boost_1_45_0/libs/variant/doc/tutorial/basic.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">
 <section id="variant.tutorial.basic">
   <title>Basic Usage</title>

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

 <para>A discriminated union container on some set of types is defined by
   instantiating the <code><classname>boost::variant</classname></code> class
   template with the desired types. These types are called
   <emphasis role="bold">bounded types</emphasis> and are subject to the
   requirements of the
   <link linkend="variant.concepts.bounded-type"><emphasis>BoundedType</emphasis></link>
   concept. Any number of bounded types may be specified, up to some
   implementation-defined limit (see
   <code><macroname>BOOST_VARIANT_LIMIT_TYPES</macroname></code>).</para>

 <para>For example, the following declares a discriminated union container on
   <code>int</code> and <code>std::string</code>:

 <programlisting><classname>boost::variant</classname>&lt; int, std::string &gt; v;</programlisting>

 </para>

 <para>By default, a <code>variant</code> default-constructs its first
   bounded type, so <code>v</code> initially contains <code>int(0)</code>. If
   this is not desired, or if the first bounded type is not
   default-constructible, a <code>variant</code> can be constructed
   directly from any value convertible to one of its bounded types. Similarly,
   a <code>variant</code> can be assigned any value convertible to one of its
   bounded types, as demonstrated in the following:

 <programlisting>v = "hello";</programlisting>

 </para>

 <para>Now <code>v</code> contains a <code>std::string</code> equal to
   <code>"hello"</code>. We can demonstrate this by
   <emphasis role="bold">streaming</emphasis>&nbsp;<code>v</code> to standard
   output:

 <programlisting>std::cout &lt;&lt; v &lt;&lt; std::endl;</programlisting>

 </para>

 <para>Usually though, we would like to do more with the content of a
   <code>variant</code> than streaming. Thus, we need some way to access the
   contained value. There are two ways to accomplish this:
   <code><functionname>apply_visitor</functionname></code>, which is safest
   and very powerful, and
   <code><functionname>get</functionname>&lt;T&gt;</code>, which is
   sometimes more convenient to use.</para>

 <para>For instance, suppose we wanted to concatenate to the string contained
   in <code>v</code>. With <emphasis role="bold">value retrieval</emphasis>
   by <code><functionname>get</functionname></code>, this may be accomplished
   quite simply, as seen in the following:

 <programlisting>std::string&amp; str = <functionname>boost::get</functionname>&lt;std::string&gt;(v);
 str += " world! ";</programlisting>

 </para>

 <para>As desired, the <code>std::string</code> contained by <code>v</code> now
   is equal to <code>"hello world! "</code>. Again, we can demonstrate this by
   streaming <code>v</code> to standard output:

 <programlisting>std::cout &lt;&lt; v &lt;&lt; std::endl;</programlisting>

 </para>

 <para>While use of <code>get</code> is perfectly acceptable in this trivial
   example, <code>get</code> generally suffers from several significant
   shortcomings. For instance, if we were to write a function accepting a
   <code>variant&lt;int, std::string&gt;</code>, we would not know whether
   the passed <code>variant</code> contained an <code>int</code> or a
   <code>std::string</code>. If we insisted upon continued use of
   <code>get</code>, we would need to query the <code>variant</code> for its
   contained type. The following function, which &quot;doubles&quot; the
   content of the given <code>variant</code>, demonstrates this approach:

 <programlisting>void times_two( boost::variant&lt; int, std::string &gt; &amp; operand )
 {
     if ( int* pi = <functionname>boost::get</functionname>&lt;int&gt;( &amp;operand ) )
         *pi *= 2;
     else if ( std::string* pstr = <functionname>boost::get</functionname>&lt;std::string&gt;( &amp;operand ) )
         *pstr += *pstr;
 }</programlisting>

 </para>

 <para>However, such code is quite brittle, and without careful attention will
   likely lead to the introduction of subtle logical errors detectable only at
   runtime. For instance, consider if we wished to extend
   <code>times_two</code> to operate on a <code>variant</code> with additional
   bounded types. Specifically, let's add
   <code>std::complex&lt;double&gt;</code> to the set. Clearly, we would need
   to at least change the function declaration:

 <programlisting>void times_two( boost::variant&lt; int, std::string, std::complex&lt;double&gt; &gt; &amp; operand )
 {
     // as above...?
 }</programlisting>

 </para>

 <para>Of course, additional changes are required, for currently if the passed
   <code>variant</code> in fact contained a <code>std::complex</code> value,
   <code>times_two</code> would silently return -- without any of the desired
   side-effects and without any error. In this case, the fix is obvious. But in
   more complicated programs, it could take considerable time to identify and
   locate the error in the first place.</para>

 <para>Thus, real-world use of <code>variant</code> typically demands an access
   mechanism more robust than <code>get</code>. For this reason,
   <code>variant</code> supports compile-time checked
   <emphasis role="bold">visitation</emphasis> via
   <code><functionname>apply_visitor</functionname></code>. Visitation requires
   that the programmer explicitly handle (or ignore) each bounded type. Failure
   to do so results in a compile-time error.</para>

