boost_1_45_0/libs/any/doc/any.xml - nest-learning-thermostat/5.0/boost - Git at Google

 <?xml version="1.0" encoding="utf-8"?>
 <!DOCTYPE library PUBLIC "-//Boost//DTD BoostBook XML V1.0//EN"
   "http://www.boost.org/tools/boostbook/dtd/boostbook.dtd">
 <library name="Any" dirname="any" xmlns:xi="http://www.w3.org/2001/XInclude"
          id="any" last-revision="$Date: 2009-07-26 16:11:03 -0400 (Sun, 26 Jul 2009) $">
   <libraryinfo>
     <author>
       <firstname>Kevlin</firstname>
       <surname>Henney</surname>
     </author>

     <copyright>
       <year>2001</year>
       <holder>Kevlin Henney</holder>
     </copyright>

     <librarypurpose>
       Safe, generic container for single values of different value types
     </librarypurpose>
     <librarycategory name="category:data-structures"/>

     <legalnotice>
       <para>Distributed under the Boost Software License, Version 1.0.
       (See accompanying file <filename>LICENSE_1_0.txt</filename> or copy at
       <ulink
       url="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</ulink>)
       </para>
     </legalnotice>
   </libraryinfo>

   <title>Boost.Any</title>

   <section>
     <title>Introduction</title>

     <para>There are times when a generic (in the sense of
     <emphasis>general</emphasis> as opposed to
     <emphasis>template-based programming</emphasis>) type is needed:
     variables that are truly variable, accommodating values of many
     other more specific types rather than C++'s normal strict and
     static types. We can distinguish three basic kinds of generic
     type:</para>

     <itemizedlist>
       <listitem>
         <para>Converting types that can hold one of a number of
         possible value types, e.g. <code>int</code> and
         <code>string</code>, and freely convert between them, for
         instance interpreting <code>5</code> as <code>"5"</code> or
         vice-versa.  Such types are common in scripting and other
         interpreted
         languages.
         <code><functionname>boost::lexical_cast</functionname></code>
         supports such conversion functionality.</para>
       </listitem>
       <listitem>
         <para>
         Discriminated types that contain values of different types but
         do not attempt conversion between them, i.e. <code>5</code> is
         held strictly as an <code>int</code> and is not implicitly
         convertible either to <code>"5"</code> or to
         <code>5.0</code>. Their indifference to interpretation but
         awareness of type effectively makes them safe, generic
         containers of single values, with no scope for surprises from
         ambiguous conversions.</para>
       </listitem>
       <listitem>
         <para>
         Indiscriminate types that can refer to anything but are
         oblivious to the actual underlying type, entrusting all forms
         of access and interpretation to the programmer. This niche is
         dominated by <code>void *</code>, which offers plenty of scope
         for surprising, undefined behavior.</para>
       </listitem>
     </itemizedlist>

     <para>The <code><classname>boost::any</classname></code> class
     (based on the class of the same name described in <ulink
     url="http://www.two-sdg.demon.co.uk/curbralan/papers/ValuedConversions.pdf">"Valued
     Conversions"</ulink> by Kevlin Henney, <emphasis>C++
     Report</emphasis> 12(7), July/August 2000) is a variant value type
     based on the second category. It supports copying of any value
     type and safe checked extraction of that value strictly against
     its type. A similar design, offering more appropriate operators,
     can be used for a generalized function adaptor,
     <code>any_function</code>, a generalized iterator adaptor,
     <code>any_iterator</code>, and other object types that need
     uniform runtime treatment but support only compile-time template
     parameter conformance.</para>
   </section>

   <section>
     <title>Examples</title>

     <using-namespace name="boost"/>
     <using-class name="boost::any"/>

     <para>The following code demonstrates the syntax for using
     implicit conversions to and copying of any objects:</para>

 <programlisting name="any.example.first">
 #include &lt;list&gt;
 #include &lt;boost/any.hpp&gt;

 using <functionname>boost::any_cast</functionname>;
 typedef std::list&lt;<classname>boost::any</classname>&gt; many;

 void append_int(many &amp; values, int value)
 {
     <classname>boost::any</classname> to_append = value;
     values.push_back(to_append);
 }

 void append_string(many &amp; values, const std::string &amp; value)
 {
     values.push_back(value);
 }

 void append_char_ptr(many &amp; values, const char * value)
 {
     values.push_back(value);
 }

 void append_any(many &amp; values, const <classname>boost::any</classname> &amp; value)
 {
     values.push_back(value);
 }

 void append_nothing(many &amp; values)
 {
     values.push_back(<classname>boost::any</classname>());
 }
 </programlisting>

