boost_1_45_0/libs/proto/doc/reference/transform/call.xml - nest-learning-thermostat/5.0/boost - Git at Google

 <?xml version="1.0" encoding="utf-8"?>
 <header name="boost/proto/transform/call.hpp">
   <para>Contains definition of the call&lt;&gt; transform. </para>
   <namespace name="boost">
     <namespace name="proto">
       <struct name="call">
         <template>
           <template-type-parameter name="T"/>
         </template>
         <purpose>Make the given <conceptname>CallableTransform</conceptname> into a <conceptname>PrimitiveTransform</conceptname>.</purpose>

         <description>
           <para>
             The purpose of <computeroutput>proto::call&lt;&gt;</computeroutput> is to annotate a transform as callable
             so that <computeroutput><classname alt="proto::when">proto::when&lt;&gt;</classname></computeroutput> knows
             how to apply it. The template parameter must be either a <conceptname>PrimitiveTransform</conceptname> or a
             <conceptname>CallableTransform</conceptname>; that is, a function type for which the return type is a callable
             <conceptname>PolymorphicFunctionObject</conceptname>.
           </para>

           <para>
             For the complete description of the behavior of the <computeroutput>proto::call&lt;&gt;</computeroutput>
             transform, see the documentation for the nested
             <computeroutput>
               <classname alt="proto::call::impl">proto::call::impl&lt;&gt;</classname>
             </computeroutput>
             class template.
           </para>
         </description>

         <inherit><type><classname>proto::transform</classname>&lt; call&lt;T&gt; &gt;</type></inherit>

