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 <Title>OptionalPointee Concept</Title>
 </HEAD>
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      ALT="C++ Boost" width="277" height="86">
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 <BR Clear>
 <H1>Concept: OptionalPointee</H1>

 <h3>Description</h3>
 A type is a model of <i>OptionalPointee</i> if it points to (or refers to) a value
 that may not exist. That is, if it has a <b>pointee</b> which might be <b>valid</b>
 (existent) or <b>invalid</b> (inexistent); and it is possible to test whether the
 pointee is valid or not.
 This model does <u>not</u> imply pointer semantics: i.e., it does not imply shallow copy nor
 aliasing.
 <h3>Notation</h3>
 <Table>
   <TR>
     <TD VAlign=top> <tt>T</tt> </TD>
     <TD VAlign=top> is a type that is a model of OptionalPointee</TD>
   </TR>
   <TR>
     <TD VAlign=top> <tt>t</tt> </TD>
     <TD VAlign=top> is an object of type <tt>T</tt> or possibly <tt>const T</tt></TD>
   </tr>
 </table>
 <h3>Definitions</h3>
 <h3>Valid expressions</h3>
 <Table border>
   <TR>
     <TH> Name </TH>
     <TH> Expression </TH>
     <TH> Return type </TH>
     <TH> Semantics </TH>
   </TR>
   <TR>
     <TD VAlign=top>Value Access</TD>
     <TD VAlign=top>&nbsp;<tt>*t</tt></TD>
     <TD VAlign=top>&nbsp;<tt>T&amp;</tt></TD>
     <TD VAlign=top>If the pointee is valid returns a reference to
       the pointee.<br>
       If the pointee is invalid the result is <i>undefined</i>.</TD>
     <TD VAlign=top> </TD>
   </TR>
   <TR>
     <TD VAlign=top>Value Access</TD>
     <TD VAlign=top>&nbsp;<tt>t-><i>xyz</i></tt></TD>
     <TD VAlign=top>&nbsp;<tt>T*</tt></TD>
     <TD VAlign=top>If the pointee is valid returns a builtin pointer to the pointee.<br>
       If the pointee is invalid the result is <i>undefined</i> (It might not even return NULL).<br>
     </TD>
     <TD VAlign=top> </TD>
   </TR>
   <TR>
     <TD VAlign=top>Validity Test</TD>
     <TD VAlign=top>&nbsp;<tt>t</tt><br>
      &nbsp;<tt>t != 0</tt><br>
      &nbsp;<tt>!!t</tt>
      </TD>
     <TD VAlign=top>&nbsp;bool </TD>
     <TD VAlign=top>If the pointee is valid returns true.<br>
       If the pointee is invalid returns false.</TD>
     <TD VAlign=top></TD>
   </TR>
   <TR>
     <TD VAlign=top>Invalidity Test</TD>
     <TD VAlign=top>&nbsp;<tt>t == 0</tt><br>
                    &nbsp;<tt>!t</tt>
     </TD>
     <TD VAlign=top>&nbsp;bool </TD>
     <TD VAlign=top>If the pointee is valid returns false.<br>
       If the pointee is invalid returns true.</TD>
     <TD VAlign=top></TD>
   </TR>
 </table>


 <h3>Models</h3>

 <UL>
   <LI><tt>pointers, both builtin and smart.</tt>
   <LI><tt>boost::optional&lt;&gt;</tt>
 </UL>

