 2003-2007 Peter Dimov
# Copyright (c) 2003 Dave Abrahams
#
# 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)
# bring in rules for testing
import testing ;
{
test-suite "smart_ptr"
: [ run smart_ptr_test.cpp ]
[ run shared_ptr_basic_test.cpp : : : <toolset>gcc:<cxxflags>-Wno-non-virtual-dtor ]
[ run shared_ptr_test.cpp : : : <toolset>gcc:<cxxflags>-Wno-non-virtual-dtor ]
[ run weak_ptr_test.cpp ]
[ run weak_ptr_move_test.cpp ]
[ run shared_from_this_test.cpp : : : <toolset>gcc:<cxxflags>-Wno-non-virtual-dtor ]
[ run get_deleter_test.cpp ]
[ run intrusive_ptr_test.cpp ]
[ run intrusive_ptr_move_test.cpp ]
[ run atomic_count_test.cpp ]
[ run lw_mutex_test.cpp ]
[ compile-fail shared_ptr_assign_fail.cpp ]
[ compile-fail shared_ptr_delete_fail.cpp ]
[ compile-fail shared_ptr_compare_fail.cpp ]
[ run shared_ptr_alloc2_test.cpp ]
[ run pointer_cast_test.cpp ]
[ compile pointer_to_other_test.cpp ]
[ run auto_ptr_rv_test.cpp ]
[ run shared_ptr_alias_test.cpp ]
[ run shared_ptr_rv_test.cpp ]
[ run shared_ptr_move_test.cpp ]
[ compile-fail shared_ptr_pv_fail.cpp ]
[ run sp_unary_addr_test.cpp ]
[ compile-fail scoped_ptr_eq_fail.cpp ]
[ compile-fail scoped_array_eq_fail.cpp ]
[ run esft_regtest.cpp ]
[ run yield_k_test.cpp ]
[ run yield_k_test.cpp : : : <threading>multi : yield_k_test.mt ]
[ run spinlock_test.cpp ]
[ run spinlock_try_test.cpp ]
[ run spinlock_try_test.cpp : : : <threading>multi : spinlock_try_test.mt ]
[ run spinlock_pool_test.cpp ]
[ run make_shared_test.cpp ]
[ run sp_convertible_test.cpp ]
[ run wp_convertible_test.cpp ]
[ run ip_convertible_test.cpp ]
[ run allocate_shared_test.cpp ]
[ run sp_atomic_test.cpp ]
[ run esft_void_test.cpp ]
[ run esft_second_ptr_test.cpp ]
[ run make_shared_esft_test.cpp ]
[ run allocate_shared_esft_test.cpp ]
[ run sp_recursive_assign_test.cpp ]
[ run sp_recursive_assign2_test.cpp ]
[ run sp_recursive_assign_rv_test.cpp ]
[ run sp_recursive_assign2_rv_test.cpp ]
[ run esft_constructor_test.cpp ]
[ compile-fail auto_ptr_lv_fail.cpp ]
[ run atomic_count_test2.cpp ]
;
}

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// allocate_shared_esft_test.cpp
//
// Copyright 2007-2009 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/make_shared.hpp>
#include <boost/shared_ptr.hpp>
#include <boost/enable_shared_from_this.hpp>
#include <memory>
class X: public boost::enable_shared_from_this<X>
{
private:
X( X const & );
X & operator=( X const & );
public:
static int instances;
explicit X( int = 0, int = 0, int = 0, int = 0, int = 0, int = 0, int = 0, int = 0, int = 0 )
{
++instances;
}
~X()
{
--instances;
}
};
int X::instances = 0;
int main()
{
BOOST_TEST( X::instances == 0 );
{
boost::shared_ptr< X > px = boost::allocate_shared< X >( std::allocator<void>() );
BOOST_TEST( X::instances == 1 );
try
{
boost::shared_ptr< X > qx = px->shared_from_this();
BOOST_TEST( px == qx );
BOOST_TEST( !( px < qx ) && !( qx < px ) );
px.reset();
BOOST_TEST( X::instances == 1 );
}
catch( boost::bad_weak_ptr const& )
{
BOOST_ERROR( "px->shared_from_this() failed" );
}
}
BOOST_TEST( X::instances == 0 );
{
boost::shared_ptr< X > px = boost::allocate_shared< X >( std::allocator<void>(), 1 );
BOOST_TEST( X::instances == 1 );