         <struct name="impl">
           <template>
             <template-type-parameter name="Expr"/>
             <template-type-parameter name="State"/>
             <template-type-parameter name="Data"/>
           </template>
           <inherit><type><classname>proto::transform_impl</classname>&lt;Expr, State, Data&gt;</type></inherit>
           <typedef name="result_type">
             <type><replaceable>see-below</replaceable></type>
             <description>
               <para>
                 <computeroutput><classname>proto::call</classname>&lt;T&gt;::impl&lt;Expr,State,Data&gt;::result_type</computeroutput>
                 is computed as follows:
                 <itemizedlist>
                   <listitem>
                     <para>
                       If <computeroutput>T</computeroutput> if of the form
                       <computeroutput><conceptname>PrimitiveTransform</conceptname></computeroutput> or
                       <computeroutput><conceptname>PrimitiveTransform</conceptname>()</computeroutput>, then
                       <computeroutput>result_type</computeroutput> is:
                       <programlisting>typename boost::result_of&lt;PrimitiveTransform(Expr, State, Data)&gt;::type</programlisting>
                     </para>
                   </listitem>
                   <listitem>
                     <para>
                       If <computeroutput>T</computeroutput> is of the form
                       <computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>)</computeroutput>, then
                       <computeroutput>result_type</computeroutput> is:
                       <programlisting>typename boost::result_of&lt;PrimitiveTransform(
   typename boost::result_of&lt;<classname>when</classname>&lt;<classname>_</classname>,A<subscript>0</subscript>&gt;(Expr, State, Data)&gt;::type,
   State,
   Data
 )&gt;::type</programlisting>
                     </para>
                   </listitem>
                   <listitem>
                     <para>
                       If <computeroutput>T</computeroutput> is of the form
                       <computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>, A<subscript>1</subscript>)</computeroutput>, then
                       <computeroutput>result_type</computeroutput> is:
                       <programlisting>typename boost::result_of&lt;PrimitiveTransform(
   typename boost::result_of&lt;<classname>when</classname>&lt;<classname>_</classname>,A<subscript>0</subscript>&gt;(Expr, State, Data)&gt;::type,
   typename boost::result_of&lt;<classname>when</classname>&lt;<classname>_</classname>,A<subscript>1</subscript>&gt;(Expr, State, Data)&gt;::type,
   Data
 )&gt;::type</programlisting>
                     </para>
                   </listitem>
                   <listitem>
                     <para>
                       If <computeroutput>T</computeroutput> is of the form
                       <computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>, A<subscript>1</subscript>, A<subscript>2</subscript>)</computeroutput>, then
                       <computeroutput>result_type</computeroutput> is:
                       <programlisting>typename boost::result_of&lt;PrimitiveTransform(
   typename boost::result_of&lt;<classname>when</classname>&lt;<classname>_</classname>,A<subscript>0</subscript>&gt;(Expr, State, Data)&gt;::type,
   typename boost::result_of&lt;<classname>when</classname>&lt;<classname>_</classname>,A<subscript>1</subscript>&gt;(Expr, State, Data)&gt;::type,
   typename boost::result_of&lt;<classname>when</classname>&lt;<classname>_</classname>,A<subscript>2</subscript>&gt;(Expr, State, Data)&gt;::type
 )&gt;::type</programlisting>
                     </para>
                   </listitem>
                   <listitem>
                     <para>
                       If <computeroutput>T</computeroutput> is of the form
                       <computeroutput><conceptname>PolymorphicFunctionObject</conceptname>(A<subscript>0</subscript>,...A<subscript>n</subscript>)</computeroutput>, then
                       <computeroutput>result_type</computeroutput> is:
                       <programlisting>typename boost::result_of&lt;PolymorphicFunctionObject(
   typename boost::result_of&lt;<classname>when</classname>&lt;<classname>_</classname>,A<subscript>0</subscript>&gt;(Expr, State, Data)&gt;::type,
   ...
   typename boost::result_of&lt;<classname>when</classname>&lt;<classname>_</classname>,A<subscript>n</subscript>&gt;(Expr, State, Data)&gt;::type
 &gt;::type</programlisting>
                     </para>
                   </listitem>
                 </itemizedlist>
               </para>