     <para>The following predicates follow on from the previous
     definitions and demonstrate the use of queries on any
     objects:</para>

 <programlisting name="any.example.second">
 bool is_empty(const <classname>boost::any</classname> &amp; operand)
 {
     return operand.<methodname>empty</methodname>();
 }

 bool is_int(const <classname>boost::any</classname> &amp; operand)
 {
     return operand.<methodname>type</methodname>() == typeid(int);
 }

 bool is_char_ptr(const <classname>boost::any</classname> &amp; operand)
 {
     try
     {
         <functionname>any_cast</functionname>&lt;const char *&gt;(operand);
         return true;
     }
     catch(const <classname>boost::bad_any_cast</classname> &amp;)
     {
         return false;
     }
 }

 bool is_string(const <classname>boost::any</classname> &amp; operand)
 {
     return <functionname>any_cast</functionname>&lt;std::string&gt;(&amp;operand);
 }

 void count_all(many &amp; values, std::ostream &amp; out)
 {
     out &lt;&lt; "#empty == "
         &lt;&lt; std::count_if(values.begin(), values.end(), is_empty) &lt;&lt; std::endl;
     out &lt;&lt; "#int == "
         &lt;&lt; std::count_if(values.begin(), values.end(), is_int) &lt;&lt; std::endl;
     out &lt;&lt; "#const char * == "
         &lt;&lt; std::count_if(values.begin(), values.end(), is_char_ptr) &lt;&lt; std::endl;
     out &lt;&lt; "#string == "
         &lt;&lt; std::count_if(values.begin(), values.end(), is_string) &lt;&lt; std::endl;
 }
 </programlisting>

     <para>The following type, patterned after the OMG's Property Service, defines name-value pairs for arbitrary value types:</para>

 <programlisting>
 struct property
 {
     property();
     property(const std::string &amp;, const <classname>boost::any</classname> &amp;);

     std::string name;
     <classname>boost::any</classname> value;
 };

 typedef std::list&lt;property&gt; properties;
 </programlisting>

     <para>The following base class demonstrates one approach to
     runtime polymorphism based callbacks that also require arbitrary
     argument types. The absence of virtual member templates requires
     that different solutions have different trade-offs in terms of
     efficiency, safety, and generality. Using a checked variant type
     offers one approach:</para>

 <programlisting>
 class consumer
 {
 public:
     virtual void notify(const <classname>any</classname> &amp;) = 0;
     ...
 };
 </programlisting>
   </section>

   <library-reference>
     <section id="any.ValueType">
       <title><emphasis>ValueType</emphasis> requirements</title>

       <para>Values are strongly informational objects for which
       identity is not significant, i.e. the focus is principally on
       their state content and any behavior organized around
       that. Another distinguishing feature of values is their
       granularity: normally fine-grained objects representing simple
       concepts in the system such as quantities.</para>

       <para>As the emphasis of a value lies in its state not its
       identity, values can be copied and typically assigned one to
       another, requiring the explicit or implicit definition of a
       public copy constructor and public assignment operator. Values
       typically live within other scopes, i.e. within objects or
       blocks, rather than on the heap. Values are therefore normally
       passed around and manipulated directly as variables or through
       references, but not as pointers that emphasize identity and
       indirection.</para>

       <para>The specific requirements on value types to be used in an
       <code><classname alt="boost::any">any</classname></code>
       are:</para>

       <itemizedlist spacing="compact">
         <listitem><simpara>A <emphasis>ValueType</emphasis> is
           <emphasis>CopyConstructible</emphasis> [20.1.3].</simpara>
         </listitem>

         <listitem><simpara>A <emphasis>ValueType</emphasis> is
         optionally <emphasis>Assignable</emphasis> [23.1]. The strong
         exception-safety guarantee is required for all forms of
         assignment.</simpara>
         </listitem>