try
{
boost::shared_ptr< X > qx = px->shared_from_this();
BOOST_TEST( px == qx );
BOOST_TEST( !( px < qx ) && !( qx < px ) );
px.reset();
BOOST_TEST( X::instances == 1 );
}
catch( boost::bad_weak_ptr const& )
{
BOOST_ERROR( "px->shared_from_this() failed" );
}
}
BOOST_TEST( X::instances == 0 );
{
boost::shared_ptr< X > px = boost::allocate_shared< X >( std::allocator<void>(), 1, 2 );
BOOST_TEST( X::instances == 1 );
try
{
boost::shared_ptr< X > qx = px->shared_from_this();
BOOST_TEST( px == qx );
BOOST_TEST( !( px < qx ) && !( qx < px ) );
px.reset();
BOOST_TEST( X::instances == 1 );
}
catch( boost::bad_weak_ptr const& )
{
BOOST_ERROR( "px->shared_from_this() failed" );
}
}
BOOST_TEST( X::instances == 0 );
{
boost::shared_ptr< X > px = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3 );
BOOST_TEST( X::instances == 1 );
try
{
boost::shared_ptr< X > qx = px->shared_from_this();
BOOST_TEST( px == qx );
BOOST_TEST( !( px < qx ) && !( qx < px ) );
px.reset();
BOOST_TEST( X::instances == 1 );
}
catch( boost::bad_weak_ptr const& )
{
BOOST_ERROR( "px->shared_from_this() failed" );
}
}
BOOST_TEST( X::instances == 0 );
{
boost::shared_ptr< X > px = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4 );
BOOST_TEST( X::instances == 1 );
try
{
boost::shared_ptr< X > qx = px->shared_from_this();
BOOST_TEST( px == qx );
BOOST_TEST( !( px < qx ) && !( qx < px ) );
px.reset();
BOOST_TEST( X::instances == 1 );
}
catch( boost::bad_weak_ptr const& )
{
BOOST_ERROR( "px->shared_from_this() failed" );
}
}
BOOST_TEST( X::instances == 0 );
{
boost::shared_ptr< X > px = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4, 5 );
BOOST_TEST( X::instances == 1 );
try
{
boost::shared_ptr< X > qx = px->shared_from_this();
BOOST_TEST( px == qx );
BOOST_TEST( !( px < qx ) && !( qx < px ) );
px.reset();
BOOST_TEST( X::instances == 1 );
}
catch( boost::bad_weak_ptr const& )
{
BOOST_ERROR( "px->shared_from_this() failed" );
}
}
BOOST_TEST( X::instances == 0 );
{
boost::shared_ptr< X > px = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4, 5, 6 );
BOOST_TEST( X::instances == 1 );
try
{
boost::shared_ptr< X > qx = px->shared_from_this();
BOOST_TEST( px == qx );
BOOST_TEST( !( px < qx ) && !( qx < px ) );
px.reset();
BOOST_TEST( X::instances == 1 );
}
catch( boost::bad_weak_ptr const& )
{
BOOST_ERROR( "px->shared_from_this() failed" );
}
}
BOOST_TEST( X::instances == 0 );
{
boost::shared_ptr< X > px = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4, 5, 6, 7 );
BOOST_TEST( X::instances == 1 );
try
{
boost::shared_ptr< X > qx = px->shared_from_this();
BOOST_TEST( px == qx );
BOOST_TEST( !( px < qx ) && !( qx < px ) );
px.reset();
BOOST_TEST( X::instances == 1 );
}
catch( boost::bad_weak_ptr const& )
{
BOOST_ERROR( "px->shared_from_this() failed" );
}
}
BOOST_TEST( X::instances == 0 );
{
boost::shared_ptr< X > px = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4, 5, 6, 7, 8 );
BOOST_TEST( X::instances == 1 );
try
{
boost::shared_ptr< X > qx = px->shared_from_this();
BOOST_TEST( px == qx );
BOOST_TEST( !( px < qx ) && !( qx < px ) );
px.reset();
BOOST_TEST( X::instances == 1 );
}
catch( boost::bad_weak_ptr const& )
{
BOOST_ERROR( "px->shared_from_this() failed" );