 <HR>
 <h3>OptionalPointee and relational operations</h3>
 <p>This concept does not define any particular semantic for relational operations, therefore,
 a type which models this concept might have either shallow or deep relational semantics.<br>
 For instance, pointers, which are models of OptionalPointee, have shallow relational operators:
 comparisons of pointers do not involve comparisons of pointees.
 This makes sense for pointers because they have shallow copy semantics.<br>
 But boost::optional&lt;T&gt;, on the other hand, which is also a model of OptionalPointee, has
 deep-copy and deep-relational semantics.<br>
 If generic code is written for this concept, it is important not to use relational
 operators directly because the semantics might be different depending on the actual type.<br>
 Still, the concept itsef can be used to define <i>deep</i> relational tests that can
 be used in generic code with any type which models OptionalPointee:</p>
 <a name="equal"></a>
 <p><u>Equivalence relation:</u></p>
 <pre>template&lt;class OptionalPointee&gt;
 inline
 bool equal_pointees ( OptionalPointee const&amp; x, OptionalPointee const&amp; y )
 {
   return (!x) != (!y) ? false : ( !x ? true : (*x) == (*y) ) ;
 }
 template&lt;class OptionalPointee&gt;
 struct equal_pointees_t : std::binary_function&lt;OptionalPointee,OptionalPointee,bool&gt;
 {
   bool operator() ( OptionalPointee const& x, OptionalPointee const& y ) const
     { return equal_pointees(x,y) ; }
 } ;
 </pre>
 <p>The preceding generic function and function object have the following semantics:<br>
 If both <b>x</b> and <b>y</b> have valid pointees, it compares values via <code>(*x == *y)</code>.<br>
 If only one has a valid pointee, returns <code>false</code>.<br>
 If both have invalid pointees, returns <code>true</code>.</p>
 <a name="less"></a>
 <p><u>Less-than relation:</u></p>
 <pre>template&lt;class OptionalPointee&gt;
 inline
 bool less_pointees ( OptionalPointee const&amp; x, OptionalPointee const&amp; y )
 {
   return !y ? false : ( !x ? true : (*x) < (*y) ) ;
 }
 template&lt;class OptionalPointee&gt;
 struct less_pointees_t : std::binary_function&lt;OptionalPointee,OptionalPointee,bool&gt;
 {
   bool operator() ( OptionalPointee const& x, OptionalPointee const& y ) const
     { return less_pointees(x,y) ; }
 } ;
 </pre>
 <p>The preceding generic function and function object have the following semantics:<br>
 If <b>y</b> has an invalid pointee, returns <code>false</code>.<br>
 Else, if <b>x</b> has an invalid pointee, returns <code>true</code>.<br>
 Else, ( <b>x</b> and <b>y</b> have valid pointees), compares values via <code>(*x &lt;
 *y).</code></p>
 <p><br>
 All these functions and function
 objects are is implemented in <a href="../../boost/utility/compare_pointees.hpp">compare_pointees.hpp</a></p>
 <p>Notice that OptionalPointee does not imply aliasing (and optional&lt;&gt; for instance does not alias);
 so direct usage of relational operators with the implied aliasing of shallow semantics
 -as with pointers- should not be used with generic code written for this concept.</p>

 <h3>Acknowledgements</h3>
 <p>Based on the original concept developed by Augustus Saunders.

 <br>
 </p>
 <HR>
 <TABLE>
 <TR valign=top>
 <TD nowrap>Copyright &copy 2003</TD><TD>
 <A HREF="mailto:fernando_cacciola@hotmail.com">Fernando Cacciola</A>
 </TD></TR></TABLE>

 <p>Distributed under the Boost Software License, Version 1.0. See
 <a href="http://www.boost.org/LICENSE_1_0.txt">www.boost.org/LICENSE_1_0.txt</a></p>

 </BODY>
 </HTML>
	<HTML>
	<Head>
	<Title>OptionalPointee Concept</Title>
	</HEAD>
	<BODY BGCOLOR="#ffffff" LINK="#0000ee" TEXT="#000000" VLINK="#551a8b"
	ALINK="#ff0000">
	<IMG SRC="../../boost.png"
	ALT="C++ Boost" width="277" height="86">
	<!--end header-->
	<BR Clear>
	<H1>Concept: OptionalPointee</H1>

	<h3>Description</h3>
	A type is a model of <i>OptionalPointee</i> if it points to (or refers to) a value
	that may not exist. That is, if it has a <b>pointee</b> which might be <b>valid</b>
	(existent) or <b>invalid</b> (inexistent); and it is possible to test whether the
	pointee is valid or not.
	This model does <u>not</u> imply pointer semantics: i.e., it does not imply shallow copy nor
	aliasing.
	<h3>Notation</h3>
	<Table>
	<TR>
	<TD VAlign=top> <tt>T</tt> </TD>
	<TD VAlign=top> is a type that is a model of OptionalPointee</TD>
	</TR>
	<TR>
	<TD VAlign=top> <tt>t</tt> </TD>
	<TD VAlign=top> is an object of type <tt>T</tt> or possibly <tt>const T</tt></TD>
	</tr>
	</table>
	<h3>Definitions</h3>
	<h3>Valid expressions</h3>
	<Table border>
	<TR>
	<TH> Name </TH>
	<TH> Expression </TH>
	<TH> Return type </TH>
	<TH> Semantics </TH>
	</TR>
	<TR>
	<TD VAlign=top>Value Access</TD>
	<TD VAlign=top> <tt>*t</tt></TD>
	<TD VAlign=top> <tt>T&</tt></TD>
	<TD VAlign=top>If the pointee is valid returns a reference to
	the pointee.<br>
	If the pointee is invalid the result is <i>undefined</i>.</TD>
	<TD VAlign=top> </TD>
	</TR>
	<TR>
	<TD VAlign=top>Value Access</TD>
	<TD VAlign=top> <tt>t-><i>xyz</i></tt></TD>
	<TD VAlign=top> <tt>T*</tt></TD>
	<TD VAlign=top>If the pointee is valid returns a builtin pointer to the pointee.<br>
	If the pointee is invalid the result is <i>undefined</i> (It might not even return NULL).<br>
	</TD>
	<TD VAlign=top> </TD>
	</TR>
	<TR>
	<TD VAlign=top>Validity Test</TD>
	<TD VAlign=top> <tt>t</tt><br>
	<tt>t != 0</tt><br>
	<tt>!!t</tt>
	</TD>
	<TD VAlign=top> bool </TD>
	<TD VAlign=top>If the pointee is valid returns true.<br>
	If the pointee is invalid returns false.</TD>
	<TD VAlign=top></TD>
	</TR>
	<TR>
	<TD VAlign=top>Invalidity Test</TD>
	<TD VAlign=top> <tt>t == 0</tt><br>
	<tt>!t</tt>
	</TD>
	<TD VAlign=top> bool </TD>
	<TD VAlign=top>If the pointee is valid returns false.<br>
	If the pointee is invalid returns true.</TD>
	<TD VAlign=top></TD>
	</TR>
	</table>