             </description>
           </typedef>
           <method-group name="public member functions">
             <method name="operator()" cv="const">
               <type>result_type</type>
               <parameter name="expr">
                 <paramtype>typename impl::expr_param</paramtype>
               </parameter>
               <parameter name="state">
                 <paramtype>typename impl::state_param</paramtype>
               </parameter>
               <parameter name="data">
                 <paramtype>typename impl::data_param</paramtype>
               </parameter>
               <description>
               <para>
                 <computeroutput><classname>proto::call</classname>&lt;T&gt;::impl&lt;Expr,State,Data&gt;::operator()</computeroutput> behaves as follows:
                 <itemizedlist>
                   <listitem>
                     <para>
                       If <computeroutput>T</computeroutput> if of the form
                       <computeroutput><conceptname>PrimitiveTransform</conceptname></computeroutput> or
                       <computeroutput><conceptname>PrimitiveTransform</conceptname>()</computeroutput>, then
                       return
                       <programlisting>PrimitiveTransform()(expr, state, data)</programlisting>
                     </para>
                   </listitem>
                   <listitem>
                     <para>
                       If <computeroutput>T</computeroutput> is of the form
                       <computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>)</computeroutput>, then
                       return
                       <programlisting>PrimitiveTransform()(
   <classname>when</classname>&lt;<classname>_</classname>,A<subscript>0</subscript>&gt;()(expr, state, data),
   state,
   sata
 )</programlisting>
                     </para>
                   </listitem>
                   <listitem>
                     <para>
                       If <computeroutput>T</computeroutput> is of the form
                       <computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>, A<subscript>1</subscript>)</computeroutput>, then
                       return:
                       <programlisting>PrimitiveTransform()(
   <classname>when</classname>&lt;<classname>_</classname>,A<subscript>0</subscript>&gt;()(expr, state, data),
   <classname>when</classname>&lt;<classname>_</classname>,A<subscript>1</subscript>&gt;()(expr, state, data),
   Data
 )</programlisting>
                     </para>
                   </listitem>
                   <listitem>
                     <para>
                       If <computeroutput>T</computeroutput> is of the form
                       <computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>, A<subscript>1</subscript>, A<subscript>2</subscript>)</computeroutput>, then
                       return
                       <programlisting>PrimitiveTransform()(
   <classname>when</classname>&lt;<classname>_</classname>,A<subscript>0</subscript>&gt;()(expr, state, data),
   <classname>when</classname>&lt;<classname>_</classname>,A<subscript>1</subscript>&gt;()(expr, state, data),
   <classname>when</classname>&lt;<classname>_</classname>,A<subscript>2</subscript>&gt;()(expr, state, data)
 )</programlisting>
                     </para>
                   </listitem>
                   <listitem>
                     <para>
                       If <computeroutput>T</computeroutput> is of the form
                       <computeroutput><conceptname>PolymorphicFunctionObject</conceptname>(A<subscript>0</subscript>,...A<subscript>n</subscript>)</computeroutput>, then
                       return:
                       <programlisting>PolymorphicFunctionObject()(
   <classname>when</classname>&lt;<classname>_</classname>,A<subscript>0</subscript>&gt;()(expr, state, data),
   ...
   <classname>when</classname>&lt;<classname>_</classname>,A<subscript>n</subscript>&gt;()(expr, state, data)
 )</programlisting>
                     </para>
                   </listitem>
                 </itemizedlist>
               </para>
               </description>
             </method>
           </method-group>
         </struct>
       </struct>
     </namespace>
   </namespace>
 </header>
	<?xml version="1.0" encoding="utf-8"?>
	<header name="boost/proto/transform/call.hpp">
	<para>Contains definition of the call<> transform. </para>
	<namespace name="boost">
	<namespace name="proto">
	<struct name="call">
	<template>
	<template-type-parameter name="T"/>
	</template>
	<purpose>Make the given <conceptname>CallableTransform</conceptname> into a <conceptname>PrimitiveTransform</conceptname>.</purpose>