}
}
BOOST_TEST( X::instances == 0 );
{
boost::shared_ptr< X > px = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4, 5, 6, 7, 8, 9 );
BOOST_TEST( X::instances == 1 );
try
{
boost::shared_ptr< X > qx = px->shared_from_this();
BOOST_TEST( px == qx );
BOOST_TEST( !( px < qx ) && !( qx < px ) );
px.reset();
BOOST_TEST( X::instances == 1 );
}
catch( boost::bad_weak_ptr const& )
{
BOOST_ERROR( "px->shared_from_this() failed" );
}
}
BOOST_TEST( X::instances == 0 );
return boost::report_errors();
}

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// allocate_shared_test.cpp
//
// Copyright 2007-2009 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/make_shared.hpp>
#include <boost/shared_ptr.hpp>
#include <boost/weak_ptr.hpp>
#include <cstddef>
class X
{
private:
X( X const & );
X & operator=( X const & );
void * operator new( std::size_t n )
{
// lack of this definition causes link errors on Comeau C++
BOOST_ERROR( "private X::new called" );
return ::operator new( n );
}
void operator delete( void * p )
{
// lack of this definition causes link errors on MSVC
BOOST_ERROR( "private X::delete called" );
::operator delete( p );
}
public:
static int instances;
int v;
explicit X( int a1 = 0, int a2 = 0, int a3 = 0, int a4 = 0, int a5 = 0, int a6 = 0, int a7 = 0, int a8 = 0, int a9 = 0 ): v( a1+a2+a3+a4+a5+a6+a7+a8+a9 )
{
++instances;
}
~X()
{
--instances;
}
};
int X::instances = 0;
int main()
{
{
boost::shared_ptr< int > pi = boost::allocate_shared< int >( std::allocator<int>() );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( *pi == 0 );
}
{
boost::shared_ptr< int > pi = boost::allocate_shared< int >( std::allocator<int>(), 5 );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( *pi == 5 );
}
BOOST_TEST( X::instances == 0 );
{
boost::shared_ptr< X > pi = boost::allocate_shared< X >( std::allocator<void>() );
boost::weak_ptr<X> wp( pi );
BOOST_TEST( X::instances == 1 );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( pi->v == 0 );
pi.reset();
BOOST_TEST( X::instances == 0 );
}
{
boost::shared_ptr< X > pi = boost::allocate_shared< X >( std::allocator<void>(), 1 );
boost::weak_ptr<X> wp( pi );
BOOST_TEST( X::instances == 1 );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( pi->v == 1 );
pi.reset();
BOOST_TEST( X::instances == 0 );
}
{
boost::shared_ptr< X > pi = boost::allocate_shared< X >( std::allocator<void>(), 1, 2 );
boost::weak_ptr<X> wp( pi );
BOOST_TEST( X::instances == 1 );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( pi->v == 1+2 );
pi.reset();
BOOST_TEST( X::instances == 0 );
}
{
boost::shared_ptr< X > pi = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3 );
boost::weak_ptr<X> wp( pi );
BOOST_TEST( X::instances == 1 );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( pi->v == 1+2+3 );
pi.reset();
BOOST_TEST( X::instances == 0 );
}
{
boost::shared_ptr< X > pi = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4 );
boost::weak_ptr<X> wp( pi );
BOOST_TEST( X::instances == 1 );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( pi->v == 1+2+3+4 );
pi.reset();
BOOST_TEST( X::instances == 0 );
}
{
boost::shared_ptr< X > pi = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4, 5 );