         <listitem><simpara>The destructor for a
         <emphasis>ValueType</emphasis> upholds the no-throw
         exception-safety guarantee.</simpara>
         </listitem>
       </itemizedlist>
     </section>

     <header name="boost/any.hpp">
       <namespace name="boost">
         <class name="bad_any_cast">
           <inherit access="public">
             <classname>std::bad_cast</classname>
           </inherit>
           <purpose>The exception thrown in the event of a failed
           <code><functionname>any_cast</functionname></code> of an
           <code><classname>any</classname></code> value.</purpose>

           <method name="what" specifiers="virtual" cv="const">
             <type>const char *</type>
           </method>
         </class>

         <class name="any">
           <purpose>A class whose instances can hold instances of any
           type that satisfies <link
           linkend="any.ValueType">ValueType</link>
           requirements.</purpose>

           <constructor>
             <postconditions><simpara><code>this-&gt;<methodname>empty</methodname>()</code></simpara></postconditions>
           </constructor>

           <constructor>
             <parameter name="other">
               <paramtype>const <classname>any</classname> &amp;</paramtype>
             </parameter>

             <effects><simpara> Copy constructor that copies content of
             <code>other</code> into new instance, so that any content
             is equivalent in both type and value to the content of
             <code>other</code>, or empty if <code>other</code> is
             empty. </simpara></effects>

             <throws><simpara>May fail with a
             <code><classname>std::bad_alloc</classname></code>
             exception or any exceptions arising from the copy
             constructor of the contained type.</simpara></throws>
           </constructor>

           <constructor>
             <template>
               <template-type-parameter name="ValueType"/>
             </template>

             <parameter name="value">
               <paramtype>const ValueType &amp;</paramtype>
             </parameter>

             <effects><simpara>Makes a copy of <code>value</code>, so
             that the initial content of the new instance is equivalent
             in both type and value to
             <code>value</code>.</simpara></effects>

             <throws><simpara><code><classname>std::bad_alloc</classname></code>
             or any exceptions arising from the copy constructor of the
             contained type.</simpara></throws>
           </constructor>

           <destructor>
             <effects><simpara>Releases any and all resources used in
             management of instance.</simpara></effects>
             <throws><simpara>Nothing.</simpara></throws>
           </destructor>

           <copy-assignment>
             <type><classname>any</classname> &amp;</type>

             <parameter name="rhs">
               <paramtype>const <classname>any</classname> &amp;</paramtype>
             </parameter>

             <effects><simpara>Copies content of <code>rhs</code> into
             current instance, discarding previous content, so that the
             new content is equivalent in both type and value to the
             content of <code>rhs</code>, or empty if
             <code>rhs.<methodname>empty</methodname>()</code>.</simpara></effects>

             <throws><simpara><code><classname>std::bad_alloc</classname></code>
             or any exceptions arising from the copy constructor of the
             contained type. Assignment satisfies the strong guarantee
             of exception safety.</simpara></throws>
           </copy-assignment>

           <copy-assignment>
              <template>
               <template-type-parameter name="ValueType"/>
             </template>

             <type><classname>any</classname> &amp;</type>

             <parameter name="rhs">
               <paramtype>const ValueType &amp;</paramtype>
             </parameter>

             <effects><simpara>Makes a copy of <code>rhs</code>,
             discarding previous content, so that the new content of is
             equivalent in both type and value to
             <code>rhs</code>.</simpara></effects>

             <throws><simpara><code><classname>std::bad_alloc</classname></code>
             or any exceptions arising from the copy constructor of the
             contained type. Assignment satisfies the strong guarantee
             of exception safety.</simpara></throws>
           </copy-assignment>

           <method-group name="modifiers">
             <method name="swap">
               <type><classname>any</classname> &amp;</type>

               <parameter name="rhs">
                 <paramtype><classname>any</classname> &amp;</paramtype>
               </parameter>

               <effects><simpara>Exchange of the contents of
               <code>*this</code> and
               <code>rhs</code>.</simpara></effects>

               <returns><simpara><code>*this</code></simpara></returns>

               <throws><simpara>Nothing.</simpara></throws>
             </method>
           </method-group>

           <method-group name="queries">
             <method name="empty" cv="const">
               <type>bool</type>

               <returns><simpara><code>true</code> if instance is
               empty, otherwise <code>false</code>.</simpara></returns>

