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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<T></STRONG> can be implicitly converted to <STRONG>shared_ptr<U></STRONG> |
| whenever <STRONG>T*</STRONG> can be implicitly converted to <STRONG>U*</STRONG>. |
| In particular, <STRONG>shared_ptr<T></STRONG> is implicitly convertible |
| to <STRONG>shared_ptr<T const></STRONG>, to <STRONG>shared_ptr<U></STRONG> |
| where <STRONG>U</STRONG> is an accessible base of <STRONG>T</STRONG>, and to <STRONG> |
| shared_ptr<void></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<T> 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<int>, int); |
| int g(); |
| |
| void ok() |
| { |
| shared_ptr<int> p(new int(2)); |
| f(p, g()); |
| } |
| |
| void bad() |
| { |
| f(shared_ptr<int>(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<class T> class <A href="weak_ptr.htm" >weak_ptr</A>; |
| |
| template<class T> class shared_ptr { |
| |
| public: |
| |
| typedef T <A href="#element_type" >element_type</A>; |
| |
| <A href="#constructors" >shared_ptr</A>(); // never throws |
| template<class Y> explicit <A href="#constructors" >shared_ptr</A>(Y * p); |
| template<class Y, class D> <A href="#constructors" >shared_ptr</A>(Y * p, D d); |
| template<class Y, class D, class A> <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 & r); // never throws |
| template<class Y> <A href="#constructors" >shared_ptr</A>(shared_ptr<Y> const & r); // never throws |
| template<class Y> <A href="#constructors" >shared_ptr</A>(shared_ptr<Y> const & r, T * p); // never throws |
| template<class Y> explicit <A href="#constructors" >shared_ptr</A>(<A href="weak_ptr.htm" >weak_ptr</A><Y> const & r); |
| template<class Y> explicit <A href="#constructors" >shared_ptr</A>(std::auto_ptr<Y> & r); |
| |
| shared_ptr & <A href="#assignment" >operator=</A>(shared_ptr const & r); // never throws |
| template<class Y> shared_ptr & <A href="#assignment" >operator=</A>(shared_ptr<Y> const & r); // never throws |
| template<class Y> shared_ptr & <A href="#assignment" >operator=</A>(std::auto_ptr<Y> & r); |
| |
| void <A href="#reset" >reset</A>(); // never throws |
| template<class Y> void <A href="#reset" >reset</A>(Y * p); |
| template<class Y, class D> void <A href="#reset" >reset</A>(Y * p, D d); |
| template<class Y, class D, class A> void <A href="#reset" >reset</A>(Y * p, D d, A a); |
| template<class Y> void <A href="#reset" >reset</A>(shared_ptr<Y> const & r, T * p); // never throws |
| |
| T & <A href="#indirection" >operator*</A>() const; // never throws |
| T * <A href="#indirection" >operator-></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 & b); // never throws |
| }; |
| |
| template<class T, class U> |
| bool <A href="#comparison" >operator==</A>(shared_ptr<T> const & a, shared_ptr<U> const & b); // never throws |
| |
| template<class T, class U> |
| bool <A href="#comparison" >operator!=</A>(shared_ptr<T> const & a, shared_ptr<U> const & b); // never throws |
| |
| template<class T, class U> |
| bool <A href="#comparison" >operator<</A>(shared_ptr<T> const & a, shared_ptr<U> const & b); // never throws |
| |
| template<class T> void <A href="#free-swap" >swap</A>(shared_ptr<T> & a, shared_ptr<T> & b); // never throws |
| |
| template<class T> T * <A href="#get_pointer" >get_pointer</A>(shared_ptr<T> const & p); // never throws |
| |
| template<class T, class U> |
| shared_ptr<T> <A href="#static_pointer_cast" >static_pointer_cast</A>(shared_ptr<U> const & r); // never throws |
| |
| template<class T, class U> |
| shared_ptr<T> <A href="#const_pointer_cast" >const_pointer_cast</A>(shared_ptr<U> const & r); // never throws |
| |
| template<class T, class U> |
| shared_ptr<T> <A href="#dynamic_pointer_cast" >dynamic_pointer_cast</A>(shared_ptr<U> const & r); // never throws |
| |
| template<class E, class T, class Y> |
| std::basic_ostream<E, T> & <A href="#insertion-operator" >operator<<</A> (std::basic_ostream<E, T> & os, shared_ptr<Y> const & p); |
| |
| template<class D, class T> |
| D * <A href="#get_deleter">get_deleter</A>(shared_ptr<T> const & 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 && 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<class Y> 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 && 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<class Y, class D> shared_ptr(Y * p, D d); |
| template<class Y, class D, class A> 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 && 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 & r); // never throws |
| template<class Y> shared_ptr(shared_ptr<Y> const & 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() && use_count() == |
| r.use_count()</code>.</p> |
| <p><b>Throws:</b> nothing.</p> |
| </blockquote> |
| <pre>template<class Y> shared_ptr(shared_ptr<Y> const & 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 && use_count() == r.use_count()</code>.</p> |
| <p><b>Throws:</b> nothing.</p> |
| </blockquote> |