	<description>
	<para>
	The purpose of <computeroutput>proto::call<></computeroutput> is to annotate a transform as callable
	so that <computeroutput><classname alt="proto::when">proto::when<></classname></computeroutput> knows
	how to apply it. The template parameter must be either a <conceptname>PrimitiveTransform</conceptname> or a
	<conceptname>CallableTransform</conceptname>; that is, a function type for which the return type is a callable
	<conceptname>PolymorphicFunctionObject</conceptname>.
	</para>

	<para>
	For the complete description of the behavior of the <computeroutput>proto::call<></computeroutput>
	transform, see the documentation for the nested
	<computeroutput>
	<classname alt="proto::call::impl">proto::call::impl<></classname>
	</computeroutput>
	class template.
	</para>
	</description>

	<inherit><type><classname>proto::transform</classname>< call<T> ></type></inherit>

	<struct name="impl">
	<template>
	<template-type-parameter name="Expr"/>
	<template-type-parameter name="State"/>
	<template-type-parameter name="Data"/>
	</template>
	<inherit><type><classname>proto::transform_impl</classname><Expr, State, Data></type></inherit>
	<typedef name="result_type">
	<type><replaceable>see-below</replaceable></type>
	<description>
	<para>
	<computeroutput><classname>proto::call</classname><T>::impl<Expr,State,Data>::result_type</computeroutput>
	is computed as follows:
	<itemizedlist>
	<listitem>
	<para>
	If <computeroutput>T</computeroutput> if of the form
	<computeroutput><conceptname>PrimitiveTransform</conceptname></computeroutput> or
	<computeroutput><conceptname>PrimitiveTransform</conceptname>()</computeroutput>, then
	<computeroutput>result_type</computeroutput> is:
	<programlisting>typename boost::result_of<PrimitiveTransform(Expr, State, Data)>::type</programlisting>
	</para>
	</listitem>
	<listitem>
	<para>
	If <computeroutput>T</computeroutput> is of the form
	<computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>)</computeroutput>, then
	<computeroutput>result_type</computeroutput> is:
	<programlisting>typename boost::result_of<PrimitiveTransform(
	typename boost::result_of<<classname>when</classname><<classname>_</classname>,A<subscript>0</subscript>>(Expr, State, Data)>::type,
	State,
	Data
	)>::type</programlisting>
	</para>
	</listitem>
	<listitem>
	<para>
	If <computeroutput>T</computeroutput> is of the form
	<computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>, A<subscript>1</subscript>)</computeroutput>, then
	<computeroutput>result_type</computeroutput> is:
	<programlisting>typename boost::result_of<PrimitiveTransform(
	typename boost::result_of<<classname>when</classname><<classname>_</classname>,A<subscript>0</subscript>>(Expr, State, Data)>::type,
	typename boost::result_of<<classname>when</classname><<classname>_</classname>,A<subscript>1</subscript>>(Expr, State, Data)>::type,
	Data
	)>::type</programlisting>
	</para>
	</listitem>
	<listitem>
	<para>
	If <computeroutput>T</computeroutput> is of the form
	<computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>, A<subscript>1</subscript>, A<subscript>2</subscript>)</computeroutput>, then
	<computeroutput>result_type</computeroutput> is:
	<programlisting>typename boost::result_of<PrimitiveTransform(
	typename boost::result_of<<classname>when</classname><<classname>_</classname>,A<subscript>0</subscript>>(Expr, State, Data)>::type,
	typename boost::result_of<<classname>when</classname><<classname>_</classname>,A<subscript>1</subscript>>(Expr, State, Data)>::type,
	typename boost::result_of<<classname>when</classname><<classname>_</classname>,A<subscript>2</subscript>>(Expr, State, Data)>::type
	)>::type</programlisting>
	</para>
	</listitem>
	<listitem>
	<para>
	If <computeroutput>T</computeroutput> is of the form
	<computeroutput><conceptname>PolymorphicFunctionObject</conceptname>(A<subscript>0</subscript>,...A<subscript>n</subscript>)</computeroutput>, then
	<computeroutput>result_type</computeroutput> is:
	<programlisting>typename boost::result_of<PolymorphicFunctionObject(
	typename boost::result_of<<classname>when</classname><<classname>_</classname>,A<subscript>0</subscript>>(Expr, State, Data)>::type,
	...
	typename boost::result_of<<classname>when</classname><<classname>_</classname>,A<subscript>n</subscript>>(Expr, State, Data)>::type
	>::type</programlisting>
	</para>
	</listitem>
	</itemizedlist>
	</para>
	</description>
	</typedef>
	<method-group name="public member functions">
	<method name="operator()" cv="const">
	<type>result_type</type>
	<parameter name="expr">
	<paramtype>typename impl::expr_param</paramtype>
	</parameter>
	<parameter name="state">
	<paramtype>typename impl::state_param</paramtype>
	</parameter>
	<parameter name="data">
	<paramtype>typename impl::data_param</paramtype>
	</parameter>
	<description>
	<para>
	<computeroutput><classname>proto::call</classname><T>::impl<Expr,State,Data>::operator()</computeroutput> behaves as follows:
	<itemizedlist>
	<listitem>
	<para>
	If <computeroutput>T</computeroutput> if of the form
	<computeroutput><conceptname>PrimitiveTransform</conceptname></computeroutput> or
	<computeroutput><conceptname>PrimitiveTransform</conceptname>()</computeroutput>, then
	return
	<programlisting>PrimitiveTransform()(expr, state, data)</programlisting>
	</para>
	</listitem>
	<listitem>
	<para>
	If <computeroutput>T</computeroutput> is of the form
	<computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>)</computeroutput>, then
	return
	<programlisting>PrimitiveTransform()(
	<classname>when</classname><<classname>_</classname>,A<subscript>0</subscript>>()(expr, state, data),
	state,
	sata
	)</programlisting>
	</para>
	</listitem>
	<listitem>
	<para>
	If <computeroutput>T</computeroutput> is of the form
	<computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>, A<subscript>1</subscript>)</computeroutput>, then
	return:
	<programlisting>PrimitiveTransform()(
	<classname>when</classname><<classname>_</classname>,A<subscript>0</subscript>>()(expr, state, data),
	<classname>when</classname><<classname>_</classname>,A<subscript>1</subscript>>()(expr, state, data),
	Data
	)</programlisting>
	</para>
	</listitem>
	<listitem>
	<para>
	If <computeroutput>T</computeroutput> is of the form
	<computeroutput><conceptname>PrimitiveTransform</conceptname>(A<subscript>0</subscript>, A<subscript>1</subscript>, A<subscript>2</subscript>)</computeroutput>, then
	return
	<programlisting>PrimitiveTransform()(
	<classname>when</classname><<classname>_</classname>,A<subscript>0</subscript>>()(expr, state, data),
	<classname>when</classname><<classname>_</classname>,A<subscript>1</subscript>>()(expr, state, data),
	<classname>when</classname><<classname>_</classname>,A<subscript>2</subscript>>()(expr, state, data)
	)</programlisting>
	</para>
	</listitem>
	<listitem>
	<para>
	If <computeroutput>T</computeroutput> is of the form
	<computeroutput><conceptname>PolymorphicFunctionObject</conceptname>(A<subscript>0</subscript>,...A<subscript>n</subscript>)</computeroutput>, then
	return:
	<programlisting>PolymorphicFunctionObject()(
	<classname>when</classname><<classname>_</classname>,A<subscript>0</subscript>>()(expr, state, data),
	...
	<classname>when</classname><<classname>_</classname>,A<subscript>n</subscript>>()(expr, state, data)
	)</programlisting>
	</para>
	</listitem>
	</itemizedlist>
	</para>
	</description>
	</method>
	</method-group>
	</struct>
	</struct>
	</namespace>
	</namespace>
	</header>