               <throws><simpara>Will not throw.</simpara></throws>
             </method>

             <method name="type" cv="const">
               <type>const <classname>std::type_info</classname> &amp;</type>

               <returns><simpara>the <code>typeid</code> of the
               contained value if instance is non-empty, otherwise
               <code>typeid(void)</code>.</simpara></returns>

               <notes><simpara>Useful for querying against types known
               either at compile time or only at
               runtime.</simpara></notes>
             </method>
           </method-group>
         </class>

         <overloaded-function name="any_cast">
           <signature>
             <template>
               <template-type-parameter name="T"/>
             </template>

             <type>T</type>

             <parameter name="operand">
               <paramtype><classname>any</classname> &amp;</paramtype>
             </parameter>
           </signature>

           <signature>
             <template>
               <template-type-parameter name="T"/>
             </template>

             <type>T</type>

             <parameter name="operand">
               <paramtype>const <classname>any</classname> &amp;</paramtype>
             </parameter>
           </signature>

           <signature>
             <template>
               <template-type-parameter name="ValueType"/>
             </template>

             <type>const ValueType *</type>

             <parameter name="operand">
               <paramtype>const <classname>any</classname> *</paramtype>
             </parameter>
           </signature>

           <signature>
             <template>
               <template-type-parameter name="ValueType"/>
             </template>

             <type>ValueType *</type>

             <parameter name="operand">
               <paramtype><classname>any</classname> *</paramtype>
             </parameter>
           </signature>

           <purpose><simpara>Custom keyword cast for extracting a value
           of a given type from an
           <code><classname>any</classname></code>.</simpara></purpose>

           <returns><simpara> If passed a pointer, it returns a
           similarly qualified pointer to the value content if
 	  successful, otherwise null is returned.
 	  If T is ValueType, it returns a copy of the held value, otherwise, if T is a reference
 	  to (possibly const qualified) ValueType, it returns a reference to the held
 	  value.</simpara></returns>

           <throws><simpara>Overloads taking an
           <code><classname>any</classname></code> pointer do not
           throw; overloads taking an
           <code><classname>any</classname></code> value or reference
           throws <code><classname>bad_any_cast</classname></code> if
           unsuccessful.</simpara></throws>

         </overloaded-function>
       </namespace>
     </header>
   </library-reference>

   <section>
     <title>Acknowledgements</title>

     <para>Doug Gregor ported the documentation to the BoostBook format.</para>
   </section>
 </library>
	<?xml version="1.0" encoding="utf-8"?>
	<!DOCTYPE library PUBLIC "-//Boost//DTD BoostBook XML V1.0//EN"
	"http://www.boost.org/tools/boostbook/dtd/boostbook.dtd">
	<library name="Any" dirname="any" xmlns:xi="http://www.w3.org/2001/XInclude"
	id="any" last-revision="$Date: 2009-07-26 16:11:03 -0400 (Sun, 26 Jul 2009) $">
	<libraryinfo>
	<author>
	<firstname>Kevlin</firstname>
	<surname>Henney</surname>
	</author>

	<copyright>
	<year>2001</year>
	<holder>Kevlin Henney</holder>
	</copyright>

	<librarypurpose>
	Safe, generic container for single values of different value types
	</librarypurpose>
	<librarycategory name="category:data-structures"/>

	<legalnotice>
	<para>Distributed under the Boost Software License, Version 1.0.
	(See accompanying file <filename>LICENSE_1_0.txt</filename> or copy at
	<ulink
	url="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</ulink>)
	</para>
	</legalnotice>
	</libraryinfo>

	<title>Boost.Any</title>

	<section>
	<title>Introduction</title>

	<para>There are times when a generic (in the sense of
	<emphasis>general</emphasis> as opposed to
	<emphasis>template-based programming</emphasis>) type is needed:
	variables that are truly variable, accommodating values of many
	other more specific types rather than C++'s normal strict and
	static types. We can distinguish three basic kinds of generic
	type:</para>