| <pre>template<class Y> explicit shared_ptr(<A href="weak_ptr.htm" >weak_ptr</A><Y> const & 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<class Y> shared_ptr(std::auto_ptr<Y> & 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() > 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 & operator=(shared_ptr const & r); // never throws |
| template<class Y> shared_ptr & operator=(shared_ptr<Y> const & r); // never throws |
| template<class Y> shared_ptr & operator=(std::auto_ptr<Y> & 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<int> p(new int); |
| shared_ptr<void> 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<class Y> void reset(Y * p);</pre> |
| <BLOCKQUOTE> |
| <P><B>Effects:</B> Equivalent to <code>shared_ptr(p).swap(*this)</code>.</P> |
| </BLOCKQUOTE> |
| <pre>template<class Y, class D> 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<class Y, class D, class A> 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<class Y> void reset(shared_ptr<Y> const & 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 & 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->() 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 && p->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 & 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<class T, class U> |
| bool operator==(shared_ptr<T> const & a, shared_ptr<U> const & 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<class T, class U> |
| bool operator!=(shared_ptr<T> const & a, shared_ptr<U> const & 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<class T, class U> |
| bool operator<(shared_ptr<T> const & a, shared_ptr<U> const & b); // never throws</pre> |
| <blockquote> |
| <p><b>Returns:</b> an unspecified value such that</p> |
| <UL> |
| <LI> |
| <b>operator<</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<</STRONG>, <code>!(a |
| < b) && !(b < 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<</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<</STRONG>, and many |
| standard algorithms use <STRONG>operator<</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<</STRONG> in terms of their contained |
| subobjects' <STRONG>operator<</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<class T> |
| void swap(shared_ptr<T> & a, shared_ptr<T> & 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<class T> |
| T * get_pointer(shared_ptr<T> const & 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<class T, class U> |
| shared_ptr<T> static_pointer_cast(shared_ptr<U> const & r); // never throws</pre> |
| <BLOCKQUOTE> |
| <P><STRONG>Requires:</STRONG> The expression <code>static_cast<T*>(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<T></b>; |
| otherwise, a <STRONG>shared_ptr<T></STRONG> object that stores a copy of <code> |
| static_cast<T*>(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<T>(static_cast<T*>(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<class T, class U> |
| shared_ptr<T> const_pointer_cast(shared_ptr<U> const & r); // never throws</pre> |
| <BLOCKQUOTE> |
| <P><STRONG>Requires:</STRONG> The expression <code>const_cast<T*>(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<T></b>; |
| otherwise, a <STRONG>shared_ptr<T></STRONG> object that stores a copy of <code> |
| const_cast<T*>(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<T>(const_cast<T*>(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<class T, class U> |
| shared_ptr<T> dynamic_pointer_cast(shared_ptr<U> const & r);</pre> |
| <BLOCKQUOTE> |
| <P><STRONG>Requires:</STRONG> The expression <CODE>dynamic_cast<T*>(r.get())</CODE> |
| must be well-formed and its behavior defined.</P> |
| <P><B>Returns:</B></P> |
| <UL> |
| <LI> |
| When <CODE>dynamic_cast<T*>(r.get())</CODE> returns a nonzero value, a <STRONG> |
| shared_ptr<T></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<T></STRONG> object.</LI></UL> |
| <P><B>Throws:</B> nothing.</P> |
| <P><B>Notes:</B> the seemingly equivalent expression</P> |
| <P><CODE>shared_ptr<T>(dynamic_cast<T*>(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<<</a></h3> |
| <pre>template<class E, class T, class Y> |
| std::basic_ostream<E, T> & operator<< (std::basic_ostream<E, T> & os, shared_ptr<Y> const & p);</pre> |
| <BLOCKQUOTE> |
| <p><STRONG>Effects:</STRONG> <code>os << p.get();</code>.</p> |
| <P><B>Returns:</B> <b>os</b>.</P> |
| </BLOCKQUOTE> |
| <h3><a name="get_deleter">get_deleter</a></h3> |
| <pre>template<class D, class T> |
| D * get_deleter(shared_ptr<T> const & 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>&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<></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<int> p(new int(42)); |
| |
| //--- Example 1 --- |
| |
| // thread A |
| shared_ptr<int> p2(p); // reads p |
| |
| // thread B |
| shared_ptr<int> 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> </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&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<int> a(new int); |
| shared_ptr<int> 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->()</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: 2009-03-11 11:08:14 -0400 (Wed, 11 Mar 2009) $</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> |
| </body> |
| </html> |