boost::weak_ptr<X> wp( pi );
BOOST_TEST( X::instances == 1 );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( pi->v == 1+2+3+4+5 );
pi.reset();
BOOST_TEST( X::instances == 0 );
}
{
boost::shared_ptr< X > pi = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4, 5, 6 );
boost::weak_ptr<X> wp( pi );
BOOST_TEST( X::instances == 1 );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( pi->v == 1+2+3+4+5+6 );
pi.reset();
BOOST_TEST( X::instances == 0 );
}
{
boost::shared_ptr< X > pi = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4, 5, 6, 7 );
boost::weak_ptr<X> wp( pi );
BOOST_TEST( X::instances == 1 );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( pi->v == 1+2+3+4+5+6+7 );
pi.reset();
BOOST_TEST( X::instances == 0 );
}
{
boost::shared_ptr< X > pi = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4, 5, 6, 7, 8 );
boost::weak_ptr<X> wp( pi );
BOOST_TEST( X::instances == 1 );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( pi->v == 1+2+3+4+5+6+7+8 );
pi.reset();
BOOST_TEST( X::instances == 0 );
}
{
boost::shared_ptr< X > pi = boost::allocate_shared< X >( std::allocator<void>(), 1, 2, 3, 4, 5, 6, 7, 8, 9 );
boost::weak_ptr<X> wp( pi );
BOOST_TEST( X::instances == 1 );
BOOST_TEST( pi.get() != 0 );
BOOST_TEST( pi->v == 1+2+3+4+5+6+7+8+9 );
pi.reset();
BOOST_TEST( X::instances == 0 );
}
return boost::report_errors();
}

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//
// atomic_count_test.cpp
//
// Copyright 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/atomic_count.hpp>
#include <boost/detail/lightweight_test.hpp>
int main()
{
boost::detail::atomic_count n( 4 );
BOOST_TEST( n == 4L );
++n;
BOOST_TEST( n == 5L );
BOOST_TEST( --n != 0L );
boost::detail::atomic_count m( 0 );
BOOST_TEST( m == 0 );
++m;
BOOST_TEST( m == 1 );
++m;
BOOST_TEST( m == 2 );
BOOST_TEST( --m != 0 );
BOOST_TEST( --m == 0 );
return boost::report_errors();
}

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//
// atomic_count_test2.cpp
//
// Copyright 2009 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/atomic_count.hpp>
#include <boost/detail/lightweight_test.hpp>
int main()
{
boost::detail::atomic_count n( 4 );
BOOST_TEST( n == 4 );
BOOST_TEST( ++n == 5 );
BOOST_TEST( ++n == 6 );
BOOST_TEST( n == 6 );
BOOST_TEST( --n == 5 );
BOOST_TEST( --n == 4 );
BOOST_TEST( n == 4 );
boost::detail::atomic_count m( 0 );
BOOST_TEST( m == 0 );
BOOST_TEST( ++m == 1 );
BOOST_TEST( ++m == 2 );
BOOST_TEST( m == 2 );
BOOST_TEST( --m == 1 );
BOOST_TEST( --m == 0 );
BOOST_TEST( m == 0 );
BOOST_TEST( --m == -1 );
BOOST_TEST( --m == -2 );
BOOST_TEST( m == -2 );
BOOST_TEST( ++m == -1 );
BOOST_TEST( ++m == 0 );
BOOST_TEST( m == 0 );
return boost::report_errors();
}

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#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
#endif
//
// auto_ptr_lv_fail.cpp - a negative test for converting an auto_ptr to shared_ptr
//
// Copyright 2009 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/shared_ptr.hpp>
#include <memory>
void f( boost::shared_ptr<int> )
{
}
int main()
{
std::auto_ptr<int> p;
f( p ); // must fail
return 0;
}

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