	<itemizedlist>
	<listitem>
	<para>Converting types that can hold one of a number of
	possible value types, e.g. <code>int</code> and
	<code>string</code>, and freely convert between them, for
	instance interpreting <code>5</code> as <code>"5"</code> or
	vice-versa. Such types are common in scripting and other
	interpreted
	languages.
	<code><functionname>boost::lexical_cast</functionname></code>
	supports such conversion functionality.</para>
	</listitem>
	<listitem>
	<para>
	Discriminated types that contain values of different types but
	do not attempt conversion between them, i.e. <code>5</code> is
	held strictly as an <code>int</code> and is not implicitly
	convertible either to <code>"5"</code> or to
	<code>5.0</code>. Their indifference to interpretation but
	awareness of type effectively makes them safe, generic
	containers of single values, with no scope for surprises from
	ambiguous conversions.</para>
	</listitem>
	<listitem>
	<para>
	Indiscriminate types that can refer to anything but are
	oblivious to the actual underlying type, entrusting all forms
	of access and interpretation to the programmer. This niche is
	dominated by <code>void *</code>, which offers plenty of scope
	for surprising, undefined behavior.</para>
	</listitem>
	</itemizedlist>

	<para>The <code><classname>boost::any</classname></code> class
	(based on the class of the same name described in <ulink
	url="http://www.two-sdg.demon.co.uk/curbralan/papers/ValuedConversions.pdf">"Valued
	Conversions"</ulink> by Kevlin Henney, <emphasis>C++
	Report</emphasis> 12(7), July/August 2000) is a variant value type
	based on the second category. It supports copying of any value
	type and safe checked extraction of that value strictly against
	its type. A similar design, offering more appropriate operators,
	can be used for a generalized function adaptor,
	<code>any_function</code>, a generalized iterator adaptor,
	<code>any_iterator</code>, and other object types that need
	uniform runtime treatment but support only compile-time template
	parameter conformance.</para>
	</section>

	<section>
	<title>Examples</title>

	<using-namespace name="boost"/>
	<using-class name="boost::any"/>

	<para>The following code demonstrates the syntax for using
	implicit conversions to and copying of any objects:</para>

	<programlisting name="any.example.first">
	#include <list>
	#include <boost/any.hpp>

	using <functionname>boost::any_cast</functionname>;
	typedef std::list<<classname>boost::any</classname>> many;

	void append_int(many & values, int value)
	{
	<classname>boost::any</classname> to_append = value;
	values.push_back(to_append);
	}

	void append_string(many & values, const std::string & value)
	{
	values.push_back(value);
	}

	void append_char_ptr(many & values, const char * value)
	{
	values.push_back(value);
	}

	void append_any(many & values, const <classname>boost::any</classname> & value)
	{
	values.push_back(value);
	}

	void append_nothing(many & values)
	{
	values.push_back(<classname>boost::any</classname>());
	}
	</programlisting>

	<para>The following predicates follow on from the previous
	definitions and demonstrate the use of queries on any
	objects:</para>

	<programlisting name="any.example.second">
	bool is_empty(const <classname>boost::any</classname> & operand)
	{
	return operand.<methodname>empty</methodname>();
	}

	bool is_int(const <classname>boost::any</classname> & operand)
	{
	return operand.<methodname>type</methodname>() == typeid(int);
	}

	bool is_char_ptr(const <classname>boost::any</classname> & operand)
	{
	try
	{
	<functionname>any_cast</functionname><const char *>(operand);
	return true;
	}
	catch(const <classname>boost::bad_any_cast</classname> &)
	{
	return false;
	}
	}

	bool is_string(const <classname>boost::any</classname> & operand)
	{
	return <functionname>any_cast</functionname><std::string>(&operand);
	}

	void count_all(many & values, std::ostream & out)
	{
	out << "#empty == "
	<< std::count_if(values.begin(), values.end(), is_empty) << std::endl;
	out << "#int == "
	<< std::count_if(values.begin(), values.end(), is_int) << std::endl;
	out << "#const char * == "
	<< std::count_if(values.begin(), values.end(), is_char_ptr) << std::endl;
	out << "#string == "
	<< std::count_if(values.begin(), values.end(), is_string) << std::endl;
	}
	</programlisting>

	<para>The following type, patterned after the OMG's Property Service, defines name-value pairs for arbitrary value types:</para>