 <para>Visitation of a <code>variant</code> requires a visitor object. The
   following demonstrates one such implementation of a visitor implementating
   behavior identical to <code>times_two</code>:

 <programlisting>class times_two_visitor
     : public <classname>boost::static_visitor</classname>&lt;&gt;
 {
 public:

     void operator()(int &amp; i) const
     {
         i *= 2;
     }

     void operator()(std::string &amp; str) const
     {
         str += str;
     }

 };</programlisting>

 </para>

 <para>With the implementation of the above visitor, we can then apply it to
   <code>v</code>, as seen in the following:

 <programlisting><functionname>boost::apply_visitor</functionname>( times_two_visitor(), v );</programlisting>

 </para>

 <para>As expected, the content of <code>v</code> is now a
   <code>std::string</code> equal to <code>"hello world! hello world! "</code>.
   (We'll skip the verification this time.)</para>

 <para>In addition to enhanced robustness, visitation provides another
   important advantage over <code>get</code>: the ability to write generic
   visitors. For instance, the following visitor will &quot;double&quot; the
   content of <emphasis>any</emphasis>&nbsp;<code>variant</code> (provided its
   bounded types each support operator+=):

 <programlisting>class times_two_generic
     : public <classname>boost::static_visitor</classname>&lt;&gt;
 {
 public:

     template &lt;typename T&gt;
     void operator()( T &amp; operand ) const
     {
         operand += operand;
     }

 };</programlisting>

 </para>

 <para>Again, <code>apply_visitor</code> sets the wheels in motion:

 <programlisting><functionname>boost::apply_visitor</functionname>( times_two_generic(), v );</programlisting>

 </para>

 <para>While the initial setup costs of visitation may exceed that required for
   <code>get</code>, the benefits quickly become significant. Before concluding
   this section, we should explore one last benefit of visitation with
   <code>apply_visitor</code>:
   <emphasis role="bold">delayed visitation</emphasis>. Namely, a special form
   of <code>apply_visitor</code> is available that does not immediately apply
   the given visitor to any <code>variant</code> but rather returns a function
   object that operates on any <code>variant</code> given to it. This behavior
   is particularly useful when operating on sequences of <code>variant</code>
   type, as the following demonstrates:

 <programlisting>std::vector&lt; <classname>boost::variant</classname>&lt;int, std::string&gt; &gt; vec;
 vec.push_back( 21 );
 vec.push_back( "hello " );

 times_two_generic visitor;
 std::for_each(
       vec.begin(), vec.end()
    , <functionname>boost::apply_visitor</functionname>(visitor)
    );</programlisting>

 </para>

 </section>
	<?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">
	<section id="variant.tutorial.basic">
	<title>Basic Usage</title>

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

	<para>A discriminated union container on some set of types is defined by
	instantiating the <code><classname>boost::variant</classname></code> class
	template with the desired types. These types are called
	<emphasis role="bold">bounded types</emphasis> and are subject to the
	requirements of the
	<link linkend="variant.concepts.bounded-type"><emphasis>BoundedType</emphasis></link>
	concept. Any number of bounded types may be specified, up to some
	implementation-defined limit (see
	<code><macroname>BOOST_VARIANT_LIMIT_TYPES</macroname></code>).</para>

	<para>For example, the following declares a discriminated union container on
	<code>int</code> and <code>std::string</code>:

	<programlisting><classname>boost::variant</classname>< int, std::string > v;</programlisting>

	</para>

	<para>By default, a <code>variant</code> default-constructs its first
	bounded type, so <code>v</code> initially contains <code>int(0)</code>. If
	this is not desired, or if the first bounded type is not
	default-constructible, a <code>variant</code> can be constructed
	directly from any value convertible to one of its bounded types. Similarly,
	a <code>variant</code> can be assigned any value convertible to one of its
	bounded types, as demonstrated in the following:

	<programlisting>v = "hello";</programlisting>

	</para>

	<para>Now <code>v</code> contains a <code>std::string</code> equal to
	<code>"hello"</code>. We can demonstrate this by
	<emphasis role="bold">streaming</emphasis> <code>v</code> to standard
	output:

	<programlisting>std::cout << v << std::endl;</programlisting>

	</para>

	<para>Usually though, we would like to do more with the content of a
	<code>variant</code> than streaming. Thus, we need some way to access the
	contained value. There are two ways to accomplish this:
	<code><functionname>apply_visitor</functionname></code>, which is safest
	and very powerful, and
	<code><functionname>get</functionname><T></code>, which is
	sometimes more convenient to use.</para>

	<para>For instance, suppose we wanted to concatenate to the string contained
	in <code>v</code>. With <emphasis role="bold">value retrieval</emphasis>
	by <code><functionname>get</functionname></code>, this may be accomplished
	quite simply, as seen in the following:

	<programlisting>std::string& str = <functionname>boost::get</functionname><std::string>(v);
	str += " world! ";</programlisting>

	</para>

	<para>As desired, the <code>std::string</code> contained by <code>v</code> now
	is equal to <code>"hello world! "</code>. Again, we can demonstrate this by
	streaming <code>v</code> to standard output:

	<programlisting>std::cout << v << std::endl;</programlisting>

	</para>

	<para>While use of <code>get</code> is perfectly acceptable in this trivial
	example, <code>get</code> generally suffers from several significant
	shortcomings. For instance, if we were to write a function accepting a
	<code>variant<int, std::string></code>, we would not know whether
	the passed <code>variant</code> contained an <code>int</code> or a
	<code>std::string</code>. If we insisted upon continued use of
	<code>get</code>, we would need to query the <code>variant</code> for its
	contained type. The following function, which "doubles" the
	content of the given <code>variant</code>, demonstrates this approach:

	<programlisting>void times_two( boost::variant< int, std::string > & operand )
	{
	if ( int* pi = <functionname>boost::get</functionname><int>( &operand ) )
	pi = 2;
	else if ( std::string* pstr = <functionname>boost::get</functionname><std::string>( &operand ) )
	pstr += pstr;
	}</programlisting>

	</para>

	<para>However, such code is quite brittle, and without careful attention will
	likely lead to the introduction of subtle logical errors detectable only at
	runtime. For instance, consider if we wished to extend
	<code>times_two</code> to operate on a <code>variant</code> with additional
	bounded types. Specifically, let's add
	<code>std::complex<double></code> to the set. Clearly, we would need
	to at least change the function declaration:

	<programlisting>void times_two( boost::variant< int, std::string, std::complex<double> > & operand )
	{
	// as above...?
	}</programlisting>

	</para>

	<para>Of course, additional changes are required, for currently if the passed
	<code>variant</code> in fact contained a <code>std::complex</code> value,
	<code>times_two</code> would silently return -- without any of the desired
	side-effects and without any error. In this case, the fix is obvious. But in
	more complicated programs, it could take considerable time to identify and
	locate the error in the first place.</para>

	<para>Thus, real-world use of <code>variant</code> typically demands an access
	mechanism more robust than <code>get</code>. For this reason,
	<code>variant</code> supports compile-time checked
	<emphasis role="bold">visitation</emphasis> via
	<code><functionname>apply_visitor</functionname></code>. Visitation requires
	that the programmer explicitly handle (or ignore) each bounded type. Failure
	to do so results in a compile-time error.</para>

	<para>Visitation of a <code>variant</code> requires a visitor object. The
	following demonstrates one such implementation of a visitor implementating
	behavior identical to <code>times_two</code>:

	<programlisting>class times_two_visitor
	: public <classname>boost::static_visitor</classname><>
	{
	public:

	void operator()(int & i) const
	{
	i *= 2;
	}

	void operator()(std::string & str) const
	{
	str += str;
	}

	};</programlisting>

	</para>

	<para>With the implementation of the above visitor, we can then apply it to
	<code>v</code>, as seen in the following:

	<programlisting><functionname>boost::apply_visitor</functionname>( times_two_visitor(), v );</programlisting>

	</para>

	<para>As expected, the content of <code>v</code> is now a
	<code>std::string</code> equal to <code>"hello world! hello world! "</code>.
	(We'll skip the verification this time.)</para>

	<para>In addition to enhanced robustness, visitation provides another
	important advantage over <code>get</code>: the ability to write generic
	visitors. For instance, the following visitor will "double" the
	content of <emphasis>any</emphasis> <code>variant</code> (provided its
	bounded types each support operator+=):

	<programlisting>class times_two_generic
	: public <classname>boost::static_visitor</classname><>
	{
	public:

	template <typename T>
	void operator()( T & operand ) const
	{
	operand += operand;
	}

	};</programlisting>

	</para>

	<para>Again, <code>apply_visitor</code> sets the wheels in motion:

	<programlisting><functionname>boost::apply_visitor</functionname>( times_two_generic(), v );</programlisting>

	</para>

	<para>While the initial setup costs of visitation may exceed that required for
	<code>get</code>, the benefits quickly become significant. Before concluding
	this section, we should explore one last benefit of visitation with
	<code>apply_visitor</code>:
	<emphasis role="bold">delayed visitation</emphasis>. Namely, a special form
	of <code>apply_visitor</code> is available that does not immediately apply
	the given visitor to any <code>variant</code> but rather returns a function
	object that operates on any <code>variant</code> given to it. This behavior
	is particularly useful when operating on sequences of <code>variant</code>
	type, as the following demonstrates:

	<programlisting>std::vector< <classname>boost::variant</classname><int, std::string> > vec;
	vec.push_back( 21 );
	vec.push_back( "hello " );

	times_two_generic visitor;
	std::for_each(
	vec.begin(), vec.end()
	, <functionname>boost::apply_visitor</functionname>(visitor)
	);</programlisting>

	</para>

	</section>