	<h3>Models</h3>

	<UL>
	<LI><tt>pointers, both builtin and smart.</tt>
	<LI><tt>boost::optional<></tt>
	</UL>

	<HR>
	<h3>OptionalPointee and relational operations</h3>
	<p>This concept does not define any particular semantic for relational operations, therefore,
	a type which models this concept might have either shallow or deep relational semantics.<br>
	For instance, pointers, which are models of OptionalPointee, have shallow relational operators:
	comparisons of pointers do not involve comparisons of pointees.
	This makes sense for pointers because they have shallow copy semantics.<br>
	But boost::optional<T>, on the other hand, which is also a model of OptionalPointee, has
	deep-copy and deep-relational semantics.<br>
	If generic code is written for this concept, it is important not to use relational
	operators directly because the semantics might be different depending on the actual type.<br>
	Still, the concept itsef can be used to define <i>deep</i> relational tests that can
	be used in generic code with any type which models OptionalPointee:</p>
	<a name="equal"></a>
	<p><u>Equivalence relation:</u></p>
	<pre>template<class OptionalPointee>
	inline
	bool equal_pointees ( OptionalPointee const& x, OptionalPointee const& y )
	{
	return (!x) != (!y) ? false : ( !x ? true : (x) == (y) ) ;
	}
	template<class OptionalPointee>
	struct equal_pointees_t : std::binary_function<OptionalPointee,OptionalPointee,bool>
	{
	bool operator() ( OptionalPointee const& x, OptionalPointee const& y ) const
	{ return equal_pointees(x,y) ; }
	} ;
	</pre>
	<p>The preceding generic function and function object have the following semantics:<br>
	If both <b>x</b> and <b>y</b> have valid pointees, it compares values via <code>(x == y)</code>.<br>
	If only one has a valid pointee, returns <code>false</code>.<br>
	If both have invalid pointees, returns <code>true</code>.</p>
	<a name="less"></a>
	<p><u>Less-than relation:</u></p>
	<pre>template<class OptionalPointee>
	inline
	bool less_pointees ( OptionalPointee const& x, OptionalPointee const& y )
	{
	return !y ? false : ( !x ? true : (x) < (y) ) ;
	}
	template<class OptionalPointee>
	struct less_pointees_t : std::binary_function<OptionalPointee,OptionalPointee,bool>
	{
	bool operator() ( OptionalPointee const& x, OptionalPointee const& y ) const
	{ return less_pointees(x,y) ; }
	} ;
	</pre>
	<p>The preceding generic function and function object have the following semantics:<br>
	If <b>y</b> has an invalid pointee, returns <code>false</code>.<br>
	Else, if <b>x</b> has an invalid pointee, returns <code>true</code>.<br>
	Else, ( <b>x</b> and <b>y</b> have valid pointees), compares values via <code>(*x <
	*y).</code></p>
	<p><br>
	All these functions and function
	objects are is implemented in <a href="../../boost/utility/compare_pointees.hpp">compare_pointees.hpp</a></p>
	<p>Notice that OptionalPointee does not imply aliasing (and optional<> for instance does not alias);
	so direct usage of relational operators with the implied aliasing of shallow semantics
	-as with pointers- should not be used with generic code written for this concept.</p>

	<h3>Acknowledgements</h3>
	<p>Based on the original concept developed by Augustus Saunders.

	<br>
	</p>
	<HR>
	<TABLE>
	<TR valign=top>
	<TD nowrap>Copyright &copy 2003</TD><TD>
	<A HREF="mailto:fernando_cacciola@hotmail.com">Fernando Cacciola</A>
	</TD></TR></TABLE>

	<p>Distributed under the Boost Software License, Version 1.0. See
	<a href="http://www.boost.org/LICENSE_1_0.txt">www.boost.org/LICENSE_1_0.txt</a></p>

	</BODY>
	</HTML>