	<programlisting>
	struct property
	{
	property();
	property(const std::string &, const <classname>boost::any</classname> &);

	std::string name;
	<classname>boost::any</classname> value;
	};

	typedef std::list<property> properties;
	</programlisting>

	<para>The following base class demonstrates one approach to
	runtime polymorphism based callbacks that also require arbitrary
	argument types. The absence of virtual member templates requires
	that different solutions have different trade-offs in terms of
	efficiency, safety, and generality. Using a checked variant type
	offers one approach:</para>

	<programlisting>
	class consumer
	{
	public:
	virtual void notify(const <classname>any</classname> &) = 0;
	...
	};
	</programlisting>
	</section>

	<library-reference>
	<section id="any.ValueType">
	<title><emphasis>ValueType</emphasis> requirements</title>

	<para>Values are strongly informational objects for which
	identity is not significant, i.e. the focus is principally on
	their state content and any behavior organized around
	that. Another distinguishing feature of values is their
	granularity: normally fine-grained objects representing simple
	concepts in the system such as quantities.</para>

	<para>As the emphasis of a value lies in its state not its
	identity, values can be copied and typically assigned one to
	another, requiring the explicit or implicit definition of a
	public copy constructor and public assignment operator. Values
	typically live within other scopes, i.e. within objects or
	blocks, rather than on the heap. Values are therefore normally
	passed around and manipulated directly as variables or through
	references, but not as pointers that emphasize identity and
	indirection.</para>

	<para>The specific requirements on value types to be used in an
	<code><classname alt="boost::any">any</classname></code>
	are:</para>

	<itemizedlist spacing="compact">
	<listitem><simpara>A <emphasis>ValueType</emphasis> is
	<emphasis>CopyConstructible</emphasis> [20.1.3].</simpara>
	</listitem>

	<listitem><simpara>A <emphasis>ValueType</emphasis> is
	optionally <emphasis>Assignable</emphasis> [23.1]. The strong
	exception-safety guarantee is required for all forms of
	assignment.</simpara>
	</listitem>

	<listitem><simpara>The destructor for a
	<emphasis>ValueType</emphasis> upholds the no-throw
	exception-safety guarantee.</simpara>
	</listitem>
	</itemizedlist>
	</section>

	<header name="boost/any.hpp">
	<namespace name="boost">
	<class name="bad_any_cast">
	<inherit access="public">
	<classname>std::bad_cast</classname>
	</inherit>
	<purpose>The exception thrown in the event of a failed
	<code><functionname>any_cast</functionname></code> of an
	<code><classname>any</classname></code> value.</purpose>

	<method name="what" specifiers="virtual" cv="const">
	<type>const char *</type>
	</method>
	</class>

	<class name="any">
	<purpose>A class whose instances can hold instances of any
	type that satisfies <link
	linkend="any.ValueType">ValueType</link>
	requirements.</purpose>

	<constructor>
	<postconditions><simpara><code>this-><methodname>empty</methodname>()</code></simpara></postconditions>
	</constructor>

	<constructor>
	<parameter name="other">
	<paramtype>const <classname>any</classname> &</paramtype>
	</parameter>

	<effects><simpara> Copy constructor that copies content of
	<code>other</code> into new instance, so that any content
	is equivalent in both type and value to the content of
	<code>other</code>, or empty if <code>other</code> is
	empty. </simpara></effects>

	<throws><simpara>May fail with a
	<code><classname>std::bad_alloc</classname></code>
	exception or any exceptions arising from the copy
	constructor of the contained type.</simpara></throws>
	</constructor>

	<constructor>
	<template>
	<template-type-parameter name="ValueType"/>
	</template>

	<parameter name="value">
	<paramtype>const ValueType &</paramtype>
	</parameter>

	<effects><simpara>Makes a copy of <code>value</code>, so
	that the initial content of the new instance is equivalent
	in both type and value to
	<code>value</code>.</simpara></effects>

	<throws><simpara><code><classname>std::bad_alloc</classname></code>
	or any exceptions arising from the copy constructor of the
	contained type.</simpara></throws>
	</constructor>

	<destructor>
	<effects><simpara>Releases any and all resources used in
	management of instance.</simpara></effects>
	<throws><simpara>Nothing.</simpara></throws>
	</destructor>

	<copy-assignment>
	<type><classname>any</classname> &</type>

	<parameter name="rhs">
	<paramtype>const <classname>any</classname> &</paramtype>
	</parameter>

