libstdc++-v3/doc/xml/manual/algorithms.xml - gcc - Git at Google

 <chapter xmlns="http://docbook.org/ns/docbook" version="5.0"
 	 xml:id="std.algorithms" xreflabel="Algorithms">
 <?dbhtml filename="algorithms.html"?>

 <info><title>
   Algorithms
   <indexterm><primary>Algorithms</primary></indexterm>
 </title>
   <keywordset>
     <keyword>ISO C++</keyword>
     <keyword>library</keyword>
     <keyword>algorithm</keyword>
   </keywordset>
 </info>


 <para>
   The neatest accomplishment of the algorithms section is that all the
   work is done via iterators, not containers directly.  This means two
   important things:
 </para>
 <orderedlist inheritnum="ignore" continuation="restarts">
   <listitem>
     <para>
       Anything that behaves like an iterator can be used in one of
       these algorithms.  Raw pointers make great candidates, thus
       built-in arrays are fine containers, as well as your own
       iterators.
     </para>
   </listitem>
   <listitem>
     <para>
       The algorithms do not (and cannot) affect the container as a
       whole; only the things between the two iterator endpoints.  If
       you pass a range of iterators only enclosing the middle third of
       a container, then anything outside that range is inviolate.
     </para>
   </listitem>
 </orderedlist>
 <para>
   Even strings can be fed through the algorithms here, although the
   string class has specialized versions of many of these functions
   (for example, <code>string::find()</code>).  Most of the examples
   on this page will use simple arrays of integers as a playground
   for algorithms, just to keep things simple.  The use of
   <emphasis>N</emphasis> as a size in the examples is to keep things
   easy to read but probably won't be valid code.  You can use wrappers
   such as those described in
   the <link linkend="std.containers">containers section</link> to keep
   real code readable.
 </para>
 <para>
   The single thing that trips people up the most is the definition
   of <emphasis>range</emphasis> used with iterators; the famous
   "past-the-end" rule that everybody loves to hate.  The
   <link linkend="std.iterators">iterators section</link> of this
     document has a complete explanation of this simple rule that seems
     to cause so much confusion.  Once you
     get <emphasis>range</emphasis> into your head (it's not that hard,
     honest!), then the algorithms are a cakewalk.
 </para>

 <!-- Sect1 01 : Non Modifying -->

 <!-- Sect1 02 : Mutating -->
 <section xml:id="std.algorithms.mutating" xreflabel="Mutating"><info><title>Mutating</title></info>


   <section xml:id="algorithms.mutating.swap" xreflabel="swap"><info><title><function>swap</function></title></info>


     <section xml:id="algorithms.swap.specializations" xreflabel="Specializations"><info><title>Specializations</title></info>


    <para>If you call <code> std::swap(x,y); </code> where x and y are standard
       containers, then the call will automatically be replaced by a call to
       <code> x.swap(y); </code> instead.
    </para>
    <para>This allows member functions of each container class to take over, and
       containers' swap functions should have O(1) complexity according to
       the standard.  (And while "should" allows implementations to
       behave otherwise and remain compliant, this implementation does in
       fact use constant-time swaps.)  This should not be surprising, since
       for two containers of the same type to swap contents, only some
       internal pointers to storage need to be exchanged.
    </para>

     </section>
   </section>
 </section>

 <!-- Sect1 03 : Sorting -->

 </chapter>
	<chapter xmlns="http://docbook.org/ns/docbook" version="5.0"
	xml:id="std.algorithms" xreflabel="Algorithms">
	<?dbhtml filename="algorithms.html"?>

	<info><title>
	Algorithms
	<indexterm><primary>Algorithms</primary></indexterm>
	</title>
	<keywordset>
	<keyword>ISO C++</keyword>
	<keyword>library</keyword>
	<keyword>algorithm</keyword>
	</keywordset>
	</info>



	<para>
	The neatest accomplishment of the algorithms section is that all the
	work is done via iterators, not containers directly. This means two
	important things:
	</para>
	<orderedlist inheritnum="ignore" continuation="restarts">
	<listitem>
	<para>
	Anything that behaves like an iterator can be used in one of
	these algorithms. Raw pointers make great candidates, thus
	built-in arrays are fine containers, as well as your own
	iterators.
	</para>
	</listitem>
	<listitem>
	<para>
	The algorithms do not (and cannot) affect the container as a
	whole; only the things between the two iterator endpoints. If
	you pass a range of iterators only enclosing the middle third of
	a container, then anything outside that range is inviolate.
	</para>
	</listitem>
	</orderedlist>
	<para>
	Even strings can be fed through the algorithms here, although the
	string class has specialized versions of many of these functions
	(for example, <code>string::find()</code>). Most of the examples
	on this page will use simple arrays of integers as a playground
	for algorithms, just to keep things simple. The use of
	<emphasis>N</emphasis> as a size in the examples is to keep things
	easy to read but probably won't be valid code. You can use wrappers
	such as those described in
	the <link linkend="std.containers">containers section</link> to keep
	real code readable.
	</para>
	<para>
	The single thing that trips people up the most is the definition
	of <emphasis>range</emphasis> used with iterators; the famous
	"past-the-end" rule that everybody loves to hate. The
	<link linkend="std.iterators">iterators section</link> of this
	document has a complete explanation of this simple rule that seems
	to cause so much confusion. Once you
	get <emphasis>range</emphasis> into your head (it's not that hard,
	honest!), then the algorithms are a cakewalk.
	</para>

	<!-- Sect1 01 : Non Modifying -->

	<!-- Sect1 02 : Mutating -->
	<section xml:id="std.algorithms.mutating" xreflabel="Mutating"><info><title>Mutating</title></info>


	<section xml:id="algorithms.mutating.swap" xreflabel="swap"><info><title><function>swap</function></title></info>


	<section xml:id="algorithms.swap.specializations" xreflabel="Specializations"><info><title>Specializations</title></info>


	<para>If you call <code> std::swap(x,y); </code> where x and y are standard
	containers, then the call will automatically be replaced by a call to
	<code> x.swap(y); </code> instead.
	</para>
	<para>This allows member functions of each container class to take over, and
	containers' swap functions should have O(1) complexity according to
	the standard. (And while "should" allows implementations to
	behave otherwise and remain compliant, this implementation does in
	fact use constant-time swaps.) This should not be surprising, since
	for two containers of the same type to swap contents, only some
	internal pointers to storage need to be exchanged.
	</para>

	</section>
	</section>
	</section>

	<!-- Sect1 03 : Sorting -->

	</chapter>