	<effects><simpara>Copies content of <code>rhs</code> into
	current instance, discarding previous content, so that the
	new content is equivalent in both type and value to the
	content of <code>rhs</code>, or empty if
	<code>rhs.<methodname>empty</methodname>()</code>.</simpara></effects>

	<throws><simpara><code><classname>std::bad_alloc</classname></code>
	or any exceptions arising from the copy constructor of the
	contained type. Assignment satisfies the strong guarantee
	of exception safety.</simpara></throws>
	</copy-assignment>

	<copy-assignment>
	<template>
	<template-type-parameter name="ValueType"/>
	</template>

	<type><classname>any</classname> &</type>

	<parameter name="rhs">
	<paramtype>const ValueType &</paramtype>
	</parameter>

	<effects><simpara>Makes a copy of <code>rhs</code>,
	discarding previous content, so that the new content of is
	equivalent in both type and value to
	<code>rhs</code>.</simpara></effects>

	<throws><simpara><code><classname>std::bad_alloc</classname></code>
	or any exceptions arising from the copy constructor of the
	contained type. Assignment satisfies the strong guarantee
	of exception safety.</simpara></throws>
	</copy-assignment>

	<method-group name="modifiers">
	<method name="swap">
	<type><classname>any</classname> &</type>

	<parameter name="rhs">
	<paramtype><classname>any</classname> &</paramtype>
	</parameter>

	<effects><simpara>Exchange of the contents of
	<code>*this</code> and
	<code>rhs</code>.</simpara></effects>

	<returns><simpara><code>*this</code></simpara></returns>

	<throws><simpara>Nothing.</simpara></throws>
	</method>
	</method-group>

	<method-group name="queries">
	<method name="empty" cv="const">
	<type>bool</type>

	<returns><simpara><code>true</code> if instance is
	empty, otherwise <code>false</code>.</simpara></returns>

	<throws><simpara>Will not throw.</simpara></throws>
	</method>

	<method name="type" cv="const">
	<type>const <classname>std::type_info</classname> &</type>

	<returns><simpara>the <code>typeid</code> of the
	contained value if instance is non-empty, otherwise
	<code>typeid(void)</code>.</simpara></returns>

	<notes><simpara>Useful for querying against types known
	either at compile time or only at
	runtime.</simpara></notes>
	</method>
	</method-group>
	</class>

	<overloaded-function name="any_cast">
	<signature>
	<template>
	<template-type-parameter name="T"/>
	</template>

	<type>T</type>

	<parameter name="operand">
	<paramtype><classname>any</classname> &</paramtype>
	</parameter>
	</signature>

	<signature>
	<template>
	<template-type-parameter name="T"/>
	</template>

	<type>T</type>

	<parameter name="operand">
	<paramtype>const <classname>any</classname> &</paramtype>
	</parameter>
	</signature>

	<signature>
	<template>
	<template-type-parameter name="ValueType"/>
	</template>

	<type>const ValueType *</type>

	<parameter name="operand">
	<paramtype>const <classname>any</classname> *</paramtype>
	</parameter>
	</signature>

	<signature>
	<template>
	<template-type-parameter name="ValueType"/>
	</template>

	<type>ValueType *</type>

	<parameter name="operand">
	<paramtype><classname>any</classname> *</paramtype>
	</parameter>
	</signature>

	<purpose><simpara>Custom keyword cast for extracting a value
	of a given type from an
	<code><classname>any</classname></code>.</simpara></purpose>

	<returns><simpara> If passed a pointer, it returns a
	similarly qualified pointer to the value content if
	successful, otherwise null is returned.
	If T is ValueType, it returns a copy of the held value, otherwise, if T is a reference
	to (possibly const qualified) ValueType, it returns a reference to the held
	value.</simpara></returns>

	<throws><simpara>Overloads taking an
	<code><classname>any</classname></code> pointer do not
	throw; overloads taking an
	<code><classname>any</classname></code> value or reference
	throws <code><classname>bad_any_cast</classname></code> if
	unsuccessful.</simpara></throws>

	</overloaded-function>
	</namespace>
	</header>
	</library-reference>

	<section>
	<title>Acknowledgements</title>

	<para>Doug Gregor ported the documentation to the BoostBook format.</para>
	</section>
	</library>